Analysis of the Clinical Advancements for BRCA-Related Malignancies Highlights the Lack of Treatment Evidence for BRCA-Positive Male Breast Cancer
Abstract
:Simple Summary
Abstract
1. Introduction
2. The Genetic Landscape of MBC
2.1. BRCA1 and BRCA2
2.2. Moderate to Low Penetrance Germline Mutations
3. Clinical Management of BRCA-Related MBC
4. BRCA-Related MBC Studies
5. BRCA Mutations in Transgender Patients
6. Clinical Trial Led Advancements in Other BRCA-Related Cancers
6.1. Female Breast Cancer (FBC)
6.2. Prostate Cancer
7. Future Directions in BRCA-Related MBC
7.1. National Registry and Combining Efforts
7.2. Translational Research
8. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Author (Year) | Study Population | No. of Patients | Study Objective |
---|---|---|---|
Tirkkonen et al. (1999) [94] | MBC patients | 25 | Somatic genetic alterations in BRCA2-associated and sporadic MBC |
BRCA2-mutated | 5 | ||
Basham et al. (2002) [75] | MBC patients | 94 | BRCA1/2-mutation status and risk of breast cancer in female relatives |
BRCA1-mutated | 0 | ||
BRCA2-mutated | 5 | ||
Ottini et al. (2003) [48] | MBC patients | 25 | The Characterisation of BRCA1 and BRCA2 MBC |
BRCA1-mutated | 1 | ||
BRCA2-mutated | 3 | ||
Kwiatkowska et al. (2003) [76] | MBC patients | 43 | Investigation of the prognostic value of BRCA2 status in MBC |
BRCA2-mutated | 12 | ||
Palli et al. (2007) [93] | MBC patients | 99 | The association between the BRCA2 N732H variant and MBC risk |
Ottini et al. (2009) [49] | MBC patients | 108 | Characterisation the clinic-pathological features of BRCA1/2- positive MBC |
BRCA1-mutated | 2 | ||
BRCA2-mutated | 8 | ||
Ding et al. (2011) [78] | MBC patients | 115 | To determine the frequency of pathogenic mutations in BRCA2 and PALB2 in MBC cases and to investigate the correlations between mutation status and cancer phenotype |
BRCA2-mutated | 18 | ||
Ottini et al. (2012) [50] | MBC patients | 382 | Investigation of the clinical–pathologic features of MBC in association with BRCA mutations |
BRCA1-mutated | 4 | ||
BRCA2-mutated | 6 | ||
de Juan et al. (2015) [92] | MBC patients | 312 | BRCA1/2 mutations in males with familial breast and ovarian cancer syndrome |
BRCA1-mutated | 20 | ||
BRCA2-mutated | 49 | ||
Gargiulo et al. (2016) [53] | MBC patients | 47 | Characterisation of MBC, including BRCA1/2-mutated patients, and the impact on long-term survival |
BRCA1-mutated | 1 | ||
BRCA2-mutated | 5 | ||
Silvestri et al. (2016) [74] | MBC patients | 366 * | To determine if BRCA1/2 mutation carriers display specific pathologic features and if these differ from FBCs |
BRCA1-mutated | 40 | ||
BRCA2-mutated | 326 | ||
Deb et al. (2017) [90] | MBC patients | 60 | Investigation of a panel of commonly methylated breast cancer genes in familial MBCs |
BRCA1-mutated | 3 | ||
BRCA2-mutated | 25 | ||
Rizzolo et al. (2018) [77] | MBC patients | 69 | Gene-specific methylation profiles in BRCA-mutation positive and negative MBC |
BRCA1-mutated | 2 | ||
BRCA2-mutated | 8 | ||
Ibrahim et al. (2018) [18] | MBC patients | 102 | Evaluation of clinical characteristics, pathology findings, treatment selection and survival in BRCA-positive males |
BRCA1-mutated | 0 | ||
BRCA2-mutated | 9 | ||
André et al. (2019) [52] | MBC patients | 196 | Specific biological characteristics and survival in MBC |
BRCA1-mutated | 0 | ||
BRCA2-mutated | 13 | ||
Vietri et al. (2020) [72] | MBC patients | 28 | Characterisation of BRCA1/BRCA2 and PALB2 mutations in MBC patients |
BRCA1-mutated | 2 | ||
BRCA2-mutated | 8 |
Author (Year) | Study Population | No. of Patients | Study Objective |
---|---|---|---|
Savelyeva et al. (1998) [84] | BRCA2-mutated MBC | 3 | Case report describing three brothers with BRCA2 mutation, two of which developed infiltrating ductal breast cancer |
Scheidbach et al. (2000) [87] | BRCA2-mutated MBC | 1 | Describe a case of BRCA2-mutation positive MBC |
Kwiatkowska et al. (2002) [89] | BRCA2-mutated MBC | 2 | Novel BRCA2 mutation (frameshift mutation 6621del4 in exon 11) in two male breast cancer cases (father and son) in a Polish family. |
Brenner et al. (2004) [86] | BRCA2-mutated MBC | 1 | Highlight a case of BRCA2-mutation positive MBC and the implications for screening |
Karamanakos et al. (2004) [83] | BRCA1-mutated MBC | 1 | A case of male breast adenocarcinoma in a prostate cancer patient following prolonged anti-androgen monotherapy |
Azzouzi et al. (2007) [88] | BRCA2-mutated MBC | 3 | To highlight three BRCA2-positive MBC patients who were identified following positive prostate cancer screening |
Panchal et al. (2009) [85] | BRCA2-mutated MBC | 1 | A case of BRCA2-mutation positive MBC case with a history of prostate cancer |
Guaoua et al. (2014) [82] | BRCA2-mutated MBC | 1 | An account of a novel BRCA2c.6428C>A p.Ser2143Ter nonsense mutation in a man with familial breast cancer |
Benjamin & Riker (2015) [73] | BRCA1/HER2-positive MBC | 1 | To describe a case of a BRCA1/HER2 positive MBC |
Singer et al. (2015) [80] | BRCA2-mutated MBC | 1 | Highlight the risk of BRCA2 on multiple cancer risk through a case of prostate and MBC. |
Saha et al. (2017) [81] | BRCA1-mutated MBC | 1 | Describe the treatment of MBC by dual HER2 blockade and response prediction using novel optical tomography imaging. |
Cheng et al. (2019) [79] | BRCA2-mutated MBC | 1 | To describe an account of metachronous MBC that progressed following radio and chemotherapy which responded to palbociclib, fulvestrant and leuprolide. |
Huszno et al. (2019) [91] | BRCA2-mutated MBC | 1 | Clinicopathological analysis of BRCA2 gene variant, c. 2808_2811delACAA (p. Ala938Profs) in MBC |
Phase III Trial (Year) | Trial Arms | Study Population | No. of Patients | Study Result | ||
---|---|---|---|---|---|---|
PARPi (F/M) | PFS HR (95%CI) | mPFS (Months) | ORR (%) | |||
Advanced breast cancer | ||||||
OlympiAD (2017) [38] | Olaparib vs. standard chemotherapy | Patients with <2 lines of previous chemotherapy | 205 (200/5) | 0.58 (0.43–0.80); p < 0.001 | 7.0 vs. 4.2 | 59.9 vs. 28.8 |
EMBRACA (2018) [40] | Talazoparib vs. standard single agent of a clinician’s choice * | gBRCA-mutated | 287 (283/4) | 0.54 (0.41–0.71); p < 0.001 | 8.6 vs. 5.6 | 62.2 vs. 27.2 |
BROCADE (2020) [103] | Veliparib with carboplatin/paclitaxel vs. carboplatin/paclitaxel alone | gBRCA-mutated | 337 (333/4) | 0.71 (0.57–0.88); p = 0.0016 | 14.5 vs. 12.6 | |
Early breast cancer | DD or death (99.5%CI) | ID or death (99.5%CI) | ||||
OlympiA (2021) [67] | Olaparib vs. placebo | gBRCA-mutated with local treatment and neoadjuvant or adjuvant chemotherapy | 921 (919/2) | 0.57 (0.39–0.83); p < 0.001 | 0.58 (0.41–0.82); p < 0.001 |
Trial (Year) | Phase | Trial Arms | Study Population | No. of Patients | Study Result |
---|---|---|---|---|---|
PARPi | |||||
PROfound (2020) [41] | III | Olaparib versus standard anti-androgen therapy | Cohort A (BRCA1, BRCA2, or ATM mutation) | 162 | rPFS 7.4 m vs. 3.6 m; HR 0.34 (95% CI 0.25–0.47); p < 0.001 |
Cohort A+ B (Other DDR alterations *) | 256 | rPFS 5.8 m vs. 3.5 m; HR 0.49 (0.38–0.63); p < 0.001 | |||
TRITON2 (2020) [105] | II | Rucaparib | gBRCA-mutated mCRPC patients progressing after previous androgen hormonal therapy and a taxane chemotherapy | 177 | rORRa BRCA-mutated 43.5% (95% CI, 31.0–56.7) and independent investigator ORR 50.8% (95% CI 38.1–63.4) rORR a for other HRD-mutation 28.6%; CHEK2-mutation 11.1%; ATM-mutation 10.5%; CDK2-mutation 0% |
GALAHAD (2019) [106] | II | Niraparib | mCRPC and biallelic DRD mutated mCRPC patients with disease progression on taxane and androgen receptor-targeted therapy. | 81 | rORR a BRCA-mutated 41% (95% CI 23.5–61.6); rPFS 8.2 (95% CI 5.2–11.1) rORR a BRCA1/2-WT HRD-mutation 9% (95% CI 1.1–29.2); rPFS 5.3 (95% CI 1.9–5.7) |
TALAPRO-1 (2020) [107] | II | Talazoparib | BRCA- mutated mCRPC patients with disease progression on taxane and androgen receptor-targeted therapy | 46 | ORR 43.9%; rPFS 9.3 (95% CI 8.1–13.7) |
BRCA-WT mCRPC patients | 40 | ORR PALB2-mutated 33%; rPFS 7.4 (95% CI 2–7.4); ATM-mutated 11.8%; rPFS 5.5 95% CI (1.7–8.2) |
Trial | Phase | PARPi | Combined Agent |
---|---|---|---|
Anti-androgen therapy | |||
PROpel [113] | III | Olaparib | Abiraterone |
MAGNITUDE [114] | III | Niraparib | Abiraterone |
TALAPRO-2 [115] | III | Talazoparib | Enzalutamide |
Immunotherapy | |||
NCT02484404 [116] | I/II | Olaparib | Durvalumab |
ATRi | |||
NCT03787680 [119] | II | Olaparib | Ceralasertib |
High dose testosterone | |||
NCT03516812 [120] | II | Olaparib | Testosterone enanthate or cypionate |
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McClurg, D.P.; Urquhart, G.; McGoldrick, T.; Chatterji, S.; Miedzybrodzka, Z.; Speirs, V.; Elsberger, B. Analysis of the Clinical Advancements for BRCA-Related Malignancies Highlights the Lack of Treatment Evidence for BRCA-Positive Male Breast Cancer. Cancers 2022, 14, 3175. https://doi.org/10.3390/cancers14133175
McClurg DP, Urquhart G, McGoldrick T, Chatterji S, Miedzybrodzka Z, Speirs V, Elsberger B. Analysis of the Clinical Advancements for BRCA-Related Malignancies Highlights the Lack of Treatment Evidence for BRCA-Positive Male Breast Cancer. Cancers. 2022; 14(13):3175. https://doi.org/10.3390/cancers14133175
Chicago/Turabian StyleMcClurg, Dylan P., Gordan Urquhart, Trevor McGoldrick, Subarnarekha Chatterji, Zosia Miedzybrodzka, Valerie Speirs, and Beatrix Elsberger. 2022. "Analysis of the Clinical Advancements for BRCA-Related Malignancies Highlights the Lack of Treatment Evidence for BRCA-Positive Male Breast Cancer" Cancers 14, no. 13: 3175. https://doi.org/10.3390/cancers14133175
APA StyleMcClurg, D. P., Urquhart, G., McGoldrick, T., Chatterji, S., Miedzybrodzka, Z., Speirs, V., & Elsberger, B. (2022). Analysis of the Clinical Advancements for BRCA-Related Malignancies Highlights the Lack of Treatment Evidence for BRCA-Positive Male Breast Cancer. Cancers, 14(13), 3175. https://doi.org/10.3390/cancers14133175