Introduction

Pertuzumab (brand name, Perjeta) is a monoclonal antibody used in the treatment of breast cancer. Pertuzumab was designed to target an epidermal growth factor receptor encoded by the ERBB2 gene, commonly referred to as the HER2 gene.

The ERBB2 gene is overexpressed in 15–20% of breast cancers and is also overexpressed in some cases of other cancer types (gastric, colon, head, and neck). Historically, “HER2-positive” tumors are associated with a faster rate of growth and a poorer prognosis than other breast cancer subtypes. The use of pertuzumab in treatment regimens improves outcomes, with limited adverse effects that include cardiac toxicity.

Pertuzumab is used with other drugs as an advanced breast cancer treatment, a neoadjuvant treatment, and an adjuvant treatment for HER2-positive breast cancer. In the advanced/metastatic setting, pertuzumab added to trastuzumab and a taxane is used to increase long-term progression-free and overall survival when administered in the first line setting. As neoadjuvant treatment, pertuzumab is given with trastuzumab and chemotherapy before surgery in individuals with early breast cancer to increase pathologic complete response rates. And as an adjuvant treatment, pertuzumab is given with trastuzumab and chemotherapy to reduce the risk of cancer reoccurrence in individuals with early breast cancer (Table 1).

The 2020 FDA-approved drug label states that pertuzumab should only be used to treat individuals with tumors that have either HER2 protein overexpression or ERBB2 gene amplification, as determined by an accurate and validated FDA-approved assay. This is because these are the only individuals studied for whom benefit has been shown (1).

The most recent update (2018) American Society of Clinical Oncology (ASCO) / College of American Pathologists (CAP) guidelines continue to state that all newly diagnosed individuals with breast cancer must have an HER2 test performed. Individuals who then develop metastatic disease must have an HER2 test performed in a metastatic site, if a tissue sample is available (2).

Drug Class: HER2 Inhibitors

Human epidermal growth factor receptor 2 (commonly referred to as HER2 or HER-2/neu) is encoded by the gene ERBB2, which is a transmembrane receptor tyrosine kinase. Overexpression of ERBB2 leads to rapid cell growth in multiple types of solid tumors. The HER2 can be inactivated by a class of chemicals known as tyrosine kinase inhibitors or via targeted monoclonal antibodies. An increasing number of HER2-targeted therapies have been approved to treat HER2-positive breast cancer, including:

• Pertuzumab –– monoclonal antibody (brand name Perjeta)
• Trastuzumab –– monoclonal antibody (brand name Herceptin)
• Ado-trastuzumab emtansine –– antibody-drug-conjugate (monoclonal antibody attached to a chemotherapy drug (brand name Kadcyla, also called TDM-1)
• Fam-trastuzumab deruxtecan –– antibody-drug-conjugate (brand name Enhertu)
• Neratinib –– a kinase inhibitor (brand name Nerlynx)
• Lapatinib –– a kinase inhibitor (brand name Tykerb)
• Tucatinib –– a kinase inhibitor (brand name Tukysa)
• Dacomitinib –– a kinase inhibitor (brand name Vizimpro)

There are more anti-HER2 drugs progressing through clinical trials, and some trials are looking at whether HER2-targeted therapies could be used to treat other tumors that overexpress HER2, such as colorectal and non-small-cell lung cancer. However, early results are not replicating the success of HER2-targeted therapies in breast and gastric cancer (3, 4, 5). One exception is the use of trastuzumab, which has been approved for use in HER2-positive metastatic gastric cancer (6).

Drug: Pertuzumab

Pertuzumab is a monoclonal antibody that targets HER2 (a tyrosine kinase receptor, encoded by the ERBB2 gene). Pertuzumab is only used to treat specific tumors that overexpress or are amplified for ERBB2, which are known as “HER2-positive” tumors.

In 2012, the FDA approved the use of pertuzumab in the treatment of HER2-positive metastatic breast cancer to increase the chance of long-term disease-free survival. Pertuzumab is used with trastuzumab (another monoclonal antibody that targets ERBB2) and docetaxel (a chemotherapy drug) to treat individuals who have not previously had anti-HER2 therapy or chemotherapy for HER2-positive metastatic breast cancer.

In 2013, the FDA granted an accelerated approval to pertuzumab, again with trastuzumab and docetaxel, as a neoadjuvant treatment of HER2-positive breast cancer. In the neoadjuvant setting, pertuzumab is given before surgical therapy in women with HER2-positive breast cancer that is locally advanced, inflammatory, or at an early stage (either greater than 2 cm in diameter or lymph node positive) (1, 7, 8, 9). In 2017, the FDA approved pertuzumab for use with trastuzumab and chemotherapy as an adjuvant treatment for individuals with HER2-positive early breast cancer with a high risk of recurrence, to reduce the risk of recurrence (10, 11).

Before treatment with pertuzumab begins, overexpression of the HER-2 protein or amplification of the ERBB2 gene must first be determined. In clinical studies of pertuzumab, individuals with breast cancer were required to have evidence of HER2 overexpression defined as 3+ immunohistochemistry (IHC) or fluorescence in situ hybridization (FISH) amplification ratio of 2 or greater (see Tumor Testing for ERBB2 (HER2)).

The FDA recommends that testing be performed using an FDA-approved test, in a laboratory with demonstrated proficiency with the technology being used. This is because the benefits of pertuzumab have only been proven in individuals with HER2 positive tumors (12).

In addition, although pertuzumab is well tolerated, the risks of treatment include infusion reactions, diarrhea, and cardiomyopathy that can result in cardiac failure. The mechanism of how anti-HER2 drugs such as pertuzumab can cause cardiotoxicity is not known, but evidence from mouse models suggests HER2 signaling plays a key role in heart development and cardiomyocyte survival during stress (reviewed by (13). Additional evidence suggests that using cardiac drugs, such as beta blockers and ace inhibitors, may help prevent subsequent cardiomyopathy. Data on the safety of anti-HER2 drugs in older individuals, who are most likely to take these drugs, are lacking, having been mostly derived from subgroup analysis of larger trials (14, 15, 16).

The pregnancy status of women of child-bearing age should be checked, and women should be warned that exposure to pertuzumab during pregnancy, or within 7 months before conception, can result in fetal harm and potentially, fetal death. Therefore, women should use effective contraception for 7 months following their last dose of pertuzumab (1).

Pertuzumab targets the HER2 receptor by binding to a specific region in its extracellular domain. The HER2 receptor is an epidermal growth factor receptor, consisting of an intracellular tyrosine kinase domain, a single transmembrane spanning region, and an extracellular domain, made up of 4 subdomains (I–IV). Pertuzumab binds to subdomain II and trastuzumab binds to subdomain IV. This binding limits the receptor’s ability to activate its intrinsic kinase, which in turn, limits the activation of numerous signaling pathways that can promote cell growth.

A number of proposed mechanisms may underlie the anti-tumor effects of pertuzumab and trastuzumab. One such mechanism is that these drugs block the HER3 receptor from binding to HER2. The HER2-HER3 dimerized receptor is thought to be highly active, triggering many signaling cascades in the absence of a “true” ligand (17, 18, 19, 20).

Another proposed mechanism is antibody-dependent cellular cytotoxicity. Once pertuzumab or trastuzumab have bound to a cancer cell, immune cells (typically activated natural killer cells) bind to the drug and initiate lysis of the cancer cell (21).

Unfortunately, breast cancer may start to progress again during HER2 targeted therapy. Mechanisms that may facilitate drug resistance and disease progression during treatment include increased signaling from the HER family of receptors, an upregulation of downstream signaling pathways, and an increased level of insulin growth factor-1 receptor (22, 23). In the instance of metastatic disease, ASCO practice guidelines suggest obtaining a tissue sample from the metastatic site to confirm HER2-status in case of relapse after curative treatment (24).

As a new drug, there is not enough data on the risk of developing resistance to pertuzumab therapy. However, there is a lower response rate to pertuzumab among individuals previously treated with trastuzumab. Resistance is particularly problematic because pertuzumab is now being used earlier, to treat of early-stage disease (25, 26).

Gene: ERBB2 (HER2)

The human epidermal growth factor receptor (HER) protein family consists of 4 members: the epidermal growth factor receptor (EGFR), ERBB2 (HER2), ERBB3 (HER3), and ERBB4 (HER4) (see Nomenclature for Selected Genes). All 4 members are transmembrane tyrosine kinase receptors, and they regulate a number of important cellular processes, such as cell growth, survival, and differentiation (27).

The ERBB2 gene, along with EGFR, are proto-oncogenes. Proto-oncogenes are a group of genes that, when mutated or expressed at abnormally high levels, can contribute to abnormal cell growth. The mutated version of the proto-oncogene is called an oncogene. Proto-oncogenes typically encode proteins that stimulate cell division, inhibit cell differentiation, and halt cell death. All these are important biological processes. However, the increased production of these proteins, caused by oncogenes, can lead to the proliferation of poorly differentiated cancer cells (28).

The official gene symbol for HER2 is ERBB2, which is derived from a viral oncogene with which the receptor shares homology; “v-erb-b2 avian erythroblastic leukemia viral oncogene homolog 2.” However, clinicians commonly refer to the ERBB2 gene as “HER2” (Human Epidermal growth factor Receptor 2) or “HER2/neu” (neu was the name given to the gene that caused cancer derived from a rodent neuro/glioblastoma). It is the legacy gene symbol for ERBB2 and may be more commonly used by the community in clinical care, it is also commonly used to describe the protein encoded by the ERBB2 gene.

One unique feature of HER2 compared with the other receptors in the HER family is the absence of a known ligand. This receptor may permanently be in an activated state, or it may become activated during heterodimerization with one of the other members of the HER family (29). Additionally, one unique feature of HER3 is that it has little enzymatic activity compared with the other tyrosine kinase receptors in the HER family. An important role of HER3 is to act as a heterodimerization partner for HER2 (30, 31).

When a partner such as HER3 binds to HER2, the heterodimer undergoes activation, which stimulates the intrinsic tyrosine kinase activity of the receptor. Autophosphorylation of several key residues of the receptor triggers the downstream activation of many commonly used growth factor signaling pathways, such as the PI3K/AKT/mTOR pathway and the RAS/RAF/MEK/ERK pathway (17, 32). Impaired HER2 signaling is associated with the development of neurodegenerative diseases, such as multiple sclerosis and Alzheimer disease, while excessive HER2 signaling is associated with the development of cancers.

The ERBB2 gene is overexpressed in approximately 15–20% of breast tumors, as a result of amplification of the ERBB2 gene, and tumors with increased HER2 typically have a higher growth rate and more aggressive clinical behavior (33, 34, 35, 36). Although gene amplification is frequently seen in cancer and other degenerative disorders, the underlying basis for amplification remains largely unknown (37). In the case of ERBB2, although sequence variants have been identified, it is most commonly a wildtype ERBB2 gene copy that is overexpressed in tumors (23). In approximately 1% of breast cancers, activating variants in ERBB2 can be identified that are likely to drive tumorigenesis, without ERBB2 amplification (38).

Genes: ESR1 and PR

The ESR1 gene encodes the estrogen receptor, and the PR gene encodes the progesterone receptor. Breast cancer cells may have:

• a receptor for estrogen (ER-positive)
• a receptor for progesterone (PR-positive)
• receptors for both estrogen and progesterone (hormone receptor positive)
• nether receptor (hormone receptor negative)
• or receptors for both hormones and HER2 overexpression (triple positive).

Endocrine (hormone) therapy is typically indicated for hormone receptor positive tumors. Some evidence suggests that HER2 status influences the response of hormone receptor positive tumors to endocrine therapy. In one study, individuals with ER-positive tumors and low-level ERBB2 amplification (as defined by quantitative FISH) had significantly less benefit from adjuvant anti-HER2 therapy after chemotherapy (39). However, ASCO guidelines clearly state that HER2 status should not be used to withhold endocrine therapy for an individual with a hormone receptor-positive breast cancer, nor to select one specific type of endocrine therapy over another (40).

The drug label discuses 2 trials that included analyses of how hormone receptor status influenced the response of HER2-positive tumors to pertuzumab. The NeoSphere clinical trial (NCT00545688) reported that individuals with hormone receptor-positive tumors responded less well to pertuzumab therapy compared with individuals with hormone receptor-negative tumors. The CLEOPATRA clinical trial (NCT00567190) reported that individuals with hormone receptor–positive disease had a higher hazard ratio than individuals with hormone receptor-negative disease. (1, 41, 42) Furthermore, in the interim overall survival analysis of the APHINITY clinical trial (NCT01358877), a treatment benefit of pertuzumab was seen in the node positive, hormone receptor positive cohort (invasive disease-free survival hazard ratio for HR positive is 0.73 [95% confidence interval 0.59–0.92]). Subgroup analysis of the APHINITY trial further suggests that ER-negative individuals benefit more from dual blockade with trastuzumab and pertuzumab. (43) Early results from another study (NCT02564900) suggest that trastuzumab deruxtecan may be effective as an anti-HER2 therapy in HER2-low expressing (HER2 “negative” scores of 1+ or 2+ by standard IHC testing) tumors (44).

Linking Gene Overexpression with Treatment Response

The HER2 overexpression or amplification is strongly linked to a beneficial treatment response to pertuzumab. This is to be expected, given that pertuzumab was developed to target HER2. Consequently, current guidelines for breast cancer treatment limit the use of HER2-blocking agents to tumors with HER2 gene amplification (2, 35, 36).

Genetic Testing

The NIH Genetic Testing Registry (GTR) displays genetic tests that are available for the ERBB2 gene and the pertuzumab drug response.

Therapeutic Recommendations based on Genotype

This section contains excerpted¹ information on gene-based dosing recommendations. Neither this section nor other parts of this review contain the complete recommendations from the sources.

Nomenclature for Selected Genes Associated with Pertuzumab Response

Acknowledgments

The authors would like to thank Noam Pondé, MD, Medical Oncologist, Clinical Oncology Department, A.C. Camargo Cancer Center, São Paulo, Brazil and Sarah Sammons, MD, Assistant Professor of Medicine, Multidisciplinary Breast Program, Duke Cancer Institute, Duke University, Durham, NC, USA for reviewing this summary.

Reviewers for 2015 edition:

The author would like to thank Professor Andreas Schneeweiss, Head of Division Gynecologic Oncology, National Center for Tumor Diseases, Heidelberg University Hospital, Heidelberg, Germany; and Jo Anne Zujewski, Head of Breast Cancer Therapeutics, Clinical Investigation Branch, Cancer Therapy Evaluation Program, Division of Cancer Treatment and Diagnosis, National Cancer Institute, National Institutes of Health, Bethesda, MD, USA; for reviewing this summary.

Version History

An earlier version of this Summary (published September 10^th, 2015) may be viewed here.

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