Target specificity of human immunodeficiency virus type 1 NCp7 requires an intact conformation of its CCHC N-terminal zinc finger.

The modification of zinc-binding residues inside the conserved CCHC motif of human immunodeficiency virus type 1 NCp7, in particular into CCHH, induces a complete loss of infectivity. Since the mutant His28NCp7 has been shown to be devoid of infectivity in vivo, the structure-function relationships of the mutant His28(12-53)NCp7 were investigated by nuclear magnetic resonance and surface plasmonic resonance. Although the Cys28-->His mutation modifies drastically the structure of the core domain (residues 12 to 53) of NCp7, His28(12-53)NCp7 still interacts with a 10-fold-lower affinity to specific nucleic acid targets, such as SL3, a stem-loop critically involved in viral RNA packaging, and without affinity change with the nonspecific, single-stranded nucleic acid poly(T). Moreover, His28(12-53)NCp7 and native (12-53)NCp7 displayed the same affinity with reverse transcriptase, but the natures of the complexes are probably different, accounting for the drastic reduction in the amount of RNA packaged in the mutated virus. We propose a structural model of His28(12-53)NCp7 that provides insights into the NCp7 structural features necessary for target recognition and that shows that the specific native structure of the zinc finger domain is strictly required for the optimal target selectivity of NCp7.

Structural investigation on the requirement of CCHH zinc finger type in nucleocapsid protein of human immunodeficiency virus 1.

The nucleocapsid proteins (NCps) of lentiviruses play a key role during the retroviral replication cycle. NCps contain one or two highly conserved domains characterized by a CX(2)CX(4)HX(4)C sequence which binds zinc with a high affinity. The reasons of the high conservation of zinc fingers of CCHC type in lentiviruses were investigated by a structural study of mutants in which the zinc-coordinated ligands were exchanged. The HCHC form was unable to bind zinc tetrahedrally, whereas in His(28)(13-30)NCp7 corresponding to the CCHH motif, the zinc was tightly complexed. The mutant peptide exists in two interconverting conformations E and D [DeltaG(DE) (293K) = 0.1 kcal/mol] arising from the zinc coordination of His(28), by either its Nepsilon2 or its Ndelta1, respectively. As compared to the native CCHC zinc finger, the Cys(28) --> His mutation induces structural changes in the finger due to a modification in the coordination state of His(23) bound to zinc by Nepsilon2 in the wild-type finger by Ndelta1 in both conformers of the mutant. Introduction of these single mutations within the NCp7 proximal zinc finger in the HIV-1 genome was very recently shown to result in a loss of viral infection. This supports the hypothesis that structural changes of the zinc finger domain of NCp7 inhibit the recognition of one or several targets critically involved in the virus life cycle.

Model of the complex formed between the H2 domain of the TATA box binding protein and the L(281-301) fragment of the human transcription factor TFIIA.

Additional interactions possibly involving the well-exposed H2 helical domain of hTBP and the acidic fragment L(281-301) of the non-conserved domain of hTFIIA have been proposed to account for the apparent discrepancies between the results of mutagenesis experiments on human proteins and the structure of the ternary complex TBP/TATA box/TFIIA established from yeast proteins by X-ray crystallography. To verify this hypothesis both peptides were synthesized and their structures studied by circular dichroism (CD), NMR and molecular modelling. These peptides exist preferentially under helical conformations in solution (30% TFE in H2O). An interaction between the two peptides was observed by fluorescence (Kapp 170 microM), CD and NMR techniques. Molecular modelling studies indicate that this complex could be stabilized by electrostatic interactions involving the glutamate Glu287 and aspartates (Asp290, Asp294, Asp297 and Asp298) of L(281-301)TFIIA and lysine residues (Lys133, Lys138 and Lys145) and arginine residues (Arg137, Arg140) of H2(TBP) in agreement with mutagenesis experiments. Similar studies could now be carried out with human proteins to demonstrate the biological relevance of this interaction.