DNA condensation by the nucleocapsid protein of HIV-1: a mechanism ensuring DNA protection

The nucleocapsid (NC) protein NCp7 of the immunodeficiency virus type 1 is a small basic protein with two zinc finger motifs. NCp7 has key roles in virus replication and structure, which rely on its interactions with nucleic acids. Although most interactions involve RNAs, binding to the viral DNA is thought to be of importance to achieve protection of the DNA against cellular nucleases and its integration into the host genome. We investigated the interaction of NCp7 with plasmid DNA as a model system. The fluorescence probe YOYO-1 was used as the reporter. Binding of NCp7 to DNA caused DNA condensation, as inferred from the dramatic decrease in YOYO-1 fluorescence. Efficient condensation of DNA required the full length NCp7 with the zinc fingers. The fingerless peptide was less efficient in condensing DNA. Binding of both these NC peptides led to freezing of the segmental dynamics of DNA as revealed by anisotropy decay kinetics of YOYO-1. The truncated peptide NC(12–55) which retains the zinc fingers did not lead to DNA condensation despite its ability to bind and partially freeze the segmental motion of DNA. We propose that the histone-like property of NCp7 leading to DNA condensation contributes to viral DNA stability, in vivo.     

Cofactors for human immunodeficiency virus type 1 cDNA integration in vitro

We have investigated the function of two DNA binding proteins that stimulate human immunodeficiency virus type 1 cDNA integration in vitro, the cellular HMGa1 protein and the viral nucleocapsid (NC) protein. Of the three forms of NC (NCp7, NCp9, and NCp15), we find that NCp9 is the most effective at increasing integration in vitro; thus, processing of NC may potentially modulate its activities during infection. We also found that maximal stimulation by NCp9 required roughly enough NC to coat the reactant DNAs whereas less HMGa1 was required, and the reactions displayed different optima for divalent metal cofactors and order of addition. These findings reveal probable distinct mechanisms of action in vitro.     

Analysis of the nucleic acid annealing activities of nucleocapsid protein from HIV-1.

Retroviral nucleocapsid (NC) protein is an integral part of the virion nucleocapsid where it is in tight association with genomic RNA and the tRNA primer. NC protein is necessary for the dimerization and encapsidation of genomic RNA, the annealing of the tRNA primer to the primer binding site (PBS) and the initial strand transfer event. Due to the general nature of NC protein-promoted annealing, its use to improve nucleic acid interactions in various reactions can be envisioned. Parameters affecting NC-promoted nucleic acid annealing of NCp7 from HIV-1 have been analyzed. The promotion of RNA:RNA and RNA:DNA annealing by NCp7 is more sensitive to the concentration of MgCl2 than the promotion of DNA:DNA hybridization. Stimulation of complex formation for all three complexes was efficient at 0-90 mM NaCl, between 23 and 55 degrees C and at pH values between 6.5 and 9.5, inclusive. Parameters affecting NCp7-promoted hybridization of tRNA(Lys,3) to the PBS, which appears to be specific for NC protein, will be discussed. Results implicate the basic regions of NCp7, but not the zinc fingers, in promoting the annealing of complementary nucleic acid sequences. Finally, NCp7 strand transfer activity aids the formation of the most stable nucleic acid complex.     

Human immunodeficiency virus type 1 nucleocapsid protein specifically stimulates Mg2+-dependent DNA integration in vitro.

The integrase (IN) protein of the human immunodeficiency virus mediates integration of the viral DNA into the cellular genome. In vitro, this reaction can be mimicked by using purified recombinant IN and model DNA substrates. IN mediates two reactions: an endonucleolytic cleavage at each 3' end of the proviral DNA (terminal cleavage) and the joining of the linear viral DNA to 5' phosphates in the target DNA (strand transfer). Previous investigators have shown that purified IN requires Mn2+ or Mg2+ to promote strand transfer in vitro, although Mg2+ is the likely metal cofactor in vivo. IN activity in the presence of Mg2+ in vitro requires high IN concentrations and low concentrations of salt. Here, we show that the viral nucleocapsid protein NCp7 allows efficient IN-mediated strand transfer in the presence of Mg2+ at low enzyme concentrations. This potentiating effect appears to be unique to NCp7, as other small DNA-binding proteins, while capable of stimulating integration in the presence of Mn2+, all failed to stimulate strand transfer in the presence of Mg2+.     

Nucleic acid binding properties of the simian immunodeficiency virus nucleocapsid protein NCp8

The nucleocapsid protein of simian immunodeficiency virus (SIV) NCp8 has two copies of conserved sequences (termed zinc fingers, ZF) of 14 amino acids with 4 invariant residues (CCHC) that coordinate Zn(II). Each of its two ZFs has a Trp residue. A significant quenching of NCp8 Trp fluorescence was seen in nucleic acid complexes, suggesting stacking of the indole ring with nucleobases and the simultaneous involvement of both ZFs in the binding process. Both ZFs contribute to the nucleic acid binding free energy of NCp8, albeit in a not additive manner. NCp8 exhibited a base preference analogous to that of NCp7: G approximately I > T > U > C > A. Alternating base sequences that bind HIV-1 NCp7 in a sequence-specific manner were also bound selectively by NCp8. Specific sequence recognition required at least five bases and the presence of bound Zn(II). The two ZFs account for the net displacement of 3 out of 4 sodium ions upon binding (2 by the first and one by the second finger), and for most (85%) of the hydrophobic stabilization in complex formation. Based on the sequence and functional similarity of SIV NCp8 and HIV-1 NCp7, and using available structural information for free and oligonucleotide bound NCp7, we propose a structural model for NCp8-oligonucleotide complexes.     

G-quartets direct assembly of HIV-1 nucleocapsid protein along single-stranded DNA

The d(TTGGGGGGTACAGTGCA) sequence, derived from the human immunodeficiency virus type 1 (HIV-1) central DNA flap, can form in vitro an intermolecular parallel DNA quadruplex. This work demonstrates that the HIV-1 nucleocapsid protein (NCp) exhibits a high affinity (10⁸ M^–1) for this quadruplex. This interaction is predominantly hydrophobic, maintained by a stabilization between G-quartet planes and the C-terminal zinc finger of the protein. It also requires 5 nt long tails flanking the quartets plus both the second zinc-finger and the N-terminal domain of NCp. The initial binding nucleates an ordered arrangement of consecutive NCp along the four single-stranded tails. Such a process requires the N-terminal zinc finger, and was found to occur for DNA site sizes shorter than usual in a sequence-dependent manner. Concurrently, NCp binding is efficient on a G′2 quadruplex also derived from the HIV-1 central DNA flap. Apart from their implication within the DNA flap, these data lead to a model for the nucleic acid architecture within the viral nucleocapsid, where adjacent single-stranded tails and NCp promote a compact assembly of NCp and nucleic acid growing from stably and primary bound NCp.     

Effects of temperature on the dynamic behaviour of the HIV-1 nucleocapsid NCp7 and its DNA complex

The nucleocapsid protein NCp7 of human immunodeficiency virus type 1 (HIV-1) contains two highly conserved CCHC zinc fingers and is involved in many crucial steps of the virus life-cycle. A large number of physiological r?les of NCp7 involve its binding to single-stranded nucleic acid chains. Several solution structures of NCp7 and its complex with single-stranded RNA or DNA have been reported. We have investigated the changes in the dynamic behaviour experienced by the (12-53)NCp7 peptide upon DNA binding using (15)N heteronuclear relaxation measurements at 293 K and 308 K, and fluorescence spectroscopy. The relaxation data were interpreted using the reduced spectral density approach, which allowed the high-frequency motion, overall tumbling rates and the conformational exchange contributions to be characterized for various states of the peptide without using a specific motional model. Analysis of the temperature-dependent correlation times derived from both NMR and fluorescence data indicated a co-operative change of the molecular shape of apo (12-53)NCp7 around 303 K, leading to an increased hydrodynamic radius at higher temperatures. The binding of (12-53)NCp7 to a single-stranded d(ACGCC) pentanucleotide DNA led to a reduction of the conformational flexibility that characterized the apo peptide. Translational diffusion experiments as well as rotational correlation times indicated that the (12-53)NCp7/d(ACGCC) complex tumbles as a rigid object. The amplitudes of high-frequency motions were restrained in the complex and the occurrence of conformational exchange was displaced from the second zinc finger to the linker residue Ala30.     

Inactivation of HIV-1 nucleocapsid protein P7 by pyridinioalkanoyl thioesters. Characterization of reaction products and proposed mechanism of action

The synthesis and antiviral properties of pyridinioalkanoyl thioester (PATE) compounds that target nucleocapsid p7 protein (NCp7) of the human immunodeficiency virus type 1 (HIV-1) have been described previously (Turpin, J. A., Song, Y., Inman, J. K., Huang, M., Wallqvist, A., Maynard, A., Covell, D. G., Rice, W. G., and Appella, E. (1999) J. Med. Chem. 42, 67-86). In the present study, fluorescence and electrospray ionization-mass spectrometry were employed to determine the mechanism of modification of NCp7 by two lead compounds, N-[2-(5-pyridiniovaleroylthio)benzoyl]sulfacetamide bromide and N-[2-(5-pyridiniovaleroylthio)benzoyl]-4-(4-nitrophenylsulfonyl )anili ne bromide (compounds 45 and 47, respectively). Although both compounds exhibit antiviral activity in cell-based assays, we failed to detect appreciable ejection of zinc from NCp7 under conditions in which previously described NCp7-active disulfides readily eject zinc. However, upon "activation" by Ag(+), compound 45 reacted with NCp7 resulting in the zinc ejection from both zinc fingers. The reaction followed a two-step mechanism in which zinc was ejected from the carboxyl-terminal zinc finger faster than from the amino-terminal zinc finger. Both compounds covalently modified the protein with pyridinioalkanoyl groups. Compound 45 modified cysteines 36 and 49 of the carboxyl-terminal zinc finger. The results obtained herein demonstrate that PATE compounds can be constructed that selectively target only one of the two zinc fingers of NCp7, thus providing an impetus to pursue development of highly selective zinc finger inhibitors.     

Application of electrospray ionization mass spectrometry for studying human immunodeficiency virus protein complexes

Mass spectrometry (MS) with electrospray ionization (ESI) has shown utility for studying noncovalent protein complexes, as it offers advantages in sensitivity, speed, and mass accuracy. The stoichiometry of the binding partners can be easily deduced from the molecular weight measurement. In many examples of protein complexes, the gas phase-based measurement is consistent with the expected solution phase binding characteristics. This quality suggests the utility of ESI-MS for investigating solution phase molecular interactions. Complexes composed of proteins from the human immunodeficiency virus (HIV) have been studied using ESI-MS. Multiply charged protein dimers from HIV integrase catalytic core (F185K) and HIV protease have been observed. Furthermore, the ternary complex between HIV protease dimer and inhibitor pepstatin A was studied as a function of solution pH. Zinc binding to zinc finger-containing nucleocapsid protein (NCp7) and the NCp7-psi RNA 1:1 stoichiometry complex was also studied by ESI-MS. No protein-RNA complex was observed in the absence of zinc, consistent with the role of the zinc finger motifs for RNA binding. Proteins Suppl. 2:28–37, 1998. © 1998 Wiley-Liss, Inc.