Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

We report the 1.7 A resolution structure of RNase Sa complexed with the polypeptide inhibitor barstar. The crystals are in the hexagonal space group P65 with unit-cell dimensions a = b = 56.9, c = 135.8 A and the asymmetric unit contains one molecule of the complex. RNase Sa is an extracellular microbial ribonuclease produced by Streptomyces aureofaciens. Barstar is the natural inhibitor of barnase, the ribonuclease of Bacillus amyloliquefaciens. It inhibits RNase Sa and barnase in a similar manner by steric blocking of the active site. The structure of RNase Sa is very similar to that observed in crystals of the native enzyme and its complexes with nucleotides. Barstar retains the structure found in its complex with barnase. The accessible surface area of protein buried in the complex is about 300 A2 smaller and there are fewer hydrogen bonds in the enzyme-inhibitor interface in RNase Sa-barstar than in barnase-barstar, providing an explanation of the reduced binding affinity in the former. Previous studies of barstar complexes have used mutants of the inhibitor and this is the first structure which includes wild-type barstar.
Acta Crystallogr D Biol Crystallogr 1998 Sep 01
PMID:Recognition of RNase Sa by the inhibitor barstar: structure of the complex at 1.7 A resolution. 975 10

Chimeric enzymes were constructed to elucidate the differences in physicochemical properties of two related bacterial RNases, barnase and binase. Chimeras (Ba26Bi, Ba73Bi, Ba26Bi73Ba and Bi73Ba) contain six to thirteen residue substitutions relative to barnase, which are beyond the active site. The catalytic activity of RNases toward GpU, GpC and poly(I), as well as conformational distinctions and heat denaturation parameters, were studied. Thermal denaturation of binase, barnase and chimeric RNases is a two-state transition. The mutation-induced changes in the free energy of unfolding of barnase deduced from thermal and urea denaturation nearly coincide. The kinetic parameters for GpU and GpC demonstrate that the chimeras fall into two groups: barnase-like and binase-like. This division is determined by the origin of their C-terminal part (residues 73-110) which is also responsible for their thermostability at pH 2.4. An inverse linear dependence was found between kcat for poly(I) and denaturation temperature of RNases at pH 5.5, which points out that certain lability of the protein molecule appears to be necessary for efficient polynucleotide cleavage.
Protein Eng 1998 Sep
PMID:Comparative study of binase and barnase: experience in chimeric ribonucleases. 979 26

Post-transcriptional methylation of ribose at position O-2' is one of the most common and conserved types of RNA modification. Details of the functional roles of these methylations are far from clear, although in tRNA they are involved at position 34 in regulation of codon recognition and in eukaryotic rRNAs they are required for subunit assembly. Experimental difficulties in the mapping of ribose methylations increase with RNA molecular size and the complexity of mixtures resulting from nuclease digestion. A new and relatively rapid approach based on tandem mass spectrometry is described in which any of four ion reaction pathways occurring in the mass spectrometer can be monitored which are highly specific for the presence of 2'-O -methylribose residues. These pathways emanate from further dissociation of ribose-methylated mononucleotide (Nmp) ions formed in the electrospray ionization region of the mass spectrometer to then form the base, methylribose phosphate or PO(3)(-)anions. The mass spectrometer can be set for detection of generic ribose methylation (Nm) in oligonucleotides, selectively for each of the common methylated nucleo-sides Cm, Gm, Am or Um or for specific cases in which the base or sugar is further modified. By direct combination of mass spectrometry with liquid chromatography the method can be applied to analysis of complex mixtures of oligonucleotides, as for instance from synthetic or in vitro reaction mixtures or from nuclease digests of RNA. An example is given in which the single ribose-methylated nucleoside in Escherichia coli 16S rRNA (1542 nt), N(4),O-2'-dimethylcytidine, is detected in 25 pmol of a RNase T1 digest and localized to the fragment 1402-CCCGp-1405 in a single 45 min analysis.
Nucleic Acids Res 1999 Sep 15
PMID:Selective detection of ribose-methylated nucleotides in RNA by a mass spectrometry-based method. 1047 50

It is difficult to increase protein stability by adding hydrogen bonds or burying nonpolar surface. The results described here show that reversing the charge on a side chain on the surface of a protein is a useful way of increasing stability. Ribonuclease T1 is an acidic protein with a pI approximately 3.5 and a net charge of approximately -6 at pH 7. The side chain of Asp49 is hyperexposed, not hydrogen bonded, and 8 A from the nearest charged group. The stability of Asp49Ala is 0.5 kcal/mol greater than wild-type at pH 7 and 0.4 kcal/mol less at pH 2.5. The stability of Asp49His is 1.1 kcal/mol greater than wild-type at pH 6, where the histidine 49 side chain (pKa = 7.2) is positively charged. Similar results were obtained with ribonuclease Sa where Asp25Lys is 0.9 kcal/mol and Glu74Lys is 1.1 kcal/mol more stable than the wild-type enzyme. These results suggest that protein stability can be increased by improving the coulombic interactions among charged groups on the protein surface. In addition, the stability of RNase T1 decreases as more hydrophobic aromatic residues are substituted for Ala49, indicating a reverse hydrophobic effect.
Protein Sci 1999 Sep
PMID:Increasing protein stability by altering long-range coulombic interactions. 1049 85

Oxygen quenching of protein phosphorescence and activation enthalpies for the structural fluctuations underlying O2 and acrylamide diffusion were determined for RNase T1, glyceraldehyde-3-phosphate dehydrogenase and beta-lactoglobulin, which have the phosphorescing residues located in relatively solvent-exposed and flexible regions of the polypeptide. The results, compared with those obtained for proteins characterised by a very rigid environment, established that kqO2 was directly correlated to the flexibility of the protein matrix surrounding the chromophore. While the migration of acrylamide was characterised by delta H(double dagger), which was strongly dependent on the fluidity of the structure about the Trp residue, the values of the activation enthalpies for the oxygen migration of all the proteins studied were rather similar, approximately 10 kcal mol(-1), in spite of the depth of the chromophore and the rigidity of its environment. The implications of these findings for the migration of small solutes inside proteins have been discussed.
Biophys Chem 2000 Sep 15
PMID:Oxygen and acrylamide quenching of protein phosphorescence: correlation with protein dynamics. 1103 66

Constant-time 3D heteronuclear relayed E.COSY [Schmidt et al. (1996) J. Biomol. NMR, 7, 142-152], as based on generic 2D small-flip-angle HMQC-COSY [Schmidt et al. (1995) J. Biomol. NMR, 6, 95-105], has been modified to allow for quantitative determination of heteronuclear three-bond 3J(H(alpha),C(gamma)) couplings. The method is applicable to amino acid spin topologies with carbons in the gamma position which lack attached protons, i.e. to asparagine, aspartate, and aromatic residues in uniformly 13C-enriched proteins. The pulse sequence critically exploits heteronuclear triple-quantum coherence (HTQC) of CH2 moieties involving geminal H(beta) proton pairs, taking advantage of improved multiple-quantum relaxation properties, at the same time avoiding scalar couplings between those spins involved in multiple-quantum coherence, thus yielding E.COSY-type multiplets with a splitting structure that is simpler than with the original scheme. Numerical least-squares 2D line-shape simulation is used to extract 3J(H(alpha),C(gamma)) coupling constants which are of relevance to side-chain chi1 dihedral-angle conformations in polypeptides. Methods are demonstrated with recombinant 15N,13C-enriched ribonuclease T1 and Desulfovibrio vulgaris flavodoxin with bound oxidized FMN.
J Biomol NMR 2000 Sep
PMID:Heteronuclear relayed E.COSY revisited: determination of 3J(H(alpha),C(gamma)) couplings in Asx and aromatic residues in proteins. 1106 Dec 24

Mutation detection based on ribonuclease cleavage of basepair mismatches in single-stranded RNA probes hybridized to DNA targets was first described over 15 years ago. The original methods relied on RNase A for mismatch cleavage; however, this enzyme fails to cleave many mismatches and has other drawbacks. More recently, a new method for RNase-cleavage-based mutation scanning has been developed, which takes advantage of the ability of RNase 1 and RNase T1 to cleave mismatches in duplex RNA targets, when these enzymes are used in conjunction with nucleic acid intercalating dyes. The method, called NIRCA, is relatively low-cost in terms of materials and equipment required. It is being used to detect mutations and SNPs in a wide variety of genes involved in human genetic disease and cancer, as well as in disease-related viral and bacterial genes. This review describes historical and recently developed RNase cleavage-based methods for mutation/SNP scanning.
Hum Mutat 2001 Sep
PMID:RNase cleavage-based methods for mutation/SNP detection, past and present. 1152 30

The aim of this study was to gain a better understanding of the contribution of hydrogen bonds by tyrosine -OH groups to protein stability. The amino acid sequences of RNases Sa and Sa3 are 69 % identical and each contains eight Tyr residues with seven at equivalent structural positions. We have measured the stability of the 16 tyrosine to phenylalanine mutants. For two equivalent mutants, the stability increases by 0.3 kcal/mol (RNase Sa Y30F) and 0.5 kcal/mol (RNase Sa3 Y33F) (1 kcal=4.184 kJ). For all of the other mutants, the stability decreases with the greatest decrease being 3.6 kcal/mol for RNase Sa Y52F. Seven of the 16 tyrosine residues form intramolecular hydrogen bonds and the average decrease in stability for these is 2.0(+/-1.0) kcal/mol. For the nine tyrosine residues that do not form intramolecular hydrogen bonds, the average decrease in stability is 0.4(+/-0.6) kcal/mol. Thus, most tyrosine -OH groups contribute favorably to protein stability even if they do not form intramolecular hydrogen bonds. Generally, the stability changes for equivalent positions in the two proteins are remarkably similar. Crystal structures were determined for two of the tyrosine to phenylalanine mutants of RNase Sa: Y80F (1.2 A), and Y86F (1.7 A). The structures are very similar to that of wild-type RNase Sa, and the hydrogen bonding partners of the tyrosine residues always form intermolecular hydrogen bonds to water in the mutants. These results provide further evidence that the hydrogen bonding and van der Waals interactions of polar groups in the tightly packed interior of folded proteins are more favorable than similar interactions with water in the unfolded protein, and that polar group burial makes a substantial contribution to protein stability.
J Mol Biol 2001 Sep 14
PMID:Tyrosine hydrogen bonds make a large contribution to protein stability. 1155 95

Differential scanning calorimetry was used to study the thermodynamics of denaturation of protein complexes for which the free energy stabilizing the complexes varied between -8 and -16 kcal/mol. The proteins studied were the ribonucleases barnase and binase, their inhibitor barstar and mutants thereof, and complexes between the two. The results are in good agreement with the model developed by Brandts and Lin for studying the thermodynamics of denaturation for tight complexes between two proteins which undergo two-state thermal unfolding transitions.
Biophys Chem 2003 Sep
PMID:Thermodynamics of denaturation of complexes of barnase and binase with barstar. 1449 6

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.
J Mass Spectrom 2003 Sep
PMID:Role of opposite charges in protein electrospray ionization mass spectrometry. 1450 21


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