The Intersection of HPV Epidemiology, Genomics and Mechanistic Studies of HPV-Mediated Carcinogenesis

Mirabello, Lisa; Clarke, Megan A.; Nelson, Chase W.; Dean, Michael; Wentzensen, Nicolas; Yeager, Meredith; Cullen, Michael; Boland, Joseph F.; Schiffman, Mark; Burk, Robert D.

doi:10.3390/v10020080

Cited by 103 publications

(98 citation statements)

References 79 publications

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“…While there are no differences in E7 between A1 and D2 or D3, there are 3 amino acid differences in the E6 gene and functional studies indicate that these changes increase transforming ability (39). There are also a considerable number of amino acid differences (3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16) between A1 and D2 and D3 in other viral proteins, with the most variable E1, E2, and L1.…”

Section: Discussionmentioning

confidence: 99%

“…HPV16 can be classified into four evolutionary-defined lineages (A, B, C, D), and 16 sublineages (A1-4, B1-4, C1-4, D1-4) (11), that vary in geographic distribution and disease risks (12)(13)(14)(15). HPV16 sublineages differ by 0.5-1% of the viral genome, and the A4, D2 and D3 sublineages are associated with 9-28-fold higher risk of cancer and 10-130-fold risk of adenocarcinoma (15).…”

Section: Introductionmentioning

confidence: 99%

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Human papillomavirus 16 positive cervical cancer in Guatemala: The D2 and D3 sublineages differ in integration rate and age of diagnosis

Boland

Torres-Gonzalez

et al. 2020

Preprint

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Human papillomavirus (HPV) 16 displays substantial sequence variation; four HPV16 lineages (A, B, C, D) have been described, as well as multiple sub-lineages. To identify molecular events associated with HPV16 carcinogenesis we evaluated viral variation, the integration of HPV16, and somatic mutation in 96 cervical cancer samples from Guatemala. A total of 64% (60/94) of the samples had integrated HPV16 sequences, and integration was associated with an earlier age of diagnosis (P=0.0007) and pre-menopausal disease. HPV16 integration sites were broadly distributed in the genome but in one tumor, HPV16 integrated into the promoter of the interferon regulatory factor 4 (IRF4) gene, which plays an important role in the regulation of the interferon response to viral infection. The HPV16 D2 and D3 sub-lineages were found in 23% and 30% of the tumors, respectively and were significantly associated with adenocarcinoma. D2-positive tumors had a higher rate of integration (P=0.011), earlier age of diagnosis (P=0.012), and a lower rate of somatic mutation (P=0.03). Whereas D3-positive tumors are less likely to integrate, have later age-of-diagnosis, and a higher rate of somatic mutation. In conclusion, Guatemalan cervical tumors have a high frequency of the very high-risk HPV16 D2 and D3 sub-lineages and cervical cancer patients with these variants of HPV16 differ in histology, age of-diagnosis, integration, and somatic mutation frequency. In summary, related lineages of HPV16 have different features of oncogenicity.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Human papillomavirus 16 positive cervical cancer in Guatemala: The D2 and D3 sublineages differ in integration rate and age of diagnosis

Boland

Torres-Gonzalez

et al. 2020

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“…HPV16 has coevolved with human kind, and its variants segregate robustly into a phylogenetic tree with four phylogenetic lineages (A, B, C and D) and 16 sub-lineages: A1-A3 variant (previously known as EUR), A4 variant (As), B1-B4 variant (AFR1), C1-C4 variant (AFR2), D1 variant (NA), D2 variant (AA2), D3 variant (AA1) and D4 variant [19,20]. Many studies reported that the carcinogenic capacity is different between sub-lineages, and the non-European lineages have stronger pathogenicity in developing cervix cancer in comparison with European lineages, such as the D3 variant (AA1) and A4 variant (As) [19,21].…”

Section: Introductionmentioning

confidence: 99%

Association of Human Papillomavirus Type 16 Long Control Region Variations with Cervical Cancer in a Han Chinese Population

Dai¹,

Zhang³

et al. 2020

Int. J. Med. Sci.

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Objective: High-risk human papillomavirus (HPV) E6 and E7 proteins are the major oncoproteins involved in the tumorigenesis of cervical cancer. The long control region (LCR) in HPV plays an important role in regulating the expression of the E6 and E7 oncogenes. In the current study, we investigated the association of HPV16 LCR variations with cervical cancer. Methods: A total of 139 HPV16-positive cervical cancer patients (case group) and 116 HPV16-positive asymptomatic individuals (control group) were enrolled in the current study. Then, the HPV16 LCR was sequenced to determine the association between LCR variations and cervical cancer.Results: In the current study, HPV16 A1-A3 (19.4%), A4 (78.4%) and D3 (2.2%) variants were found in the case group. However, only A1-A3 (34.5%) and A4 variants (65.5%) were found in the control group. The distribution of the HPV16 variants between the case and control groups was significantly different (P=0.009). Moreover, a total of eleven variations (A7167G, A7173C, C7176T, C7200T, T7269C, C7286A, C7729A, C7763T, A7841G, G7867A and T24C) were significantly different between the case and control groups (P<0.05). For the sub-lineage analysis, only C7873G variations were significantly different between the case and control groups in the A4 (As) variant (P=0.039). Conclusion: Our results showed that specific variations in the HPV16 LCR were associated with cervical cancer. Our study will provide a good reference for further understanding of the relationship between HPV16 LCR variation and cervical cancer.

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“…48 While cellular integration of viral genomic material is a means of propagation for families such as 49 4 of cancer) and eventual integration of HPV16 sequences into human DNA via double-strand break 71 (DSB) repair events [Winder et al, 2007], yielding unique integration signatures found in next- 72 generation sequencing (NGS) data from human carcinomas [Holmes et al, 2016]. 73 HPV16 sub-lineages (variants) via epidemiological and lab-based studies have been 74 reported to infer differing cancer risk [reviewed by Mirabello et al, 2018 and references within; 75 Clifford et al, 2019]. HPV16 variant designations were originally based on their geographical 76 region of origin and have since been updated to lineage (1.0 to 10.0% whole viral genome 77 sequence difference) and sub-lineage (0.5 to 1.0% difference) nomenclature.…”

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Human papillomavirus type 16 sub-lineages and integration in cancer

Jackson

Ortigas-Vásquez

Zehbe

2020

Preprint

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21Our lab has been intrigued by the fact that viral genomes often take on the role of mobile 22 Retroviridae (e.g., human immunodeficiency virus, HIV), it can also occur during persistent 50 infections with DNA viruses and is often associated with virally induced cancers. One such family 51 of common DNA tumour viruses, Papillomaviridae, is responsible for causing ~5% of all human 52 cancers worldwide [Ghittoni et al., 2015]. There are 660 types of papillomaviruses (PVs) 53 discovered as of June 2020 based on the PaVE reference genome database [PaVE: 54 https://pave.niaid.nih.gov, Van Doorslaer et al., 2013; 2017a]. The number of PV types, including 55 the non-human PVs (currently 215) is expected to continue rising due to high-throughput 56 genomics and sampling [Van Doorslaer and Dillner, 2019]. The majority of PVs currently identified 57 are the human papillomaviruses (HPVs) [Van Doorslaer et al., 2017b] and these types (445 to 58 date) differ in their propensity for inducing cancer as well as their epithelial tropism, with "high-59 risk" types being the primary cause of malignancies: predominantly via sexually-transmitted 60 persistent HPV type 16 (HPV16) infection of anogenital and oropharyngeal mucosa [Ndiaye et 61 al., 2014]. Although this and other HPV genomes are considered "small", only ~7.9 kb containing 62 nine open reading frames (ORFs) and a variety of alternatively spliced and multi-cistronic variant 63 transcripts [Graham & Faizo, 2017], it encodes potent oncoproteins such as E6 and E7 which 64 drive host cells to acquire the hallmarks of cancer [Hanahan and Weinberg, 2000; 2011; Mesri et 65 al., 2014]. The combined E6 and E7 actions disable protective apoptotic mechanisms and 66 promote host cell proliferation as outlined by Hoppe-Seyler and colleagues [2018]-a 67 phenomenon that could potentially be exploited therapeutically at an RNA [Togtema et al., 2018] 68 or protein-level [Togtema et al., 2019]. Of particular relevance for this study, the HPV-augmented 69 environment can permit chromosomal instability (an enabling characteristic among the hallmarks 70 157proportion of integrated cases was 1.23x higher in D2/D3-containing CESC samples (9/10, 90.0% 158 vs 51/70, 72.9% for A1), the sample size was very low rendering this initial analysis underpowered 159 and the finding as not statistically significant (P = 0.242, Χ 2 test). 160

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The Intersection of HPV Epidemiology, Genomics and Mechanistic Studies of HPV-Mediated Carcinogenesis

Cited by 103 publications

References 79 publications

Human papillomavirus 16 positive cervical cancer in Guatemala: The D2 and D3 sublineages differ in integration rate and age of diagnosis

Human papillomavirus 16 positive cervical cancer in Guatemala: The D2 and D3 sublineages differ in integration rate and age of diagnosis

Association of Human Papillomavirus Type 16 Long Control Region Variations with Cervical Cancer in a Han Chinese Population

Human papillomavirus type 16 sub-lineages and integration in cancer

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