Assignment of NH resonances in nucleic acids using natural abundance <sup>15</sup>N‐<sup>1</sup>H correlation spectroscopy with spin‐echo and gradient pulses

Szewczak, Alexander A.; Kellogg, Gregory W.; Moore, Peter B.

doi:10.1016/0014-5793(93)81000-p

Cited by 48 publications

(45 citation statements)

References 22 publications

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“…The TOCSY (Griesinger et al+, 1988) spectrum in D 2 O was acquired at 600 MHz and 35 8C with 2,048 data points in the t2 dimension and 512 t1 increments+ The spectral width was 6,000 Hz in both dimensions+ A homonuclear proton spin lock with a MLEV-17 pulse sequence (Bax & Davis, 1985) was applied during a mixing time of 40 ms+ A 1 H-15 N HMQC experiment (Szewczak et al+, 1993) was carried out at 800 MHz and 15 8C with 128 t1 increments and 1,024 data points per increment+ The spectral widths were 6,000 Hz in the 1 H dimension and 2,000 Hz in the 15 N dimension+ The solvent signal suppression was realized as in the NOESY experiment+ An HNCO experiment (Kay et al+, 1990) was carried out at 600 MHz and 15 8C in a two-dimensional version with 1 H and 13 C dimensions+ We acquired 1,024 data points for 256 increments in the 13 C dimension and 384 scans per increment+ The high rate of exchange of imino protons with water makes this experiment less sensitive for nucleic acids than for proteins+ To avoid saturation of the exchangeable protons of tRNA, water suppression was achieved using flip-back pulses (Grzesiek & Bax, 1993)+ The spectral widths were 6,000 Hz in the 1 H dimension and 7,545 Hz in the 13 C dimension+ The 1 H carrier frequency was set in the middle of the region of the exchangeable proton resonances+ Protons were decoupled from 15 N during acquisition using the GARP sequence (Shaka et al+, 1985)+…”

Section: Nmr Spectroscopymentioning

confidence: 99%

NMR and biochemical characterization of recombinant human tRNA3 Lys expressed in Escherichia coli: Identification of posttranscriptional nucleotide modifications required for efficient initiation of HIV-1 reverse transcription

Tisné

Rigourd

Marquet

et al. 2000

RNA

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Reverse transcription of HIV-1 viral RNA uses human tRNA 3 Lys as a primer. Some of the modified nucleotides carried by this tRNA must play a key role in the initiation of this process, because unmodified tRNA produced in vitro is only marginally active as primer. To provide a better understanding of the contribution of base modifications in the initiation complex, we have designed a recombinant system that allows tRNA 3 Lys expression in Escherichia coli. Because of their high level of overexpression, some modifications are incorporated at substoichiometric levels. We have purified the two major recombinant tRNA 3Lys subspecies, and their modified nucleotide contents have been characterized by a combination of NMR and biochemical techniques. Both species carry Cs, Ds, T, t 6 A, and m 7 G. Differences are observed at position 34, within the anticodon. One fraction lacks the 5-methylaminomethyl group, whereas the other lacks the 2-thio group. Although the s 2 U 34 -containing recombinant tRNA is a less efficient primer, it presents most of the characteristics of the mammalian tRNA. On the other hand, the mnm 5 U 34 -containing tRNA has a strongly reduced activity. Our results demonstrate that the modifications that are absent in E. coli (m 2 G 10 , C 27 , m 5 C 48 , m 5 C 49 , and m 1 A 58 ) as well as the mnm 5 group at position 34 are dispensable for initiation of reverse transcription. In contrast, the 2-thio group at position 34 seems to play an important part in this process.

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Section: Nmr Spectroscopymentioning

confidence: 99%

NMR and biochemical characterization of recombinant human tRNA3 Lys expressed in Escherichia coli: Identification of posttranscriptional nucleotide modifications required for efficient initiation of HIV-1 reverse transcription

Tisné

Rigourd

Marquet

et al. 2000

RNA

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“…Exchange of amide protons with the solvent was monitored by recording at 303 K a series of IH-"N HMQC spectra (Szewczak et al, 1993) over a period of 90 h. A sample of lSN-labelled angiogenin was freezedried and resuspended in the same volume of 100% *H,O. The first HMQC spectrum was started within 30 min after dissolving the protein in the deuterated solvent.…”

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confidence: 99%

Three‐Dimensional Solution Structure of Human Angiogenin Determined by ¹H,¹⁵N‐NMR Spectroscopy — Characterisation of Histidine Protonation States and Pk_a Values

Lequin

Thüring

Robin³

et al. 1997

European Journal of Biochemistry

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Human angiogenin is a member of the pancreatic ribonuclease superfamily that induces blood vessel foimation. Its three-dimensional solution structure has been determined to high resolution by heteronuclear NMR spectroscopy. 30 structures were calculated, based on a total of 1441 assigned NOE correlations, 64 coupling constants and 50 hydrogen bonds. The backbone atomic rms difference from the mean coordinates is 0.067 ? 0.012 nm and 0.13 nm from the previously determined crystal structure. The sidechain of Gln117 was found to obstruct the active site as observed in the crystal state. There was no evidence of an alternative open form of angiogenin, although two sets of chemical shifts were observed for some residues, mainly around the active site and in the C-terminal segment. The topology of the ribonucleolytic active site is described with a particular emphasis on the conformation and protonation of active-site His residues. The side-chain of His114 adopts two main conformations in solution. In contrast to pancreatic ribonuclease A, His13 was shown to be more basic than Hisl14, with pK, values of 6.65 and 6.05 respectively. The His47 residue is located in an environment very resistant to protonation with a pK, lower than 4.

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“…The 2D NOESY spectra in H20 were obtained in the pure absorption mode (21) using a standard pulse sequence (22), except that the last 900 pulse was replaced with a gradient-enhanced jump-return spin-echo sequence for water suppression (19,20). The 2D {15N}1H heteronuclear multiple quantum correlation (HMQC) was collected for imino protons using a gradient-enhanced jump-return spinecho pulse sequence (23).…”

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confidence: 99%

Determining RNA solution structure by segmental isotopic labeling and NMR: application to Caenorhabditis elegans spliced leader RNA 1.

Lapham

Crothers

1996

Proc. Natl. Acad. Sci. U.S.A.

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Recent developments in multidimensional heteronuclear NMR spectroscopy and large-scale synthesis of uniformly 13C-and 15N-labeled oligonucleotides have greatly improved the prospects for determination of the solution structure of RNA. However, there are circumstances in which it may be advantageous to label only a segment of the entire RNA chain. For example, in a larger RNA molecule the structural question of interest may reside in a localized domain. Labeling only the corresponding nucleotides simplifies the spectrum and resonance assignments because one can filter proton spectra for coupling to 13C and '5N. Another example is in resolving alternative secondary structure models that are indistinguishable in imino proton connectivities. Here we report a general method for enzymatic synthesis of quantities of segmentally labeled RNA molecules required for NMR spectroscopy. We use the method to distinguish definitively two competing secondary structure models for the 5' half of Caenorhabditis elegans spliced leader RNA by compar- However, when dealing with RNAs larger than -35 nucleotides, the limitations of uniform labeling become apparent because of two fundamental problems. The first is associated with the twin difficulties of extensive spectral overlap due to the larger number of resonance and poorer intrinsic spectral resolution because of the increasing rotational correlation time. Many spectral editing techniques have been developed to simplify the spectra further (5).The second problem, which will be the focus of this paper, reflects the increased diversity of secondary structures that are accessible to longer and more complicated RNAs (6). ForThe publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.short oligonucleotides, such diversity is very limited and usually there is only one plausible secondary structure. For large oligonucleotides, however, there may be several possible secondary structures for one defined sequence. The problems caused by this diversity can be subdivided into two classes. First, multiple conformations of the RNA may exist, complicating the spectra and making their interpretation difficult. Therefore, for NMR studies, every effort is made in sample preparation to ensure that only one major conformation exists under the conditions studied. In the second class, only one major conformation exists but it may be difficult to define the correct secondary structure based on the exchangeable proton spectra. The difficulties in this second case arise from two independent sources-namely, spectral overlap, which is frequently encountered, and imino pathway degeneracy, which refers to the situation in which two distinct secondary structures have indistinguishable imino proton connectivities. If a defined sequence has two secondary structures that are degenerate in their imino pathway, there is no way to distinguish them based on a conv...

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Assignment of NH resonances in nucleic acids using natural abundance ¹⁵N‐¹H correlation spectroscopy with spin‐echo and gradient pulses

Cited by 48 publications

References 22 publications

NMR and biochemical characterization of recombinant human tRNA3 Lys expressed in Escherichia coli: Identification of posttranscriptional nucleotide modifications required for efficient initiation of HIV-1 reverse transcription

NMR and biochemical characterization of recombinant human tRNA3 Lys expressed in Escherichia coli: Identification of posttranscriptional nucleotide modifications required for efficient initiation of HIV-1 reverse transcription

Three‐Dimensional Solution Structure of Human Angiogenin Determined by ¹H,¹⁵N‐NMR Spectroscopy — Characterisation of Histidine Protonation States and Pk_a Values

Determining RNA solution structure by segmental isotopic labeling and NMR: application to Caenorhabditis elegans spliced leader RNA 1.

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Assignment of NH resonances in nucleic acids using natural abundance 15N‐1H correlation spectroscopy with spin‐echo and gradient pulses

Cited by 48 publications

References 22 publications

NMR and biochemical characterization of recombinant human tRNA3 Lys expressed in Escherichia coli: Identification of posttranscriptional nucleotide modifications required for efficient initiation of HIV-1 reverse transcription

NMR and biochemical characterization of recombinant human tRNA3 Lys expressed in Escherichia coli: Identification of posttranscriptional nucleotide modifications required for efficient initiation of HIV-1 reverse transcription

Three‐Dimensional Solution Structure of Human Angiogenin Determined by 1H,15N‐NMR Spectroscopy — Characterisation of Histidine Protonation States and Pka Values

Determining RNA solution structure by segmental isotopic labeling and NMR: application to Caenorhabditis elegans spliced leader RNA 1.

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Assignment of NH resonances in nucleic acids using natural abundance ¹⁵N‐¹H correlation spectroscopy with spin‐echo and gradient pulses

Three‐Dimensional Solution Structure of Human Angiogenin Determined by ¹H,¹⁵N‐NMR Spectroscopy — Characterisation of Histidine Protonation States and Pk_a Values