Nature and possible origin of Human Serum ribonuclease

Human Serum contains an acidic RNase which is glycoprotein in nature. It is thermostable at pH 4.2 and thermolabile at pH 8.5. It has a pH optimum at 6.5. Its activity either on poly (C) or RNA is endonucleolytic and is absolutely dependent on citrate or phosphate. It exhibits highest preference for the secondary phosphate esters of cytidine 3′-phosphates. It has no action on cytidine 2′:3′-cyclic phosphate. Poly (A) and poly (G) are not only refractory to its action, but also inhibit its action on poly (C). Its rate of hydrolysis of Poly (U) is about 2% of that of poly (C). It differs from bovine pancreatic RNase. It is, however, similar to human pancreatic RNase suggesting that its primary source is pancreas.     

Human platelet ribonuclease

Human platelets contain an RNase which has a pH optimum at 5.0. It hydrolyzes the secondary phosphate esters of uridine 3′-phosphates. It slowly converts uridine 2′:3′-and cytidine 2′:3′-cyclic phosphates to their corresponding nucleoside 3′-phosphates. Poly (A), poly (G) and poly (C) are not only refractory to the action of this enzyme, but also inhibit its action on poly (U). It differs from human granulocyte RNase, human serum RNase and bovine pancreatic RNase. Because of its unique property, this enzyme could serve as a biochemical marker in disorders involving the platelet destruction.     

Human granulocyte ribonuclease.

Human granulocytes contain an RNase which is thermostable at pH 4.2 and thermolabile at pH 8.5. It has a pH optimum at 6.5. It exhibits highest preference for the secondary phosphate esters of uridine 3′-phosphates. It has no action on uridine 2′: 3′-cyclic phosphates. Poly (A) and poly (G) are inert to its action. Its rate of hydrolysis of poly (C) is about 1% of that of poly (U). It differs from bovine pancreatic RNase and human serum RNase. Because of its unique specificity, this enzyme might serve as a biochemical marker in certain granulocyte disorders.     

Purification and properties of a ribonuclease in human urine that hydrolyses polycytidylic acid.

Human urine RNase was purified about 2000-fold. The preparation is free from phosphatase, phosphodiesterase and DNase activities. On electrophoresis through polyacrylamide gel at pH 8.3, it migrates toward the anode and stains with periodic acid-Schiff reagent, suggesting that it is acidic and glycoprotein in nature. Its isoelectric point is at pH 4.1. It has a molecular weight of about 21,500. It is thermostable at pH 4.2 and thermolabile at pH 8.5. It has a pH optimum at 6.5. It exhibits highest preference for cytidine 3'-phosphate linkages. Its activity on poly (C) is endonucleolytic. It cleaves poly (C) via intramolecular transphosphorylation. It has no action on cytidine 2': 3'-cyclic phosphate or uridine 2':3'-cyclic phosphate. Its rate of hydrolysis of poly (U) is less than 2% of that of poly C). Poly (A) and poly (G) are totally inert to its action. Its action on poly (C) is inhibited by poly (G), poly (A) and poly (U). It differs from bovine pancreatic Rnase A in its physical, chemical and catalytic properties. It is, however, similar to human serum and pancreatic RNase in all its properties, suggesting that pancreas is its likely source.     

Computer Modelling Studies on the Mechanism of Action of Ribonuclease T1

Abstract

The mechanism of action of ribonuclease (RNase) T₁ is still a matter of considerable debate as the results of x-ray, 2-D nmr and site-directed mutagenesis studies disagree regarding the role of the catalytically important residues. Hence computer modelling studies were carried out by energy minimisation of the complexes of RNase T₁ and some of its mutants (His40Ala, His40Lys, and Glu58Ala) with the substrate guanyl cytosine (GpC), and of native RNase T₁ with the reaction intermediate guanosine 2′, 3′-cyclic phosphate (G>p). The puckering of the guanosine ribose moiety in the minimum energy conformer of the RNase T₁ - GpC (substrate) complex was found to be O4′-endo and not C3′-endo as in the RNase T₁ - 3′-guanylic acid (inhibitor/product) complex. A possible scheme for the mechanism of action of RNase T₁ has been proposed on the basis of the arrangement of the catalytically important amino acid residues His40, Glu58, Arg77, and His92 around the guanosine ribose and the phosphate moiety in the RNase T₁ - GpC and RNase T₁ - G>p complexes. In this scheme, Glu58 serves as the general base group and His92 as the general acid group in the transphosphorylation step. His40 may be essential for stabilising the negatively charged phosphate moiety in the enzyme-transition state complex.     

Purification and properties of an endoribonuclease existing as a complex with inhibitor in rat liver cytosol

An endoribonuclease existing as a complex with inhibitor in the cytosol of rat liver has been purified about 128,000-fold after inactivation of the inhibitor with CdCl2. The enzyme had a molecular weight of 16,000 and produced 3'-CMP via 2',3'-cyclic phosphate of cytidine from poly(C). The breakdown of poly(U) by the enzyme was less than 5% of poly(C) breakdown. Poly(A) was not hydrolyzed by the enzyme. The enzyme had a pH optimum of 7.5-8, was heat-stable and had a Km of 952 micrograms yeast RNA and a Km of 198 micrograms poly(C) per ml. The maximal velocities for yeast RNA and poly(C) degradation were 3,970 A260/min/mg protein and 1,890 A260/min/mg protein, respectively. The enzyme was slightly stimulated by polyamines or monovalent and divalent cations except Mn2+, but was inhibited by nucleoside triphosphate, poly(G) and rat liver RNase inhibitor. Inhibition of the enzyme by rat liver RNase inhibitor was not prevented by monovalent and divalent cations or polyamines, although inhibition by poly(G) was prevented by these ions.     

Ribonuclease in Bovine Milk

The RNase (EC 2.7.7.16) in bovine milk was partially purified from milk whey. The basic properties and the hydrolyzing specificity of this enzyme were studied. This enzyme was heat stable. When RNA was used as the substrate, the pH optimum was 7.5 and 3′- nucleotides were produced, but the extent of the hydrolysis stopped at 31 per cent and core was left. C! and U! were hydrolyzed but purine cyclic nucleotides were not. Poly U was digested to 3′-uridylic acid passing through U! but poly A was not. These properties are quite similar to pancreatic RNase.     

Ternary borate–nucleoside complex stabilization by ribonuclease A demonstrates phosphate mimicry

Phosphate esters play a central role in cellular energetics, biochemical activation, signal transduction and conformational switching. The structural homology of the borate anion with phosphate, combined with its ability to spontaneously esterify hydroxyl groups, suggested that phosphate ester recognition sites on proteins might exhibit significant affinity for nonenzymatically formed borate esters. ¹¹B NMR studies and activity measurements on ribonuclease A (RNase A) in the presence of borate and several cytidine analogs demonstrate the formation of a stable ternary RNase A·3′-deoxycytidine–2′-borate ternary complex that mimics the complex formed between RNase A and a 2′-cytidine monophosphate (2′-CMP) inhibitor. Alternatively, no slowly exchanging borate resonance is observed for a ternary RNase A, borate, 2′-deoxycytidine mixture, demonstrating the critical importance of the 2′-hydroxyl group for complex formation. Titration of the ternary complex with 2′-CMP shows that it can displace the bound borate ester with a binding constant that is close to the reported inhibition constant of RNase A by 2′-CMP. RNase A binding of a cyclic cytidine-2′,3′-borate ester, which is a structural homolog of the cytidine-2′,3′-cyclic phosphate substrate, could also be demonstrated. The apparent dissociation constant for the cytidine-2′,3′-borate·RNase A complex is 0.8 mM, which compares with a Michaelis constant of 11 mM for cytidine-2′,3′-cyclic phosphate at pH 7, indicating considerably stronger binding. However, the value is 1,000-fold larger than the reported dissociation constant of the RNase A complex with uridine–vanadate. These results are consistent with recent reports suggesting that in situ formation of borate esters that mimic the corresponding phosphate esters supports enzyme catalysis.     

A novel ribonuclease with antiproliferative activity from fresh fruiting bodies of the edible mushroom Hypsizigus marmoreus

An 18-kDa ribonuclease (RNase) with a novel N-terminal sequence was purified from fresh fruiting bodies of the mushroom Hypsizigus marmoreus. The purification protocol comprised ion exchange chromatography on DEAE cellulose, affinity chromatography on Affi-gel blue gel, ion exchange chromatography on CM-cellulose and Q-Sepharose and gel filtration by fast protein liquid chromatography on Superdex 75. The starting buffer was 10 mM Tris-HCl buffer (pH 7.2), 10 mM Tris-HCl buffer (pH 7.2), 10 mM NH(4)OAc buffer (pH 5), 10 mM NH(4)HCO(3) buffer (pH 9.4) and 200 mM NH(4)HCO(3) (pH 8.5), respectively. Absorbed proteins were desorbed using NaCl added to the starting buffer. A 42-fold purification of the enzyme was achieved. The RNase was unadsorbed on DEAE cellulose, Affi-gel blue gel and CM-cellulose but adsorbed on Q-Sepharose. It exhibited maximal RNase activity at pH 5 and 70 degrees C. Some RNase activity was detectable at 100 degrees C. It demonstrated the highest ribonucleolytic activity (196 U/mg) toward poly C, the next highest activity (126 U/mg) toward poly A, and much weaker activity toward poly U (48 U/mg) and poly G (41 U/mg). The RNase inhibited [(3)H-methyl]-thymidine uptake by leukemia L1210 cells with an IC(50) of 60 microM.     

12 S small nuclear ribonucleoprotein-associated acidic and pyrimidine-specific endoribonuclease from calf thymus and L5178y cells

12 S ribonucleoprotein (RNP) particles were separated from a 45 S RNP complex (Bachmann, M., Zahn, R.K. and Müller, W.E.G. (1983) J. Biol. Chem. 258, 7033–7040) isolated from calf thymus and L5178y cells. The particles were determined to be associated with an acidic endoribonuclease (pI 4.1; pH optimum 6.2). the enzyme requires Mg²⁺ and is sensitively inhibited by higher NaCl concentrations. The nuclease specifically degrades poly(U) and poly(C) in an endonucleolytic manner; the end-products are 3′-UMP (85%) and 2′,3′-cyclic UMP (12%). Poly(A) strongly inhibits the pI 4.1 endoribonuclease activity. The Michaelis constant (for poly(U)) was determined as 82 μM and the maximal reaction velocity was 0.54 μmol/μg per h. The endoribonuclease is distinguished from the known pyrimidine-specific ribonucleases (pancreatic ribonuclease and endoribonuclease VII) by further criteria, e.g., resistance to thiol reagents, inhibition by EDTA, Mg²⁺ requirement, pI and pH optimum. Using the techniques of counterimmunoelectrophoresis and immunoaffinity column chromatography it was shown that the pI 4.1 endoribonuclease-associated 12 S RNP particles display antigenicity to anti-Sm and anti-(U1)-RNP antibodies. An RNA component, isolated from the 12 S-45 S hypercomplex, was identified as U1-snRNA.     

New sequence-specific human ribonuclease: purification and properties.

A new sequence-specific RNase was isolated from human colon carcinoma T84 cells. The enzyme was purified to electrophoretical homogeneity by pH precipitation, HiTrapSP and Superdex 200 FPLC. The molecular weight of the new enzyme, which we have named RNase T84, is 19 kDa. RNase T84 is an endonuclease which generates 5'-phosphate-terminated products. The new RNase selectively cleaved the phosphodiester bonds at AU or GU steps at the 3' side of A or G and the 5' side of U. 5'AU3' or 5'GU3' is the minimal sequence required for T84 RNase activity, but the rate of cleavage depends on the sequence and/or structure context. Synthetic ribohomopolymers such as poly(A), poly(G), poly(U) and poly(C) were very poorly hydrolysed by T84 enzyme. In contrast, poly(I) and heteroribopolymers poly(A,U) and poly(A,G,U) were good substrates for the new RNase. The activity towards poly(I) was stronger in two colon carcinoma cell lines than in three other epithelial cell lines. Our results show that RNase T84 is a new sequence-specific enzyme whose gene is abundantly expressed in human colon carcinoma cell lines.     

Studies on the restoration of the activities of Ribonucleases by polyamines in the presence of various ribonuclease inhibitors.

The effect of polyamines on ribonucleases in the presence of various inhibitors (poly(G), heparin, and rat liver RNase inhibitor) has been studied. Bovine pancreatic RNas A and a ribonuclease from horse submaxillary gland (RNase HS) were inhibited by the inhibitors, but RNase T1 and RNase M were not inhibited. Polyamines were found to restore the activites of RNase A and RNase HS inhibited by poly(G) or heparin but not those activities inhibited by rat liver RNase inhibitor. When poly(U) and poly(C) were used as substrates, the inhibitory effects of poly(G) and heparin were greater with poly(U) than poly(C) as a substrate. However, when poly(C) was used as a substrate in the presence of either of the above inhibitors, the restoration of RNase activity by sperimine was more efficient. In fact, a stimulatory effect was observed. From the double-reciprocal plots, it was concluded that polyamines restored the activiities of RNases by increasing the availability of the substrate and enzyme to each other. The restoration of enzyme activity by polyamines occurred through the binding of the polyamines to the inhibitor and the subsequent release of enzyme from the inhibitor.     

The crystal structure of ribonuclease A in complex with thymidine‐3′‐monophosphate provides further insight into ligand binding

Thymidine‐3′‐monophosphate (3′‐TMP) is a competitive inhibitor analogue of the 3′‐CMP and 3′‐UMP natural product inhibitors of bovine pancreatic ribonuclease A (RNase A). Isothermal titration calorimetry experiments show that 3′‐TMP binds the enzyme with a dissociation constant (K_d) of 15 μM making it one of the strongest binding members of the five natural bases found in nucleic acids (A, C, G, T, and U). To further investigate the molecular properties of this potent natural affinity, we have determined the crystal structure of bovine pancreatic RNase A in complex with 3′‐TMP at 1.55 Å resolution and we have performed NMR binding experiments with 3′‐CMP and 3′‐TMP. Our results show that binding of 3′‐TMP is very similar to other natural and non‐natural pyrimidine ligands, demonstrating that single nucleotide affinity is independent of the presence or absence of a 2′‐hydroxyl on the ribose moiety of pyrimidines and suggesting that the pyrimidine binding subsite of RNase A is not a significant contributor of inhibitor discrimination. Accumulating evidence suggests that very subtle structural, chemical, and potentially motional variations contribute to ligand discrimination in this enzyme. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Ribonuclease, cell-free translation-inhibitory and superoxide radical scavenging activities of the iron-binding protein lactoferrin from bovine milk

The purpose of this study was to characterize the ribonuclease (RNase) and cell-free translation-inhibitory activities of lactoferrin isolated from bovine milk. It was found that bovine lactoferrin exhibited ribonucleolytic activity toward yeast transfer RNA in a dose-dependent manner. The pH optimum for this RNase activity was in the vicinity of 7.5. Lactoferrin exerted RNase activity on poly C with an activity of 2.15 U/mg. No activity was detected toward poly A, poly G, and poly U. The milk protein inhibited cell-free translation in rabbit reticulocyte lysate with an IC50 of 9.6 microM. The protein was devoid of N-glycosidase activity characteristic of ribosome inactivating proteins which also possess RNase and cell-free translation-inhibitory activities. It inhibited superoxide radical formation.     

Purification and characterization of a new ribonuclease from fruiting bodies of the oyster mushroom Pleurotus ostreatus.

A ribonuclease (RNase), possessing an N-terminal sequence disparate from those of ribonucleases from other mushrooms and previously isolated Pleuotus ostreatus RNases, was purified from the fruiting bodies of the edible mushroom Pleurotus ostreatus. The N-terminal sequence of Pleurotus ostreatus RNase did not manifest homology even to a previously reported RNase from the same mushroom. The ribonuclease was adsorbed on CM-Sepharose and Mono S. It exhibited a molecular mass of 12 kDa in both sodium dodecyl sulphate-polyacrylamide gel electrophoresis and gel filtration on Superdex 75. The ribonuclease displayed an activity of 11490 U/mg on yeast tRNA. The highest ribonuclease activity was exhibited toward poly U, followed by poly A and poly C. No activity was shown toward poly G. The optimal pH for its activity was 7 and the optimal temperature was 55 degrees C. It inhibited cell-free translation in a rabbit reticulocyte lysate with an IC50 of 240 nM.     

Inhibition and Substrate Competition Kinetics in Analysis of Porcine Thyroid Alkaline Ribonuclease's Specificity Toward Synthetic Rna's and Trna

Abstract

Inhibition and substrate competition kinetics demonstrated that tRNA is a highly preferred substrate of thyroid alkaline RNase. The pyrimidine-specific RNase cleaved poly(C) 2.8 × 10⁵ faster than poly(U). k_cat: K_M ratios for tRNA and poly(C) based on molecular weights failed to predict preference when both were present. Competition experiments between poly(C) and tRNA revealed tRNA was a tight-binding competing substrate and the cytidylate residues in the 3prime;-CCA terminus of tRNA were preferred about 280: 1 over those in poly(C). Poly(U) was competitive with tRNA. When poly(C) was the substrate, inhibition type by poly(G) depended on poly(G) concentration. Neither tRNA lacking its 3prime; terminal cytidylyl(3prime;-5prime;)adenosine and terminating in a 2prime;:3prime; cCMP residue, tRNA lacking its 3prime; terminal 5prime;AMP residue, guanosine, nor guanylyl(3prime;-5prime;)guanylyl(3prime;-5prime;)guanosine were inhibitors. Product inhibition by adenosine and 2prime;:3prime; cCMP showed the kinetic mechanism for cleavage of tRNA was ordered uni bi.     

A ribonuclease from the wild mushroom Boletus griseus

A ribonuclease (RNase) with a molecular mass of 29 kDa and cospecific for poly A and poly U was isolated from fruiting bodies of the mushroom Boletus griseus. Its N-terminal sequence exhibited some similarity to those of RNases from the mushrooms Irpex lacteus and Lentinus edodes. The RNase was adsorbed on diethylaminoethyl-cellulose, Q-Sepharose, and Affi-gel blue gel and was unadsorbed on CM-cellulose. The enzyme exhibited a temperature optimum between 60 and 70°C and a pH optimum at 3.5.     

Rp-phosphorothioate modifications in RNase P RNA that interfere with tRNA binding.

We have used Rp-phosphorothioate modifications and a binding interference assay to analyse the role of phosphate oxygens in tRNA recognition by Escherichia coli ribonuclease P (RNase P) RNA. Total (100%) Rp-phosphorothioate modification at A, C or G positions of RNase P RNA strongly impaired tRNA binding and pre-tRNA processing, while effects were less pronounced at U positions. Partially modified E. coli RNase P RNAs were separated into tRNA binding and non-binding fractions by gel retardation. Rp-phosphorothioate modifications that interfered with tRNA binding were found 5' of nucleotides A67, G68, U69, C70, C71, G72, A130, A132, A248, A249, G300, A317, A330, A352, C353 and C354. Manganese rescue at positions U69, C70, A130 and A132 identified, for the first time, sites of direct metal ion coordination in RNase P RNA. Most sites of interference are at strongly conserved nucleotides and nine reside within a long-range base-pairing interaction present in all known RNase P RNAs. In contrast to RNase P RNA, 100% Rp-phosphorothioate substitutions in tRNA showed only moderate effects on binding to RNase P RNAs from E. coli, Bacillus subtilis and Chromatium vinosum, suggesting that pro-Rp phosphate oxygens of mature tRNA contribute relatively little to the formation of the tRNA-RNase P RNA complex.     

Ribonuclease L and metal-ion–independent endoribonuclease cleavage sites in host and viral RNAs

Ribonuclease L (RNase L) is a metal-ion–independent endoribonuclease associated with antiviral and antibacterial defense, cancer and lifespan. Despite the biological significance of RNase L, the RNAs cleaved by this enzyme are poorly defined. In this study, we used deep sequencing methods to reveal the frequency and location of RNase L cleavage sites within host and viral RNAs. To make cDNA libraries, we exploited the 2′, 3′-cyclic phosphate at the end of RNA fragments produced by RNase L and other metal-ion–independent endoribonucleases. We optimized and validated 2′, 3′-cyclic phosphate cDNA synthesis and Illumina sequencing methods using viral RNAs cleaved with purified RNase L, viral RNAs cleaved with purified RNase A and RNA from uninfected and poliovirus-infected HeLa cells. Using these methods, we identified (i) discrete regions of hepatitis C virus and poliovirus RNA genomes that were profoundly susceptible to RNase L and other single-strand specific endoribonucleases, (ii) RNase L-dependent and RNase L-independent cleavage sites within ribosomal RNAs (rRNAs) and (iii) 2′, 3′-cyclic phosphates at the ends of 5S rRNA and U6 snRNA. Monitoring the frequency and location of metal-ion–independent endoribonuclease cleavage sites within host and viral RNAs reveals, in part, how these enzymes contribute to health and disease.