Retroviral nucleocapsid proteins display nonequivalent levels of nucleic acid chaperone activity.

Human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein (NC) is a nucleic acid chaperone that facilitates the remodeling of nucleic acids during various steps of the viral life cycle. Two main features of NC's chaperone activity are its abilities to aggregate and to destabilize nucleic acids. These functions are associated with NC's highly basic character and with its zinc finger domains, respectively. While the chaperone activity of HIV-1 NC has been extensively studied, less is known about the chaperone activities of other retroviral NCs. In this work, complementary experimental approaches were used to characterize and compare the chaperone activities of NC proteins from four different retroviruses: HIV-1, Moloney murine leukemia virus (MLV), Rous sarcoma virus (RSV), and human T-cell lymphotropic virus type 1 (HTLV-1). The different NCs exhibited significant differences in their overall chaperone activities, as demonstrated by gel shift annealing assays, decreasing in the order HIV-1 approximately RSV > MLV >> HTLV-1. In addition, whereas HIV-1, RSV, and MLV NCs are effective aggregating agents, HTLV-1 NC, which exhibits poor overall chaperone activity, is unable to aggregate nucleic acids. Measurements of equilibrium binding to single- and double-stranded oligonucleotides suggested that all four NC proteins have moderate duplex destabilization capabilities. Single-molecule DNA-stretching studies revealed striking differences in the kinetics of nucleic acid dissociation between the NC proteins, showing excellent correlation between nucleic acid dissociation kinetics and overall chaperone activity.

Single DNA molecule stretching measures the activity of chemicals that target the HIV-1 nucleocapsid protein.

We develop a biophysical method for investigating chemical compounds that target the nucleic acid chaperone activity of HIV-1 nucleocapsid protein (NCp7). We used an optical tweezers instrument to stretch single lambda-DNA molecules through the helix-coil transition in the presence of NCp7 and various chemical compounds. The change in the helix-coil transition width induced by wild-type NCp7 and its zinc finger variants correlates with in vitro nucleic acid chaperone activity measurements and in vivo assays. The compound-NC interaction measured here reduces NCp7's capability to alter the transition width. Purified compounds from the NCI Diversity set, 119889, 119911, and 119913 reduce the chaperone activity of 5 nM NC in aqueous solution at 10, 25, and 100 nM concentrations respectively. Similarly, gallein reduced the activity of 4 nM NC at 100 nM concentration. Further analysis allows us to dissect the impact of each compound on both sequence-specific and non-sequence-specific DNA binding of NC, two of the main components of NC's nucleic acid chaperone activity. These results suggest that DNA stretching experiments can be used to screen chemical compounds targeting NC proteins and to further explore the mechanisms by which these compounds interact with NC and alter its nucleic acid chaperone activity.

Rapid kinetics of protein-nucleic acid interaction is a major component of HIV-1 nucleocapsid protein's nucleic acid chaperone function.

The nucleic acid chaperone activity of the human immunodeficiency virus type-1 (HIV-1) nucleocapsid protein (NC) plays an important role in the retroviral life cycle, in part, by facilitating numerous nucleic acid rearrangements throughout the reverse transcription process. Recent studies have identified duplex destabilization and nucleic acid aggregation as the two major components of NC's chaperone activity. In order to better understand the contribution of the functional domains of NC to these two activities, we used optical tweezers to stretch single lambda DNA molecules through the helix-coil transition in the presence of wild-type or mutant HIV-1 NC. Protein-induced duplex destabilization was measured directly as an average decrease of the force-induced melting free energy, while NC's ability to facilitate strand annealing was determined by the amount of hysteresis in the DNA stretch-relax cycle. By studying zinc-free variants of full-length and truncated NC, the relative contributions of NC's zinc fingers and N-terminal basic domain to the two major components of chaperone activity were elucidated. In addition, examination of NC variants containing mutations affecting one or both zinc finger motifs showed that effective strand annealing activity is correlated with NC's ability to rapidly bind and dissociate from nucleic acids. NC variants with slow on/off rates are inefficient in strand annealing, even though they may still be capable of high affinity nucleic acid binding, duplex destabilization, and/or nucleic acid aggregation. Taken together, these observations establish the rapid kinetics of protein-nucleic acid interaction as another major component of NC's chaperone function.

Nucleic acid binding and chaperone properties of HIV-1 Gag and nucleocapsid proteins.

The Gag polyprotein of HIV-1 is essential for retroviral replication and packaging. The nucleocapsid (NC) protein is the primary region for the interaction of Gag with nucleic acids. In this study, we examine the interactions of Gag and its NC cleavage products (NCp15, NCp9 and NCp7) with nucleic acids using solution and single molecule experiments. The NC cleavage products bound DNA with comparable affinity and strongly destabilized the DNA duplex. In contrast, the binding constant of Gag to DNA was found to be approximately 10-fold higher than that of the NC proteins, and its destabilizing effect on dsDNA was negligible. These findings are consistent with the primary function of Gag as a nucleic acid binding and packaging protein and the primary function of the NC proteins as nucleic acid chaperones. Also, our results suggest that NCp7's capability for fast sequence-nonspecific nucleic acid duplex destabilization, as well as its ability to facilitate nucleic acid strand annealing by inducing electrostatic attraction between strands, likely optimize the fully processed NC protein to facilitate complex nucleic acid secondary structure rearrangements. In contrast, Gag's stronger DNA binding and aggregation capabilities likely make it an effective chaperone for processes that do not require significant duplex destabilization.

LINE-1 retrotransposition requires the nucleic acid chaperone activity of the ORF1 protein.

LINE-1 is a highly successful, non-LTR retrotransposon that has played a leading role in shaping mammalian genomes. These elements move autonomously through an RNA intermediate using target-primed reverse transcription (TPRT). L1 encodes two essential polypeptides for retrotransposition, the products of its two open reading frames, ORF1 and ORF2. The exact function of the ORF1 protein (ORF1p) in L1 retrotransposition is unknown, although it is an RNA-binding protein that can act as a nucleic acid chaperone. Here, we investigate the requirements for these two activities in L1 retrotransposition by examining the consequences of mutating two adjacent and highly conserved arginine residues in the ORF1p from mouse L1. Substitution of both arginine residues with alanine strongly reduces the affinity of the protein for single-stranded nucleic acid, whereas substitution of one or both with lysine has only minimal effects on this feature. Rather, the lysine substitutions alter the delicate balance between the ORF1 protein's melting and reannealing activities, thereby reducing its nucleic acid chaperone activity. These findings establish the importance of the nucleic acid chaperone activity of ORF1p to successful L1 retrotransposition, and provide insight into the essential properties of nucleic acid chaperones.