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Breast cancer is the most common cancer worldwide and is a leading cause of cancer death in women.1 It is a heterogeneous disease with distinct molecular subtypes based on hormone receptors (HR) and human epidermal growth factor receptor 2 (HER2) status, with triple-negative cancers (absence of estrogen and progesterone hormone receptors and HER2 protein) being more aggressive. HR-positive breast cancers make up the majority of breast cancer cases (~80%) and are more likely to respond to hormone therapy.2
Recent advances in breast cancer research have uncovered many relevant and emerging biomarkers that go beyond these immunohistochemical-based biomarkers. Therefore, the use of next-generation sequencing (NGS) technologies for broad molecular profiling is necessary (Table 1). In addition, tumor-agnostic biomarkers such as NTRK1/2/3, RET, tumor mutational burden (TMB), and microsatellite instability (MSI) are becoming more relevant across tumor types regardless of tumor histology.
Table 1: Relevant and emerging biomarkers in advanced breast cancer research
| Breast cancer subtype | Breast biomarker | NGS | Other testing methods | |
| Relevant | HR+/HER2- | PIK3CA activating mutations | NGS | PCR |
| AKT1 activating mutations | NGS | PCR | ||
| PTEN inactivating mutations | NGS | PCR | ||
| ESR1 mutations | NGS | PCR | ||
| Any | Germline BRCA1/2 mutations | NGS (germline) | ||
| NTRK1/2/3 fusions | NGS | FISH, PCR | ||
| RET fusions | NGS | |||
| TMB-H (≥10 mut/Mb) | NGS | |||
| MSI-H/dMMR | NGS | IHC, PCR | ||
| Emerging | ER+/HER2-, ER-/HER2- | ERBB2 activating mutations | NGS | PCR |
| Any | Somatic BRCA1/2 mutations | NGS | ||
| FGFR1/2/3 fusions/mutations | NGS | |||
| Germline PALB2 mutations | NGS (germline) |
The PI3K/AKT/PTEN pathway is a key signaling pathway involved in cell proliferation and survival. Activating mutations in PIK3CA and AKT1 and inactivating mutations in PTEN can lead to hyperactivation of this pathway in up to 50% of HR-positive breast cancer samples. While polymerase chain reaction (PCR) can be used to evaluate alterations in single genes like PIK3CA, next-generation sequencing (NGS) would enable the simultaneous assessment of alterations in PIK3CA, AKT, PTEN, and more.
The estrogen receptor 1 (ESR1) gene encodes estrogen receptor alpha (ERα) and plays a critical role in breast cancer by regulating the cell’s response to estrogen. Mutations in ESR1 are commonly associated with resistance to endocrine therapy and are more likely found after cancer progression in HR-positive, HER2-negative breast cancers.
Since ESR1 mutations are acquired over time, repeat testing with liquid biopsy may be preferred to determine the relevant ESR1 mutations, which are typically located in the ligand-binding domain. Although both PCR and NGS can be used to assess for ESR1, NGS allows for the detection of ESR1 and other relevant biomarkers at the same time from one sample. In contrast, PCR offers a relatively simpler and faster method but may be more limited in coverage.
Breast cancer early onset gene 1 (BRCA1) and 2 (BRCA2) were initially discovered as major hereditary breast cancer susceptibility genes. BRCA1/2 are tumor suppressor genes that play an important role in double-strand break repair through the homologous recombination repair (HRR) pathway. Inherited mutations in BRCA1/2 are associated with an increased risk of breast and ovarian cancer because pathogenic germline BRCA1/2 mutation carriers generally follow a two-hit hypothesis, where the first “germline hit” followed by the second “somatic hit” drives tumorigenesis.3
A robust assay to identify pathogenic BRCA1/2 mutations, including large rearrangements, is therefore critical to gain important insights into this biomarker. NGS testing can be used to detect both somatic and germline variants in BRCA1/2, and if a mutation is detected, a subsequent germline test may be needed to determine the mutation origin.
Breast cancer molecular profiling includes various methods such as PCR, immunohistochemistry (IHC), fluorescence in situ hybridization (FISH), and NGS. However, NGS enables comprehensive evaluation of tumors for genomic alterations across hundreds of genes and for complex biomarkers or genomic signatures like TMB, MSI, and homologous recombination deficiency (HRD).
Because NGS can identify multiple biomarkers in a cost- and time-efficient manner while conserving tissue, traditional methods are gradually being replaced by high-throughput technologies, though they remain useful in certain contexts. For instance, digital PCR (dPCR) may be used to verify NGS results from the same sample or to monitor specific genes over time at lower cost than with NGS. While tissue NGS is the gold standard for gaining insights into the biology of a tumor, liquid biopsy–based NGS is emerging as a highly sensitive method to understand resistance mechanisms as a tumor evolves. Liquid biopsies are minimally invasive and may be used as an alternative when tissue samples are not available. Moreover, liquid biopsy testing may complement tissue testing to better understand inter-and intra-tumor heterogeneity.
Figure 1. NGS uses a single assay to assess for relevant and emerging biomarkers in breast cancer research.
As a single vendor of sample-to-report solutions, including instruments, consumables, analysis, and support, Thermo Fisher Scientific simplifies the implementation of in-house NGS. The breadth of Ion Torrent Oncomine assays, from focused to comprehensive panels for tissue and liquid biopsy applications, enables researchers to select the optimal solution for their needs.
Key benefits of Oncomine assays include ease of use with minimal hands-on time to improve efficiency, fast turnaround times for timely insights and decisions, and high success rates for reliable testing of more samples, including those typically considered quantity not sufficient (QNS) with other technologies.
Table 2: Oncomine assays for advanced breast cancer research testing
| Oncomine assay | Sample types | Relevant breast biomarker coverage | Emerging breast biomarker coverage | Number of genes | Recommended nucleic acid input amount | Instrument | Turnaround time** |
| Oncomine Comprehensive Assay Plus | Tissue | AKT1, PIK3CA, PTEN, ESR1, NTRK1/2/3, RET, TMB, MSI | Somatic BRCA1/2, ERBB2 mutations, FGFR1/2/3 | 517 | 20-30 ng DNA/RNA | Genexus System or GeneStudio S5 System | 1-3 days |
| Oncomine Comprehensive Assay v3 | Tissue | AKT1, PIK3CA, PTEN, ESR1, NTRK1/2/3, RET | Somatic BRCA1/2, ERBB2 mutations, FGFR1/2/3 | 161 | 20 ng DNA/RNA | Genexus System or GeneStudio S5 System | 1–3 days |
| Oncomine Precision Assay | Tissue, plasma | AKT1, PIK3CA, PTEN, ESR1, NTRK1/2/3, RET | ERBB2 mutations, FGFR1/2/3 | 50 | 10 ng DNA/RNA, 20 ng cfTNA | Genexus System | 1 day |
| Oncomine Pan-Cancer Cell-Free Assay | Plasma | AKT1, PIK3CA, PTEN, ESR1, NTRK1/3, RET | ERBB2 mutations, FGFR1/2/3 | 52 | 20 ng cfTNA* | GeneStudio S5 System | 2–3 days |
| Oncomine Breast cfDNA Assay v2 | Plasma | AKT1, PIK3CA, ESR1 | ERBB2 mutations, FGFR1 | 12 | 20 ng cfDNA* | GeneStudio S5 System | 2–3 days |
| Oncomine BRCA Assay | Tissue, blood | Germline BRCA1/2 | Somatic BRCA1/2 | 2 | 20 ng DNA | Genexus System or GeneStudio S5 System | 1–3 days |
* Input recommended to achieve 0.1% LOD, lower amounts can be used.
** Timing varies by number of samples, sample type, and instrument used.
Table 3: Oncomine assay variant coverage in PIK3CA, AKT1, PTEN, and ESR1
| Oncomine assay | Sample type | PIK3CA variants | AKT1 variants | PTEN variants | ESR1 variants |
| Oncomine Comprehensive Assay Plus | Tissue | p.(R88Q), p.(N345K), p.(C420R), p.(E542K), p.(E545A), p.(E545D), p.(E545G), p.(E545K), p.(E545Q), p.(Q546E), p.(Q546K), p.(Q546P), p.(Q546R), p.(M1043I), p.(M1043V), p.(H1047L), p.(H1047R), p.(H1047Y), p.(G1049R) |
p.(E17K) | p.(C124R), p.(C124S), p.(G129E), p.(G129V), p.(G129R), p.(R130Q), p.(R130G), p.(R130L), p.(R130P), p.(C136R), p.(C136Y), p.(S170R), p.(R173C) |
p.(E380Q), p.(V392I), p.(S463P), p.(V534E), p.(P535H), p.(P535T), p.(L536H), p.(L536P), p.(L536Q), p.(L536R), p.(Y537C), p.(Y537D), p.(Y537H), p.(Y537N), p.(Y537S), p.(D538G) |
| Oncomine Comprehensive Assay v3 | Tissue | p.(R88Q), p.(N345K), p.(C420R), p.(E542K), p.(E545A), p.(E545D), p.(E545G), p.(E545K), p.(E545Q), p.(Q546E), p.(Q546K), p.(Q546P), p.(Q546R), p.(M1043I), p.(M1043V), p.(H1047L), p.(H1047R), p.(H1047Y), p.(G1049R) |
p.(E17K) | p.(C124R), p.(C124S), p.(G129E), p.(G129V), p.(G129R), p.(R130Q), p.(R130G), p.(R130L), p.(R130P), p.(C136R), p.(C136Y), p.(S170R), p.(R173C) |
p.(E380Q), p.(V392I), p.(S463P), p.(V534E), p.(P535H), p.(P535T), p.(L536H), p.(L536P), p.(L536Q), p.(L536R), p.(Y537C), p.(Y537D), p.(Y537H), p.(Y537N), p.(Y537S), p.(D538G) |
| Oncomine Precision Assay | Tissue, plasma | p.(N345K), p.(C420R), p.(E542K), p.(E545A), p.(E545D), p.(E545G), p.(E545K), p.(E545Q), p.(Q546E), p.(Q546K), p.(Q546P), p.(Q546R), p.(M1043I), p.(M1043V), p.(H1047L), p.(H1047R), p.(H1047Y), p.(G1049R) |
p.(E17K) | p.(G129E), p.(G129V), p.(G129R), p.(R130Q), p.(R130G), p.(R130L), p.(R130P), p.(C136R), p.(C136Y), p.(S170R), p.(R173C) |
p.(E380Q), p.(V392I), p.(S463P), p.(V534E), p.(P535H), p.(P535T), p.(L536H), p.(L536P), p.(L536Q), p.(L536R), p.(Y537C), p.(Y537D), p.(Y537H), p.(Y537N), p.(Y537S), p.(D538G) |
| Oncomine Pan-Cancer Cell-Free Assay | Plasma | p.(R88Q), p.(N345K), p.(C420R), p.(E542K), p.(E545A), p.(E545D), p.(E545G), p.(E545K), p.(E545Q), p.(Q546E), p.(Q546K), p.(Q546P), p.(Q546R), p.(M1043I), p.(M1043V), p.(H1047L), p.(H1047R), p.(H1047Y), p.(G1049R) |
p.(E17K) | p.(S170R), p.(R173C) | p.(E380Q), p.(V392I), p.(S463P), p.(P535H), p.(P535T), p.(L536H), p.(L536P), p.(L536Q), p.(L536R), p.(Y537C), p.(Y537D), p.(Y537H), p.(Y537N), p.(Y537S), p.(D538G) |
| Oncomine Breast cfDNA Assay v2 | Plasma | p.(N345K), p.(C420R), p.(E542K), p.(E545A), p.(E545G), p.(E545K), p.(E545Q), p.(Q546K), p.(Q546P), p.(Q546R), p.(M1043I), p.(M1043V), p.(H1047L), p.(H1047R), p.(H1047Y), p.(G1049R) |
p.(E17K) | p.(E380Q), p.(V392I), p.(S463P), p.(P535H), p.(P535T), p.(L536H), p.(L536P), p.(L536Q), p.(L536R), p.(Y537C), p.(Y537D), p.(Y537H), p.(Y537N), p.(Y537S), p.(D538G) |
* PTEN deletions are also detected by the Oncomine Comprehensive Assay Plus and Oncomine Precision Assay.
For Research Use Only. Not for use in diagnostic procedures.
PMR-000630