Simian retroviruses (SRVs), the etiological agent of a spontaneous Simian acquired immunodeficiency syndrome, endemically infects large percentages of Asian macaques housed in biomedical research colonies and severely compromises the effective use of these species as a viable research animal. We recently described the molecular cloning of a serogroup 2 SRV, D2/RHE/OR, which causes mild immunosuppression in rhesus macaques. A restriction site variant, D2/RHE/OR/V1, has also been recovered from severely ill animals endemically infected with D2/RHE/OR. We now report the complete nucleotide sequences of D2/RHE/OR and D2/RHE/OR/V1. Both infectious molecular clones retain the genetic structure typical of type D SRVs (5' LTR-gag-prt-pol-env-3'LTR) and encode identically sized 8105-bp proviruses. D2/RHE/OR and D2/RHE/OR/V1 are 99.3% similar at the amino acid level, exhibiting only 17 residue differences, of which 10 are located in the envelope glycoproteins. The molecular clones and reciprocal chimeric viruses were used to assess the contribution of different genetic domains to virus infectivity in a T cell infection assay. These experiments indicate that D2/RHE/OR has a reduced ability to infect specific T cell lines, especially Hut-78 and MT-4 cells, and that the envelope gene is not the sole determinant of in vitro tropism.
We demonstrated here that 4,5',8-trimethylpsoralen (trioxsalen) is a valuable probe for the structure of SV40 DNA-histone complexes. Trioxsalen readily penetrated intact cells and, in the presence of 340to 380-nm light, covalently cross-linked DNA preferentially at the sites available for micrococcal nuclease digestion. Histograms of the lengths of the regions of SV40 DNA protected from cross-linking, as visualized by electron microscopy, indicated a repeating pattern of base pairs in DNA from both infected cells and virus particles. The ability of the trioxsalen probe to act in vivo and to map the location of protected regions may provide a powerful tool for analyzing the role of nucleosomes in the structure of the virus particle and in intracellular complexes such as transcription templates and replication intermediates.
Preferential psoralen photobinding sites have been mapped in vitro on restriction fragments spanning the SV40 origin region and surrounding sequences by a new fine structure analysis technique. Purified DNA fragments were photoreacted with 3H-5-methylisopsoralen (3H-5-MIP), a psoralen derivative which forms only monoadducts. Fragments were then end-labeled and digested with lambda exonuclease, a 5' processive enzyme which we have determined pauses at 5-MIP monoadducts. When photobinding sites were mapped on denaturing sequencing gels, it was observed that 5-MIP binds preferentially to 5'-TA sites, and to a lesser degree to 5'-AT sites. Utilizing this approach, we have identified a psoralen hypersensitive region in which the binding sites were much stronger than those in the surrounding sequences. This region extends from 150 base pairs (bp) to the late side of the enhancers to the early enhancer/promoter boundary. We suggest that this region contains a sequence directed structural alteration of the DNA helix which can be detected by the psoralen mapping approach described.
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