Faculty Bibliography

We have compared the ability of cloned DNAs of HPV16, a human papillomavirus associated with cervical carcinoma, and BPV1, a papillomavirus inducing skin lesions in cattle, to transform murine C127 cells. Unlike BPV1, HPV16 DNA failed to induce foci when C127 cells were transfected and maintained as monolayers; HPV16-transformed C127 cells could only be detected after cotransfection with HPV16 and pSV2neo DNA, selection for resistance to G418, and assay of pooled selectants for colony growth in agar. HPV16 and BPV1 C127 cells differed in terms of the size and morphology of their colonies in agar, but not in their colony-forming efficiencies. In addition, the tumors they induced in nude mice were clearly histologically distinct, with the HPV16 C127 tumors considerably more anaplastic. The HPV16 C127 cells contained viral DNA at high copy numbers integrated at random sites in the C127 genome, while the BPV1 C127, as expected, contained episomal BPV1 DNA molecules. The high complexity of the integrated HPV16 DNA was maintained in the pooled cells grown through extended passage in vitro, in clonal lines derived from single agar colonies, in nude mouse tumors induced by the cells, and in a nude mouse tumor-derived cell line, indicating the stability of the HPV16 sequences in the cells. HPV16 transcripts in the transformed C127 cells were present in three size classes (1.5, 2, and 4 kilobases) on Northern blots. The different transformed phenotypes in the same cell line induced by two structurally similar, yet distinct viruses imply differences in the underlying transforming mechanisms and possible different virus-host cell molecular interactions

We demonstrate DNA binding by papillomavirus (PV) open reading frame (ORF) proteins that correspond to the early transforming and trans-activating (E6 and E2) and late structural regions (L2 and L1) from bovine PV type 1 and human PV types 6b and 16. All PV proteins were synthesized in Escherichia coli and had a common 13-amino-acid leader sequence from the expression vector pRA10. Antibodies have been generated in rabbits against these PV proteins. The PV ORF proteins bind double-stranded DNA, and this activity is demonstrated to be inherent to the PV proteins. DNA-binding activity by PV proteins is optimal at 50 mM NaCl and at pH 7.0. For some PV proteins (e.g., bovine PV type 1 E2), DNA binding is enhanced at a lower pH (pH 6.0) and NaCl concentration (50 to 100 mM). DNA binding is inhibited by the appropriate antibodies. The possible significance of these findings is discussed in relation to the genetic and structural evidence on the function of these ORFs

A new expression vector, pRA10, has been constructed for the expression of the open reading frames (ORF) of bovine (B) and human (H) papilloma viruses (PV). This vector is a derivative of pAJ pi and contains 15 restriction sites proximal to the lambda PL promoter, offering considerable versatility for insertion of different ORFs. This vector was used specifically to express the E2 ORF gene products from BPV1 and HPV6b at high level in Escherichia coli. The genuine nature of these proteins was demonstrated by restriction map analysis of expression vector plasmids to insure proper orientation, nucleotide sequence analysis to demonstrate in-frame insertion, E2 ORF protein production by expression-vector plasmids, and not by appropriate controls and, immunoprecipitation of E2 proteins by antibody specific for a common N-terminal sequence derived from the expression vector

Previous reports from this laboratory indicate that cultured simian virus 40 (SV40)-transformed human keratinocytes express keratin proteins characteristic of simple epithelia that are not found in their untransformed counterparts. In this study we show by in vitro translation and RNA transfer blot analysis that the altered keratin synthesis reflects changes in the abundance of specific keratin mRNAs. SV40-transformed keratinocytes have a reduced abundance of transcripts for 58-, 56-, 52-, 50-, 48-, and 46-kDa keratin species, compared with uninfected cultured keratinocytes, but express significant levels of transcripts for 52-, 45-, and 40-kDa keratins, typical of simple epithelia. The SV40-transformed cells also express mRNA for a 48-kDa keratin that is unique to SV40-transformed keratinocytes. Analysis of the keratin genome with keratin-specific cDNAs as probes indicates that the changes in keratin transcription are not correlated with gross rearrangements of the keratin genome. These results suggest that analysis of viral transformation of cultured keratinocytes affords a novel approach to study mechanisms regulating keratin gene expression

Transformation of human epidermal keratinocytes by the oncogenic virus SV40 is a stage-specific process in which normal patterns of differentiation are progressively altered over time following infection. Within the context of this scheme, we examined the keratins produced by the infected cells. Immunofluorescence studies indicated that viral infection led to the formation of variant cells visibly lacking the normal keratin cytoskeleton after about 10-15 serial passages (60-90 cell generations) post infection. Analyses of variant cell formation in clonal populations grown on palladium islands revealed that the variants were derived within 2-3 cell divisions from cells containing an apparently normal keratin cytoskeleton, but that variant formation depended upon cell density. Immunoprecipitation of 35S-methionine labelled keratins from the infected keratinocytes revealed a gradual loss of the normal 46, 50, 56 and 58Kd keratin species over a period of many months after infection. The loss of the normal keratins was accompanied by the appearance of at least two species in the 48-52Kd size range not present in uninfected cells and the enhancement of a third, 40Kd, protein quite early after infection. Analysis of the altered keratin patterns on two-dimensional acrylamide gels using either isoelectric focusing (IEF) or non-equilibrium pH gradient electrophoresis (NEPHG) along the first dimension showed that the infected cells produced basic keratins which increased in relative abundance as cells became more transformed with serial passage including at least five isoelectric forms not seen in uninfected cells. Translation of poly A+ RNAs from the infected cells indicated that the altered keratin synthesis probably reflects changes in the translatable mRNA pool

We have studied the synthesis and distribution of fibronectin in human epidermal keratinocytes infected by SV40, a system in which the acquisition of transformed properties occurs in a sequential and progressive manner. Immunofluorescence studies showed that cultured uninfected keratinocytes do not exhibit fibronectin on the superficial cell surface, but that virus-infected cells come to display superficial fibronectin-containing cables in a density-dependent manner after a certain point in the transformation process. In contrast, organized arrays of fibronectin-containing fibrils associated with the cell-substrate attachment complex were seen in uninfected keratinocytes and in virus-infected cells at all stages of the transformation process. Studies of fibronectin synthesis using metabolic labelling of cell proteins with 35S methionine showed that viral infection caused a striking increase in overall fibronectin synthesis, although with a much higher proportion of newly synthesized fibronectin being secreted into the cell culture medium than in the case of the uninfected cells

Previous studies have indicated that some Simian-virus-40-transformed human epidermal keratinocytes (SV40-HE) undergo significant changes in their growth and differentiated properties. To better understand the significance of these changes, we have characterized the keratins of SV40-HE cells by one- and two-dimensional immunoblot analysis using the subfamily-specific AE1 and AE3 monoclonal antikeratin antibodies. The results indicate that our SV40-HE cells have lost the Mr 58,000 (No. 5), Mr 56,000 (No. 6), Mr 50,000 (No. 14/15), Mr 48,000 (No. 16), and Mr 46,000 (No. 17) keratins that are expressed by cultured normal human keratinocytes. Instead, these cells express mainly Mr 52,000 (No. 8), Mr 45,000 (No. 18), and Mr 40,000 (No. 19) keratins, a set highly characteristic of simple epithelial cells. Furthermore, our SV40-HE cells have ceased to express involucrin, another marker for keratinocytes, and have a greatly diminished ability to undergo in vitro stratification. These results suggest that epidermal cells can sometimes lose their keratinocyte features as a consequence of viral transformation. This finding may have important implications regarding the mechanisms of epithelial differentiation and tumorigenesis and in the use of keratinocyte markers for tumor diagnosis

Primary tumors induced by Simian Virus 40 (SV40) in nude mice, lines derived from them, and subsequent transplanted tumors were analyzed as to the state of the viral DNA. It was found that SV40 DNA is present only as integrated molecules, each tumor having a different integration pattern; all tumors were SV40 T-antigen positive by immunofluorescence. One tumor and its derivatives in vitro and in vivo have maintained a single integration structure consisting of a head-to-tail arrangement of a molecule slightly larger than whole-length viral DNA (approximately equal to 1.1). This tumor expresses a full-sized T-antigen and a Mr 54,000 host-associated protein