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PDBsum entry 2adt
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RNA PDB id
2adt

 

 

 

 

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Contents
DNA/RNA
PDB id:
2adt
Name: RNA
Title: Nmr structure of a 30 kda gaaa tetraloop-receptor complex.
Structure: 43-mer. Chain: a, b. Engineered: yes. Other_details: gaaa tetraloop-receptor RNA
Source: Synthetic: yes
NMR struc: 20 models
Authors: J.H.Davis,M.Tonelli,L.G.Scott,L.Jaeger,J.R.Williamson,S.E.Butcher
Key ref:
J.H.Davis et al. (2005). RNA helical packing in solution: NMR structure of a 30 kDa GAAA tetraloop-receptor complex. J Mol Biol, 351, 371-382. PubMed id: 16002091 DOI: 10.1016/j.jmb.2005.05.069
Date:
20-Jul-05     Release date:   26-Jul-05    
 Headers
 References

DNA/RNA chains
  G-G-G-A-U-A-U-G-G-A-A-G-A-A-C-C-G-G-G-G-A-A-A-C-U-U-G-G-U-U-C-U-U-C-C-U-A-A-G- 43 bases
  G-G-G-A-U-A-U-G-G-A-A-G-A-A-C-C-G-G-G-G-A-A-A-C-U-U-G-G-U-U-C-U-U-C-C-U-A-A-G- 43 bases

 

 
DOI no: 10.1016/j.jmb.2005.05.069 J Mol Biol 351:371-382 (2005)
PubMed id: 16002091  
 
 
RNA helical packing in solution: NMR structure of a 30 kDa GAAA tetraloop-receptor complex.
J.H.Davis, M.Tonelli, L.G.Scott, L.Jaeger, J.R.Williamson, S.E.Butcher.
 
  ABSTRACT  
 
Tertiary interactions are critical for proper RNA folding and ribozyme catalysis. RNA tertiary structure is often condensed through long-range helical packing interactions mediated by loop-receptor motifs. RNA structures displaying helical packing by loop-receptor interactions have been solved by X-ray crystallography, but not by NMR. Here, we report the NMR structure of a 30 kDa GAAA tetraloop-receptor RNA complex. In order to stabilize the complex, we used a modular design in which the RNA was engineered to form a homodimer, with each subunit containing a GAAA tetraloop phased one helical turn apart from its cognate 11-nucleotide receptor domain. The structure determination utilized specific isotopic labeling patterns (2H, 13C and 15N) and refinement against residual dipolar couplings. We observe a unique and highly unusual chemical shift pattern for an adenosine platform interaction that reveals a spectroscopic fingerprint for this motif. The structure of the GAAA tetraloop-receptor interaction is well defined solely from experimental NMR data, shows minor deviations from previously solved crystal structures, and verifies the previously inferred hydrogen bonding patterns within this motif. This work demonstrates the feasibility of using engineered homodimers as modular systems for the determination of RNA tertiary interactions by NMR.
 
  Selected figure(s)  
 
Figure 8.
Figure 8. Structure of the GAAA tetraloop-receptor RNA. The ensemble of the 20 lowest energy structures with one half of the homodimer in red/gold and the other in blue/cyan. 		Figure 9.
Figure 9. Comparison of the NMR structure and crystal structure. (a) The ensemble of the 20 lowest energy NMR structures is shown in color, superimposed with the crystal structure (shown in gray). (b) and (c) Base-pairing interactions between the tetraloop and receptor. Hydrogen bonds are indicated with broken lines. Residues from the tetraloop are shown in orange and residues from the receptor are shown in cyan. The crystal structure is in white. G8 is in a Watson-Crick pair with C35 and forms a base quadruplet with A23 and G20 from the tetraloop. A6 is in a reverse-Hoogsteen pair with U36, and forms a triplet with A21 from the tetraloop.
 
  The above figures are reprinted by permission from Elsevier: J Mol Biol (2005, 351, 371-382) copyright 2005.  
  Figures were selected by an automated process.  

Literature references that cite this PDB file's key reference

  PubMed id Reference
20876687 C.Geary, A.Chworos, and L.Jaeger (2011).
Promoting RNA helical stacking via A-minor junctions.
  Nucleic Acids Res, 39, 1066-1080.  
20549304 B.S.Tolbert, Y.Miyazaki, S.Barton, B.Kinde, P.Starck, R.Singh, A.Bax, D.A.Case, and M.F.Summers (2010).
Major groove width variations in RNA structures determined by NMR and impact of 13C residual chemical shift anisotropy and 1H-13C residual dipolar coupling on refinement.
  J Biomol NMR, 47, 205-219.
PDB code: 2kyd
19789981 K.Lu, Y.Miyazaki, and M.F.Summers (2010).
Isotope labeling strategies for NMR studies of RNA.
  J Biomol NMR, 46, 113-125.  
20651028 S.C.Flores, and R.B.Altman (2010).
Turning limited experimental information into 3D models of RNA.
  RNA, 16, 1769-1778.  
19427322 D.Lambert, D.Leipply, R.Shiman, and D.E.Draper (2009).
The influence of monovalent cation size on the stability of RNA tertiary structures.
  J Mol Biol, 390, 791-804.  
19742176 I.Agmon (2009).
The dimeric proto-ribosome: structural details and possible implications on the origin of life.
  Int J Mol Sci, 10, 2921-2934.  
19186984 J.L.Fiore, B.Kraemer, F.Koberling, R.Edmann, and D.J.Nesbitt (2009).
Enthalpy-driven RNA folding: single-molecule thermodynamics of tetraloop-receptor tertiary interaction.
  Biochemistry, 48, 2550-2558.  
19036788 L.Jaeger, E.J.Verzemnieks, and C.Geary (2009).
The UA_handle: a versatile submotif in stable RNA architectures.
  Nucleic Acids Res, 37, 215-230.  
19749271 L.Jaeger (2009).
Defining the syntax for self-assembling RNA tertiary architectures.
  Nucleic Acids Symp Ser (Oxf), (), 83-84.  
19067179 M.P.Latham, and A.Pardi (2009).
Measurement of imino (1)H- (1)H residual dipolar couplings in RNA.
  J Biomol NMR, 43, 121-129.  
18158305 C.Geary, S.Baudrey, and L.Jaeger (2008).
Comprehensive features of natural and in vitro selected GNRA tetraloop-binding receptors.
  Nucleic Acids Res, 36, 1138-1152.  
18058789 D.W.Staple, V.Venditti, N.Niccolai, L.Elson-Schwab, Y.Tor, and S.E.Butcher (2008).
Guanidinoneomycin B recognition of an HIV-1 RNA helix.
  Chembiochem, 9, 93.
PDB code: 2juk
  18707057 H.L.Schultheisz, B.R.Szymczyna, L.G.Scott, and J.R.Williamson (2008).
Pathway engineered enzymatic de novo purine nucleotide synthesis.
  ACS Chem Biol, 3, 499-511.  
18845162 K.A.Vander Meulen, J.H.Davis, T.R.Foster, M.T.Record, and S.E.Butcher (2008).
Thermodynamics and folding pathway of tetraloop receptor-mediated RNA helical packing.
  J Mol Biol, 384, 702-717.  
19325801 K.T.Dayie (2008).
Key labeling technologies to tackle sizeable problems in RNA structural biology.
  Int J Mol Sci, 9, 1214-1240.  
18026844 M.P.Latham, P.Hanson, D.J.Brown, and A.Pardi (2008).
Comparison of alignment tensors generated for native tRNA(Val) using magnetic fields and liquid crystalline media.
  J Biomol NMR, 40, 83-94.  
17981525 R.Russell (2008).
RNA misfolding and the action of chaperones.
  Front Biosci, 13, 1.  
18281388 S.Fulle, and H.Gohlke (2008).
Analyzing the flexibility of RNA structures by constraint counting.
  Biophys J, 94, 4202-4219.  
18824128 T.Xia (2008).
Taking femtosecond snapshots of RNA conformational dynamics and complexity.
  Curr Opin Chem Biol, 12, 604-611.  
17119098 J.H.Davis, T.R.Foster, M.Tonelli, and S.E.Butcher (2007).
Role of metal ions in the tetraloop-receptor complex as analyzed by NMR.
  RNA, 13, 76-86.
PDB codes: 2i7e 2i7z
17200997 M.C.Erat, O.Zerbe, T.Fox, and R.K.Sigel (2007).
Solution structure of domain 6 from a self-splicing group II intron ribozyme: a Mg(2+) binding site is located close to the stacked branch adenosine.
  Chembiochem, 8, 306-314.
PDB code: 2aht
17868691 R.J.Marcheschi, D.W.Staple, and S.E.Butcher (2007).
Programmed ribosomal frameshifting in SIV is induced by a highly structured RNA stem-loop.
  J Mol Biol, 373, 652-663.
PDB code: 2jtp
17940098 Z.Zhuang, L.Jaeger, and J.E.Shea (2007).
Probing the structural hierarchy and energy landscape of an RNA T-loop hairpin.
  Nucleic Acids Res, 35, 6995-7002.  
16689639 A.G.Tzakos, C.R.Grace, P.J.Lukavsky, and R.Riek (2006).
NMR techniques for very large proteins and rnas in solution.
  Annu Rev Biophys Biomol Struct, 35, 319-342.  
16718586 B.Wu, M.Petersen, F.Girard, M.Tessari, and S.S.Wijmenga (2006).
Prediction of molecular alignment of nucleic acids in aligned media.
  J Biomol NMR, 35, 103-115.  
16533049 C.D.Downey, J.L.Fiore, C.D.Stoddard, J.H.Hodak, D.J.Nesbitt, and A.Pardi (2006).
Metal ion dependence, thermodynamics, and kinetics for intramolecular docking of a GAAA tetraloop and receptor connected by a flexible linker.
  Biochemistry, 45, 3664-3673.  
16945907 C.S.Badorrek, C.M.Gherghe, and K.M.Weeks (2006).
Structure of an RNA switch that enforces stringent retroviral genomic RNA dimerization.
  Proc Natl Acad Sci U S A, 103, 13640-13645.  
17165766 K.A.Afonin, and N.B.Leontis (2006).
Generating new specific RNA interaction interfaces using C-loops.
  J Am Chem Soc, 128, 16131-16137.  
16843653 L.Jaeger, and A.Chworos (2006).
The architectonics of programmable RNA and DNA nanostructures.
  Curr Opin Struct Biol, 16, 531-543.  
16522648 L.Nasalean, S.Baudrey, N.B.Leontis, and L.Jaeger (2006).
Controlling RNA self-assembly to form filaments.
  Nucleic Acids Res, 34, 1381-1392.  
16894219 O.H.Gumbs, R.A.Padgett, and K.T.Dayie (2006).
Fluorescence and solution NMR study of the active site of a 160-kDa group II intron ribozyme.
  RNA, 12, 1693-1707.  
16430131 P.Guo (2005).
RNA nanotechnology: engineering, assembly and applications in detection, gene delivery and therapy.
  J Nanosci Nanotechnol, 5, 1964-1982.  
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 code is shown on the right.

 

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