Mechanism of HIV-1 RNA dimerization in the central region of the genome and significance for viral evolution.

The genome of HIV-1 consists of two identical or nearly identical RNA molecules. The RNA genomes are held in the same, parallel orientation by interactions at the dimer initiation site (DIS). Previous studies showed that in addition to interactions at DIS, sequences located 100 nucleotides downstream from the 5' splice site can dimerize in vitro through an intermolecular G-quartet structure. Here we report that the highly conserved G-rich sequence in the middle portion of the HIV-1 genome near the central polypurine tract (cPPT) dimerizes spontaneously under high ionic strength in the absence of protein. The antisense RNA does not dimerize, strongly indicating that RNA dimerization does not exclusively involve A:U and G:C base pairing. The cation-dependent reverse transcriptase pausing profile, CD spectra profile, and cation-dependent association and thermal dissociation characteristics indicate G-quartet structures. Different forms of G-quartets are formed including monomers and, significantly, intermolecular dimers. Our results indicate that RNA genome dimerization and parallel alignment initiated through interactions at DIS may be greatly expanded and stabilized by formation of an intermolecular G-quartet at a distant site near the cPPT. It is likely that formation of G-quartet structure near the cPPT in vivo keeps the RNA genomes in proximity over a long range, promoting genetic recombination in numerous hot spots.