POLG-Related Disorders

Bruce H Cohen; Patrick F Chinnery; William C Copeland

NCBI Bookshelf. A service of the National Library of Medicine, National Institutes of Health.

Adam MP, Feldman J, Mirzaa GM, et al., editors. GeneReviews® [Internet]. Seattle (WA): University of Washington, Seattle; 1993-2024.

GeneReviews^® [Internet].

Show details

GeneReviews by Title

< Prev Next >

POLG-Related Disorders

Bruce H Cohen, MD, Patrick F Chinnery, BMedSci, MBBS, PhD, FRCPath, FRCP, FMedSci, and William C Copeland, PhD.

Author Information and Affiliations

Initial Posting: March 16, 2010; Last Update: February 29, 2024.

Estimated reading time: 56 minutes

Summary

Clinical characteristics.

POLG-related disorders comprise a continuum of overlapping phenotypes that were clinically defined before the molecular basis was known. POLG-related disorders can therefore be considered an overlapping spectrum of disease presenting from early childhood to late adulthood. The age of onset broadly correlates with the clinical phenotype.

In individuals with early-onset disease (prior to age 12 years), liver involvement, feeding difficulties, seizures, hypotonia, and muscle weakness are the most common clinical features. This group has the worst prognosis.

In the juvenile/adult-onset form (age 12-40 years), disease is typically characterized by peripheral neuropathy, ataxia, seizures, stroke-like episodes, and, in individuals with longer survival, progressive external ophthalmoplegia (PEO). This group generally has a better prognosis than the early-onset group.

Late-onset disease (after age 40 years) is characterized by ptosis and PEO, with additional features such as peripheral neuropathy, ataxia, and muscle weakness. This group overall has the best prognosis.

Diagnosis/testing.

Establishing the diagnosis of a POLG-related disorder relies on clinical findings and the identification of biallelic POLG pathogenic variants on molecular genetic testing for all phenotypes except autosomal dominant progressive external ophthalmoplegia (adPEO), for which identification of a heterozygous POLG pathogenic variant on molecular genetic testing is diagnostic.

Management.

Treatment of manifestations: Clinical management is largely supportive and involves standard approaches for associated complications including occupational, physical, and speech therapy; nutritional support; respiratory support; and standard treatment of liver failure, epilepsy, movement abnormalities, sleep disorders, vision, and hearing issues.

Surveillance: Evaluations by a multidisciplinary team of health care providers based on clinical findings; routine evaluation of growth, nutrition, oral intake, and respiratory status; monitoring of liver enzymes every three months or as clinically indicated; monitoring of epilepsy with repeat liver function tests after introduction of any new anti-seizure medication.

Agents/circumstances to avoid: Valproic acid (Depakene^®) and sodium divalproate (divalproex) (Depakote^®) because of the risk of precipitating and/or accelerating liver disease.

Genetic counseling.

Early-onset and juvenile/adult-onset POLG-related disorders are typically caused by biallelic pathogenic variants and inherited in an autosomal recessive manner. Late-onset PEO may be caused by a heterozygous POLG pathogenic variant and inherited in an autosomal dominant manner.

Autosomal recessive inheritance: If both parents are known to be heterozygous for a POLG pathogenic variant, each sib of an affected individual has at conception a 25% chance of inheriting biallelic pathogenic variants and being affected, a 50% chance of being heterozygous, and a 25% chance of inheriting neither of the familial POLG pathogenic variants. Heterozygous sibs of a proband with an autosomal recessive POLG-related disorder are typically asymptomatic. Once the POLG pathogenic variants have been identified in an affected family member, testing for at-risk family members is possible.

Autosomal dominant inheritance: Most individuals with PEO caused by a heterozygous POLG pathogenic variant (i.e., adPEO) have an affected parent, although age of onset and severity of presentation can vary greatly from generation to generation. Each child of an individual with POLG-related adPEO has a 50% chance of inheriting the pathogenic variant.

Once the POLG pathogenic variant(s) have been identified in an affected family member, prenatal and preimplantation genetic testing for POLG-related disorders is possible.

GeneReview Scope

POLG-related disorders encompass a broad range of phenotypes. With the current widespread use of multigene panels and comprehensive genomic testing based on an unbiased (i.e., not phenotype-driven) approach, it has become apparent that (1) POLG pathogenic variants are associated with a continuum of features – encompassing and transcending previously defined clinical designations – in which almost any organ system can be involved, and (2) the presenting features in individuals with POLG-related disorders cluster by age (e.g., neonates are likely to present with liver involvement, feeding difficulties, and seizures, while adolescents are likely to present with seizure, ataxia, and peripheral neuropathy) [Rahman & Copeland 2019, Hikmat et al 2020].

POLG-Related Disorders: Typically Presenting Features by Age

Age at Onset	Feeding Difficulties	Hypotonia	Liver Involvement	Seizures	Stroke-Like Episodes	Migraine	Ataxia	Peripheral Neuropathy	Limb Weakness	PEO	Ptosis	Selected Clinical Designations
<12 yrs	+++	+	+++	+++	+	+	+	+				AHS MCHS
12-40 yrs			+	+++	+	+	+++	+++	+	+		MEMSA ANS
>40 yrs							+++	+	+	+++	+++	arPEO adPEO

: Adapted from Rahman & Copeland [2019] and Hikmat et al [2020]
: +++ = feature is typically present; + = feature is often present
: adPEO = autosomal dominant progressive external ophthalmoplegia; AHS = Alpers-Huttenlocher syndrome; ANS = ataxia neuropathy spectrum; arPEO = autosomal recessive progressive external ophthalmoplegia; MCHS = myocerebrohepatopathy spectrum; MEMSA = myoclonic epilepsy myopathy sensory ataxia

Diagnosis

Suggestive Findings

POLG-related disorders comprise a continuum of overlapping phenotypes. A POLG-related disorder should be suspected in individuals with combinations of the following clinical features and laboratory and neuroimaging findings.

Clinical features. Clinical features form a continuum but vary in their age of onset. Apart from progressive external ophthalmoplegia (PEO) / ptosis, other features could present at any time from infancy to adulthood. The most common clinical features by age of onset are:

Prior to age 12 years (early-onset disease):
- Liver involvement (See Laboratory Findings.)
- Feeding difficulties
- Seizures
- Hypotonia and muscle weakness that can evolve into corticospinal tract dysfunction (spasticity and dystonia)
Between age 12 and 40 years (juvenile/adult-onset disease):
- Ataxia
- Peripheral neuropathy
- Seizures
- Stroke-like episodes
- PEO (in individuals with longer survival)
After age 40 years (late-onset disease):
- Ptosis
- PEO
- Ataxia
- Muscle weakness
Other features
- Developmental delay, especially in childhood-onset disease
- Movement disorder (e.g., myoclonus, dysarthria, choreoathetosis, parkinsonism)
- Myopathy (e.g., proximal > distal limb weakness with fatigue and exercise intolerance)
- Episodic psychomotor regression
- Psychiatric illness (e.g., depression, mood disorder), more commonly reported in adult-onset phenotypes
- Endocrinopathy (e.g., premature ovarian failure)

Laboratory findings

Elevated serum lactate in serum and cerebrospinal fluid (CSF) is common throughout the spectrum of phenotypes but is more common in early-onset disease (however, normal values do not eliminate the likelihood of a POLG-related disorder).
CSF protein levels are generally elevated in individuals with Alpers-Huttenlocher syndrome (AHS) and other POLG-related disorders, but absence of this finding does not exclude a POLG-related disorder.
Evidence of liver dysfunction or failure can be present, which may occur following exposure to certain anti-seizure medications. This could result in elevation of liver enzymes (alanine transaminase, aspartate transaminase, and gamma-glutamyl transferase) as well as synthetic liver dysfunction, causing hypoglycemia, hyperammonemia, elevated glutamine, hyperbilirubinemia, prolonged bleeding times (international normalized ratio, prothrombin time, partial thromboplastin time), hypoalbuminemia, and low cholesterol levels.
Respiratory chain defect and/or a defect of mitochondrial DNA (mtDNA) (depletion or multiple deletions) can be present. This could result in respiratory chain dysfunction, identified by either enzymatic assays or polarographic assays. Depletion of mtDNA can be measured by comparing mtDNA to nuclear DNA content in an affected tissue (e.g., liver). Normal respiratory chain function or absence of mtDNA depletion does not rule out a POLG-related disorder.
In muscle biopsy samples, ragged-red fibers, COX-negative fibers, excessive lipid deposits, and abnormal respiratory chain activities can be present. However, biochemical findings on muscle biopsy can be normal.

Neuroimaging features

Brain computerized tomography (CT) or magnetic resonance imaging (MRI) may be normal early in the course of AHS.
As AHS evolves, neuroimaging shows gliosis (initially more pronounced in occipital lobe regions) and generalized brain atrophy. These findings are also reported in some individuals with adult-onset POLG-related disorders.
Cortical focal lesions manifesting as T₂/FLAIR hyperintensities in cortical and subcortical areas can be seen. These findings are typical in AHS but have also been reported in sensory ataxia neuropathy dysarthria and ophthalmoplegia (SANDO) and ataxia neuropathy spectrum (ANS) [Parada-Garza et al 2020, García-Cabo et al 2023].

Other diagnostic studies

Abnormal epileptiform activity over the occipital lobes in individuals with epilepsy
Abnormal nerve conduction studies (NCVs)

Establishing the Diagnosis

The diagnosis of most POLG-related disorders is established in a proband by identification of biallelic pathogenic (or likely pathogenic) variants in POLG by molecular genetic testing (see Table 1). The diagnosis of autosomal dominant progressive external ophthalmoplegia (adPEO) is established in a proband by identification of a heterozygous pathogenic (or likely pathogenic) variant in POLG by molecular genetic testing (see Table 1).

Note: (1) Per ACMG/AMP variant interpretation guidelines, the terms "pathogenic variant" and "likely pathogenic variant" are synonymous in a clinical setting, meaning that both are considered diagnostic and can be used for clinical decision making [Richards et al 2015]. Reference to "pathogenic variants" in this GeneReview is understood to include likely pathogenic variants. (2) The identification of variant(s) of uncertain significance cannot be used to confirm or rule out the diagnosis.

Molecular genetic testing approaches can include a combination of gene-targeted testing (single gene testing, multigene panel) and comprehensive genomic testing (exome sequencing, genome sequencing). Gene-targeted testing requires that the clinician determine which gene(s) are likely involved (see Option 1), whereas comprehensive genomic testing does not (see Option 2).

Option 1

Single-gene testing. Sequence analysis of POLG is performed first to detect missense, nonsense, and splice site variants and small intragenic deletions/insertions. Note: Depending on the sequencing method used, single-exon, multiexon, or whole-gene deletions/duplications may not be detected. If only one or no variant is detected by the sequencing method used, the next step is to perform gene-targeted deletion/duplication analysis to detect intragenic and whole-gene deletions or duplications.

Note: (1) In individuals with a suspected autosomal recessive POLG-related disorder but in whom only one POLG pathogenic variant has been identified by single-gene testing, identification of a second in trans pathogenic variant in POLG, use of RNA sequencing of POLG, or identification of pathogenic variants in other genes known to be associated with the phenotype may be revealing. (2) Sequence analysis of TWNK (formerly C10orf2 or PEO1) may be considered in persons with a suspected autosomal recessive POLG-related disorder but in whom only one POLG pathogenic variant has been identified by single-gene testing, to investigate the possibility of digenic inheritance (see Differential Diagnosis). Digenic inheritance has been reported in PEO in two individuals with pathogenic variants in POLG and TWNK [Van Goethem et al 2003a, Da Pozzo et al 2015]. (3) In the 5% of simplex cases of PEO in which only a single pathogenic variant is identified, it can be difficult to distinguish between autosomal recessive inheritance and autosomal dominant inheritance caused by a de novo POLG pathogenic variant.

A multigene panel that includes POLG, TWNK (formerly C10orf2 or PEO1), and other genes of interest (see Differential Diagnosis) may be considered to identify the genetic cause of the condition while limiting identification of variants of uncertain significance and pathogenic variants in genes that do not explain the underlying phenotype. Note: (1) The genes included in the panel and the diagnostic sensitivity of the testing used for each gene vary by laboratory and are likely to change over time. (2) Some multigene panels may include genes not associated with the condition discussed in this GeneReview. (3) In some laboratories, panel options may include a custom laboratory-designed panel and/or custom phenotype-focused exome analysis that includes genes specified by the clinician. (4) Methods used in a panel may include sequence analysis, deletion/duplication analysis, and/or other non-sequencing-based tests.

For an introduction to multigene panels click here. More detailed information for clinicians ordering genetic tests can be found here.

Option 2

Comprehensive genomic testing including exome sequencing, mtDNA sequencing, and genome sequencing may be considered.

For an introduction to comprehensive genomic testing click here. More detailed information for clinicians ordering genomic testing can be found here.

Table 1.

Molecular Genetic Testing Used in POLG-Related Disorders

Gene ¹	Method	Proportion of Pathogenic Variants ² Identified by Method
POLG	Sequence analysis ³	~95% ⁴
POLG	Gene-targeted deletion/duplication analysis ⁵	~5% ⁶

1.: See Table A. Genes and Databases for chromosome locus and protein.
2.: See Molecular Genetics for information on variants detected in this gene.
3.: Sequence analysis detects variants that are benign, likely benign, of uncertain significance, likely pathogenic, or pathogenic. Variants may include missense, nonsense, and splice site variants and small intragenic deletions/insertions; typically, exon or whole-gene deletions/duplications are not detected. For issues to consider in interpretation of sequence analysis results, click here.
4.: Ashley et al [2008], Hunter et al [2011], and data derived from the subscription-based professional view of Human Gene Mutation Database [Stenson et al 2020]
5.: Gene-targeted deletion/duplication analysis detects intragenic deletions or duplications. Methods used may include a range of techniques such as quantitative PCR, long-range PCR, multiplex ligation-dependent probe amplification (MLPA), and a gene-targeted microarray designed to detect single-exon deletions or duplications. Exome and genome sequencing may be able to detect deletions/duplications using breakpoint detection or read depth; however, sensitivity can be lower than gene-targeted deletion/duplication analysis.
6.: Compton et al [2011], Naess et al [2012], Rouzier et al [2014], Lin et al [2021]

Clinical Characteristics

Clinical Description

POLG-related disorders comprise a continuum of broad and overlapping phenotypes that range from fatal neonatal-onset disease to mild late-onset disease with myopathy and progressive external ophthalmoplegia (PEO).

Although some affected individuals present with one of the clinical entities caused by POLG pathogenic variants, many have some, but not all, of the features of one or more of the recognized phenotypes. Although clinical phenotypes in affected individuals from the same family are often similar, ages of onset, specific features, and rate of progression may differ. POLG-related disorders can therefore be considered an overlapping spectrum of disease presenting from early childhood to late adulthood. The age of onset broadly correlates with the clinical phenotype [Rahman & Copeland 2019, Hikmat et al 2020]. Table 2 summarizes the clinical findings in POLG-related disorders.

Table 2.

Clinical Findings in POLG-Related Disorders

System	Manifestation	% of Persons w/Manifestation
Neurologic	Epilepsy (incl myoclonic, focal motor & generalized seizures, status epilepticus, & epilepsia partialis continua)	~70%
	Tone abnormalities (most commonly hypotonia)	~50%
	"Cerebrovascular" involvement (incl migraines & stroke-like episodes)	~36%
	Movement disorder (incl extrapyramidal movement disorders such as parkinsonism & chorea, & cerebellar ataxia)	~60%
	Peripheral neuropathy (sensory neuronopathy / ganglionopathy & axonal sensorimotor neuropathy ¹)	~53%
	Headache (migraine-like)	~36%
Gastrointestinal	Liver issues (most notably liver failure that is either spontaneous or precipitated by valproic acid or sodium divalproate in children)	~64%
Gastrointestinal	Gastrointestinal dysmotility (incl vomiting, diarrhea, & feeding difficulties)	~6%-52%
Ophthalmologic	Cataracts	~7%
	Ptosis & external ophthalmoplegia	~34%-38%
	Cortical blindness	~30%
	Retinopathy	~2%
Audiologic	Sensorineural hearing loss	~11%
Neuromuscular/ myopathy	Proximal or distal myopathy	~70%
Neuromuscular/ myopathy	Exercise intolerance	Common in adolescence & adult-onset phenotypes
Endocrine	Primary ovarian failure & ovarian dysgenesis	Rare
	Primary testicular failure	Rare
	Diabetes mellitus	~1%
Renal	Renal tubular acidosis, renal failure, renal stones	~11% (MCHS)
Respiratory	Ventilatory Weakness (muscle, nerve, central respiratory drive)	~12%

: Based on Hudson & Chinnery [2006], Chow et al [2017], Hikmat et al [2017b], Rahman & Copeland [2019], and Hikmat et al [2020]
: MCHS = childhood myocerebrohepatopathy spectrum
1.: Corresponds to the acronym SANDO (sensory ataxia neuropathy dysarthria and ophthalmoplegia)

Early-Onset Disease (Prior to Age 12 Years)

Typical features of early-onset POLG-related disorders (prior to age 12 years) include liver involvement, feeding difficulties, seizures, hypotonia and muscle weakness. Prognosis is usually the worst of the three age-related groups. Phenotypes that typically occur include Alpers-Huttenlocher syndrome and childhood myocerebrohepatopathy spectrum.

Alpers-Huttenlocher Syndrome (AHS)

AHS, one of the most severe phenotypic manifestations in the POLG-related spectrum, is characterized by progressive and severe encephalopathy with intractable epilepsy, neuropathy, and liver failure. While AHS is usually fatal, age of onset, rate of neurologic deterioration, presence of liver failure, and age of death vary among affected individuals [Davidzon et al 2006, Nguyen et al 2006, Wong et al 2008, Cohen & Naviaux 2010, Saneto et al 2013, Hikmat et al 2020]. Children with AHS appear healthy at birth and may develop normally over the first few weeks to years of life. Some have variable degrees of developmental delay prior to the initial recognition of neurodegeneration. Onset is usually between ages two and four years but ranges overall from one month to 36 years.

Seizures are the first sign of AHS in about 50% of affected children. Seizures may be simple focal, primary generalized, or myoclonic. The most common early seizure types are partial seizures and secondary generalized tonic-clonic seizures. In some children, the first seizure presents with status epilepticus. EEG findings include high-amplitude slow activity with smaller polyspikes or intermittent continuous spike-wave activity [Hikmat et al 2017a].

In some instances, the initial seizure type is epilepsia partialis continua (EPC), a classic motor seizure type that involves only one portion of the body (e.g., a limb) with constant and repetitive myoclonic jerking, continuing for hours or days with or without dramatic effects on consciousness. EPC is not always apparent as an abnormality on EEG and can be mistaken for a conversion reaction. EEG may be normal or show only focal slowing of the background rhythm.

Over time, seizures can evolve into a complex epileptic disorder such as focal status epilepticus, EPC, or multifocal myoclonic epilepsy [Horvath et al 2006, Tzoulis et al 2006, Hikmat et al 2017a].

In some children, seizures are initially controllable with standard dosages of anti-seizure medications (ASM); in others, seizures, such as EPC, are refractory from the onset. Over time, seizures become increasingly resistant to ASMs. (See Treatment of Manifestations for further information about management of seizures.)

Of note, valproic acid (Depakene^®) and sodium divalproate (divalproex) (Depakote^®) can precipitate liver dysfunction in individuals with AHS and should be avoided. These medications are considered absolutely contraindicated in individuals with POLG-related disorders [Saneto et al 2010] (see Agents/Circumstances to Avoid).

Headaches, another common first presenting symptom, are typically associated with visual sensations or visual auras that reflect early occipital lobe dysfunction and have features similar to migraines [Hakonen et al 2005, Tzoulis et al 2006, Hikmat et al 2020]. Stroke and stroke-like episodes may occur as well [Horvath et al 2006].

Movement disorders, primarily myoclonus and choreoathetosis, are common [Horvath et al 2006]. Myoclonus can be difficult to distinguish from myoclonic seizures and EPC. Palatal myoclonus resulting from involvement of the inferior olivary nuclei can be seen as well. Some individuals develop parkinsonism, which may temporarily respond to levodopa [Luoma et al 2004, Mancuso et al 2004] (see Treatment of Manifestations).

Neuropathy and ataxia develop in all persons with AHS unless the disease process is so rapid that it results in early death. All neurologic signs and symptoms, including ataxia and nystagmus, may worsen during infections or with other physiologic stressors.

Areflexia (resulting from neuropathy) and hypotonia (possibly the result of generalized weakness as part of systemic illness or pyramidal or extrapyramidal dysfunction) are often both present early in the disease course.

Episodic psychomotor regression is variably present at the time of initial consideration of the diagnosis. The major motor manifestation is a progressive spastic paraparesis resulting from progressive loss of cortical neuronal function. Progressive spasticity occurs universally, has variable onset, and evolves over months to years.

Loss of cognitive function occurs throughout the course of the disease, but the time of onset and rate of progression are variable. Significant sudden or rapid regression is often seen during infectious illnesses. The clinical manifestations may include somnolence, loss of concentration, loss of language skills (both receptive and expressive), irritability with loss of normal emotional responses, and memory deficits. In addition to cognitive impairment caused by refractory epilepsy, high dosages of ASMs can lead to significant cognitive dysfunction. Therefore, the degree of cognitive dysfunction is often difficult to assess due to frequent seizures and high therapeutic doses of ASMs.

Vision loss leading to blindness may appear months to years after the onset of other neurologic manifestations. Retinopathy (see Retinitis Pigmentosa) may also play a less important role in vision loss [Hakonen et al 2005, Hikmat et al 2020]. Hearing loss is variable [Hakonen et al 2005, Horvath et al 2006].

Liver involvement can progress rapidly to end-stage liver failure within a few months, although this is highly variable. End-stage liver disease is often heralded by hypoalbuminemia and prolonged coagulation time, followed shortly thereafter by fasting hypoglycemia and hyperammonemia. Rapid-onset liver failure has been described when valproic acid (Depakene^®) and sodium divalproate (divalproex) (Depakote^®) have been used to treat seizures, although the introduction of other ASMs, including phenytoin, may also play a role in onset of hepatic failure (see Agents/Circumstances to Avoid).

Disease progression is variable in timing and rapidity. Loss of neurologic function culminates in dementia, spastic quadriparesis from corticospinal tract involvement, visual loss, and death. The rate of neurodegeneration varies and is marked by periods of stability. The typical life expectancy from onset of first symptoms ranges from three months to 12 years.

Neuroimaging. CT or MRI of the brain may be normal early in the course of AHS. As the illness evolves, neuroimaging shows gliosis (initially more pronounced in the occipital lobe regions) and generalized cortical atrophy. Restricted diffusion unilaterally in the pulvinar and occipital region is described in the acute phase. FLAIR and T₂-weighted sequence images demonstrate high signal intensity in deep gray matter nuclei, especially in the thalamus and cerebellum [Alves et al 2018]. Progressive cerebellar atrophy can occur in addition to cortical atrophy. The pons, midbrain, and globus pallidum can also be involved. Lesions described in the inferior olivary nuclei may also be a part of AHS and are associated with palatal myoclonus. Brain magnetic resonance spectroscopy (MRS) typically shows reduced N-acetylaspartate, normal creatine, and lactate.

Histopathologic abnormalities

Brain. The gross appearance of the brain varies from normal to severe atrophy, depending on the state of disease progression. Central nervous system regions affected in AHS are the same as those affected by Leigh syndrome but typically evolve in the reverse order. For example, in AHS, gliosis is most severe and occurs earliest in the cerebral cortex, followed by the cerebellum, basal ganglia, and brain stem. Involved regions demonstrate neuronal degeneration, characteristic spongiform or microcystic degeneration, and – as seen in Leigh syndrome – gliosis, necrosis, and capillary proliferation. The cortical ribbon shows patchy lesions, but the calcarine cortex, which is characteristically involved early in the course of the disease, is usually narrowed, granular, and discolored.
Microscopic abnormalities throughout the cerebral cortex evolve as the disease progresses. Early in the course of the disease, spongiosis, astrocytosis, and neuronal loss are prevalent in the superficial cortex. Later, the deeper laminae are affected. In the most advanced stages, the entire cortex becomes a thin dense gliotic scar. Usually, the striate cortex is the most affected part of the brain, followed by the thalamus, hippocampus, and cerebellum. These pathologic features differ from those resulting from hypoxic injury, recurrent seizures, or other causes of hepatic failure.
Liver. Liver histology may demonstrate macro- and microvesicular steatosis, centrilobular necrosis, disorganization of the normal lobular architecture, hepatocyte loss with or without bridging fibrosis or cirrhosis, regenerative nodules, bile duct proliferation, or mitochondrial proliferation with a vivid eosinophilic cytoplasm. Florid cirrhosis occurs late in the disease. This pathology differs from that seen in chemically induced or toxic hepatopathies.

Childhood Myocerebrohepatopathy Spectrum (MCHS)

MCHS presents between the first few months of life through age three years. In one study, it presented at a median age of 4.7 months (range: 0.9-7 months) with developmental delay or dementia, lactic acidosis, myopathy/hypotonia, and failure to thrive.

Other features that may be present include liver failure, renal tubular acidosis, pancreatitis, cyclic vomiting, and hearing loss. Seizures occur in about 75% of affected individuals. This is an ultimately fatal illness with a median age of death in one study of 15.8 months (range: 1.0-184.6 months). Major causes of death include liver failure, sepsis, and status epilepticus [Wong et al 2008, Hikmat et a 2017b, Rahman & Copeland 2019].

Juvenile/Adult-Onset Disease (Age 12-40 Years)

Typical features of juvenile/adult-onset POLG-related disorders (age 12-40 years) include peripheral neuropathy, ataxia, seizures, stroke-like episodes, and, in individuals with longer survival, progressive external ophthalmoplegia (PEO). Prognosis is usually better than in the early-onset group. Phenotypes that typically occur include myoclonic epilepsy myopathy sensory ataxia and ataxia neuropathy spectrum.

Myoclonic Epilepsy Myopathy Sensory Ataxia (MEMSA)

Previously referred to as spinocerebellar ataxia with epilepsy (SCAE), MEMSA describes the spectrum of disorders presenting with myopathy, epilepsy, and ataxia without ophthalmoplegia. Cerebellar ataxia, generally the first sign, begins in young adulthood as a subclinical sensory polyneuropathy. Epilepsy develops in later years, often beginning focally and then spreading to become generalized. As in other POLG-related phenotypes, seizures may be refractory to medical therapy. Recurrent seizures are accompanied by progressive interictal encephalopathy. The myopathy in MEMSA may be distal or proximal, and, as in other POLG-related disorders, it may also present as exercise intolerance.

Ataxia Neuropathy Spectrum (ANS)

ANS includes mitochondrial recessive ataxia syndrome (MIRAS) and a separate entity known as sensory ataxia neuropathy dysarthria and ophthalmoplegia (SANDO) [Fadic et al 1997]. ANS is characterized by ataxia, neuropathy, and (in most but not all affected individuals) encephalopathy with seizures. The encephalopathy is similar to that seen in AHS but tends to be more slowly progressive and can even be mild. The neuropathy may be sensory, motor, or mixed and can be severe enough to contribute to ataxia – so-called sensory ataxia. About 25% of affected individuals have cramps, but clinical myopathy is less common and, if present, is not the main component of issues pertaining to gait dysfunction or balance difficulties.

Other features include myoclonus, blindness, and liver dysfunction [Wong et al 2008]. Liver findings range from no dysfunction, to elevated enzymes and mild synthetic dysfunction, to florid liver failure in some cases [Tzoulis et al 2006, Wong et al 2008]. Psychiatric illness including depression is common. Headaches, generally migraines, are also common and may precede other symptoms by many years.

Although muscle pathology may show COX-negative fibers, there may be no pathologic findings.

Late-Onset Disease (Age >40 Years)

Typical features of late-onset POLG-related disorders (age >40 years) include ptosis and PEO, with additional features such as peripheral neuropathy ataxia and muscle weakness. Prognosis is usually the best of the three age-related groups. Phenotypes that typically occur include autosomal recessive PEO and autosomal dominant PEO.

Autosomal Recessive Progressive External Ophthalmoplegia (arPEO)

Progressive PEO without systemic involvement is the hallmark of arPEO. Caution needs to be exercised, however, when making the diagnosis of arPEO, as some POLG pathogenic variants associated with arPEO are also associated with ANS and other POLG-related disorders with systemic involvement. Thus, many individuals who have no other clinical findings at the time of diagnosis with isolated arPEO develop other manifestations of POLG-related disorders over subsequent years or decades [Van Goethem et al 2001, Lamantea et al 2002, Van Goethem et al 2003b].

Autosomal Dominant Progressive External Ophthalmoplegia (adPEO)

The universal manifestation of this adult-onset disorder is progressive weakness of the extraocular eye muscles resulting in ptosis and strabismus [Van Goethem et al 2001]. A generalized myopathy is present in most affected individuals, leading to early fatigue and exercise intolerance. Some affected individuals have variable degrees of sensorineural hearing loss, axonal neuropathy, ataxia, depression, parkinsonism, hypogonadism, and cataracts [Luoma et al 2004, Pagnamenta et al 2006]. Cardiomyopathy and gastrointestinal dysmotility are less common.

Rare Phenotypes

POLG pathogenic variants have been shown to be associated with Charcot-Marie-Tooth neuropathy type 2 [Harrower et al 2008, Phillips et al 2019], Leigh syndrome [Naess et al 2009, Taanman et al 2009], and a MNGIE-like illness [Tang et al 2012].

Genotype-Phenotype Correlations

No genotype-phenotype correlations have been identified.

Nomenclature

In a study of 155 individuals with POLG-related disorders in which the age of onset of features was analyzed by median age rather than age range, Hikmat et al [2020] observed that age of onset broadly correlates with clinical phenotype (see GeneReview Scope) and prognosis. Based on this observation, Hikmat et al [2020] proposed the following system of classification that differs from the classic descriptions of POLG-related phenotypes and provides alternate nomenclature:

Early-onset disease refers to individuals with onset prior to age 12 years. This classification encompasses Alpers-Huttenlocher syndrome (AHS) and childhood myocerebrohepatopathy spectrum (MCHS) and is associated with the worst prognosis.
Juvenile/adult-onset disease refers to individuals with onset at age 12-40 years. This classification encompasses myoclonic epilepsy myopathy sensory ataxia (MEMSA) / spinocerebellar ataxia with epilepsy (SCAE) and ataxia neuropathy spectrum (ANS) and generally has a better prognosis than the early-onset disease group.
Late-onset disease refers to individuals with onset after age 40 years. This classification encompasses autosomal recessive progressive external ophthalmoplegia (arPEO), autosomal dominant progressive external ophthalmoplegia (adPEO), and progressive external ophthalmoplegia plus (PEO-plus) and has the best prognosis overall.

Prevalence

AHS is reported to affect approximately 1:51,000 people [Darin et al 2001].

The combined frequency of the most common autosomal recessive pathogenic variants in POLG can be used to estimate disease frequency at 1:10,000. Common POLG variants include those in Table 3.

Table 3.

Frequency of the Most Common POLG Pathogenic Variants

POLG Pathogenic Variant	Prevalence	Reference
p.Ala467Thr	0.6% (Belgian)	Van Goethem et al [2001]
	0.17%-0.69% (European)	Horvath et al [2006]
	0.69% (United Kingdom)	Craig et al [2007]
	0% (Italian)	Craig et al [2007]
p.Trp748Ser	0.8% (Finnish)	Hakonen et al [2005]
p.Trp748Ser	0% (Italian)	Craig et al [2007]
p.Gly848Ser	0.016% (likely European)	Hakonen et al [2007], Nurminen et al [2017]
p.[Thr251Ile;Pro587Leu] ¹	1% (Italian)	Ferrari et al [2005], Scuderi et al [2015]

: Based on Rahman & Copeland [2019]; see also Table 8
1.: Indicates two different pathogenic variants in cis (see varnomen.hgvs.org)

Pathogenic variants in POLG, identified in nearly 50% of individuals with adPEO in one study [Lamantea et al 2002], may be the most frequent cause of adPEO.

Genetically Related (Allelic) Disorders

To date, no phenotypes other than those discussed in this GeneReview are known to be associated with germline pathogenic variants in POLG.

Differential Diagnosis

Table 4.

Genes of Interest in the Differential Diagnosis of POLG-Related Disorders

Gene(s) ¹ / Genetic Mechanism	Disorder	MOI	Comment
ALDH7A1	Pyridoxine-dependent epilepsy – ALDH7A1 (pyridoxine-dependent epilepsy)	AR	Neonatal-onset progressive encephalopathy w/refractory seizures Targeted therapy: seizures are not well controlled w/ASMs but respond to large daily supplements of pyridoxine (vitamin B₆).
AMT GLDC	Nonketotic hyperglycinemia (NKH)	AR	Epilepsia partialis continua has been described in some affected persons. ²
ATP7A	Menkes disease (See ATP7A-Related Copper Transport Disorders.)	XL	Neonatal-onset progressive encephalopathy w/refractory seizures Usually present earlier in infancy than AHS
BCS1L	BCS1L-related disorders (incl GRACILE syndrome [OMIM 603358], Bjørnstad syndrome [OMIM 262000], & GRACILE syndrome-Bjørnstad syndrome overlap phenotype]	AR	The clinical scenario of a hepatoencephalopathy may appear similar to AHS at a single point in time, but mtDNA depletion is not part of the pathology described in those w/BCS1L pathogenic variants.
BTD	Biotinidase deficiency	AR	Neonatal-onset progressive encephalopathy w/refractory seizures Targeted therapy: Oral biotin. Compliance w/biotin therapy can prevent development of disease & also improves symptoms in symptomatic persons.
CACNA1A	CACNA1A-related early infantile epileptic encephalopathy (OMIM 617106)	AD	Severe infantile epileptic disorder that appears progressive at onset but usually plateaus into developmental arrest/delay
CACNB4	Idiopathic generalized epilepsy & myoclonic epilepsy (OMIM 607682) & episodic ataxia type 5 (OMIM 613855)	AD	Early-onset epileptic disorder that is often assoc w/myoclonic, generalized tonic-clonic, or absence seizures w/photosensitivity reported in some persons ³
CERS1 CSTB EPM2A GOSR2 KCNC1 KCTD7 LMNB2 NHLRC1 PRDM8 PRICKLE1 SCARB2 SEMA6B SLC7A6OS	Myoclonic epilepsy (OMIM PS254800)	AR AD	Can cause dementia or pseudodementia because of unrelenting seizures & anticonvulsant side effects
CLN5 CLN6 CLN8 PPT1 TPP1	CLN1 disease & CLN2 disease (neuronal ceroid lipofuscinoses [NCLs]) (OMIM PS256730)	AR	Phenotypes incl in NCLs that overlap w/AHS are CLN1 disease, classic infantile (previously classic infantile NCL, INCL, Santavuori-Haltia) & CLN2 disease, classic late infantile (previously late-infantile NCL, LINCL, Jansky-Bielschowsky disease)
COQ8A	COQ8A-related primary coenzyme Q₁₀ (CoQ₁₀) deficiency	AR	Epilepsia partialis continua has been described in some affected persons. ⁴ Targeted therapy: Persons w/primary CoQ₁₀ deficiency may respond well to high-dose oral CoQ₁₀ supplementation.
CTSA	Galactosialidosis (OMIM 256540)	AR	During infancy & early childhood, storage diseases can be assoc w/progressive encephalopathy w/primary involvement of cortical gray matter & refractory epilepsy.
DGUOK	Deoxyguanosine kinase deficiency (DGUOK deficiency)	AR	In contrast to POLG-related AHS, DGUOK deficiency is not characterized by seizures or brain imaging abnormalities.
DNA2	DNA2-related mtDNA maintenance defect	AD	PEO & PEO w/systemic involvement ⁵
FBXL4	FBXL4-related encephalomyopathic mtDNA depletion syndrome	AR	Early infantile encephalopathy, hypotonia, lactic acidosis, & mtDNA depletion ⁶
FOLR1	FOLR1-related cerebral folate transport deficiency	AR	Neonatal-onset progressive encephalopathy w/refractory seizures Targeted therapy: Oral administration of 5-formylTHF is usually sufficient to bring CSF folate levels into normal range for age.
HEXA	Hexosaminidase A deficiency	AR	During infancy & early childhood, storage diseases can be assoc w/progressive encephalopathy w/primary involvement of cortical gray matter & refractory epilepsy.
HEXB	Sandhoff disease	AR
MGME1	MGME1-related mtDNA maintenance defect	AR	Multisystemic mitochondrial phenotype w/PEO, emaciation, & respiratory failure
MPV17	MPV17-related mtDNA maintenance defect	AR	Multisystemic mitochondrial disease w/liver dysfunction, brain & peripheral nerve disease, gastrointestinal dysmotility, & lactic acidosis
MT-TK ⁷	MERFF ⁸	See footnote 9.	Multisystemic mitochondrial disorder characterized by myoclonus (often 1st symptom) followed by generalized epilepsy, ataxia, weakness, exercise intolerance, & dementia Onset can occur from childhood to adulthood, following normal early development Common findings are ptosis, hearing loss, short stature, optic atrophy, cardiomyopathy, cardiac dysrhythmias, & peripheral neuropathy
MT-TL1 ¹⁰	MELAS ^8, 11	See footnote 12.	Multisystemic mitochondrial disorder w/onset typically occurring in childhood Onset of symptoms is often ages 2-10 yrs. Most common initial symptoms are generalized tonic-clonic seizures, recurrent headaches, anorexia, & recurrent vomiting. Seizures are often assoc w/stroke-like episodes of transient hemiparesis or cortical blindness. The cumulative residual effects of the stroke-like episodes gradually impair motor abilities, vision, & mentation by adolescence or young adulthood. Sensorineural hearing loss is common.
NDUFS4	NADH coenzyme Q reductase deficiency (OMIM 252010)	AR	Epilepsia partialis continua has been described in some affected persons. ¹³
NEU1	Infantile sialidosis (OMIM 256550)	AR	During infancy & early childhood, storage diseases can be assoc w/progressive encephalopathy w/primary involvement of cortical gray matter & refractory epilepsy.
OPA1	Optic atrophy type 1 (OMIM 165500)	AD	Childhood-onset visual loss
PABPN1	Oculopharyngeal muscular dystrophy	AD	Progressive adult-onset myopathy w/ ptosis, dysphagia, & proximal weakness
PLPBP	PLPBP deficiency (pyridoxine-dependent epilepsy)	AR	Neonatal-onset progressive encephalopathy w/refractory seizures Targeted therapy: Pyridoxine is the first-line therapy. Most individuals have a favorable response to pyridoxine.
PNPO	PNPO deficiency (pyridoxine-dependent epilepsy)	AR	Neonatal-onset progressive encephalopathy w/refractory seizures Targeted therapy: ~60% of persons are resistant to pyridoxine & require treatment with pyridoxal 5'-phosphate; ~40% respond to pyridoxine alone.
POLG2	POLG2-related mtDNA maintenance defect	AD	Adult-onset PEO & multisystemic mitochondrial disease w/mtDNA depletion
RNASEH1	RNASEH1-related mtDNA maintenance defect	AR	PEO & multisystemic mitochondrial disease w/mtDNA depletion
RRM2B	RRM2B mtDNA maintenance defects	AR AD	Neonatal-onset hypotonia, lactic acidosis, & neurologic deterioration, w/ or w/o renal tubular dysfunction Adult-onset PEO, variable gastrointestinal dysmotility, multisystemic mitochondrial disease
SCN1A	SCN1A seizure disorders	AD	At the severe end of the spectrum, severe infantile epileptic disorder that appears progressive at onset but usually plateaus into developmental arrest/delay
SCN2A	SCN2A-related early infantile epileptic encephalopathy (OMIM 613721)	AD	Severe infantile epileptic disorder that appears progressive at onset but usually plateaus into developmental arrest/delay
SCO1	SCO1-related disorders (OMIM 603644)	AR	Infantile-onset multisystemic mitochondrial disease, Leigh-like syndrome w/cardiac hypertrophy & failure
SLC25A19	SLC25A19-related thiamine metabolism dysfunction (incl Amish lethal microcephaly & thiamine metabolism dysfunction syndrome 4)	AR	Targeted therapy: Oral thiamine treatment is critical from the time of diagnosis. This treatment is lifelong. It prevents metabolic decompensation & improves outcomes.
SLC25A4	SLC25A4-related mtDNA maintenance defect	AR	Primary presenting features are myopathy, hypertrophic cardiomyopathy, & ophthalmoplegia.
SLC46A1	Hereditary folate malabsorption	AR	Neonatal-onset progressive encephalopathy w/refractory seizures Targeted therapy: Early treatment w/oral 5-formylTHF or, preferably, the active isomer of 5-formylTHF (Isovorin^® or Fusilev^®) readily corrects the systemic folate deficiency &, if the dose is sufficient, can achieve CSF folate levels that prevent or mitigate the neurologic consequences of hereditary folate malabsorption.
SUCLA2	SUCLA2-related mtDNA depletion syndrome, encephalomyopathic form w/methylmalonic aciduria	AR	Infantile encephalomyopathy, methylmalonic aciduria, epilepsy, hepatopathy, & cardiomyopathy
SUCLG1	SUCLG1-related mtDNA depletion syndrome, encephalomyopathic form w/methylmalonic aciduria ¹⁴	AR
SUOX	Isolated sulfite oxidase deficiency	AR	Neonatal-onset progressive encephalopathy w/refractory seizures Usually present earlier in infancy than AHS
TBC1D24	TBC1D24-related disorders	AR ¹⁵	Epilepsia partialis continua has been described in some affected persons. ²
TK2	TK2-related mtDNA maintenance defect, myopathic form	AR	At the severe end of the spectrum, infantile-onset myopathy w/neurologic involvement & rapid progression to early death
TWNK	Autosomal dominant PEO, infantile-onset spinocerebellar ataxia, Perrault syndrome, & TWNK-related mtDNA maintenance defect ¹⁶	AR AD	Digenic inheritance of PEO has been reported in 2 persons w/double heterozygosity for a POLG pathogenic variant & a TWNK pathogenic variant. ¹⁷
TYMP	Mitochondrial neurogastrointestinal encephalopathy	AR	Cachexia, gastrointestinal dysmotility, peripheral neuropathy, PEO, leukoencephalopathy ¹⁸
Single large-scale mitochondrial DNA deletion ranging in size from 1.1 to 10 kb	Chronic progressive external ophthalmoplegia (CPEO) & Kearns-Sayre syndrome (KSS) (See Single Large-Scale Mitochondrial DNA Deletion Syndromes.)	See footnote 19.	CPEO in a simplex case or when there is a maternal family history can be the result of a large-scale single deletion of mtDNA that may only be detected in limited tissues (e.g., skeletal muscle). CPEO is sometimes complicated by mild proximal muscle weakness & dysphagia & can be considered to lie on a spectrum of disease from pure CPEO to KSS. ²⁰ A multisystemic disorder defined by the triad of onset age <20 years, pigmentary retinopathy, & PEO. In addition, persons have ≥1 of the following: cardiac conduction block, CSF protein concentration >100 mg/dL, or cerebellar ataxia. Onset is usually in childhood. PEO, characterized by ptosis, paralysis of the extraocular muscles (ophthalmoplegia), & variably severe proximal limb weakness, is relatively benign. ²¹

: 5-formytetrahydrofolate = 5-formylTHF; AD = autosomal dominant; AHS = Alpers-Huttenlocher syndrome; AR = autosomal recessive; ASM = anti-seizure medication; CSF = cerebrospinal fluid; GRACILE syndrome = growth restriction, aminoaciduria, cholestasis, iron overload, lactic acidosis, and early death syndrome; MOI = mode of inheritance; PEO = progressive external ophthalmoplegia; XL = X-linked
1.: Genes are ordered alphabetically.
2.: Mameniškienė & Wolf [2017]
3.: Amadori et al [2022]
4.: Hikmat et al [2016]
5.: Ronchi et al [2013]
6.: Gai et al [2013]
7.: The m.8344A>G pathogenic variant in the mitochondrial gene MT-TK is present in more than 80% of affected individuals with typical findings. Pathogenic variants in MT-TF, MT-TH, MT-TI, MT-TL1, MT-TP, MT-TS1, and MT-TS2 have also been described in a subset of individuals with MERRF.
8.: Evidence to date suggests that diabetes and cardiomyopathy are not common in POLG-related disorders, distinguishing POLG-related disorders from other multisystemic mitochondrial diseases.
9.: MERRF is caused by pathogenic variants in mtDNA and is transmitted by maternal inheritance.
10.: The m.3243A>G pathogenic variant in the mitochondrial gene MT-TL1 is present in approximately 80% of individuals with MELAS. Pathogenic variants in MT-TL1 or other mtDNA genes, particularly MT-ND5, can also cause this disorder
11.: Hirano et al [1992]
12.: MELAS is caused by pathogenic variants in mtDNA and is transmitted by maternal inheritance.
13.: Antozzi et al [1995]
14.: Molaei Ramsheh et al [2020]
15.: Most TBC1D24-related disorders are inherited in an autosomal recessive manner.
16.: Peter & Falkenberg [2020]
17.: Van Goethem et al [2003a], Da Pozzo et al [2015]
18.: Pacitti et al [2018]
19.: SLSMDSs are almost never inherited, suggesting that these disorders are typically caused by a de novo single large-scale mitochondrial DNA deletion (SLSMD) that occurs in the mother's oocytes during germline development or in the embryo during embryogenesis.
20.: Some individuals with CPEO (<20%) have a pathogenic single-nucleotide variant of mtDNA (e.g., m.3243A>G).
21.: Most individuals with KSS have a common deletion of 4,977 nucleotides involving 12 mitochondrial genes.

Other Disorders to Consider

Leigh syndrome is a progressive neurodegenerative disorder characterized by hypotonia, spasticity, dystonia, muscle weakness, hypo- or hyperreflexia, seizures, movement disorders, cerebellar ataxia, and peripheral neuropathy. In individuals with Leigh syndrome, MRI changes most often occur initially in the brain stem, and the gliosis "migrates" over time to involve the deep gray masses and cortex, whereas in AHS the initial lesions form in the cerebral cortex (usually the occipital lobes), followed by the cerebellum, basal ganglia, thalamus, and brain stem. Epilepsia partialis continua (EPC), seen in Alpers-Huttenlocher syndrome (AHS), has been described in individuals with Leigh syndrome [Mameniškienė & Wolf 2017]. Most individuals with Leigh syndrome have an autosomal recessive or X-linked disorder of mitochondrial energy generation (see Nuclear Gene-Encoded Leigh Syndrome Spectrum Overview); Leigh syndrome can also be caused by genetic alternations in mitochondrial DNA (see Mitochondrial DNA-Associated Leigh Syndrome and NARP and Single Large-Scale Mitochondrial DNA Deletion Syndromes).

For additional disorders to consider in the differential diagnosis of individuals presenting with ataxia, see Hereditary Ataxia Overview.

For additional disorders to consider in the differential diagnosis of individuals presenting with peripheral neuropathy, see Charcot-Marie-Tooth Hereditary Neuropathy Overview.

Management

No clinical practice guidelines for POLG-related disorders have been published, although consensus statement guidelines for primary mitochondrial diseases are available [Parikh et al 2017].

Evaluations Following Initial Diagnosis

To establish the extent of disease and needs in an individual diagnosed with POLG-related disorder, the evaluations summarized in Table 5 (if not performed as part of the evaluation that led to diagnosis) are recommended. Evaluation should always include measures of functional neurologic status.

Table 5.

POLG-Related Disorders: Recommended Evaluations Following Initial Diagnosis

System	Evaluation	Comment
Neurologic	Neurologic eval	To incl brain MRI ¹ Consider EEG & video EEG if seizures are a concern.
Ataxia	Orthopedics / physical medicine & rehab / PT & OT eval	To incl assessment of: Gross motor & fine motor skills Mobility, ADL, & need for adaptive devices Need for PT (to improve gross motor skills) &/or OT (to improve fine motor skills)
Development	Developmental assessment	To incl motor, adaptive, cognitive, & speech-language eval Eval for early intervention / special education, need for speech therapy
Neurobehavioral/ Psychiatric	Neuropsychiatric eval	For persons age >12 mos: screening for concerns incl sleep disturbances, ADHD, anxiety, &/or findings suggestive of ASD. Formal neuropsychological eval can be considered for those w/any concerns identified on screening.
Neurobehavioral/ Psychiatric	Depression screen	Assess for mood disturbances.
Musculoskeletal	Orthopedics / physical medicine & rehab / PT & OT eval	To incl assessment of: Gross motor & fine motor skills Contractures, clubfoot, & kyphoscoliosis Mobility, ADL, & need for adaptive devices Need for PT (to improve gross motor skills) &/or OT (to improve fine motor skills) Consideration of exercise program
Gastrointestinal/ Feeding	Gastroenterology / nutrition / feeding team eval	To incl liver function tests incl ALT & AST; serum concentrations of ammonia, glutamine & tyrosine, bilirubin, albumin, & cholesterol; fasting blood glucose levels; & coagulation factors (prothrombin time or INR) ² Consideration of liver ultrasound to evaluate for liver fibrosis To incl eval of aspiration risk incl swallow study for bulbar symptoms & nutritional status Consider eval for gastrostomy tube placement in persons w/dysphagia &/or aspiration risk.
Eyes	Ophthalmologic eval	To assess for reduced vision, abnormal ocular movement, best corrected visual acuity, refractive errors, strabismus, & more complex findings (e.g., cataract, retinal dystrophy) that may require referral for subspecialty care &/or low vision services
Hearing	Audiologic eval	Assess for hearing loss.
ENT/Mouth	ENT eval	A sleep study is recommended to evaluate for central or obstructive apnea or hypopnea that results in either pCO₂ elevation or O₂ desaturation.
Cardiovascular	Cardiac eval	To incl echocardiogram & electrocardiogram
Respiratory	Pulmonary eval	To incl baseline pulmonary function testing
Endocrine	Screen for pancreatic, thyroid, & adrenal function.	Consider if clinically indicated & in critical illness. ³
Pregnancy	High-risk obstetrical care	To incl discussion between managing physicians
Genetic counseling	By genetics professionals ⁴	To inform affected persons & their families re nature, MOI, & implications of POLG-related disorders to facilitate medical & personal decision making
Family support & resources	By clinicians, wider care team, & family support organizations	Assessment of family & social structure to determine need for: Community or online resources such as Parent to Parent Social work involvement for parental support Home nursing referral

: ADHD = attention-deficit/hyperactivity disorder; ADL = activities of daily living; ALT = alanine transaminase; ASD = autism spectrum disorder; AST = aspartate aminotransferase; INR = international normalized ratio; MOI = mode of inheritance; OT = occupational therapy; pCO₂: partial pressure of carbon dioxide; PT = physical therapy
1.: In some instances, the first neuroimaging study may be normal, but with certain phenotypes, such as Alpers-Huttenlocher syndrome, changes may be seen in a relatively short amount of time.
2.: AST elevation, and to a lesser extent ALT elevation, may be due to muscle disease. Therefore, simultaneously obtaining a serum CK level helps differentiate between liver & muscle involvement, which can both be seen in individuals with POLG-related disorders.
3.: Parikh et al [2017]
4.: Medical geneticist, certified genetic counselor, certified advanced genetic nurse

Treatment of Manifestations

There is no cure for POLG-related disorders. Supportive care to improve quality of life, maximize function, and reduce complications is recommended. This ideally involves multidisciplinary care by specialists in relevant fields (see Table 6).

Table 6.

POLG-related disorders: Treatment of Manifestations

Manifestation/Concern	Treatment	Considerations/Other
Developmental delay / Intellectual disability / Neurobehavioral issues	See Developmental Delay / Intellectual Disability Management Issues.	OT, PT, & ST are indicated in AHS to maintain or improve neurologic function for as long as possible & for comfort care.
Epilepsy	Standardized treatment w/ASM by experienced neurologist	Many ASMs may be effective; none has been demonstrated effective specifically for this disorder. Note: Valproic acid (Depakene^®) & sodium divalproate (divalproex) (Depakote^®) should be avoided (see Agents/Circumstances to Avoid). Because other ASMs may also accelerate liver deterioration, it is reasonable to monitor liver enzymes every 2-4 weeks after introducing any new ASM. Treatment of epilepsy is similar to non-mitochondrial disease w/seizures. Lamotrigine may worsen myoclonic seizures. ¹ Vigabatrin may need to be avoided in persons w/mtDNA depletion because it inhibits conversion of deoxyribonucleoside diphosphate to deoxyribonucleoside triphosphate in the mitochondrial nucleoside salvage pathway & may worsen mtDNA depletion. ² Topiramate may worsen acidosis. ³ Refractory epilepsy, esp EPC, may be impossible to control w/any treatment. In persons w/EPC, use of high-dose ASM may control the clinical seizures, but assoc obtundation & subsequent risk of aspiration & ventilatory failure may outweigh the benefit. Education of parents/caregivers ⁴
Movement disorders	Standard treatment by an experienced neurologist	Myoclonus & other non-epileptic movement disorders occur as part of AHS. The use of benzodiazepines often ↓ severity of abnormal movements & also assists in seizure control & reduction of spasticity. Chorea & athetosis may cause pain, & treatment w/muscle relaxants & pain medications, incl narcotics, is advised. Some movement disorders can be treated w/dopaminergic medication such as levodopa-carbidopa or tetrabenazine; a trial of either of these medications can be considered. ⁵
Spasticity	Orthopedics / physical medicine & rehab / PT & OT incl stretching to help avoid contractures & falls	Consider need for positioning & mobility devices, disability parking placard. Botulinum toxin can be used w/caution (w/consideration of systemic effects). ⁶
Inadequate weight gain & linear growth (children) or unexplained weight loss (all ages)	Feeding therapy Gastrostomy tube placement may be required for persistent feeding issues.	Low threshold for renal eval in persons w/inadequate weight gain & linear growth or unexplained weight loss A feeding eval &/or radiographic swallowing study should be considered when showing clinical signs or symptoms of dysphagia.
GI & bowel dysfunction	Standard treatment by GI specialist for feeding or nutritional issues	Placement of a gastric feeding tube when appropriate can maintain nutritional status &/or prevent aspiration.
GI & bowel dysfunction	Monitor for constipation.	Stool softeners, prokinetics, osmotic agents, or laxatives as needed
Liver failure	Standard treatment	Treatment may incl small, frequent meals or continuous feeding to compensate for defective gluconeogenesis; reduction in dietary protein; use of non-absorbable sugars to create an osmotic diarrhea; & use of conjugating agents to treat hyperammonemia. Levocarnitine may have some benefit in the setting of liver failure & has a low risk, yet there is no evidence for routine use.
Eyes	Standardized treatment by ophthalmologist	For refractive errors, strabismus, & more complex findings (e.g., cataract, retinal dystrophy)
	Ptosis	Surgery for ptosis may provide symptomatic relief for some persons.
	Low vision services	Children: through early intervention programs &/or school district Adults: low vision clinic &/or community vision services / OT / mobility services
Cerebral visual impairment	No specific treatment	Consideration of referral to a low vision clinic
Hearing	Hearing aids may be helpful per otolaryngologist	Community hearing services through early intervention or school district
Respiratory	Standard treatment by pulmonologist for respiratory issues	Tracheostomy placement & artificial ventilation may be performed as needed. Assessment of nocturnal ventilatory function can be performed for evidence of central &/or obstructive apnea using polysomnography w/measurement of pCO₂ & monitoring by pulse oximetry. Treatment w/CPAP, BiPAP, or more invasive ventilatory therapy as indicated.
Family/Community	Ensure appropriate social work involvement to connect families w/local resources, respite, & support. Coordinate care to manage multiple subspecialty appointments, equipment, medications, & supplies.	Ongoing assessment of need for palliative care involvement &/or home nursing (esp for persons w/AHS) Consider involvement in adaptive sports or Special Olympics.

: AHS = Alpers-Huttenlocher syndrome; ASM = anti-seizure medication; BiPAP = bilevel positive airway pressure; CPAP = continuous positive airway pressure; EPC = epilepsia partialis continua; OT = occupational therapy; PT = physical therapy; ST = speech therapy
1.: Hikmat et al [2017a]
2.: Besse et al [2015]
3.: Mirza et al [2011]
4.: Education of parents/caregivers regarding common seizure presentations is appropriate. For information on non-medical interventions and coping strategies for children diagnosed with epilepsy, see Epilepsy Foundation Toolbox.
5.: Hakonen et al [2005]
6.: Parikh et al [2017]

Developmental Delay / Intellectual Disability Management Issues

The following information represents typical management recommendations for individuals with developmental delay / intellectual disability in the United States; standard recommendations may vary from country to country.

Ages 0-3 years. Referral to an early intervention program is recommended for access to occupational, physical, speech, and feeding therapy as well as infant mental health services, special educators, and sensory impairment specialists. In the US, early intervention is a federally funded program available in all states that provides in-home services to target individual therapy needs.

Ages 3-5 years. In the US, developmental preschool through the local public school district is recommended. Before placement, an evaluation is made to determine needed services and therapies and an individualized education plan (IEP) is developed for those who qualify based on established motor, language, social, or cognitive delay. The early intervention program typically assists with this transition. Developmental preschool is center based; for children too medically unstable to attend, home-based services are provided.

All ages. Consultation with a developmental pediatrician is recommended to ensure the involvement of appropriate community, state, and educational agencies (US) and to support parents in maximizing quality of life. Some issues to consider:

IEP services:
- An IEP provides specially designed instruction and related services to children who qualify.
- IEP services will be reviewed annually to determine whether any changes are needed.
- Special education law requires that children participating in an IEP be in the least restrictive environment feasible at school and included in general education as much as possible, when and where appropriate.
- Vision and hearing consultants should be a part of the child's IEP team to support access to academic material.
- PT, OT, and speech services will be provided in the IEP to the extent that the need affects the child's access to academic material. Beyond that, private supportive therapies based on the affected individual's needs may be considered. Specific recommendations regarding type of therapy can be made by a developmental pediatrician.
- As a child enters the teen years, a transition plan should be discussed and incorporated in the IEP. For those receiving IEP services, the public school district is required to provide services until age 21.
A 504 plan (Section 504: a US federal statute that prohibits discrimination based on disability) can be considered for those who require accommodations or modifications such as front-of-class seating, assistive technology devices, classroom scribes, extra time between classes, modified assignments, and enlarged text.
Developmental Disabilities Administration (DDA) enrollment is recommended. DDA is a US public agency that provides services and support to qualified individuals. Eligibility differs by state but is typically determined by diagnosis and/or associated cognitive/adaptive disabilities.
Families with limited income and resources may also qualify for supplemental security income (SSI) for their child with a disability.

Motor Dysfunction

Gross motor dysfunction

Physical therapy is recommended to maximize mobility and to reduce the risk for later-onset orthopedic complications (e.g., contractures, scoliosis, hip dislocation).
Consider use of durable medical equipment and positioning devices as needed (e.g., wheelchairs, walkers, bath chairs, orthotics, adaptive strollers).
For muscle tone abnormalities including hypertonia or dystonia, consider involving appropriate specialists to aid in management of baclofen, tizanidine, Botox^®, anti-parkinsonian medications, or orthopedic procedures.

Fine motor dysfunction. Occupational therapy is recommended for difficulty with fine motor skills that affect adaptive function such as feeding, grooming, dressing, and writing.

Oral motor dysfunction should be assessed at each visit and clinical feeding evaluations and/or radiographic swallowing studies should be obtained for choking/gagging during feeds, poor weight gain, frequent respiratory illnesses, or feeding refusal that is not otherwise explained. Assuming that the child is safe to eat by mouth, feeding therapy (typically from an occupational or speech therapist) is recommended to help improve coordination or sensory-related feeding issues. Feeds can be thickened or chilled for safety. When feeding dysfunction is severe, an NG-tube or G-tube may be necessary.

Communication issues. Consider evaluation for alternative means of communication (e.g., augmentative and alternative communication [AAC]) for individuals who have expressive language difficulties. An AAC evaluation can be completed by a speech-language pathologist who has expertise in the area. The evaluation will consider cognitive abilities and sensory impairments to determine the most appropriate form of communication. AAC devices can range from low-tech, such as picture exchange communication, to high-tech, such as voice-generating devices. Contrary to popular belief, AAC devices do not hinder verbal development of speech, but rather support optimal speech and language development.

Neurobehavioral/Psychiatric Concerns

Children may qualify for and benefit from interventions used in treatment of autism spectrum disorder, including applied behavior analysis (ABA). ABA therapy is targeted to the individual child's behavioral, social, and adaptive strengths and weaknesses and typically performed one on one with a board-certified behavior analyst.

Consultation with a developmental pediatrician may be helpful in guiding parents through appropriate behavior management strategies or providing prescription medications, such as medication used to treat attention-deficit/hyperactivity disorder, when necessary.

Concerns about serious aggressive or destructive behavior can be addressed by a pediatric psychiatrist.

Surveillance

To monitor existing manifestations, the individual's response to supportive care, and the emergence of new manifestations, evaluations by a multidisciplinary team including neurologist, biochemical geneticist, hepatologist or gastroenterologist, physiatrist, psychiatrist, neuropsychologist and/or psychologist, ophthalmologist, and pulmonologist are recommended. No standard-of-care guidelines regarding the recommended frequency of evaluations exist; surveillance should be guided by clinical features, and the schedule should be modified if the clinical course is stable. For those with the most severe phenotypes, the recommendations in Table 7 can be considered.

Table 7.

POLG-related disorders: Recommended Surveillance

System/Concern	Evaluation	Frequency
Neurologic	Monitor those w/seizures as clinically indicated. Assess for new manifestations such as seizures, changes in tone, & movement disorders. EEG & video EEG monitoring (e.g., for suspicion of subclinical status epilepticus or EPC, to determine if events are seizures or non-epileptic movements)	At each visit
Development	Monitor developmental progress & educational needs.
Neurobehavioral/ Psychiatric	Assessment for anxiety, ADHD, ASD, aggression, & depression
Musculoskeletal	Physical medicine, OT/PT assessment of mobility, self-help skills
Feeding	Measurement of growth parameters Eval of nutritional status & safety of oral intake
Liver function & metabolic status	Complete blood count Electrolytes Liver enzymes (AST, ALT, GGT) CK level Liver function tests incl preprandial serum glucose level; serum concentration of ammonia, albumin, bilirubin (free & conjugated), & cholesterol; coagulation factors incl prothrombin time or INR	Every 3 mos, or as clinically indicated
	Urine analysis Lactic acid levels Liver ultrasound	Annually or as clinically indicated
	Plasma amino acids Plasma concentration of free & total carnitine (unless treated w/levocarnitine, in which case measure annually)	Annually or as clinically indicated
Gastrointestinal	Monitor for swallowing dysfunction through barium swallow study, gastrointestinal paresis, constipation, feeding intolerance, or malabsorption.	At each visit or as clinically indicated
Respiratory	Monitor for evidence of aspiration & respiratory insufficiency.	At each visit
Respiratory	Polysomnogram w/CPAP titration as part of an eval of subacute mental status changes, apnea, or snoring	As clinically indicated or every 2-3 yrs
Auditory	Audiogram or brain stem auditory evoked responses	As clinically indicated
Ophthalmologic involvement	Routine ophthalmologic exam	Per treating ophthalmologist(s)
Ophthalmologic involvement	Low vision services	Per treating clinicians
Cardiovascular	Routine cardiac exam	At each visit
Endocrine	Laboratory testing for thyroid or adrenal dysfunction	Upon critical illness or as clinically indicated
Family/Community	Assess family need for social work support (e.g., palliative/respite care, home nursing, other local resources), care coordination, or follow-up genetic counseling if new questions arise (e.g., family planning).	At each visit

: ADHD = attention-deficit/hyperactivity disorder; ALT = alanine transaminase; ASD = autism spectrum disorder; AST = aspartate transaminase; CK = creatine kinase; EPC = epilepsia partialis continua; GGT = gamma-glutamyl transferase; INR = international normalized ratio; OT = occupational therapy; PT = physical therapy

Agents/Circumstances to Avoid

Valproic acid (Depakene^®) and sodium divalproate (divalproex) (Depakote^®) should be avoided because of the risk of precipitating and/or accelerating liver disease [Saneto et al 2010].

As with some other mitochondrial diseases, physical stressors such as infection, fever, dehydration, and anorexia can result in a sudden deterioration and should be avoided if possible.

Evaluation of Relatives at Risk

See Genetic Counseling for issues related to testing of at-risk relatives for genetic counseling purposes.

Therapies Under Investigation

Search ClinicalTrials.gov in the US and EU Clinical Trials Register in Europe for information on clinical studies for a wide range of diseases and conditions. Note: There may not be clinical trials for this disorder.

Other

Liver transplantation is not advised in children with Alpers-Huttenlocher syndrome (AHS) because transplanting the liver does not alter the rapid progression of the brain disease [Kelly 2000].

However, liver transplantation in adults who have an acceptable quality of life may be of benefit.

In one report, one of two individuals undergoing liver transplantation survived [Tzoulis et al 2006]. In another report of solid organ transplantation in primary mitochondrial disease, of six individuals with POLG-related disease, two survived without complications [Parikh et al 2016].
In another report, a woman underwent liver transplantation at age 19 years, eight years after experiencing fulminant hepatic failure following onset of valproate therapy. Molecular genetic testing seven years after her liver transplantation confirmed the diagnosis of a POLG-related disorder; her phenotype fit best with SANDO [Wong et al 2008, Parikh et al 2016].

The use of other treatments for refractory epilepsy, such as corticotropin or prednisone, ketogenic diet, and intravenous immunoglobulin G, are unproven in the treatment of AHS. The following, however, may be considered:

Vitamin and cofactor therapy with the intent to fortify mitochondrial function may be offered, yet there is insufficient evidence demonstrating objective benefit in cohorts of persons. There have not been formal studies of the use of these vitamins and cofactors in AHS or other POLG-related disorders [Parikh et al 2009, Parikh et al 2015, Camp et al 2016].
The use of folinic acid should be considered [Hasselmann et al 2010].
The use of levoarginine has been reported to be helpful in reducing the frequency and severity of the strokes associated with MELAS, and can be considered for use in persons with POLG-related disorders, especially if deficiency in the plasma or cerebrospinal fluid arginine concentration is confirmed [El-Hattab et al 2017].
The use of levocarnitine should be reserved for individuals with reduced free carnitine levels in the blood, and the levels should be monitored [Parikh et al 2015].
Creatine monohydrate, coenzyme Q₁₀, B vitamins, and antioxidants such as alpha-lipoic acid, vitamin E, and vitamin C have been used as mitochondrial supplements based on limited case reports and small series but with a lack of objective evidence based on randomized controlled trials. Use of all in POLG-related disorders is reasonable given the general lack of toxicity but is not mandatory [Gold & Cohen 2001, Rodriguez et al 2007, Horvath et al 2008, Parikh et al 2013, Parikh et al 2015].

Genetic Counseling

Genetic counseling is the process of providing individuals and families with information on the nature, mode(s) of inheritance, and implications of genetic disorders to help them make informed medical and personal decisions. The following section deals with genetic risk assessment and the use of family history and genetic testing to clarify genetic status for family members; it is not meant to address all personal, cultural, or ethical issues that may arise or to substitute for consultation with a genetics professional. —ED.

Mode of Inheritance

Early-onset and juvenile/adult-onset POLG-related disorders are typically caused by biallelic pathogenic variants and inherited in an autosomal recessive manner. Late-onset progressive external ophthalmoplegia (PEO) may be caused by a heterozygous POLG pathogenic variant and inherited in an autosomal dominant manner.

Note: Digenic inheritance involving pathogenic variants in POLG and TWNK has been reported in two individuals with PEO [Van Goethem et al 2003a, Da Pozzo et al 2015].

Autosomal Recessive Inheritance – Risk to Family Members

Parents of a proband

The parents of an affected child are presumed to be heterozygous for a POLG pathogenic variant.
Molecular genetic testing is recommended for the parents of a proband to confirm that both parents are heterozygous for a POLG pathogenic variant and to allow reliable recurrence risk assessment.
If a pathogenic variant is detected in only one parent and parental identity testing has confirmed biological maternity and paternity, it is possible that one of the pathogenic variants identified in the proband occurred as a de novo event in the proband [Chan et al 2009, Lutz et al 2009] or as a postzygotic de novo event in a mosaic parent. If the proband appears to have homozygous pathogenic variants (i.e., the same two pathogenic variants), additional possibilities to consider include:
- A single- or multiexon deletion in the proband that was not detected by sequence analysis and resulted in the artifactual appearance of homozygosity;
- Uniparental isodisomy for the parental chromosome with the pathogenic variant that resulted in homozygosity for the pathogenic variant in the proband.
Heterozygous parents of a child with an autosomal recessive POLG-related disorder are typically asymptomatic.

Sibs of a proband

If both parents are known to be heterozygous for a POLG pathogenic variant, each sib of an affected individual has at conception a 25% chance of inheriting biallelic pathogenic variants and being affected, a 50% chance of being heterozygous, and a 25% chance of inheriting neither of the familial POLG pathogenic variants.
The POLG-related phenotype is usually similar in affected family members; less commonly, affected sibs may present differently in terms of age of onset, specific clinical features, and severity. For example, in a family in which affected sibs were compound heterozygotes (POLG pathogenic variants p.Gly848Ser and p.Trp748Ser), one sib presented with developmental delays and status epilepticus at age three years, while the other sib presented with ataxia and myoclonus in early adolescence [Tang et al 2011].
Heterozygous sibs of a proband with an autosomal recessive POLG-related disorder are typically asymptomatic.

Offspring of a proband

Unless an affected individual's reproductive partner also has POLG-related pathogenic variant(s), offspring will be obligate heterozygotes (carriers) for a pathogenic variant in POLG (see Family planning).
Individuals with early-onset POLG-related disorders (e.g., Alpers-Huttenlocher syndrome and childhood myocerebrohepatopathy spectrum) are not known to reproduce.

Other family members. Each sib of the proband's parents is at a 50% risk of being heterozygous for a POLG pathogenic variant.

Carrier (heterozygote) detection. Carrier testing for at-risk relatives requires prior identification of the POLG pathogenic variants in the family.

Autosomal Dominant Inheritance – Risk to Family Members

Parents of a proband

Most individuals with PEO caused by a heterozygous POLG pathogenic variant (i.e., autosomal dominant PEO or adPEO) have an affected parent, although age of onset and severity of presentation can vary greatly from generation to generation.
Some individuals diagnosed with adPEO have the disorder as the result of a de novo POLG pathogenic variant. The proportion of probands who have a de novo pathogenic variant is unknown but thought to be low (<1%).
If the proband appears to be the only affected family member (i.e., a simplex case), recommendations for the evaluation of the parents include molecular genetic testing for the POLG pathogenic variant identified in the proband, a complete family history, and physical examination focusing on the most common features of POLG-related disease (ophthalmoplegia, myopathy, ataxia, and neuropathy). Note: Because migraine, depression, gastrointestinal problems, fatigue, exercise intolerance, and seizures are common in the general population, their presence as isolated findings is not likely to be relevant.
If the pathogenic variant identified in the proband is not identified in either parent and parental identity testing has confirmed biological maternity and paternity, the following possibilities should be considered:
- The proband has a de novo pathogenic variant.
- The proband inherited a pathogenic variant from a parent with germline (or somatic and germline) mosaicism. Note: Testing of parental leukocyte DNA may not detect all instances of somatic mosaicism and will not detect a pathogenic variant that is present in the germ cells only.
Evaluation of parents may determine that one is affected but has escaped previous diagnosis because of a milder phenotypic presentation, failure to recognize the disorder in family members, early death of the parent before the onset of symptoms, or late onset of the disease in the affected parent. Therefore, an apparently negative family history cannot be confirmed unless molecular genetic testing has demonstrated that neither parent is heterozygous for the pathogenic variant identified in the proband.

Sibs of a proband. The risk to the sibs of the proband depends on the genetic status of the proband's parents:

If a parent of the proband is affected and/or is known to have the pathogenic variant identified in the proband, the risk to the sibs of inheriting the pathogenic variant is 50%. The POLG-related phenotype is generally similar in affected family members, although the age of onset can vary significantly. Data on penetrance of adPEO are not available.
If the POLG pathogenic variant is not detected in the leukocyte DNA of either parent, the recurrence risk to sibs is estimated to be 1% because of the possibility of parental germline mosaicism [Rahbari et al 2016].
If the parents have not been tested for the POLG pathogenic variant but are clinically unaffected, sibs of a proband are still presumed to be at increased risk for adPEO because of the possibility of late onset in a heterozygous parent or the theoretic possibility of parental germline mosaicism.

Offspring of a proband. Each child of an individual with POLG-related adPEO has a 50% chance of inheriting the POLG pathogenic variant.

Other family members. The risk to other family members depends on the status of the proband's parents: if a parent has a POLG pathogenic variant, the parent's family members may be at risk.

Related Genetic Counseling Issues

At-risk family members. Sibs who are close in age to or younger than the proband may still be at risk and in need of diagnostic evaluation. Note: Because the age of onset, even among family members with identical POLG pathogenic variants, can vary considerably, there is no firm certainty as to how many years need to pass before there is no longer a risk of POLG-related features in a sib [Rahman & Copeland 2019].

Family planning

The optimal time for determination of genetic risk and discussion of the availability of prenatal/preimplantation genetic testing is before pregnancy.
It is appropriate to offer genetic counseling (including discussion of potential risks to offspring and reproductive options) to young adults who are affected or are at risk of having a POLG pathogenic variant.
Carrier testing should be considered for the reproductive partners of individuals known to have a POLG pathogenic variant, particularly if consanguinity is likely and/or if both partners are of the same ancestry.

Prenatal Testing and Preimplantation Genetic Testing

Once the POLG pathogenic variant(s) have been identified in an affected family member, prenatal and preimplantation genetic testing for POLG-related disorders are possible.

Differences in perspective may exist among medical professionals and within families regarding the use of prenatal testing. While most centers would consider use of prenatal testing to be a personal decision, discussion of these issues may be helpful.

Resources

GeneReviews staff has selected the following disease-specific and/or umbrella support organizations and/or registries for the benefit of individuals with this disorder and their families. GeneReviews is not responsible for the information provided by other organizations. For information on selection criteria, click here.

The PolG Foundation
polgfoundation.org
American Epilepsy Society
aesnet.org
Children's Liver Disease Foundation
United Kingdom
Phone: +44 (0) 121 212 3839
Email: info@childliverdisease.org
childliverdisease.org
Epilepsy Foundation
Phone: 800-332-1000; 866-748-8008
epilepsy.com
MitoAction
Phone: 888-648-6228
Email: support@mitoaction.org
mitoaction.org
Mitochondrial Care Network
www.mitonetwork.org
National Ataxia Foundation
Phone: 763-553-0020
Email: naf@ataxia.org
ataxia.org
The Charlie Gard Foundation
United Kingdom
Email: hello@thecharliegardfoundation.org
www.thecharliegardfoundation.org
The Lily Foundation
United Kingdom
Email: liz@thelilyfoundation.org.uk
www.thelilyfoundation.org.uk
United Mitochondrial Disease Foundation
Phone: 888-317-UMDF (8633)
Email: info@umdf.org
www.umdf.org
mitoSHARE: UMDF’s Patient-Driven Registry
www.umdf.org/mitoshare
RDCRN Patient Contact Registry: North American Mitochondrial Disease Consortium
Patient Contact Registry

Molecular Genetics

Information in the Molecular Genetics and OMIM tables may differ from that elsewhere in the GeneReview: tables may contain more recent information. —ED.

Table A.

POLG-Related Disorders: Genes and Databases

Gene	Chromosome Locus	Protein	Locus-Specific Databases	HGMD	ClinVar
POLG	15q26.1	DNA polymerase subunit gamma-1	POLG database Human DNA Polymerase Gamma Mutation Database	POLG	POLG

: Data are compiled from the following standard references: gene from HGNC; chromosome locus from OMIM; protein from UniProt. For a description of databases (Locus Specific, HGMD, ClinVar) to which links are provided, click here.

Table B.

OMIM Entries for POLG-Related Disorders (View All in OMIM)

157640	PROGRESSIVE EXTERNAL OPHTHALMOPLEGIA WITH MITOCHONDRIAL DNA DELETIONS, AUTOSOMAL DOMINANT 1; PEOA1
174763	POLYMERASE, DNA, GAMMA; POLG
203700	MITOCHONDRIAL DNA DEPLETION SYNDROME 4A (ALPERS TYPE); MTDPS4A
258450	PROGRESSIVE EXTERNAL OPHTHALMOPLEGIA WITH MITOCHONDRIAL DNA DELETIONS, AUTOSOMAL RECESSIVE 1; PEOB1
607459	SENSORY ATAXIC NEUROPATHY, DYSARTHRIA, AND OPHTHALMOPARESIS; SANDO
613662	MITOCHONDRIAL DNA DEPLETION SYNDROME 4B (MNGIE TYPE); MTDPS4B

Molecular Pathogenesis

The mitochondrion comprises almost 1,500 proteins, but only the 13 that comprise small portions of the respiratory chain complexes I, III, IV, and V are encoded by the mitochondrial genome. The mitochondrial genome is a circular molecule that in humans contains 15,569 base pairs including 37 genes – 13 genes encoding for subunits of complexes I, III, IV, and V, as well as 22 tRNAs and 2 rRNAs – that are distinct and necessary for mitochondrial translation. The terminal portion of energy production occurs in the respiratory chain; disruption of the production and/or assembly of any component leads to a deficiency of ATP and resultant cellular energy failure. The cause of clinical symptoms likely includes insufficient ATP production, but also excessive free radical production, disturbed calcium handling, and other factors. Unlike nuclear DNA, mitochondrial DNA (mtDNA) replicates continuously and independently of cell division. Polymerase (pol) gamma is the major DNA polymerase in humans required for replication and repair of mtDNA. Replication of mtDNA requires a heterotrimer of one catalytic subunit of pol gamma and two accessory subunits, encoded by POLG2, that assist in binding and processing the synthesized DNA. The twinkle protein, encoded by TWNK, functions as the 5' → 3' DNA helicase.

POLG encodes DNA pol gamma, which has three functional domains:

Exonuclease, responsible for proofreading (first third of the protein)
Linker region (center of the protein)
Polymerase, responsible for replication (last third of the protein)

The clinical features POLG-related disorders most likely result from mtDNA depletion or multiple mtDNA deletions [Lujan et al 2020] over time of normal mtDNA, with resultant reduced electron transport chain activity. The adPEO-causing pathogenic variants cluster in the active site region of the DNA polymerase.

Mechanism of disease causation. Loss of POLG function results in loss of polymerase activity – resulting in loss of mtDNA – or loss of endonuclease function – resulting in non-fidelity of mtDNA replication – or both. The loss of mtDNA results in loss of normal mitochondrial translation as well as loss of function involving mtDNA-encoded subunits found in complexes I, III, IV, and V. The result is loss of normal ATP production and elevated free radical production and other mitochondrial functions, with resultant injury to neurons and other cells.

Table 8.

POLG Pathogenic Variants Referenced in This GeneReview

Reference Sequences	DNA Nucleotide Change	Predicted Protein Change	Comment [Reference]
NM_002693.3 NP_002684.1	c.695G>A	p.Arg232His	Pathogenic variant that when in trans w/the p.[Trp748Ser;p.Glu1143Gly] haplotype causes AHS
	c.1399G>A	p.Ala467Thr	Common pathogenic variant in POLG-related disorders; severely ↓ DNA polymerase (pol) gamma activity (4% of wild type pol gamma activity) by ↓ affinity for dNTPs & lowering catalytic activity [Chan et al 2005].
	c.1760C>T	p.Pro587Leu	Common pathogenic variant; nearly always occurs w/p.Thr251Ile in cis (i.e., p.[Thr251Ile;Pro587Leu]) in affected persons & in general population. Individually, these variants cause an approximately 30% reduction in DNA polymerase activity, but together there is a synergistic impairment of polymerase function to levels about 5% of normal [DeBalsi et al 2017].
	c.2243G>C	p.Trp748Ser	Common pathogenic variant that causes AHS, ANS, arPEO, & ataxia-neuropathy. Results in ↓ DNA polymerase activity, low processivity, & severe DNA binding defect, but normal POLG2 interactions [Chan et al 2006]. Note: (1) The p.Glu1143Gly variant in cis modulates the deleterious effect of p.Trp748Ser by partially rescuing activity & ↓ protein stability [Chan et al 2006]. AHS results when the p.[Trp748Ser;p.Glu1143Gly] haplotype occurs in trans with a different pathogenic variant on the other allele (e.g., p.Arg232His). (2) This pathogenic variant is a Finnish founder variant.
	c.2542G>A	p.Gly848Ser	Common pathogenic variant that results in <1% polymerase activity & a defect in DNA binding function [Kasiviswanathan et al 2009]

: Variants listed in the table have been provided by the authors. GeneReviews staff have not independently verified the classification of variants.
: GeneReviews follows the standard naming conventions of the Human Genome Variation Society (varnomen.hgvs.org). See Quick Reference for an explanation of nomenclature.
: AHS = Alpers-Huttenlocher syndrome; ANS = ataxia neuropathy spectrum; arPEO = autosomal recessive progressive external ophthalmoplegia; dNTP = deoxyribonucleotide triphosphate

An up-to-date listing of all pathogenic variants is available at tools.niehs.nih.gov, managed by William Copeland, PhD.

Chapter Notes

Author Notes

Bruce H Cohen is a clinician caring for children and adults with mitochondrial disease since his training starting four decades ago. He first began caring for patients with POLG disease ten years before the POLG gene was cloned and characterized by Dr Copeland and has followed the work of the coauthors over the last 25 years. He has lectured hundreds of times to medical audiences and families on the topic of mitochondrial medicine. For the last decade his focus has been on clinical trials for mitochondrial disease.

Web pages: ‪‪Google Scholar‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬ and Akron Children's

William C Copeland is a biochemist studying mitochondrial DNA replication. He has been leading the Mitochondrial DNA Replication group at the National Institute of Environmental Health Sciences for more than 30 years and is currently the Chief of the Genome Integrity and Structural Biology Laboratory. He uses biochemistry, enzyme kinetics, structural biology, and genetics to study the consequences of POLG pathogenic variants.

William C Copeland, PhD
Chief, Genome Integrity and Structural Biology Laboratory;
Principal Investigator, Mitochondrial DNA Replication Group,
National Institute of Environmental Health Sciences
111 TW Alexander Dr
Research Triangle Park, NC 27709
Phone: 984-287-4269
Email: vog.hin.shein@1nalepoc
Web page:www.niehs.nih.gov
POLG mutation database: tools.niehs.nih.gov

Patrick F Chinnery is a neurologist and clinician-scientist caring for adults with mitochondrial disorders. He runs a laboratory and clinical research group studying disease mechanisms and developing new treatments for mitochondrial disorders based at the MRC Mitochondrial Biology Unit and Department of Clinical Neurosciences, University of Cambridge, United Kingdome.

Web pages: ORCID, Cambridge Clinical Mitochondrial Research Group, and MRC Mitochondrial Biology Unit – Chinnery Group

Patrick F Chinnery, FRCP, FMedSci
Professor of Neurology, University of Cambridge
Department of Clinical Neurosciences
University Neurology Unit
Level 5 'A' Block, Box 165
Cambridge Biomedical Campus
Cambridge, CB2 0QQ, United Kingdom
Email: ku.ca.mac@52cfp

Bruce Cohen (gro.snerdlihcnorka@nehocb) and Patrick Chinnery (ku.ca.mac@52cfp) are actively involved in clinical research regarding individuals with POLG-related disorders. They would be happy to communicate with persons who have any questions regarding diagnosis of POLG-related disorders or other considerations.

Bruce Cohen (gro.snerdlihcnorka@nehocb), Patrick Chinnery (ku.ca.mac@52cfp), and Bill Copeland (vog.hin.shein@1nalepoc) are also interested in hearing from clinicians treating families affected by mitochondrial disorders in whom no causative variant has been identified through molecular genetic testing of the genes known to be involved in this group of disorders.

Contact Dr Bill Copeland (vog.hin.shein@1nalepoc) to inquire about review of POLG variants of uncertain significance.

The Mitochondrial Medicine Society (MMS) represents an international group of physicians, researchers, and clinicians working toward advancing education, research, and global collaboration in clinical mitochondrial medicine. Information about the MMS and educational resources can be found at www.mitosoc.org.

Acknowledgments

Funding: This work was funded in part by the Intramural Research Program of the NIEHS, National Institutes of Health [Z01ES065078 and Z01ES065080] to W.C.C.

P.F.C. is currently funded by a Wellcome Discovery Award (226653/Z/22/Z), a Wellcome Collaborative Award (224486/Z/21/Z), the Medical Research Council Mitochondrial Biology Unit (MC_UU_00028/7), the Biological and Biotechnology Research Council (BB/Y003209/1), and the LifeArc Centre to Treat Mitochondrial Diseases (LAC-TreatMito). His research is supported by the NIHR Cambridge Biomedical Research Centre (BRC-1215-20014). The views expressed are those of the author(s) and not necessarily those of the NIHR or the Department of Health and Social Care.

Revision History

29 February 2024 (gm) Comprehensive update posted live
1 March 2018 (sw) Comprehensive update posted live
18 December 2014 (me) Comprehensive update posted live
11 October 2012 (me) Comprehensive update posted live
16 March 2010 (me) Review posted live
9 December 2007 (bhc) Original submission

References

Literature Cited

Alves CAPF, Gonçalves FG, Grieb D, Lucato LT, Goldstein AC, Zuccoli G. Neuroimaging of Mitochondrial Cytopathies. Top Magn Reson Imaging. 2018;27:219-40. [PubMed: 30086109]
Amadori E, Pellino G, Bansal L, Mazzone S, Møller RS, Rubboli G, Striano P, Russo A. Genetic paroxysmal neurological disorders featuring episodic ataxia and epilepsy. Eur J Med Genet. 2022;65:104450. [PubMed: 35219921]
Antozzi C, Franceschetti S, Filippini G, Barbiroli B, Savoiardo M, Fiacchino F, Rimoldi M, Lodi R, Zaniol P, Zeviani M. Epilepsia partialis continua associated with NADH-coenzyme Q reductase deficiency. J Neurol Sci. 1995;129:152–61. [PubMed: 7608730]
Ashley N, O'Rourke A, Smith C, Adams S, Gowda V, Zeviani M, Brown GK, Fratter C, Poulton J. Depletion of mitochondrial DNA in fibroblast cultures from patients with POLG1 mutations is a consequence of catalytic mutations. Hum Mol Genet. 2008;17:2496–506. [PMC free article: PMC2486441] [PubMed: 18487244]
Besse A, Wu P, Bruni F, Donti T, Graham BH, Craigen WJ, McFarland R, Moretti P, Lalani S, Scott KL, Taylor RW, Bonnen PE. The GABA transaminase, ABAT, is essential for mitochondrial nucleoside metabolism. Cell Metab. 2015;21:417-27. [PMC free article: PMC4757431] [PubMed: 25738457]
Camp KM, Krotoski D, Parisi MA, Gwinn KA, Cohen BH, Cox CS, Enns GM, Falk MJ, Goldstein AC, Gopal-Srivastava R, Gorman GS, Hersh SP, Hirano M, Hoffman FA, Karaa A, MacLeod EL, McFarland R, Mohan C, Mulberg AE, Odenkirchen JC, Parikh S, Rutherford PJ, Suggs-Anderson SK, Tang WH, Vockley J, Wolfe LA, Yannicelli S, Yeske PE, Coates PM. Nutritional interventions in primary mitochondrial disorders: developing an evidence base. Mol Genet Metab. 2016;119:187–206. [PMC free article: PMC5083179] [PubMed: 27665271]
Chan SS, Longley MJ, Copeland WC. Modulation of the W748S mutation in DNA polymerase gamma by the E1143G polymorphism in mitochondrial disorders. Hum Mol Genet. 2006;15:3473–83. [PMC free article: PMC1780027] [PubMed: 17088268]
Chan SS, Longley MJ, Copeland WC. The common A467T mutation in the human mitochondrial DNA polymerase (POLG) compromises catalytic efficiency and interaction with the accessory subunit. J Biol Chem. 2005;280:31341–6. [PubMed: 16024923]
Chan SS, Naviaux RK, Basinger AA, Casas KA, Copeland WC. De novo mutation in POLG leads to haplotype insufficiency and Alpers syndrome. Mitochondrion. 2009;9:340–5. [PMC free article: PMC2748142] [PubMed: 19501198]
Chow J, Rahman J, Achermann JC, Dattani MT, Rahman S. Mitochondrial disease and endocrine dysfunction. Nat Rev Endocrinol. 2017;13:92-104. [PubMed: 27716753]
Cohen BH, Naviaux RK. The clinical diagnosis of POLG disease and other mitochondrial DNA depletion disorders. Methods. 2010;51:364–73. [PubMed: 20558295]
Compton AG, Troedson C, Wilson M, Procopis PG, Li FY, Brundage EK, Yamazaki T, Thorburn DR, Wong LJ. Application of oligonucleotide array CGH in the detection of a large intragenic deletion in POLG associated with Alpers syndrome. Mitochondrion. 2011;11:104–7. [PubMed: 20708716]
Craig K, Ferrari G, Tiangyou W, Hudson G, Gellera C, Zeviani M, Chinnery PF. The A467T and W748S POLG substitutions are a rare cause of adult-onset ataxia in Europe. Brain. 2007;130:E69. [PubMed: 17438011]
Da Pozzo P, Rubegni A, Rufa A, Cardaioli E, Taglia I, Gallus GN, Malandrini A, Federico A. Sporadic PEO caused by a novel POLG variation and a Twinkle mutation: digenic inheritance? Neurol Sci. 2015;36:1713-5. [PubMed: 26050231]
Darin N, Oldfors A, Moslemi AR, Holme E, Tulinius M. The incidence of mitochondrial encephalomyopathies in childhood: clinical features and morphological, biochemical, and DNA anbormalities. Ann Neurol. 2001;49:377–83. [PubMed: 11261513]
Davidzon G, Greene P, Mancuso M, Klos KJ, Ahlskog JE, Hirano M, DiMauro S. Early-onset familial parkinsonism due to POLG mutations. Ann Neurol. 2006;59:859–62. [PubMed: 16634032]
DeBalsi KL, Longley MJ, Hoff KE, Copeland WC. Synergistic effects of the cis T251I and P587L mitochondrial DNA polymerase gamma disease mutations. J. Biol. Chem. 2017;292:4198–209. [PMC free article: PMC5354484] [PubMed: 28154168]
El-Hattab AW, Almannai M, Scaglia F. Arginine and citrulline for the treatment of MELAS syndrome. J Inborn Errors Metab Screen. 2017;5:1–5. [PMC free article: PMC5519148] [PubMed: 28736735]
Fadic R, Russell JA, Vedanarayanan VV, Lehar M, Kuncl RW, Johns DR. Sensory ataxic neuropathy as the presenting feature of a novel mitochondrial disease. Neurology. 1997;49:239–45. [PubMed: 9222196]
Ferrari G, Lamantea E, Donati A, Filosto M, Briem E, Carrara F, Parini R, Simonati A, Santer R, Zeviani M. Infantile hepatocerebral syndromes associated with mutations in the mitochondrial DNA polymerase-gammaA. Brain. 2005;128:723-31. [PubMed: 15689359]
Gai X, Ghezzi D, Johnson MA, Biagosch CA, Shamseldin HE, Haack TB, Reyes A, Tsukikawa M, Sheldon CA, Srinivasan S, Gorza M, Kremer LS, Wieland T, Strom TM, Polyak E, Place E, Consugar M, Ostrovsky J, Vidoni S, Robinson AJ, Wong LJ, Sondheimer N, Salih MA, Al-Jishi E, Raab CP, Bean C, Furlan F, Parini R, Lamperti C, Mayr JA, Konstantopoulou V, Huemer M, Pierce EA, Meitinger T, Freisinger P, Sperl W, Prokisch H, Alkuraya FS, Falk MJ, Zeviani M. Mutations in FBXL4, encoding a mitochondrial protein, cause early-onset mitochondrial encephalomyopathy. Am J Hum Genet. 2013;93:482-95. [PMC free article: PMC3769923] [PubMed: 23993194]
García-Cabo C, Carvajal-García P, Fernández-Vega I, Peña-Suárez J, Mateos-Marcos V, Suárez-Santos P, Álvarez-Martínez V, Morís-de la Tassa G. Ataxia y neuropatía sensitiva de inicio en la edad adulta como manifestación clínica de mutaciones en el gen POLG [Adult-onset sensory neuropathy and ataxia as a clinical manifestation of POLG gene mutations]. Rev Neurol. 2023;76:75-81. [PMC free article: PMC10364044] [PubMed: 36703500]
Gold DR, Cohen BH. Treatment of mitochondrial cytopathies. Semin Neurol. 2001;21:309–25. [PubMed: 11641821]
Hakonen AH, Davidzon G, Salemi R, Bindoff LA, Van Goethem G, Dimauro S, Thorburn DR, Suomalainen A. Abundance of the POLG disease mutations in Europe, Australia, New Zealand, and the United States explained by single ancient European founders. Eur J Hum Genet. 2007;15:779-83. [PubMed: 17426723]
Hakonen AH, Heiskanen S, Juvonen V, Lappalainen I, Luoma PT, Rantamäki M, Goethem GV, Lofgren A, Hackman P, Paetau A, Kaakkola S, Majamaa K, Varilo T, Udd B, Kaariainen H, Bindoff LA, Suomalainen A. Mitochondrial DNA polymerase W748S mutation: a common cause of autosomal recessive ataxia with ancient European origin. Am J Hum Genet. 2005;77:430–41. [PMC free article: PMC1226208] [PubMed: 16080118]
Harrower T, Stewart JD, Hudson G, Houlden H, Warner G, O'Donovan DG, Findlay L, Taylor RW, De Silva R, Chinnery PF. POLG1 mutations manifesting as autosomal recessive axonal Charcot-Marie-Tooth disease. Arch Neurol. 2008;65:133–6. [PubMed: 18195151]
Hasselmann O, Blau N, Ramaekers VT, Quadros EV, Sequeira JM, Weissert M. Cerebral folate deficiency and CNS inflammatory markers in Alpers disease. Mol Genet Metab. 2010;99:58–61. [PubMed: 19766516]
Hikmat O, Eichele T, Tzoulis C, Bindoff LA. Understanding the epilepsy in POLG related disease. Int J Mol Sci. 2017a;18:1845. [PMC free article: PMC5618494] [PubMed: 28837072]
Hikmat O, Naess K, Engvall M, Klingenberg C, Rasmussen M, Tallaksen CM, Brodtkorb E, Ostergaard E, de Coo IFM, Pias-Peleteiro L, Isohanni P, Uusimaa J, Darin N, Rahman S, Bindoff LA. Simplifying the clinical classification of polymerase gamma (POLG) disease based on age of onset; studies using a cohort of 155 cases. J Inherit Metab Dis. 2020;43:726-36. [PubMed: 32391929]
Hikmat O, Tzoulis C, Chong WK, Chentouf L, Klingenberg C, Fratter C, Carr LJ, Prabhakar P, Kumaraguru N, Gissen P, Cross JH, Jacques TS, Taanman JW, Bindoff LA, Rahman S. The clinical spectrum and natural history of early-onset diseases due to DNA polymerase gamma mutations. Genet Med. 2017b;19:1217-25. [PubMed: 28471437]
Hikmat O, Tzoulis C, Knappskog PM, Johansson S, Boman H, Sztromwasser P, Lien E, Brodtkorb E, Ghezzi D, Bindoff LA. ADCK3 mutations with epilepsy, stroke-like episodes and a POLG mimic? Eur J Neurol. 2016;23:1188–94. [PubMed: 27106809]
Hirano M, Ricci E, Koenigsberger MR, Defendini R, Pavlakis SG, DeVivo DC, DiMauro S, Rowland LP. Melas: an original case and clinical criteria for diagnosis. Neuromuscul Disord. 1992;2:125-35. [PubMed: 1422200]
Horvath R, Gorman G, Chinnery PF. How can we treat mitochondrial encephalomyopathies? Approaches to treatment. Neurotherapeutics. 2008;5:558–68. [PMC free article: PMC4514691] [PubMed: 19019307]
Horvath R, Hudson G, Ferrari G, Fütterer N, Ahola S, Lamantea E, Prokisch H, Lochmüller H, McFarland R, Ramesh V, Klopstock T, Freisinger P, Salvi F, Mayr JA, Santer R, Tesarova M, Zeman J, Udd B, Taylor RW, Turnbull D, Hanna M, Fialho D, Suomalainen A, Zeviani M, Chinnery PF. Phenotypic spectrum associated with mutations of the mitochondrial polymerase γ gene. Brain. 2006;129:1674–84. [PubMed: 16621917]
Hudson G, Chinnery PF. Mitochondrial DNA polymerase-gamma and human disease. Hum Mol Genet. 2006;15:R244–52. [PubMed: 16987890]
Hunter MF, Peters H, Salemi R, Thorburn D, Mackay MT. Alpers syndrome with mutations in POLG: clinical and investigative features. Pediatr Neurol. 2011;45:311–8. [PubMed: 22000311]
Kasiviswanathan R, Longley MJ, Chan SS, Copeland WC. Disease mutations in the human DNA polymerase thumb subdomain impart severe defects in mitochondrial DNA replication. J. Biol. Chem. 2009;284:19501–10. [PMC free article: PMC2740576] [PubMed: 19478085]
Kelly DA. Liver transplantation: to do or not to do? Pediatr Transplant. 2000;4:170–2. [PubMed: 10933314]
Lamantea E, Tiranti V, Bordoni A, Toscano A, Bono F, Servidei S, Papadimitriou A, Spelbrink H, Silvestri L, Casari G, Comi GP, Zeviani M. Mutations of mitochondrial DNA polymerase gammaA are a frequent cause of autosomal dominant or recessive progressive external ophthalmoplegia. Ann Neurol. 2002;52:211–9. [PubMed: 12210792]
Lin Y, Du J, Wang W, Ren H, Zhao D, Liu F, Lin P, Ji K, Zhao Y, Yan C. Novel biallelic mutations in POLG gene: large deletion and missense variant associated with PEO. Neurol Sci. 2021;42:4271-80. [PubMed: 34189666]
Lujan SA, Longley MJ, Humble MH, Lavender CA, Burkholder A, Blakely EL, Alston CL, Gorman GS, Turnbull DM, McFarland R, Taylor RW, Kunkel TA, Copeland WC. Ultrasensitive deletions detection links mitochondrial DNA replication, disease, and aging. Genome Biol. 2020;21: 248. [PMC free article: PMC7500033] [PubMed: 32943091]
Luoma P, Melberg A, Rinne JO, Kaukonen JA, Nupponen NN, Chalmers RM, Oldfors A, Rautakorpi I, Peltonen L, Majamaa K, Somer H, Suomalainen A. Parkinsonism, premature menopause, and mitochondrial DNA polymerase gamma mutations: clinical and molecular genetic study. Lancet. 2004;364:875–82. [PubMed: 15351195]
Lutz RE, Dimmock D, Schmitt ES, Zhang Q, Tang LY, Reyes C, Truemper E, McComb RD, Hernandez A, Basinger A, Wong LJ. De novo mutations in POLG presenting with acutre liver failure or encephalopathy. J Pediatr Gastroenterol Nutr. 2009;49:126–9. [PubMed: 19252446]
Mameniškienė R, Wolf P. Epilepsia partialis continua: a review. Seizure. 2017;44:74–80. [PubMed: 28029552]
Mancuso M, Filosto M, Oh SJ, DiMauro S. A novel polymerase gamma mutation in a family with ophthalmoplegia, neuropathy, and Parkinsonism. Arch Neurol. 2004;61:1777–9. [PubMed: 15534189]
Mirza NS, Alfirevic A, Jorgensen A, Marson AG, Pirmohamed M. Metabolic acidosis with topiramate and zonisamide: an assessment of its severity and predictors. Pharmacogenet Genomics 2011;21:297–302. [PubMed: 21278619]
Molaei Ramsheh S, Erfanian Omidvar M, Tabasinezhad M, Alipoor B, Salmani TA, Ghaedi H. SUCLG1 mutations and mitochondrial encephalomyopathy: a case study and review of the literature. Mol Biol Rep. 2020;47:9699-714. [PubMed: 33230783]
Naess K, Barbaro M, Bruhn H, Wibom R, Nennesmo I, Von Dobeln U, Larsson N-G, Nemeth A, Lesko N. A deletion in the POLG1 gene causing Alpers syndrome. JIMD Rep. 2012;4:67–73. [PMC free article: PMC3509876] [PubMed: 23430898]
Naess K, Freyer C, Bruhn H, Wibom R, Malm G, Nennesmo I, von Döbeln U, Larsson N. MtDNA mutations are a common cause of severe disease phenotypes in children with Leigh syndrome. Biochimica et Biophysica Acta. 2009;1787:484–90. [PubMed: 19103152]
Nguyen KV, Sharief FS, Chan SS, Copeland WC, Naviaux RK. Molecular diagnosis of Alpers syndrome. J Hepatol. 2006;45:108–16. [PubMed: 16545482]
Nurminen A, Farnum GA, Kaguni LS. Pathogenicity in POLG syndromes: DNA polymerase gamma pathogenicity prediction server and database. BBA Clin. 2017;7:147-56. [PMC free article: PMC5413197] [PubMed: 28480171]
Pacitti D, Levene M, Garone C, Nirmalananthan N, Bax BE. Mitochondrial neurogastrointestinal encephalomyopathy: into the fourth decade, what we have learned so far. Front Genet. 2018;9:669. [PMC free article: PMC6309918] [PubMed: 30627136]
Pagnamenta AT, Taanman JW, Wilson CJ, Anderson NE, Marotta R, Duncan AJ, Bitner-Glindzicz M, Taylor RW, Laskowski A, Thorburn DR, Rahman S. Dominant inheritance of premature ovarian failure associated with mutant mitochondrial DNA polymerase gamma. Hum Reprod. 2006;21:2467–73. [PubMed: 16595552]
Parada-Garza JD, López-Valencia G, Miranda-García LA, Pérez-García G, Ruiz-Sandoval JL. MRI findings in SANDO variety of the ataxia-neuropathy spectrum with a novel mutation in POLG (c.3287G>T): a case report. Neuromuscul Disord. 2020;30:590-2 [PubMed: 32600829]
Parikh S, Goldstein A, Karaa A, Koenig MK, Anselm I, Brunel-Guitton C, Christodoulou J, Cohen BH, Dimmock D, Enns GM, Falk MJ, Feigenbaum A, Frye RE, Ganesh J, Griesemer D, Haas R, Horvath R, Korson M, Kruer MC, Mancuso M, McCormack S, Raboisson MJ, Reimschisel T, Salvarinova R, Saneto RP, Scaglia F, Shoffner J, Stacpoole PW, Sue CM, Tarnopolsky M, Van Karnebeek C, Wolfe LA, Cunningham ZZ, Rahman S, Chinnery PF. Patient care standards for primary mitochondrial disease: a consensus statement from the Mitochondrial Medicine Society. Genet Med. 2017;19:10. [PMC free article: PMC7804217] [PubMed: 28749475]
Parikh S, Goldstein A, Koenig MK, Scaglia F, Enns GM, Saneto R, Anselm I, Cohen BH, Falk MJ, Greene C, Gropman AL, Haas R, Hirano M, Morgan P, Sims K, Tarnopolsky M, Van Hove JL, Wolfe L, DiMauro S. Diagnosis and management of mitochondrial disease: a consensus statement from the Mitochondrial Medicine Society. Genet Med. 2015;17:689-701. [PMC free article: PMC5000852] [PubMed: 25503498]
Parikh S, Goldstein A, Koenig MK, Scaglia F, Enns GM, Saneto R, et al. Practice patterns of mitochondrial disease physicians in North America. Part 2: treatment, care and management. Mitochondrion. 2013;13:681–7. [PubMed: 24063850]
Parikh S, Karaa A, Goldstein A, Ng YS, Gorman G, Feigenbaum A, Christodoulou J, Haas R, Tarnopolsky M, Cohen BK, Dimmock D, Feyma T, Koenig MK, Mundy H, Niyazov D, Saneto RP, Wainwright MS, Wusthoff C, McFarland R, Scaglia F. Solid organ transplantation in primary mitochondrial disease: Proceed with caution. Mol Genet Metab. 2016;118:178-84. [PubMed: 27312126]
Parikh S, Saneto R, Falk MJ, Anslem I, Cohen BH, Haas R. A modern approach to the treatment of mitochondrial diseases. Curr Treat Options Neurol. 2009;11:414–30. [PMC free article: PMC3561461] [PubMed: 19891905]
Peter B, Falkenberg M. TWINKLE and other human mitochondrial DNA helicases: structure, function and disease. Genes (Basel). 2020;11:408. [PMC free article: PMC7231222] [PubMed: 32283748]
Phillips J, Courel S, Rebelo AP, Bis-Brewer DM, Bardakjian T, Dankwa L, Hamedani AG, Züchner S, Scherer SS. POLG mutations presenting as Charcot-Marie-Tooth disease. J Peripher Nerv Syst. 2019 Jun;24(2):213-218. [PMC free article: PMC8287532] [PubMed: 30843307]
Rahbari R, Wuster A, Lindsay SJ, Hardwick RJ, Alexandrov LB, Turki SA, Dominiczak A, Morris A, Porteous D, Smith B, Stratton MR, Hurles ME, et al. Timing, rates and spectra of human germline mutation. Nat Genet. 2016;48:126-33. [PMC free article: PMC4731925] [PubMed: 26656846]
Rahman S, Copeland WC. POLG-related disorders and their neurological manifestations. Nat Rev Neurol. 2019;15:40-52. [PMC free article: PMC8796686] [PubMed: 30451971]
Richards S, Aziz N, Bale S, Bick D, Das S, Gastier-Foster J, Grody WW, Hegde M, Lyon E, Spector E, Voelkerding K, Rehm HL, et al. Standards and guidelines for the interpretation of sequence variants: a joint consensus recommendation of the American College of Medical Genetics and Genomics and the Association for Molecular Pathology. Genet Med. 2015;17:405–24. [PMC free article: PMC4544753] [PubMed: 25741868]
Rodriguez MC, MacDonald JR, Mahoney DJ, Parise G, Beal MF, Tarnopolsky MA. Beneficial effects of creatine, CoQ10, and lipoic acid in mitochondrial disorders. Muscle Nerve. 2007;35:235–42. [PubMed: 17080429]
Ronchi D, Di Fonzo A, Lin W, Bordoni A, Liu C, Fassone E, Pagliarani S, Rizzuti M, Zheng L, Filosto M, Ferrò MT, Ranieri M, Magri F, Peverelli L, Li H, Yuan YC, Corti S, Sciacco M, Moggio M, Bresolin N, Shen B, Comi GP. Mutations in DNA2 link progressive myopathy to mitochondrial DNA instability. Am J Hum Genet. 2013;92:293-300. [PMC free article: PMC3567272] [PubMed: 23352259]
Rouzier C, Chaussenot A, Serre V, Fragaki K, Bannwarth S, Ait-El-Mkadem S, Attarian S, Kaphan E, Cano A, Delmont E, Sacconi S, Mousson de Camaret B, Rio M, Lebre AS, Jardel C, Deschamps R, Richelme C, Pouget J, Chabrol B, Paquis-Flucklinger V. Quantitative multiplex PCR of short fluorescent fragments for the detection of large intragenic POLG rearrangements in a large French cohort. Eur J Hum Genet. 2014;22:542–50. [PMC free article: PMC3953900] [PubMed: 23921535]
Saneto RP, Cohen BH, Copeland WC, Naviaux RK. Alpers-Huttenlocher syndrome. Pediatr Neurol. 2013;48:167–78. [PMC free article: PMC3578656] [PubMed: 23419467]
Saneto RP, Lee I-C, Koenig MK, Bao X, Weng SW, Naviaux RK, Wong L-J. POLG DNA testing as an emerging standard of care before instituting valproic acid therapy for pediatric seizure disorders. Seizure. 2010;19:140–6. [PMC free article: PMC3099441] [PubMed: 20138553]
Scuderi C, Borgione E, Castello F, Lo Giudice M, Santa Paola S, Giambirtone M, Di Blasi FD, Elia M, Amato C, Città S, Gagliano C, Barbarino G, Vitello GA, Musumeci SA. The in cis T251I and P587L POLG1 base changes: description of a new family and literature review. Neuromuscul Disord. 2015;25:333-9. [PubMed: 25660390]
Stenson PD, Mort M, Ball EV, Chapman M, Evans K, Azevedo L, Hayden M, Heywood S, Millar DS, Phillips AD, Cooper DN. The Human Gene Mutation Database (HGMD®): optimizing its use in a clinical diagnostic or research setting. Hum Genet. 2020;139:1197-207. [PMC free article: PMC7497289] [PubMed: 32596782]
Taanman JW, Rahman S, Pagnamenta AT, Morris AA, Bitner-Glindzicz M, Wolf NI, Leonard JV, Clayton PT, Schapira AH. Analysis of mutant DNA polymerase gamma in patients with mitochondrial DNA depletion. Hum Mutat. 2009;30:248–54. [PubMed: 18828154]
Tang S, Dimberg EL, Milone M, Wong LJ. Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE)-like phenotype: an expanded clinical spectrum of POLG1 mutations. J Neurol. 2012;259:862–8. [PubMed: 21993618]
Tang S, Wang J, Lee NC, Milone M, Halberg MC, Schmitt ES, Craigen WJ, Zhang W, Wong LJ. Mitochondrial DNA polymerase gamma mutations: an ever expanding molecular and clinical spectrum. J Med Genet. 2011;48:669–81. [PubMed: 21880868]
Tzoulis C, Engelsen BA, Telstad W, Aasly J, Zeviani M, Winterthun S, Ferrari G, Aarseth JH, Bindoff LA. The spectrum of clinical disease caused by the A467T and W748S POLG mutations: a study of 26 cases. Brain. 2006;129:1685–92. [PubMed: 16638794]
Van Goethem G, Dermaut B, Lofgren A, Martin JJ, Van Broeckhoven C. Mutation of POLG is associated with progressive external ophthalmoplegia characterized by mtDNA deletions. Nat Genet. 2001;28:211–2. [PubMed: 11431686]
Van Goethem G, Löfgren A, Dermaut B, Ceuterick C, Martin JJ, Van Broeckhoven C. Digenic progressive external ophthalmoplegia in a sporadic patient: recessive mutations in POLG and C10orf2/Twinkle. Hum Mutat. 2003a;22:175–6. [PubMed: 12872260]
Van Goethem G, Martin JJ, Dermaut B, Löfgren A, Wibail A, Ververken D, Tack P, Dehaene I, Van Zandijcke M, Moonen M, Ceuterick C, De Jonghe P, Van Broeckhoven C. Recessive POLG mutations presenting with sensory and ataxic neuropathy in compound heterozygote patients with progressive external ophthalmoplegia. Neuromuscul Disord. 2003b;13:133–42. [PubMed: 12565911]
Wong LJ, Naviaux RK, Brunetti-Pierri N, Zhang Q, Schmitt ES, Truong C, Milone M, Cohen BH, Wical B, Ganesh J, Basinger AA, Burton BK, Swoboda K, Gilbert DL, Vanderver A, Saneto RP, Maranda B, Arnold G, Abdenur JE, Waters PJ, Copeland WC. Molecular and clinical genetics of mitochondrial diseases due to POLG mutations. Hum Mutat. 2008;29:E150–E172. [PMC free article: PMC2891192] [PubMed: 18546365]

GeneReviews® chapters are owned by the University of Washington. Permission is hereby granted to reproduce, distribute, and translate copies of content materials for noncommercial research purposes only, provided that (i) credit for source (http://www.genereviews.org/) and copyright (© 1993-2024 University of Washington) are included with each copy; (ii) a link to the original material is provided whenever the material is published elsewhere on the Web; and (iii) reproducers, distributors, and/or translators comply with the GeneReviews® Copyright Notice and Usage Disclaimer. No further modifications are allowed. For clarity, excerpts of GeneReviews chapters for use in lab reports and clinic notes are a permitted use.

For more information, see the GeneReviews® Copyright Notice and Usage Disclaimer.

For questions regarding permissions or whether a specified use is allowed, contact: ude.wu@tssamda.

Bookshelf ID: NBK26471PMID: 20301791

GeneReviews by Title

< Prev Next >

PubReader
Print View
Cite this Page
Cohen BH, Chinnery PF, Copeland WC. POLG-Related Disorders. 2010 Mar 16 [Updated 2024 Feb 29]. In: Adam MP, Feldman J, Mirzaa GM, et al., editors. GeneReviews® [Internet]. Seattle (WA): University of Washington, Seattle; 1993-2024.
PDF version of this page (753K)

Bulk Download

Bulk download GeneReviews data from FTP

GeneReviews Links

Tests in GTR by Gene

Variations in ClinVar

Variations from this GeneReview in ClinVar

Related information

MedGen
Related information in MedGen
OMIM
Related OMIM records
PMC
PubMed Central citations
PubMed
Links to PubMed
Gene
Locus Links

Recent Activity

Clear Turn Off Turn On

POLG-Related Disorders - GeneReviews®
POLG-Related Disorders - GeneReviews®

Your browsing activity is empty.

Activity recording is turned off.

Turn recording back on

Bookshelf

GeneReviews® [Internet].

POLG-Related Disorders

Summary

Clinical characteristics.

Diagnosis/testing.

Management.

Genetic counseling.

GeneReview Scope

Diagnosis

Suggestive Findings

Establishing the Diagnosis

Option 1

Option 2

Table 1.

Clinical Characteristics

Clinical Description

Table 2.

Early-Onset Disease (Prior to Age 12 Years)

Alpers-Huttenlocher Syndrome (AHS)

Childhood Myocerebrohepatopathy Spectrum (MCHS)

Juvenile/Adult-Onset Disease (Age 12-40 Years)

Myoclonic Epilepsy Myopathy Sensory Ataxia (MEMSA)

Ataxia Neuropathy Spectrum (ANS)

Late-Onset Disease (Age >40 Years)

Autosomal Recessive Progressive External Ophthalmoplegia (arPEO)

Autosomal Dominant Progressive External Ophthalmoplegia (adPEO)

Rare Phenotypes

Genotype-Phenotype Correlations

Nomenclature

Prevalence

Table 3.

Genetically Related (Allelic) Disorders

Differential Diagnosis

Table 4.

Other Disorders to Consider

Management

Evaluations Following Initial Diagnosis

Table 5.

Treatment of Manifestations

Table 6.

Developmental Delay / Intellectual Disability Management Issues

Motor Dysfunction

Neurobehavioral/Psychiatric Concerns

Surveillance

Table 7.

Agents/Circumstances to Avoid

Evaluation of Relatives at Risk

Therapies Under Investigation

Other

Genetic Counseling

Mode of Inheritance

Autosomal Recessive Inheritance – Risk to Family Members

Autosomal Dominant Inheritance – Risk to Family Members

Related Genetic Counseling Issues

Prenatal Testing and Preimplantation Genetic Testing

Resources

Molecular Genetics

Table A.

Table B.

Molecular Pathogenesis

Table 8.

Chapter Notes

Author Notes

Acknowledgments

Revision History

References

Literature Cited

Views

In this GeneReview

Bulk Download

GeneReviews Links

Tests in GTR by Gene

Variations in ClinVar

Related information

Similar articles in PubMed

Recent Activity

GeneReviews^® [Internet].