Gene/Protein
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Enzyme
Compound
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Gene/Protein
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Target Concepts:
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Query: EC:3.1.27.3 (
RNase T1
)
1,228
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The conformation dependence of protein spectra recorded by electrospray ionization mass spectrometry (ESI-MS) is an interesting and useful phenomenon, whose origin is still the object of debate. Different mechanisms have been invoked in the attempt to explain the lower charge state of folded versus unfolded protein ions in
ESI
-MS, such as electrostatic repulsions, solvent accessibility, charge availability, and native-like interactions. In this work we try to subject to direct experimental test the hypothesis that conformation-dependent neutralization of charges with polarity opposite to the net charge of the protein ion could play a critical role in such an effect. We present results of time-of-flight nano-
ESI
-MS on the peptide angiotensin II, indicating that negative charges of carboxylate groups can contribute to spectra recorded in positive-ion mode when stabilized by favorable electrostatic interactions, which is the central assumption of our hypothesis. Comparison of horse and spermwhale myoglobin (Mb) shows that changing the total number of basic residues within a given three-dimensional structure shifts the charge-state distribution (CSD) of the folded protein in positive-ion mode. This result appears to be in contrast to models in which electrostatic repulsions or availability of charges in the
ESI
droplets represent the limiting factor for the ionization of folded protein ions in
ESI
-MS. At the same time, it suggests a role of acidic residues in conformational effects in positive-ion mode. Furthermore, an attempt is made to rationalize those cases in which, in contrast, the main charge state observed in
ESI
-MS under non-denaturing conditions deviates considerably from the net charge expected on the basis of the amino-acid composition. These cases usually correspond to proteins with quite balanced content in basic and acidic residues, suggesting that this might be a factor influencing their charging behavior in
ESI
-MS. Experiments on mutants of ribonuclease Sa (
RNase Sa
) reveal that progressively reducing the excess of acidic residues, replacing them by lysine, causes almost no shift in the spectrum of the folded protein in negative-ion mode. Analogously, variants with an excess of three or five basic residues give similar spectra in positive-ion mode. These results indicate a lower limit to the extent of ionization observable by
ESI
-MS (6- or 8+ in the case of
RNase Sa
in water). Below such limit of net charge, changes in the relative amount of ionizable side chains do not affect the qualitative features of the observed CSDs. A progressive loss of signal intensity caused by the mutations in negative-ion mode suggests that low charge states might also be counterselected, even within the m/z range theoretically accessible to the instrument.
...
PMID:Role of opposite charges in protein electrospray ionization mass spectrometry. 1450 21
The characterization of water molecules bound to
ribonuclease T1
(
RNase T1
) was carried out using cold-spray ionization mass spectrometry (CSI-MS). CSI-MS is a variant of electrospray ionization mass spectrometry (ESI-MS) operating at low temperature, and is particularly suitable for investigating the weaker molecular associations, since the temperature at the spray interface is much lower than that in the conventional
ESI
-MS. In this approach, ion peaks due to the addition of nine water molecules were identified at a spray temperature of 48 degrees C. This result showed good agreement with that inferred by the combinational analysis of NMR and X-ray crystallography, indicating that CSI-MS is capable of rapidly providing reliable information to characterize the number of water molecules bound to a macromolecule.
...
PMID:Observation of water molecules bound to a protein using cold-spray ionization mass spectrometry. 1584 45
Pseudouridine, an isomer of uridine, is probably the most common of many posttranscriptional RNA modifications found in nature. Although mass spectrometry has become widely used in the characterization of modified nucleic acids, its application to the recognition and sequence placement of pseudouridine has not been straightforward, particularly in the case of complex mixtures such as those resulting from selective enzymatic hydrolysis of RNA into oligonucleotides. We report results of a study of the characteristic dissociation reactions of pseudouridine-containing oligonucleotides following ionization by electrospray and use of those pathways in an LC/MS-based method applicable to direct analysis of RNase digests of RNA. As a consequence of the C-C (rather than C-N) glycosidic bond of pseudouridine, the otherwise common dissociation paths involving base loss do not occur, resulting in characteristic formation of a set of low-mass negative ions containing the intact glycosidic bond (m/z 225, 207, 189, 165, 164, 139), which permit recognition of pseudouridine-containing oligonucleotides. Those components can subsequently be subjected to sequence analysis by MS/MS, in which enhancement of selective sequence-determining ions (a-, w-, y-types), and absence of a - base ions, are observed at the site of pseudouridylation. Also, selected reaction pathways can be monitored in the LC/MS/MS analysis that are indicative of pseudouridine at the 5' terminus (m/z 225 --> 165), internal positions (m/z 207 --> 164), and in the
RNase T1
-derived product Psi pGp (m/z 668 --> 207) arising from the RNA sequence ...G Psi G... These procedures can be effectively integrated into an existing suite of LC/
ESI
-MS-based methods designed for the analysis of posttranscriptionally modified sites in RNA.
...
PMID:Detection of the common RNA nucleoside pseudouridine in mixtures of oligonucleotides by mass spectrometry. 1605 77
