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 ~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.     

Identification of HIV-1 nucleocapsid protein: nucleic acid antagonists with cellular anti-HIV activity

The crucial functions of HIV-1 nucleocapsid-p7 protein (NC-p7) at different stages of HIV replication are dependent on its nucleic acid binding properties. In this study, a search has been made to identify antagonists of the interaction between NC-p7 and d(TG)(4). A chemical library of approximately 2000 small molecules (the NCI Diversity Set) was screened, of the 26 active inhibitors that were identified, five contained a xanthenyl ring structure. Further analysis of 63 structurally related compounds led to the identification of 2,3,4,5-tetrachloro-6-(4('),5('),6(')-trihydroxy-3(')-oxo-3H-xanthen-9(')-yl)benzoic acid, which binds to NC-p7 stoichiometrically. This compound exerted a significant anti-HIV activity in vitro with an IC(50) of 16.6+/-4.3 microM (means+/-SD). Synthetic variants lacking the two hydroxyls at positions 4(') and 5(') in the xanthenyl ring system failed to bind NC-p7 and showed significantly less protection against HIV infection. Molecular modeling predicts that these hydroxyl groups would bind to the amide nitrogen of Gly(35) with other contacts at the carbonyl oxygens of Gly(40) and Lys(33).     

Subtle alterations of the native zinc finger structures have dramatic effects on the nucleic acid chaperone activity of human immunodeficiency virus type 1 nucleocapsid protein

The nucleocapsid protein (NC) of human immunodeficiency virus type 1 has two zinc fingers, each containing the invariant CCHC zinc-binding motif; however, the surrounding amino acid context is not identical in the two fingers. Recently, we demonstrated that zinc coordination is required when NC unfolds complex secondary structures in RNA and DNA minus- and plus-strand transfer intermediates; this property of NC reflects its nucleic acid chaperone activity. Here we have analyzed the chaperone activities of mutants having substitutions of alternative zinc-coordinating residues, i.e., CCHH or CCCC, for the wild-type CCHC motif. We also investigated the activities of mutants that retain the CCHC motifs but have mutations that exchange or duplicate the zinc fingers (mutants 1-1, 2-1, and 2-2); these changes affect amino acid context. Our results indicate that in general, for optimal activity in an assay that measures stimulation of minus-strand transfer and inhibition of nonspecific self-priming, the CCHC motif in the zinc fingers cannot be replaced by CCHH or CCCC and the amino acid context of the fingers must be conserved. Context changes also reduce the ability of NC to facilitate primer removal in plus-strand transfer. In addition, we found that the first finger is a more crucial determinant of nucleic acid chaperone activity than the second finger. Interestingly, comparison of the in vitro results with earlier in vivo replication data raises the possibility that NC may adopt multiple conformations that are responsible for different NC functions during virus replication.     

Matrix domain modulates HIV-1 Gag's nucleic acid chaperone activity via inositol phosphate binding

Retroviruses replicate by reverse transcribing their single-stranded RNA genomes into double-stranded DNA using specific cellular tRNAs to prime cDNA synthesis. In HIV-1, human tRNA(3)(Lys) serves as the primer and is packaged into virions during assembly. The viral Gag protein is believed to chaperone tRNA(3)(Lys) placement onto the genomic RNA primer binding site; however, the timing and possible regulation of this event are currently unknown. Composed of the matrix (MA), capsid (CA), nucleocapsid (NC), and p6 domains, the multifunctional HIV-1 Gag polyprotein orchestrates the highly coordinated process of virion assembly, but the contribution of these domains to tRNA(3)(Lys) annealing is unclear. Here, we show that NC is absolutely essential for annealing and that the MA domain inhibits Gag's tRNA annealing capability. During assembly, MA specifically interacts with inositol phosphate (IP)-containing lipids in the plasma membrane (PM). Surprisingly, we find that IPs stimulate Gag-facilitated tRNA annealing but do not stimulate annealing in Gag variants lacking the MA domain or containing point mutations involved in PM binding. Moreover, we find that IPs prevent MA from binding to nucleic acids but have little effect on NC or Gag. We propose that Gag binds to RNA either with both NC and MA domains or with NC alone and that MA-IP interactions alter Gag's binding mode. We propose that MA's interactions with the PM trigger the switch between these two binding modes and stimulate Gag's chaperone function, which may be important for the regulation of events such as tRNA primer annealing.     

Kinetic analysis of the nucleic acid chaperone activity of the Hepatitis C virus core protein

The multifunctional HCV core protein consists of a hydrophilic RNA interacting D1 domain and a hydrophobic D2 domain interacting with membranes and lipid droplets. The core D1 domain was found to possess nucleic acid annealing and strand transfer properties. To further understand these chaperone properties, we investigated how the D1 domain and two peptides encompassing the D1 basic clusters chaperoned the annealing of complementary canonical nucleic acids that correspond to the DNA sequences of the HIV-1 transactivation response element TAR and its complementary cTAR. The core peptides were found to augment cTAR-dTAR annealing kinetics by at least three orders of magnitude. The annealing rate was not affected by modifications of the dTAR loop but was strongly reduced by stabilization of the cTAR stem ends, suggesting that the core-directed annealing reaction is initiated through the terminal bases of cTAR and dTAR. Two kinetic pathways were identified with a fast pre-equilibrium intermediate that then slowly converts into the final extended duplex. The fast and slow pathways differed by the number of base pairs, which should be melted to nucleate the intermediates. The three peptides operate similarly, confirming that the core chaperone properties are mostly supported by its basic clusters.     

Cellular nucleic acid binding protein binds G-rich single-stranded nucleic acids and may function as a nucleic acid chaperone

Cellular nucleic acid binding protein (CNBP) is a small single-stranded nucleic acid binding protein made of seven Zn knuckles and an Arg-Gly rich box. CNBP is strikingly conserved among vertebrates and was reported to play broad-spectrum functions in eukaryotic cells biology. Neither its biological function nor its mechanisms of action were elucidated yet. The main goal of this work was to gain further insights into the CNBP biochemical and molecular features. We studied Bufo arenarum CNBP (bCNBP) binding to single-stranded nucleic acid probes representing the main reported CNBP putative targets. We report that, although bCNBP is able to bind RNA and single-stranded DNA (ssDNA) probes in vitro, it binds RNA as a preformed dimer whereas both monomer and dimer are able to bind to ssDNA. A systematic analysis of variant probes shows that the preferred bCNBP targets contain unpaired guanosine-rich stretches. These data expand the knowledge about CNBP binding stoichiometry and begins to dissect the main features of CNBP nucleic acid targets. Besides, we show that bCNBP presents a highly disordered predicted structure and promotes the annealing and melting of nucleic acids in vitro. These features are typical of proteins that function as nucleic acid chaperones. Based on these data, we propose that CNBP may function as a nucleic acid chaperone through binding, remodeling, and stabilizing nucleic acids secondary structures. This novel CNBP biochemical activity broadens the field of study about its biological function and may be the basis to understand the diverse ways in which CNBP controls gene expression.     

Intrinsically disordered proteins display no preference for chaperone binding in vivo

Intrinsically disordered/unstructured proteins (IDPs) are extremely sensitive to proteolysis in vitro, but show no enhanced degradation rates in vivo. Their existence and functioning may be explained if IDPs are preferentially associated with chaperones in the cell, which may offer protection against degradation by proteases. To test this inference, we took pairwise interaction data from high-throughput interaction studies and analyzed to see if predicted disorder correlates with the tendency of chaperone binding by proteins. Our major finding is that disorder predicted by the IUPred algorithm actually shows negative correlation with chaperone binding in E. coli, S. cerevisiae, and metazoa species. Since predicted disorder positively correlates with the tendency of partner binding in the interactome, the difference between the disorder of chaperone-binding and non-binding proteins is even more pronounced if normalized to their overall tendency to be involved in pairwise protein–protein interactions. We argue that chaperone binding is primarily required for folding of globular proteins, as reflected in an increased preference for chaperones of proteins in which at least one Pfam domain exists. In terms of the functional consequences of chaperone binding of mostly disordered proteins, we suggest that its primary reason is not the assistance of folding, but promotion of assembly with partners. In support of this conclusion, we show that IDPs that bind chaperones also tend to bind other proteins.     

A nucleic acid switch triggered by the HIV-1 nucleocapsid protein

A unimolecular oligonucleotide switch, termed here an AlloSwitch, binds the mature HIV-1 nucleocapsid protein, NCp7. This switch can be used as an indicator for the presence of free NCp7 and NC domains in precursor and fusion proteins. It is thermodynamically stable in two conformations, H and O. A FRET pair is covalently attached to the strands to report on the molecular state of the switch. The results show that NC has an affinity for O 170 times higher than its affinity for H and that in the absence of NC the equilibrium ratio K1 = [O]/[H] = 0.10 +/- 0.03 for the switch sequence reported here. The change between the two states happens on a rapid kinetic time scale. A framework is introduced to aid in the design of AlloSwitches aimed at other targets. A high-affinity probe segment must be available to bind the target in the O-form, while a cover segment hides the probe in H. A key is adjusting the cover sequence to favor the H-form by a factor of 10-1000. This affords a robust response to small changes in target concentration, while saturation produces more than 90% of the maximal change in fluorescence. When a competitor displaces the switch from the NC-O complex, the released switch reverts to the H-form. This is the basis for a mix-and-read strategy for high-throughput screening of anti-nucleocapsid drug candidates that is much simpler to execute than traditional assays that require immobilization and washing steps.     

Fluorescence and nucleic acid binding properties of bovine leukemia virus nucleocapsid protein

Peptidyl-prolyl cis/trans isomerization, observed in the native state of an increasing number of proteins, is of considerable biological significance. The first evidence for an asymmetric transmission along the polypeptide chain of the structural effects of prolyl isomerization is now derived from the statistics of the C(alpha)/C(alpha)-atom distance distributions in the crystal structures of 848 non-homologous proteins. More detailed information on how isomerization affects segments adjacent to proline is obtained from crystal structures of proteins, that are more than 95% homologous, and that exhibit two different states of isomerization at a particular prolyl bond. The resulting 64 cases, which represent 3.8% of the database used, form pairs of coordinates which were analyzed for the existence of isomer-specific intramolecular nonbonded C(alpha)/C(alpha)-atom distances around the critical proline, and for the positional preferences for particular amino acids in the isomeric sequence segment. The probability that a native protein exhibits both prolyl isomers in the crystalline state increases in particular with a Pro at the third position N-terminal to the isomeric bond (-3 position), and with Ser, Gly and Asp at the position preceding the isomeric bond (-1 position). Structural alignment of matched pairs of isomeric proteins generates three classes with respect to position-specific distribution of C(alpha)-atom displacements around an isomeric proline imide bond. In the majority of cases the distribution of these intermolecular isomer-specific C(alpha)-atom distances shows a symmetric behavior for the N-terminal and C-terminal segment flanking the proline residue, and the magnitude did not exceed 1.3+/-0.6 A including the C(alpha) atoms in proximity to the prolyl bond. However, in the remaining 12 protein pairs the structural changes are unidirectional relative to the isomerizing bond whereby the magnitude of the isomer-specific effect exceeds 3.0+/-2.0 A even at positions remote to proline. Interestingly, the magnitude of the intramolecular isomer-specific C(alpha) atom displacements reveals a lever-arm amplification of the isomerization-mediated structural changes in a protein backbone. The observed backbone effects provide a structural basis for isomer-specific reactions of proline-containing polypeptides, and thus may play a role in biological recognition and regulation.     

Nucleic acid binding properties of the nucleic acid chaperone domain of hepatitis delta antigen

The N terminal region of hepatitis delta antigen (HDAg), referred to here as NdAg, has a nucleic acid chaperone activity that modulates the ribozyme activity of hepatitis delta virus (HDV) RNA and stimulates hammerhead ribozyme catalysis. We characterized the nucleic acid binding properties of NdAg, identified the structural and sequence domains important for nucleic acid binding, and studied the correlation between the nucleic acid binding ability and the nucleic acid chaperone activity. NdAg does not recognize the catalytic core of HDV ribozyme specifically. Instead, NdAg interacts with a variety of nucleic acids and has higher affinities to longer nucleic acids. The studies with RNA homopolymers reveal that the binding site size of NdAg is around nine nucleotides long. The extreme N terminal portion of NdAg, the following coiled-coil domain and the basic amino acid clusters in these regions are important for nucleic acid binding. The nucleic acid–NdAg complex is stabilized largely by electrostatic interactions. The formation of RNA–protein complex appears to be a prerequisite for facilitating hammerhead ribozyme catalysis of NdAg and its derivatives. Mutations that reduce the RNA binding activity or high ionic strength that destabilizes the RNA–protein complex, reduce the nucleic acid chaperone activity of NdAg.     

Poliovirus protein 3AB displays nucleic acid chaperone and helix-destabilizing activities

Poliovirus protein 3AB displayed nucleic acid chaperone activity in promoting the hybridization of complementary nucleic acids and destabilizing secondary structure. Hybridization reactions at 30 degrees C between 20- and 40-nucleotide RNA oligonucleotides and 179- or 765-nucleotide RNAs that contained a complementary region were greatly enhanced in the presence of 3AB. The effect was nonspecific as reactions between DNA oligonucleotides and RNA or DNA templates were also enhanced. Reactions were optimal with 1 mM MgCl(2) and 20 mM KCl. Analysis of the reactions with various 3AB and template concentrations indicated that enhancement required a critical amount of 3AB that increased as the concentration of nucleic acid increased. This was consistent with a requirement for 3AB to "coat" the nucleic acids for enhancement. The helix-destabilizing activity of 3AB was tested in an assay with two 42-nucleotide completely complementary DNAs. Each complement formed a strong stem-loop (DeltaG = -7.2 kcal/mol) that required unwinding for hybridization to occur. DNAs were modified at the 3' or 5' end with fluorescent probes such that hybridization resulted in quenching of the fluorescent signal. Under optimal conditions at 30 degrees C, 3AB stimulated hybridization in a concentration-dependent manner, as did human immunodeficiency virus nucleocapsid protein, an established chaperone. The results are discussed with respect to the role of 3AB in viral replication and recombination.     

An improved algorithm for nucleic acid secondary structure display

An improved algorithm for the display of nucleic acid secondarystructures is presented. It is particularly suitable for largesequence segments and it automatically generates an aestheticallypleasing display of the structure with very limited overlapof strands. Structural similarities in different structuresare conserved in the display thus greatly aiding structuralhomology comparisons. Using the algorithm, we illustrate theeffect of ribosome translocation on the secondary structureof a rat neuropeptide messenger RNA. Received on September 21, 1987; accepted on October 22, 1987