The reaction of ribonuclease inhibitor with modified ribonucleases

1. The effect of chemical modification of ribonuclease on its reaction with ribonuclease inhibitor has been studied. 2. Removal of free amino groups from the enzyme with nitrous acid or by acetylation did not affect the reaction. Some changes altered the stoicheiometry of the reaction and ribonuclease S was found to be inhibited linearly by increasing amounts of ribonuclease inhibitor, in contrast with ribonuclease A, which is inhibited in a non-linear way. One derivative of ribonuclease containing dimethylaminonaphthalenesulphonyl groups actually reacted with ribonuclease inhibitor to a greater extent (and linearly) than did the unaltered enzyme. 3. The positively charged histidine at the active site and the active enzyme did not appear to be necessary for the reaction since 1-carboxymethylhistidine-119-ribonuclease reacted with ribonuclease inhibitor to almost the same extent as the native enzyme. In general, any significant change in the conformation of ribonuclease was accompanied by a loss in its ability to combine with inhibitor. The presence of 8m-urea also prevented reaction of ribonuclease with inhibitor. 4. Some characteristics of the reaction of ribonuclease inhibitor, ribonuclease and deaminated ribonuclease with RNA and deaminated RNA were investigated.     

Reduction of ribonuclease by glutathione at elevated temperatures: the molecular mechanism

1. The mechanism of the reaction between ribonuclease and GSH at elevated temperatures has been studied by using N-(4-dimethylamino-3,5-dinitrophenyl)-maleimide to label the reduced ribonuclease. 2. After incubation for 2hr. at 35 degrees , enzymically active ribonuclease was recovered; at 50.8 degrees half of the initial ribonuclease was recovered as enzymically active ribonuclease and half as reduced labelled ribonuclease; at 55 degrees all of the initial ribonuclease was recovered in the labelled form. 3. It was inferred that the rate-limiting step was the reduction of the first disulphide bond in any one molecule. This was followed by rapid reduction of the other bonds in the same molecule.     

Characterization of ribonucleases and ribonuclease inhibitor in subcellular fractions from rat adrenals

1. The presence of two RNA-degrading enzymes, one with optimum activity at pH5.6 (acid ribonuclease) and the other with optimum activity at pH7.8 (alkaline ribonuclease), in rat adrenals has been demonstrated. The acid ribonuclease was localized in the mitochondrial fraction whereas the alkaline ribonuclease was present in mitochondria as well as in the supernatant fraction. Freezing and thawing of mitochondria and treatment with Triton X-100 gave a three- to four-fold increase in acid-ribonuclease activity, whereas the mitochondrial alkaline-ribonuclease activity was practically unaffected. 2. The amount of free ribonuclease in the adrenal supernatant was small. Treatment of the supernatant fraction with N-ethylmaleimide resulted in release of large amounts of ribonuclease activity, indicating the presence of a ribonuclease inhibitor having reactive thiol groups. 3. Considerable amounts of free ribonuclease inhibitor in excess over the bound alkaline ribonuclease are present in the rat-adrenal supernatant fraction. The inhibitor is heat-labile and non-diffusible. A 400-500-fold purification of the ribonuclease inhibitor was achieved by ammonium sulphate fractionation, treatment with calcium phosphate gel and DEAE-cellulose chromatography. It is concluded that the adrenal inhibitor is protein in nature, similar to the inhibitor present in rat liver.     

Control of the formation of extracellular ribonuclease in Neurospora crassa.

A finding was made that a species of ribonuclease is released into mycelial culture media when a wild-type strain of Neurospora crassa was grown on limiting amounts of phosphate. The ribonuclease activity in the fully derepressed state extends to about 60 to 100 fold of that in the repressed state. The synthesis of the ribonuclease was inhibited by the addition of rifampicin, cycloheximide or orthophosphate. Three molecular species of the ribonuclease were found. Two enzyme fractions showing larger molecular weights were suspected to be aggregates containing the enzyme showing the smallest molecular weight (molecular weight of 10 300). All three fractions showed pH optima of around 7, preferential hydrolysis of polyguanylic acid and poor hydrolysis of guanosine 2',3',-cyclic monophosphate. These characteristics were the same as those of ribonuclease N1, and it was suggested that ribonuclease N1 is a repressible extracellular enzyme. Mutations in the genes nuc-1 and nuc-2 caused loss of ability to derepress this enzyme, but heterokaryon between them partially restored the ability. The nuc-1 mutation was epistatic to the nuc-2 alleles which are partly constitutive in the ribonuclease production.     

Effect of nucleic-acid-binding compounds on the hydrolytic activity of various ribonucleases.

Studies were conducted on the stimulatory effect that various nucleic-acid-binding compounds have on the hydrolysis of RNA and polyribonucleotides by pancreatic ribonuclease A and by other ribonucleases. The stimulatory activity of chloroquine on tRNA hydrolysis by pancreatic ribonuclease was due to the formation of oligonucleotides of a wide range of sizes and was not due to the formation of very short ( n greater than 5) oligonucleotide fragments of tRNA. The dextrorotatory and levorotatory isomers of chloroquine did not differ in their ability to stimulate the hydrolysis of tRNA by pancreatic ribonuclease A. In addition to chloroquine and primaquine, other nucleic-acid-binding compounds (e.g., quinacrine, lucanthone, and proflavin) stimulated the hydrolysis of tRNA by pancreatic ribonuclease A. Chloroquine did not alter the rate of hydrolysis by pancreatic ribonuclease A of low-molecular-weight substrates (cytidine cyclic 2':o'-monophosphate, uridine cyclic 2':3'-monophosphate, cytidylyl-adenosine, or uridylyl-uridine). Furthermore, chloroquine and primaquine did not affect the hydrolysis of poly(A) by high concentrations of pancreatic ribonuclease A. In studies on the hydrolysis of tRNA by other endoribonucleases, several of the nucleic-acid-binding compounds (e.g., quinacrine and ethidium) exhibited appreciable inhibition of both ribonuclease N1 and ribonuclease T1. None of the compounds tested stimulated the activity of ribonuclease T1, and only chloroquine, and perhaps lucanthone, stimulated the hydrolysis of tRNA by ribonuclease N1.     

Nuclear magnetic resonance titration curves of histidine ring protons. A direct assignment of the resonances of the active site histidine residues of ribonuclease.

One of the four titrating histidine ring C-2 proton resonances of bovine pancreatic ribonuclease has been assigned to histidine residue 12. This was accomplished by a direct comparison of the rate of tritium incorporation into position C-2 of histidine 12 of S-peptide (residues 1 to 20) derived from ribonuclease S, with the rates of deuterium exchange of the four histidine C-2 proton resonances of ribonuclease S under the same experimental conditions. The same assignment was obtained by a comparison of the NMR titration curves of ribonuclease S, the noncovalent complex of S-peptide and S-protein (residues 21 to 124) with the results for the recombined complex in which position C-2 of histidine 12 was fully deuterated. The second active site histidine resonance was assigned to histidine residue 119 by consideration of the NMR titration results fro carboxymethylated histidines and 1-carboxymethylhistidine 119 ribonuclease. This assignment is a reversal of that originally reported, and has important implications for the interpretation of NMR titration data of ribonuclease.     

Elevation of an acid ribonuclease in serum of patients with chronic granulocytic leukaemia.

Ribonuclease (Ribonucleate nucleotide 2'-transferase E.C. 2.7.7.17) activity in serum of patients with chronic granulocytic leukaemia measured at pH 4.5-6.0 amounts to more than three times of that in serum of healthy subjects. At pH 6.0-8.0 the elevation of ribonuclease activity in serum of patients with chronic granulocytic leukaemia is less pronounced and amounts to about two times of that in normal ones. Using chromatography on CM Sephadex C-50 column, serum ribonuclease of both normal and chronic granulocytic leukaemia patients was separated into five distinct fractions. In serum of healthy subjects ribonuclease fractions denoted I-V contribute to 10; 21; 29; 22, and 18 percent of the total ribonuclease activity. In the serum of patients with chronic granulocytic leukaemia a decrease in ribonuclease fraction III to merely 17 percent and an increase in contribution of fraction IV to 32 percent of total ribonuclease activity could be observed. The comparison of each individual concentration of fraction in normal and leukaemia patients serum reveals, that ribonuclease fraction IV will increase about 3 times. A less pronounced increase could also be found for fractions I, II and V. However, ribonuclease fraction IV may be supposed to carry more than 50 percent of the whole extra load of ribonuclease present in the serum of chronic granulocytic leukaemia patients.     

Changes in Ribonuclease Activity and Content of RNA during Dormancy and Growth of Bird-cherry Buds

Ribonuclease has been extracted from buds of bird-cherry (Prunus padus L.) by a three-step method. In step 1 ribonuclease was extracted from the homogenized tissue at p^H 6. In step 2 the tissue residue from (1) was extracted at p^H 7. In step 3 the tissue residue from (2) was extracted with a buffer of p^H 8.5 and containing 0.7 M KCl. The ribonuclease from step 1 and 2 is named soluble and that from step 3 bound ribonuclease. The activity of the soluble ribonuclease was very low in October and increased slowly until March. When the buds sprouted in April the activity of this fraction rose rapidly. The activity of the bound ribonuclease was rather high in October and increased continuously from autumn to spring. RNA accumulated slowly between autumn and spring. The change in activity of the two ribonuclease fractions is discussed in relation to development.     

First demonstration of lactoribonuclease, a ribonuclease from bovine milk with similarity to bovine pancreatic ribonuclease

The isolation of a ribonuclease designated lactoribonuclease, with a molecular weight and an N-terminal amino acid sequence identical to those of bovine pancreatic ribonuclease, was first reported from bovine milk. After removal of globulin from acid whey by precipitation with 1.8 M (NH4)2SO4, (NH4)2SO4 was added to attain a concentration of 3.6 M. Adsorption on the ion exchanger CM-Sepharose and subsequently on Mono S by fast protein liquid chromatography yielded pure lactoribonuclease. The enzyme, like pancreatic ribonuclease, was most active at pH 7.5 with yeast transfer RNA (tRNA) as substrate. Lactoribonuclease and pancreatic ribonuclease showed a strong preference for poly(C) over poly(U). However, pancreatic ribonuclease did so with a higher specific activity, suggesting that the two ribonucleases are not identical. No inhibitory effect was shown by either lactoribonuclease or pancreatic ribonuclease toward poly (A) and poly (G). The effect of lactoribonuclease and pancreatic ribonuclease on tRNA increased with the concentration of tRNA. Lactoribonuclease inhibited cell-free translation in a rabbit reticulocyte lysate system with an IC50 of 3.5 nM while the corresponding IC50 for pancreatic ribonuclease was 0.09 nM.     

Purification of a calcium dependent ribonuclease from Xenopus laevis.

We have purified a Ca2+ dependent ribonuclease from the oocytes of Xenopus leavis. Two properties of this ribonuclease set it apart from other known nucleases. First, Ca2+ was required for ribonuclease activity, and Mg2+ would not substitute. Second, the enzyme specifically degraded RNA and digestion of double or single stranded DNA was not observed. Ca2+ dependent ribonuclease activity of the purified 36-kDa protein was directly observed after renaturation of the protein following electrophoresis in an SDS-Laemmli gel. In addition, the enzyme was shown to have endoribonuclease activity at numerous sites. The Ca2+ dependence suggests that the ribonuclease activity may be modulated by changes in the level of intracellular Ca2+ and thereby provide a direct link to signal transduction systems.     

An Escherichia coli ribonuclease which removes an extra nucleotide from a biosynthetic intermediate of bacteriophage T4 proline transfer RNA.

The biosynthesis of bacteriophage T4 tRNAPro, tRNASer, and tRNAIle requires enzymatic removal of extra nucleotides from the 3' terminus of the respective precursor RNAs. A ribonuclease activity capable of catalyzing such reactions has been partially purified from uninfected Escherichia coli using an artificial precursor RNA as substrate. A number of ribonuclease activities were resolved during purification. Use of E. coli strain BN, a mutant known to be deficient in the relevant ribonuclease activity, permitted us to identify it in wild-type cells. This activity was designated the BN ribonuclease. BN ribonuclease had an apparent molecular weight of 35,000 as measured by Sephadex gel filtration. Mg2+ was required for activity, which was optimal at [Mg2+] of 2mM. Activity did not require monovalent cations K+ or Na+. BN ribonuclease was less efficient at removing extra residues in the biosynthesis of tRNASer and tRNAIle than in the biosynthesis of tRNAPro.     

The ribonuclease activity of nucleolar protein B23.

Protein B23 is an abundant nucleolar protein and putative ribosome assembly factor. The protein was analyzed for ribonuclease activity using RNA-embedded gels and perchloric acid precipitation assays. Three purified bacterially expressed forms of the protein, B23.1, B23.2 and an N-terminal polyhistidine tagged B23.1 as well as the natural protein were found to have ribonuclease activity. However, the specific activity of recombinant B23.1 was approximately 5-fold greater than that of recombinant B23.2. The activity was insensitive to human placental ribonuclease inhibitor, but was inhibited by calf thymus DNA in a dose dependent manner. The enzyme exhibited activity over a broad range of pH with an apparent optimum at pH 7.5. The activity was stimulated by but not dependent on the presence of low concentrations of Ca2+, Mg2+ or NaCl. The Ca2+ effect was saturable and only stimulatory in nature. In contrast, Mg2+ and NaCl exhibited optimal concentrations for stimulation and both inhibited the ribonuclease at concentrations above these optima. These data suggest that protein B23 has intrinsic ribonuclease activity. The location of protein B23 in subcompartments of the nucleolus that contain preribosomal RNA suggests that its ribonuclease activity plays a role in the processing of preribosomal RNA.     

Properties of a ribonuclease from Aedes aegypti larvae

1. The properties of a soluble ribonuclease from Aedes aegypti larvae have been compared with ribonuclease activity in adult female tissue. 2. In larval extracts ribonuclease activity was maximal at 40-45 degrees C whereas activity in tissue from adult females was highest at 50 degrees C. 3. Ribonuclease activity that was recovered in a 20-60% ammonium sulfate precipitate was further purified by batch elution from DEAE-Sephacel and from carboxymethylcellulose. 4. Ribonuclease activity in the partially purified fraction was sensitive to EDTA, stimulated by magnesium, had a pH optimum at 9.0 and a Mr of 45,000. 5. Agarose gels containing yeast RNA substrate were used to monitor partial purification of the larval ribonuclease.     

The inhibition of ribonuclease activity and the isolation of polysomes from leaves of the french bean, Phaseolus vulgaris

The effect of inhibitors on the ribonuclease activity of soluble and microsomal fractions of bean leaves has been examined. The soluble ribonuclease activity could be completely inhibited by Zn²⁺, Cu²⁺, bentonite, and diethylpyrocarbonate, although these inhibitors had little effect on the microsomal ribonuclease activity. Ribonuclease activity in the soluble fraction was completely inhibited by guanosine 2′(3′)-monophosphate, which was the first nucleotide to accumulate on degradation of yeast RNA. Adenosine 2′(3′)-monophosphate, the first nucleotide to accumulate on degradation of yeast RNA by the microsomal preparations, completely inhibited the ribonuclease activity of the microsomal fraction.The ribonuclease activity of both enzyme preparations was completely inhibited by an analog of the transition state of the ribonuclease reaction, a complex of guanosine and vanadyl sulfate. Inclusion of this complex in homogenization media markedly increased the proportion of polysomes isolated from bean leaves.     

The isolation and partial characterization of ribonuclease A from Bison bison

1. Bison ribonuclease was isolated from pancreas glands of Bison bison by acid extraction, (NH(4))(2)SO(4) fractionation, affinity chromatography on Sepharose-5'-(4-aminophenylphosphoryl)uridine 2',3'-phosphate and ion-exchange chromatography on Bio-Rex-70. 2. The selectivity of the affinity column towards bison ribonuclease in heterogeneous protein solutions was greatly improved by employing piperazine buffers at pH5.3, which decreased non-specific interactions of other proteins. Rapid desorption from the affinity column was obtained with sodium phosphate buffer (pH3). 3. Bison ribonuclease has a total amino acid content very similar to ox ribonuclease. Inactivation of bison ribonuclease with iodoacetic acid leads to the formation of 0.62 residues of pi-carboxymethylhistidine and 0.36 residues of tau-carboxymethylhistidine. The amino acid composition of peptides isolated from diagonal peptide ;maps' and also of peptides isolated after pH1.6 and 2.4 two-dimensional high-voltage electrophoresis of a digest of bison ribonuclease labelled with pyridoxal 5-phosphate indicates that there is complete homology between ox and bison ribonucleases. 4. The Schiff-base attachment site of pyridoxal 5-phosphate was identified as lysine-41 by NaBH(4) reduction followed by peptide isolation.     

Porcine thyroid cytosolic, latent alkaline ribonuclease: resistance to protein denaturants.

1. A ribonuclease isolated from porcine thyroid cytosol using phenol: sodium dodecylsulfate treatment was associated with RNA and identical to latent alkaline ribonuclease. 2. Distribution of activity between aqueous and phenolic phases depended on pH, RNA, and ribonuclease inhibitor. 3. The ribonuclease was totally resistant to urea, guanidinium: HCl, chloroform:isoamyl alcohol, ethanol, heating at 100 degrees C for 10 min or at 80 degrees C plus 100 mM NaCl. It was highly resistant to hydrolysis by proteinase K except in the presence of detergent. 4. The extreme stability and other properties of latent alkaline ribonuclease could be the result of its association with RNA.     

Ribonuclease Activities and Distribution in Alzheimer''s and Control Brains

Levels of free and total alkaline ribonuclease, and levels of acidic ribonuclease, were measured postmortem in control brains and in the brains of patients with Alzheimer's disease. In each brain region assayed, whether control or Alzheimer's, there was a statistically significant difference between the levels of free and total alkaline ribonuclease. Between 59 and 90% of the enzyme activity was associated with alkaline ribonuclease inhibitor in an inactive complex. Levels of free and total alkaline ribonuclease varied widely among different brains and brain regions, and were always lower in cerebellum than in temporal cortex and occipital pole. There was no significant difference in the levels of total alkaline ribonuclease, free alkaline ribonuclease, or acidic ribonucleases between corresponding regions of Alzheimer's and control brains. There was also no qualitative difference in the subcellular distribution of the alkaline and acidic ribonucleases between Alzheimer's and control brain. No significant relationships were found between ribonuclease levels and age, neuritic plaque density, postmortem interval, or storage time.     

A Fourier transform infrared investigation of the structural differences between ribonuclease A and ribonuclease S

Fourier transform infrared spectroscopy was used to investigate the small conformational differences which exist between ribonuclease A and ribonuclease S in aqueous systems. Deconvolution and derivative methods were used to observe the overlapping components of the amide I and II bands. These proteins give identical spectra in H2O and after complete exchange in 2H2O. However structural differences are revealed by monitoring the rate of 1H-2H exchange by Fourier transform infrared spectroscopy. At equivalent times of exposure in 2H2O buffer ribonuclease S undergoes greater isotopic exchange than ribonuclease A. Thus complete exchange takes place for ribonuclease S but not ribonuclease A after incubation at room temperature for 8 days. Complete 1H-2H exchange of ribonuclease A was achieved by incubation at 62 degrees C for 30 min. The available X-ray data and comparison with the infrared spectra of other soluble proteins was used to assign the components of the amide I and II bands to various secondary structures. In particular, band shifts observed during the later stages of exchange are associated with slowly exchanging residues in beta-strand and alpha-helical regions. The higher rate of exchange for ribonuclease S is associated with a greater conformational flexibility and a more open structure. The results show that it is necessary to be cautious in making band assignments based on exchange methods unless the extent of exchange is known. Furthermore, it is seen that the combination of Fourier transform infrared spectroscopy and hydrogen-deuterium exchange is a powerful technique for revealing small differences in protein secondary structure.     

Amino acid sequence determination of guanyl-specific ribonuclease Sa from Streptomyces aureofaciens

Using automated Edman degradation of two nonfractionated peptide mixtures of tryptic and staphylococcal protease digests of the protein, the complete amino acid sequence of the guanyl-specific ribonuclease Sa from Streptomyces aureofaciens was established. Ribonuclease Sa contains 96 amino acid residues (Mr 10,566). A 50% sequence homology of ribonuclease Sa to the guanyl-specific ribonuclease St from S. erythreus was found.     

Magnesium ion-independent ribonucleic acid depolymerases in bacteria

The distribution of ribonucleases among bacteria has been determined from the examination of a wide variety of species. Bacteria that had been growing rapidly on a solid medium were harvested, treated with acetone and incubated in the presence of EDTA between pH4 and pH9. The ribonuclease activity was determined from the rate at which acid-soluble nucleotides were released. Out of nearly 200 strains examined, about 30 did not contain a detectable ribonuclease. The pH optima of ribonucleases in the remainder were sufficiently distinctive to suggest a use in taxonomy. Escherichia coli B was examined in more detail to determine the factors responsible for variations in the ribonuclease content of this bacterium. Growth rate had little influence on ribonuclease content when a complex medium containing no readily assimilable carbohydrate was used; the addition of glucose resulted in a marked increase in ribonuclease and a dependence of enzyme content on growth rate. An increase in the concentration of sodium chloride in the medium decreased the ribonuclease content of bacteria growing on it.