Long terminal repeat (LTR)-derived recombination of retroviral DNA: sequence analyses of an aberrant clone of baboon endogenous virus DNA which carries an inversion from the LTR to the gag region

Molecular characterization of human immunodeficiency virus type 1 cloned directly from uncultured human brain tissue: identification of replication-competent and -defective viral genomes

All presently available replication-competent proviral clones of human immunodeficiency virus type 1 (HIV-1) are derived from cell culture-amplified virus. Since tissue culture is highly selective for viral strains with an in vitro growth advantage, such clones may not be representative of the biologically relevant virus present in vivo. In this study, we report the molecular cloning and genotypic characterization of 10 HIV-1 genomes directly from uncultured brain tissue of a patient with AIDS dementia complex. Targeting unintegrated circular HIV-1 molecules for recombinant lambda phage cloning, we obtained four full-length genomes with one or two long terminal repeats (LTRs), three defective genomes with internal deletions, two rearranged genomes with inverted LTR sequences, and one integrated proviral half with flanking cellular sequences. Nucleotide sequence analysis of these clones demonstrated chromosomal integration, circle formation, genomic inversion, and LTR-mediated autointegration of HIV-1 genomes in vivo. Comparison of a 510-bp hypervariable envelope region among 8 lambda phage-derived and 12 polymerase chain reaction-derived clones from the same brain specimen identified a predominant viral form as well as genetically divergent variants. Variability among 19 of 20 clones ranged between 0.2 and 1.2%. One clone exhibited 8.2% nucleotide sequence differences consisting almost exclusively of G-to-A changes. Transfection of the four full-length HIV-1 genomes identified one clone (YU-2) as replication competent and exhibiting growth characteristics similar to those of tissue culture-derived macrophage tropic strains of HIV-1. These results demonstrate, for the first time, that replication-competent HIV-1 genomes, complex mixtures of defective viral forms, and chromosomally integrated provirus persist in vivo. In addition, the brain-derived viral clones are expected to prove valuable for future studies of macrophage and neurotropism as well as for the analysis of other viral properties that are subject to in vitro selection pressures.

Rearrangements in unintegrated retroviral DNA are complex and are the result of multiple genetic determinants

We used a replication-competent retrovirus shuttle vector based on a DNA clone of the Schmidt-Ruppin A strain of Rous sarcoma virus to characterize rearrangements in circular viral DNA. In this system, circular molecules of viral DNA present after acute infection of cultured cells were cloned as plasmids directly into bacteria. The use of a replication-competent shuttle vector permitted convenient isolation of a large number of viral DNA clones; in this study, over 1,000 clones were analyzed. The circular DNA molecules could be placed into a limited number of categories. Approximately one-third of the rescued molecules had deletions in which one boundary was very near the edge of a long terminal repeat (LTR) unit. Subtle differences in the patterns of deletions in circular DNAs with one versus two copies of the LTR sequence were observed, and differences between deletions emanating from the right and left boundaries of the LTR were seen. A virus with a missense mutation in the region of the pol gene responsible for integration and exhibiting a temperature sensitivity phenotype for replication had a marked decrease in the number of rescued molecules with LTR-associated deletions when infection was performed at the nonpermissive temperature. This result suggests that determinants in the pol gene, possibly in the integration protein, play a role in the generation of LTR-associated deletions. Sequences in a second region of the genome, probably within the viral gag gene, were also found to affect the types of circular viral DNA molecules present after infection. Sequences in this region from different strains of avian sarcoma-leukosis viruses influenced the fraction of circular molecules with LTR-associated deletions, as well as the relative proportion of circular molecules with either one or two copies of the LTR. Thus, the profile of rearrangements in unintegrated viral DNA is complex and dependent upon the nature of sequences in the gag and pol regions.

Identification of a common ecotropic viral integration site, Evi-1, in the DNA of AKXD murine myeloid tumors

AKXD-23 recombinant inbred mice develop myeloid tumors at a high frequency, unlike other AKXD recombinant inbred strains which develop B-cell lymphomas, T-cell lymphomas, or both. AKXD-23 myeloid tumors are monoclonal, and their DNA contains somatically acquired proviruses, suggesting that they are retrovirally induced. We identified a common site of ecotropic proviral integration that is present in the DNA of all AKXD-23 myeloid tumors that were analyzed and in the DNA of all myeloid tumors that occur in AKXD strains other than AKXD-23. We designated this locus Evi-1 (ecotropic viral integration site 1). Rearrangements in the Evi-1 locus were also detected in the DNA of a number of myeloid tumors and myeloid cell lines isolated from strains other than AKXD. In contrast, few Evi-1 rearrangements were detected in the DNA of T- or B-cell tumors. Evi-1 may thus identify a new proto-oncogene locus that is involved in myeloid disease.

Identification of a common ecotropic viral integration site, Evi-1, in the DNA of AKXD murine myeloid tumors

AKXD-23 recombinant inbred mice develop myeloid tumors at a high frequency, unlike other AKXD recombinant inbred strains which develop B-cell lymphomas, T-cell lymphomas, or both. AKXD-23 myeloid tumors are monoclonal, and their DNA contains somatically acquired proviruses, suggesting that they are retrovirally induced. We identified a common site of ecotropic proviral integration that is present in the DNA of all AKXD-23 myeloid tumors that were analyzed and in the DNA of all myeloid tumors that occur in AKXD strains other than AKXD-23. We designated this locus Evi-1 (ecotropic viral integration site 1). Rearrangements in the Evi-1 locus were also detected in the DNA of a number of myeloid tumors and myeloid cell lines isolated from strains other than AKXD. In contrast, few Evi-1 rearrangements were detected in the DNA of T- or B-cell tumors. Evi-1 may thus identify a new proto-oncogene locus that is involved in myeloid disease.

Variable number of tandem repeat (VNTR) markers for human gene mapping

A large collection of good genetic markers is needed to map the genes that cause human genetic diseases. Although nearly 400 polymorphic DNA markers for human chromosomes have been described, the majority have only two alleles and are thus uninformative for analysis of genetic linkage in many families. A few known marker systems, however, detect loci that respond to restriction enzyme cleavage by producing a fragment that can have many different lengths. This polymorphism is due to variation in the number of tandem repeats of a short DNA sequence. Because most individuals will be heterozygous at such loci, these markers will provide linkage information in almost all families. Ten oligomeric sequences derived from the tandem repeat regions of the myoglobin gene, the zeta-globin pseudogene, the insulin gene, and the X-gene region of hepatitis B virus, were used to develop a series of single-copy probes. These probes revealed new, highly polymorphic genetic loci whose allele sizes reflected variation in the number of tandem repeats.

Hepadnaviruses and retroviruses share genome homology and features of replication

The hepadnavirus family includes hepatitis B virus (HBV), woodchuck hepatitis virus (WHV), ground squirrel hepatitis virus (GSHV) and duck hepatitis B virus (DHBV). These viruses share unique ultrastructural, molecular and biological features. HBV has great medical importance in many parts of the world. More important numerically than acute hepatitis B in high prevalence geographic regions is the liver disease associated with chronic infection. There appear to be more than 200 million chronically infected humans in the world, and these HBV infections appear to be the single most common cause of chronic liver disease and liver cancer in man. All hepadnaviruses share the propensity for silent infection in early life leading to persistence of the virus, and hepatocellular carcinoma (HCC) is clearly associated with long-standing persistent infection in man, woodchucks and ground squirrels. Although the viral DNA has been found to be integrated in cellular DNA of many HCC in man, woodchucks and ground squirrels, the precise role of the virus in tumor formation has not been defined. Hepadna viruses have an interesting molecular structure and mechanisms of replication, and they appear to share certain important features with retroviruses as reviewed here. It is of interest to define similarities and differences between hepadnaviruses and retroviruses in order to understand their evolutionary relationship and to determine whether they share a common oncogenic mechanism, since infection with members of both virus families is associated with neoplastic disease.

Common evolutionary origin of hepatitis B virus and retroviruses

Hepatitis B virus (HBV), although classified as a double-stranded DNA virus, has been shown recently to replicate by reverse transcription of an RNA intermediate. Also, the putative viral polymerase has been found to share amino acid homology with reverse transcriptase of retroviruses. Using computer-assisted DNA and protein sequence analyses, we examined the genomes of 13 hepadnavirus isolates (nine human, two duck, one woodchuck, and one ground squirrel) and found that other conserved regions of the hepadnavirus genome share homology to corresponding regions of the genomes of type C retroviruses and retrovirus-like endogenous human DNA elements. Specifically, the most highly conserved sequence of the HBV genome, positioned at or near the initiation site for first-strand HBV DNA synthesis, is homologous over 67 nucleotides to the U5 region, a comparable region in retrovirus long terminal repeats. Within a highly conserved (i.e., 90%) 16-nucleotide sequence a heptanucleotide sequence CCTTGGG is 97% homologous between 27 virus isolates. Also, we found that the highly conserved HBV core, or nucleocapsid, protein shares 41% homology over 98 amino acids with the carboxyl-terminal region of the p30 gag nucleocapsid protein of type C retroviruses. In both cases, as with the previously reported polymerase homology, HBV is most homologous to the murine leukemia/sarcoma retroviruses. Further analysis revealed additional similarities between hepadnavirus and retroviral genomes. Taken together, our results suggest that HBV and retroviruses have a common evolutionary origin, with HBV arising through a process of deletion from a retrovirus, or retrovirus-like, progenitor.

A new pathway in the generation of defective retrovirus DNA

We used a retrovirus shuttle vector to make molecular clones of circular viral DNA from infected cells. One-third of the molecules examined had deletions that started within or near the U5 domain of the long terminal repeat (LTR) region and extended a variable distance toward the gag gene. We present evidence that some of these deletions arose by cleavage of a single LTR unit, in contrast to the cleavage of tandem LTR units associated with the integration reaction. These results suggest that in the formation of defective circular DNA, the U5 domain can be recognized and cleaved in the absence of an adjacent U3 domain. The cleavage of isolated U5 domains may represent an important mechanism responsible for the generation of certain forms of both defective circular DNA and defective integrated DNA.

Dilute-coat-color locus of mice: nucleotide sequence analysis of the d+2J and d+Ha revertant alleles

The unstable dilute-coat-color mutation (d) of DBA/2J mice has been shown to be the result of integration of an ecotropic murine leukemia virus within the mouse genome. Molecular cloning and restriction enzyme analysis of the dilute allele and the viral preintegration site (+ allele), as well as two independent dilute revertants (d+2J and d+Ha), suggested that reversion is due to virus excision occurring by homologous recombination involving the viral long terminal repeats. The DNA sequence has now been determined for the cell-virus junctions of the provirus associated with the d mutation, for the viral preintegration site, and for the two revertant sites. These data (i) indicate that the d mutation was caused by a normal virus integration, (ii) confirm that virus excision occurs by precise homologous recombination, as exactly one long terminal repeat is present in each revertant site, and (iii) suggest that the virus induced the d mutation by integration into a noncoding sequence.

Dilute-coat-color locus of mice: nucleotide sequence analysis of the d+2J and d+Ha revertant alleles

The unstable dilute-coat-color mutation (d) of DBA/2J mice has been shown to be the result of integration of an ecotropic murine leukemia virus within the mouse genome. Molecular cloning and restriction enzyme analysis of the dilute allele and the viral preintegration site (+ allele), as well as two independent dilute revertants (d+2J and d+Ha), suggested that reversion is due to virus excision occurring by homologous recombination involving the viral long terminal repeats. The DNA sequence has now been determined for the cell-virus junctions of the provirus associated with the d mutation, for the viral preintegration site, and for the two revertant sites. These data (i) indicate that the d mutation was caused by a normal virus integration, (ii) confirm that virus excision occurs by precise homologous recombination, as exactly one long terminal repeat is present in each revertant site, and (iii) suggest that the virus induced the d mutation by integration into a noncoding sequence.