Characterizing complex dynamics in the transactivation response element apical loop and motional correlations with the bulge by NMR, molecular dynamics, and mutagenesis.

The HIV-1 transactivation response element (TAR) RNA binds a variety of proteins and is a target for developing anti-HIV therapies. TAR has two primary binding sites: a UCU bulge and a CUGGGA apical loop. We used NMR residual dipolar couplings, carbon spin relaxation (R(1) and R(2)), and relaxation dispersion (R(1rho)) in conjunction with molecular dynamics and mutagenesis to characterize the dynamics of the TAR apical loop and investigate previously proposed long-range interactions with the distant bulge. Replacement of the wild-type apical loop with a UUCG loop did not significantly affect the structural dynamics at the bulge, indicating that the apical loop and the bulge act largely as independent dynamical recognition centers. The apical loop undergoes complex dynamics at multiple timescales that are likely important for adaptive recognition: U31 and G33 undergo limited motions, G32 is highly flexible at picosecond-nanosecond timescales, and G34 and C30 form a dynamic Watson-Crick basepair in which G34 and A35 undergo a slow (approximately 30 mus) likely concerted looping in and out motion, with A35 also undergoing large amplitude motions at picosecond-nanosecond timescales. Our study highlights the power of combining NMR, molecular dynamics, and mutagenesis in characterizing RNA dynamics.

[1]  C. Di Primo,et al.  NMR structure of a kissing complex formed between the TAR RNA element of HIV-1 and a LNA-modified aptamer , 2007, Nucleic acids research.

[2]  H. Al‐Hashimi,et al.  Structural plasticity and Mg2+ binding properties of RNase P P4 from combined analysis of NMR residual dipolar couplings and motionally decoupled spin relaxation. , 2006, RNA.

[3]  H. Hauser,et al.  Recognition of 5'-terminal TAR structure in human immunodeficiency virus-1 mRNA by eukaryotic translation initiation factor 2. , 2000, Nucleic acids research.

[4]  Ben Berkhout,et al.  Evidence for a base triple in the free HIV-1 TAR RNA. , 2004, RNA.

[5]  G. Lipari Model-free approach to the interpretation of nuclear magnetic resonance relaxation in macromolecules , 1982 .

[6]  P A Kollman,et al.  Molecular dynamics studies of the HIV-1 TAR and its complex with argininamide. , 2000, Nucleic acids research.

[7]  W. L. Jorgensen,et al.  Comparison of simple potential functions for simulating liquid water , 1983 .

[8]  J H Prestegard,et al.  Structural and dynamic analysis of residual dipolar coupling data for proteins. , 2001, Journal of the American Chemical Society.

[9]  A. Gronenborn,et al.  Measurement of Residual Dipolar Couplings of Macromolecules Aligned in the Nematic Phase of a Colloidal Suspension of Rod-Shaped Viruses , 1998 .

[10]  Ioan Andricioaei,et al.  iRED analysis of TAR RNA reveals motional coupling, long-range correlations, and a dynamical hinge. , 2007, Biophysical journal.

[11]  S. Sigurdsson,et al.  EPR spectroscopic analysis of TAR RNA-metal ion interactions. , 2003, Biochemical and biophysical research communications.

[12]  J. Williamson Induced fit in RNA–protein recognition , 2000, Nature Structural Biology.

[13]  A. Serganov,et al.  Argininamide binding arrests global motions in HIV-1 TAR RNA: comparison with Mg2+-induced conformational stabilization. , 2004, Journal of molecular biology.

[14]  G. Varani,et al.  Recent advances in RNA-protein recognition. , 2001, Current opinion in structural biology.

[15]  K. Jeang,et al.  Direct interactions between autoantigen La and human immunodeficiency virus leader RNA , 1994, Journal of virology.

[16]  J. Williamson,et al.  Solution structure of the HIV-2 TAR-argininamide complex. , 1997, Journal of molecular biology.

[17]  A. Szabó,et al.  Model-free approach to the interpretation of nuclear magnetic resonance relaxation in macromolecules. 1. Theory and range of validity , 1982 .

[18]  Hoover,et al.  Canonical dynamics: Equilibrium phase-space distributions. , 1985, Physical review. A, General physics.

[19]  J H Prestegard,et al.  Order matrix analysis of residual dipolar couplings using singular value decomposition. , 1999, Journal of magnetic resonance.

[20]  D. Patel,et al.  Towards structural genomics of RNA: rapid NMR resonance assignment and simultaneous RNA tertiary structure determination using residual dipolar couplings. , 2002, Journal of molecular biology.

[21]  T. Rana,et al.  Specific HIV-1 TAR RNA loop sequence and functional groups are required for human cyclin T1-Tat-TAR ternary complex formation. , 2002, Biochemistry.

[22]  J. Feigon,et al.  Two-and three-dimensional HCN experiments for correlating base and sugar resonances in 15N, 13C-labeled RNA oligonucleotides , 1993, Journal of biomolecular NMR.

[23]  D. Capon,et al.  Regulation of mRNA accumulation by a human immunodeficiency virus trans-activator protein , 1987, Cell.

[24]  I. Tinoco,et al.  The structure of an RNA "kissing" hairpin complex of the HIV TAR hairpin loop and its complement. , 1997, Journal of molecular biology.

[25]  H. Schwalbe,et al.  Triple resonance experiments for the simultaneous correlation of H6/H5 and exchangeable protons of pyrimidine nucleotides in 13C,15N-labeled RNA applicable to larger RNA molecules , 2003, Journal of biomolecular NMR.

[26]  T. Kulinski,et al.  The Apical Loop of the HIV-1 TAR RNA Hairpin Is Stabilized by a Cross-loop Base Pair* , 2003, Journal of Biological Chemistry.

[27]  J. Karn,et al.  The structure of the human immunodeficiency virus type-1 TAR RNA reveals principles of RNA recognition by Tat protein. , 1995, Journal of molecular biology.

[28]  A. Giordano,et al.  Transcriptional regulation by targeted recruitment of cyclin-dependent CDK9 kinase in vivo , 1999, Oncogene.

[29]  H. Al‐Hashimi,et al.  Insight into the CSA tensors of nucleobase carbons in RNA polynucleotides from solution measurements of residual CSA: towards new long-range orientational constraints. , 2006, Journal of magnetic resonance.

[30]  S. Sigurdsson,et al.  Electron paramagnetic resonance dynamic signatures of TAR RNA-small molecule complexes provide insight into RNA structure and recognition. , 2002, Biochemistry.

[31]  H. Al‐Hashimi,et al.  Dynamics of large elongated RNA by NMR carbon relaxation. , 2007, Journal of the American Chemical Society.

[32]  M. Negroni,et al.  Specific interactions between HIV-1 nucleocapsid protein and the TAR element. , 2005, Journal of molecular biology.

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

[34]  O. W. Sørensen,et al.  The role of coherence transfer efficiency in design of TROSY-type multidimensional NMR experiments. , 1999, Journal of magnetic resonance.

[35]  D. Crothers,et al.  Characterization of the solution conformations of unbound and Tat peptide-bound forms of HIV-1 TAR RNA. , 1999, Biochemistry.

[36]  K. Jeang,et al.  An Arg/Lys-rich core peptide mimics TRBP binding to the HIV-1 TAR RNA upper-stem/loop. , 1998, Journal of molecular biology.

[37]  Francesca Massi,et al.  Characterization of the dynamics of biomacromolecules using rotating-frame spin relaxation NMR spectroscopy. , 2006, Chemical reviews.

[38]  N. Walter,et al.  Long-range impact of peripheral joining elements on structure and function of the hepatitis delta virus ribozyme , 2007, Biological chemistry.

[39]  H. Al‐Hashimi,et al.  Probing Na(+)-induced changes in the HIV-1 TAR conformational dynamics using NMR residual dipolar couplings: new insights into the role of counterions and electrostatic interactions in adaptive recognition. , 2007, Biochemistry.

[40]  Hashim M. Al-Hashimi,et al.  Review NMR studies of RNA dynamics and structural plasticity using NMR residual dipolar couplings , 2007 .

[41]  S. Nosé A unified formulation of the constant temperature molecular dynamics methods , 1984 .

[42]  P. Hagerman,et al.  Bulge-induced bends in RNA: quantification by transient electric birefringence. , 1995, Journal of molecular biology.

[43]  I. Andricioaei,et al.  Impact of static and dynamic A-form heterogeneity on the determination of RNA global structural dynamics using NMR residual dipolar couplings , 2006, Journal of biomolecular NMR.

[44]  J. Williamson,et al.  Base flexibility in HIV-2 TAR RNA mapped by solution (15)N, (13)C NMR relaxation. , 2002, Journal of molecular biology.

[45]  H. Schwalbe,et al.  NMR Spectroscopy of RNA , 2003, Chembiochem : a European journal of chemical biology.

[46]  Yueh-Hsin Ping,et al.  TAR RNA loop: A scaffold for the assembly of a regulatory switch in HIV replication , 2002, Proceedings of the National Academy of Sciences of the United States of America.

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

[48]  S. Neidle Oxford handbook of nucleic acid structure , 1998 .

[49]  T. Steitz,et al.  A 1.3-A resolution crystal structure of the HIV-1 trans-activation response region RNA stem reveals a metal ion-dependent bulge conformation. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[50]  S. Grzesiek,et al.  NMRPipe: A multidimensional spectral processing system based on UNIX pipes , 1995, Journal of biomolecular NMR.

[51]  Alexander D. MacKerell,et al.  Development and current status of the CHARMM force field for nucleic acids , 2000, Biopolymers.

[52]  Zhihua Du,et al.  Structure of TAR RNA complexed with a Tat-TAR interaction nanomolar inhibitor that was identified by computational screening. , 2002, Chemistry & biology.

[53]  D. Patel,et al.  Characterizing the relative orientation and dynamics of RNA A-form helices using NMR residual dipolar couplings , 2007, Nature Protocols.

[54]  J. Karn,et al.  Structure-based drug design targeting an inactive RNA conformation: exploiting the flexibility of HIV-1 TAR RNA. , 2004, Journal of molecular biology.

[55]  A. Pardi,et al.  Filamentous bacteriophage for aligning RNA, DNA, and proteins for measurement of nuclear magnetic resonance dipolar coupling interactions. , 2000, Methods in enzymology.

[56]  J H Prestegard,et al.  Nuclear magnetic dipole interactions in field-oriented proteins: information for structure determination in solution. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[57]  J. Karn,et al.  Tackling Tat. , 1999, Journal of molecular biology.

[58]  G. Varani,et al.  Solid-state deuterium NMR studies reveal micros-ns motions in the HIV-1 transactivation response RNA recognition site. , 2008, Journal of the American Chemical Society.

[59]  I. Haneef,et al.  Modeling and solution structure probing of the HIV-1 TAR stem-loop. , 1993, Journal of molecular graphics.

[60]  K. Jones,et al.  Taking a new TAK on tat transactivation. , 1997, Genes & development.

[61]  A. Gatignol,et al.  HIV-1 TAR RNA: the target of molecular interactions between the virus and its host. , 2005, Current HIV research.

[62]  J. Puglisi,et al.  Specific recognition of HIV TAR RNA by the dsRNA binding domains (dsRBD1-dsRBD2) of PKR. , 2006, Journal of molecular biology.

[63]  Gabriele Varani,et al.  Rational design of inhibitors of HIV-1 TAR RNA through the stabilisation of electrostatic "hot spots". , 2004, Journal of molecular biology.

[64]  A. Bax,et al.  Direct measurement of distances and angles in biomolecules by NMR in a dilute liquid crystalline medium. , 1997, Science.

[65]  A. Kirschning,et al.  TAR-RNA recognition by a novel cyclic aminoglycoside analogue , 2006, Nucleic acids research.

[66]  J. Kjems,et al.  Role of the Trans-activation Response Element in Dimerization of HIV-1 RNA* , 2004, Journal of Biological Chemistry.

[67]  P. Borer,et al.  Structure of the HIV-1 nucleocapsid protein bound to the SL3 psi-RNA recognition element. , 1998, Science.

[68]  D. Patel,et al.  Concerted motions in HIV-1 TAR RNA may allow access to bound state conformations: RNA dynamics from NMR residual dipolar couplings. , 2002, Journal of molecular biology.

[69]  H. Sticht,et al.  Structural Rearrangements of HIV-1 Tat-responsive RNA upon Binding of Neomycin B* , 2000, The Journal of Biological Chemistry.

[70]  A. W. Czarnik,et al.  Inhibitors of protein-RNA complexation that target the RNA: specific recognition of human immunodeficiency virus type 1 TAR RNA by small organic molecules. , 1998, Biochemistry.

[71]  J. Karn,et al.  Structure of HIV-1 TAR RNA in the absence of ligands reveals a novel conformation of the trinucleotide bulge. , 1996, Nucleic acids research.

[72]  Qi Zhang,et al.  Resolving the Motional Modes That Code for RNA Adaptation , 2006, Science.

[73]  A. Litovchick,et al.  Aminoglycoside-arginine conjugates that bind TAR RNA: synthesis, characterization, and antiviral activity. , 2000, Biochemistry.

[74]  Charles K. Fisher,et al.  Visualizing spatially correlated dynamics that directs RNA conformational transitions , 2007, Nature.

[75]  M. Karplus,et al.  Deformable stochastic boundaries in molecular dynamics , 1983 .

[76]  Jafar Kafaie,et al.  Role of the 5' TAR stem--loop and the U5-AUG duplex in dimerization of HIV-1 genomic RNA. , 2008, Biochemistry.

[77]  Michael J Rust,et al.  Single-molecule enzymology of RNA: essential functional groups impact catalysis from a distance. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[78]  N. Tjandra,et al.  An Approach to Direct Determination of Protein Dynamics from 15N NMR Relaxation at Multiple Fields, Independent of Variable 15N Chemical Shift Anisotropy and Chemical Exchange Contributions , 1999 .

[79]  D. Patel,et al.  Evidence that electrostatic interactions dictate the ligand-induced arrest of RNA global flexibility. , 2005, Angewandte Chemie.