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PDBsum entry 397d
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dna_rna metals links
RNA PDB id
397d

 

 

 

 

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Contents
DNA/RNA
Metals
_CA ×4
Waters ×178
PDB id:
397d
Name: RNA
Title: A 1.3 a resolution crystal structure of the HIV-1 trans-activation response region RNA stem reveals a metal ion-dependent bulge conformation
Structure: RNA (5'-r( Gp Gp Cp Cp Ap Gp Ap Up Cp Up Gp Ap Gp Cp G)- 3'). Chain: a. Engineered: yes. RNA (5'-r( Gp Cp Up Cp Up Cp Up Gp Gp Cp Cp C)-3'). Chain: b. Engineered: yes
Source: Synthetic: yes. Synthetic: yes
Biol. unit: Monomer (from PDB file)
Resolution:
1.30Å     R-factor:   0.131     R-free:   0.177
Authors: J.A.Ippolito,T.A.Steitz
Key ref:
J.A.Ippolito and T.A.Steitz (1998). A 1.3-A resolution crystal structure of the HIV-1 trans-activation response region RNA stem reveals a metal ion-dependent bulge conformation. Proc Natl Acad Sci U S A, 95, 9819-9824. PubMed id: 9707559 DOI: 10.1073/pnas.95.17.9819
Date:
30-Apr-98     Release date:   11-Sep-98    
 Headers
 References

DNA/RNA chains
  G-G-C-C-A-G-A-U-C-U-G-A-G-C-G 15 bases
  G-C-U-C-U-C-U-G-G-C-C-C 12 bases

 

 
DOI no: 10.1073/pnas.95.17.9819 Proc Natl Acad Sci U S A 95:9819-9824 (1998)
PubMed id: 9707559  
 
 
A 1.3-A resolution crystal structure of the HIV-1 trans-activation response region RNA stem reveals a metal ion-dependent bulge conformation.
J.A.Ippolito, T.A.Steitz.
 
  ABSTRACT  
 
The crystal structure of an HIV-1 trans-activation response region (TAR) RNA fragment containing the binding site for the trans-activation protein Tat has been determined to 1.3-A resolution. In this crystal structure, the characteristic UCU bulge of TAR adopts a conformation that is stabilized by three divalent calcium ions and differs from those determined previously by solution NMR. One metal ion, crucial to the loop conformation, binds directly to three phosphates in the loop region. The structure emphasizes the influence of metal ion binding on RNA structure and, given the abundance of divalent metal ion in the cell, raises the question of whether metal ions play a role in the conformation of TAR RNA and the interaction of TAR with Tat and cyclin T in vivo.
 
  Selected figure(s)  
 
Figure 2.
Fig. 2. The refined model superimposed on a 2Fo-Fc electron density map of the TAR RNA Ca1-binding site contoured at 1.3 . Ca1 (yellow sphere) stabilizes the bulge backbone structure through direct ligands with the phosphate oxygens of U23, C24, and G26. Three water molecules, depicted as cyan-colored spheres, complete the octahedral coordination. All Ca^2+-phosphate oxygen distances are 2.3 Å. All Ca^2+-water distances are 2.4 Å. 		Figure 3.
Fig. 3. Stereo diagram of the TAR RNA 3-nt bulge region showing the direct and indirect ligands of Ca1, Ca2, and Ca3. Water molecules are colored cyan. Solid yellow bonds denote inner-sphere ligand interactions with the RNA, and black dashed bonds represent outer-sphere coordination. Additional water molecules binding in the bulge region have been omitted for clarity.
 
  Figures were selected by an automated process.  

Literature references that cite this PDB file's key reference

  PubMed id Reference
20535204 T.H.Tahirov, N.D.Babayeva, K.Varzavand, J.J.Cooper, S.C.Sedore, and D.H.Price (2010).
Crystal structure of HIV-1 Tat complexed with human P-TEFb.
  Nature, 465, 747-751.
PDB codes: 3mi9 3mia
19369218 A.T.Frank, A.C.Stelzer, H.M.Al-Hashimi, and I.Andricioaei (2009).
Constructing RNA dynamical ensembles by combining MD and motionally decoupled NMR RDCs: new insights into RNA dynamics and adaptive ligand recognition.
  Nucleic Acids Res, 37, 3670-3679.  
19444830 J.Ferner, M.Suhartono, S.Breitung, H.R.Jonker, M.Hennig, J.Wöhnert, M.Göbel, and H.Schwalbe (2009).
Structures of HIV TAR RNA-ligand complexes reveal higher binding stoichiometries.
  Chembiochem, 10, 1490-1494.
PDB code: 2kmj
19776156 Q.Zhang, and H.M.Al-Hashimi (2009).
Domain-elongation NMR spectroscopy yields new insights into RNA dynamics and adaptive recognition.
  RNA, 15, 1941-1948.  
18166198 D.Nayak, S.Siller, Q.Guo, and R.Sousa (2008).
Mechanism of T7 RNAP pausing and termination at the T7 concatemer junction: a local change in transcription bubble structure drives a large change in transcription complex architecture.
  J Mol Biol, 376, 541-553.  
18621815 E.A.Dethoff, A.L.Hansen, C.Musselman, E.D.Watt, I.Andricioaei, and H.M.Al-Hashimi (2008).
Characterizing complex dynamics in the transactivation response element apical loop and motional correlations with the bulge by NMR, molecular dynamics, and mutagenesis.
  Biophys J, 95, 3906-3915.  
18952821 I.Carter-O'Connell, D.Booth, B.Eason, and N.Grover (2008).
Thermodynamic examination of trinucleotide bulged RNA in the context of HIV-1 TAR RNA.
  RNA, 14, 2550-2556.  
19029897 K.Anand, A.Schulte, K.Vogel-Bachmayr, K.Scheffzek, and M.Geyer (2008).
Structural insights into the cyclin T1-Tat-TAR RNA transcription activation complex from EIAV.
  Nat Struct Mol Biol, 15, 1287-1292.
PDB code: 2w2h
17449677 C.Musselman, H.M.Al-Hashimi, and I.Andricioaei (2007).
iRED analysis of TAR RNA reveals motional coupling, long-range correlations, and a dynamical hinge.
  Biophys J, 93, 411-422.  
18047298 J.M.Blose, M.L.Manni, K.A.Klapec, Y.Stranger-Jones, A.C.Zyra, V.Sim, C.A.Griffith, J.D.Long, and M.J.Serra (2007).
Non-nearest-neighbor dependence of the stability for RNA bulge loops based on the complete set of group I single-nucleotide bulge loops.
  Biochemistry, 46, 15123-15135.  
17594140 M.Getz, X.Sun, A.Casiano-Negroni, Q.Zhang, and H.M.Al-Hashimi (2007).
NMR studies of RNA dynamics and structural plasticity using NMR residual dipolar couplings.
  Biopolymers, 86, 384-402.  
17571061 M.H.Bailor, C.Musselman, A.L.Hansen, K.Gulati, D.J.Patel, and H.M.Al-Hashimi (2007).
Characterizing the relative orientation and dynamics of RNA A-form helices using NMR residual dipolar couplings.
  Nat Protoc, 2, 1536-1546.  
18097416 Q.Zhang, A.C.Stelzer, C.K.Fisher, and H.M.Al-Hashimi (2007).
Visualizing spatially correlated dynamics that directs RNA conformational transitions.
  Nature, 450, 1263-1267.  
16399833 A.Barthel, and M.Zacharias (2006).
Conformational transitions in RNA single uridine and adenosine bulge structures: a molecular dynamics free energy simulation study.
  Biophys J, 90, 2450-2462.  
16492787 B.Pan, K.Shi, and M.Sundaralingam (2006).
Base-tetrad swapping results in dimerization of RNA quadruplexes: implications for formation of the i-motif RNA octaplex.
  Proc Natl Acad Sci U S A, 103, 3130-3134.
PDB code: 2awe
17077936 C.Musselman, S.W.Pitt, K.Gulati, L.L.Foster, I.Andricioaei, and H.M.Al-Hashimi (2006).
Impact of static and dynamic A-form heterogeneity on the determination of RNA global structural dynamics using NMR residual dipolar couplings.
  J Biomol NMR, 36, 235-249.  
16138302 H.M.Al-Hashimi (2005).
Dynamics-based amplification of RNA function and its characterization by using NMR spectroscopy.
  Chembiochem, 6, 1506-1519.  
15861447 S.W.Pitt, Q.Zhang, D.J.Patel, and H.M.Al-Hashimi (2005).
Evidence that electrostatic interactions dictate the ligand-induced arrest of RNA global flexibility.
  Angew Chem Int Ed Engl, 44, 3412-3415.  
14970387 H.Huthoff, F.Girard, S.S.Wijmenga, and B.Berkhout (2004).
Evidence for a base triple in the free HIV-1 TAR RNA.
  RNA, 10, 412-423.  
15189877 N.H.Green, P.M.Williams, O.Wahab, M.C.Davies, C.J.Roberts, S.J.Tendler, and S.Allen (2004).
Single-molecule investigations of RNA dissociation.
  Biophys J, 86, 3811-3821.  
15121895 P.S.Klosterman, D.K.Hendrix, M.Tamura, S.R.Holbrook, and S.E.Brenner (2004).
Three-dimensional motifs from the SCOR, structural classification of RNA database: extruded strands, base triples, tetraloops and U-turns.
  Nucleic Acids Res, 32, 2342-2352.  
12737819 A.Matsugami, S.Kobayashi, K.Ouhashi, S.Uesugi, R.Yamamoto, K.Taira, S.Nishikawa, P.K.Kumar, and M.Katahira (2003).
Structural basis of the highly efficient trapping of the HIV Tat protein by an RNA aptamer.
  Structure, 11, 533-545.
PDB code: 1nbk
14604532 B.Pan, Y.Xiong, K.Shi, and M.Sundaralingam (2003).
Crystal structure of a bulged RNA tetraplex at 1.1 a resolution: implications for a novel binding site in RNA tetraplex.
  Structure, 11, 1423-1430.
PDB code: 1p79
12604517 C.Parolin, B.Gatto, C.Del Vecchio, T.Pecere, E.Tramontano, V.Cecchetti, A.Fravolini, S.Masiero, M.Palumbo, and G.Palù (2003).
New anti-human immunodeficiency virus type 1 6-aminoquinolones: mechanism of action.
  Antimicrob Agents Chemother, 47, 889-896.  
12736317 E.Ennifar, P.Walter, and P.Dumas (2003).
A crystallographic study of the binding of 13 metal ions to two related RNA duplexes.
  Nucleic Acids Res, 31, 2671-2682.
PDB codes: 1nlc 1nle 1o3z 1wvd 1y6s 1y6t 1y73 1y90 1y95 2oij
12796301 S.Sbicego, J.D.Alfonzo, A.M.Estévez, M.A.Rubio, X.Kang, C.W.Turck, M.Peris, and L.Simpson (2003).
RBP38, a novel RNA-binding protein from trypanosomatid mitochondria, modulates RNA stability.
  Eukaryot Cell, 2, 560-568.  
12691533 T.Hamma, and P.S.Miller (2003).
Interactions of hairpin oligo-2'-O-methylribonucleotides containing methylphosphonate linkages with HIV TAR RNA.
  Antisense Nucleic Acid Drug Dev, 13, 19-30.  
12595698 V.Kacer, S.A.Scaringe, J.N.Scarsdale, and J.P.Rife (2003).
Crystal structures of r(GGUCACAGCCC)2.
  Acta Crystallogr D Biol Crystallogr, 59, 423-432.
PDB codes: 1kd3 1kd4 1kd5
12136136 E.Ennifar, P.Carpentier, J.L.Ferrer, P.Walter, and P.Dumas (2002).
X-ray-induced debromination of nucleic acids at the Br K absorption edge and implications for MAD phasing.
  Acta Crystallogr D Biol Crystallogr, 58, 1262-1268.  
12526808 F.Li, Y.Xiong, J.Wang, H.D.Cho, K.Tomita, A.M.Weiner, and T.A.Steitz (2002).
Crystal structures of the Bacillus stearothermophilus CCA-adding enzyme and its complexes with ATP or CTP.
  Cell, 111, 815-824.
PDB codes: 1miv 1miw 1miy
12364603 M.Olejniczak, Z.Gdaniec, A.Fischer, T.Grabarkiewicz, L.Bielecki, and R.W.Adamiak (2002).
The bulge region of HIV-1 TAR RNA binds metal ions in solution.
  Nucleic Acids Res, 30, 4241-4249.  
12079781 T.E.Edwards, T.M.Okonogi, and S.T.Sigurdsson (2002).
Investigation of RNA-protein and RNA-metal ion interactions by electron paramagnetic resonance spectroscopy. The HIV TAR-Tat motif.
  Chem Biol, 9, 699-706.  
12079782 Z.Du, K.E.Lind, and T.L.James (2002).
Structure of TAR RNA complexed with a Tat-TAR interaction nanomolar inhibitor that was identified by computational screening.
  Chem Biol, 9, 707-712.
PDB code: 1lvj
11410668 H.Huthoff, and B.Berkhout (2001).
Mutations in the TAR hairpin affect the equilibrium between alternative conformations of the HIV-1 leader RNA.
  Nucleic Acids Res, 29, 2594-2600.  
11222771 V.Tereshko, C.J.Wilds, G.Minasov, T.P.Prakash, M.A.Maier, A.Howard, Z.Wawrzak, M.Manoharan, and M.Egli (2001).
Detection of alkali metal ions in DNA crystals using state-of-the-art X-ray diffraction experiments.
  Nucleic Acids Res, 29, 1208-1215.
PDB codes: 1i0f 1i0g 1i0j 1i0k 1i0m 1i0n 1i0o 1i0p 1i0q 1i0t
10715103 A.Litovchick, A.G.Evdokimov, and A.Lapidot (2000).
Aminoglycoside-arginine conjugates that bind TAR RNA: synthesis, characterization, and antiviral activity.
  Biochemistry, 39, 2838-2852.  
10903943 D.Sussman, and C.Wilson (2000).
A water channel in the core of the vitamin B(12) RNA aptamer.
  Structure, 8, 719-727.
PDB code: 1et4
10745012 E.Westhof, and V.Fritsch (2000).
RNA folding: beyond Watson-Crick pairs.
  Structure, 8, R55-R65.  
10917595 M.A.Rubio, X.Liu, H.Yuzawa, J.D.Alfonzo, and L.Simpson (2000).
Selective importation of RNA into isolated mitochondria from Leishmania tarentolae.
  RNA, 6, 988.  
11121486 R.Nifosì, C.M.Reyes, and P.A.Kollman (2000).
Molecular dynamics studies of the HIV-1 TAR and its complex with argininamide.
  Nucleic Acids Res, 28, 4944-4955.  
10745015 T.Hermann, and D.J.Patel (2000).
RNA bulges as architectural and recognition motifs.
  Structure, 8, R47-R54.  
10648795 Y.Ben-Asouli, Y.Banai, H.Hauser, and R.Kaempfer (2000).
Recognition of 5'-terminal TAR structure in human immunodeficiency virus-1 mRNA by eukaryotic translation initiation factor 2.
  Nucleic Acids Res, 28, 1011-1018.  
10999608 Y.Xiong, and M.Sundaralingam (2000).
Two crystal forms of helix II of Xenopus laevis 5S rRNA with a cytosine bulge.
  RNA, 6, 1316-1324.
PDB codes: 1dqf 1dqh
10410795 A.R.Ferré-D'Amaré, and J.A.Doudna (1999).
RNA folds: insights from recent crystal structures.
  Annu Rev Biophys Biomol Struct, 28, 57-73.  
10095059 B.I.Klasens, H.T.Huthoff, A.T.Das, R.E.Jeeninga, and B.Berkhout (1999).
The effect of template RNA structure on elongation by HIV-1 reverse transcriptase.
  Biochim Biophys Acta, 1444, 355-370.  
10047585 D.J.Patel (1999).
Adaptive recognition in RNA complexes with peptides and protein modules.
  Curr Opin Struct Biol, 9, 74-87.  
10625466 J.Zhu, and R.M.Wartell (1999).
The effect of base sequence on the stability of RNA and DNA single base bulges.
  Biochemistry, 38, 15986-15993.  
10555960 P.S.Klosterman, S.A.Shah, and T.A.Steitz (1999).
Crystal structures of two plasmid copy control related RNA duplexes: An 18 base pair duplex at 1.20 A resolution and a 19 base pair duplex at 1.55 A resolution.
  Biochemistry, 38, 14784-14792.
PDB codes: 1qc0 1qcu
10563819 T.Hamma, and P.S.Miller (1999).
Syntheses of alternating oligo-2'-O-methylribonucleoside methylphosphonates and their interactions with HIV TAR RNA.
  Biochemistry, 38, 15333-15342.  
  10364292 Y.Ramanathan, S.M.Reza, T.M.Young, M.B.Mathews, and T.Pe'ery (1999).
Human and rodent transcription elongation factor P-TEFb: interactions with human immunodeficiency virus type 1 tat and carboxy-terminal domain substrate.
  J Virol, 73, 5448-5458.  
10333740 D.J.Patel (1998).
Molecular insights into the RNA world.
  Biopolymers, 48, 97.  
11180044 D.M.Lilley (1998).
Folding of branched RNA species.
  Biopolymers, 48, 101-112.  
10333744 M.A.Weiss, and N.Narayana (1998).
RNA recognition by arginine-rich peptide motifs.
  Biopolymers, 48, 167-180.  
The most recent references are shown first. Citation data come partly from CiteXplore and partly from an automated harvesting procedure. Note that this is likely to be only a partial list as not all journals are covered by either method. However, we are continually building up the citation data so more and more references will be included with time. Where a reference describes a PDB structure, the PDB codes are shown on the right.

 

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