Abstract
The nucleocapsid protein NC is a crucial component in the human immunodeficiency virus type 1 life cycle. It functions both in its processed mature form and as part of the polyprotein Gag that plays a key role in the formation of new viruses. NC can protect nucleic acids (NAs) from degradation by compacting them to a dense coil. Moreover, through its NA chaperone activity, NC can also promote the most stable conformation of NAs. Here, we explore the balance between these activities for NC and Gag by confining DNA-protein complexes in nanochannels. The chaperone activity is visualized as concatemerization and circularization of long DNA via annealing of short single-stranded DNA overhangs. The first ten amino acids of NC are important for the chaperone activity that is almost completely absent for Gag. Gag condenses DNA more efficiently than mature NC, suggesting that additional residues of Gag are involved. Importantly, this is the first single DNA molecule study of full-length Gag and we reveal important differences to the truncated Δ-p6 Gag that has been used before. In addition, the study also highlights how nanochannels can be used to study reactions on ends of long single DNA molecules, which is not trivial with competing single DNA molecule techniques.
Highlights
The synthesis of the viral DNA in human immunodeficiency virus type 1 (HIV-1) results from the reverse transcription (RTion) process, where two copies of single-stranded RNA are transcribed into double-stranded DNA
One of the transcription products is an mRNA that codes for the Gag polyprotein, which is the main structural protein of HIV-1, and is on its own sufficient for assembly of new viral particles in cells (Campbell and Rein, 1999)
Our results show that the ability to compact and condense double-stranded DNA (dsDNA) is mainly related to the N-terminal domain of NC
Summary
The synthesis of the viral DNA in human immunodeficiency virus type 1 (HIV-1) results from the reverse transcription (RTion) process, where two copies of single-stranded RNA (ssRNA) are transcribed into double-stranded DNA (dsDNA). One of the transcription products is an mRNA that codes for the Gag polyprotein, which is the main structural protein of HIV-1, and is on its own sufficient for assembly of new viral particles in cells (Campbell and Rein, 1999). After the viral particle leaves the infected cell, the Gag polyprotein is sequentially cleaved by the virus-encoded protease to lead to the mature MA, CA, NC and p6 proteins. MA associates with the inner viral membrane, CA assembles into the conical capsid and NC coats and condenses the viral RNA (Ganser-Pornillos et al, 2008; Briggs et al, 2009; Briggs and Kräusslich, 2011; Bell and Lever, 2013)
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