A ribonuclease from human seminal plasma active on double-stranded RNA

A ribonuclease, active on single- and double-stranded RNAs, has been isolated from human seminal plasma 3-5 micrograms of enzyme were recovered per ml of seminal plasma, equivalent to 71% of total activity and a 2500-fold purification (measured with poly(A) X poly(U) as substrate) from the initial dialyzed material. Similar amounts of RNAase were found per g (wet weight) of human prostate, where the enzyme appears to be produced. Human seminal RNAase degrades poly(U) 3-times faster than poly(A) X poly(U), and poly(C) or viral single-stranded RNA about 10-times faster than poly(U). Degradation of poly(A) X poly(U), viral double-stranded RNA, and poly(A) by human seminal RNAase is 500-, 380- and 140-times more efficient, respectively, than by bovine RNAase A. The enzyme, a basic protein with maximum absorbance at 276 nm, occurs in two almost equivalent forms, one of which is glycosylated. Mr values of the glycosylated and non-glycosylated form are 21000 and 16000, respectively. The amino-acid composition of the RNAase is very similar to that of human pancreatic RNAase. The same is true for the carbohydrate content of its glycosylated form.     

The action of ribonuclease T1 on reovirus double-stranded RNA.

A small number of nucleotides are released from highly purified reovirus double-stranded RNA by ribonuclease T₁ in the presence of 0.3 m NaCl. These nucleotides include ppGp, which is quantitatively released from the RNA, and lesser amounts of ApUpGp, Gp, and ApGp. The same products are released from each of the three size classes of double-stranded RNA segments. In experiments involving specific labeling of termini, the only demonstrable sites of hydrolysis were at the 5′ termini of the minus strands. The limited extent of ribonuclease T₁ hydrolysis and localization of its action at the 5′ termini of the minus strands are compatible with a perfect duplex structure for the double-stranded RNA segments wherein the secondary structure of the termini is less stable than that of internal regions.     

Interferon-gamma activates the cleavage of double-stranded RNA by bovine seminal ribonuclease

Bovine seminal ribonuclease (BS-RNase), a dimeric homologue of RNase A, cleaves both single- and double-stranded RNA and inhibits the growth of tumor cells. Its catalytic activity against double-stranded RNA, either homopolymeric ([3H]polyA/polyU) or mixed sequence, is enhanced by bovine or human recombinant interferon-gamma (IFN-gamma). Activation is seen with as little as 4-10 interferon units per assay. Enhancing the degradation of double-stranded RNA, an intermediate in the growth cycle of many viruses, could contribute to IFN-gamma's ability to control cell growth and induce an antiviral state.     

Revisiting the action of bovine ribonuclease A and pancreatic-type ribonucleases on double-stranded RNA

Single-strand-preferring ribonucleases of the pancreatic type, structurally and/or catalytically similar to bovine RNase A but endowed with a higher protein basicity, are able to degrade double-stranded RNA (dsRNA) or DNA: RNA hybrids under standard assay conditions (0.15 M NaCl, 0.015 M sodium citrate, pH 7), where RNase A is inactive. This enzyme too, however, becomes quite active if assay conditions are slightly modified or its basicity is increased (polyspermine-RNase). In the attempt to review these facts, we have analyzed and discussed the role that in the process have the secondary structure of dsRNA as well as other variables whose influence has come to light in addition to that of the basicity of the enzyme protein, i.e., the ionic strength, the presence of carbohydrates on the RNase molecule, and the structure (monomeric or dimeric) of the enzyme. A possible mechanism by which dsRNAs are attacked by pancreatic-type RNases has been proposed.Abbreviations RNase Ribonuclease - dsRNA Double-stranded RNA - ssRNA Single-stranded RNA - poly(A) poly(U), poly(I) : poly(C) Double-stranded Homopolymers formed between Polyadenylate and Polyurydilate, and Polyinosinate and Polycytidylate, respectively - poly(dA): poly (rU) Double-stranded complex formed between Polydeoxyriboadenylate and Polyribouridylate - poly(A), poly(C) Polyadenylate and Polycytidylate, respectively - poly[d(A-T)] Double-stranded Homopolymers formed between Polydeoxyriboadenilate and Polydeoxyribothymidylate - poly(dA-dT) : poly (dA-dT) Double-stranded alternating copolymers - SSC 0.15 M Sodium Chloride, 0.015 M Sodium Citrate pH 7     

Degradation of double-stranded RNA by human pancreatic ribonuclease: crucial role of noncatalytic basic amino acid residues

Under physiological salt conditions double-stranded (ds) RNA is resistant to the action of most mammalian extracellular ribonucleases (RNases). However, some pancreatic-type RNases are able to degrade dsRNA under conditions in which the activity of bovine RNase A, the prototype of the RNase superfamily, is essentially undetectable. Human pancreatic ribonuclease (HP-RNase) is the most powerful enzyme to degrade dsRNA within the tetrapod RNase superfamily, being 500-fold more active than the orthologous bovine enzyme on this substrate. HP-RNase has basic amino acids at positions where RNase A shows instead neutral residues. We found by modeling that some of these basic charges are located on the periphery of the substrate binding site. To verify the role of these residues in the cleavage of dsRNA, we prepared four variants of HP-RNase: R4A, G38D, K102A, and the triple mutant R4A/G38D/K102A. The overall structure and active site conformation of the variants were not significantly affected by the amino acid substitutions, as deduced from CD spectra and activity on single-stranded RNA substrates. The kinetic parameters of the mutants with double-helical poly(A).poly(U) as a substrate were determined, as well as their helix-destabilizing action on a synthetic DNA substrate. The results obtained indicate that the potent activity of HP-RNase on dsRNA is related to the presence of noncatalytic basic residues which cooperatively contribute to the binding and destabilization of the double-helical RNA molecule. These data and the wide distribution of the enzyme in different organs and body fluids suggest that HP-RNase has evolved to perform both digestive and nondigestive physiological functions.     

Interferon-γ activates the cleavage of double-stranded RNA by bovine seminal ribonuclease

Bovine seminal ribonuclease (BS-RNase), a dimeric homologue of RNase A, cleaves both single- and double-stranded RNA and inhibits the growth of tumor cells. Its catalytic activity against double-stranded RNA, either homopolymeric ([³H]polyA/polyU) or mixed sequence, is enhanced by bovine or human recombinant interferon-γ (IFN-γ). Activation is seen with as little as 4–10 interferon units per assay. Enhancing the degradation of double-stranded RNA, an intermediate in the growth cycle of many viruses, could contribute to IFN-γ's ability to control cell growth and induce an antiviral state.     

HnRNP from HeLa cells contain a ribonuclease active on double-stranded RNA.

A ribonuclease D, i-e acting against double-stranded RNA structures like poly r(AU), was identified in ribonucleoprotein structures containing the heterogenous nuclear RNA (hnRNP) from HeLa cells. This activity could not however be detected in intact hnRNP but only after passage through a DEAE-cellulose column or digestion by a combination of ribonucleases A+T₁. This enzyme does not degrade poly r(A)-poly d(T) nor poly r(A), nor does it yield mononucleotides, excluding the possibility of a non-specific exonuclease type of activity like phosphodiesterase. It is inhibited by ethidium bromide and double-stranded RNA and resembles in all respects so far investigated the ribonuclease D previously isolated from Krebs cells by Rech et al (Nucl. Acids Res. 1976, 3, 2055–2065).     

Antitumor action of seminal ribonuclease, its dimeric structure, and its resistance to the cytosolic ribonuclease inhibitor

Bovine seminal RNase (BS-RNase) is a homodimeric enzyme with a cytotoxic activity selective for tumor cells. In this study, the relationships of its cytotoxic activity to its dimeric structure and its resistance to the cytosolic RNase inhibitor (cRI) are investigated systematically by site-directed mutagenesis. The results show that (1) the dimericity of BS-RNase is essential for its full cytotoxic action; (2) the role of the dimeric structure in the antitumor activity is that of making the enzyme insensitive to the cytosolic RNase inhibitor; (3) a RNase may not be completely insensitive to cRI to exploit a full cytotoxic potential.     

Crystal structure of a hybrid between ribonuclease A and bovine seminal ribonuclease--the basic surface, at 2.0 A resolution.

A variant of bovine pancreatic ribonuclease A has been prepared with seven amino acid substitutions (Q55K, N62K, A64T, Y76K, S80R, E111G, N113K). These substitutions recreate in RNase A the basic surface found in bovine seminal RNase, a homologue of pancreatic RNase that diverged some 35 million years ago. Substitution of a portion of this basic surface (positions 55, 62, 64, 111 and 113) enhances the immunosuppressive activity of the RNase variant, activity found in native seminal RNase, while substitution of another portion (positions 76 and 80) attenuates the activity. Further, introduction of Gly at position 111 has been shown to increase the catalytic activity of RNase against double-stranded RNA. The variant and the wild-type (recombinant) protein were crystallized and their structures determined to a resolution of 2.0 A. Each of the mutated amino acids is seen in the electron density map. The main change observed in the mutant structure compared with the wild-type is the region encompassing residues 16-22, where the structure is more disordered. This loop is the region where the polypeptide chain of RNase A is cleaved by subtilisin to form RNase S, and undergoes conformational change to allow residues 1-20 of the RNase to swap between subunits in the covalent seminal RNase dimer.     

A small RNA that complements mutants in the RNA processing enzyme ribonuclease P

Four temperature-sensitive RNase P mutants were analyzed for the accumulation of 10 S RNA. In the 10 S region of the polyacrylamide gel two molecules appear, a and b. While the level of 10 Sa seems to be affected in some of the mutants, the 10 Sb molecule was not found in rnpB mutants. A plasmid (pL2), which contains Escherichia coli DNA sequences that complement, at least partially, rnp mutations, directs the synthesis of 10 Sb RNA. The presence of the pL2 plasmid complements the rnpA49, rnpB3187 and the rnpC241 mutations, as revealed by colony formation at “non-permissive” temperatures. However, the complementation of the rnpA49 mutation is much better than that of the other mutations. The complementation can also be measured by the increased level of RNase P activity in extracts. 10 Sa and b RNAs are unique among all RNAs tested thus far, since they are stable during exponential growth at 30 °C and 37 °C. However, at higher temperatures, such as 43 °C, the molecules are somewhat less stable, and they become rather labile when RNA synthesis is blocked by rifampicin. Structural analysis revealed that the 10 Sa and 10 Sb RNA molecules have dissimilar sequences.     

A double-stranded RNA degrading enzyme reduces the efficiency of oral RNA interference in migratory locust

Application of RNA interference (RNAi) for insect pest management is limited by variable efficiency of RNAi in different insect species. In Locusta migratoria, RNAi is highly efficient through injection of dsRNA, but oral delivery of dsRNA is much less effective. Efforts to understand this phenomenon have shown that dsRNA is more rapidly degraded in midgut fluid than in hemolymph due to nuclease enzyme activity. In the present study, we identified and characterized two full-length cDNAs of double-stranded RNA degrading enzymes (dsRNase) from midgut of L. migratoria, which were named LmdsRNase2 and LmdsRNase3. Gene expression analysis revealed that LmdsRNase2 and LmdsRNase3 were predominantly expressed in the midgut, relatively lower expression in gastric caeca, and trace expression in other tested tissues. Incubation of dsRNA in midgut fluid from LmdsRNase3-suppressed larvae or control larvae injected with dsGFP resulted in high levels of degradation; however, dsRNA incubated in midgut fluid from LmdsRNase2-suppressed larvae was more stable, indicating LmdsRNase2 is responsible for dsRNA degradation in the midgut. To verify the biological function of LmdsRNase2 in vivo, nymphs were injected with dsGFP, dsLmdsRNase2 or dsLmdsRNase3 and chitinase 10 (LmCht10) or chitin synthase 1 (LmCHS1) dsRNA were orally delivered. Mortality associated with reporter gene knockdown was observed only in locusts injected with dsLmdsRNase2 (48% and 22%, for dsLmCht10 and dsLmCHS1, respectively), implicating LmdsRNase2 in reducing RNAi efficiency. Furthermore, recombinantly expressed LmdsRNase2 fusion proteins degraded dsRNA rapidly, whereas LmdsRNase3 did not. These results suggest that rapid degradation of dsRNA by dsRNase2 in the midgut is an important factor causing low RNAi efficiency when dsRNA is orally delivered in the locust.     

Structure and stability of the non-covalent swapped dimer of bovine seminal ribonuclease: an enzyme tailored to evade ribonuclease protein inhibitor

A growing number of pancreatic-type ribonucleases (RNases) present cytotoxic activity against malignant cells. The cytoxicity of these enzymes is related to their resistance to the ribonuclease protein inhibitor (RI). In particular, bovine seminal ribonuclease (BS-RNase) is toxic to tumor cells both in vitro and in vivo. BS-RNase is a covalent dimer with two intersubunit disulfide bridges between Cys(31) of one chain and Cys(32) of the second and vice versa. The native enzyme is an equilibrium mixture of two isomers, MxM and M=M. In the former the two subunits swap their N-terminal helices. The cytotoxic action is a peculiar property of MxM. In the reducing environment of cytosol, M=M dissociates into monomers, which are strongly inhibited by RI, whereas MxM remains as a non-covalent dimer (NCD), which evades RI. We have solved the crystal structure of NCD, carboxyamidomethylated at residues Cys(31) and Cys(32) (NCD-CAM), in a complex with 2'-deoxycitidylyl(3'-5')-2'-deoxyadenosine. The molecule reveals a quaternary structural organization much closer to MxM than to other N-terminal-swapped non-covalent dimeric forms of RNases. Model building of the complexes between these non-covalent dimers and RI reveals that NCD-CAM is the only dimer equipped with a quaternary organization capable of interfering seriously with the binding of the inhibitor. Moreover, a detailed comparative structural analysis of the dimers has highlighted the residues, which are mostly important in driving the quaternary structure toward that found in NCD-CAM.     

Unaltered stability of newly synthesized RNA in strains of Escherichia coli missing a ribonuclease specific for double-stranded RNA

Pairs of very closely related Escherichia coli strains were prepared, one having the wild-type allele for ribonuclease III, an enzyme which specifically degrades double-stranded RNA, and the other having a mutant RNase III allele. Growth and phage plating efficiency were compared in these strains. The RNase III+ strains grow better than the RNase III- strains and plate T7 and lambda phage better, but T4 plates with the same efficiency on both strains. On the other hand, the half lives of newly synthesized RNA as well as of functional beta-galactosidase mRNA are similar in both kind of strains. These two parameters, however, are significantly longer in both strains as compared to the original strain from which they were derived. Also, no difference in the differential induction of beta-galactosidase was observed between such strains. Thus, we have to conclude that either ribonuclease III does not play a significant role in the functioning and stability of newly synthesized mRNA, or that enough enzymatic activity was left, residual RNase III or some other enzyme to deal with double-stranded regions in the message.     

Studies on the state of tyrosyl residues in a ribonuclease from seminal vesicles.

In order to study the state of tyrosyl residues in a ribouuclease from bovine semina vesicles [EC 3.1.4.22, RNase Vs1] several lines of experiments were carried out. Spectrophotometric titration of RNase Vs1 indicated that two out of 8 tyrosine residues were titrated very easily and their apparent pKa values were about 9.8. Next, about 4 residues were titrated at pH up to 13.5. The remaining 2 residues were titrated time-dependently at pH 13.5. In 8 M urea, about 6 tyrosine residues were titrated with apparent pK4 values of about 11.2 and about 2 residues were titrated time-dependently at pH 13.5. Acetylation of RNase Vs1 with N-acetylimidazole was studied at pH 7.5. In aqueous solution, about 1.1-3.5 tyrosine residues were acetylated, depending on the experimental conditions, and in 8 M urea, 5.3 tyrosine residues were modified. RNase Vs1 was nitrated with tetranitromethane at pH 7.5. In aqueous solution, about 2.5 tyrosine residues were nitrated very easily; the enzymatic activity of the modified enzymes was 130-200% of that of the native enzyme. In 8 M urea, the reactivity of the tyrosine residues increased and about 4-5.5 residues were modified. The results of chemical modification and spectrophotometric titration indicated that about two tyrosine residues in RNase Vs1 were exposed to the solvent and were more reactive to various reagents, and 3-4 tyrosine residues were less reactive. The final 2 residues were not accessible to the reagent even in the presence of urea, but were titraten at pH 13.5. The solvent perturbation difference spectrum using ethylene glycol as a perturbant indicated that about 4 tyrosine residues were perturbed. When the pH of the enzyme solution was changed from 7.0 to 1.0, the change in optical density of RNase Vs1 due to denaturation blue shift was about 1,600 at 287nm. The optical density change at 287 nm of native RNase Vs1 on exposure to 8 M urea and 6 M guanidine-HCl indicated that the environments of 2-3 and 4 tyrosine residues were changed by the addition of the denaturants, urea and guanidine-HCl, respectively. In RNase Vs1 having about four nitrotyrosine residues, the two most inaccessible tyrosine residues remained resistant to titration with alkali. On adding nucleotide, nitrated RNase Vs1 gave a difference spectrum in the ultraviolet region but not in 320-460 nm region, where nitrotyrosine residues absorb light. This may indicate that tyrosine residues located relatively near the surface of the molecule are not perturbed directly by nucleotide binding.     

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.     

Glycine 38 is crucial for the ribonucleolytic activity of human pancreatic ribonuclease on double-stranded RNA

Evidence is now in favor of protein-facilitated mechanisms for the intestinal cholesterol absorption. Here we report that the unesterified cholesterol uptake by rat jejunal brush border membrane vesicles (BBMVs) is efficient, saturable, and protein-mediated. The human apolipoproteins biliary anionic peptide factor (APF) and A-I (apoA-I) up-regulate micellar cholesterol uptake in a dose-dependent manner, but for all tested concentrations (0.1-20 microM), the lipid-free APF was more efficient than apoA-I. This uptake stimulation was suppressed after addition of Pabs directed to the external lipid-binding domain of the CLA-1/SR-BI and reduced by Pabs directed to the external loop of CD36. Thus, CLA-1/SR-BI and to a lesser extent CD36 are involved in the regulation of intestinal cholesterol uptake. APF, the main protein bound to biliary lipids, is likely one of their physiological effectors. As APF is an unesterified cholesterol carrier, it could facilitate the intestinal absorption of biliary cholesterol.     

Evolutionary role of posttranslational modifications of proteins,as illustrated by the glycosylation characteristics of the digestive enzyme pancreatic ribonuclease

Summary The glycosylation characteristics of the digestive enzyme ribonuclease are summarized. The evolutionary role of this posttranslational modification is discussed and evidence is presented that selection has much influence on the presence or absence of carbohydrate in glycoproteins and on the positions of the carbohydrate attachment sites.Presented at the FEBS Symposium on Genome Organization and Evolution, held in Crete, Greece, September 1–5, 1986     

A ribonuclease specific for double-stranded RNA and two distinct ribonuclease H activities from the ribosomal salt wash fraction of Ehrlich ascites tumor cells

Three distinct nuclease activities, degrading double-stranded substrates, were isolated from the ribosomal salt wash fraction of Ehrlich ascites tumor cells. One of them is an absolutely Mn²⁺-dependent RNase H, capable of degrading the polyribonucleotide strand of a poly(A) · poly(dT) hybrid only. The other two nuclease activities are: a Mg²⁺-dependent RNase H and a Mn²⁺-dependent ribonuclease, specific for double-stranded RNA. These two activities were inseparable by DEAE-cellulose and phosphocellulose chromatography and both were completely inhibited by 20 mmN-ethymaleimide. It is possible that one protein molecule is responsible for the two activities, depending on the nature of the metal ion, though the existence of two different enzyme molecules is not excluded. The three activities are most probably of extranucleolar origin. A function for the double-stranded RNA-specific enzyme is suggested in the processes regulating protein synthesis. The role of the RNase H activities isolated from the ribosomal salt wash fraction is unclear.     

Partial purification of a double-stranded RNA specific ribonuclease (RNAse D) from Krebs II ascites cells.

In a search for eucaryotic enzymes which might process the heterogenous nuclear RNA (HnRNA) from animal cells into messenger RNA, a ribonuclease called RNAse D analogous to E. coli RNAse III in its ability to cleave specifically synthetic or viral double-stranded polyribonucleotides has been detected and extensively purified from the cytosol of Krebs II mouse ascites cells. The purification procedure involved cellular fractionation followed by DEAE-and CM-cellulose chromatography and resulted in an RNAas D preparation contaminated with trace amounts of single-strand specific RNAse (equivalent to less than 0.3 ng per ml) as assayed against poly (rC). Significant levels of RNAse H activity against poly (rA)-poly (dT) were still present in these preparations.