Stimulation of HIV-1 minus strand strong stop DNA transfer by genomic sequences 3' of the primer binding site

The mechanism of human immunodeficiency virus 1 (HIV-1) minus strand transfer was examined using a genomic RNA sequence-based donor-acceptor template system. The donor RNA, D199, was a 199-nucleotide sequence from the 5'-end of the genome to the primer binding site (PBS) and shared 97 nucleotides of homology with the acceptor RNA. To investigate the influence of RNA structure on transfer, a second donor RNA, D520, was generated by extending the 3'-end of D199 to include an additional 321 nucleotides of the genome. The position of priming, length of homology with the acceptor, and length of cDNA synthesized were identical with the two donors. Interestingly, at 200% NC coating, donor D520 yielded a transfer efficiency of about 75% compared with about 35% with D199. A large proportion of the D520 promoted transfers occurred after the donor RNA was copied to the end. Analysis of donor RNA cleavage, the acceptor invasion site and R homology requirements indicated that transfers with D520 involved a similar but more efficient acceptor invasion mechanism compared with D199. RNA structure probing by RNase T1 and the RT pause profile during synthesis indicated conformational differences between D199 and D520 in the starting structure, and in dynamic structures formed during synthesis within the R region. Overall observations suggest that regions 3' of the primer binding site influence the conformation of the R region of D520 to facilitate steps that promote strand transfer.     

The antisense sequence of the HIV-1 TAR stem-loop structure covalently linked to the hairpin ribozyme enhances its catalytic activity against two artificial substrates

This work is an in vitro study of the efficiency of catalytic antisense RNAs whose catalytic domain is the wild-type sequence of the hairpin ribozyme, derived from the minus strand of the tobacco ringspot virus satellite RNA. The sequence in the target RNA recognized by the antisense molecule was the stem-loop structure of the human immunodeficiency virus-1 (HIV-1) TAR region. This region was able to form a complex with its antisense RNA with a binding rate of 2 x 10(4) M(-1)s(-1). Any deletion of the antisense RNA comprising nucleotides of the stem-loop resulted in a decrease in binding rate. Sequences 3' of the stem in the sense RNA also contributed to binding. This stem-loop TAR-antisense segment, covalently linked to a hairpin ribozyme, enhanced its catalytic activity. The highest cleavage rate was obtained when the stem-loop structure was present in both ribozyme and substrate RNAs and they were complementary. Similarly, an extension at the 5'-end of the hairpin ribozyme increased the cleavage rate when its complementary sequence was present in the substrate. Inclusion of the stem-loop at the 3'-end and the extension at the 5'-end of the hairpin ribozyme abolished the positive effect of both antisense units independently. These results may help in the design of hairpin ribozymes for gene silencing.