Structure of HCV IRES domain II determined by NMR

Lukavsky, Peter J.; Kim, Insil; Otto, Geoff; Puglisi, Joseph D.

doi:10.1038/nsb1004

Cited by 262 publications

(313 citation statements)

References 28 publications

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“…The molecule contains tertiary fold motifs, the IIIabc four-way junction and the IIIef/IV pseudoknot 4,14,15 , and adopts a defined ion-dependent fold under physiological conditions 16 , although it does not form a compact, globular structure 13,16,17 . The structure at atomic resolution has been determined for several autonomous folding regions, including domain II, the III abc junction and, more recently, the III ef /IV pseudoknot [18][19][20][21][22][23][24] . The presence of several hairpin loops and regions predicted to be single-stranded likely confers dynamic flexibility to the entire IRES molecule 13,16,23 and has so far hampered structure determination of the entire molecule by X-ray crystallography or electron microscopy.…”

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confidence: 99%

“…The structure at atomic resolution has been determined for several autonomous folding regions, including domain II, the III abc junction and, more recently, the III ef /IV pseudoknot [18][19][20][21][22][23][24] . The presence of several hairpin loops and regions predicted to be single-stranded likely confers dynamic flexibility to the entire IRES molecule 13,16,23 and has so far hampered structure determination of the entire molecule by X-ray crystallography or electron microscopy. As the IRES is essential for viral replication and its sequence is well conserved among all HCV genotypes, its structure represents a novel target for drug design 25 .…”

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confidence: 99%

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Structure of the full-length HCV IRES in solution

et al. 2013

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The 5 0 -untranslated region of the hepatitis C virus genome contains an internal ribosome entry site (IRES) that initiates cap-independent translation of the viral RNA. Until now, the structural characterization of the entire (IRES) remained limited to cryo-electron microscopy reconstructions of the (IRES) bound to different cellular partners. Here we report an atomic model of free full-length hepatitis C virus (IRES) refined by selection against small-angle X-ray scattering data that incorporates the known structures of different fragments. We found that an ensemble of conformers reproduces small-angle X-ray scattering data better than a single structure suggesting in combination with molecular dynamics simulations that the hepatitis C virus (IRES) is an articulated molecule made of rigid parts that move relative to each other. Principal component analysis on an ensemble of physically accessible conformers of hepatitis C virus (IRES) revealed dominant collective motions in the molecule, which may underlie the conformational changes occurring in the (IRES) molecule upon formation of the initiation complex.

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Structure of the full-length HCV IRES in solution

et al. 2013

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“…RDCs are particularly useful in nucleic acids, where the number of NOE restraints is typically relatively low, especially those involving long-range contacts. The fact that dipolar restraints provide information on internuclear bond vectors relative to a single axis system, that of the alignment tensor, allows for the study of global properties such as helix bending or relative helix orientations in multi-subunit molecules (Tjandra et al, 2000;Vermeulen et al, 2000;Al-Hashimi et al, 2002;Bondensgaard et al, 2002;MacDonald and Lu, 2002;Barbic et al, 2003;Lukavsky et al, 2003;Stefl et al, 2004). However, most applications have relied on a relatively small number of couplings per nucleotide, far fewer than the number of variable torsion angles.…”

Section: Introductionmentioning

confidence: 99%

“…NMR spectroscopy provides the opportunity to study the structure and dynamics of oligonucleotides as large as 30 kD Cabello-Villegas et al, 2002;Lawrence et al, 2003;Leeper et al, 2003;Lukavsky et al, 2003;D'Souza et al, 2004). Traditionally, many of the structural restraints have relied on quantitative interpretation of 1 H-1 H NOEs, supplemented by 3 J HH and 3 J HP couplings.…”

Section: Introductionmentioning

confidence: 99%

Resolution-optimized NMR measurement of 1DCH, 1DCC and 2DCH residual dipolar couplings in nucleic acid bases

et al. 2004

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New methods are described for accurate measurement of multiple residual dipolar couplings in nucleic acid bases. The methods use TROSY-type pulse sequences for optimizing resolution and sensitivity, and rely on the E.COSY principle to measure the relatively small two-bond 2 D CH couplings at high precision. Measurements are demonstrated for a 24-nt stem-loop RNA sequence, uniformly enriched in 13 C, and aligned in Pf1. The recently described pseudo-3D method is used to provide homonuclear 1 H-1 H decoupling, which minimizes cross-correlation effects and optimizes resolution. Up to seven 1 H-13 C and 13 C-13 C couplings are measured for pyrimidines (U and C), including 1 ). Only three dipolar couplings are linearly independent in planar structures such as nucleic acid bases, permitting cross validation of the data and evaluation of their accuracies. For the vast majority of dipolar couplings, the error is found to be less than ±3% of their possible range, indicating that the measurement accuracy is not limiting when using these couplings as restraints in structure calculations. Reported isotropic values of the one-and two-bond J couplings cluster very tightly for each type of nucleotide.

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“…However, paralleling the advances in NMR of larger proteins, isotope labeling strategies have allowed investigation of RNAs whose spectral complexity would have previously been prohibitive. For example, by implementing segmental and residue-specific isotope labeling strategies, the solution structure of domain II of the hepatitis C virus IRES (internal ribosome entry site) RNA was determined using both conventional and RDC restraints ( Figure 10) (17,68). Although the domain adopts an extended structure, inclusion of the orientation information from RDC restraints enabled precise definition of the orientation of the top and bottom of the domain.…”

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Solution NMR of Large Molecules and Assemblies

2006

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Solution NMR spectroscopy represents a powerful tool for examining the structure and function of biological macromolecules. The advent of multidimensional (2D-4D) NMR, together with the widespread use of uniform isotopic labeling of proteins and RNA with the NMR-active isotopes, 15 N and 13 C, opened the door to detailed analyses of macromolecular structure, dynamics and interactions of smaller macromolecules (< ~25 kDa). Over the past 10 years, advances in NMR and isotope labeling methods have expanded the range of NMR-tractable targets by at least an order of magnitude. Here we briefly describe the methodological advances that allow NMR spectroscopy of large macromolecules and their complexes, and provide a perspective on the wide range of applications of NMR to biochemical problems.Solution NMR spectroscopy represents a powerful tool for examining the structure and function of biological macromolecules. The advent of multidimensional (2D-4D) NMR, together with the widespread use of uniform isotopic labeling of proteins and RNA with the NMR-active isotopes, 15 N and 13 C, opened the door to detailed analyses of macromolecular structure, dynamics and interactions of smaller macromolecules (< ~25 kDa). Work on these proteins and nucleic acids has been very fruitful and allowed us to learn much about structurefunction relationships, but is inherently limitied, as the majority of macromolecular complexes of biochemical interest are significantly larger than 25 kDa. Indeed, although much can be learned by examining macromolecules in isolation, mechanistic insights are often only gained upon studying functional higher-order assemblies with partner molecules.NMR studies of large molecules and complexes are complicated by the increased linewidths associated with slower tumbling, and the spectral overlap from the large number of unique signals. Over the past 10 years, advances in NMR and isotope labeling methods have expanded the range of NMR-tractable targets by at least an order of magnitude (for recent reviews, see (1,2)). Here we briefly describe the methodological advances that allow NMR spectroscopy of large macromolecules and their complexes, and provide a perspective on the wide range of applications of NMR to biochemical problems. Overcoming Size Limitations: Narrow Lines and Simple SpectraThe slow tumbling of larger macromolecules in solution leads to faster relaxation of transverse magnetization (short T 2 ) due to enhanced spin-spin interactions. One simple, albeit limited, solution to this problem is to increase the overall molecular tumbling rate by recording NMR spectra at elevated temperatures. This can be highly effective for thermostable macromolecules, with the caveat that behavior at physiological temperatures should be † Authors supported by grants from the National Science Foundation (MCB-0092962) and National Institutes of Health (GM067807) *Contact information: foster.281@osu.edu, 614-292-1377, FAX: 614-292-6773. NIH Public Access [3][4][5][6]. Another ingenious approach to reduce tu...

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Structure of HCV IRES domain II determined by NMR

Cited by 262 publications

References 28 publications

Structure of the full-length HCV IRES in solution

Structure of the full-length HCV IRES in solution

Resolution-optimized NMR measurement of 1DCH, 1DCC and 2DCH residual dipolar couplings in nucleic acid bases

Solution NMR of Large Molecules and Assemblies

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