Cloning and partial DNA sequencing of two new human papillomavirus types associated with condylomas and low-grade cervical neoplasia

Configuration of the surfaces of epithelial cells infected by human papillomavirus

Human papillomavirus (HPV) types were investigated hy iri situ hybridization (ISH) in biopsiesfroin J8patients with diverse pathologies ofcervix uteri (7 condylomas, 1 CINI +HPV, 3 CIN II, 4 CIN II + HPV and 3 CIN III). Cervical sniears ofthe same patients were processed by Scanning Electron Mycroscopy (SEM) in order to study the configuration of sitrfaces ofcells infected hy different HPV types. Seven condylomas, I CIN I + HPV, 3 CIN II and 3 CIN II + HPV showed alinost identical surface configurations to those of normal cells (short, thin, homogeneous microvi lli o r typicai microridgesj. This group presented low, moderate and high risk HPV types in a episomal form, while I CINII + HPV and3 CINIII with integratedHPV 16/]8 exfoliatedcells covered with gross microvilli, with variahle length and uneven distribution, oran amorphous surface. The presence of HPV 16/18 cannot be sufficient for the development of an anormal configuration, hut the integrated State ofthis viral type coiild he related to the morphological changes in cellular surface morphology. The results of this paper underline the importance of viral integration in the genesis of cervical carcinoma.

Phylogenetic analysis of Alphapapillomavirus based on L1, E6 and E7 regions suggests that carcinogenicity and tissue tropism have appeared multiple times during viral evolution

Members of the Alphapapillomavirus genus are causative agents for cervix cancer and benign lesions in humans. These viruses are classified according to sequence similarities in their L1 region. Yet, viral carcinogenicity has been associated with variations in the proteins encoded by the E6 and E7 genes. In order to relate evolutionary history with origin of carcinogenicity, we performed phylogenetic reconstructions using both nucleotide and predicted amino acid sequences of the L1, E6 and E7 genes. Whilst phylogenetic analysis of L1 reconstructed genus evolutionary history, phylogenies based on E6 and E7 proteins support the idea that mutations at amino acids S/Tx [V/L] (E6) and LxCxE (E7) might be responsible for carcinogenic potential. These findings indicate that virulence within Alphapapillomavirus have appeared multiple times during evolution. Our results reveal that oncogenic potential is not a monophyletic clade-specific adaptation but might be the result of positive selection on random mutations occurring on proteins involved in host infection during viral diversification.

Human papillomavirus genotyping by Linear Array and Next-Generation Sequencing in cervical samples from Western Mexico

BACKGROUND

The Linear Array® (LA) genotyping test is one of the most used methodologies for Human papillomavirus (HPV) genotyping, in that it is able to detect 37 HPV genotypes and co-infections in the same sample. However, the assay is limited to a restricted number of HPV, and sequence variations in the detection region of the HPV probes could give false negatives results. Recently, 454 Next-Generation sequencing (NGS) technology has been efficiently used also for HPV genotyping; this methodology is based on massive sequencing of HPV fragments and is expected to be highly specific and sensitive. In this work, we studied HPV prevalence in cervixes of women in Western Mexico by LA and confirmed the genotypes found by NGS.

METHODS

Two hundred thirty three cervical samples from women Without cervical lesions (WCL, n = 48), with Cervical intraepithelial neoplasia grade 1 (CIN I, n = 98), or with Cervical cancer (CC, n = 87) were recruited, DNA was extracted, and HPV positivity was determined by PCR amplification using PGMY09/11 primers. All HPV- positive samples were genotyped individually by LA. Additionally, pools of amplicons from the PGMY-PCR products were sequenced using 454 NGS technology. Results obtained by NGS were compared with those of LA for each group of samples.

RESULTS

We identified 35 HPV genotypes, among which 30 were identified by both technologies; in addition, the HPV genotypes 32, 44, 74, 102 and 114 were detected by NGS. These latter genotypes, to our knowledge, have not been previously reported in Mexican population. Furthermore, we found that LA did not detect, in some diagnosis groups, certain HPV genotypes included in the test, such as 6, 11, 16, 26, 35, 51, 58, 68, 73, and 89, which indicates possible variations at the species level.

CONCLUSIONS

There are HPV genotypes in Mexican population that cannot be detected by LA, which is, at present, the most complete commercial genotyping test. More studies are necessary to determine the impact of HPV-44, 74, 102 and 114 on the risk of developing CC. A greater number of samples must be analyzed by NGS for the most accurate determination of Mexican HPV variants.

Human papillomavirus typing by single tube multiplex amplification in real time (SMART): the PapillomaFinder® SMART 20 assay

BACKGROUND

High-risk (hr) human papillomavirus (HPV) infections play a causal role in the development of cervical cancer. The detection of hrHPV is, therefore, advocated in cervical cancer screening programs.

OBJECTIVES

The aim of this study was to determine the performance of a novel HPV typing assay, PapillomaFinder® SMART 20. This is a one-tube-per-sample method, to be performed on standard real-time PCR platforms, using melting curve analysis to distinguish targets. The assay detects all 14 hrHPV types, of which 16, 18, 31, 33, 35, 39, 45, 52, 56 and 58 individually. HrHPV types 51, 59, 66 and 68 are detected in an hrHPV pool, and low-risk (lr) HPV types 6, 11, 40, 42, 43 and 44 in an lrHPV pool.

STUDY DESIGN

The method was tested on HPV plasmid models, WHO and QCMD proficiency panels and a series of clinical cytological samples (n=45), the latter in comparison with a clinically validated real-time quantitative PCR.

RESULTS

Type-specificity of the test was 100% using plasmids, the WHO and QCMD panels. Sensitivity for hrHPV in single infections was 100% using the WHO and QCMD panels and cytological samples, with an analytical sensitivity of 10-25 copies per reaction for all HPV types tested. Of the 34 HPV types present in the 8 multiple infections in the WHO panel, 30 were detected. In all cytological samples at least one hrHPV type was found, in concordance with the clinically validated method. Only when the viral load of the dominant HPV types in multiple infections greatly exceeded that of the other types in the infection, those other types were not always detected.

CONCLUSIONS

PapillomaFinder® SMART 20 is a rapid, easy to perform, single tube HPV typing assay. The assay detects the 14 hrHPV types, and the 6 most important lrHPV types with a high sensitivity and type-specificity.

Analyzing the Human Papillomavirus (HPV) Life Cycle in Primary Keratinocytes with a Quantitative Colony-Forming Assay

Papillomavirus genomes replicate as extrachromosomal plasmids within infected keratinocytes, requiring the regulated expression of early viral gene products to initially amplify the viral genomes and subvert cell growth checkpoints as part of a complex path to immortalization. Building on contemporary keratinocyte transfection and culture systems, the methods described in this unit form a detailed approach to analyzing critical events in the human papillomavirus (HPV) life cycle, utilizing physiologic levels of viral gene products expressed from their native promoter(s) in the natural host cells for HPV infection. A quantitative colony-forming assay permits comparison of the capacities of various transfected HPV types and mutant HPV genomes to initially form colonies and immortalize human keratinocytes. In conjunction with additional methods, these protocols enable examination of genomic stability, viral and cellular gene expression, viral integration, and differentiation patterns influenced by HPV persistence in clonal human keratinocytes that effectively mimic early events in HPV infection.

Genomic diversity of low-risk human papillomavirus genotypes HPV 40, HPV 42, HPV 43, and HPV 44

In order to investigate the genomic diversity of low-risk human papillomavirus (HPV) genotypes, a total of 108 isolates of HPV 40, HPV 42, HPV 43, or HPV 44, obtained from anal swabs or tissue specimens of patients with anogenital warts, and cervical swabs of women with cervical intraepithelial neoplasia of different grades, were analyzed. The characterization of genomic variants was established by sequencing one third of the viral genome and analysis of three different genomic regions: L1, LCR, and E6. Maximum variant divergence accounted for 0.4-1.1% of the investigated genomic segments. Several novel, potentially important nucleotide substitutions, deletions, and insertions are described. Altogether, among 14 HPV 40 isolates, a total of nine different genomic variants were identified, composed of eight L1, five LCR, and four E6 genomic variants. Among 49 HPV 42 isolates, a total of 30 genomic variants were identified, composed of 20 L1, 18 LCR, and four E6 genomic variants. Among 10 HPV 43 isolates, distributed into two major genomic variant lineages with clearly defined nucleotide signatures, three genomic variants were identified, composed of three L1, two LCR, and two E6 genomic variants. Among 35 HPV 44 isolates, a total of eight HPV 44 and 11 subtype HPV 44 genomic variants were identified, composed of 13 L1, 14 LCR, and 6 E6 genomic variants. A similar level of genomic diversity of HPV 44 and its subtype was identified in our geographic region as has been reported previously on isolates collected worldwide.

Human papillomavirus (HPV) type 18 induces extended growth in primary human cervical, tonsillar, or foreskin keratinocytes more effectively than other high-risk mucosal HPVs

Mucosal high-risk (HR) human papillomaviruses (HPVs) that cause cervical and other anogenital cancers also are found in approximately 25% of head and neck carcinomas (HNCs), especially those arising in the oropharynx and the tonsils. While many HR HPV types are common in anogenital cancer, over 90% of HPV-positive HNCs harbor HPV type 16 (HPV-16). Using a quantitative colony-forming assay, we compared the ability of full-length mucosal HPV genomes, i.e., the low-risk HPV-11 and HR HPV-16, -18, and -31, to persist in and alter the growth of primary human keratinocytes from the foreskin, cervix, and tonsils. The HR HPV types led to the formation of growing keratinocyte colonies in culture independent of the site of epithelial origin. However, HPV-18 induced colony growth in all keratinocytes >4-fold more effectively than HPV-16 or HPV-31 and >20-fold more efficiently than HPV-11 or controls. HPV-11-transfected or control colonies failed to expand beyond 32 to 36 population doublings postexplantation. In contrast, individual HR HPV-transfected clones exhibited no apparent slowdown of growth or "crisis," and many maintained HPV plasmid persistence beyond 60 population doublings. Keratinocyte clones harboring extrachromosomal HR HPV genomes had shorter population doubling times and formed dysplastic stratified epithelia in organotypic raft cultures, mirroring the pathological features of higher-grade intraepithelial lesions, yet did not exhibit chromosomal instability. We conclude that, in culture, the HR HPV type, rather than the site of epithelial origin of the cells, determines the efficacy of inducing continued growth of individual keratinocytes, with HPV-18 being the most aggressive mucosal HR HPV type tested.

Human papillomavirus type-distribution in condylomata acuminata of mainland China: a meta-analysis

The aim of this work was to study the human papillomavirus (HPV) type-distribution in condylomata acuminata (CA) of mainland China and to estimate the potential role of HPV prophylactic vaccines for CA in mainland China. Forty-three studies using polymerase chain reaction to detect HPV were included in this meta-analysis, and totally 5247 CA cases and 436 controls were included. The overall and type-specific prevalence of HPV 6, 11, 40, 42, 43, 44 were estimated using non-conditional logistic regression model. Overall HPV prevalence was 84.2% and 4.6% for CA and controls, respectively. Estimated HPV types 6, 11, 40, 42 positive fractions in CA were 54.9%, 41.1%, 2.7% and 2.0%, respectively, and exactly 0% for HPV types 43 and 44. HPV 6 and/or 11-positive fractions were 83.0% in mainland China. Thus, prophylactic HPV vaccine has the potential to protect up to 83% of CA cases in mainland China.

The E8--E2 gene product of human papillomavirus type 16 represses early transcription and replication but is dispensable for viral plasmid persistence in keratinocytes

A conserved E8(wedge)E2 spliced mRNA is detected in keratinocytes transfected with human papillomavirus type 16 (HPV-16) plasmid DNA. Expression of HPV-16 E8--E2 (16-E8--E2) is independent of the major early promoter, P97, and is modulated by both specific splicing events and conserved cis elements in the upstream regulatory region in a manner that differs from transcriptional regulation of other early viral genes. Mutations that disrupt the predicted 16-E8--E2 message also increase initial HPV-16 plasmid amplification 8- to 15-fold and major early gene (P97) transcription 4- to 5-fold over those of the wild type (wt). Expressing the 16-E8--E2 gene product from the cytomegalovirus (CMV) promoter represses HPV-16 early gene transcription from P97 in a dose-dependent manner, as detected by RNase protection assays. When expressed from the CMV promoter, 16-E8--E2 also inhibits the amplification of an HPV-16 plasmid and a heterologous simian virus 40 (SV40) ori plasmid that contains E2 binding sites in cis. In contrast, cotransfections with HPV-16 wt genomes that express physiologic levels of 16-E8--E2 are sufficient to repress HPV-16 plasmid amplification but are limiting and insufficient for the repression of SV40 amplification. 16-E8--E2-dependent repression of HPV-16 E1 expression is sufficient to account for this observed inhibition of initial HPV-16 plasmid amplification. Unlike with other papillomaviruses, primary human keratinocytes immortalized by the HPV-16 E8 mutant genome contain more than eightfold-higher levels of unintegrated plasmid than the wt, demonstrating that 16-E8(wedge)E2 limits the viral copy number but is not required for plasmid persistence and maintenance.

Papillomavirus subtypes are natural and old taxa: phylogeny of human papillomavirus types 44 and 55 and 68a and -b

A human papillomavirus (HPV) type is defined as an HPV isolate whose L1 gene sequence is at least 10% different from that of any other type, while a subtype is 2 to 10% different from any HPV type. In order to analyze the phylogeny behind the subtype definition, we compared 49 isolates of HPV type 44 (HPV-44) and its subtype HPV-55, previously misclassified as a separate type, and 41 isolates of the subtype pair HPV-68a and -b, sampled from cohorts in four continents. The subtypes of each pair are separated by deep dichotomic branching, and three of the four subtypes have evolved large phylogenetic clusters of genomic variants forming a "star" phylogeny, with some branches specific for ethnically defined cohorts. We conclude that subtypes of HPV types are natural and old taxa, equivalent to types, which either diverged more recently than types or evolved more slowly.

Papillomavirus subtypes are natural and old taxa: phylogeny of human papillomavirus types 44 and 55 and 68a and -b

A human papillomavirus (HPV) type is defined as an HPV isolate whose L1 gene sequence is at least 10% different from that of any other type, while a subtype is 2 to 10% different from any HPV type. In order to analyze the phylogeny behind the subtype definition, we compared 49 isolates of HPV type 44 (HPV-44) and its subtype HPV-55, previously misclassified as a separate type, and 41 isolates of the subtype pair HPV-68a and -b, sampled from cohorts in four continents. The subtypes of each pair are separated by deep dichotomic branching, and three of the four subtypes have evolved large phylogenetic clusters of genomic variants forming a "star" phylogeny, with some branches specific for ethnically defined cohorts. We conclude that subtypes of HPV types are natural and old taxa, equivalent to types, which either diverged more recently than types or evolved more slowly.

Human papillomavirus and cervical cancer

Of the many types of human papillomavirus (HPV), more than 30 infect the genital tract. The association between certain oncogenic (high-risk) strains of HPV and cervical cancer is well established. Although HPV is essential to the transformation of cervical epithelial cells, it is not sufficient, and a variety of cofactors and molecular events influence whether cervical cancer will develop. Early detection and treatment of precancerous lesions can prevent progression to cervical cancer. Identification of precancerous lesions has been primarily by cytologic screening of cervical cells. Cellular abnormalities, however, may be missed or may not be sufficiently distinct, and a portion of patients with borderline or mildly dyskaryotic cytomorphology will have higher-grade disease identified by subsequent colposcopy and biopsy. Sensitive and specific molecular techniques that detect HPV DNA and distinguish high-risk HPV types from low-risk HPV types have been introduced as an adjunct to cytology. Earlier detection of high-risk HPV types may improve triage, treatment, and follow-up in infected patients. Currently, the clearest role for HPV DNA testing is to improve diagnostic accuracy and limit unnecessary colposcopy in patients with borderline or mildly abnormal cytologic test results.

Rapid detection and typing of herpes simplex virus DNA in clinical specimens by the hybrid capture II signal amplification probe test

A second-generation signal amplification, nucleic acid-based test for the rapid detection and typing of herpes simplex virus (HSV) DNA was developed and evaluated with artificial and clinical specimens. The analytical sensitivity of the Hybrid Capture II (HC II) HSV DNA assay was determined by testing either cloned HSV DNA or total genomic HSV DNA titrations and resulted in detection thresholds of between 5 x 10(3) and 1 x 10(4) copies per assay. Specificity was assessed by testing a panel of bacteria and viruses commonly found in the female genital tract. Sensitivity was assessed by testing 112 ulcerative genital lesions by the HC II assay and comparing the results to those obtained by routine cell culture. Discrepant results were resolved by PCR testing. After resolution of the discrepant results, the sensitivity of the HC II assay compared to the consensus result (the results of two of three tests, the HC II assay, culture, and PCR, were in agreement) was 93.2% (41 of 44 specimens), and the specificity was 100% (60 of 60 specimens). Culture gave a sensitivity of 84.1% (37 of 44 specimens) and a specificity of 100% (60 of 60 specimens) compared to the consensus result. The results of HSV typing by the HC II assay and culture agreed in all cases. The HC II assay is a rapid and accurate assay for detecting and typing HSV types 1 and 2, with a sensitivity comparable to that of culture and greater ease of use than culture.

A novel genital human papillomavirus (HPV), HPV type 74, found in immunosuppressed patients

The genome of a novel human papillomavirus (HPV) type, HPV74, was cloned from an iatrogenically immunosuppressed woman with persisting low-grade vaginal intraepithelial neoplasia. HPV74 was found to be phylogenetically related to the low-risk HPV types 6, 11, 44, and 55. HPV74 or a variant of this type was found in specimens from three additional immunosuppressed women but not in about 3,000 anogenital specimens from immunocompetent patients.

Serological responses to human papillomavirus type 6 and 16 virus-like particles in patients with cervical neoplastic lesions

Serum samples from 36 cervical carcinoma patients, 33 patients with high-grade squamous intraepithelial lesions, and 31 cytologically normal women were tested by enzyme-linked immunosorbent assay (ELISA) using human papilloma virus type 6 (HPV 6) and HPV 16 virus-like particles as antigens. Forty serum specimens from 1-year-old children were used to assign cutoff points. When serum samples from the subjects infected with HPV 16 were tested in an HPV 16 ELISA detecting immunoglobulin A (IgA), IgG, and IgM binding, 61% showed IgA, 44% showed IgG, and 39% showed IgM reactivity. Of HPV 6- or 11- or HPV 18-infected subjects. fewer than 17% showed IgA or IgG responses and 33% showed IgM reactivity. In contrast, 13% showed IgA, 10% showed IgG, and 16% showed IgM reactivity in the HPV DNA-negative controls. The results suggest that the IgA and IgG responses are HPV 16 specific and the IgM response is cross-reactive to different HPV types. On the other hand, the serological responses to HPV 6 did not differ in the patient and control groups. The percentages of patients positive for both IgA and IgG antibodies were significantly higher in the groups with high-grade squamous intraepithelial lesions (12% [4 of 33]; P = 0.04) and cancer (17% [6 of 36]; P = 0.02) than in the healty women (0% [0 of 31]), and the percentages for either IgA or IgG were higher for the cancer group (47% [17 of 36]; P = 0.01) than in the normal group (19% [6 of 31]). Most sera positive for IgA and IgG in the patient groups showed higher titers than those in the normal group. All these results suggest that high IgA and IgG responses are good indicators for estimating HPV 16 infection.

Typing of human papillomaviruses in condylomata acuminata from Greece

DNA samples from recurrent condylomata acuminata biopsies of Greek males and females were examined for the presence of human papillomavirus (HPV) DNA using high-stringency Southern blot hybridization analysis. Of the twenty-six biopsies, 25 were positive for the HPV 6/11-related DNA sequences, and when further analyzed with the polymerase chain reaction (PCR) the HPV-negative biopsy was also positive for HPV 6/11 DNA. Nineteen specimens were further characterized based on their Pstl restriction endonuclease hybridization pattern. Twelve biopsies were positive for HPV 6a, one biopsy was positive for HPV 11a, and one biopsy was positive for HPV 6c DNA. Three specimens contained HPV 6/11 related DNA that gave an unusual Pstl pattern, and one specimen appeared to represent a multiple HPV infection containing HPV 6/11- and HPV 31/35/39-related sequences. Finally, one sample contained a mixture of HPV 6a DNA and an HPV 6a-like genome. Biopsies were also taken from adjacent apparently normal tissue, 0.5 cm away from the lesion, in 19 of the patients. Only one of these was found to be positive for HPV 6a DNA by Southern blot analysis.

Human papillomavirus (HPV) DNA in penile carcinomas and in two cell lines from high-incidence areas for genital cancers in Africa

Biopsies of 13 penile cancers (PC), from patients living in regions of Uganda with a high incidence of genital cancers, were studied for the presence, molecular characteristics and physical state of DNA related to that of human papillomavirus (HPV) types 6, 11, 16, 18, 31 and 33. HPV DNA sequences were detected in all PC specimens by dot/Southern blot analyses and by gene amplification of DNA sequences highly conserved among several HPVs. HPV 16 DNA sequences were found in one PC; DNA sequences with low homology to HPV16 or HPV18 were present in all other samples. Viral DNA is primarily integrated in the cellular DNA. To isolate and characterize a possible highly oncogenic HPV, a genomic library of the DNA extracted from the PC-8 biopsy has been constructed in the EcoRI arms of the EMBL4 phage. A single phage containing 8.30-kb HPV16-related sequences has been identified and the 3 segments of 0.45, 0.65 and 7.2 kb, released by EcoRI digestion, have been independently subcloned in pUC18 for further analysis.

Cervical papillomavirus infection and cervical dysplasia in Hispanic, Native American, and non-Hispanic white women in New Mexico

BACKGROUND

Human papillomavirus infections of the cervix are found with varying frequencies in different populations worldwide, and have been associated with cervical cytologic abnormalities.

METHODS

We studied 1,603 randomly selected Hispanic, Native American, and non-Hispanic White women in New Mexico to determine the prevalence of cervical HPV infection in these ethnic groups, and its association with Pap smear abnormalities, using a new commercial dot-blot hybridization assay.

RESULTS

Nine percent of all women screened had evidence of cervical HPV infection (13.7% of non-Hispanic White women, 9.7% of Hispanics, and 6.6% of Native American women). Prevalence was higher in younger women ages 14-19 years than in older age groups. Over half of women with cervical HPV infection (n = 145) had normal Pap smears. The proportion of infected women increased among those with more advanced cytopathologic abnormalities; 5.6 percent with normal Pap smears had cervical HPV vs 66.7 percent with moderate-severe dysplasia.

CONCLUSIONS

Cervical HPV infection is common among New Mexico clinic attendees, varies in prevalence among the three major ethnic groups, and is strongly associated with cervical cytopathologic abnormalities.

Human papillomavirus in exophytic condylomatous lesions on different female genital regions

Clinically diagnosed exophytic condylomatous lesions on the vulva (20 cases), vagina (5 cases), and cervix (9 cases) were examined pathologically, and human papillomavirus (HPV) types present in those lesions were identified by Southern blot hybridization analysis. All vulvar and vaginal lesions showed typical histopathological features of classical condylomata, and HPV 6 and 11 were found in 15 vulvar and 3 vaginal lesions and in 5 vulvar and 2 vaginal lesions, respectively. In 5 cervical lesions with typical condylomatous changes, HPV 6 or 11 was also detected; however, HPV 16 was found in 2 cases of cervical lesion surrounded by prominent intraepithelial neoplasia, and HPV 31 was found in 2 cases of slightly elevated lesion with intraepithelial neoplasia. These observations suggest that HPV 6 and 11 have the potency to induce the specific pathological changes, condylomatous, in any regions of the female lower genital tract.

Analysis of the physical state of different human papillomavirus DNAs in intraepithelial and invasive cervical neoplasm

The integration of human papillomavirus (HPV) DNA into the human genome has been generally accepted as a characteristic of malignant lesions. To gain a better understanding of this phenomenon, genomic DNA from 181 cervical biopsy specimens was isolated and analyzed for HPV type and physical state of the HPV genome. These specimens represented the full spectrum of cervical disease, from condyloma to invasive carcinoma. Discrimination between integrated and episomal HPV DNA was accomplished by the detection of HPV-human DNA junction fragments on Southern blots. In most cases in which ambiguous Southern blot results were obtained, the specimens were reanalyzed by two-dimensional gel electrophoresis. Of the 100 biopsy specimens of cervical intraepithelial neoplasia analyzed, only 3 showed integrated HPV DNA, in contrast to 56 (81%) of 69 cervical carcinomas (P less than 0.001) showing integrated HPV DNA. Of the 40 carcinomas containing HPV 16 DNA, 29 (72%) had integrated HPV DNA, of which 8 (20%) also had episomal HPV DNA. In 11 (27%) cancers, only episomal HPV 16 DNA was detected. All 23 HPV 18-containing carcinomas had integrated HPV DNA, and 1 also had episomal HPV 18 DNA. The difference between HPV types 16 and 18 with respect to frequency of integration was statistically significant (P less than 0.01). The results of this study indicate that detectable integration of HPV DNA, regardless of type, occurs infrequently in cervical intraepithelial neoplasia. The absence of HPV 16 DNA integration in some carcinomas implies that integration is not always required for malignant progression. In contrast, the consistent integration of HPV 18 DNA in all cervical cancers examined may be related to its greater transforming efficiency in vitro and its reported clinical association with more aggressive cervical cancers.

Typing and molecular characterization of human papillomaviruses in genital warts from South African women

Condyloma acuminata from 12 women were examined for the presence of human papillomavirus DNA. Six of the women had HPV 6a, two had HPV 11a, one had a new HPV 6 subtype, and one a new HPV 11 subtype. The new HPV 6 subtype could be distinguished from other HPV 6 subtypes on the basis of Pst I fragments as well as Hind II fragments. The new HPV 11 subtype had a different Hpa II restriction endonuclease pattern. Restriction maps of both new subtypes were constructed. Two of the biopsies did not contain detectable HPV DNA when probed with HPV 6, HPV 11, and HPV 16. Biopsies were taken from normal tissue 1 cm away from the condyloma in 11 of the patients. Only one of these normal tissue biopsies was positive for HPV by Southern blot hybridization.

Temporal associations of human papillomavirus infection with cervical cytologic abnormalities

The relationship between infection with different human papillomavirus types and cervical intraepithelial neoplasia was studied in a group of 398 women seen in a private gynecology practice in Washington, D.C. Each woman was assessed for human papillomavirus infection by Southern blot hybridization analysis of cervical cells obtained by swab. The human papillomavirus results were correlated with the results of Papanicolaou smears taken the same day and with data abstracted from medical records regarding past cervical disease. Subjects with normal cytologic findings at the time of human papillomavirus testing were followed up for an average of 2 to 3 years with additional Papanicolaou smears. At the time of human papillomavirus testing, 58% (19/33) of women with cervical intraepithelial neoplasia had detectable human papillomavirus deoxyribonucleic acid in contrast to 10% (28/289) of women with normal cytologic findings (p less than 0.001). This association persisted after statistical adjustment for age and current use of oral contraceptives, a factor that appeared to increase the detection of human papillomavirus. Among women with no current cytologic evidence of neoplasia, human papillomavirus detection was more likely in those with a history of past genital neoplasia (p = 0.05). In the follow-up study, 15% (3 of 20) of cytologically normal women who were human papillomavirus-positive at baseline subsequently exhibited cervical cells suggestive of cervical intraepithelial neoplasia compared with only 5% (9 of 195) of human papillomavirus-negative women. However, this difference reflected recurrent and not incident neoplasia.

Two new human papillomavirus types (HPV54 and 55) characterized from genital tumours illustrate the plurality of genital HPVs

The genomes of two new human papillomavirus (HPV) types, named HPV54 and HPV55, were cloned from penile lesions of 2 patients. HPV54 was isolated from a verrucous carcinoma (Buschke-Löwenstein tumour) together with full-length HPV6 genomes and HPV6 DNA molecules with a deletion of about 0.3 kb located in the non-coding region. HPV55 was isolated from a condyloma acuminatum. No cross-hybridization was observed between HPV54 DNA and the DNAs of the known cutaneous and genital HPVs by blot hybridization experiments performed under stringent conditions. In contrast, significant cross-hybridization was detected between HPV55 DNA and the DNA of HPV13, associated with benign oral lesions, and, to a lesser extent, with the DNAs of HPV6, 11, and 44, associated with benign genital proliferative lesions. The DNA sequence homology between HPV55 and HPV6, 11, and 13 was estimated at 12%, 12%, and 20%, respectively, by hybridization in liquid phase at saturation, followed by nuclease S1 analysis. The physical maps of HPV54 and 55 were aligned with the genetic maps of HPV16 and 11, respectively, by heteroduplex mapping and partial DNA sequencing. HPV54 is thus only weakly related to the known HPVs, while HPV55 represents an additional HPV6-related HPV type. HPV54 and HPV55 are uncommon genital HPV types since, in a survey of a large series of specimens of benign, pre-malignant or malignant anogenital and orolaryngeal tumours, HPV54 was not detected, and HPV55 was found in another case of condyloma acuminatum.

Amplification of human papillomavirus DNA sequences by using conserved primers

The polymerase chain reaction has potential for use in the detection of small amounts of human papillomavirus (HPV) viral nucleic acids present in clinical specimens. However, new HPV types for which no probes exist would remain undetected by using type-specific primers for the polymerase chain reaction before hybridization. Primers corresponding to highly conserved HPV sequences may be useful for detecting low amounts of known HPV DNA as well as new HPV types. Here we analyze a pair of primers derived from conserved sequences within the E1 open reading frame for HPV sequence amplification by using the polymerase chain reaction. The longest perfect homology among HPV sequences is a 12-mer within the first exon of E1M. A region of conserved amino acids coded by the E1 open reading frame allowed the detection of another highly conserved region about 850 base pairs downstream. Two 21-mers derived from these conserved regions were used to amplify sequences from all HPV DNAs used as templates. The amplified DNA was shown to be specific for HPV sequences within the E1 open reading frame. DNA from HPVs whose sequences were not available were amplified by using these two primers. HPV DNA sequences in clinical specimens could also be amplified with the primers.

Nucleotide sequence of human papillomavirus type 31: a cervical neoplasia-associated virus

The nucleotide sequence of human papillomavirus (HPV) 31 DNA (7912 bp) was determined and used to deduce the genomic organization of this cervical cancer-associated virus. Based on comparisons of the HPV 31 DNA sequence to other sequenced HPVs, HPV 31 is a typical papillomavirus most related to HPV 16 (70% identical nucleotides). The E6 and E7 open reading frames (ORF) of HPV 31 contain several potential DNA binding motifs (Cys-X-X-Cys), the locations of which are conserved in all HPVs. The E6 ORF also has the potential to code for an E6* protein. The E7 ORF of HPV31 encodes a polypeptide motif which appears to distinguish HPVs associated with cervical cancer, such as types 16, 18, 31, and 33, from HPVs found primarily in benign lesions, such as types 6 and 11.

Human papillomaviruses and carcinomas

The recognition of multiple types of human papillomaviruses has resulted in remarkable progress in the detection of persisting viral nucleic acid sequences in carcinomas. The consistent transcription in tumors of two early open reading frames, E6 and E7, with few exceptions (Lehn et al., 1985), indicates a role for the products of these genes in the induction and/or maintenance of the transformed state. A number of studies have shown that in vitro transformation can be achieved by transfection of E6/E7 DNA, and proteins encoded by these DNA sequences can be demonstrated in primary human keratinocytes immortalized by this DNA (Kaur et al., 1989). Mutagenesis experiments are needed to determine the absolute requirement for and function of these genes in transformation. A preferential association of some types with benign lesions while others may be frequently found in malignant tumors has been observed. HPV types 5 and 8 in epidermodysplasia verruciformis patients and types 16, 18, 31, 33, etc. in genital lesions are most frequently associated with progression to malignancy, whereas other types, such as HPV-6,-10, -11, and -20, are regularly identified in benign warts. Such distinctions are not absolute but provide the initial steps toward establishing a causal role for some human papillomaviruses in carcinomas. The need for well-designed epidemiological studies in concert with optimum molecular and serologic evaluations is evident (Armstrong et al., 1988). The data from human and animal studies indicate that papillomaviruses contribute significantly to the development of many, if not all, carcinomas, but we do not yet have a clear understanding of the importance of other interacting viral, chemical, or cellular factors. The application of gene cloning and non-stringent hybridization (Law et al., 1979) has provided us with an apparently ever-increasing catalog of human papillomaviruses. More effort is now required to establish their prevalence, the natural history of infection, and the mechanism of neoplastic transformation.