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 describe the construction and testing of a structural model at the nucleotide level for conformation CH of the central hairpin of genomic RNA from coliphage Q beta. The model was developed with the computer program MFOLD using both optimal and suboptimal predictions. Structural information obtained by electron microscopic analysis of Kleinschmidt spreadings of Q beta RNA was used to guide the modeling. The model was tested in solution with three enzymatic probes: RNase T1, RNase T2, and RNase V1, as well as four chemical probes: dimethylsulfate, diethylpyrocarbonate, kethoxal and 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluene sulfonate (CMCT). The structural analyses in solution are consistent with the predicted structural model. The model is also supported by comparative structural analysis with the related coliphage SP. The model provides a structural basis for published biochemical and genetic studies implicating large, long-range structural features in the co-regulation of viral coat and replicase expression. In addition, we show that the read-through region of the viral protein A1 forms a separate structural domain, and we suggest that it functions as a nucleation site that participates in the folding and refolding of the molecule during replication and translation. In addition to the central hairpin, we have analyzed the structure of the viral coat initiation region. Our studies show that the entire region consists of small local hairpins and that 26 nucleotides immediately surrounding the coat initiation codon are single-stranded.
J Mol Biol 1993 Sep 20
PMID:A two-dimensional model at the nucleotide level for the central hairpin of coliphage Q beta RNA. 837 1

We have chosen two members of the microbial RNase family, barnase and binase, which have 85% identity (17 substitutions and 1 deletion) and almost identical three-dimensional structure, to study the evolution of protein stability. The 17 residues that differ are scattered throughout the molecule. Each of the 17 differing residues has been mutated independently and the effect on protein stability analysed. Each point mutation has an effect on protein stability that ranges from +1.1 to -1.1 kcal mol-1. These changes in energy are additive. There is no clear correlation between the type of mutation and the effect on protein stability. A multiple mutant having six of the single mutations that increase the stability of barnase is 3.3 kcal mol-1 more stable than wild type and has the same activity. There could be selective pressure to maintain proteins at a certain stability and, consequently, mutations that decrease stability tend to be counterbalanced by stabilizing mutations. Alternatively, there could simply be pressure to maintain stability above a certain level, and any further increases in stability need not be maintained during evolution. These results suggest a simple way to improve the stability of proteins: choose two homologous proteins that have high similarity, mutate individually all of the residues that differ between the two, and combine the mutations that increase the stability in a multiple mutant.
J Mol Biol 1993 Sep 20
PMID:Step-wise mutation of barnase to binase. A procedure for engineering increased stability of proteins and an experimental analysis of the evolution of protein stability. 837 5

Barnase has been co-crystallized at neutral pH with its natural product the 3'-guanylic acid. The X-ray structure was solved by molecular replacement methods and refined to a final R-factor of 18.7%. The protein folding is essentially the same as that of the native form. The base recognition site is almost identical to that of the homologous binase-3'GMP complex, but the nucleotide is bound in a productive binding mode for a substrate with a syn glycosyl torsion angle allowing the general base Glu73 to hydrogen bond with the 2'O of the nucleotide as is assumed in the classical catalytic mechanism. The two molecules of the asymmetric unit form a dimer and the positions of the two nucleotides partially mimic the interaction of the RNA with the enzyme, one of the inhibitors being located in a secondary subsite.
FEBS Lett 1993 Sep 13
PMID:Three-dimensional structure of a barnase-3'GMP complex at 2.2A resolution. 839 45

Chaperonins prevent the aggregation of partially folded or misfolded forms of a protein and, thus, keep it competent for productive folding. It was suggested that GroEL, the chaperonin of Escherichia coli, exerts this function 1 unfolding such intermediates, presumably in a catalytic fashion. We investigated the kinetic mechanism of GroEL-induced protein unfolding by using a reduced and carbamidomethylated variant of RNase T1, RCAM-T1, as a substrate. RCAM-T1 cannot fold to completion, because the two disulfide bonds are missing, and it is, thus, a good model for long-lived folding intermediates. RCAM-T1 unfolds when GroEL is added, but GroEL does not change the microscopic rate constant of unfolding, ruling out that it catalyzes unfolding. GroEL unfolds RCAM-T1 because it binds with high affinity to the unfolded form of the protein and thereby shifts the overall equilibrium toward the unfolded state. GroEL can unfold a partially folded or misfolded intermediate by this thermodynamic coupling mechanism when the Gibbs free energy of the binding to GroEL is larger than the conformational stability of the intermediate and when the rate of its unfolding is high.
Proc Natl Acad Sci U S A 1996 Sep 03
PMID:A thermodynamic coupling mechanism for GroEL-mediated unfolding. 879 Mar 46

We present a lattice Monte Carlo study to examine the effect of denaturants on the folding rates of simplified models of proteins. The two-dimensional model is made from a three-letter code mimicking the presence of hydrophobic, hydrophilic, and cysteine residues. We show that the rate of folding is maximum when the effective hydrophobic interaction epsilon H is approximately equal to the free energy gain epsilon S upon forming disulfide bonds. In the range 1 < or = epsilon H/ epsilon S < or = 3, multiple paths that connect several intermediates to the native state lead to fast folding. It is shown that at a fixed temperature and epsilon S the folding rate increases as epsilon H decreases. An approximate model is used to show that epsilon H should decrease as a function of the concentration of denaturants such as urea or guanidine hydrochloride. Our simulation results, in conjunction with this model, are used to show that increasing the concentration of denaturants can lead to an increase in folding rates. This occurs because denaturants can destabilize the intermediates without significantly altering the energy of the native conformation. Our findings are compared with experiments on the effects of denaturants on the refolding of bovine pancreatic trypsin inhibitor and ribonuclease T1. We also argue that the phenomenon of denaturant-enhanced folding of proteins should be general.
Protein Sci 1996 Sep
PMID:Denaturants can accelerate folding rates in a class of globular proteins. 888 Sep 6

Our understanding of the factors stabilizing alpha-helical structure has been greatly enhanced by the study of model alpha-helical peptides. However, the relationship of these results to the folding of helices in intact proteins is not well characterized. Helix propensities measured in model peptides are not in good agreement with those from proteins. In order to address these questions, we have measured helix propensities in the alpha-helix of ribonuclease T1 and a helical peptide of identical sequence. We have previously demonstrated excellent agreement between peptide and protein for the nonpolar amino acids [Myers, J. K., Pace, C. N., and Scholtz, J. M. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 2833-2837]. Most other amino acids also show good agreement, although certain polar amino acids are exceptions. Helix propensities measured in the ribonuclease T1 peptide/protein are compared with those measured in other systems. Reasonable agreement is found between most systems; however, our propensities differ substantially from those measured in several model peptide systems. Alanine-based peptides overestimate the propensity differences by a factor of 2, and host/guest experiments underestimate them by a factor of 2-3.
Biochemistry 1997 Sep 09
PMID:Helix propensities are identical in proteins and peptides. 928 83

1. In order to understand the differences in pH optima and reaction rates of RNase A towards low molecular weight substrates and polymer substrates, the subsite structure of bovine pancreatic RNase A was studied. The kinetic studies of various sizes of oligouridylic acids showed that the size of the subsite is three nucleotides long. The kinetic studies on the inhibition of pUp, X-ray crystallographies of RNase A-ApC and pTp complexes, 31P-NMR studies on the binding of RNase A-pAp, and pTp showed the presence of P0, P2 and B3 sites. The location of the P0 site was assigned to be Lys66 by X-ray crystallography of the RNase A-pTp complex. The location of the P2 and/or P3/B3 site was determined by studying the enzymatic activities of several S-peptide analogs in which N-Leu was substituted for Lys7 and/or Lys1 coupled with S-protein toward various chain lengths of oligouridylic acids. The experiment suggested that P2 is Lys7 and P3/B3 is Lys1. 2. Several new pyrimidine base specific RNases were isolated and their primary structures were determined. They were two non-secretory RNases, a bovine liver alkaline RNase, a bovine brain RNase, and a bullfrog liver RNase. The bovine brain RNase has extra 16 amino acids at the C-terminus with O-glycosylated Ser. The bullfrog liver RNase was an extremely heat-stable RNase so far known. 3. Two new RNases belonging to RNase T1 family were isolated and their primary structures were elucidated. They were RNases isolated from Aspergillus saitoi and a mushroom (hiratake). The former RNase has a similar structure to RNase T1, but it was a base non-specific and guanylic acid preferential enzyme. From the results of X-crystallographic studies of this RNase, we suggested that the mechanism of RNase T1 RNase is essentialy a general acid-base catalysis between His40 and Glu58. 4. We isolated several fungal, plant and animal base non-specific acid RNases with a molecular mass about 24 kDa or more, and elucidated their primary structures. These RNases contain two sequences containing common 7-8 amino acid residues in common which include most of the amino acid residues important for the catalysis. Therefore, we proposed to designate these RNases as RNase T2 family RNase. On the basis of chemical modifications, kinetic studies and protein engineering studies of RNase Rh from Rhizopus niveus and RNase M from A. saitoi, we assigned that the catalytic site of RNase Rh consists of His46, His104, His109, Glu105, and Lys108. In the mechanism we proposed for RNase Rh, His46 and His109 work as a general acid and base catalysts. His104 was a phosphate binding site, and Glu105 and Lys108 might work to polarize a P=O bond of the substrate or stabilize the pentacovalent intermediate. However, in the reverse reaction of the transfer reaction step and the hydrolysis step of RNase Rh, His109 and His46 work as an acid and base catalyst, respectively. The X-ray crystallographic studies of RNase Rh, an RNase Rh-2'-AMP or d(ApC)complex, and the protein engineering studies of several mutant enzymes assigned the components of the major base recognition site (B1 site) and the minor base recognition site (B2 sites) of RNase Rh. The enzymatic studies of several mutant enzymes indicated that (i) Asp51 is very crucial for adenine base recognition, and the replacement of Asp51 by other amino acid, such as Thr, Ser, Glu, Asn makes RNase Rh more guanylic acid preferential, (ii) the replacement of Trp49 by Phe, and Tyr57 by Trp make the enzyme more pyrimidine and purine bases preferential, respectively. These trials are the first example of marked artificial change in the base specificity of RNases.
Yakugaku Zasshi 1997 Sep
PMID:[Structures and functions of ribonucleases]. 935 26

To elucidate the metabolic function of mRNA polyadenylation in Escherichia coli. we searched for a polyadenylate-binding protein as a potential mediator of the function of the poly(A) moiety. Using a nitrocellulose filter-binding assay and a Northwestern blot technique, a protein in the ribosomal supernatant fraction of E coli was identified and purified to homogeneity. N-terminal sequence analysis yielded a 25-residue sequence which corresponded to the 25 N-terminal amino acids of protein S1, one of the proteins of the E coli 30S ribosomal subunit. Poly(A) binding to S1 protein was inhibited by Mg2+ and Mn2+ and by ATP and stimulated 8-fold by 100 mM KCl. The binding of S1 to poly(A) occurred with an association constant of 3 x 10(6) M-1 and seemed to be only mildly cooperative. Competition studies of the binding of poly(A) and poly(C) to purified S1 protein were consistent with the presence of two polynucleotide binding sites, of which one binds poly(A) five times more strongly than poly(C), whereas the other binds poly(C) 50 times more strongly than poly(A). Poly(A) bound to 30S ribosomal subunits but not to 50S ribosomes. To study possible association of S1 with the poly(A) tracts of E coli mRNA in the process of translation, poly(A) RNA was isolated from polysomes by oligo(dT) cellulose chromatography and the poly(A) RNA with bound protein was eluted either directly or after digestion with RNase T1 and A. When subjected to Western blot analysis with antibody to S1, both poly(A) RNA and isolated poly(A) tracts revealed bound S1 protein. The implications of these results for the possible interaction of poly(A) tracts of mRNA and the translational machinery of E coli are discussed.
Biochimie 1997 Sep
PMID:Identification of ribosomal protein S1 as a poly(A) binding protein in Escherichia coli. 945 50

In Euplotes crassus, telomerase is responsible for telomere maintenance during vegetative growth and de novo telomere synthesis during macronuclear development. Here we show that telomerase in the vegetative stage of the life cycle exists as a 280-kD complex that can add telomeric repeats only onto telomeric DNA primers. Following the initiation of macronuclear development, telomerase assembles into larger complexes of 550 kD, 1600 kD, and 5 MD. In the 1600-kDa and 5-MDa complexes, telomerase is more processive than in the two smaller complexes and can add telomeres de novo onto nontelomeric 3' ends. Assembly of higher order telomerase complexes is accompanied by an extended region of RNase V1 and RNase T1 protection in the telomerase RNA subunit that is not observed with telomerase from vegetatively growing cells. The protected residues encompass a highly conserved region previously proposed to serve as a platform for formation of higher order structures. These findings provide the first direct demonstration of developmentally regulated higher order telomerase complexes with unique biochemical and structural properties.
Genes Dev 1998 Sep 15
PMID:Developmentally programmed assembly of higher order telomerase complexes with distinct biochemical and structural properties. 974 68

Cyclophilin (the product of the ppiB gene) and the trigger factor (the product of the tig gene) are the only cytosolic peptidyl-prolyl cis-trans isomerases that are known in Bacillus subtilis. Both enzymes catalyze the in vitro refolding of ribonuclease T1, a reaction that is limited in rate by a prolyl cis/trans isomerization. The efficiency of cyclophilin as a folding catalyst is only modest with a kcat/KM value of 3.8 x 10(4) M-1 s-1, but the trigger factor shows an almost 40-fold higher specific activity with a kcat/KM value of 1.4 x 10(6) M-1 s-1. This high catalytic activity originates from the tight binding to the protein substrate as reflected in both the low KM value of 0.5 microM and in the strong inhibition of the trigger factor by unfolded proteins. By use of a protein-folding assay, the concentrations of cyclophilin and the trigger factor in the cytosol of B. subtilis could be determined as 26 and 35 microM, respectively. Together they account for the entire folding activity that is detectable in crude extracts of wild-type B. subtilis cells. The genes encoding cyclophilin and the trigger factor in the B. subtilis chromosome were disrupted individually and simultaneously. Even in combination, these disruptions had no effect on cell viability in rich medium or under several stress conditions, such as heat, osmotic, or oxidative stress. However, in poor medium and, in particular, in the absence of amino acids, the growth of the double mutant strain was strongly decelerated, indicating that the prolyl isomerases become essential for growth under starvation conditions. It is not yet known whether this function relates to the catalysis of the proline-limited folding of essential proteins.
Biochemistry 1998 Sep 22
PMID:Cyclophilin and trigger factor from Bacillus subtilis catalyze in vitro protein folding and are necessary for viability under starvation conditions. 974 46


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