Significance of the four carboxyl terminal amino acid residues of bovine pancreatic ribonuclease A for structural folding

The C-terminal amino acid residues of bovine pancreatic ribonuclease A (RNase A) form a core structure in the initial stage of the folding process that leads to the formation of the tertiary structure. In this paper, roles of the C-terminal four amino acids in the structure, function, and refolding were studied by use of recombinant mutant enzymes in which these residues were deleted or replaced. Purified mutant enzymes were analyzed for their secondary structure, thermal stability, and ability to regenerate from the denatured and reduced state. The C-terminal deleted mutant enzymes showed lower hydrolytic activity for C>p and nearly identical CD spectra compared with the wild-type enzyme. The rate of recovery of activity was significantly different among the C-terminal deleted mutant enzymes when air oxidation was employed in the absence of GSH and GSSG: the rates decreased in the order of des-124-, des-(123-124)-, and des-(122-124)-RNase A. It is noteworthy that the regeneration rates of mutant RNase A in the presence of GSH and GSSG were nearly the same. Des-(121-124)-RNase A failed to recover activity both in the presence and absence of glutathione, due to the mismatched formation of disulfide bonds. The mutant enzyme in which all of the C-terminal four amino acid residues were replaced by alanine residues showed lower hydrolytic activity and an indistinguishable CD spectrum compared with the wild-type enzyme, and also recovered its activity from the denatured and reduced state by air oxidation. The D121 mutant enzymes showed decreased hydrolytic activity and identical CD spectra compared with the wild type. The recovery rates of activity of D121A and D121K were determined to be lower than that of the wild-type enzyme, while the rate of recovery of D121E was comparable to that of the wild type. The C-terminal amino acids play a significant role in the formation of the correct disulfide bonds during the refolding process, and the interaction of amino acid residues and the existence of the main chain around the C-terminal region are both important for achieving the efficient packing of the RNase A molecule.     

Effect of bovine seminal ribonuclease and bovine pancreatic ribonuclease A on bovine oocyte maturation

Bovine seminal ribonuclease (BS-RNase) contains the MxM (noncovalent dimer) and M=M (free monomer) in constant ratio. The aim of this work was to evaluate the effect of BS-RNase, its monomer and dimer forms, and also various mutants of this enzyme on meiotic completion in cattle oocytes. It was found that BS-RNase has irreversible effects on the meiotic maturation of bovine oocytes in vitro, particularly on the completion of meiosis. The effect of BS-RNase is dose-dependent. In medium supplemented with 1 microg/ml, the results were comparable with those of the control (70% MII oocytes after 24 hr of culture). Whereas 5 microg/ml reduced the number of MII oocytes to 50%, 10 and 25 microg/ml arrested this process completely. The MxM form and RNase A at 5 microg/ml inhibited the maturation rate by 71 and 48%, respectively, but a less significant effect was observed for the M=M form, or the carboxymethylated monomers MCM31 and MCM32 (21%, 16%, and 42% MII oocytes, respectively, in comparison with control). These data demonstrate that bovine ribonucleases can have variable detrimental effects on the maturation of bovine oocyte. J. Exp. Zool. 287:394-399, 2000.     

Modification of amino acids and bovine pancreatic ribonuclease A by kethoxal.

Kethoxal (3-ethoxy-2-ketobutanal) reacts with the guanidino group of Nalpha-acetylarginine to produce four derivatives, reactive to periodate, stable at pH 7, with 15% reverting to arginine on acid hydrolysis. Other amino acids with blocked alpha-amino groups do not react, except the epsilon-amino of lysine (slowly). The pK of the mixed Kethoxal-Nalpha-acetylarginine derivatives is 5.8-6.1. Kethoxal reacts at neutral pH with arginyl residues of bovine pancreatic ribonuclease A. In the presence of an active-site ligand, arginine-39 and arginine-85 react at about equal rates. The loss of enzymic activity at pH 7 is proportional to the combined loss of these residues. The enzymic activity toward RNA is 20-25% of that of native RNAase at pH 7, and 90-100% at pH 5. In the absence of an active site ligand, arginine-10 is also modified with the loss of almost all enzymic activity, although arginine-10 is not an active-site residue. Arginine-33 is unreactive. Kethoxal-modified RNAase undergoes cross-linking in solution at pH 7 or in the freeze-dried state, Incubation at pH 9 in the presence of homoarginine results in partial regeneration of arginyl residues and activity at pH 7. Kethoxal modification of arginines-39 and -85 appears to raise the pK of lysine-41 by about 1 unit, as indicated ty the pH dependence of arylation by 2-carboxy-4,6-dinitrochlorobenzene. The claims of Patthy and Smith (J. Biol, Chem. (1975) 250, 565-569), and of Takahashi (J. Biol. Chem. (1968) 243, 6171-6179) that arginine-39 is a more important functional residue than is arginine-85 are questioned.     

Effect of protein disulfide isomerase on the regeneration of bovine ribonuclease A with dithiothreitol.

The role of protein disulfide isomerase (PDI) in the regeneration of ribonuclease A with dithiothreitol (DTT) was investigated at three different temperatures. The rates of formation of the native protein were markedly increased in the presence of PDI, 9-fold at 15 degrees C, 6-fold at 25 degrees C and 62-fold at 37 degrees C, respectively. In the presence of PDI, major changes were found in the distribution of intermediates in the three-disulfide region at 25 and 15 degrees C and also in the one-disulfide region at 15 degrees C, with the fast accumulation of the two native-like species des-[65-72] and des-[40-95]. The present results indicate that PDI does not alter the two major parallel pathways involving des-[65-72] and des-[40-95] in the regeneration of ribonuclease A with DTT.     

1H-NMR studies on the binding subsites of bovine pancreatic ribonuclease A

The titration curves of the C-2 histidine protons of an RNAase derivative (a covalent derivative obtained by reaction of bovine pancreatic RNAase A (EC 3.1.27.5) with 6-chloropurine 9-beta-D-ribofuranosyl 5'-monophosphate) were studied by means of 1H-NMR spectroscopy at 270 MHz. The interaction of natural (5'AMP, 5'GMP, 5'IMP) and halogenated purine mononucleotides (cl6RMP, br8AMP) with RNAase A was also monitored by using the same technique. The slight change observed in the pK values of the active centre histidine residues of the RNAase derivative, with respect to those in the native enzyme, can be considered as evidence that the phosphate of the label does not interact directly either with His-12 or 119 in the p1 site, but the p2 site as proposed previously (Parés, X., Llorens, R., Arús, C. and Cuchillo, C.M. (1980) Eur. J. Biochem. 105, 571--579). Lys-7 and/or Arg-10 are proposed as part of the p2 phosphate-binding subsite. The pK values of His-12 and 119 and the shift of an aromatic resonance of the native enzyme found on interaction with some purine nucleotides, can be interpreted by postulating that the interaction of 5'AMP, 5'GMP and 5'IMP takes place not only in the so-called purine-binding site B2R2p1 but also in the primary pyrimidine-binding site B1R1 and p0 of RNAase A.     

Effect of protein disulfide isomerase on the rate-determining steps of the folding of bovine pancreatic ribonuclease A

To address the effect of an agglutogen on virus infection, we studied the avidin-associated inhibition of infection by biotinylated M13 phages (BIO-phages). Microscopic observation of mixtures of BIO-phages and avidin–fluorescein conjugates revealed many aggregates. Even at low phage concentrations, avidin induced inhibition of infection significantly. Anti-M13 phage antibody also made aggregates and inhibited the infection but in a different manner from avidin. The inhibition by avidin was at ≥2 μg/ml, time dependent and marked until 10 min after the mixing of the BIO-phages and Escherichia coli. On the other hand, antibody inhibited the infection at ≥0.1 μg/ml dose dependently, and the inhibition was time dependent and marked until 45 min after the mixing at moderate and low phage concentrations. These results indicate that avidin against BIO-phages and antibodies are agglutogens, and the inhibition of the BIO-phages by avidin is closely related to the tetramerization of avidin. Agglutogens may be novel alternative antiviral drugs.     

Kinetic studies on turtle pancreatic ribonuclease: a comparative study of the base specificities of the B2 and P0 sites of bovine pancreatic ribonuclease A and turtle pancreatic ribonuclease

Kinetic constants for the transesterification of eight dinucleoside phosphates CpX and UpX by bovine and turtle pancreatic ribonuclease were determined. Both ribonucleases have a preference for purine nucleotides at the position X. However, bovine ribonuclease, like other mammalian ribonucleases, prefers 6-amino bases at this site, while turtle ribonuclease prefers 6-keto bases. This difference in specificity at the B2 site may be explained by the substitution of glutamic acid at position 111 by valine in turtle ribonuclease. These results have been confirmed by inhibition studies with the four nucleoside triphosphates. Inhibition studies with pT and pTp showed that a cationic binding group (P0) for the 5'-phosphate of the pyrimidine nucleotides bound at the primary B1 site is present in turtle ribonuclease, although lysine at position 66 in bovine ribonuclease is absent in turtle ribonuclease. However, the side chain of lysine 122 in turtle ribonuclease is probably located in the correct position to take over the role as cationic P0 site.     

Isolation and characterization of monodeamidated derivatives of bovine pancreatic ribonuclease A

The isolation and characterization of the initial intermediates formed during the irreversible acid denaturation of enzyme Ribonuclease A are described. The products obtained when RNase A is maintained in 0.5 M HCl at 30 degrees for periods up to 20 h have been analyzed by ion-exchange chromatography on Amberlite XE-64. Four distinct components were found to elute earlier to RNase A; these have been designated RNase Aa2, Aa1c, Aa1b, and Aa1a in order of their elution. With the exception of RNase Aa2, the other components are nearly as active as RNase A. Polyacrylamide gel electrophoresis at near-neutral pH indicated that RNase Aa1a, Aa1b, and Aa1c are monodeamidated derivatives of RNase A; RNase Aa1c contains, in addition, a small amount of a dideamidated component. RNase Aa2, which has 75% enzymic activity as compared to RNase A, consists of dideamidated and higher deamidated derivatives of RNase A. Except for differences in the proteolytic susceptibilities at an elevated temperature or acidic pH, the monodeamidated derivatives were found to have very nearly the same enzymic activity and the compact folded structure as the native enzyme. Fingerprint analyses of the tryptic peptides of monodeamidated derivatives have shown that the deamidations are restricted to an amide cluster in the region 67-74 of the polypeptide chain. The initial acid-catalyzed deamidation occurs in and around the 65-72 disulfide loop giving rise to at least three distinct monodeamidated derivatives of RNase A without an appreciable change in the catalytic activity and conformation of the ribonuclease molecule. Significance of this specific deamidation occurring in highly acidic conditions, and the biological implications of the physiological deamidation reactions of proteins are discussed.     

The ribonuclease inhibitors from porcine thyroid and liver are slow, tight-binding inhibitors of bovine pancreatic ribonuclease A

Ribonuclease inhibitors were purified from the latent ribonuclease fractions of porcine thyroid and liver and used to test the hypothesis that their inhibition of bovine pancreatic ribonuclease A is correctly described by tight-binding rather than Michaelis-Menton kinetics. Both proteins were found to act as slow, tight-binding inhibitors of the enzyme. These steady-state velocities also showed that both the thyroid and liver inhibitors were competitive inhibitors of bovine pancreatic ribonuclease A with Ki's of 0.1 and 0.4 nM, respectively. In contrast to interpretations based on Michaelis-Menton assumptions that show non-competitive inhibition, these results suggest that an enzyme:inhibitor:substrate complex does not exist.