We investigated the structure of adenovirus deoxyribonucleic acid (DNA)-protein complexes in nuclei of infected cells by using micrococcal nuclease. Parental (infecting) DNA was digested into multimers which had a unit fragment size that was indistinguishable from the size of the nucleosomal repeat of cellular chromatin. This pattern was maintained in parental DNA throughout infection. Similar repeating units were detected in hamster cells that were nonpermissive for human adenovirus and in cells pretreated with n-butyrate. Late in infection, the patternm of digestion of viral DNA was determined by two different experimental approaches. Nuclear DNA was electrophoresed, blotted, and hybridized with labeled viral sequences; in this procedure all virus-specific DNA was detected. This technique revealed a diffuse protected band of viral DNA that was smaller than 160 base pairs, but no discrete multimers. All regions of the genome were represented in the protected DNA. To examine the nuclease protection of newly replicated viral DNA, infected cells were labeled with [3H]thymidine after blocking of cellular DNA synthesis but not viral DNA synthesis. With this procedure we identified a repeating unit which was distinctly different from the cellular nucleosomal repeat. We found broad bands with midpoints at 200, 400, and 600 base pairs, as well as the limit digest material revealed by blotting. High-resolution acrylamide gel electrophoresis revealed that the viral species comprised a series of closely spaced bands ranging in size from less than 30 to 250 base pairs.Histones, the ubiquitous structural proteins of eucaryotic chromatin, are complexed with deoxyribonucleic acid (DNA) in repeating units called nucleosomes. The repeating element of chromatin structure has been characterized by electron microscopy and by digestion with micrococcal nuclease, which cuts between nucleosomes, yielding a multimeric array of DNA fragments (19,29
Human papillomavirus type 6 (HPV-6) DNA was detected in a rapidly growing vulvar verrucous carcinoma and two recurrent tumor samples. The viral DNA (HPV-6vc) was molecularly cloned and found to have a high degree of DNA sequence homology to HPV-6b DNA. Comparison of restriction endonuclease cleavage patterns between HPV-6b and HPV-6vc genomes and DNA sequencing analysis demonstrated an additional 106 bases in the HPV-6vc genome. These additional nucleotides were located in the noncoding region of the viral genome which contains the putative viral DNA replication and early gene transcriptional control elements. Seventy-four of the additional 106 nucleotides were found as one insert in the purine-thymidine-rich region 3' to the end of the LI open reading frame. This 74-base-pair addition had homology with viral sequences immediately upstream to it and to poly(dG-dT) sequences found in the human genome including the conserved repeated sequences in human DNA (EC1) and in the human cardiac muscle actin gene. Two smaller inserts, 19 and 15 nucleotides, were found upstream from the transcriptional control elements and demonstrate homology with regions of human alpha and gamma interferon genes.
The genome of deer papillomavirus (DPV) isolated from American white-tailed deer was cloned into pBR322, and the entire nucleotide sequence of 8,374 base pairs was determined. The overall genetic organization of the DPV genome was similar to that of other papillomaviruses. All significant open reading frames were located on one strand, and the locations of putative promoters and polyadenylation signals were similar to those identified in the closely related bovine papillomavirus type 1 (BPV-1) genome. The DPV genome was approximately colinear with BPV-1 except for a noncoding region separating the early and late regions. The regions of highest nucleotide sequence homology between DPV and BPV-1 were found in the E1 open reading frame coding for BPV-1 DNA replication function and in the L1 open reading frame, which encodes the major capsid protein of BPV-1.
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