Aqueous solution structure of a hybrid lentiviral Tat peptide and a model of its interaction with HIV-1 TAR RNA.

Human immunodeficiency virus, type 1, (HIV-1) encodes a transactivating regulatory protein, called Tat, which is required for efficient transcription of the viral genome. Tat acts by binding to a specific RNA stem-loop element, called TAR, on nascent viral transcripts. The specificity of binding is principally determined by residues in a short, highly basic domain of Tat. The structure in aqueous solution of a biologically active peptide, comprised of the ten-amino acid HIV-1 Tat basic domain linked to a 15-amino acid segment of the core regulatory domain of another lentiviral Tat, i.e., that from equine infectious anemia virus (EIAV), has been determined. The restraint data set includes interproton distance bounds determined from two-dimensional nuclear Overhauser effect (2D NOE) spectra via a complete relaxation matrix analysis. Thirty structures consistent with the experimental data were generated via the distance geometry program DIANA. Subsequent restrained molecular mechanics calculations were used to define the conformational space subtended by the peptide. A large fraction of the 25-mer peptide assumes a structure in aqueous solution with the lysine- and arginine-rich HIV-1 basic domain being separated from the basic domain by a turn and characterized by a nascent helix as well. The Tat peptide/TAR complex could be modeled with the basic alpha-helix lying in the major groove of TAR such that important interactions of a putative specificity-endowing arginine are maintained and very slight widening of the major groove is entailed.

[1]  P. Sharp,et al.  HIV‐1 Tat protein promotes formation of more‐processive elongation complexes. , 1991, The EMBO journal.

[2]  A. Frankel,et al.  Electrostatic interactions modulate the RNA-binding and transactivation specificities of the human immunodeficiency virus and simian immunodeficiency virus Tat proteins. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[3]  B Tidor,et al.  Arginine-mediated RNA recognition: the arginine fork , 1991, Science.

[4]  K Wüthrich,et al.  Improved efficiency of protein structure calculations from NMR data using the program DIANA with redundant dihedral angle constraints , 1991, Journal of biomolecular NMR.

[5]  K. Wüthrich NMR of proteins and nucleic acids , 1988 .

[6]  J. Stewart Solid Phase Peptide Synthesis , 1984 .

[7]  T. James,et al.  A theoretical study of distance determinations from NMR. Two-dimensional nuclear overhauser effect spectra , 1984 .

[8]  C. Turck,et al.  NMR structure of a biologically active peptide containing the RNA-binding domain of human immunodeficiency virus type 1 Tat. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[9]  D. Hudson,et al.  Analysis of arginine-rich peptides from the HIV Tat protein reveals unusual features of RNA-protein recognition. , 1991, Genes & development.

[10]  Werner Braun,et al.  Automated stereospecific 1H NMR assignments and their impact on the precision of protein structure determinations in solution , 1989 .

[11]  Ad Bax,et al.  MLEV-17-based two-dimensional homonuclear magnetization transfer spectroscopy , 1985 .

[12]  E. Purisima,et al.  Conformational stability of a thrombin-binding peptide derived from the hirudin C-terminus. , 1992, Biochemistry.

[13]  D M Crothers,et al.  Fragments of the HIV-1 Tat protein specifically bind TAR RNA. , 1990, Science.

[14]  B. Borgias,et al.  COMATOSE, a method for constrained refinement of macromolecular structure based on two-dimensional nuclear overhauser effect spectra , 1988 .

[15]  P. Thomas,et al.  Protein solution structure determination using distances from two-dimensional nuclear Overhauser effect experiments: effect of approximations on the accuracy of derived structures. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[16]  R. Cramer,et al.  Validation of the general purpose tripos 5.2 force field , 1989 .

[17]  M. Malim,et al.  Mutational analysis of the conserved basic domain of human immunodeficiency virus tat protein , 1989, Journal of virology.

[18]  F. Kashanchi,et al.  Direct interaction of human TFIID with the HIV-1 transactivator Tat , 1994, Nature.

[19]  G. Ciccotti,et al.  Numerical Integration of the Cartesian Equations of Motion of a System with Constraints: Molecular Dynamics of n-Alkanes , 1977 .

[20]  D. Crothers,et al.  RNA recognition by Tat-derived peptides: Interaction in the major groove? , 1991, Cell.

[21]  K Wüthrich,et al.  Pseudo-structures for the 20 common amino acids for use in studies of protein conformations by measurements of intramolecular proton-proton distance constraints with nuclear magnetic resonance. , 1983, Journal of molecular biology.

[22]  Richard R. Ernst,et al.  Coherence transfer by isotropic mixing: Application to proton correlation spectroscopy , 1983 .

[23]  J. Puglisi,et al.  Conformation of the TAR RNA-arginine complex by NMR spectroscopy. , 1992, Science.

[24]  Thomas L. James,et al.  Computational strategies pertinent to NMR solution structure determination , 1994 .

[25]  R Langridge,et al.  Molecular interactive display and simulation: MIDAS , 1984 .

[26]  B. Borgias,et al.  MARDIGRAS : a procedure for matrix analysis of relaxation for discerning geometry of an aqueous structure , 1990 .

[27]  A. Frankel,et al.  Circular dichroism studies suggest that TAR RNA changes conformation upon specific binding of arginine or guanidine. , 1992, Biochemistry.

[28]  P. Luciw,et al.  Anti-termination of transcription within the long terminal repeat of HIV-1 by tat gene product , 1987, Nature.

[29]  Y. Vaishnav,et al.  The biochemistry of AIDS. , 1991, Annual review of biochemistry.

[30]  J. Puglisi,et al.  Role of RNA structure in arginine recognition of TAR RNA. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[31]  B. Cullen,et al.  Does the human immunodeficiency virus Tat trans-activator contain a discrete activation domain? , 1990, Virology.

[32]  J T Finch,et al.  RNA binding by the tat and rev proteins of HIV-1. , 1991, Biochimie.

[33]  A J Wand,et al.  Statistical strategy for stereospecific hydrogen NMR assignments: Validation procedures for the floating prochirality method , 1993, Journal of biomolecular NMR.

[34]  D. Antelman,et al.  Characterization of recombinant HIV-1 Tat and its interaction with TAR RNA. , 1992, Biochemistry.

[35]  B. Peterlin,et al.  Inhibition of human immunodeficiency virus type 1 Tat activity by coexpression of heterologous trans activators , 1992, Journal of virology.

[36]  P. Thomas,et al.  Averaging of cross-relaxation rates and distances for methyl, methylene, and aromatic ring protons due to motion or overlap. Extraction of accurate distances iteratively via relaxation matrix analysis of 2D NOE spectra , 1992 .

[37]  F. Richards,et al.  The chemical shift index: a fast and simple method for the assignment of protein secondary structure through NMR spectroscopy. , 1992, Biochemistry.

[38]  J Grasby,et al.  Hydrogen-bonding contacts in the major groove are required for human immunodeficiency virus type-1 tat protein recognition of TAR RNA. , 1993, Journal of molecular biology.

[39]  P. S. Ho,et al.  Circular dichroism and molecular modeling yield a structure for the complex of human immunodeficiency virus type 1 trans-activation response RNA and the binding region of Tat, the trans-acting transcriptional activator. , 1992, Proceedings of the National Academy of Sciences of the United States of America.

[40]  B. Peterlin,et al.  A minimal lentivirus Tat , 1991, Journal of virology.

[41]  G. Wagner Prospects for NMR of large proteins , 1993, Journal of biomolecular NMR.

[42]  J. Gasteiger,et al.  ITERATIVE PARTIAL EQUALIZATION OF ORBITAL ELECTRONEGATIVITY – A RAPID ACCESS TO ATOMIC CHARGES , 1980 .

[43]  H. Sticht,et al.  Structure of the equine infectious anemia virus Tat protein. , 1994, Science.