HPV-Associated Breast Cancer: Myth or Fact?
Abstract
:1. Introduction
2. Mechanisms of HPV Infection Targeting Breast Tissue
Virus Entry to the Breast Cells
3. Molecular Base of HPV-Associated Breast Cancer Carcinogenesis
4. Research Analyzing the Association of HPV and Breast Cancer
4.1. HPV DNA and Breast Cancer Types
4.2. Presence of HPV DNA in BC Tissue in Correlation with Previous Cervical Dysplasia
4.3. Heterogeneity of the Research
5. Discussion
- HPV should be more prevalent in breast cancer cases than in normal samples;
- Exposure to the HPV should precede disease outcome;
- Multidisciplinary research should be conducted to replicate the association between HPV and breast cancer;
- A dose–response relationship should exist between exposure levels and the incidence of BC;
- Viral causality should be explained in terms of the mode of transmission and the natural history and pathology;
- The virus can infect and transform mammary epithelium and induce cancer in an animal model;
- The virus can induce cancer in an animal model by infecting and transforming the mammary epithelium;
- Preventing HPV infection should reduce the incidence of cervical cancer.
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Study | Method | No. of Histological Samples | HPV Positivity | HPV Types Detected |
---|---|---|---|---|
Aguayo et al., 2011 [34] | PCR, Inno-Lipa-HPV 16 | BC: 55 | 8.7% | 16 |
Frega et al., 2011 [35] | PCR, INNO-LiPA | BC: 31 Benign lesions: 12 | 29% 0% | 16, 6 |
Herrera-Goepfert et al., 2011 [36] | PCR, INNO-LiPA | BC: 69 | 24% | 16 |
Silva et al., 2011 [37] | PCR–HPV 6, 11, 16, 18 | BC: 79 | No positive results | n.a. |
Baltzell et al., 2012 [38] | IS-PCR, IHC–12 hrHPVs | BC: 70 | 2.9 % (IS-PCR) 5.7 % (ISH) | 16 |
Herrera-Romano et al., 2012 [39] | PCR | BC: 118 nipple lesions: 2 | No positive results | n.a. |
Sigaroodi et al., 2012 [40] | PCR | BC: 79 Benign lesions: 51 | 25.9% 2.4% | 16, 18, 23, 6, 11, 15, 124 |
Eslamifar et al., 2015 [41] | PCR | BC: 100 Healthy controls: 50 | No positive results | n.a. |
Fu et al., 2015 [42] | PCR and ISH–HPV 58, HPV 58 E7 DNA | BC: 169 Benign lesions: 83 | PCR/ISH–14.79%/10.06% PCR/ISH–1.2%/1.2% | 58 |
Lawson et al., 2015 [43] | IS-PCR, NGS | BC: 855 | 3.5% (lrHPV) 2.3% (hrHPV) | 18, 16, 52, 113 |
Li et al., 2015 [44] | PCR–HPV 16, 18 HPV 16 E6, E7 HPV 18 E6, E7 | BC: 187 Adjacent tissue: 187 Benign lesions: 92 | 1.6% 0% 0% | 16, 18 |
Ngan et al., 2015 [45] | HPV E7 IHC, PCR | sets of benign and subsequent BC specimens: 32 healthy controls: 20 | 72% (benign specimens) 62.5% (subsequent BC) 10% | 16, 18, 45, 58 |
Vernet-Tomas 2015 [46] | PCR, DEIA 54 mucosal HPV types | BC: 76 Benign lesions: 2 | No positive results | n.a. |
Chen et al., 2016 [47] | PCR-HPV 16, 18 oncogens E6, E7 | BC: 76 | 23.68% for HPV18 E7 6.58% for HPV18 E6 all samples negative for HPV16 E6/E7 | 18 |
Choi et al., 2016 [48] | PCR-28 hrHPVs and lrHPVs | BC: 123 Intraductal papillomas: 9 Nipple tissues: 13 | 17.9% 22.2% 0 % | 51, 53, 40 |
Doosti et al., 2016 [49] | PCR | BC: 87 benign lesions: 84 | 22.9% 0% | 16, 18, 6, 11 |
Ilahi et al., 2016 [50] | PCR–HPV 16 and 18 | BC: 46 | 17.3% | 16 |
Karimi et al., 2016 [51] | PCR–HPV 16, 18, 31, 33 | BC: 70 benign lesions: 70 | 2.6% 0% | 18 |
Wang et al.,2016 [52] | ISH for HPV DNA and mRNA (HPV 16,18,58) | BC: 146 Benign lesions: 83 | 35.6% 3.6% | 16, 18, 58 |
Bakhtiyrizadeh et al., 2017 [53] | PCR | BC: 150 Benign lesions: 150 | No positive results | n.a. |
Delgado- Garcìa et al., 2017 [7] | PCR | BC: 251 Benign lesions: 186 | 51.8% 26.3% | 16, 51, 89 as the most prevalent |
Naushad et al., 2017 [54] | PCR | BC: 250 Benign tissue: 15 | 18,1% n.a. | n.a. |
Rezaei et al., 2017 [55] | PCR, ARMS-PCR -HPV 16, 18, 31, 11, 33, 35 | BC (familial): 38 BC (non-familial): 46 | 44.73% 26.08% | 16, 18, 11 as the most prevalent |
Bønløkke et al., 2018 [56] | SPF10 PCR-DEIA-LiPA25 assay–25 hrHPV and lrHPV | BC with prior dysplasia: 93 BC without prior dysplasia: 100 | 2.1% 1.0% | 16, 56 |
Cavalcante et al., 2018 [57] | PCR–11 HPV types | BC: 103 Healthy tissue: 90 | 49.5% 15.8% | 6, 11, 18, 31, 33, 52 |
De Carolis et al., 2018 [26] | PCR–16 HPV types | Intraductal papilloma: 10 DCIS: 9 BC: 10 | 40% 11.1% 30% | 16, 18, 33, 51, 53 |
Ghaffari et al., 2018 [58] | PCR, microarray–35 hrHPV and lrHPV types | BC:72 | 5.52% | n.a. |
Habyarimana et al., 2018 [59] | PCR | BC: 47 | 46.8% | 16, 33, 31 as the most prevalent |
Malekpour Afshar et al., 2018 [60] | PCR, INNO-LiPA | BC: 98 Benign lesions: 40 | 8.2% No positive results | 16, 18 as the most prevalent |
Balci et al., 2019 [61] | PCR | BC: 18 Breast papillomas: 27 | 44.4% 29.6% | 11, 39 as the most prevalent |
De Carolis et al., 2019 [30] | CISH (HPV 16,18), PCR (16 HPV types), NGS | BC: 273 | 30.4% | 16, 18 as the most prevalent |
Biesaga et al., 2021 [62] | PCR-21 HPV types | BC: 383 | 4.4% | 16 |
Boumba et al., 2021 [63] | PCR–14 hrHPV types | BC:40 | 15% | 16 as the most prevalent |
Elagali et al., 2021 [64] | PCR | BC: 150 | 8.7% | 16, 58, 18, 11 |
Gebregzabher et al., 2021 [65] | PCR–19 hrHPVs, 9 lr HPVs | BC: 75 | 2.7% | 16, 6 |
Golrokh Mofrad et al., 2021 [66] | PCR | BC: 59 Benign lesions: 11 | 11.8% No positive results | 18, 6 |
Guo et al., 2021 [67] | CISH–HPV 6, 11, 18, 18 | BC: 90 Intraductal papillomas: 33 Healthy tissue: 33 | 21.1% (HPV 6,11), 43.3% (HPV 16, 18) 3.0% (HPV 6,11), 18.8% (HPV 16, 18) 0% (HPV 6, 11), 9.1% (HPV 16, 18) | 16, 18, 6, 11 |
Gupta et al., 2021 [68] | PCR–14 hrHPV types | TNBC: 70 Healthy tissues: 14 | 53% 37.5% | 52, 45, 31, 58, 68 |
Metwally et al., 2021 [69] | PCR | BC:40 | 17.5% | n.a. |
Nagi et al., 2021 [70] | PCR–14 hrHPV types, TMA | BC: 102 Healthy tissue: 14 | 65% 35.6% | 52, 35, 58, 45, 16 and 51 as the most prevalent |
Alinezhadi et al., 2022 [71] | PCR | BC: 63 Benign lesions: 32 | 17.89% 28.12% | 11, 16, 31, 33 |
De Oliveira et al., 2022 [32] | PCR | BC: 75 | 0% | n.a. |
Gupta et al., 2022 [72] | PCR–11 hrHPV types | BC:74 | 65% | n.a. |
Maldonado-Rodriguèz et al., 2022 [73] | PCR–32 hrHPV and lrHPV types | BC: 59 Benign lesions: 46 Healthy tissue: 11 | 20.3% 34.8% 27.3% | 42, 31, 59 as the most prevalent |
Study | Method | No. of Histological Samples | HPV Positivity | HPV Types Detected |
---|---|---|---|---|
Hachana et al., 2010 [74] | PCR, ISH–HPV 16, 18, 31, 33, 6, 11 | BC: 123 | No positive results | n.a. |
Antonsson et al., 2011 [75] | PCR–16 hrHPV types | BC: 54 Healthy controls: 4 | 50% 25% | 18 |
Hedau et al., 2011 [76] | PCR-HPV 16,18 | BC: 228 | No positive results | n.a. |
Mou et al., 2011 [77] | PCR–21 hrHPV and lrHPV types | BC: 62 Benign lesions: 46 | 6,5% No positive results | 16, 18 |
Herrera- Romano et al., 2012 [39] | PCR | BC: 10 | No positive results | n.a. |
Fernandes et al., 2015 [78] | PCR, INNO-LiPA-28 HPV types | BC: 24 | 41.7% | 51, 33, 18, 6, 11 |
Gannon et al. 2015 [79] | PCR, NGS | BC: 80 Benign lesions:10 | 16% 10% | 16, 18 |
Zhou et al., 2015 [80] | PCR | BC/DCIS: 77 Adjacent tissue: 77 | No positive results | n.a. |
Islam et al., 2017 [81] | PCR–HPV 16, 18, 33 | BC (prior NACT): 272 BC (after NACT): 41 Adjacent normal tissues: 21 Benign lesions: 17 | 63.9% 71.0% 9.5% 47.1% | 16, 18, 33 |
Ngamkham et al., 2017 [82] | PCR–14 hrHPV and 22 lrHPV types | BC: 350 Benign lesions: 350 | 4.3% 2.9% | 16, 33, 18, 35, 52 |
Salman et al., 2017 [83] | PCR-12 hrHPV types | BC:74 Benign lesions:36 | 47% 31% | 39, 18, 45 as the most prevalent |
Wang et al., 2017 [84] | HC2–13 hrHPV types | BC:81 | 17.3% | n.a. |
ElAmrani et al., 2018 [85] | PCR–62 lrHPV and hrHPV types | BC: 76 Benign lesions: 12 | 25% 8.3% | 51, 52, 58, 59, 66 as the most prevalent |
Kouloura et al., 2018 [86] | Microarray | BC: 201 Adjacent healthy tissue: 201 | No positive results | n.a. |
Khodabandehlou et al., 2019 [87] | PCR | BC: 72 Healthy tissue: 31 | 48.6% 16.1% | 16, 18, 33, 6, 11 |
Sher et al., 2020 [88] | PCR–12 hrHPV types | BC:50 Benign lesions: 100 | 10% 8% | 16, 35, 58 |
Charostad et al., 2021 [89] | PCR | BC:36 Adjacent healthy tissue: 36 | 33.3% 5.5% | 16, 18, 31, 6 |
El-Sheikh et al., 2021 [90] | PCR–HPV 16, 18, 31 | BC: 72 Benign lesions: 15 | 22.2% No positive results | 16, 18 |
Metwally et al., 2021 [69] | PCR | BC (fresh tissue): 40 | 50% | n.a. |
Calderon et al., 2022 [91] | PCR | BC: 447 Benign lesions: 79 | 2.9% 1.3% | 16, 18 |
Factors | Commentary |
---|---|
Sampling | |
Sample size | Low sample size influences the statistical power of the research [139] |
Type of analyzed samples (FFPE tissue, fresh-frozen tissue) | Formalin-induced DNA fragmentation in FFPE samples [140] |
Age of samples (especially in case of FFPE) | Significant degradation of DNA in 4–6 years of storage [141] |
Contamination | Manipulation with the sample |
Diagnostics | |
Diagnostic techniques (ISH, PCR, NGS) | It is impossible to confirm that the positive reactions are directly from mammary cells in case of PCR method [116] |
Designed PCR primers | Variable sensitivity and specificity [8] |
Viral factors | |
Viral load | Extremely low viral load causes false test negativity [73] |
Less common types of HPV undetected by PCR, etc. | Detection methods are in most cases used for the common hrHPV types |
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Kudela, E.; Kudelova, E.; Kozubík, E.; Rokos, T.; Pribulova, T.; Holubekova, V.; Biringer, K. HPV-Associated Breast Cancer: Myth or Fact? Pathogens 2022, 11, 1510. https://doi.org/10.3390/pathogens11121510
Kudela E, Kudelova E, Kozubík E, Rokos T, Pribulova T, Holubekova V, Biringer K. HPV-Associated Breast Cancer: Myth or Fact? Pathogens. 2022; 11(12):1510. https://doi.org/10.3390/pathogens11121510
Chicago/Turabian StyleKudela, Erik, Eva Kudelova, Erik Kozubík, Tomas Rokos, Terezia Pribulova, Veronika Holubekova, and Kamil Biringer. 2022. "HPV-Associated Breast Cancer: Myth or Fact?" Pathogens 11, no. 12: 1510. https://doi.org/10.3390/pathogens11121510
APA StyleKudela, E., Kudelova, E., Kozubík, E., Rokos, T., Pribulova, T., Holubekova, V., & Biringer, K. (2022). HPV-Associated Breast Cancer: Myth or Fact? Pathogens, 11(12), 1510. https://doi.org/10.3390/pathogens11121510