Standardization of assay procedure and some properties of ribonuclease fromaspergillus candidus

Screening of several fungal cultures resulted in the selection of an isolate of Aspergillus candidus which produced a considerable around of RNa-degrading enzyme in both surface and submerged methods of cultivation. The conditions for the assay of the RNAase were standardized at pH 4.5, 55 degrees C and using 0.25% yeast RNA as substrate. The enzyme was stable at pH 5.2. EDTA was found to activate the enzyme slightly. at temperatures 50-60 degrees C there was considerable loss in enzyme activity which was traced to the presence of a contaminating protease which presumably degraded the RNAase optimally at this temperature. The protease could be preferentially inactivated at or above 75 degrees C. The crude enzyme, in addition to RNAase was found to possess DNAase, nonspecific phosphodiesterase and 3'- and 5'-phosphomonoesterase activities.     

Isolation and characterization of two alkaline ribonucleases from calf serum.

Treatment of calf serum at 60 degrees C and pH 3.5 followed by chromatography on carboxymethyl (CM) cellulose resulted in the separation of two major peaks of alkaline RNAse activity. One was eluted from CM-cellulose at 0.075 M KCl with an overall purification of 5400-fold and the other was eluted at 0.25 M KCl with a 6700-fold purification. The RNAse eluted from CM-cellulose at 0.075 M KCl was almost completely inhibited by anti-RNAse A serum and by the endogenous RNAse inhibitor and a 33% inhibition was observed in the presence of 5 mM MgCl2. This enzyme seems to be similar or identical to RNAse A. The other RNAse, eluted from CM-cellulose at 0.25 M KCl was not inhibited by anti-RNAse A or 5 mM MgCl2 and was much less sensitive to the endogenous inhibitor. Both enzymes degraded RNA endonucleolytically and the nucleoside monophosphates obtained after partial hydrolysis of RNA by the two serum RNAases were primarily 2'- or 3' -CMP and 2'- or 3' -UMP. Poly(A), native DNA and denatured DNA were degraded slowly or not at all. The RNAase A-like enzyme degraded poly(C) at a significantly faster rate, and poly(U) at a slower rate, than RNA. However, the other serum RNAase was more active with poly(U) than with RNA and almost inactive with poly(C) as the substrate.     

How much is secondary structure responsible for resistance of double-stranded RNA to pancreatic ribonuclease A?

1. Double-stranded f2 sus11 or Qbeta RNAs, resistant to bovine pancreatic RNAase A in 0.15 M NaCl/0.015 M sodium citrate (SSC), are quickly and completely degraded at 10-fold lower ionic strength (0.1 X SSC) under otherwise similar conditions. At this ionic strength the secondary structure of double-stranded RNA is maintained, as judged by the following: (a) the unchanged resistance of double-stranded RNA and DNA, under similar low ionic strength conditions, to nuclease S1 from Aspergillus oryzae, in contrast with the sensitivity of the corresponding denatured nucleic acids to this enzyme, specific for single-stranded RNA and DNA; (b) the co-operative pattern of the thermal-transition profile of double-stranded RNA (with a Tm of 89 degrees C) in 0.1 X SSC. 2. Whereas in SSC bovine seminal RNAase (RNAase BS-1) and whale pancreatic RNAase show an activity on double-stranded RNA significantly higher than that of RNAase A, in 0.1 X SSC the activity of the latter enzyme on this substrate becomes distinctly higher than that of RNAase BS-1, and similar to that of whale RNAase. 3. From these results it is deduced that the secondary structure is probably not the only nor the most important variable in determining the susceptibility double-stranded RNA to ribonuclease. Other factors, such as the effect of ionic strength on the enzyme and/or the binding of enzyme to nucleic acids, may play an important role in the process of double-stranded RNA degradation by ribonucleases specific for single-stranded RNA.     

Extracellular RNAase Pch2 of Penicillium chrysogenum 152A: purification, specificity and physico-chemical properties

Acid RNAase Pch2 was isolated from a filtrate of the cultural fluid of the fungus Penicillium chrysogenum 152A and purified to homogeneity. An analysis of RNAase Pch2 action on RNA and synthetic substrates showed that the enzyme can be attributed to non-specific true ribonucleases (ribonucleate-3'-oligo-nucleotide hydrolase, EC 3.1.4.23). The maximal effect of the enzyme on RNA is observe at pH 4.5 and 55 degree. The RNAase Pch2 is not activated by bivalent metal ions, p-chloromercurybenzoate or beta-mercaptoethanol and is reversibly inactivated by 8 M urea. The enzyme molecule consists of 332 amino acid residues; its molecular weight is 36160, the isoelectric point lies at 5.2.     

A rapid method for the isolation of ribonuclease from yeast (Saccharomyces carlsbergensis).

A ribonuclease (RNAase; EC 3.1.14.1) from brewer's yeast was purified 90-fold. Crude RNAase was initially separated from other proteins by precipitation at pH 4.0 after incubation of the mechanically disrupted yeast cells at pH 6.0 and 52 degrees C for 30 min. The RNAase was purified from the supernatant by ultrafiltration with a PM-30 membrane and adsorption chromatography on hydroxyapatite. RNAase preparation was free of phosphatase, deoxyribonuclease and phosphodiesterase activities. It showed maximum activity at pH 6.0 and a temperature optimum of 52 degrees C with yeast RNA as substrate. This RNAase hydrolysed yeast RNA to nucleoside 3'-phosphates and showed no evidence of base specificity.     

Crystallization and some properties of chondroitinase from Arthrobacter aurescens.

A strain of Arthrobacter aurescens which secretes a large amount of chondroitinase into a culture broth, was isolated from soil. The chondroitinase was purified 380-fold over culture broth in 24% yield and crystallized. Some properties of the purified enzyme were studied and described: thermal stability (below 45 degrees), pH stability (pH 4.9 to 7.4), optimum temperature (50 degrees), and optimum pH (pH 6.0). Chrondroitin sulfate A and C, chondroitin, and hyaluronic acid were split by the enzyme but dermatan sulfate could not be. The initial rates of enzymic degradation of chondroitin sulfate C, chondroitin, and hyaluronic acid were 1.1, 1.95, and 3.2, respectively, compared to that of chondroitin sulfate A. When the enzyme was allowed to act on chondroitin sulfate A and C, the reducing power and the ultraviolet absorption at 232 nm increased proportionally to the decrease in viscosity of the substrate solution. Finally these substrates were degraded to the extent of 100% to disaccharides. By the enzyme action the main products from chondroitin sulfate A and C were deta 4,5-unsaturated disaccharides, which were identified as 2-acetamido-2-deoxy-3-O-(Beta-D-gluco-4-enepyranosyluronic acid)-4-O-sulfo-D-galactose and 2-acet-amido-2-deoxy-3-O-(Beta-D-gluco-4-enepyranosyluronic acid)-6-O-sulfo-D-galactose by paper chromatography, ultraviolet absorption spectroscophy, and infrared spectroscopy. Thus it is suggested that the chondroitinase is a chondroitin sulfate A and C lyase, one of the hyaluronate lyases (EC 4.2.99.1).     

Extracellular nucleases of Lysobacter enzymogenes: production of the enzymes and purification and characterization of an endonuclease

Lysobacter enzymogenes produced a nonspecific extracellular nuclease and an extracellular RNAase when grown in tryptone broth. Both enzyme activities appeared after the exponential growth phase of the organism. The addition of RNA to the medium specifically inhibited the production of the nuclease and the addition of phosphate prevented the synthesis of the RNAase. DNA had no effect on the enzyme production. The Lysobacter nuclease was purified 274-fold and its molecular weight was estimated to be between 22 000 and 28 000. Freshly purified nuclease showed one major protein band and one major activity band on polyacrylamide gels, whereas two major bands were seen after prolonged storage of the enzyme. The nuclease was most active at pH 8.0 and required Mg2+ or Mn2+. Little activity was obtained in the presence of Ca2+. The enzyme degraded double-stranded DNA more rapidly than single-stranded DNA or RNA and was essentially inactive with poly(A) or poly(C) as the substrate. Extensive hydrolysis of double-stranded DNA by the enzyme yielded oligodeoxyribonucleotides with terminal 5'-phosphate groups. The Lysobacter RNAase appeared to have a molecular weight approximately twice that of the nuclease and was specific for ribonucleotide polymers.     

Inhibition of ribonuclease. Efficacy of sodium dodecyl sulfate, diethyl pyrocarbonate, protein ase K and heparin using a sensitive ribonuclease assay.

The effectiveness of several commonly used inhibitors of ribonuclease (RNAase) has been studied using the removal of radio-labelled leucine from leucyl-tRNA as a sensitive assay for RNAase activity. The inhibitors were tested under a variety of conditions, varying the temperature, the pH, and the source of RNAase. When each inhibitor is udes separately in the presence of pancreatic RNAase, sodium dodecyl sulfate (SDS) is the most effective; but during long exposures to temperatures above 0 degrees C considerable amounts of RNA are still degraded. Combination of inhibitors are more effective in preserving RNA; with this assay, a combination of SDS with diethyl pyrocarbonate is the most effective. Proteinase K acts as an inhibitor when used in combination with SDS; however, it has RNAase activity when used by itself. Diethyl pyrocarbonate, when used at the high range of concentrations employed by others for RNAase inhibition, reacts with RNA changing its charge. However, when diethyl pyrocarbonate is used in smaller amounts the effects on RNA are minimal, and when used in combination with SDS it effectively inhibits RNAase.     

Differential, structure-dependent susceptibility of poly(A) and RNA to monomeric and dimeric pancreatic ribonuclease A.

Cross-linked dimers of bovine RNAase A are definitely more efficient than monomers at degrading polyadenylic acid under conditions of ionic strength and pH, where the polymer assumes either a double-helical or an ordered single-stranded, base-stacked structure. The opposite occurs, i.e., monomers of RNAase A are definitely more active than dimers,when poly(A) is digested by the two enzyme species under conditions where the conformation of the polymer is essentially that of a random coil. The same pattern of events occurs when total RNA from Escherichia coli or single-stranded RNA of f2 sus11 bacteriophage are used as substrates under opposite ionic-strength conditions. In the presence of high salt concentrations, favouring the formation and the stability of a secondary structure in self-complementary sequences of RNA, the ribonucleic acids are degraded at a higher rate by dimers than by monomers of bovine RNAase A. The opposite occurs in the presence of very low salt concentrations, i.e. when the RNAs are in solution presumably as random coils. These observations are discussed in the light of a hypothesis already advanced to understand the mechanism of enzymic degradation of secondary structures of polyribonucleotides.     

Preparation of the bifunctional enzyme ribonuclease-deoxyribonuclease by cross-linkage.

Protease-free bovine pancreatic deoxyribonuclease (DNase) (1.6 X 10(-4) mmol) was thiolated on the NH2 groups with N-acetyl-DL-homocysteine thiolactone (2.4 X 10(-2) mmol) at pH 10.5 with imidazole (2.4 X 10(-2) mmol) as the catalyst in the presence of 4,4'-dithiodipyridine (4.2 X 10(-2) mmol). The product obtained after 16 h at 4 degrees C, 2-acetamido-4-(4'-dithiopyridyl)butyryl-DNase, isolated by gel filtration, contained an average of 0.87 +/- 0.13 mol of mixed disulfide per mol of DNase. Ribonuclease (RNase) was thiolated in a similar manner, but under N2 in the absence of 4,4'-dithiodipyridine. The protein N-acetylhomocysteinyl-RNase contained on the average 0.94 +/- 0.11 mol of sulfhydryl groups per mol of RNase. The coupling of RNase ot DNase was accomplished by thiol-disulfide interchange at pH 6.2 and 25 degrees C for 90 min. The hybrid enzyme (yield 25--33%, based upon the DNase derivative used) was freed from unreacted DNase, RNase, and homodimers by gel filtration, affinity chromatography, and salting-out chromatography. The purified enzyme contained one molecule each of DNase and RNase and hydrolyzed thymus deoxyribonucleic acid (DNA) and yeast or transfer ribonucleic acid (RNA) with 75 and 40% of the efficiencies, respectively, of the parent enzymes. The RNA strand of the hybrid substrate, phage f1 DNA-[3H]RNA, prepared from phage DNA with RNA polymerase, was hydrolyzed rapidly by the hybrid enzyme but was not hydrolyzed by RNase alone. A conjugate of the two enzymes offers the possibility in vivo of delivering two enzymes that differ in size, charge, and biological function to the same site at the same time.     

Purification and characterization of myofibril-bound serine protease from lizard fish (Saurida undosquamis) muscle

Myofibril-bound serine protease (MBSP) from lizard fish (SAURIDA UNDOSQUAMIS: Synodontidae) skeletal muscle was purified to homogeneity with higher purification (1260-fold) and higher recovery (7%) than our previous report in lizard fish (Saurida wanieso). The new purification method combines a heat-treatment for dissociation from washed myofibrils, acid-treatment at pH 5.0 before and after lyophilization, and alcohol-treatment, followed by two column chromatographies. The molecular mass of the enzyme was estimated to be 50 kDa under non-reducing conditions and 28 kDa under reducing conditions by SDS-PAGE. The N-terminal amino acid sequence of the MBSP was determined to be 22 residues (IVGGYEXEAYSKPYQVSINLGY) and the sequence showed high homology to carp and other fish trypsins (64-77%), but did not show high homology to carp MBSP (41%). The enzyme activity was inhibited by serine protease inhibitors such as Pefabloc SC, leupeptin, TLCK and native protein inhibitors (soybean trypsin inhibitor, alpha(1)-antitrypsin and aprotinin). The purified enzyme specifically hydrolyzed at the carboxyl side of the arginine residue of synthetic 4-methyl-coumaryl-7-amide substrate. When purified MBSP was stored at -35 degrees C in the presence of 50% ethylene glycol (V/V), the enzyme activity was entirely preserved over 6 months and stable against freezing and thawing. Activities for both casein and the synthetic substrate were most active at pH 9.0, and the enzyme was most active approximately 55 degrees C with casein and between 35 and 45 degrees C for synthetic substrate. When myofibrils were incubated with purified MBSP, myosin heavy chain was mostly degraded approximately 55 degrees C, but the degradation of actin was very slow.     

Thermolabile ribonucleases from antarctic psychrotrophic bacteria: detection of the enzyme in various bacteria and purification from Pseudomonas fluorescens

Abstract Thirteen terrestrial psychrotrophic bacteria from Antarctica were screened for the presence of a thermolabile ribonuclease (RNAase-HL). The enzyme was detected in three isolates of Pseudomonas fluorescens and one isolate of Pseudomonas syringae . It was purified from one P. fluorescens isolate and the molecular mass of the enzyme as determined by SDS-PAGE was 16 kDa. RNAase-HL exhibited optimum activity around 40°C at pH 7.4. It could hydrolyse Escherichia coli RNA and the synthetic substrates poly(A), poly(C), poly(U) and poly(A-U). Unlike the crude RNAase from mesophilic P. fluorescens and pure bovine pancreatic RNAase A which were active even at 65°C, RNAase-HL was totally and irreversibly inactivated at 65°C.     

A pyrimidine-guanine sequence-specific ribonuclease from Rana catesbeiana (bullfrog) oocytes.

A pyrimidine-guanine sequence-specific ribonuclease (RC-RNase) was purified from Rana catesbeiana (bullfrog) oocytes by sequential phosphocellulose, Sephadex G75, heparin Sepharose CL 6B and CM-Sepharose CL 6B column chromatography. The purified enzyme with molecular weight of 13,000 daltons gave a single band on SDS-polyacrylamide gel. One CNBr-cleaved fragment has a sequence of NVLSTTRFQLNT/TRTSITPR, which is identical to residues 59-79 of a sialic acid binding lectin from R. catesbeiana eggs, and is 71% homologous to residues 60-80 of an RNase from R. catesbeaina liver. The RC-RNase preferentially cleaved RNA at pyrimidine residues with a 3' flanking guanine under various conditions. The sequence specificity of RC-RNase was further confirmed with dinucleotide as substrates, which were analyzed by thin layer chromatography after enzyme digestion. The values of kcat/km for pCpG, pUpG and pUpU were 2.66 x 10(7) M-1s-1, 2.50 x 10(7) M-1s-1 and 2.44 x 10(6) M-1s-1 respectively, however, those for other phosphorylated dinucleotides were less than 2% of pCpG and pUpG. As compared to single strand RNA, double strand RNA was relatively resistant to RC-RNase. Besides poly (A) and poly (G), most of synthetic homo- and heteropolynucleotides were also susceptible to RC-RNase. The RC-RNase was stable in the acidic (pH 2) and alkaline (pH 12) condition, but could be inactivated by heating to 80 degrees C for 15 min. No divalent cation was required for its activity. Furthermore, the enzyme activity could be enhanced by 2 M urea, and inhibited to 50% by 0.12 M NaCl or 0.02% SDS.     

RNase I*, a form of RNase I, and mRNA degradation in Escherichia coli.

A previously unreported endoRNase present in the spheroplast fraction of Escherichia coli degraded homoribopolymers and small RNA oligonucleotides but not polymer RNA. Like the periplasmic endoRNase, RNase I, the enzyme cleaved the phosphodiester bond between any nucleotides; however, RNase I degraded polymer RNA as fast as homopolymers or oligomers. Both enzymes migrated as 27-kDa polypeptides by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and could not be separated by various chromatographic procedures. In rna insertion mutants, both enzymes were completely missing; the spheroplast enzyme is called RNase I*, since it must be a form of RNase I. The two forms could be distinguished by physical treatments. RNase I could be activated by Zn2+, while RNase I* was inactive in the presence of Zn2+. RNase I was inactivated very slowly at 100 degrees C over a wide pH range, while RNase I* was inactivated slowly by heat at pH 4.0 but much more rapidly as the pH was increased to 8.0. In the presence of a thiol-binding agent, the inactivation at the higher pH values was much slower. These results suggest that RNase I*, but not RNase I, has free sulfhydryl groups. RNase I* activity in the cell against a common substrate was estimated to be several times that of RNase I. All four 2',3'-phosphomonoribonucleotides were identified in the soluble pools of growing cells. Such degradative products must arise from RNase I* activity. The activity would be suited for the terminal step in mRNA degradation, the elimination of the final oligonucleotide fragments, without jeopardizing the cell RNA. An enzyme with very similar specificity was found in Saccharomyces cerevisiae, suggesting that the activity may be widespread in nature.     

Purification and characterization of a human urine ribonuclease (RNAase 1) showing genetic polymorphism

A ribonuclease (RNAase) was isolated and purified from the urine of a 45-year-old man by column chromatographies on DEAE-Sepharose CL-6B, cellulose phosphate and CM-cellulose followed by gel filtrations on Bio-Gel P-100 and Sephadex G-75, and finally to a homogeneous state by SDS-polyacrylamide gel electrophoresis. The enzyme was designated RNAase 1. It was possible to detect RNAase 1 isozymes in urine and serum without difficulty using isoelectric focusing electrophoresis followed by immunoblotting with a rabbit antibody specific to RNAase 1. The existence of genetic polymorphism of RNAase 1 was detected in human serum utilizing this technique (Yasuda, T. et al. (1988) Am. J. Hum. Genet., in press). RNAase 1 in serum and urine seemed to exist in multiple forms with regard to molecular weight and pI value. Genetically polymorphic RNAase 1 was a glycoprotein, containing three mannose, one fucose, four glucosamine and no sialic acid residues per molecule, with a molecular weight of 16,000 and 17,500 determined by gel filtration and SDS-polyacrylamide gel electrophoresis, respectively. The enzyme was most active at pH 7.0 on yeast RNA substrate and inhibited remarkably by Cu2+, Hg2+ and Zn2+. It also showed definite substrate preference for poly(C) and poly(U), but much less activity against poly(A) and poly(G). Thus, the enzyme is a pyrimidine-specific RNAase.     

Purification and characterization of ribonucleases from human seminal plasma.

Four ribonucleases (RNAases I-IV) have been purified to homogeneity from human seminal plasma by precipitation with 40-75%-satd. (NH4)2SO4, followed by chromatographies on concanavalin A-Sepharose 4B, DEAE-cellulose phosphocellulose, agarose-5'-(4-aminophenylphospho)uridine 2'(3')-phosphate (RNAase affinity column) and Sephadex G-75 or G-100. The homogeneity of these RNAases was confirmed by polyacrylamide-gel electrophoresis. Mr values for these purified RNAases were 78 000, 16 000, 13 300 and 5000 as estimated by gel filtration. Enzyme activities of RNAases I, III and IV were inhibited by Mn2+, Zn2+ and Cu2+ and activated by Na+, K+, Ba2+, Mg2+, Fe2+ and EDTA, whereas that of RNAase II was inhibited by Ba2+, Mg2+, Fe2+, Mn2+, Zn2+ and Cu2+ and activated by Na+, K+ and EDTA. RNAases I, II and IV demonstrated a higher affinity for poly(C) and poly(U) or yeast RNA, whereas RNAase III preferentially hydrolysed poly(U) over poly(C) and yeast RNA. In the presence of 5 mM-spermine, RNAase I was dissociated to a low-Mr (5000) enzyme with an increase in total RNAase enzymic activity. Xenoantiserum to each RNAase was raised and evaluated by immunoprecipitation and immunohistochemical methods. Anti-(seminal RNAase III) antiserum showed no immunological cross-reaction with RNAases of other human origin, whereas anti-(seminal RNAase I), -(RNAase II) and -(RNAase IV) antisera exhibited indistinguishable immunological reactions with serum RNAase and other human RNAases, except that anti-(seminal RNAase I) and -(RNAase antisera IV) did not react with pancreatic RNAases. Seminal RNAases I and IV were identical immunologically as shown by anti-(RNAase I) and anti-(RNAase IV) in immunodiffusion. Immunohistochemical study revealed that, among human tissues examined, only prostate expressed seminal RNAase III. These results suggested that human seminal RNAase I may be an aggregated molecule of RNAase IV and that seminal RNAases II and IV are similar to serum RNAases, whereas seminal RNAase III is a prostate-specific enzyme.     

Synthesis, characterization and properties of uridine 5′-(α-d-apio-d-furanosyl pyrophosphate)

1. A method was developed for synthesizing UDP-apiose [uridine 5'-(alpha-d-apio-d-furanosyl pyrophosphate)] from UDP-glucuronic acid [uridine 5'-(alpha-d-glucopyranosyluronic acid pyrophosphate)] in 62% yield with the enzyme UDP-glucuronic acid cyclase. 2. UDP-apiose had the same mobility as uridine 5'-(alpha-d-xylopyranosyl pyrophosphate) when chromatographed on paper and when subjected to paper electrophoresis at pH5.8. When [(3)H]UDP-[U-(14)C]glucuronic acid was used as the substrate for UDP-glucuronic acid cyclase, the (3)H/(14)C ratio in the reaction product was that expected if d-apiose remained attached to the uridine. In separate experiments doubly labelled reaction product was: (a) hydrolysed at pH2 and 100 degrees C for 15min; (b) degraded at pH8.0 and 100 degrees C for 3min; (c) used as a substrate in the enzymic synthesis of [(14)C]apiin. In each type of experiment the reaction products were isolated and identified and were found to be those expected if [(3)H]UDP-[U-(14)C]apiose was the starting compound. 3. Chemical characterization established that the product containing d-[U-(14)C]apiose and phosphate formed on alkaline degradation of UDP-[U-(14)C]apiose was alpha-d-[U-(14)C]apio-d-furanosyl 1:2-cyclic phosphate. 4. Chemical characterization also established that the product containing d-[U-(14)C]apiose and phosphate formed on acid hydrolysis of alpha-d-[U-(14)C]apio-d-furanosyl 1:2-cyclic phosphate was d-[U-(14)C]apiose 2-phosphate. 5. The half-life periods for the degradation of UDP-[U-(14)C]apiose to alpha-d-[U-(14)C]apio-d-furanosyl 1:2-cyclic phosphate and UMP at pH8.0 and 80 degrees C, at pH8.0 and 25 degrees C and at pH8.0 and 4 degrees C were 31.6s, 97.2min and 16.5h respectively. The half-life period for the hydrolysis of UDP-[U-(14)C]-apiose to d-[U-(14)C]apiose and UDP at pH3.0 and 40 degrees C was 4.67min. After 20 days at pH6.2-6.6 and 4 degrees C, 17% of the starting UDP-[U-(14)C]apiose was degraded to alpha-d-[U-(14)C]apio-d-furanosyl 1:2-cyclic phosphate and UMP and 23% was hydrolysed to d-[U-(14)C]apiose and UDP. After 120 days at pH6.4 and -20 degrees C 2% of the starting UDP-[U-(14)C]apiose was degraded and 4% was hydrolysed.     

Purification and characterization of cathepsin L-like proteinase from goat brain

Cathepsin L-like proteinase was purified approximately 1708-fold with 40% activity yield to an apparent electrophoretic homogeneity from goat brain by homogenization, acid-autolysis at pH 4.2, 30-80% (NH4)2SO4 fractionation, Sephadex G-100 column chromatography and ion-exchange chromatography on CM-Sephadex C-50 at pH 5.0 and 5.6. The molecular weight of proteinase was found to be approximately 65,000 Da, by gel-filtration chromatography. The pH optima were 5.9 and 4.5 for the hydrolysis of Z-Phe-Arg-4mbetaNA (benzyloxycarbonyl-L-phenylalanine-L-arginine-4-methoxy-beta-naphthylamide) and azocasein, respectively. Of the synthetic chromogenic substrates tested, Z-Phe-Arg-4mbetaNA was hydrolyzed maximally by the enzyme (Km value for hydrolysis was 0.06 mM), followed by Z-Val-Lys-Lys-Arg-4mbetaNA, Z-Phe-Val-Arg-4mbetaNA, Z-Arg-Arg-4mbetaNA and Z-Ala-Arg-Arg-4mbetaNA. The proteinase was activated maximally by glutathione in conjunction with EDTA, followed by cysteine, dithioerythritol, thioglycolic acid, dithiothreitol and beta-mercaptoethanol. It was strongly inhibited by p-hydroxymercuribenzenesulphonic acid, iodoacetic acid, iodoacetamide and microbial peptide inhibitors, leupeptin and antipain. Leupeptin inhibited the enzyme competitively with Ki value 44 x 10(-9) M. The enzyme was strongly inhibited by 4 M urea. Metal ions, Hg(2+), Ca(2+), Cu(2+), Li(2+), K(+), Cd(2+), Ni(2+), Ba(2+), Mn(2+), Co(2+) and Sn(2+) also inhibited the activity of the enzyme. The enzyme was stable between pH 4.0-6.0 and up to 40 degrees C. The optimum temperature for the hydrolysis of Z-Phe-Arg-4mbetaNA was approximately 50-55 degrees C with an activation energy Ea of approximately 6.34 KCal mole(-1).     

Influence of phosphate ligands in abolishing the conformational difference between ribonuclease A and its acid-denatured derivative.

The initial structural alteration of RNAase A due to acid denaturation (0.5 N HCl, 30 degrees C) that accompanies deamidation (without altering enzymic activity) has been dectected by spectrophotometric titration, fluorescence and ORD/CD measurements. It is shown that acid treated RNAase A has an altered conformation at neutral pH, 25 degrees C. This is characterized by the increased accessibility of buried tyrosine residue(s) towards the solvent. The most altered conformation of RNAase A is found in the 10 h acid-treated derivative. This has about 1.5 additional exposed tyrosine residues and a lesser amount of secondary structure than RNAase A. All three methods (titration, fluorescence and CD) established that the structural transition of RNAase A is biphasic. The first phase occurs within 1 h and the resulting subtle conformational change is constant up to 7 h. Following this, after the release of 0.55 mol of ammonia, the major conformational change begins. The altered conformation of the acid-denatured RNAase A could be reversed completely to the native state through a conformational change induced by substrate analogs like 2'- or 3'-CMP. Thus the monodeamidated derivative isolated from the acid-denatured RNAase A by phosphate is very similar to RNAase A in over-all conformation. The results suggest the possibility of flexibility in the RNAase A molecule that does not affect its catalytic activity, as probed through the tyrosine residues.     

Isolation and characterization of nucleases from a clinical isolate of Serratia marcescens kums 3958

Two new extracellular nucleases, nucleases SM1 and SM2, were purified from the culture fluid of S. marcescens kums 3958, a fresh clinical isolate. The purification was carried out by the following steps; ammonium sulfate precipitation, and DEAE-cellulose and Sephadex G-100 column chromatography. At the final step, nucleases SM1 and SM2 were purified about 3,700- and 1,000-fold, respectively. They were free from phosphomonoesterase and phosphodiesterase activities. The pIs were 8.1 and 7.5 for nucleases SM1 and SM2, respectively. The molecular weight was estimated to be 35,000 for both enzymes by SDS-polyacrylamide disc gel electrophoresis. The results of amino acid analyses showed that both the threonine and serine contents were higher in nuclease SM2 than in SM1. Furthermore, nuclease SM1 was more stable than nuclease SM2 at 4 degrees C. The other properties of the two enzymes were similar; pH optimum (8.0), Mg2+ or Mn2+ for activation, and inhibition by chemical reagents such as EDTA and pyrophosphate. No significant difference was found in base specificity between nucleases SM1 and SM2. Both enzymes specifically degraded double-stranded homopolymers, especially poly(I). poly(C), as well as yeast RNA and calf thymus DNA. They hardly degraded, however, single-stranded homopolymers such as poly(dA), poly(G), and poly(U).