Mechanisms of retroviral recombination

A new family of chimeric retrotranscripts formed by a full copy of U6 small nuclear RNA fused to the 3' terminus of l1

Long interspersed nuclear elements (LINE-1, L1) constitute a large family of mammalian retrotransposons that have been replicating and evolving in mammals for more than 100 million years and now compose 17% of the human genome. They have an important creative role in human genomic evolution through mechanisms such as new integrations, generation of processed pseudogenes, and transfer of non-L1 DNA flanking their 3' ends to new genomic locations. Here we present evidence that the L1 integration machinery was used for the creation of a new family of chimeric retrotranscripts, which contain a full copy of U6 small nuclear RNA and a 3' part of L1 at their 5' and 3' ends, respectively. There are at least 56 members of this family in the human genome. The integrations of such fused retrotranscripts into the human genome took place until recently. Here we report one U6-L1 insertion that is polymorphic in humans. We also propose a mechanism used to generate chimeric retrotranscripts.

Specific zinc-finger architecture required for HIV-1 nucleocapsid protein's nucleic acid chaperone function

The nucleocapsid protein (NC) of HIV type 1 (HIV-1) is a nucleic acid chaperone that facilitates the rearrangement of nucleic acid secondary structure during reverse transcription. HIV-1 NC contains two CCHC-type zinc binding domains. Here, we use optical tweezers to stretch single lambda-DNA molecules through the helix-to-coil transition in the presence of wild-type and several mutant forms of HIV-1 NC with altered zinc-finger domains. Although all forms of NC lowered the cooperativity of the DNA helix-coil transition, subtle changes in the zinc-finger structures reduced NC's effect on the transition. The change in cooperativity of the DNA helix-coil transition correlates strongly with in vitro nucleic acid chaperone activity measurements and in vivo HIV-1 replication studies using the same NC mutants. Moreover, Moloney murine leukemia virus NC, which contains a single zinc finger, had little effect on transition cooperativity. These results suggest that a specific two-zinc-finger architecture is required to destabilize nucleic acids for optimal chaperone activity during reverse transcription in complex retroviruses such as HIV-1.