Translocation of the pAntp peptide and its amphipathic analogue AP-2AL.

The pAntp peptide, corresponding to the third helix of the homeodomain of the Antennapedia protein, enters by a receptor-independent process into eukaryotic cells. The interaction between the pAntp peptide and the phospholipid matrix of the plasma membrane seems to be the first step involved in the translocation mechanism. However, the mechanism by which the peptide translocates through the cell membrane is still not well established. We have investigated the translocation ability of pAntp through a protein-free phospholipid membrane in comparison with a more amphipathic analogue. We show by fluorescence spectroscopy, circular dichroism, NMR spectroscopy, and molecular modeling that pAntp is not sufficiently helically amphipathic to cross a phospholipid membrane of a model system. Due to its primary sequence related to its DNA binding ability in the Antennapedia homeodomain-DNA complex, the pAntp peptide does not belong to the amphipathic alpha-helical peptide family whose members are able to translocate by pore formation.

Structure of the complex between the HIV-1 nucleocapsid protein NCp7 and the single-stranded pentanucleotide d(ACGCC).

The nucleocapsid protein NCp7 of HIV-1 Mal contains two successive Zn knuckles of the CX2CX4HX4C type and plays a major role in virion morphogenesis, genomic RNA packaging and viral infectivity, mainly through single-stranded nucleic acid binding. We report here the study by 1H 2D NMR of the complex formed between the (12-53)NCp7, encompassing the two Zn knuckles, and d(ACGCC), a deoxynucleotide sequence analog corresponding to the shortest NCp7 binding site. Ten structures of the (12-53)NCp7/d(ACGCC) complex have been obtained from 607 NOE-derived distance constraints, 28 of which are intermolecular, and from molecular dynamics studies. The oligonucleotide is almost perpendicular to the sequence linking the two Zn knuckles. The Trp37 indole ring is inserted between the C2 and G3 bases and stacked on the latter. The complex is stabilized by hydrophobic interactions and hydrogen bonds, and accounts for the observed loss of virus infectivity induced by mutations in the Zn knuckle domain. Thus, the interaction between d(ACGCC) and the inactive mutant Cys23 (12-53)NCp7 was found by NMR to be completely different from that observed with the wild-type peptide. A mechanism of action for NCp7 in virus morphogenesis and replication is proposed from these results, which could facilitate the design of possible antiviral agents acting by a new mechanism.

Structure, biological functions and inhibition of the HIV-1 proteins Vpr and NCp7.

The Gag-encoded nucleocapsid protein NCp7 (72 amino acids) from HIV-1, the regulatory protein, Vpr (96 amino acids) and numerous derivatives have been synthesized by solid phase method and their structures determined by 2D NMR. In NCp7, the two highly folded zinc fingers of the Cx2Cx4Hx4C type are in close spacial proximity and the replacement of H by C in the first zinc finger or P by L in the short interdigital domain led to structural modifications evidenced by NMR. In vivo, these point mutations induced a complete loss of viral infectivity by interrupting critical step(s) of the retroviral life cycle. To account for these findings, a model of the complex between NCp7 and d (ACGCC) has been proposed from NMR data, showing the intercalation of Trp37 in the oligonucleotide. This model could also explain the role of NCp7 in the formation of viral particles and agrees with the modifications in morphology of the virions containing mutations in the NCp7 zinc fingers. Vpr is essentially constituted by two long helical domains at its N- and C-terminals and the side chains of Leu60 and Leu67 participate in a leucine-zipper mode of intramolecular interaction. The results obtained have been used to try to develop new antiviral agents inhibiting NCp7 functions and thus possibly devoid of the resistance effects found with inhibitors of HIV enzymes (reverse transcriptase and protease).

1H NMR structure and biological studies of the His23-->Cys mutant nucleocapsid protein of HIV-1 indicate that the conformation of the first zinc finger is critical for virus infectivity.

The nucleocapsid protein NCp7 of human immunodeficiency virus type 1 (HIV-1), which has key functions in the virus life cycle, possesses two zinc fingers of the CX2CX4HX4C type characterized by three successive loops containing a tetrahedrally coordinated zinc atom. The replacement of any cysteine by a serine in either finger has been shown to result in the production of noninfectious viruses, probably by impairing the biological functions of NCp7. In order to more precisely elucidate the structural role of the zinc finger motif, His23 was replaced by Cys in the proximal finger of the peptide (13-64)NCp7 which retains NCp7 activities in vitro. The peptide Cys23(13-64)NCp7 was synthesized by solid phase and studied by 2D 1H NMR and molecular modeling. The His to Cys modification causes important structural modifications of the N-terminal zinc finger which impair the spatial proximity of the two zinc fingers as shown by the disappearance of several interresidue NOEs. The side chains of Val13, Lys14, Phe16, Thr24, Ala25, Trp37, Gln45, and Met46, which are thought to be involved in nucleic acid recognition, are no longer found clustered in the Cys23(13-64)NCp7 mutant as they are in the wild-type NCp7 structure. In vitro, Cys23(13-64)NCp7 is unable to tightly interact with the viral RNA or replication primer tRNA(Lys,3). The Cys23(NCp7) mutation was introduced into an infectious HIV-1 molecular clone, and virions produced upon DNA transfection into cells were analyzed for their viral protein and RNA compositions as well as for their infectivity. Results show that, while the Cys23(NCp7) mutation does not impair virion production, viruses contain a low amount of degraded viral RNA and are not infectious. These findings suggest that a bona fide conformation of the HIV-1 NCp7 is critical for the packaging of viral RNA, its stability in virions, and virus infectivity.

Three-dimensional 1H NMR structure of the nucleocapsid protein NCp10 of Moloney murine leukemia virus.

The nucleocapsid protein of Moloney murine leukemia virus (NCp10) is a 56-amino acid protein which contains one zinc finger of the CysX2CysX4HisX4Cys form, a highly conserved motif present in most retroviruses and retroelements. At pH > or = 5, NCp10 binds one zinc atom and the complexation induces a folding of the CysX2CysX4HEsX4Cys box, similar to that observed for the zinc-binding domains of HIV-1 NC protein. The three-dimensional structure of NCp10 has been determined in aqueous solution by 600 MHz 1H NMR spectroscopy. The proton resonances could be almost completely assigned by means of phase-sensitive double-quantum-filtered COSY, TOCSY and NOESY techniques. NOESY spectra yielded 597 relevant structural constraints, which were used as input for distance geometry calculations with DIANA. Further refinement was performed by minimization with the program AMBER, which was modified by introducing a zinc force field. The solution structure is characterized by a well-defined central zinc finger (rmsd of 0.747 +/- 0.209 A for backbone atoms and 1.709 +/- 0.187 A when all atoms are considered), surrounded by flexible N- and C-terminal domains. The Tyr28, Trp35, Lys37, Lys41 and Lys42 residues, which are essential for activity, lie on the same face of the zinc finger, forming a bulge structure probably involved in viral RNA binding. The significance of these structural characteristics for the various biological functions of the protein is discussed, taking into account the results obtained with various mutants.

Conformational behaviour of the active and inactive forms of the nucleocapsid NCp7 of HIV-1 studied by 1H NMR.

The nucleocapsid protein NCp7 of the human immunodeficiency virus type I (HIV-1) is a 72 amino acid peptide containing two zinc fingers of the type CX2CX4HX4C linked by a short basic sequence 29RAPRKKG35. NCp7 was shown to activate in vitro both viral RNA dimerization and replication primer tRNA(Lys,3) annealing to the initiation site of reverse transcription. In order to clarify the possible structural role of the zinc fingers in the various functions of NCp7, complete sequence specific 1H NMR assignment of the entire protein was achieved by two-dimensional NMR experiments. Moreover, to characterize the role of the peptide linker in NCp7 folding, a synthetic analogue with an inversion of Pro31 configuration was studied by NMR and fluorescence techniques. Several long range NOEs implying amino acid protons from the folded zinc fingers and the spacer, such as Ala25 and Trp37, Phe16 and Trp37, Arg32 and Trp37, Lys33 and Trp37, Cys18 and Lys33 disappeared in the D-Pro31 (12-53)NCp7, confirming the spatial proximity of the two CCHC boxes observed in the (13-51)NCp7. This was also confirmed by iodide fluorescence quenching experiments. The N and C-terminal parts of NCp7 displayed a large flexibility except for two short sequences Tyr56 to Gly58 and Tyr64 to Gly66, which seemed to oscillate between random-coil and helical conformations. The biological relevance of the structural characteristics of NCp7 was studied in vitro and in vivo. Substitution of Pro31 by D-Pro31 in the active (13-64)NCp7 peptide led to a severe reduction of dimerization in vitro. Moreover, site-directed mutagenesis substituting Leu for Pro31 resulted in the formation of non-infectious and immature viral particles. These results suggest that the spatial proximity of the zinc fingers induced by the peptide linker, plays a critical role in encapsidation of genomic RNA and morphogenesis of HIV-1 infectious particles.

Replacement of His23 by Cys in a zinc finger of HIV-1 NCp7 led to a change in 1H NMR-derived 3D structure and to a loss of biological activity.

The nucleocapsid protein NCp7 of human immunodeficiency virus type 1 (HIV-1), which is necessary for the formation of infectious virions, contains two zinc fingers of the Cys-X2-Cys-X4-His-X4-Cys form. To elucidate the importance of this particular motif, well conserved in retroviruses and retroelements, we substituted the histidine residue by a cysteine in the first zinc binding domain 13VKCFNCGKEGHTARNCRA30. The structures of the mutated and native zinc complexed peptides were studied by two-dimensional 600 MHz 1H nuclear magnetic resonance (NMR) in aqueous solution. The nuclear Overhauser effects were used as constraints to determine the solution structures using DIANA software followed by AMBER energy refinement. The results show that native and mutant peptides fold into non-identical three-dimensional structures, probably accounting for the loss of retrovirus infectivity following the His-Cys point mutation.

Influence of the N- and C-terminal chains on the zinc-binding and conformational properties of the central zinc-finger structure of Moloney murine leukaemia virus nucleocapsid protein: a steady-state and time-resolved fluorescence study.

The nucleocapsid protein NCp10 of the Moloney murine leukaemia virus is a small basic protein characterized by a central Cys26-X2-Cys29-X4-His34-X4-Cys39 zinc-finger domain. Mutants with deletion of either the N- or C-terminal chain (or both) surrounding the central zinc-finger domain were synthesized by a solid-phase approach in order to evaluate the influence of these lateral chains on zinc binding and conformational properties of NCp10. For this purpose, the steady-state and time-resolved fluorescence properties of the single Trp-35 residue of the various NCp10 derivatives were analyzed. The binding properties of the various derivatives suggest that the central zinc-finger domain affinity for zinc is not modified by the N-terminal chain and is only slightly (about one order of magnitude) increased by the C-terminal chain leading to a Kapp of (1.2 +/- 0.2).10(14) M-1 for the whole NCp10. Concerning the conformation of the NCp10 derivatives, fluorescence data are in agreement with structureless polypeptide chains in the absence of zinc. In contrast, in the presence of zinc, the fluorescence intensity decays are in agreement with a unique conformation of the finger motif backbone and a distribution of the Trp-indole moiety into two classes with different local environments. Decay-associated spectra, fluorescence quenching by acrylamide and anisotropy decay data further suggest that the Trp-indole moiety of both classes was highly exposed to solvent and had a high degree of rotational freedom. Finally, in contrast to the C-terminal chain, the N-terminal chain modifies the local environment and the accessibility to external quenchers of both Trp-35 classes, suggesting that it was folded in the vicinity of the Trp-35 residue.