EC:3.1.27.4 - FACTA Search

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Query: EC:3.1.27.4 (ribonuclease)
6,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The relationship between the structural stability and the internal motions of proteins was investigated through measurements of 15N relaxation and hydrogen-deuterium exchange rates of ribonuclease HI from Escherichia coli and its thermostable quintuple mutant (Gly23-->Ala, His62-->Pro, Val74-->Leu, Lys95-->Gly, and Asp134-->His), which has a higher melting temperature by 20.2 degreesC. For most of the residues, the generalized order parameters (S2) obtained from 15N relaxation analyses as well as the localized hydrogen-bond-breaking motions (local breathing) observed as fast H-D exchange rates were largely unaffected by the mutations, indicating no global mutational effect on the internal motions. Several local mutational effects were observed for residues close to the mutation sites as follows. The S2 value significantly increased for Lys96 and Val98, which indicated that motions on the pico- to nanosecond time-scale became restricted within a protruding region including the Lys95-->Gly mutation site. In contrast, slight decreases in S2, and drastic increases in the chemical exchange motion on the micro- to millisecond time-scale (Deltaex), were observed for residues located in the joining region between the protrusion and the major domain of the protein. These changes may be caused by the elimination of the bulky Lys95 side-chain at the center of the protrusion. Deltaex observed for residues in alpha-helix I of the wild-type protein was reduced for the mutant, probably because a cavity in the hydrophobic core is filled by the Val74-->Leu mutation. The local breathing at position 134 was restricted by the Asp134-->His mutation, probably because the reduction of the negative charge repulsion contributes to the stability of the native major conformation relative to the breathing conformations around position 134.
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PMID:Structural stability and internal motions of Escherichia coli ribonuclease HI: 15N relaxation and hydrogen-deuterium exchange analyses. 953 89

Select members of the bovine pancreatic ribonuclease A (RNase A) superfamily are potent cytotoxins. These cytotoxic ribonucleases enter the cytosol, where they degrade cellular RNA and cause cell death. Ribonuclease inhibitor (RI), a cytosolic protein, binds to members of the RNase A superfamily with inhibition constants that span 10 orders of magnitude. Here, we show that the affinity of a ribonuclease for RI plays an integral role in defining the potency of a cytotoxic ribonuclease. RNase A is not cytotoxic and binds RI with high affinity. Onconase, a cytotoxic RNase A homolog, binds RI with low affinity. To disrupt the RI-RNase A interaction, three RNase A residues (Asp-38, Gly-88, and Ala-109) that form multiple contacts with RI were replaced with arginine. Replacing Asp-38 and Ala-109 with an arginine residue has no effect on the RI-RNase interaction. In addition, these variants are not cytotoxic. In contrast, replacing Gly-88 with an arginine residue yields a ribonuclease (G88R RNase A) that retains catalytic activity in the presence of RI and is cytotoxic to a transformed cell line. Replacing Gly-88 with aspartate also yields a ribonuclease (G88D RNase A) with a decreased affinity for RI and cytotoxic activity. The cytotoxic potency of onconase, G88R RNase A, and G88D RNase A correlate with RI evasion. We conclude that ribonucleases that retain catalytic activity in the presence of RI are cytotoxins. This finding portends the development of a class of chemotherapeutic agents based on pancreatic ribonucleases.
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PMID:Ribonuclease A variants with potent cytotoxic activity. 972 16

The Kidd (JK) blood group locus encodes a urea transporter that is expressed on human red cells and on endothelial cells of the vasa recta in the kidney. Here, we report the identification in human erythroblasts of a novel cDNA, designated HUT11A, which encodes a protein identical to the previously reported erythroid HUT11 urea transporter, except for a Lys(44) --> Glu substitution and a Val-Gly dipeptide deletion after proline 227, which leads to a polypeptide of 389 residues versus 391 in HUT11. Genomic typing by polymerase chain reaction and transcript analysis by ribonuclease protection assay demonstrated that HUT11A encodes the true Kidd blood group/urea transporter protein, which carries only 2 Val-Gly motifs. Upon expression at high levels in Xenopus oocytes, the physiological Kidd/urea transporter HUT11A conferred a rapid transfer of urea (which was insensitive to p-chloromercuribenzene sulfonate or phloretin), a high water permeability, and a selective uptake of small solutes including amides and diols, but not glycerol and meso-erythritol. However, at plasma membrane expression levels close to the level observed in the red cell membrane, HUT11A-mediated water transport and small solutes uptake were absent and the urea transport was poorly inhibited by p-chloromercuribenzene sulfonate, but strongly inhibited by phloretin. These findings show that, at physiological expression levels, the HUT11A transporter confers urea permeability but not water permeability, and that the observed water permeability is a feature of the red cell urea transporter when expressed at unphysiological high levels.
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PMID:At physiological expression levels the Kidd blood group/urea transporter protein is not a water channel. 1051 15

The 15-meric S-tag is a truncated form of the S-peptide, which builds together with the 103 amino acid large S-protein the whole ribonuclease S-protein. Its small size and excessive solubility have made the S-tag an excellent fusion partner in the production of recombinant proteins, and a large variety of applications have been reported using the S-tag as a carrier. While S-tagged proteins were mostly detected and analyzed so far by use of their affinity to S-proteins, monoclonal antibodies (MAbs) for this tag have been not available. The generation of antibodies specific for S-tagged proteins is expected to broaden the range of applications of such S-tag fused recombinant proteins, and in this context, a novel MAb termed ATOM-2 was generated that specifically binds S-tagged proteins, which have been expressed using pET-vectors. Antigen specificity of ATOM-2 was confirmed in Western blot and enzyme-linked immunoadsorbent assay analysis, and using a series of amino acid deletion mutants, the binding epitope of ATOM-2 was precisely mapped. This showed that ATOM-2 recognizes the C-terminal part of the 15-meric S-tag in context with a few residues of vector encoded sequences. The core sequence for ATOM-2 binding epitope is "His-Met-Asp-Ser-Pro-Asp-Leu-Gly-Thr," which is present in all pET-expression vectors encoding S-tag fusion proteins. Because the ATOM-2 binding region does not overlap with the S-protein binding sequence, a convenient tool is provided for the simultaneous or alternative detection, purification, and analysis of recombinant S-tagged proteins to conventional S-proteins.
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PMID:Detection of pET-vector encoded, recombinant S-tagged proteins using the monoclonal antibody ATOM-2. 1128 23

Combinatorial random mutageneses involving either Asn43 with Asn44 (set 1) or Glu46 with an adjacent insertion (set 2) were undertaken to explore the functional perfection of the guanine recognition loop of ribonuclease T(1) (RNase T(1)). Four hundred unique recombinants were screened in each set for their ability to enhance enzyme catalysis of RNA cleavage. After a thorough selection procedure, only six variants were found that were either as active or more active than wild type which included substitutions of Asn43 by Gly, His, Leu, or Thr, an unplanned Tyr45Ser substitution and Glu46Pro with an adjacent Glu47 insertion. Asn43His-RNase T(1) has the same loop sequence as that for RNases Pb(1) and Fl(2). None of the most active mutants were single substitutions at Asn44 or double substitutions at Asn43 and Asn44. A total of 13 variants were purified, and these were subjected to kinetic analysis using RNA, GpC, and ApC as substrates. Modestly enhanced activities with GpC and RNA involved both k(cat) and K(M) effects. Mutants having low activity with GpC had proportionately even lower relative activity with RNA. Asn43Gly-RNase T(1) and all five of the purified mutants in set 2 exhibited similar values of k(cat)/K(M) for ApC which were the highest observed and about 10-fold that for wild type. The specificity ratio [(k(cat)/K(M))(GpC)/(k(cat)/K(M))(ApC)] varied over 30 000-fold including a 10-fold increase [Asn43His variant; mainly due to a low (k(cat)/K(M))(ApC)] and a 3000-fold decrease (Glu46Ser/(insert)Gly47 variant; mainly due to a low (k(cat)/K(M))(GpC)) as compared with wild type. It is interesting that k(cat) (GpC) for the Tyr45Ser variant was almost 4-fold greater than for wild type and that Pro46/(insert)Glu47 RNase T(1) is 70-fold more active than the permuted variant (insert)Pro47-RNase T(1) which has a conserved Glu46. In any event, the observation that only 6 out of 800 variants surveyed had wild-type activity supports the view that functional perfection of the guanine recognition loop of RNase T(1) has been achieved.
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PMID:Probing functional perfection in substructures of ribonuclease T1: double combinatorial random mutagenesis involving Asn43, Asn44, and Glu46 in the guanine binding loop. 1129 44

Mammalian ribonucleases interact very strongly with the intracellular ribonuclease inhibitor (RI). Eukaryotic cells exposed to mammalian ribonucleases are protected from their cytotoxic action by the intracellular inhibition of ribonucleases by RI. Human pancreatic ribonuclease (HPR) is structurally and functionally very similar to bovine RNase A and interacts with human RI with a high affinity. In the current study, we have investigated the involvement of Lys-7, Gln-11, Asn-71, Asn-88, Gly-89, Ser-90, and Glu-111 in HPR in its interaction with human ribonuclease inhibitor. These contact residues were mutated either individually or in combination to generate mutants K7A, Q11A, N71A, E111A, N88R, G89R, S90R, K7A/E111A, Q11A/E111A, N71A/E111A, K7A/N71A/E111A, Q11A/N71A/E111A, and K7A/Q11A/N71A/E111A. Out of these, eight mutants, K7A, Q11A, N71A, S90R, E111A, Q11A/E111A, N71A/E111A, and K7A/N71A/E111A, showed an ability to evade RI more than the wild type HPR, with the triple mutant K7A/N71A/E111A having the maximum RI resistance. As a result, these variants exhibited higher cytotoxic activity than wild type HPR. The mutation of Gly-89 in HPR produced no change in the sensitivity of HPR for RI, whereas it has been reported that mutating the equivalent residue Gly-88 in RNase A yielded a variant with increased RI resistance and cytotoxicity. Hence, despite its considerable homology with RNase A, HPR shows differences in its interaction with RI. We demonstrate that interaction between human pancreatic ribonuclease and RI can be disrupted by mutating residues that are involved in HPR-RI binding. The inhibitor-resistant cytotoxic HPR mutants should be useful in developing therapeutic molecules.
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PMID:Interaction of human pancreatic ribonuclease with human ribonuclease inhibitor. Generation of inhibitor-resistant cytotoxic variants. 1134 52

Onconase(ONC) is an amphibian ribonuclease that is in clinical trials as a cancer chemotherapeutic agent. ONC is a homolog of ribonuclease A (RNase A). RNase A can be made toxic to cancer cells by replacing Gly(88) with an arginine residue, thereby enabling the enzyme to evade the endogenous cytosolic ribonuclease inhibitor protein (RI). Unlike ONC, RNase A contains a KFERQ sequence (residues 7-11), which signals for lysosomal degradation. Here, substitution of Arg(10) of the KFERQ sequence has no effect on either the cytotoxicity of G88R RNase A or its affinity for RI. In contrast, K7A/G88R RNase A is nearly 10-fold more cytotoxic than G88R RNase A and has more than 10-fold less affinity for RI. Up-regulation of the KFERQ-mediated lysosomal degradation pathway has no effect on the cytotoxicity of these ribonucleases. Thus, KFERQ-mediated degradation does not limit the cytotoxicity of RNase A variants. Moreover, only two amino acid substitutions (K7A and G88R) are shown to endow RNase A with cytotoxic activity that is nearly equal to that of ONC.
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PMID:KFERQ sequence in ribonuclease A-mediated cytotoxicity. 1180 5

Human pancreatic ribonuclease (HPR) and bovine seminal ribonuclease (BS-RNase) exhibit significantly higher activity against double stranded RNA (dsRNA), compared to RNase A. The high dsRNA cleavage activity of BS-RNase, in part, has been attributed to glycine residues at positions 38 and 111. HPR possesses a glycine residue at position 38, whereas it has a glutamic acid at position 111. To understand the mechanism of dsRNA degradation by the single strand preferring HPR, we have generated HPR variants containing mutations at positions 38 and 111. Our study shows that Glycine 38 is crucial for the full catalytic activity of the human enzyme on duplex RNA as its substitution with aspartate or alanine results in a drastic reduction in the dsRNA cleavage activity of HPR. The substitution of Glutamate111 with glycine also resulted in the reduction of the dsRNA cleavage activity of HPR, indicating that a glycine residue at 111 is not a requirement for the ribonucleolytic activity on double stranded substrate.
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PMID:Glycine 38 is crucial for the ribonucleolytic activity of human pancreatic ribonuclease on double-stranded RNA. 1223 31

The ribonuclease MC1 (RNase MC1) from the seeds of the bitter gourd belongs to the RNase T2 family. We evaluated the contribution of 11 amino acids conserved in the RNase T2 family to protein folding of RNase MC1. Thermal unfolding experiments showed that substitution of Tyr(101), Phe(102), Ala(105), and Phe(190) resulted in a significant decrease in themostability; the T(m) values were 47-58 degrees C compared to that for the wild type (64 degrees C). Mutations of Pro(125), Gly(127), Gly(144), and Val(165) caused a moderate decrease in thermostability (T(m): 60-62 degrees C). In contrast, mutations of Asp(107) and Gly(173) did little effect on thermostability. The contribution of Tyr(101), Phe(102), Pro(125), and Gly(127) to protein stability was further corroborated by means of Gdn-HCl unfolding and protease digestions. Taken together, it appeared that Tyr(101), Phe(102), Ala(105), Pro(125), Gly(127), Gly(144), Leu(162), Val(165), and Phe(190) conserved in the RNase T2 family play an important role in the stability of the proteins.
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PMID:Amino acids conserved at the C-terminal half of the ribonuclease T2 family contribute to protein stability of the enzymes. 1532 60

The change in the structural stability of Escherichia coli ribonuclease HI (RNase HI) due to single amino acid substitutions has been estimated computationally by the stability profile of mutant protein (SPMP) [Ota, M., Kanaya, S. Nishikawa, K., 1995. Desk-top analysis of the structural stability of various point mutations introduced into ribonuclease H. J. Mol. Biol. 248, 733-738]. As well, an effective strategy using random mutagenesis and genetic selection has been developed to obtain E. coli RNase HI mutants with enhanced thermostability [Haruki, M., Noguchi, E., Akasako, A., Oobatake, M., Itaya, M., Kanaya, S., 1994. A novel strategy for stabilization of Escherichia coli ribonuclease HI involving a screen for an intragenic suppressor of carboxyl-terminal deletions. J. Biol. Chem. 269, 26904-26911]. In this study, both methods were combined: random mutations were individually introduced to Lys99-Val101 on the N-terminus of the alpha-helix IV and the preceding beta-turn, where substitutions of other amino acid residues were expected to significantly increase the stability from SPMP, and then followed by genetic selection. Val101 to Ala, Gln, and Arg mutations were selected by genetic selection. The Val101-->Ala mutation increased the thermal stability of E. coli RNase HI by 2.0 degrees C in Tm at pH 5.5, whereas the Val101-->Gln and Val101-->Arg mutations decreased the thermostability. Separately, the Lys99-->Pro and Asn100-->Gly mutations were also introduced directly. The Lys99-->Pro mutation increased the thermostability of E. coli RNase HI by 1.8 degrees C in Tm at pH 5.5, whereas the Asn100-->Gly mutation decreased the thermostability by 17 degrees C. In addition, the Lys99-->Pro mutation altered the dependence of the enzymatic activity on divalent metal ions.
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PMID:Stabilization of E. coli Ribonuclease HI by the 'stability profile of mutant protein' (SPMP)-inspired random and non-random mutagenesis. 1654 82

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