LRRK2 c.6055G>A (p.Gly2019Ser) has been associated with increased risk for Parkinson's disease. This variant has been observed in multiple ethnic backgrounds with highest frequencies in individuals of Ashkenazi Jewish ancestry (0.86%, Genome Aggregation Database (gnomAD); rs6025) and is present in ClinVar (ID: 1940). A large meta-analysis has reported an odds ratio of 14.98 [95% CI 4.8-10] for developing Parkinson's disease (Wu 2012). In vivo and in vitro functional studies provide some evidence that the p.Gly2019Ser variant may impact protein function (Chen 2012). Therefore, this variant is not expected to cause highly penetrant Mendelian disease. In summary, this variant is an established risk factor for Parkinson's disease.
ClinVar Genomic variation as it relates to human health
NM_198578.4(LRRK2):c.6055G>A (p.Gly2019Ser)
Germline
Classification
Help
The aggregate germline classification for this variant, typically for a monogenic or Mendelian disorder as in the ACMG/AMP guidelines, or for response to a drug. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the aggregate classification.
(26)
Help
Stars represent the aggregate review status, or the level of review supporting the aggregate germline classification for this VCV record. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the review status. The number of submissions which contribute to this review status is shown in parentheses.
Pathogenic/Likely pathogenic; risk factor
26
criteria provided, multiple submitters, no conflicts
Somatic
No data submitted for somatic clinical impact
Somatic
No data submitted for oncogenicity
Variant Details
- Identifiers
-
NM_198578.4(LRRK2):c.6055G>A (p.Gly2019Ser)
Variation ID: 1940 Accession: VCV000001940.68
- Type and length
-
single nucleotide variant, 1 bp
- Location
-
Cytogenetic: 12q12 12: 40340400 (GRCh38) [ NCBI UCSC ] 12: 40734202 (GRCh37) [ NCBI UCSC ]
- Timeline in ClinVar
-
First in ClinVar Help The date this variant first appeared in ClinVar with each type of classification.
Last submission Help The date of the most recent submission for each type of classification for this variant.
Last evaluated Help The most recent date that a submitter evaluated this variant for each type of classification.
Germline Apr 4, 2013 Oct 20, 2024 Sep 22, 2024 - HGVS
-
... more HGVS ... less HGVSNucleotide Protein Molecular
consequenceNM_198578.4:c.6055G>A MANE Select Help Transcripts from the Matched Annotation from the NCBI and EMBL-EBI (MANE) collaboration.
NP_940980.4:p.Gly2019Ser missense NC_000012.12:g.40340400G>A NC_000012.11:g.40734202G>A NG_011709.1:g.120390G>A Q5S007:p.Gly2019Ser - Protein change
- G2019S
- Other names
- -
- Canonical SPDI
- NC_000012.12:40340399:G:A
-
Functional
consequence HelpThe effect of the variant on RNA or protein function, based on experimental evidence from submitters.
- -
-
Global minor allele
frequency (GMAF) HelpThe global minor allele frequency calculated by the 1000 Genomes Project. The minor allele at this location is indicated in parentheses and may be different from the allele represented by this VCV record.
-
0.00020 (A)
-
Allele frequency
Help
The frequency of the allele represented by this VCV record.
-
1000 Genomes Project 0.00020
1000 Genomes Project 30x 0.00031
The Genome Aggregation Database (gnomAD) 0.00036
Exome Aggregation Consortium (ExAC) 0.00039
The Genome Aggregation Database (gnomAD), exomes 0.00053
Trans-Omics for Precision Medicine (TOPMed) 0.00059
- Links
Genes
| Gene | OMIM | ClinGen Gene Dosage Sensitivity Curation |
Variation Viewer
Help
Links to Variation Viewer, a genome browser to view variation data from NCBI databases. |
Related variants | ||
|---|---|---|---|---|---|---|
| HI score
Help
The haploinsufficiency score for the gene, curated by ClinGen’s Dosage Sensitivity Curation task team. |
TS score
Help
The triplosensitivity score for the gene, curated by ClinGen’s Dosage Sensitivity Curation task team. |
Within gene
Help
The number of variants in ClinVar that are contained within this gene, with a link to view the list of variants. |
All
Help
The number of variants in ClinVar for this gene, including smaller variants within the gene and larger CNVs that overlap or fully contain the gene. |
|||
| LRRK2 | - | - |
GRCh38 GRCh37 |
3554 | 3579 | |
Conditions - Germline
| Condition
Help
The condition for this variant-condition (RCV) record in ClinVar. |
Classification
Help
The aggregate germline classification for this variant-condition (RCV) record in ClinVar. The number of submissions that contribute to this aggregate classification is shown in parentheses. (# of submissions) |
Review status
Help
The aggregate review status for this variant-condition (RCV) record in ClinVar. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the review status. |
Last evaluated
Help
The most recent date that a submitter evaluated this variant for the condition. |
Variation/condition record
Help
The RCV accession number, with most recent version number, for the variant-condition record, with a link to the RCV web page. |
|---|---|---|---|---|
| Pathogenic/Likely pathogenic (15) |
criteria provided, multiple submitters, no conflicts
|
Sep 22, 2024 | RCV000002017.46 | |
| Pathogenic (1) |
criteria provided, single submitter
|
Jul 19, 2022 | RCV000622347.12 | |
| risk factor (1) |
criteria provided, single submitter
|
Dec 29, 2017 | RCV001195216.12 | |
| Pathogenic (1) |
criteria provided, single submitter
|
May 3, 2021 | RCV001836691.10 | |
| Pathogenic (6) |
criteria provided, multiple submitters, no conflicts
|
Nov 1, 2022 | RCV000325492.41 | |
| Pathogenic (1) |
criteria provided, single submitter
|
Mar 30, 2023 | RCV003993728.1 | |
|
LRRK2-related disorder
|
Pathogenic (1) |
no assertion criteria provided
|
Sep 4, 2024 | RCV003407254.6 |
Submissions - Germline
| Classification
Help
The submitted germline classification for each SCV record. (Last evaluated) |
Review status
Help
Stars represent the review status, or the level of review supporting the submitted (SCV) record. This value is calculated by NCBI based on data from the submitter. Read our rules for calculating the review status. This column also includes a link to the submitter’s assertion criteria if provided, and the collection method. (Assertion criteria) |
Condition
Help
The condition for the classification, provided by the submitter for this submitted (SCV) record. This column also includes the affected status and allele origin of individuals observed with this variant. |
Submitter
Help
The submitting organization for this submitted (SCV) record. This column also includes the SCV accession and version number, the date this SCV first appeared in ClinVar, and the date that this SCV was last updated in ClinVar. |
More information
Help
This column includes more information supporting the classification, including citations, the comment on classification, and detailed evidence provided as observations of the variant by the submitter. |
|
|---|---|---|---|---|---|
|
Pathogenic
(May 28, 2019)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: unknown
Allele origin:
unknown
|
Mendelics
Accession: SCV001138694.1
First in ClinVar: Jan 09, 2020 Last updated: Jan 09, 2020 |
|
|
|
risk factor
(Dec 29, 2017)
|
criteria provided, single submitter
Method: clinical testing
|
Young-onset Parkinson disease
Affected status: unknown
Allele origin:
germline
|
Laboratory for Molecular Medicine, Mass General Brigham Personalized Medicine
Accession: SCV001365523.1
First in ClinVar: Jul 04, 2020 Last updated: Jul 04, 2020 |
Comment:
LRRK2 c.6055G>A (p.Gly2019Ser) has been associated with increased risk for Parkinson's disease. This variant has been observed in multiple ethnic backgrounds with highest frequencies in … (more)
LRRK2 c.6055G>A (p.Gly2019Ser) has been associated with increased risk for Parkinson's disease. This variant has been observed in multiple ethnic backgrounds with highest frequencies in individuals of Ashkenazi Jewish ancestry (0.86%, Genome Aggregation Database (gnomAD); rs6025) and is present in ClinVar (ID: 1940). A large meta-analysis has reported an odds ratio of 14.98 [95% CI 4.8-10] for developing Parkinson's disease (Wu 2012). In vivo and in vitro functional studies provide some evidence that the p.Gly2019Ser variant may impact protein function (Chen 2012). Therefore, this variant is not expected to cause highly penetrant Mendelian disease. In summary, this variant is an established risk factor for Parkinson's disease. (less)
Number of individuals with the variant: 1
|
|
|
Pathogenic
(Oct 23, 2020)
|
criteria provided, single submitter
Method: clinical testing
|
not provided
(Unknown mechanism)
Affected status: yes
Allele origin:
germline
|
Institute of Medical Genetics and Applied Genomics, University Hospital Tübingen
Accession: SCV001446474.1
First in ClinVar: Nov 28, 2020 Last updated: Nov 28, 2020 |
Clinical Features:
Parkinsonian disorder (present)
Sex: female
|
|
|
Pathogenic
(Jan 23, 2020)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: yes
Allele origin:
unknown
|
Baylor Genetics
Accession: SCV001522345.1
First in ClinVar: Mar 22, 2021 Last updated: Mar 22, 2021 |
Comment:
This variant was determined to be pathogenic according to ACMG Guidelines, 2015 [PMID:25741868].
|
|
|
Pathogenic
(May 03, 2021)
|
criteria provided, single submitter
Method: clinical testing
|
Parkinson disease, late-onset
Affected status: yes
Allele origin:
germline
|
Fulgent Genetics, Fulgent Genetics
Accession: SCV001652801.1
First in ClinVar: May 28, 2021 Last updated: May 28, 2021 |
|
|
|
Pathogenic
(Jan 06, 2020)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: yes
Allele origin:
germline
|
Al Jalila Children’s Genomics Center, Al Jalila Childrens Speciality Hospital
Accession: SCV001984701.1
First in ClinVar: Oct 30, 2021 Last updated: Oct 30, 2021 |
|
|
|
Pathogenic
(Dec 03, 2021)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: unknown
Allele origin:
germline
|
Women's Health and Genetics/Laboratory Corporation of America, LabCorp
Accession: SCV002050743.1
First in ClinVar: Jan 08, 2022 Last updated: Jan 08, 2022 |
Comment:
Variant summary: LRRK2 c.6055G>A (p.Gly2019Ser) results in a non-conservative amino acid change located in the Protein kinase domain (IPR000719) of the encoded protein sequence. Five … (more)
Variant summary: LRRK2 c.6055G>A (p.Gly2019Ser) results in a non-conservative amino acid change located in the Protein kinase domain (IPR000719) of the encoded protein sequence. Five of five in-silico tools predict a damaging effect of the variant on protein function. The variant allele was found at a frequency of 0.00053 in 251154 control chromosomes in the gnomAD database, including 1 homozygote. This frequency is not significantly higher than expected for a pathogenic variant in LRRK2 causing Parkinson Disease 8, Autosomal Dominant, allowing no conclusion about variant significance. c.6055G>A has been widely reported in the literature in multiple individuals affected with Parkinson Disease 8, Autosomal Dominant as a common founder mutation associated with age dependent penetrance among European populations (example, Kachergus_2005) and this association continues to be subsequently acknowledged and cited by others. These data indicate that the variant is very likely to be associated with disease. At least one publication reports experimental evidence evaluating an impact on protein function (example, Greggio_2006). The most pronounced variant effect results in increased tendency to form inclusion bodies. Secondly, neurons and neuronal cell lines undergo cell death after expression of mutant protein. Multiple clinical diagnostic laboratories have submitted clinical-significance assessments for this variant to ClinVar after 2014 without evidence for independent evaluation. All submitters classified the variant as pathogenic. Based on the evidence outlined above, the variant was classified as pathogenic. (less)
|
|
|
Pathogenic
(Apr 28, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: yes
Allele origin:
germline
|
Genetics and Molecular Pathology, SA Pathology
Additional submitter:
Shariant Australia, Australian Genomics
Accession: SCV002556835.2
First in ClinVar: Aug 08, 2022 Last updated: Dec 17, 2022 |
|
|
|
Pathogenic
(Dec 07, 2017)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
(Autosomal dominant inheritance)
Affected status: yes
Allele origin:
germline
|
Institute of Human Genetics Munich, Klinikum Rechts Der Isar, TU München
Accession: SCV000680283.2
First in ClinVar: Feb 08, 2018 Last updated: Dec 24, 2022 |
Observation 1:
Number of individuals with the variant: 1
Clinical Features:
Arm dystonia (present) , Parkinsonian disorder (present) , Tremor (present) , Intracranial meningioma (present)
Observation 2:
Number of individuals with the variant: 1
Clinical Features:
Parkinsonian disorder (present)
Observation 3:
Number of individuals with the variant: 1
Clinical Features:
Iron accumulation in brain (present) , Dementia (present) , Dystonic disorder (present)
Observation 4:
Number of individuals with the variant: 1
Clinical Features:
Tremor (present) , Hypomimic face (present) , Parkinsonian disorder (present) , Bradykinesia (present) , Tachylalia (present)
Observation 5:
Number of individuals with the variant: 1
Clinical Features:
Parkinsonian disorder (present) , Muscle stiffness (present) , Tremor (present)
|
|
|
Likely pathogenic
(Sep 22, 2024)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: unknown
Allele origin:
germline
|
Center for Genomic Medicine, King Faisal Specialist Hospital and Research Center
Accession: SCV005374405.1
First in ClinVar: Oct 13, 2024 Last updated: Oct 13, 2024 |
|
|
|
Pathogenic
(May 14, 2014)
|
criteria provided, single submitter
Method: clinical testing
|
Parkinson disease 8
Affected status: yes
Allele origin:
germline
|
Courtagen Diagnostics Laboratory, Courtagen Life Sciences
Accession: SCV000236518.2
First in ClinVar: Jul 02, 2015 Last updated: Jul 02, 2015 |
|
|
|
Pathogenic
(Mar 12, 2020)
|
criteria provided, single submitter
Method: clinical testing
|
Not Provided
Affected status: yes
Allele origin:
germline
|
GeneDx
Accession: SCV000329408.5
First in ClinVar: Dec 06, 2016 Last updated: Dec 06, 2016 |
Comment:
The G2019S variant is the most common pathogenic substitution in the LRRK2 gene (Lunati et al., 2018); Individuals who are heterozygous for the G2019S variant … (more)
The G2019S variant is the most common pathogenic substitution in the LRRK2 gene (Lunati et al., 2018); Individuals who are heterozygous for the G2019S variant have more than a 20-fold increase in risk for developing Parkinson disease (Dachsel et al., 2010); Lysosomal dysfunction plays a central role in the pathogenesis of Parkinson disease, and published functional studies have shown that expression of G2019S produces enlarged lysosomes and alters their function (Henry et al., 2015); In silico analysis, which includes protein predictors and evolutionary conservation, supports a deleterious effect; This variant is associated with the following publications: (PMID: 24211199, 19397894, 22080837, 21362567, 15726496, 29357897, 29248340, 30528841, 22736029, 23241358, 23396536, 20232069, 21280089, 20008657, 22914360, 21961647, 20642453, 17447891, 21686713, 22539006, 22773119, 23357204, 23472874, 21658387, 24729340, 19072560, 24652679, 21699405, 17200152, 21972245, 24470158, 21850687, 23227859, 19302196, 22004453, 20626563, 20881132, 25401981, 25330418, 22194196, 17210620, 21885347, 24488318, 24357540, 20818610, 22488887, 21696411, 21883375, 20671708, 23075850, 20096956, 16750377, 24148854, 18675914, 23747310, 25107341, 17095157, 19283415, 21753159, 22323743, 22914834, 25008396, 21494637, 23082216, 21390248, 21799870, 24082139, 22689969, 23764467, 18752982, 19945904, 20933457, 21641848, 22575234, 25434972, 23241745, 25000966, 26251043, 20457952, 18986508, 27692902, 27383589, 27423549, 27393345, 24360742, 24243757, 25962553, 23664753, 26159606, 26282470, 28862745, 29309488, 29800472, 30245141, 30709905, 3066573, 30146349, 16333314, 28487191, 28723952, 16102999, 16001413, 28639421, 18644660, 24123150, 19741132, 30172844, 16966501, 17060589, 29795570, 17116211, 24282027, 30665703, 31077434, 31324919, 31813996, 31605779, 31980526, 32875616, 26600626, 32398759, 33281709, 32353202, 18201824, 33084218, 15852371, 31589614) (less)
|
|
|
Pathogenic
(Aug 02, 2021)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: unknown
Allele origin:
unknown
|
Illumina Laboratory Services, Illumina
Accession: SCV002034786.1
First in ClinVar: Dec 18, 2021 Last updated: Dec 18, 2021 |
Comment:
The LRRK2 c.6055G>A (p.Gly2019Ser) missense variant is the most common variant reported in individuals with LRRK2-related Parkinson disease (PD) (Saunders-Pullman et al. 2006). Across a … (more)
The LRRK2 c.6055G>A (p.Gly2019Ser) missense variant is the most common variant reported in individuals with LRRK2-related Parkinson disease (PD) (Saunders-Pullman et al. 2006). Across a selection of available literature, the p.Gly2019Ser variant has been identified in a heterozygous state in 131 individuals and in a homozygous state in two individuals with Parkinson disease (Kachergus et al. 2005; Nichols et al. 2005; Bar-Shira et al. 2009). The p.Gly2019Ser variant was absent from 3487 healthy matched controls in these studies and is reported at a frequency of 0.008396 in the Ashkenazi Jewish population of the Genome Aggregation Database (version 2.1.1). Analysis showed that carriers of the p.Gly2019Ser variant, who were of Ashkenazi Jewish descent, shared a 243 kb haplotype, suggesting a common founder in this population (Bar-Shira et al. 2009). The variant is also noted to exist as a founder variant in North African Berbers (Saunders-Pullman et al. 2006). The p.Gly2019Ser variant is associated with reduced penetrance; penetrance for heterozygotes is age dependent, and varies in different populations ranging from 25% - 42% up to age 80 (Saunders-Pullman et al. 2006). Generally clinical features are indistinguishable between individuals with LRRK2-related PD compared to idiopathic PD. However, studies have shown the p.Gly2019Ser variant results in a slightly milder clinical course than seen in individuals with Parkinson disease (Saunders-Pullman et al. 2006). Mitochondrial dysfunction and lysosomal dysfunction play central roles in PD pathophysiology. Functional studies showed increased mitochondrial DNA damage in iPSC-derived neural cells from patients carrying the p.Gly2019Ser variant than in cells from healthy controls. In patient cells in which the p.Gly2019Ser variant was repaired with zinc finger nuclease, reduced mitochondrial DNA damage was observed at levels seen in healthy control cells (Sanders et al. 2014). The p.Gly2019Ser variant has also been demonstrated to result in enlarged lysosomes, impaired lysosomal function, and increased kinase activity (Henry et al. 2015). Based on the collective evidence, the p.Gly2019Ser variant is classified as pathogenic for LRRK2-related Parkinson disease. (less)
|
|
|
Likely pathogenic
(May 22, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: yes
Allele origin:
germline
|
3billion
Accession: SCV002521485.1
First in ClinVar: Jun 05, 2022 Last updated: Jun 05, 2022 |
Comment:
The variant is observed at an allele frequency greater than expected for the associated disorder in the gnomAD v2.1.1 dataset. Missense changes are a common … (more)
The variant is observed at an allele frequency greater than expected for the associated disorder in the gnomAD v2.1.1 dataset. Missense changes are a common disease-causing mechanism. In silico tool predictions suggest damaging effect of the variant on gene or gene product (REVEL: 0.97; 3Cnet: 0.95). Same nucleotide change resulting in same amino acid change has been previously reported as pathogenic/likely pathogenic with strong evidence (ClinVar ID: VCV000001940). Therefore, this variant is classified as likely pathogenic according to the recommendation of ACMG/AMP guideline. (less)
Clinical Features:
Dysarthria (present) , Postural instability (present) , Bradykinesia (present) , Rigidity (present) , Dyskinesia (present) , Parkinsonism with favorable response to dopaminergic medication (present)
|
|
|
Pathogenic
(May 07, 2021)
|
criteria provided, single submitter
Method: clinical testing
|
not provided
Affected status: unknown
Allele origin:
unknown
|
Athena Diagnostics
Accession: SCV000842686.4
First in ClinVar: Oct 19, 2018 Last updated: Dec 31, 2022 |
Comment:
This variant is statistically more frequent in affected individuals than in the general population and/or healthy controls (Genome Aggregation Database (gnomAD), Cambridge, MA (URL: http://gnomad.broadinstitute.org)). … (more)
This variant is statistically more frequent in affected individuals than in the general population and/or healthy controls (Genome Aggregation Database (gnomAD), Cambridge, MA (URL: http://gnomad.broadinstitute.org)). This variant is reported to exhibit age-dependent penetrance that may be impacted by ethnicity (PMID: 26062626, 25330418, 18986508). This variant appears to be associated with disease in multiple families (PMID: 16240353, 16533964). According to published literature, there is no reported difference in clinical presentation between individuals with this variant in the heterozygous or homozygous state (PMID: 16966502). Assessment of experimental evidence suggests this variant results in abnormal protein function. Studies have shown expression of this variant results in increased kinase activity, dysregulation of lysosomal homeostasis, and age-dependent and kinase-dependent neurodegeneration (PMID: 29402177, 29386392, 26251043, 23472874). (less)
|
|
|
Pathogenic
(Feb 07, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: unknown
Allele origin:
unknown
|
Fulgent Genetics, Fulgent Genetics
Accession: SCV000893982.2
First in ClinVar: Mar 31, 2019 Last updated: Dec 31, 2022 |
|
|
|
Pathogenic
(Jan 26, 2024)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: unknown
Allele origin:
germline
|
Labcorp Genetics (formerly Invitae), Labcorp
Accession: SCV000640135.9
First in ClinVar: Dec 26, 2017 Last updated: Feb 28, 2024 |
Comment:
This sequence change replaces glycine, which is neutral and non-polar, with serine, which is neutral and polar, at codon 2019 of the LRRK2 protein (p.Gly2019Ser). … (more)
This sequence change replaces glycine, which is neutral and non-polar, with serine, which is neutral and polar, at codon 2019 of the LRRK2 protein (p.Gly2019Ser). This variant is present in population databases (rs34637584, gnomAD 0.9%), and has an allele count higher than expected for a pathogenic variant. This missense change has been observed in individual(s) with Parkinson’s disease (PD) and is one of the most common known genetic causes of PD. This variant has been reported to have a reduced penetrance of 25-42.5% in various populations (PMID: 15680455, 15726496, 18986508, 22575234, 26062626, 28639421). It has also been observed to segregate with disease in related individuals. ClinVar contains an entry for this variant (Variation ID: 1940). Advanced modeling of protein sequence and biophysical properties (such as structural, functional, and spatial information, amino acid conservation, physicochemical variation, residue mobility, and thermodynamic stability) performed at Invitae indicates that this missense variant is not expected to disrupt LRRK2 protein function with a negative predictive value of 80%. Experimental studies have shown that this missense change affects LRRK2 function (PMID: 26251043). For these reasons, this variant has been classified as Pathogenic. (less)
|
|
|
Pathogenic
(Mar 30, 2023)
|
criteria provided, single submitter
Method: clinical testing
|
Parkinson disease
Affected status: yes
Allele origin:
germline
|
Molecular Genetics, Royal Melbourne Hospital
Additional submitter:
Shariant Australia, Australian Genomics
Accession: SCV004812567.1
First in ClinVar: Apr 15, 2024 Last updated: Apr 15, 2024 |
Comment:
This sequence change in LRRK2 is predicted to replace glycine with serine at codon 2019, p.(Gly2019Ser). The glycine residue is highly conserved (100 vertebrates, UCSC), … (more)
This sequence change in LRRK2 is predicted to replace glycine with serine at codon 2019, p.(Gly2019Ser). The glycine residue is highly conserved (100 vertebrates, UCSC), and is located in the protein kinase domain There is a small physicochemical difference between glycine and serine. The highest population minor allele frequency in gnomAD v2.1 is 0.8% (87/10,362 alleles, 1 homozygote) in the Ashkenazi Jewish population, while the highest continental population minor allele frequency is 0.03% (33/128,908 alleles) in the European (non-Finnish) population. This is the most commonly reported pathogenic variant in LRRK2 and is associated with a risk of Parkinson disease (PD) at an estimated age-related penetrance of between 25-42.5% (PMID: 20301387, 28639421). The prevalence of the variant in affected individuals is significantly increased compared with the prevalence in controls (odds ratio 14.98, 95% CI:10.68-21.02) (PMID: 22575234). The variant has been reported to segregate with PD in multiple families (PMID: 15726496 ). A transgenic mouse model for the variant recapitulates the human PD phenotype and brain histopathology (PMID: 22539006). Multiple lines of computational evidence predict a deleterious effect for the missense substitution (6/6 algorithms). Based on the classification scheme RMH Modified ACMG Guidelines v1.5.1, this variant is classified as PATHOGENIC. Following criteria are met: PS3, PP1_Strong, PS4_Moderate, PP3. (less)
|
|
|
Pathogenic
(Jul 19, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Inborn genetic diseases
Affected status: unknown
Allele origin:
germline
|
Ambry Genetics
Accession: SCV000742130.5
First in ClinVar: Apr 15, 2018 Last updated: May 01, 2024 |
Comment:
The c.6055G>A (p.G2019S) alteration is located in exon 41 (coding exon 41) of the LRRK2 gene. This alteration results from a G to A substitution … (more)
The c.6055G>A (p.G2019S) alteration is located in exon 41 (coding exon 41) of the LRRK2 gene. This alteration results from a G to A substitution at nucleotide position 6055, causing the glycine (G) at amino acid position 2019 to be replaced by a serine (S). Based on data from gnomAD, the A allele has an overall frequency of 0.05% (138/282542) total alleles studied. The highest observed frequency was 0.84% (87/10362) of Ashkenazi Jewish alleles. The p.G2019S alteration is the most common disease-causing LRRK2 alteration (Saunders-Pullman, 2019). This amino acid position is highly conserved in available vertebrate species. Functional analysis demonstrated that compared to the wild-type, the p.G2019S alteration significantly increased the phosphorylation of peroxiredoxin 3 (PRDX3), a mitochondrial member of the antioxidant family of thioredoxin peroxidases. Increased PRDX3 phosphorylation was associated with inhibited PRDX3 peroxidase activity and increased death in LRRK2-expressing but not in LRRK2-depleted or vector-transfected neuronal cells (Angeles, 2011). This alteration is predicted to be deleterious by in silico analysis. Based on the available evidence, this alteration is classified as pathogenic. (less)
|
|
|
Pathogenic
(Nov 08, 2023)
|
criteria provided, single submitter
Method: clinical testing
|
Autosomal dominant Parkinson disease 8
Affected status: yes
Allele origin:
germline
|
Clinical Genomics Laboratory, Washington University in St. Louis
Accession: SCV005045124.1
First in ClinVar: May 26, 2024 Last updated: May 26, 2024 |
Comment:
The LRRK2 c.6055G>A (p.Gly2019Ser) variant is reported as one of the most common alleles in individuals affected with Parkinson‚Äôs disease and segregates with disease in … (more)
The LRRK2 c.6055G>A (p.Gly2019Ser) variant is reported as one of the most common alleles in individuals affected with Parkinson’s disease and segregates with disease in families (Saunders-Pullman R et al., PMID: 20301387). The highest population minor allele frequency in the population database genome aggregation database (v.2.1.1) is 0.84% in Ashkenazi Jewish population. Functional studies show increased mitochondrial DNA damage, increased phosphorylation of alpha synuclein, dysregulation of lysosomal function, and kinase-dependent neurodegeneration (Henry G et al., PMID: 26251043; Qing H et al., PMID: 19576176; Sanders LH et al., PMID: 24148854; Vermilyea SC et al., PMID: 29402177), indicating that this variant impacts protein function. This variant resides within a region, amino acids 1879-2138, of LRRK2 that is defined as a critical functional domain (Vermilyea SC et al., PMID: 29402177). Computational predictors indicate that the variant is damaging, evidence that correlates with impact to LRRK2 function. This variant has been reported in the ClinVar database as a pathogenic variant in Parkinson’s disease by 18 submitters, likely pathogenic by one submitter and a risk factor by one submitter. Based on available information and the ACMG/AMP guidelines for variant interpretation (Richards S et al., PMID: 25741868), this variant is classified as pathogenic. (less)
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Pathogenic
(Nov 01, 2022)
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criteria provided, single submitter
Method: clinical testing
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not provided
Affected status: yes
Allele origin:
germline
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CeGaT Center for Human Genetics Tuebingen
Accession: SCV001250090.26
First in ClinVar: May 12, 2020 Last updated: Oct 20, 2024 |
Comment:
LRRK2: PS4, PM1, PP1, PP3, PP4, PS3:Supporting
Number of individuals with the variant: 6
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Pathogenic
(Nov 22, 2012)
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no assertion criteria provided
Method: literature only
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PARKINSON DISEASE 8, AUTOSOMAL DOMINANT
Affected status: not provided
Allele origin:
germline
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OMIM
Accession: SCV000022175.3
First in ClinVar: Apr 04, 2013 Last updated: Oct 30, 2017 |
Comment on evidence:
In affected members of 4 of 61 (6.6%) unrelated families with autosomal dominant Parkinson disease (PARK8; 607060), Di Fonzo et al. (2005) identified a heterozygous … (more)
In affected members of 4 of 61 (6.6%) unrelated families with autosomal dominant Parkinson disease (PARK8; 607060), Di Fonzo et al. (2005) identified a heterozygous 6055G-A transition in exon 41 of the LRRK2 gene, resulting in a gly2019-to-ser (G2019S) substitution. Two families were from Italy, and 1 each were from Portugal and Brazil. The gly2019 residue is highly conserved and is part of a 3-amino acid motif required by all human kinase proteins. Gilks et al. (2005) identified the G2019S mutation in 8 of 482 (1.6%) unrelated patients with Parkinson disease. Five of the patients had no family history of the disorder, suggesting either a de novo occurrence or reduced penetrance. Nichols et al. (2005) identified the G2019S mutation in 20 of 358 (6%) families with PD. In 1 family, 1 sib was heterozygous for the mutation and another was homozygous; the homozygous individual did not differ in clinical presentation from the sib and did not have early disease onset or more rapid progression. By sequencing the LRRK2 gene in multiplex families showing linkage to the PARK8 region, Kachergus et al. (2005) identified the G2019S mutation. The families in which the mutation was found originated from the United States, Norway, Ireland, and Poland. In patients with idiopathic Parkinson disease from the same population, further screening identified 6 more patients with the LRRK2 G2019S mutation; no mutations were found in matched control individuals. Subsequently, 42 family members of the 13 probands were examined; 22 had an LRRK2 G2019S substitution, 7 with a diagnosis of PD. All patients shared an ancestral haplotype indicative of a common founder, and, within families, LRRK2 G2019S segregated with disease (multipoint lod score 2.41). Penetrance was age dependent, increasing from 17% at age 50 to 85% at age 70 years. Hernandez et al. (2005) identified the G2019S mutation in affected members of 2 unrelated families with PARK8. One family was North American with English ancestry, and the other family was of Ashkenazi Jewish origin and had migrated from Russia. Lesage et al. (2005) identified a common haplotype containing the G2019S mutation in PD patients from several European countries (France, Belgium, Portugal, and the Netherlands) and from 3 countries in North Africa (Algeria, Morocco, and Tunisia). The minimal common region spans approximately 60 kb within the LRRK2 gene, although many patients shared larger regions. Lesage et al. (2005) estimated that the G2019S mutation occurred approximately 725 years ago, in the 13th century. Aasly et al. (2005) identified the G2019S mutation in 9 Norwegian patients from 7 families with PARK8. Eleven unaffected first-degree relatives also carried the mutation, suggesting age-related penetrance. The clinical features of affected members were typical for idiopathic Parkinson disease, including resting tremor, bradykinesia, and rigidity. Deng et al. (2005) identified the G2019S mutation in 4 (1.2%) of 326 Parkinson disease patients from North America. One of the patients had no family history of the disorder. Albrecht (2005) stated that the gly2019 residue is part of a highly conserved DFG-like motif (DYG in LRRK2) at the N terminus of the kinase activation segment of the protein. As residues in and around the DFG-like motif are important for proper positioning of magnesium and phosphates, mutations in this area may impair kinase activity. West et al. (2005) determined that the G2019S mutation, which lies within the mixed-lineage kinase-like domain, did not alter the steady-state level, turnover, or intracellular localization of the LRRK2 protein, but that G2019S appeared to enhance protein kinase activity. Brice (2005) estimated that the G2019S mutation in exon 41 of the LRRK2 gene accounts for 2 to 6% of familial and 1 to 2% of sporadic cases of Parkinson disease. The mutation is less common in Asian populations but prevalent in patients from North Africa, as observed by Lesage et al. (2006). In a newly ascertained series of North African Arabs, 23 of 59 patients with Parkinson disease were carriers of the G2019S mutation (39%), as compared with only 2 of 69 controls (3%; P less than 0.001). Ozelius et al. (2006) observed that the G2019S mutation appeared to be an important cause of both familial and sporadic Parkinson disease in a group of 120 unrelated Ashkenazi Jewish patients with Parkinson disease. The prevalence of the G2019S mutation among this group reached 29.7% in familial cases and 13.3% in sporadic cases. Lesage et al. (2005) identified the G2019S mutation in 7 (41%) of 17 North African PD families and 5 (2.9%) of 174 European PD families. One patient from Algeria was homozygous for the mutation, likely due to consanguinity. His age at onset was 56 years, similar to that of heterozygotes, suggesting that gene dosage had no effect. The G2019S mutation was also identified in 1 of 256 control individuals, a 60-year-old male of European descent with no family history of the PD. Age-dependent penetrance, estimated within 2 large affected families, increased from 33% at age 55 to 100% at older than age 76. Zabetian et al. (2006) did not identify the G2019S mutation in any of 754 patients with Alzheimer disease (AD; 104300), suggesting that it is not a cause of AD. Zabetian et al. (2006) stated that the G2019S mutation accounts for 1 to 7% of Parkinson disease in patients of European origin and 20 to 40% in Ashkenazi Jews and North African Arabs with PD. Previous studies had concluded that patients from these populations share a common Middle Eastern founder who lived in the 13th century. Zabetian et al. (2006) tested this hypothesis by genotyping 25 microsatellite and single-nucleotide polymorphism (SNP) markers in 22 families with G2019S and observed 2 distinct haplotypes. Haplotype 1 was present in 19 families of Ashkenazi Jewish and European ancestry, whereas haplotype 2 occurred in 3 European American families. Using a maximum likelihood method, the authors estimated that the families with haplotype 1 shared a common ancestor 2,250 (95% confidence interval 1,650-3,120) years ago, whereas those with haplotype 2 appeared to share a more recent founder. Their data suggested 2 separate founding events for G2019S in these populations, beginning at a time that coincided with the Jewish Diasporas. Zabetian et al. (2006) identified the G2019S mutation in Japanese patients with Parkinson disease on a haplotype background clearly distinct from the 2 others, which indicated that at least 3 founding events had occurred. Ishihara et al. (2006) found no observable phenotypic differences between 26 patients with Parkinson disease who were homozygous for the G2019S mutation, including 20 patients of Tunisian origin, and reports of patients who were heterozygous for the mutation. In addition, 3 clinically unaffected Tunisian individuals were homozygous for the mutation at ages 42, 45, and 70 years. The findings did not support a gene dosage effect. Among 302 PD patients from the Catalonia region of northeast Spain, Gaig et al. (2006) identified the G2019S mutation in 6.4% of familial and 3.4% of sporadic cases. Spanaki et al. (2006) identified the G2019S mutation in 1 (1.1%) of 92 familial PD probands on the island of Crete, thus showing a decreased frequency of the mutation compared to other Mediterranean regions. Clark et al. (2006) identified the G2019S mutation in 4.9% of 245 PD patients with onset before age 50 years and 6.2% of 259 PD patients with onset after age 50 years, a nonsignificant difference. All patients with the G2019S mutation had the same 45-kb disease-associated haplotype. The frequency of the mutation was higher in the subset of 181 cases reporting 4 Jewish grandparents (9.9%) compared to other cases (3.1%). Age-specific penetrance to age 80 was 24%, suggesting that other factors must be involved. The G2019S mutation was identified in 2 (0.6%) controls of Jewish origin who showed mild signs suggestive of the disorder on further examination. Lesage et al. (2007) identified the G2019S mutation in 6 (1.9%) of 320 European patients with sporadic PD. Five patients were of French origin. In a study of 19 Italian PD families with the G2019S mutation, Goldwurm et al. (2007) estimated the cumulative incidence of the disease to be 15% at 60 years, 21% at 70 years, and 32% at 80 years, confirming reduced penetrance. Among 33 mutation carriers, 5 over age 75 years had no sign of disease. Orr-Urtreger et al. (2007) identified a heterozygous G2019S mutation in 12.3% of 472 Jewish PD patients, and in 14.8% of the 344 patients in this group who were specifically of Ashkenazi Jewish origin. The mutation was also detected in 2.4% of Ashkenazi Jewish controls. A common shared haplotype identified by Lesage et al. (2005) was found in 97% of mutation carriers. None of 42 Jewish patients from Iraq or Morocco carried the G2019S mutation. Choi et al. (2008) did not identify the G2019S mutation among 72 unrelated Korean patients with early-onset PD before age 50, suggesting that it is not a common cause of PD in the Korean population. Lesage et al. (2008) identified the G2019S mutation in 7 (41%) of 17 North African patients with familial PD and 40 (34%) of 119 North African patients with sporadic PD. All were heterozygous for the mutation except 3 patients, who were homozygous. One (1.5%) of 66 Algerian controls was homozygous for the mutation, but showed no evidence of disease at age 41 years, which is younger than the average age of disease onset. Gorostidi et al. (2009) identified a heterozygous G2019S mutation in 3.82% of 418 PD patients from the Basque country in Spain. The frequency increased to 6% when only those who were not of Basque origin were considered. The R1441G mutation (609007.0001) was more common among those of Basque descent. The findings reinforced the importance of ethnicity when establishing mutation prevalence. Bar-Shira et al. (2009) analyzed LRRK2 haplotypes in 77 G2019S carriers, mostly Ashkenazi Jews, and in 50 noncarrier Ashkenazi PD patients. A single 243-kb haplotype was detected in all mutation carriers, indicating a common founder. The authors estimated that Ashkenazi Jews with G2019S share a common ancestor who lived approximately 1,830 years ago, around the 2nd century, after the second Jewish Diaspora. Alcalay et al. (2009) found that 34 (3.7%) of 925 patients with early-onset PD, defined as age at onset before age 51 years, carried the G2019S mutation. Compared to noncarriers, carriers of the G2019S mutation were more likely to be of Ashkenazi Jewish descent (55.9% vs 11.9%), to have a lower tremor score (p = 0.03), and to have a higher score of postural instability and gait difficulty (PIGD; 92.3% vs 58.9%, p = 0.003). The PIGD phenotype in general is associated with a more severe phenotype and a faster rate of cognitive decline compared to the tremor dominant phenotype, so the findings of this study suggested implications for disease course in G2019S mutation carriers. Mortiboys et al. (2010) found that skin fibroblasts from 5 PD patients with the G2019S mutation showed evidence of mitochondrial dysfunction, both decreased membrane potential and decreased total intracellular ATP levels. There also appeared to be increased mitochondrial elongation and interconnectivity. Liu et al. (2012) reported on the generation of induced pluripotent stem cells (iPSCs) derived from Parkinson disease patients and the implications of the LRRK2 G2019S mutation in human neural stem cell populations. Mutant neural stem cells showed increased susceptibility to proteasomal stress as well as passage-dependent deficiencies in nuclear envelope organization, clonal expansion, and neuronal differentiation. Disease phenotypes were rescued by targeted correction of the LRRK2 G2019S mutation with its wildtype counterpart in Parkinson disease iPSCs and were recapitulated after targeted knockin of the LRRK2 G2019S mutation in human embryonic stem cells. Analysis of human brain tissue showed nuclear envelope impairment in clinically diagnosed Parkinson disease patients. Liu et al. (2012) concluded that their results identified the nucleus as a previously unknown cellular organelle in Parkinson disease pathology. (less)
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Pathogenic
(-)
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no assertion criteria provided
Method: clinical testing
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not provided
Affected status: yes
Allele origin:
germline
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Genome Diagnostics Laboratory, Amsterdam University Medical Center
Study: VKGL Data-share Consensus
Accession: SCV001808299.1 First in ClinVar: Aug 25, 2021 Last updated: Aug 25, 2021 |
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Pathogenic
(-)
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no assertion criteria provided
Method: clinical testing
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not provided
Affected status: yes
Allele origin:
germline
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Clinical Genetics DNA and cytogenetics Diagnostics Lab, Erasmus MC, Erasmus Medical Center
Additional submitter:
Diagnostic Laboratory, Department of Genetics, University Medical Center Groningen
Study: VKGL Data-share Consensus
Accession: SCV001964680.1 First in ClinVar: Oct 07, 2021 Last updated: Oct 07, 2021 |
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Pathogenic
(Sep 04, 2024)
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no assertion criteria provided
Method: clinical testing
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LRRK2-related condition
Affected status: unknown
Allele origin:
germline
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PreventionGenetics, part of Exact Sciences
Accession: SCV004112443.3
First in ClinVar: Nov 20, 2023 Last updated: Oct 08, 2024 |
Comment:
The LRRK2 c.6055G>A variant is predicted to result in the amino acid substitution p.Gly2019Ser. This variant has been found in patients with Parkinson disease and … (more)
The LRRK2 c.6055G>A variant is predicted to result in the amino acid substitution p.Gly2019Ser. This variant has been found in patients with Parkinson disease and is the most common and well-documented pathogenic variant in the LRRK2 gene (Trinh et al. 2016. PubMed ID: 27692902; Biosa et al. 2013. PubMed ID: 23241358; Bonifati et al. 2006. PubMed ID: 16835587). This variant is reported in 0.84% of alleles in individuals of Ashkenazi Jewish descent in gnomAD and it has been reported as a founder mutation in this population (Bar-Shira et al. 2009. PubMed ID: 19283415). Functional studies showed that this variant activated kinase activity, enlarged lysosomes and diminished the lysosomal capacity (Jaleel et al. 2007. PubMed ID: 17447891; West et al. 2007. PubMed ID: 17200152; Henry et al. 2015. PubMed ID: 26251043). This variant is interpreted as pathogenic. (less)
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not provided
(-)
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no classification provided
Method: literature only
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Autosomal dominant Parkinson disease 8
Affected status: not provided
Allele origin:
unknown
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GeneReviews
Accession: SCV000056154.2
First in ClinVar: Apr 04, 2013 Last updated: Oct 01, 2022 |
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Comment:
Comment:
This variant was determined to be pathogenic according to ACMG Guidelines, 2015 [PMID:25741868].
Comment:
Variant summary: LRRK2 c.6055G>A (p.Gly2019Ser) results in a non-conservative amino acid change located in the Protein kinase domain (IPR000719) of the encoded protein sequence. Five of five in-silico tools predict a damaging effect of the variant on protein function. The variant allele was found at a frequency of 0.00053 in 251154 control chromosomes in the gnomAD database, including 1 homozygote. This frequency is not significantly higher than expected for a pathogenic variant in LRRK2 causing Parkinson Disease 8, Autosomal Dominant, allowing no conclusion about variant significance. c.6055G>A has been widely reported in the literature in multiple individuals affected with Parkinson Disease 8, Autosomal Dominant as a common founder mutation associated with age dependent penetrance among European populations (example, Kachergus_2005) and this association continues to be subsequently acknowledged and cited by others. These data indicate that the variant is very likely to be associated with disease. At least one publication reports experimental evidence evaluating an impact on protein function (example, Greggio_2006). The most pronounced variant effect results in increased tendency to form inclusion bodies. Secondly, neurons and neuronal cell lines undergo cell death after expression of mutant protein. Multiple clinical diagnostic laboratories have submitted clinical-significance assessments for this variant to ClinVar after 2014 without evidence for independent evaluation. All submitters classified the variant as pathogenic. Based on the evidence outlined above, the variant was classified as pathogenic.
Comment:
The G2019S variant is the most common pathogenic substitution in the LRRK2 gene (Lunati et al., 2018); Individuals who are heterozygous for the G2019S variant have more than a 20-fold increase in risk for developing Parkinson disease (Dachsel et al., 2010); Lysosomal dysfunction plays a central role in the pathogenesis of Parkinson disease, and published functional studies have shown that expression of G2019S produces enlarged lysosomes and alters their function (Henry et al., 2015); In silico analysis, which includes protein predictors and evolutionary conservation, supports a deleterious effect; This variant is associated with the following publications: (PMID: 24211199, 19397894, 22080837, 21362567, 15726496, 29357897, 29248340, 30528841, 22736029, 23241358, 23396536, 20232069, 21280089, 20008657, 22914360, 21961647, 20642453, 17447891, 21686713, 22539006, 22773119, 23357204, 23472874, 21658387, 24729340, 19072560, 24652679, 21699405, 17200152, 21972245, 24470158, 21850687, 23227859, 19302196, 22004453, 20626563, 20881132, 25401981, 25330418, 22194196, 17210620, 21885347, 24488318, 24357540, 20818610, 22488887, 21696411, 21883375, 20671708, 23075850, 20096956, 16750377, 24148854, 18675914, 23747310, 25107341, 17095157, 19283415, 21753159, 22323743, 22914834, 25008396, 21494637, 23082216, 21390248, 21799870, 24082139, 22689969, 23764467, 18752982, 19945904, 20933457, 21641848, 22575234, 25434972, 23241745, 25000966, 26251043, 20457952, 18986508, 27692902, 27383589, 27423549, 27393345, 24360742, 24243757, 25962553, 23664753, 26159606, 26282470, 28862745, 29309488, 29800472, 30245141, 30709905, 3066573, 30146349, 16333314, 28487191, 28723952, 16102999, 16001413, 28639421, 18644660, 24123150, 19741132, 30172844, 16966501, 17060589, 29795570, 17116211, 24282027, 30665703, 31077434, 31324919, 31813996, 31605779, 31980526, 32875616, 26600626, 32398759, 33281709, 32353202, 18201824, 33084218, 15852371, 31589614)
Comment:
The LRRK2 c.6055G>A (p.Gly2019Ser) missense variant is the most common variant reported in individuals with LRRK2-related Parkinson disease (PD) (Saunders-Pullman et al. 2006). Across a selection of available literature, the p.Gly2019Ser variant has been identified in a heterozygous state in 131 individuals and in a homozygous state in two individuals with Parkinson disease (Kachergus et al. 2005; Nichols et al. 2005; Bar-Shira et al. 2009). The p.Gly2019Ser variant was absent from 3487 healthy matched controls in these studies and is reported at a frequency of 0.008396 in the Ashkenazi Jewish population of the Genome Aggregation Database (version 2.1.1). Analysis showed that carriers of the p.Gly2019Ser variant, who were of Ashkenazi Jewish descent, shared a 243 kb haplotype, suggesting a common founder in this population (Bar-Shira et al. 2009). The variant is also noted to exist as a founder variant in North African Berbers (Saunders-Pullman et al. 2006). The p.Gly2019Ser variant is associated with reduced penetrance; penetrance for heterozygotes is age dependent, and varies in different populations ranging from 25% - 42% up to age 80 (Saunders-Pullman et al. 2006). Generally clinical features are indistinguishable between individuals with LRRK2-related PD compared to idiopathic PD. However, studies have shown the p.Gly2019Ser variant results in a slightly milder clinical course than seen in individuals with Parkinson disease (Saunders-Pullman et al. 2006). Mitochondrial dysfunction and lysosomal dysfunction play central roles in PD pathophysiology. Functional studies showed increased mitochondrial DNA damage in iPSC-derived neural cells from patients carrying the p.Gly2019Ser variant than in cells from healthy controls. In patient cells in which the p.Gly2019Ser variant was repaired with zinc finger nuclease, reduced mitochondrial DNA damage was observed at levels seen in healthy control cells (Sanders et al. 2014). The p.Gly2019Ser variant has also been demonstrated to result in enlarged lysosomes, impaired lysosomal function, and increased kinase activity (Henry et al. 2015). Based on the collective evidence, the p.Gly2019Ser variant is classified as pathogenic for LRRK2-related Parkinson disease.
Comment:
The variant is observed at an allele frequency greater than expected for the associated disorder in the gnomAD v2.1.1 dataset. Missense changes are a common disease-causing mechanism. In silico tool predictions suggest damaging effect of the variant on gene or gene product (REVEL: 0.97; 3Cnet: 0.95). Same nucleotide change resulting in same amino acid change has been previously reported as pathogenic/likely pathogenic with strong evidence (ClinVar ID: VCV000001940). Therefore, this variant is classified as likely pathogenic according to the recommendation of ACMG/AMP guideline.
Comment:
This variant is statistically more frequent in affected individuals than in the general population and/or healthy controls (Genome Aggregation Database (gnomAD), Cambridge, MA (URL: http://gnomad.broadinstitute.org)). This variant is reported to exhibit age-dependent penetrance that may be impacted by ethnicity (PMID: 26062626, 25330418, 18986508). This variant appears to be associated with disease in multiple families (PMID: 16240353, 16533964). According to published literature, there is no reported difference in clinical presentation between individuals with this variant in the heterozygous or homozygous state (PMID: 16966502). Assessment of experimental evidence suggests this variant results in abnormal protein function. Studies have shown expression of this variant results in increased kinase activity, dysregulation of lysosomal homeostasis, and age-dependent and kinase-dependent neurodegeneration (PMID: 29402177, 29386392, 26251043, 23472874).
Comment:
This sequence change replaces glycine, which is neutral and non-polar, with serine, which is neutral and polar, at codon 2019 of the LRRK2 protein (p.Gly2019Ser). This variant is present in population databases (rs34637584, gnomAD 0.9%), and has an allele count higher than expected for a pathogenic variant. This missense change has been observed in individual(s) with Parkinson’s disease (PD) and is one of the most common known genetic causes of PD. This variant has been reported to have a reduced penetrance of 25-42.5% in various populations (PMID: 15680455, 15726496, 18986508, 22575234, 26062626, 28639421). It has also been observed to segregate with disease in related individuals. ClinVar contains an entry for this variant (Variation ID: 1940). Advanced modeling of protein sequence and biophysical properties (such as structural, functional, and spatial information, amino acid conservation, physicochemical variation, residue mobility, and thermodynamic stability) performed at Invitae indicates that this missense variant is not expected to disrupt LRRK2 protein function with a negative predictive value of 80%. Experimental studies have shown that this missense change affects LRRK2 function (PMID: 26251043). For these reasons, this variant has been classified as Pathogenic.
Comment:
This sequence change in LRRK2 is predicted to replace glycine with serine at codon 2019, p.(Gly2019Ser). The glycine residue is highly conserved (100 vertebrates, UCSC), and is located in the protein kinase domain There is a small physicochemical difference between glycine and serine. The highest population minor allele frequency in gnomAD v2.1 is 0.8% (87/10,362 alleles, 1 homozygote) in the Ashkenazi Jewish population, while the highest continental population minor allele frequency is 0.03% (33/128,908 alleles) in the European (non-Finnish) population. This is the most commonly reported pathogenic variant in LRRK2 and is associated with a risk of Parkinson disease (PD) at an estimated age-related penetrance of between 25-42.5% (PMID: 20301387, 28639421). The prevalence of the variant in affected individuals is significantly increased compared with the prevalence in controls (odds ratio 14.98, 95% CI:10.68-21.02) (PMID: 22575234). The variant has been reported to segregate with PD in multiple families (PMID: 15726496 ). A transgenic mouse model for the variant recapitulates the human PD phenotype and brain histopathology (PMID: 22539006). Multiple lines of computational evidence predict a deleterious effect for the missense substitution (6/6 algorithms). Based on the classification scheme RMH Modified ACMG Guidelines v1.5.1, this variant is classified as PATHOGENIC. Following criteria are met: PS3, PP1_Strong, PS4_Moderate, PP3.
Comment:
The c.6055G>A (p.G2019S) alteration is located in exon 41 (coding exon 41) of the LRRK2 gene. This alteration results from a G to A substitution at nucleotide position 6055, causing the glycine (G) at amino acid position 2019 to be replaced by a serine (S). Based on data from gnomAD, the A allele has an overall frequency of 0.05% (138/282542) total alleles studied. The highest observed frequency was 0.84% (87/10362) of Ashkenazi Jewish alleles. The p.G2019S alteration is the most common disease-causing LRRK2 alteration (Saunders-Pullman, 2019). This amino acid position is highly conserved in available vertebrate species. Functional analysis demonstrated that compared to the wild-type, the p.G2019S alteration significantly increased the phosphorylation of peroxiredoxin 3 (PRDX3), a mitochondrial member of the antioxidant family of thioredoxin peroxidases. Increased PRDX3 phosphorylation was associated with inhibited PRDX3 peroxidase activity and increased death in LRRK2-expressing but not in LRRK2-depleted or vector-transfected neuronal cells (Angeles, 2011). This alteration is predicted to be deleterious by in silico analysis. Based on the available evidence, this alteration is classified as pathogenic.
Comment:
The LRRK2 c.6055G>A (p.Gly2019Ser) variant is reported as one of the most common alleles in individuals affected with Parkinson’s disease and segregates with disease in families (Saunders-Pullman R et al., PMID: 20301387). The highest population minor allele frequency in the population database genome aggregation database (v.2.1.1) is 0.84% in Ashkenazi Jewish population. Functional studies show increased mitochondrial DNA damage, increased phosphorylation of alpha synuclein, dysregulation of lysosomal function, and kinase-dependent neurodegeneration (Henry G et al., PMID: 26251043; Qing H et al., PMID: 19576176; Sanders LH et al., PMID: 24148854; Vermilyea SC et al., PMID: 29402177), indicating that this variant impacts protein function. This variant resides within a region, amino acids 1879-2138, of LRRK2 that is defined as a critical functional domain (Vermilyea SC et al., PMID: 29402177). Computational predictors indicate that the variant is damaging, evidence that correlates with impact to LRRK2 function. This variant has been reported in the ClinVar database as a pathogenic variant in Parkinson’s disease by 18 submitters, likely pathogenic by one submitter and a risk factor by one submitter. Based on available information and the ACMG/AMP guidelines for variant interpretation (Richards S et al., PMID: 25741868), this variant is classified as pathogenic.
Comment:
LRRK2: PS4, PM1, PP1, PP3, PP4, PS3:Supporting
Comment:
The LRRK2 c.6055G>A variant is predicted to result in the amino acid substitution p.Gly2019Ser. This variant has been found in patients with Parkinson disease and is the most common and well-documented pathogenic variant in the LRRK2 gene (Trinh et al. 2016. PubMed ID: 27692902; Biosa et al. 2013. PubMed ID: 23241358; Bonifati et al. 2006. PubMed ID: 16835587). This variant is reported in 0.84% of alleles in individuals of Ashkenazi Jewish descent in gnomAD and it has been reported as a founder mutation in this population (Bar-Shira et al. 2009. PubMed ID: 19283415). Functional studies showed that this variant activated kinase activity, enlarged lysosomes and diminished the lysosomal capacity (Jaleel et al. 2007. PubMed ID: 17447891; West et al. 2007. PubMed ID: 17200152; Henry et al. 2015. PubMed ID: 26251043). This variant is interpreted as pathogenic.
Germline Functional Evidence
| There is no functional evidence in ClinVar for this variation. If you have generated functional data for this variation, please consider submitting that data to ClinVar. |
Comment:
LRRK2 c.6055G>A (p.Gly2019Ser) has been associated with increased risk for Parkinson's disease. This variant has been observed in multiple ethnic backgrounds with highest frequencies in individuals of Ashkenazi Jewish ancestry (0.86%, Genome Aggregation Database (gnomAD); rs6025) and is present in ClinVar (ID: 1940). A large meta-analysis has reported an odds ratio of 14.98 [95% CI 4.8-10] for developing Parkinson's disease (Wu 2012). In vivo and in vitro functional studies provide some evidence that the p.Gly2019Ser variant may impact protein function (Chen 2012). Therefore, this variant is not expected to cause highly penetrant Mendelian disease. In summary, this variant is an established risk factor for Parkinson's disease.
Comment:
This variant was determined to be pathogenic according to ACMG Guidelines, 2015 [PMID:25741868].
Comment:
Variant summary: LRRK2 c.6055G>A (p.Gly2019Ser) results in a non-conservative amino acid change located in the Protein kinase domain (IPR000719) of the encoded protein sequence. Five of five in-silico tools predict a damaging effect of the variant on protein function. The variant allele was found at a frequency of 0.00053 in 251154 control chromosomes in the gnomAD database, including 1 homozygote. This frequency is not significantly higher than expected for a pathogenic variant in LRRK2 causing Parkinson Disease 8, Autosomal Dominant, allowing no conclusion about variant significance. c.6055G>A has been widely reported in the literature in multiple individuals affected with Parkinson Disease 8, Autosomal Dominant as a common founder mutation associated with age dependent penetrance among European populations (example, Kachergus_2005) and this association continues to be subsequently acknowledged and cited by others. These data indicate that the variant is very likely to be associated with disease. At least one publication reports experimental evidence evaluating an impact on protein function (example, Greggio_2006). The most pronounced variant effect results in increased tendency to form inclusion bodies. Secondly, neurons and neuronal cell lines undergo cell death after expression of mutant protein. Multiple clinical diagnostic laboratories have submitted clinical-significance assessments for this variant to ClinVar after 2014 without evidence for independent evaluation. All submitters classified the variant as pathogenic. Based on the evidence outlined above, the variant was classified as pathogenic.
Comment:
The G2019S variant is the most common pathogenic substitution in the LRRK2 gene (Lunati et al., 2018); Individuals who are heterozygous for the G2019S variant have more than a 20-fold increase in risk for developing Parkinson disease (Dachsel et al., 2010); Lysosomal dysfunction plays a central role in the pathogenesis of Parkinson disease, and published functional studies have shown that expression of G2019S produces enlarged lysosomes and alters their function (Henry et al., 2015); In silico analysis, which includes protein predictors and evolutionary conservation, supports a deleterious effect; This variant is associated with the following publications: (PMID: 24211199, 19397894, 22080837, 21362567, 15726496, 29357897, 29248340, 30528841, 22736029, 23241358, 23396536, 20232069, 21280089, 20008657, 22914360, 21961647, 20642453, 17447891, 21686713, 22539006, 22773119, 23357204, 23472874, 21658387, 24729340, 19072560, 24652679, 21699405, 17200152, 21972245, 24470158, 21850687, 23227859, 19302196, 22004453, 20626563, 20881132, 25401981, 25330418, 22194196, 17210620, 21885347, 24488318, 24357540, 20818610, 22488887, 21696411, 21883375, 20671708, 23075850, 20096956, 16750377, 24148854, 18675914, 23747310, 25107341, 17095157, 19283415, 21753159, 22323743, 22914834, 25008396, 21494637, 23082216, 21390248, 21799870, 24082139, 22689969, 23764467, 18752982, 19945904, 20933457, 21641848, 22575234, 25434972, 23241745, 25000966, 26251043, 20457952, 18986508, 27692902, 27383589, 27423549, 27393345, 24360742, 24243757, 25962553, 23664753, 26159606, 26282470, 28862745, 29309488, 29800472, 30245141, 30709905, 3066573, 30146349, 16333314, 28487191, 28723952, 16102999, 16001413, 28639421, 18644660, 24123150, 19741132, 30172844, 16966501, 17060589, 29795570, 17116211, 24282027, 30665703, 31077434, 31324919, 31813996, 31605779, 31980526, 32875616, 26600626, 32398759, 33281709, 32353202, 18201824, 33084218, 15852371, 31589614)
Comment:
The LRRK2 c.6055G>A (p.Gly2019Ser) missense variant is the most common variant reported in individuals with LRRK2-related Parkinson disease (PD) (Saunders-Pullman et al. 2006). Across a selection of available literature, the p.Gly2019Ser variant has been identified in a heterozygous state in 131 individuals and in a homozygous state in two individuals with Parkinson disease (Kachergus et al. 2005; Nichols et al. 2005; Bar-Shira et al. 2009). The p.Gly2019Ser variant was absent from 3487 healthy matched controls in these studies and is reported at a frequency of 0.008396 in the Ashkenazi Jewish population of the Genome Aggregation Database (version 2.1.1). Analysis showed that carriers of the p.Gly2019Ser variant, who were of Ashkenazi Jewish descent, shared a 243 kb haplotype, suggesting a common founder in this population (Bar-Shira et al. 2009). The variant is also noted to exist as a founder variant in North African Berbers (Saunders-Pullman et al. 2006). The p.Gly2019Ser variant is associated with reduced penetrance; penetrance for heterozygotes is age dependent, and varies in different populations ranging from 25% - 42% up to age 80 (Saunders-Pullman et al. 2006). Generally clinical features are indistinguishable between individuals with LRRK2-related PD compared to idiopathic PD. However, studies have shown the p.Gly2019Ser variant results in a slightly milder clinical course than seen in individuals with Parkinson disease (Saunders-Pullman et al. 2006). Mitochondrial dysfunction and lysosomal dysfunction play central roles in PD pathophysiology. Functional studies showed increased mitochondrial DNA damage in iPSC-derived neural cells from patients carrying the p.Gly2019Ser variant than in cells from healthy controls. In patient cells in which the p.Gly2019Ser variant was repaired with zinc finger nuclease, reduced mitochondrial DNA damage was observed at levels seen in healthy control cells (Sanders et al. 2014). The p.Gly2019Ser variant has also been demonstrated to result in enlarged lysosomes, impaired lysosomal function, and increased kinase activity (Henry et al. 2015). Based on the collective evidence, the p.Gly2019Ser variant is classified as pathogenic for LRRK2-related Parkinson disease.
Comment:
The variant is observed at an allele frequency greater than expected for the associated disorder in the gnomAD v2.1.1 dataset. Missense changes are a common disease-causing mechanism. In silico tool predictions suggest damaging effect of the variant on gene or gene product (REVEL: 0.97; 3Cnet: 0.95). Same nucleotide change resulting in same amino acid change has been previously reported as pathogenic/likely pathogenic with strong evidence (ClinVar ID: VCV000001940). Therefore, this variant is classified as likely pathogenic according to the recommendation of ACMG/AMP guideline.
Comment:
This variant is statistically more frequent in affected individuals than in the general population and/or healthy controls (Genome Aggregation Database (gnomAD), Cambridge, MA (URL: http://gnomad.broadinstitute.org)). This variant is reported to exhibit age-dependent penetrance that may be impacted by ethnicity (PMID: 26062626, 25330418, 18986508). This variant appears to be associated with disease in multiple families (PMID: 16240353, 16533964). According to published literature, there is no reported difference in clinical presentation between individuals with this variant in the heterozygous or homozygous state (PMID: 16966502). Assessment of experimental evidence suggests this variant results in abnormal protein function. Studies have shown expression of this variant results in increased kinase activity, dysregulation of lysosomal homeostasis, and age-dependent and kinase-dependent neurodegeneration (PMID: 29402177, 29386392, 26251043, 23472874).
Comment:
This sequence change replaces glycine, which is neutral and non-polar, with serine, which is neutral and polar, at codon 2019 of the LRRK2 protein (p.Gly2019Ser). This variant is present in population databases (rs34637584, gnomAD 0.9%), and has an allele count higher than expected for a pathogenic variant. This missense change has been observed in individual(s) with Parkinson’s disease (PD) and is one of the most common known genetic causes of PD. This variant has been reported to have a reduced penetrance of 25-42.5% in various populations (PMID: 15680455, 15726496, 18986508, 22575234, 26062626, 28639421). It has also been observed to segregate with disease in related individuals. ClinVar contains an entry for this variant (Variation ID: 1940). Advanced modeling of protein sequence and biophysical properties (such as structural, functional, and spatial information, amino acid conservation, physicochemical variation, residue mobility, and thermodynamic stability) performed at Invitae indicates that this missense variant is not expected to disrupt LRRK2 protein function with a negative predictive value of 80%. Experimental studies have shown that this missense change affects LRRK2 function (PMID: 26251043). For these reasons, this variant has been classified as Pathogenic.
Comment:
This sequence change in LRRK2 is predicted to replace glycine with serine at codon 2019, p.(Gly2019Ser). The glycine residue is highly conserved (100 vertebrates, UCSC), and is located in the protein kinase domain There is a small physicochemical difference between glycine and serine. The highest population minor allele frequency in gnomAD v2.1 is 0.8% (87/10,362 alleles, 1 homozygote) in the Ashkenazi Jewish population, while the highest continental population minor allele frequency is 0.03% (33/128,908 alleles) in the European (non-Finnish) population. This is the most commonly reported pathogenic variant in LRRK2 and is associated with a risk of Parkinson disease (PD) at an estimated age-related penetrance of between 25-42.5% (PMID: 20301387, 28639421). The prevalence of the variant in affected individuals is significantly increased compared with the prevalence in controls (odds ratio 14.98, 95% CI:10.68-21.02) (PMID: 22575234). The variant has been reported to segregate with PD in multiple families (PMID: 15726496 ). A transgenic mouse model for the variant recapitulates the human PD phenotype and brain histopathology (PMID: 22539006). Multiple lines of computational evidence predict a deleterious effect for the missense substitution (6/6 algorithms). Based on the classification scheme RMH Modified ACMG Guidelines v1.5.1, this variant is classified as PATHOGENIC. Following criteria are met: PS3, PP1_Strong, PS4_Moderate, PP3.
Comment:
The c.6055G>A (p.G2019S) alteration is located in exon 41 (coding exon 41) of the LRRK2 gene. This alteration results from a G to A substitution at nucleotide position 6055, causing the glycine (G) at amino acid position 2019 to be replaced by a serine (S). Based on data from gnomAD, the A allele has an overall frequency of 0.05% (138/282542) total alleles studied. The highest observed frequency was 0.84% (87/10362) of Ashkenazi Jewish alleles. The p.G2019S alteration is the most common disease-causing LRRK2 alteration (Saunders-Pullman, 2019). This amino acid position is highly conserved in available vertebrate species. Functional analysis demonstrated that compared to the wild-type, the p.G2019S alteration significantly increased the phosphorylation of peroxiredoxin 3 (PRDX3), a mitochondrial member of the antioxidant family of thioredoxin peroxidases. Increased PRDX3 phosphorylation was associated with inhibited PRDX3 peroxidase activity and increased death in LRRK2-expressing but not in LRRK2-depleted or vector-transfected neuronal cells (Angeles, 2011). This alteration is predicted to be deleterious by in silico analysis. Based on the available evidence, this alteration is classified as pathogenic.
Comment:
The LRRK2 c.6055G>A (p.Gly2019Ser) variant is reported as one of the most common alleles in individuals affected with Parkinson’s disease and segregates with disease in families (Saunders-Pullman R et al., PMID: 20301387). The highest population minor allele frequency in the population database genome aggregation database (v.2.1.1) is 0.84% in Ashkenazi Jewish population. Functional studies show increased mitochondrial DNA damage, increased phosphorylation of alpha synuclein, dysregulation of lysosomal function, and kinase-dependent neurodegeneration (Henry G et al., PMID: 26251043; Qing H et al., PMID: 19576176; Sanders LH et al., PMID: 24148854; Vermilyea SC et al., PMID: 29402177), indicating that this variant impacts protein function. This variant resides within a region, amino acids 1879-2138, of LRRK2 that is defined as a critical functional domain (Vermilyea SC et al., PMID: 29402177). Computational predictors indicate that the variant is damaging, evidence that correlates with impact to LRRK2 function. This variant has been reported in the ClinVar database as a pathogenic variant in Parkinson’s disease by 18 submitters, likely pathogenic by one submitter and a risk factor by one submitter. Based on available information and the ACMG/AMP guidelines for variant interpretation (Richards S et al., PMID: 25741868), this variant is classified as pathogenic.
Comment:
LRRK2: PS4, PM1, PP1, PP3, PP4, PS3:Supporting
Comment:
The LRRK2 c.6055G>A variant is predicted to result in the amino acid substitution p.Gly2019Ser. This variant has been found in patients with Parkinson disease and is the most common and well-documented pathogenic variant in the LRRK2 gene (Trinh et al. 2016. PubMed ID: 27692902; Biosa et al. 2013. PubMed ID: 23241358; Bonifati et al. 2006. PubMed ID: 16835587). This variant is reported in 0.84% of alleles in individuals of Ashkenazi Jewish descent in gnomAD and it has been reported as a founder mutation in this population (Bar-Shira et al. 2009. PubMed ID: 19283415). Functional studies showed that this variant activated kinase activity, enlarged lysosomes and diminished the lysosomal capacity (Jaleel et al. 2007. PubMed ID: 17447891; West et al. 2007. PubMed ID: 17200152; Henry et al. 2015. PubMed ID: 26251043). This variant is interpreted as pathogenic.
Citations for germline classification of this variant
Help| Title | Author | Journal | Year | Link |
|---|---|---|---|---|
| LRRK2 Parkinson Disease. | Adam MP | - | 2023 | PMID: 20301387 |
| In Vitro Modeling of Leucine-Rich Repeat Kinase 2 G2019S-Mediated Parkinson's Disease Pathology. | Vermilyea SC | Stem cells and development | 2018 | PMID: 29402177 |
| Robust kinase- and age-dependent dopaminergic and norepinephrine neurodegeneration in LRRK2 G2019S transgenic mice. | Xiong Y | Proceedings of the National Academy of Sciences of the United States of America | 2018 | PMID: 29386392 |
| Penetrance estimate of LRRK2 p.G2019S mutation in individuals of non-Ashkenazi Jewish ancestry. | Lee AJ | Movement disorders : official journal of the Movement Disorder Society | 2017 | PMID: 28639421 |
| LRRK2 G2019S Mutation: Prevalence and Clinical Features in Moroccans with Parkinson's Disease. | Bouhouche A | Parkinson's disease | 2017 | PMID: 28465860 |
| Pathogenic LRRK2 mutations, through increased kinase activity, produce enlarged lysosomes with reduced degradative capacity and increase ATP13A2 expression. | Henry AG | Human molecular genetics | 2015 | PMID: 26251043 |
| Age-specific penetrance of LRRK2 G2019S in the Michael J. Fox Ashkenazi Jewish LRRK2 Consortium. | Marder K | Neurology | 2015 | PMID: 26062626 |
| Disease penetrance of late-onset parkinsonism: a meta-analysis. | Trinh J | JAMA neurology | 2014 | PMID: 25330418 |
| LRRK2 mutations cause mitochondrial DNA damage in iPSC-derived neural cells from Parkinson's disease patients: reversal by gene correction. | Sanders LH | Neurobiology of disease | 2014 | PMID: 24148854 |
| Parkinson disease phenotype in Ashkenazi Jews with and without LRRK2 G2019S mutations. | Alcalay RN | Movement disorders : official journal of the Movement Disorder Society | 2013 | PMID: 24243757 |
| Genetic correction of a LRRK2 mutation in human iPSCs links parkinsonian neurodegeneration to ERK-dependent changes in gene expression. | Reinhardt P | Cell stem cell | 2013 | PMID: 23472874 |
| Progressive degeneration of human neural stem cells caused by pathogenic LRRK2. | Liu GH | Nature | 2012 | PMID: 23075850 |
| Quantitative assessment of the effect of LRRK2 exonic variants on the risk of Parkinson's disease: a meta-analysis. | Wu X | Parkinsonism & related disorders | 2012 | PMID: 22575234 |
| (G2019S) LRRK2 activates MKK4-JNK pathway and causes degeneration of SN dopaminergic neurons in a transgenic mouse model of PD. | Chen CY | Cell death and differentiation | 2012 | PMID: 22539006 |
| Mutations in LRRK2 increase phosphorylation of peroxiredoxin 3 exacerbating oxidative stress-induced neuronal death. | Angeles DC | Human mutation | 2011 | PMID: 21850687 |
| Phenotype in parkinsonian and nonparkinsonian LRRK2 G2019S mutation carriers. | Marras C | Neurology | 2011 | PMID: 21753163 |
| Gait alterations in healthy carriers of the LRRK2 G2019S mutation. | Mirelman A | Annals of neurology | 2011 | PMID: 21280089 |
| Mitochondrial impairment in patients with Parkinson disease with the G2019S mutation in LRRK2. | Mortiboys H | Neurology | 2010 | PMID: 21115957 |
| Parkinson's disease-related LRRK2 G2019S mutation results from independent mutational events in humans. | Lesage S | Human molecular genetics | 2010 | PMID: 20197411 |
| Motor phenotype of LRRK2 G2019S carriers in early-onset Parkinson disease. | Alcalay RN | Archives of neurology | 2009 | PMID: 20008657 |
| Ashkenazi Parkinson's disease patients with the LRRK2 G2019S mutation share a common founder dating from the second to fifth centuries. | Bar-Shira A | Neurogenetics | 2009 | PMID: 19283415 |
| LRRK2 G2019S and R1441G mutations associated with Parkinson's disease are common in the Basque Country, but relative prevalence is determined by ethnicity. | Gorostidi A | Neurogenetics | 2009 | PMID: 19020907 |
| The Gly2019Ser mutation in LRRK2 is not fully penetrant in familial Parkinson's disease: the GenePD study. | Latourelle JC | BMC medicine | 2008 | PMID: 18986508 |
| Is the common LRRK2 G2019S mutation related to dyskinesias in North African Parkinson disease? | Lesage S | Neurology | 2008 | PMID: 18981379 |
| Analysis of PARK genes in a Korean cohort of early-onset Parkinson disease. | Choi JM | Neurogenetics | 2008 | PMID: 18704525 |
| LRRK2 Gly2019Ser penetrance in Arab-Berber patients from Tunisia: a case-control genetic study. | Hulihan MM | The Lancet. Neurology | 2008 | PMID: 18539535 |
| Phenotype, genotype, and worldwide genetic penetrance of LRRK2-associated Parkinson's disease: a case-control study. | Healy DG | The Lancet. Neurology | 2008 | PMID: 18539534 |
| The LRRK2 G2019S mutation in Ashkenazi Jews with Parkinson disease: is there a gender effect? | Orr-Urtreger A | Neurology | 2007 | PMID: 17938369 |
| LRRK2 exon 41 mutations in sporadic Parkinson disease in Europeans. | Lesage S | Archives of neurology | 2007 | PMID: 17353388 |
| Evaluation of LRRK2 G2019S penetrance: relevance for genetic counseling in Parkinson disease. | Goldwurm S | Neurology | 2007 | PMID: 17215492 |
| LRRK2 mutations on Crete: R1441H associated with PD evolving to PSP. | Spanaki C | Neurology | 2006 | PMID: 17060595 |
| Frequency of LRRK2 mutations in early- and late-onset Parkinson disease. | Clark LN | Neurology | 2006 | PMID: 17050822 |
| Clinical features of Parkinson disease patients with homozygous leucine-rich repeat kinase 2 G2019S mutations. | Ishihara L | Archives of neurology | 2006 | PMID: 16966502 |
| Clinical heterogeneity of the LRRK2 G2019S mutation. | Papapetropoulos S | Archives of neurology | 2006 | PMID: 16966501 |
| LRRK2 G2019S in families with Parkinson disease who originated from Europe and the Middle East: evidence of two distinct founding events beginning two millennia ago. | Zabetian CP | American journal of human genetics | 2006 | PMID: 16960813 |
| Kinase activity is required for the toxic effects of mutant LRRK2/dardarin. | Greggio E | Neurobiology of disease | 2006 | PMID: 16750377 |
| Identification and haplotype analysis of LRRK2 G2019S in Japanese patients with Parkinson disease. | Zabetian CP | Neurology | 2006 | PMID: 16728648 |
| LRRK2 mutations in Spanish patients with Parkinson disease: frequency, clinical features, and incomplete penetrance. | Gaig C | Archives of neurology | 2006 | PMID: 16533964 |
| LRRK2 G2019S as a cause of Parkinson's disease in Ashkenazi Jews. | Ozelius LJ | The New England journal of medicine | 2006 | PMID: 16436782 |
| LRRK2 G2019S as a cause of Parkinson's disease in North African Arabs. | Lesage S | The New England journal of medicine | 2006 | PMID: 16436781 |
| Analysis of the LRRK2 G2019S mutation in Alzheimer Disease. | Zabetian CP | Archives of neurology | 2006 | PMID: 16401756 |
| Genetics of Parkinson's disease: LRRK2 on the rise. | Brice A | Brain : a journal of neurology | 2005 | PMID: 16311269 |
| Parkinson's disease-associated mutations in leucine-rich repeat kinase 2 augment kinase activity. | West AB | Proceedings of the National Academy of Sciences of the United States of America | 2005 | PMID: 16269541 |
| G2019S LRRK2 mutation in French and North African families with Parkinson's disease. | Lesage S | Annals of neurology | 2005 | PMID: 16240353 |
| Lrrk2 pathogenic substitutions in Parkinson's disease. | Mata IF | Neurogenetics | 2005 | PMID: 16172858 |
| LRRK2 gene in Parkinson disease: mutation analysis and case control association study. | Paisán-Ruíz C | Neurology | 2005 | PMID: 16157901 |
| LRRK2 haplotype analyses in European and North African families with Parkinson disease: a common founder for the G2019S mutation dating from the 13th century. | Lesage S | American journal of human genetics | 2005 | PMID: 16145815 |
| Analysis of LRRK 2 G 2019 S and I 2020 T mutations in Parkinson's disease. | Bialecka M | Neuroscience letters | 2005 | PMID: 16115731 |
| Clinical traits of LRRK2-associated Parkinson's disease in Ireland: a link between familial and idiopathic PD. | Gosal D | Parkinsonism & related disorders | 2005 | PMID: 16102999 |
| Escaping Parkinson's disease: a neurologically healthy octogenarian with the LRRK2 G2019S mutation. | Kay DM | Movement disorders : official journal of the Movement Disorder Society | 2005 | PMID: 16001413 |
| The G2019S LRRK2 mutation is uncommon in an Asian cohort of Parkinson's disease patients. | Tan EK | Neuroscience letters | 2005 | PMID: 15955629 |
| Genetic and clinical identification of Parkinson's disease patients with LRRK2 G2019S mutation. | Deng H | Annals of neurology | 2005 | PMID: 15929036 |
| Clinical features of LRRK2-associated Parkinson's disease in central Norway. | Aasly JO | Annals of neurology | 2005 | PMID: 15852371 |
| LRRK2 mutations and Parkinsonism. | Albrecht M | Lancet (London, England) | 2005 | PMID: 15811455 |
| Clinical and positron emission tomography of Parkinson's disease caused by LRRK2. | Hernandez DG | Annals of neurology | 2005 | PMID: 15732108 |
| Identification of a novel LRRK2 mutation linked to autosomal dominant parkinsonism: evidence of a common founder across European populations. | Kachergus J | American journal of human genetics | 2005 | PMID: 15726496 |
| A common LRRK2 mutation in idiopathic Parkinson's disease. | Gilks WP | Lancet (London, England) | 2005 | PMID: 15680457 |
| A frequent LRRK2 gene mutation associated with autosomal dominant Parkinson's disease. | Di Fonzo A | Lancet (London, England) | 2005 | PMID: 15680456 |
| Genetic screening for a single common LRRK2 mutation in familial Parkinson's disease. | Nichols WC | Lancet (London, England) | 2005 | PMID: 15680455 |
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Text-mined citations for rs34637584 ...
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Record last updated Nov 03, 2024
This date represents the last time this VCV record was updated. The update may be due to an update to one of the included submitted records (SCVs), or due to an update that ClinVar made to the variant such as adding HGVS expressions or a rs number. So this date may be different from the date of the “most recent submission” reported at the top of this page.