Rearrangements of host and viral DNA in mouse cells transformed by simian virus 40

Illegitimate DNA integration in mammalian cells

Foreign DNA integration is one of the most widely exploited cellular processes in molecular biology. Its technical use permits us to alter a cellular genome by incorporating a fragment of foreign DNA into the chromosomal DNA. This process employs the cell's own endogenous DNA modification and repair machinery. Two main classes of integration mechanisms exist: those that draw on sequence similarity between the foreign and genomic sequences to carry out homology-directed modifications, and the nonhomologous or 'illegitimate' insertion of foreign DNA into the genome. Gene therapy procedures can result in illegitimate integration of introduced sequences and thus pose a risk of unforeseeable genomic alterations. The choice of insertion site, the degree to which the foreign DNA and endogenous locus are modified before or during integration, and the resulting impact on structure, expression, and stability of the genome are all factors of illegitimate DNA integration that must be considered, in particular when designing genetic therapies.

Site-specific in situ amplification of the integrated polyomavirus genome: a case for a context-specific over-replication model of gene amplification

The fate of the genome of the polyoma (Py) tumor virus following integration in the chromosomes of transformed rat FR3T3 cells was re-examined. The viral sequences were integrated at a single transformant-specific chromosomal site in each of 22 transformants tested. In situ amplification of the viral sequences was observed in 24 of 34 transformants analyzed. Large T antigen, the unique viral function involved in initiating DNA replication from the viral origin, was essential for the amplification process. There was an absolute requirement for a reiteration of viral sequences and the extent of the reiteration affected the degree of amplification. The reiteration may be important for homologous recombination-mediated resolution of in situ amplified sequences. Among 11 transformants harboring a 1 to 2 kb repeat, the degree of amplification was transformant-specific and varied over a wide range. At the high end of the spectrum, the genome copy number increased 1300-fold at steady state, while at the low end, amplification was below twofold. Some aspect of the host chromatin at the site integration that affected viral gene expression, also directly or indirectly modulated the amplification. Use of high-resolution electrophoresis for the analysis of the integrated amplified sequences revealed a recurring novel pattern, consisting of a ladder with numerous bands separated by a constant distance approximately the size of the Py genome. We suggest that this pattern was generated by conversion of the amplified viral genomes to head to tail linear arrays with cell to cell variations in the number of genome repeats at single, transformant-specific, chromosomal sites. In light of the known "out of schedule" firing of the Py origin, we propose an "onion skin" structure intermediate and present a homologous recombination model for the conversion from onion skins to linear arrays. The relevance of the in situ amplification of the Py genome to cellular gene amplification is discussed. Finally, these results clarify our understanding of the integration of the Py genome in rat cells. They suggest that, in most cases, the multiple bands previously described in Py-transformants are likely to reflect genome amplification rather than multiple independent integration events, as assumed in the past. This interpretation is congruent with the accepted view that the integration of the Py genome is a rare and rate-limiting event in transformation.

The genomic instability associated with integrated simian virus 40 DNA is dependent on the origin of replication and early control region

DNA rearrangements in the form of deletions and duplications are found within and near integrated simian virus 40 (SV40) DNA in nonpermissive cell lines. We have found that rearrangements also occur frequently with integrated pSV2neo plasmid DNA. pSV2neo contains the entire SV40 control region, including the origin of replication, both promoters, and the enhancer sequences. Linearized plasmid DNA was electroporated into X1, an SV40-transformed mouse cell line that expresses SV40 large T antigen (T Ag) and shows very frequent rearrangements at the SV40 locus, and into LMtk-, a spontaneously transformed mouse cell line that contains no SV40 DNA. Stability was analyzed by subcloning G-418-resistant clones and examining specific DNA fragments for alterations in size. Five independent X1 clones containing pSV2neo DNA were unstable at both the neo locus and the T Ag locus. By contrast, four X1 clones containing mutants of pSV2neo with small deletions in the SV40 core origin and three X1 clones containing a different neo plasmid lacking SV40 sequences were stable at the neo locus, although they were still unstable at the T Ag locus. Surprisingly, five independent LMtk- clones containing pSV2neo DNA were unstable at the neo locus. LMtk- clones containing origin deletion mutants were more stable but were not as stable as the X1 clones containing the same plasmid DNA. We conclude that the SV40 origin of replication and early control region are sufficient viral components for the genomic instability at sites of SV40 integration and that SV40 T Ag is not required.

Genomic structure of the locus associated with an insertional mutation in line 4 transgenic mice

In line 4 transgenic mice, six to eight copies of a 50-kb lambda recombinant clone are arranged in a head-to-tail tandem array on chromosome 3. Embryos homozygous for the transgene become arrested in their development on Day 5 of gestation shortly after implantation. The insertion site was cloned using a small segment of the transgene as a probe. Comparison of the insertion site with the wildtype locus indicates that a 22-kb deletion of host DNA has occurred in line 4 mice. Restriction enzyme analyses showed that neither the tandem array nor the flanking chromosomal DNA had any detectable rearrangements. Sequencing of the junctions between host and foreign DNA, however, revealed insertions of small fragments of DNA of unknown origin as well as an insertion of a DNA segment derived from another region of the transgene. Therefore, disruption of an essential gene in the line 4 transgenic mouse may have been caused by the insertion of 300-400 kb of foreign DNA or a deletion of sequences in the host genome.

The role of recombinational hotspots in genome instability in mammalian cells

Genome instability has been associated with progression of transformed cells to high tumorigenicity. Although genome instability may result from a variety of factors, some studies suggest that DNA in the region of a chromosome rearrangement can subsequently have much higher rates of DNA deletions or gene amplification. One approach to studying the factors that produce these high rates of DNA rearrangement is by analysis of unstable integration sites for DNA transfected into mammalian cells. Integrated sequences commonly show a temporary instability, and at rare locations this instability is continuous and can be observed even after multiple subclonings. These continuously unstable locations undergo DNA amplification of both the integrated sequences and the surrounding cell DNA, and it can occur either at the original site or on episomes after looping out from the chromosome. Because the adjacent cell DNA plays a role in this instability, and the region can be shown to be stable before integration, the results indicate that these recombinational hotspots can be formed de novo by the process of integration. Current studies are attempting to determine which sequences are responsible for the high rates of recombination and whether similar types of event are involved in the instability associated with endogenous cellular genes in cancer cells.

Mutagenic activity of BKV and JCV in human and other mammalian cells

We present data suggesting that human polyomaviruses BKV and JCV, widely distributed throughout human populations, are able to induce gene mutations in cultured cells. In this study, using different infecting agents, cell lines to be infected, mutation expression periods, and selection systems, we observed mutagenic effects of varying extent with values of spontaneous mutant frequencies being increased after BKV infection up to 100-fold in BHK cells (6-thioguanine resistance) and nearly 35-fold in virus-transformed human Lesch-Nyhan cells (ouabain resistance). In experiments with BKV the viral mutagenic potential was found to be raised both in moderately uv-irradiated cells, or when wild-type virus was replaced by the variant BKV-IR isolated from a human tumor. Since BKV-IR is defective in the expression of small-t antigen, the viral mutagenicity does not require this protein to be active. BKV was shown to mutate, besides different established cell lines, human peripheral blood lymphocytes. Moreover, as demonstrated by comparing mutagenicities of DNAs from BKV, JCV, and the related polyomavirus SV40, the mutagenic effects of the three viruses do not appear to be essentially different. Implications of these findings are discussed.

Transforming activity of E5a protein of human papillomavirus type 6 in NIH 3T3 and C127 cells

Human papillomavirus type 6 (HPV-6) is the etiologic agent of genital warts and recurrent respiratory papillomatosis. We are investigating the mechanism by which this virus stimulates cell proliferation during infection. In this paper, we report that the E5a gene of HPV-6c, an independent isolate of HPV-11, is capable of transforming NIH 3T3 cells. The E5a open reading frame (ORF) was expressed under the control of the mouse metallothionein promoter in the expression vector pMt.neo.1, which also contains the gene for G418 resistance. Transfected cells were selected for G418 resistance and analyzed for a transformed phenotype. The transformed NIH 3T3 cells overgrew a confluent monolayer, had an accelerated generation time, and were anchorage independent. In contrast, E5a did not induce foci in C127 cells, but C127 cells expressing E5a did form small colonies in suspension. The presence of the 12-kilodalton E5a gene product in the transformed NIH 3T3 cells was shown by immunoprecipitation and was localized predominantly to nuclei by an immunoperoxidase assay. A mutation in the E5a ORF was engineered to terminate translation. This mutant was defective for transformation, demonstrating that translation of the E5a ORF is required for biological activity. This is the first demonstration of a transforming oncogene in HPV-6, and the differential activity of E5a in these two cell lines should facilitate future investigations on the mechanism of transformation.

Influence of cellular sequences on instability of plasmid integration sites in human cells

To learn more about mechanisms of genome instability in human cells, I investigated DNA sequences that promote high rates of recombination by analyzing rare unstable plasmid integration sites in simian virus 40-transformed human fibroblasts. Previous studies had hypothesized that rearrangement or loss of integrated sequences could be attributed to adjacent cellular DNA. Consistent with this interpretation, a cloned fragment containing both the integrated plasmid and 2.0 kb of adjacent cell DNA from one such unstable integration site in the cell line LM205 demonstrated a much higher incidence of rearrangements when integrated into other chromosome locations than did the original plasmid. To further test this hypothesis, portions of cellular DNA from this region were integrated in duplicate in other locations to determine their ability to promote restriction-fragment-length polymorphism, an indicator of high rates of homologous recombination. Although two types of instability were observed, neither could be attributed solely to the cell sequences being tested in the plasmid. The first type of instability was a transient deletion or amplification of the plasmid DNA soon after integration, which appeared to be a general phenomenon often associated with any type of newly integrated sequence. A second type of instability continued indefinitely for many cell generations, as did that observed in cell line LM205. Because this was rare (one of 78 clones tested), it could not be attributed solely to cell sequences contained within the plasmid. However, the rearrangements in this cell clone occurred exclusively within the cell DNA adjacent to the integration site, again suggesting a role for cis-acting cell sequences in this process. The inability to identify specific cell sequences responsible for instability may therefore indicate that a complex combination of sequences is involved, possibly within both the plasmid and cell DNA.

Nucleotide sequence analysis of novel junctions near an unstable integrated plasmid in human cells

Characterization of human cell clones containing a promoterless selectable gene (neo), integrated at various locations in the genome, demonstrated that one of the integration sites had a high rate of spontaneous tandem duplications. Other investigators have suggested that specific sequences, such as short repeats, found near an integration site, could be responsible for this kind of instability. To learn more about this process, we sequenced the DNA at the recombination site in two independently derived subclones, and compared these sequences with those found in the parental cell DNA. The results demonstrate that specific sequences are not required at the recombination site. In one G418-resistant subclone, recombination occurred between an Alu retroposon in the cellular DNA and integrated pBR322 sequences sharing 3 bp of similarity at the recombination site. In the other subclone, recombination occurred between single-copy cellular DNA and integrated simian virus 40 sequences sharing a single bp of similarity at the recombination site. This heterogeneity at the recombination site indicates a general enhancement of the rate of recombination within the entire region, with little if any sequence specificity or similarity required.

Structural analysis of human papillomavirus type 6c isolates from condyloma acuminatum and juvenile-onset and adult-onset laryngeal papillomata

The human papillomavirus type 6c (HPV-6c) genome was molecularly cloned from biopsy specimens of a juvenile-onset and an adult-onset respiratory-tract papillomata and a condyloma acuminatum of the cervix. To determine if the genital-tract isolate and respiratory-tract isolates contain divergent sequences that may account for a difference in tissue trophism or for a difference in the age of onset of the disease, fine-structure mapping, heteroduplex analysis by electron microscopy, and nucleotide sequencing were used to examine the sequence relationship among these HPV-6c isolates. No differences were found in the digestion patterns with 23 restriction enzymes. Heteroduplex analysis among the three genomes demonstrated that they were colinear without apparent deletions or rearrangements and had greater than 90% sequence identity. In heteroduplex analyses with a different subtype (HPV-6e) that was molecularly cloned from a genital wart, the genomes were colinear with greater than 90% sequence identity over 90% of their length. The most divergent region had 75-80% sequence identity and was localized to the part of the genome containing the E5a and E5b open reading frames (ORFs). Comparison of the sequence of 1430 nucleotides in this region for two of the HPV-6c isolates did not identify any differences between them. Comparison with the published sequences of HPV-6b identified deletions/insertions and base changes with approximately 75% sequence identity, and comparison with HPV-11 identified only six base changes. Conservation of sequences in the E4-E5 region and similarity in the restriction enzyme maps demonstrated that HPV-6c and HPV-11 are independent isolates of the same HPV-6 subtype.

Excision of integrated simian virus 40 DNA involving homologous recombination between viral DNA sequences

We have investigated the structure of simian virus 40 (SV40) DNA integrated into the genome of transformed mouse mKS-A cells. We have identified at least six independent integration units containing intact or truncated SV40 DNA sequences. One integration unit was isolated from a genomic mKS-A cell library and investigated by restriction enzyme analysis and partial nucleotide sequencing. This integration unit contains one apparently intact SV40 genome flanked on both sides by truncated versions of the SV40 genome. One of the flanking elements contains a large deletion in the SV40 "late" region and an abbreviated SV40 "early" region. This element was efficiently excised and mobilized after fusion of mKS-A to COS cells. The excision products invariably included the entire SV40 early region even though they were derived from an integrated element lacking this part of the SV40 genome. An analysis of this discrepancy led to the conclusion that the early region sequences were acquired by homologous recombination and, furthermore, that homologous excisional recombination was clearly preferred over non-homologous recombination.

Association of high rate of recombination with amplification of dominant selectable gene in human cells

The human cell line LM205, transformed with the pLR309 plasmid, contains a stably integrated selectable gene marker (neo) without a transcriptional promoter. Spontaneous tandem duplication at the integration site relocates a Simian virus 40 transcriptional promoter to a position 5' to the neo gene at a rate of 5 x 10(-8) events/cell/generation, as measured by subsequent resistance of the cells to the toxic antibiotic G418. The heterogeneity in the site of recombination observed in various G418-resistant (G418-R) subclones indicates that the sequences involved have little or no homology. The rate of tandem duplication involving the neo gene was not affected by DNA-damaging agents or by inhibitors of DNA synthesis. Although these tandem duplications were relatively stable in most G418-R subclones, others underwent further amplification of the neo gene during cloning. In one such cell line, RS-4, subclones isolated without G418 demonstrated a high degree of heterogeneity in the neo gene copy number (2-20), indicating that amplification was associated with a high rate of homologous recombination. Because LM205 was the only clone out of the 30 original clones transformed with pLR309 that demonstrated spontaneous G418-R colonies, cell DNA sequences near the integrated neo gene may promote this recombination. Inclusion of this cell DNA in the initial tandem duplication might then explain the high rate of duplication and deletion observed in the region of the neo gene in the RS-4 subclone.

Cellular DNA rearrangements and early developmental arrest caused by DNA insertion in transgenic mouse embryos

Insertional mutagenesis was investigated in a transgenic mouse strain (HUGH/4) derived from a fertilized egg injected with plasmid DNA containing the human growth hormone gene. Lethality occurred in homozygous embryos and was traced to the egg cylinder stage on days 4 to 5 of gestation, shortly after implantation. The mutation is on chromosome 12 and is distinct in location and integration pattern from another mutation also leading to lethality of homozygotes in the egg cylinder stage. Based on this and other evidence, relatively many genes may be recruited to activity near the time of implantation and may therefore present a large target of vulnerability to mutagenesis. The single insert in HUGH/4, consisting of approximately three tandem copies of plasmid sequences, is flanked by mouse cellular sequences that have undergone rearrangements, including a probable deletion. The data suggest the hypothesis that DNA rearrangements, which appear to be commonplace in transgenic mice, may arise because the initial insertional complex is unstable; stepwise changes may then be generated until a more stable conformation is achieved.

Cellular DNA rearrangements and early developmental arrest caused by DNA insertion in transgenic mouse embryos

Insertional mutagenesis was investigated in a transgenic mouse strain (HUGH/4) derived from a fertilized egg injected with plasmid DNA containing the human growth hormone gene. Lethality occurred in homozygous embryos and was traced to the egg cylinder stage on days 4 to 5 of gestation, shortly after implantation. The mutation is on chromosome 12 and is distinct in location and integration pattern from another mutation also leading to lethality of homozygotes in the egg cylinder stage. Based on this and other evidence, relatively many genes may be recruited to activity near the time of implantation and may therefore present a large target of vulnerability to mutagenesis. The single insert in HUGH/4, consisting of approximately three tandem copies of plasmid sequences, is flanked by mouse cellular sequences that have undergone rearrangements, including a probable deletion. The data suggest the hypothesis that DNA rearrangements, which appear to be commonplace in transgenic mice, may arise because the initial insertional complex is unstable; stepwise changes may then be generated until a more stable conformation is achieved.

Inducible gene expression by DNA rearrangements in human cells

A permanent human cell line, cell line LM205, was established by transforming primary human fibroblasts with a plasmid containing both simian virus 40 sequences with a defective origin of replication and a G418 resistance gene (neo) that lacked a eucaryotic transcriptional promoter. G418-resistant cells appeared spontaneously in clonal populations of LM205 cells at a frequency of approximately 10(-5) cell per cell plated in the presence of 400 micrograms of G418 per ml. G418 resistance was stable and correlated with the appearance of neo-specific RNA. Characterization of the neo gene in the G418-sensitive parental cell line by both a Southern blot analysis and a restriction map analysis of cloned sequences demonstrated that there was a stable integration site containing a single neo coding sequence. A Southern blot analysis of five G418-resistant subclones indicated that there were heterogeneous DNA rearrangements in the region of the neo gene that were unique in each subclone. Restriction mapping of a fragment containing the neo gene isolated from one of the resistant subclones demonstrated that the rearrangement was a tandem duplication that resulted in the relocation of the simian virus 40 bidirectional transcriptional promoter 5' to the neo gene. Tandem duplication was also consistent with the Southern blot polymorphisms observed in the other resistant subclones, suggesting that there were heterogeneous sites of recombination with respect to both the neo gene and the simian virus 40 promoter. Although these rearrangements resulted in an increase in neo gene copy number per cell, amplification showed no correlation quantitatively with the large increase in neo-specific RNA in these cells. Therefore, G418-resistant colony formation in cell line LM205 provides a method for studying both the mechanisms involved in this type of recombination and the factors influencing its frequency.

Molecular aspects of persistent woodchuck hepatitis virus and hepatitis B virus infection and hepatocellular carcinoma

It seems evident that the development of fully malignant HCC is a multistage process with many variables. One possible mechanism by which many of these variables may interact is as follows. During chronic active hepatitis, viral DNA integration occurs randomly and at a low frequency in hepatocytes. Integration may be stimulated by the increased rate of hepatocyte cell division resulting from liver necrosis and regeneration during chronic disease. The presence of viral integrations in the cellular genome provides focal points for the generation of chromosomal aberrations. One pathway by which these aberrations may be generated involves rearrangement of integrated viral and cellular sequences following viral DNA integration. The rearrangements which occur may include deletion, translocation, transposition or amplification of specific viral and cellular DNA sequences. We and others have directly demonstrated that all of these events are associated with different HBV integrations. The presence of viral integrations in chromosomes may also, by some unknown mechanism, destabilize those chromosomes such that whole chromosomes fail to segregate and are lost from particular cells. Preliminary studies we have conducted using restriction fragment length polymorphisms have revealed the loss of Chromosome 11 alleles in several HCC, indicating that chromosome loss may be a common occurrence in HCC. Our studies with restriction fragment length polymorphisms support such a mechanism involving Chromosome 11 in HCC. Specific chromosomal aberrations associated with all HCCs have not yet been identified.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluctuation of simian virus 40 (SV40) super T-antigen expression in tumors induced by SV40-transformed mouse mammary epithelial cells

Higher-molecular-weight forms of the simian virus 40 (SV40) large tumor antigen (T-Ag), designated super T-Ag, are commonly found in SV40-transformed rodent cells. We examined the potential role of super T-Ag in neoplastic progression by using a series of clonal SV40-transformed mouse mammary epithelial cell lines. We confirmed an association between the presence of super T-Ag and cellular anchorage-independent growth in methylcellulose. However, tumorigenicity in nude mice did not correlate with the expression of super T-Ag. In the tumors that developed in nude mice, super T-Ag expression fluctuated almost randomly. Cell surface iodination showed that super T-Ag molecules were transported to the epithelial cell surface. The biological functions of super T-Ag remain obscure, but it is clear that it is not important for tumorigenicity by SV40-transformed mouse mammary epithelial cells. Super T-Ag may be most important as a marker of genomic rearrangements by the resident viral genes in transformed cells.

Early postimplantation embryo lethality due to DNA rearrangements in a transgenic mouse strain

Insertional mutagenesis in a transgenic mouse strain (HUGH/3) was caused by integration of plasmid DNA containing the human growth hormone gene and pBR322 plasmid sequences. From this study, which includes another instance of mutagenesis, and from other reports, it is apparent that insertional mutagenesis occurs fairly frequently during DNA integration in the mouse egg and that it is not specific for the exogenous DNA employed. The mutation in HUGH/3 is recessive and results in death of embryos homozygous for the donor sequences shortly after implantation, at the egg cylinder stage on days 4-5 of gestation. Restriction mapping of the insert and of the flanking DNA regions indicates that integration must have involved a series of complex events. Approximately five copies of plasmid sequences are arrayed in tandem but are interrupted at least twice by mouse cellular sequences. In addition, the mouse flanking DNA shows extensive rearrangements, probably including a deletion of at least 10 kilobases. The rearrangements may reflect an initially unstable DNA structure followed by attainment of a more stable conformation.

Inducible gene expression by DNA rearrangements in human cells

A permanent human cell line, cell line LM205, was established by transforming primary human fibroblasts with a plasmid containing both simian virus 40 sequences with a defective origin of replication and a G418 resistance gene (neo) that lacked a eucaryotic transcriptional promoter. G418-resistant cells appeared spontaneously in clonal populations of LM205 cells at a frequency of approximately 10(-5) cell per cell plated in the presence of 400 micrograms of G418 per ml. G418 resistance was stable and correlated with the appearance of neo-specific RNA. Characterization of the neo gene in the G418-sensitive parental cell line by both a Southern blot analysis and a restriction map analysis of cloned sequences demonstrated that there was a stable integration site containing a single neo coding sequence. A Southern blot analysis of five G418-resistant subclones indicated that there were heterogeneous DNA rearrangements in the region of the neo gene that were unique in each subclone. Restriction mapping of a fragment containing the neo gene isolated from one of the resistant subclones demonstrated that the rearrangement was a tandem duplication that resulted in the relocation of the simian virus 40 bidirectional transcriptional promoter 5' to the neo gene. Tandem duplication was also consistent with the Southern blot polymorphisms observed in the other resistant subclones, suggesting that there were heterogeneous sites of recombination with respect to both the neo gene and the simian virus 40 promoter. Although these rearrangements resulted in an increase in neo gene copy number per cell, amplification showed no correlation quantitatively with the large increase in neo-specific RNA in these cells. Therefore, G418-resistant colony formation in cell line LM205 provides a method for studying both the mechanisms involved in this type of recombination and the factors influencing its frequency.

Deletion in chromosome 11p associated with a hepatitis B integration site in hepatocellular carcinoma

Hepatitis B virus (HBV), a virus with known carcinogenic potential, integrates into cellular DNA during long-term persistent infection in man. Hepatocellular carcinomas isolated from viral carriers often contain clonally propagated viral DNA integrations. As small chromosomal deletions are associated with several types of carcinomas, the occurrence of chromosomal deletions in association with HBV integration in hepatocellular carcinoma was studied. HBV integration was accompanied by a deletion of at least 13.5 kilobases of cellular sequences in a human hepatocellular carcinoma. The viral DNA integration and deletion of cellular sequences occurred on the short arm of chromosome 11 at location 11p13-11p14. The cellular sequences that were deleted at the site of HBV integration were lost from the tumor cells, leaving only a single copy of the remaining cellular allele.

Establishment and characterization of a permanent pSV ori--transformed ataxia-telangiectasia cell line

A permanent ataxia-telangiectasia (A-T) cell line has been established from the fibroblast strain AT2SF after transfection with the bacterial plasmid pSV ori-, which contains replication origin-defective SV40 sequences. The original transfection frequency, as measured by transformed foci, was markedly reduced in two A-T strains when compared with either normal or xeroderma pigmentosum fibroblasts. As with SV40 virion-transformed fibroblasts, pSV ori--transformed cells entered a crisis phase, from which about one-fourth of the original clones from A-T and normal fibroblasts recovered. Both the pSV ori--transformed TAT2SF cell line and an SV40 virion-transformed AT5BI (GM5489) cell line retained their characteristic sensitivity to the lethal effects of ionizing radiation, as well as their X ray-resistant DNA synthesis. Southern blot analysis of cellular SV40 sequences demonstrated a single major integration site of pSV ori- in the AT2SF cells. In contrast, AT5BI cells transformed with SV40 virions demonstrated a high degree of heterogeneity of integrated viral sequences. Neither the TAT2SF nor the GM5489 transformed cell line contains any detectable freely replicating SV40 viral sequences, which are seen in many other semipermissive SV40-transformed cells.

Molecular structures of mitochondrial-DNA-like sequences in human nuclear DNA

Two lambda phage clones carrying mitochondrial-DNA-like (mtDNA-like) sequences isolated from a human gene library were named Lm E-1 and Lm C-2, and their DNA structures were characterized. Lm E-1 contains about 0.4 kb DNA homologous to the 5' portion of the mitochondrial 16S ribosomal RNA (rRNA) gene and Lm C-2, a 1.6 kb DNA homologous to the 3' portion of the 12S rRNA gene and to almost all of the 16S rRNA gene. Comparisons of their nucleotide sequences with those of the corresponding regions of the human mtDNA revealed no detectable DNA rearrangement and their homologies to the human mtDNA are 84% and 80%, respectively. There are neither terminal repeats in the nuclear mtDNA-like sequences nor duplications of the nuclear DNAs flanking the mtDNA-like sequences. Evolutionary relationship between these two human nuclear mtDNA-like sequences and the human and bovine mtDNAs is discussed.

Genetic heterogeneity of the human papovaviruses BK and JC

We have examined the structure and infectivity of BKV and JCV genomes from prototype strains after cell culture passage and of BKV genomes from primary isolates. Genomic structures were determined by restriction endonuclease analysis of molecularly cloned DNA. Infectivity was determined by transfection of the cloned genomes into urine-derived epithelial cells and assaying for viral proteins and virus production. Prototype BKV DNA, which was cloned after 14 passages in three different cell lines, contained no alterations in restriction enzyme sites and was infectious. In contrast, prototype JCV acquired changes in the late region of the genome during passage in cell culture and the cloned DNA was not infectious. Urine-derived cells were used to isolate virus from the urine of two renal transplant patients and one asymptomatic individual. The genome of the virus isolated from the normal individual was indistinguishable from prototype BKV except for a 60-base pair deletion, which was localized between 0.62 and 0.72 map units. Two isolates from transplant patients differed from each other and from prototype BKV at a number of restriction enzyme cleavage sites located in the early region and were infectious. Genomes containing deletions from 100 to 600 base pairs were also cloned but were not infectious.