Biochemical characterization of two types of human papillomaviruses associated with epidermodysplasia verruciformis.

The DNAs of the human papillomaviruses (HPVs) associated with the benign lesions of two patients suffering from epidermodysplasia verruciformis (patients JD and JK) were analyzed by using 12 restriction endonucleases. None of the restriction endonucleases were one-cut enzymes for the HPV DNA obtained from patient JD, referred to as the prototypical HPV-5, whereas five of them were one-cut enzymes for the DNA of the major virus found in patient JK, referred to as HPV-9. The molecular cloning of the two fragments resulting from the cleavage of HPV-5 DNA by endonuclease HindIII and of the single fragment obtained after treatment of HPV-9 DNA with endonuclease BamHI was performed in Escherichia coli after the fragments were inserted in plasmid pBR322. A cleavage map of the two cloned genomes was constructed. Little sequence homology (4 to 5%) was detected between HPV-5 and HPV-9 DNAs by DNA-DNA hybridization experiments in liquid phase at saturation; this homology was reproducibly higher than that (2 to 3%) detected under the same conditions between these DNAs and HPV-1a DNA. In addition, blot hybridization experiments performed under stringent conditions showed no or little sequence homology between the DNAs of HPV-5 and HPV-9 and those of HPV prototypes of types 1, 2, 3, 4, and 7 associated with skin warts. These results confirm that HPV-5 and HPV-9 are two distinct HPV types.     

Detection of viral DNA and RNA by in situ hybridization

Using cloned restriction endonuclease fragments of Herpes simplex virus (HSV), human papillomavirus (HPV), and cytomegalovirus (CMV) DNA as probes, viral DNA and RNA sequences have been detected in human tissues. The probes were labeled either with a radioactive isotope, for subsequent detection by autoradiography, or with biotin. This latter technique has been successfully used to visualize HPV DNA in tissues that have been fixed in formalin and embedded in paraffin, and is therefore of value in retrospective studies of histological specimens. HPV DNA was detected under non-stringent conditions (Tm = -42 degrees C) with heterologous probes in plantar and common warts, laryngeal papillomas, and anogenital condylomas. The specific type of HPV was established using stringent hybridization conditions (Tm = - 17 degrees C). Results from these and from malignant tissues show the distribution and localization of HSV and HPV RNA and DNA sequences in malignancies of squamous cell origin in the anogenital region. Both HSV and HPV DNA sequences have occasionally been detected in the same tumor, providing a further impetus to test the hypothesis that an initiator-promoter relationship might involve these common human viruses in the development of some tumors.     

Isolation of a novel human papillomavirus (type 51) from a cervical condyloma.

We cloned the DNA from a novel human papillomavirus (HPV) present in a cervical condyloma. When DNA from this isolate was hybridized at high stringency with HPV types 1 through 50 (HPV-1 through HPV-50), it showed weak homology with HPV-6 and -16 and stronger homology with HPV-26. A detailed restriction endonuclease map was prepared which showed marked differences from the maps for other HPVs that have been isolated from the female genital tract. Reassociation kinetic analysis revealed that HPV-26 and this new isolate were less than 10% homologous; hence, the new isolate is a novel strain of HPV. The approximate positions of the open reading frames of the new strain were surmised by hybridization with probes derived from individual open reading frames of HPV-16. In an analysis of 175 genital biopsies from patients with abnormal Papanicolaou smears, sequences hybridizing under highly stringent conditions to probes from this novel HPV type were found in 4.2, 6.1, and 2.4% of biopsies containing normal squamous epithelium, condylomata, and intraepithelial neoplasia, respectively. In addition, sequences homologous to probes from this novel isolate were detected in one of five cervical carcinomas examined.     

Cloning of human papilloma virus genomic DNAs and analysis of homologous polynucleotide sequences.

The complete DNA genomes of four distinct human papilloma viruses (human papilloma virus subtype 1a [HPV-1a], HPV-1b, HPV-2a, and HPV-4) were molecularly cloned in Escherichia coli, using the certified plasmid vector pBR322. The restriction endonuclease patterns of the cloned HPV-1a and HPV-1b DNAs were similar to those already published for uncloned DNAs. Physical maps were constructed for HPV-2a DNA and HPV-4 DNA, since these viral DNAs had not been previously mapped. By using the cloned DNAs, the genomes of HPV-1a, HPV-2a, and HPV-4 were analyzed for nucleotide sequence homology. Under standard hybridization conditions (Tm = --28 degrees C), no homology was detectable among the genomes of these papilloma viruses, in agreement with previous reports. However, under less stringent conditions (i.e., Tm = --50 degrees C), stable DNA hybrids could be detected between these viral DNAs, indicating homologous segments in the genomes with approximately 30% base mismatch. By using specific DNA fragments immobilized on nitrocellulose filters, these regions of homology were mapped. Hybridization experiments between radiolabeled bovine papilloma virus type 1 (BPV-1) DNA and the unlabeled HPV-1a, HPV-2a, or HPV-4 DNA restriction fragments under low-stringency conditions indicated that the regions of homology among the HPV DNAs are also conserved in the BPV-1 genome with approximately the same degree of base mismatch.     

Conserved polynucleotide sequences among the genomes of papillomaviruses.

The DNAs of different members of the Papillomavirus genus of papovaviruses were analyzed for nucleotide sequence homology. Under standard hybridization conditions (Tm - 28 degrees C), no homology was detectable among the genomes of human papillomavirus type 1 (HPV-1), bovine papillomavirus type 2 (BPV-2), or cottontail rabbit (Shope) papillomavirus (CRPV). However, under less stringent conditions (i.e., Tm - 43 degrees C), stable hybrids were formed between radiolabeled DNAs of CRPV, BPV-1, or BPV-2 and the HindIII-HpaI A, B, and C fragments of HPV-1. Under these same conditions, radiolabeled CRPV and HPV-1 DNAs formed stable hybrids with HincII B and C fragments of BPV-2 DNA. These results indicate that there are regions of homology with as much as 70% base match among all these papillomavirus genomes. Furthermore, unlabeled HPV-1 DNA competitively inhibited the specific hybridization of radiolabeled CRPV DNA to bpv-2 DNA fragments, indicating that the homologous DNA segments are common among these remotely related papillomavirus genomes. These conserved sequences are specific for the Papillomavirus genus of papovaviruses as evidenced by the lack of hybridization between HPV-1 DNA and either simian virus 40 or human papovavirus BK DNA under identical conditions. These results indicate a close evolutionary relationship among the papillomaviruses and further establish the papillomaviruses and polyoma viruses as distinct genera.     

Characterization of a New Type of Human Papillomavirus That Causes Skin Warts

A human papillomavirus (HPV) was isolated from the lesions of a patient (ML) bearing numerous hand common warts. This virus was compared with the well-characterized HPV found in typical plantar warts (plantar HPV). ML and plantar HPV DNAs have similar molecular weights (5.26 x 10(6) and 5.23 x 10(6), respectively) but were shown to be different by restriction enzyme analysis. When the cleavage products of both DNAs by endonuclease EcoRI, BamI, HpaI, or Hind were analyzed by electron microscopy, one, two, one, and four fragments were detected for ML HPV DNA instead of the two, one, two, and six fragments, respectively, detected for plantar HPV DNA. In contrast to plantar HPV DNA, a high proportion of ML HPV DNA molecules were resistant to these restriction enzymes. Most, if not all, of the molecules were either resistant to BamI and sensitive to EcoRI or sensitive to BamI and resistant to EcoRI. After denaturation and renaturation of the cleavage products of ML HPV DNA by a mixture of the two enzymes, the circular "heteroduplexes" formed showed one to three heterology loops corresponding to about 4 to 8% of the genome length. No sequence homology was detected between ML and plantar HPV DNAs by cRNA-DNA filter hybridization, by measuring the reassociation kinetics of an iodinated plantar HPV DNA in the presence of a 25-fold excess of ML HPV DNA, or by the heteroduplex technique. The two viruses had distinct electrophoretic polypeptide patterns and showed no antigenic cross-reaction by immunodiffusion or immunofluorescence techniques. Preliminary cRNA-DNA hybridization experiments, using viral DNAs from single or pooled plantar or hand warts, suggest that hand common warts are associated with viruses similar or related to ML HPV. The existence of at least two distinct types of HPVs that cause skin warts was demonstrated; they were provisionally called HPV type 1 and HPV type 2, with plantar HPV and ML HPV as prototypical viruses, respectively.     

Molecular cloning and characterization of the DNAs of human papillomaviruses 19, 20, and 25 from a patient with epidermodysplasia verruciformis.

Five human papillomavirus (HPV) DNAs from lesions of an epidermodysplasia verruciformis patient were cloned in lambda L 47: DNA of HPV 5, which predominated in the carcinoma; DNA of a variant type of HPV 8, which was not detected in the carcinoma DNA by Southern blot hybridization but only by cloning; and DNAs of three papillomaviruses that were isolated from warts. Southern blot and liquid phase DNA-DNA hybridization under stringent conditions showed that the three viruses from warts were new types, which we named HPVs 19, 20, and 25. These viruses cross-hybridized between 3 and 29% among themselves and with HPVs 5 and 8. After physical mapping with several restriction enzymes, the colinear genomes were aligned with HPV 8 DNA to define early and late regions. HPVs 8, 19, and 25 shared homology in different parts of their genomes.     

Coinfection of human foreskin fragments with multiple human papillomavirus types (HPV-11, -40, and -LVX82/MM7) produces regionally separate HPV infections within the same athymic mouse xenograft.

The athymic mouse xenograft system was used to prepare infectious stocks of two additional anogenital tissue-targeting human papillomaviruses (HPVs) in a manner similar to that for the development of infectious stocks of HPV-11. An anal condyloma from a transplant patient was used as material for extraction of infectious virus, and human foreskin fragments were incubated with the virus suspension and transplanted subrenally into athymic mice. Partial viral sequencing indicated that two rare HPV types (HPV-40 and HPVLVX82/MM7) were concurrently present in both the patient condyloma and the foreskin xenografts, and passage of both types was achieved as a mixed infection with HPV-40 predominating. Xenografts that developed from simultaneous infection of human foreskin fragments with HPV-11, -40, and -LVX82/MM7 virions produced regionally separate areas of HPV-11 and -40 infection as determined by in situ hybridization. In addition, in situ hybridization with HPV-40 and HPVLVX82/MM7 DNA probes demonstrated that both of these HPV types were present as adjacent but separate infections within the same anal condyloma of the transplant patient. These studies indicate that multiple HPV types can simultaneously infect genital tissue and that each HPV type predominantly maintains regional separation within the same papilloma.     

Detection of human papillomavirus DNA in skin warts from immunocompromised patients but not in semen from men whose wives have abnormal cervical cytology.

The epidemiology of human papillomaviruses (HPV) was studied in 61 immunocompromised patients (e.g. renal and cardiac transplants; Bowen's disease; genital cancer) undergoing therapy at the University Hospital of Wales at Cardiff U.K. Warts from various sites of these patients were studied for the presence of HPV types 6, 11, 16 and 18 using the dot-blot DNA hybridization technique. Four HPV-16 and one HPV-11 was detected. The presence of HPV-16 in our study is quite significant since it suggests the potential occurrence of genital HPV types in skin warts in immunocompromised patients and hence the need for screening such patients against HPV types. HPV, mainly types 16 and 18 are usually associated with genital cancer, cervical malignancies and cervical intraepithelial neoplasia. The semen of the husband of 30 women with cervical abnormalities and the semen of 30 husbands (control) of wives with normal cervix were tested for HPV-6, 11, 16 and 18. No HPV-DNA could be detected in all of the 60 specimen. This suggests that specimens were either truly negative for any of those types or because virus DNA could present in a small amount less than 5 pg/microliters in some patients. Whether semen plays a role in transmitting HPV is still controversial.     

A new type of papillomavirus DNA, its presence in genital cancer biopsies and in cell lines derived from cervical cancer.

DNA of a new papillomavirus type was cloned from a cervical carcinoma biopsy. Two EcoRI clones of 7.8 and 6.9 kb in length were obtained, the latter contained a 900-bp deletion. The BamHI fragments of both clones were used to characterize the DNA. It represents a distinct type of papillomavirus as determined by its size, its cross-hybridization with DNA of other papillomavirus types under conditions of low stringency only, the co-linear alignment of its genome with HPV 6 and HPV 16 prototypes and its occasional occurrence as oligomeric episomes. We tentatively propose to designate it as HPV 18. DNA hybridizing with HPV 18 under stringent conditions was detected in 9/36 cervical carcinomas from Africa and Brazil, in 2/13 cervical tumors from Germany and 1/10 penile carcinomas. Benign tumors (17 cervical dysplasias, 29 genital warts), eight carcinomata in situ and 15 biopsies of normal cervical tissue were devoid of detectable HPV 18 DNA. HPV 18-related DNA was found, however, in cells of the HeLa, KB and C4-1 lines all derived from cervical cancer. The state of the viral DNA was investigated in four cervical cancer biopsies. The data reveal that the DNA might be integrated into the host cell genome. One tumor provided evidence for head to tail tandem repeats some of which persisted as circular episomes.     

Complex formation of human papillomavirus E7 proteins with the retinoblastoma tumor suppressor gene product.

The E7 proteins encoded by the human papillomaviruses (HPVs) associated with anogenital lesions share significant amino acid sequence homology. The E7 proteins of these different HPVs were assessed for their ability to form complexes with the retinoblastoma tumor suppressor gene product (p105-RB). Similar to the E7 protein of HPV-16, the E7 proteins of HPV-18, HBV-6b and HPV-11 were found to associate with p105-RB in vitro. The E7 proteins of HPV types associated with a high risk of malignant progression (HPV-16 and HPV-18) formed complexes with p105-RB with equal affinities. The E7 proteins encoded by HPV types 6b and 11, which are associated with clinical lesions with a lower risk for progression, bound to p105-RB with lower affinities. The E7 protein of the bovine papillomavirus type 1 (BPV-1), which does not share structural similarity in the amino terminal region with the HPV E7 proteins, was unable to form a detectable complex with p105-RB. The amino acid sequences of the HPV-16 E7 protein involved in complex formation with p105-RB in vitro have been mapped. Only a portion of the sequences that are conserved between the HPV E7 proteins and AdE1A were necessary for association with p105-RB. Furthermore, the HPV-16 E7-p105-RB complex was detected in an HPV-16-transformed human keratinocyte cell line.     

Study of stringency conditions for human papillomavirus DNA detection on cell lines,frozen and paraffin-embedded tissue sections by in situ hybridization with biotinylated probes

Summary In situ hybridization was mainly used for typing human papillomavirus (HPV) in paraffin-embedded or frozen sections under stringent conditions (SC). We tested 5 different conditions of stringency with biotinylated HPV 1, 2, 16 and 18 probes on 3 cell lines (Siha and CaSki with HPV16, HeLa with HPV18) by varying the concentration of formamide in the hybridization mixture and washings in order to determine the stringency conditions to be used to assess the presence of HPV and its typing: A-low stringency, hybridization at 35° C below the melting temperature of DNA (Tm-35° C) and washings without formamide; B-low stringency, hybridization and washings at Tm-35° C; C-medium stringency, hybridization at Tm-35° C and washings at Tm-12° C; D-high stringency, hybridization at Tm-12° C and washing without formamide; E-very high stringency, hybridization and washings at –12° C. This study showed that HPV typing required a high stringency. On the contrary, under non stringent conditions (NSC), each cell line was positive with the heterologous probes.When 3 to 5 stringency conditions were assayed on 4 frozen samples, similar results were obtained. Typing required high stringency conditions whereas NSC allowed HPV detection. Furthermore, this study demonstrated the specificity of the reaction in lesions positive with more than one type.Stringent (Tm-12° C) and non stringent (Tm-35° C) conditions of hybridization were further applied to 57 biopsy sections (17 frozen and 40 paraffin-embedded specimens) from typical wart lesions and lesions suspected of HPV. Nineteen samples were totally negative under both NSC and SC, and considered as non-infected by HPV. In 22 specimens positive, under both NSC and stringent conditions (SC), the HPV type was identified. Ten specimens reacted with 1, 2 or 3 HPV types under NSC but the HPV DNA was not typed with the probes used. Six lesions were negative under NSC but were typed under SC. Most paraffin sections were labeled only with one HPV probe under NSC, whereas frozen sections were often labeled with 2 or 3 HPV probes. The HPV probe positive under SC was usually positive under NSC in both frozen and paraffin sections. HPV type 1 probe was more frequently positive under NSC in paraffin- embedded sections than the others and the 4 probes tested were equally positive in frozen sections.These findings show the interest of in situ hybridization in low stringency conditions since 17% of our lesions (10/57) were positive only under NSC: HPV DNA was detected but not typed with the probes used. Frozen sections were more frequently positive than paraffin sections, suggesting a loss of DNA accessibility in the latter, due to the fixation or processing before hybridization.     

Skin cancer and virus]

Human papillomaviruses (HPV) generally associated with benign skin and anogenital warts. Because several of skin cancers were found to contain HPV-DNA, it has been speculated that certain types of HPV could be specifically associated with cancers. Although HPV-DNAs are not isolated from most of skin cancers, they are often isolated from penile cancers, vulval cancers and anogenital Bowen's diseases. Patients with epidermodysplasia verruciformis start to suffer from disseminated incurable warts during their childhood, and some of these benign lesions often convert to skin cancer in adulthood. Although the disease is very rare, HPV may also play a role in malignant transformation in epidermodysplasia verruciformis. More than 60 types of HPVs distinguished by molecular hybridization techniques. The type of HPV determines the clinical picture of wart and natural fate of HPV-associated lesion. There are two groups of HPVs, which are benign types and malignant types. Viral DNA of malignant type of HPV transforms human keratinocytes in vitro, and the transforming activity has been mapped to the E6 and E7 genes.     

Detection of HPV types and neutralizing antibodies in women with genital warts in Tianjin City,China

The serum samples and corresponding cervical swabs were collected from 50 women with genital warts from Tianjin city, China. The neutralizing antibodies against HPV-16, -18, -58, -45, -6 and -11 in serum samples were tested by using pseudovirus-based neutralization assays and HPV DNAs in cervical swabs were also tested by using a typing kit that can detect 21 types of HPV. The results revealed that 36% (18/50) of sera were positive for type-specific neutralizing antibodies with a titer range of 160–2560, of which 22%(11/50), 12%(6/50), 10%(5/50), 4%(2/50), 4%(2/50) and 2%(1/50) were against HPVs -6, -16, -18, -58, -45 and -11, respectively. Additionally, 60% (30/50) of samples were HPV DNA-positive, in which the most common types detected were HPV-68(18%), HPV-16(14%), HPV-58(12%), HPV-33(8%) and HPV-6, HPV-11, HPV-18 and HPV-52 (6% each). The concordance between HPV DNA and corresponding neutralizing antibodies was 56% (28/50) with a significant difference (P<0.05). The full-length sequences of five HPV types (HPV -42, -52, -53, -58 and -68) were determined and exhibited 98%–100% identities with their reported genomes. The present data may have utility for investigating the natural history of HPV infection and promote the development of HPV vaccines.     

Human papillomaviruses associated with epidermodysplasia verruciformis. II. Molecular cloning and biochemical characterization of human papillomavirus 3a, 8, 10, and 12 genomes.

The DNAs of four human papillomaviruses (HPVs) that were found in the benign lesions of three patients suffering from epidermodysplasia verruciformis have been characterized. The flat wart-like lesions and the macular lesions of patient 1 contained two viruses, HPV-3a and HPV-8, respectively, whose genomes had previously been only partially characterized. The flat wart-like lesions of patient 2 and the macular lesions of patient 3 each contained a virus previously considered as belonging to types 3 and 5, respectively. These viruses are shown in the present study to be different from all of the HPV types so far characterized; they have tentatively been named HPV-10 and HPV-12. The HPV-3a, HPV-8, and HPV-12 DNAs and the two SalI fragments of HPV-10 DNA (94.1 and 5.9% of the genome length) were cloned in Escherichia coli after having been inserted in plasmid pBR322. The cloned HPV genomes have similar sizes (about 7,700 base pairs), but their guanine-plus-cytosine contents differ from 41.8% for HPV-12 DNA to 45.5% for HPV-3a DNA. The study of the sensitivity of the four HPV DNAs to 14 restriction endonucleases permitted the construction of cleavage maps. Evidence for conserved restriction sites was found only for the HPV-3a and HPV-10 genomes since 5 of the 21 restriction sites localized in the HPV-3a DNA seem to be present also in the HPV-10 DNA. Hybridization experiments, performed in liquid phase at saturation, showed a 35% sequence homology between HPV-3a and HPV-10 DNAs, 17 to 29% sequence homology among HPV-5, HPV-8, and HPV-12 DNAs, almost no sequence homology between the HPV-3a or HPV-10 DNA and the other HPV DNAs, and a weak homology between HPV-9 DNA and HPV-8 or HPV-12 DNA. Blot hybridization experiments showed no sequence homology between the HPV-3a, HPV-8, and HPV-12 DNAs and the DNAs of the HPVs associated with skin warts (HPV-1a, HPV-2, HPV-4, and HPV-7) or with mucocutaneous and mucous membrane lesions (HPV-6b and HPV-11a, respectively). One exception was a weak sequence homology between the HPV-2 prototype and HPV-3a or HPV-10 DNA.(ABSTRACT TRUNCATED AT 400 WORDS)     

Presence of human papillomavirus genome in human tumor cell lines and cultured cells.

A series of 47 human carcinoma cell lines and their cultured cells were examined for human papillomavirus (HPV) genomes with the use of an HPV detection kit (DNA-RNA hybridization, mixed HPV DNA probe of types 6, 11, 16, 18, 31, 33 and 35). Four of 8 cases of mild dysplasia, 3 of 9 cases of severe dysplasia, 3 of 7 cases of carcinoma in situ, 3 of 15 cases of uterine carcinoma and 5 of 6 cases of condyloma acuminatum were shown to contain the HPV DNA genome in primary cultured cells, while HPV was not detected in the third-passage cells except for the three cases of large cell, nonkeratinizing squamous cell carcinoma. HPV was also not detected in such normal tissues as uterine cervical squamous epithelium, uterine cervical columnar epithelium and endometrium. The presence of HPV DNA genomes was detected consistently in the passages of three lines (SKG-II, HKMUS and HKTUS; large cell nonkeratinizing squamous cell carcinomas of the uterine cervix) with the use of the Southern Blot method (DNA-DNA hybridization, mixed HPV probe of types 6, 11, 16 and 18). HPV type 16 DNA was detected in HKTUS, and HPV type 18 DNA was found in SKG-II and HKMUS. The other 44 cell lines, including ovarian carcinoma, endometrial carcinoma, sarcoma, gastric cancer, pancreatic cancer and rectal cancer, were negative for the HPV-6, HPV-11, HPV-16, HPV-18, HPV-31, HPV-33 and HPV-35 genomes under stringent hybridization conditions.     

Histological and cytological evidence of viral infection and human papillomavirus type 16 DNA sequences in cervical intraepithelial neoplasia and normal tissue in the west of Scotland: evaluation of treatment policy

Biopsy samples from 27 patients referred to a colposcopy clinic in Glasgow for cervical abnormalities were assessed for the relations among colposcopic appearances, cytological and histological diagnosis, expression of papillomavirus antigen, and the presence of human papillomavirus (HPV) types 6, 11, 16, and 18 deoxyribonucleic acid (DNA) sequences. Specimens were from colposcopically abnormal areas of the transformation zone and from colposcopically apparently normal areas of the zone in the same patients (paired matched internal control tissue). All 27 women referred for abnormal smears had colposcopic abnormalities.HPV-16 or 18 DNA sequences were detected in 20 of the 27 colposcopically abnormal biopsy samples and 13 of the 27 paired normal samples. Twelve samples of colposcopically normal tissue contained histological evidence of viral infection but only four of these contained HPV DNA sequences. The other nine samples of colposcopically normal tissue which contained HPV DNA sequences were, however, histologically apparently normal. HPV-6 and 11 were not detected.Integration of the HPV-16 genome into the host chromosome was indicated in both cervical intraepithelial neoplasia and control tissues. In two thirds of the HPV DNA positive samples the histological grade was classed as normal, viral atypia, or cervical intraepithelial neoplasia grade 1. Papillomavirus antigen was detected in only six of the abnormal and three of the normal biopsy samples, and HPV DNA was detected in all of these.The detection of HPV DNA correlates well with a combination of histological and cytological evidence of viral infection (20 of 22 cases in this series). A poor correlation between the site on the cervix of histologically confirmed colposcopic abnormality and the presence of HPV DNA sequences implies that a cofactor other than HPV is required for preneoplastic disease to develop.A separate study in two further sets of biopsy samples examined the state of HPV DNA alone. The sets were (a) 43 samples from cervical intraepithelial neoplasia and nine external controls and (b) 155 samples from cervical intraepithelial neoplasia, cervical cancer, vulval intraepithelial neoplasia, and vulval cancer and external controls. HPV-11 was found in only two (4·7%) of the 43 specimens from cervical intraepithelial neoplasia, whereas HPV-16 was found in 90 (58%) of the other 155 specimens. These results also suggest that HPV subtype is subject to geographical location rather than being an indicator of severity of the lesion or of prognosis.     

Identification of multiple HPV types on spermatozoa from human sperm donors

Human papillomaviruses (HPV) may cause sexually transmitted disease. High-risk types of HPV are involved in the development of cervical cell dysplasia, whereas low-risk types may cause genital condyloma. Despite the association between HPV and cancer, donor sperm need not be tested for HPV according to European regulations. Consequently, the potential health risk of HPV transmission by donor bank sperm has not been elucidated, nor is it known how HPV is associated with sperm. The presence of 35 types of HPV was examined on DNA from semen samples of 188 Danish sperm donors using a sensitive HPV array. To examine whether HPV was associated with the sperm, in situ hybridization were performed with HPV-6, HPV-16 and -18, and HPV-31-specific probes. The prevalence of HPV-positive sperm donors was 16.0% and in 66.7% of these individuals high-risk types of HPV were detected. In 5.3% of sperm donors, two or more HPV types were detected. Among all identified HPV types, 61.9% were high-risk types. In situ hybridization experiments identified HPV genomes particularly protruding from the equatorial segment and the tail of the sperm. Semen samples from more than one in seven healthy Danish donors contain HPV, most of them of high-risk types binding to the equatorial segment of the sperm cell. Most HPV-positive sperm showed decreased staining with DAPI, indicative of reduced content of DNA. Our data demonstrate that oncogenic HPV types are frequent in men.