Photochemical labeling of bovine pancreatic ribonuclease A with 8-azidoadenosine 3',5'-bisphosphate

A simple method has been developed for the preparation of 5'-32P-labeled 8-azidoadenosine 3',5'-bisphosphate (p8N3Ap) for use in photoaffinity labeling studies. Irradiation of a complex between p8N3Ap and bovine pancreatic ribonuclease A (RNase A) with light of 300-350 nm led to the covalent attachment of the nucleotide to the enzyme. RNase A could also be labeled in the dark with prephotolyzed p8N3Ap. In either case, the nucleotide reacted with the same tryptic peptide, encompassing amino acids 67-85 of the protein. The site of labeling was determined to be either Thr-78 or Thr-82, both of which are close to or at the pyrimidine binding site of the enzyme. This result is consistent with recent nuclear magnetic resonance and X-ray studies which indicate that 8-substituted adenine nucleotides interact with the pyrimidine binding site of RNase A.     

Photo-cross-linking of guanine nucleotides to the nucleotide binding site of elongation factor G

Elongation factor G (EF-G) is rapidly inactivated when irradiated at 253.7 nm. The inactivation follows first-order single-hit kinetics with a quantum efficiency of 3.15 × 10^?5 μmol/μE. Inclusion of either GTP or GDP in the irradiation mixture does not alter the kinetics of inactivation, but does result in the covalent attachment of nucleotide to between 10 and 20% of the EF-G. This relatively low percentage of cross-linking is due to the rapid rate of photoinactivation as compared to the slower rate of covalent attachment. If EF-G is reacted before irradiation with N-ethylmaleimide, a modification known to block the nucleotide binding site [Rohrbach and Bodley (1976) J. Biol. Chem.251, 930], essentially no nucleotide can be photo-cross-linked to EF-G. Treatment of the photo-cross-linked GTP-EF-G with Raney nickel led to the liberation of the nucleotide moiety, indicating that the photo-cross-link to EF-G occurred through a sulfur atom. Although the formation of the EF-G nucleotide complex has been shown to be an obligatory first step in the formation of the EF-G nucleotide ribosome complex [Rohrbach and Bodley (1976) Biochemistry15, 4565], the covalent EF-G-nucleotide adduct cannot form a ternary complex with the ribosome. The presence of both nucleotide and ribosomes during irradiation drastically alters the kinetics of inactivation. The inactivation under these conditions follows multiple-hit kinetics with an initial period during which no EF-G activity is lost. Following this lag period, EF-G is inactivated at the same rate at which ribosomes lose their ability to bind EF-G. No nucleotide is cross-linked to EF-G or the ribosome under these conditions.     

The molecular evolution of pancreatic ribonuclease

Summary The primary structures of pancreatic ribonucleases from 26 species (18 artiodactyls, horse, whale, 5 rodents and turtle) are known. Several species contain identical ribonucleases (cow/bison; sheep/goat), other species show polymorphism (arabian camel) or the presence of two structural gene loci (guinea pig pancreas contains two ribonucleases that differ at 31 positions). 26 different sequences (including the ribonuclease from bovine seminal plasma which is paralogous to the pancreatic ribonucleases) were used to construct a most parsimonious tree. A second tree that most closely approximates current biological opinion requires 402 whereas the most parsimonious tree requires 389 nucleotide substitutions. The artiodactyl part of the most parsimonious tree conforms quite well with the biological one of this order, except for the position of the giraffe which is placed with the pronghorn. Other parts of the most parsimonious tree agree less with the biological tree, probably as a result of the occurrence of many parallel and back substitutions. Bovine seminal ribonuclease was found to be the result of a gene duplication which occurred before the divergence of the true ruminants, but after the divergence of this group from the cameloids.The evolutionary rate of ribonuclease was found to be 390, 3.0 and 11 nucleotide substitutions per 10⁹ yrs per ribonuclease gene, codon and covarion respectively. However, there is much variation in evolutionary rate in different taxa. Values ranging from about 100 (in the bovidae) to about 700 (in the rodents) nucleotide substitutions per 10⁹ yrs per gene were found.A method for counting parallel and back mutations is presented. The 389 nucleotide substitutions in the most parsimonious tree occur at 88 codon positions; 154 of them are the result of parallel and back mutations. Parallel evolution to a similar structure, including the presence of 2 sites with carbohydrate, was demonstrated in an extensive region at the surface of pig and guinea pig ribonuclease B. The presence of carbohydrate probably is important in a number of species. A correlation between the presence of heavily glycosidated ribonucleases and coecal digestion was observed. Hypothetical sequences of ancestral ungulate ribonucleases contain many recognition sites for carbohydrate attachment; this suggests that herbivores with coecal digestion might have preceded the true ruminants in mammalian evolution.     

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.     

Affinity labeling of specific regions of 23 S RNA by reaction of N-bromoacetyl-phenylalanyl-transfer RNA with Escherichia coli ribosomes

Reaction of the affinity-labeling reagent N-bromoacetyl-[¹⁴C]phenylalanyl-tRNA with Escherichia coli ribosomes results in covalent labeling of 23 S ribosomal RNA in addition to the previously reported labeling of ribosomal proteins. The reaction with the 23 S RNA is absolutely dependent on the presence of messenger RNA. Covalent attachment of the affinity label to 23 S RNA was demonstrated by its integrity in strongly dissociating solvents, and the conversion of the labeled material to small oligonucleotides by ribonuclease treatment. After digestion of labeled 23 S RNA with T₁ ribonuclease, the radioactivity is found mainly in two oligonucleotide fragments. These results support models in which both ribosomal RNA and ribosomal protein contribute to the structure of the region of the ribosome surrounding the peptidyl transferase center.     

Formation of Hydrogen Peroxide by a Polyvinyl Alcohol Degrading Enzyme

A method for purification and crystallization, and some properties of ribonuclease from Aspergillus sp. [EC 2.7.7.17] (RNase L) are reported. The purification procedure consisted of six steps, including acetone precipitation, column chromatographies on Duolite A–2 and DEAE-cellulose, repeated chromatography on DEAE-Sephadex A–50 column and affinity chromatography on 5’-AMP-Sepharose 4B column. Crystallization was performed by the dialysis against ammonium sulfate solution at 60% saturation.

The crystalline enzyme was shown to be homogeneous by polyacrylamide disc electrophoresis and ultracentrifugation. Svedberg value of the crystalline enzyme was 4.2. The enzyme was the most active at pH 3.5 and 60~65°C, and it was inhibited markedly with Fe.³⁺

RNase L has no absolute base specificity, and produces four kinds of 3’-mononucleotides from yeast RNA. However, the susceptibility of four nucleotide residues to RNase L increases in the order; G < A < C < U and is quite different from those of RNase T₂, RNase M and RNase R.     

Effects of nucleotide analogs on ATP hydrolysis by P-type ATPases. Comparison between the canine kidney (Na++ K+) ATPase and maize root H+-ATPase

The mechanism by which chemical energy is converted into an electrochemical gradient by P-type ATPase is not completely understood. The effects of ATP analogs on the canine kidney (Na⁺+ K⁺) ATPase were compared to effects of the same analogs on the maize (Zea mays L. cv. W7551) root H⁺-ATPase in order to identify probes for the ATP binding site of the maize root enzyme and to determine potential similarities of ATP hydrolysis mechanisms in these two enzymes. Six compounds able to modify the ATP binding site covalently were compared. These compounds could be classed into three distinct groups based on activity. The first group had little or no effect on catalytic activity of either enzyme and included 7-chloro-4-nitrobenz-2-oxa-1.3-diazole. The second group, which included azido adenine analogs. fluorescein isothiocyanate and 5′-p-fluorosulfonylbenzoyladenine, were inhibitors of ATP hydrolysis by both enzymes. However, the sensitivity of the (Na⁺+ K⁺) ATPase to inhibition was much greater than that exhibited by the maize root enzyme. The third group, which included periodate treated nucleotide derivatives and 2′,3′-o-(4-benzoylbenzoyl)adenosine triphosphate. inhibited both enzymes similarly. This initial screening of these covalent modifiers indicated that 2′,3′-o-(4-benzoylbenzoyl)adenosine triphosphate was the optimal covalent modifier of the ATP binding site of the maize root enzyme. Certain reagents were much more effective against the (Na⁺+ K⁺) ATPase than the maize root enzyme, possibly indicating differences in the ATP binding and hydrolysis pathway for these two enzymes. Two ATP analogs that are not covalent modifiers were also tested: the trinitrophenyl derivatives of adenine nucleotides were better than 5′-adenylylimidodiphosphate for use as an ATP binding probe.     

共价连接的多肽酶联免疫测定法的研究

采用紫外线照射及戊二醛活化处理聚苯乙烯酶标板后再包被八肽胆囊收缩素（CCK-8）,以此为基础进行酶联免疫吸附试验（ELISA）,通过不同的洗涤过程对CCK-8与酶标板相互作用的性质进行研究.结果表明,该包被方法可使CCK-8通过共价交联的方式稳定地结合于固相载体上,该方法适用于不同来源的酶标板,处理后的酶标板性质稳定,可储存使用,测定的批内及批间变异系数分别为4.75%和7.80%,方法稳定可靠,重复性好,便于推广应用.     

Nucleotide Composition of RNA hybridized to Homologous DNA from Cells transformed by Avian Tumour Viruses

PART of the evidence which indicates that RNA tumour viruses replicate through a DNA intermediate¹ was the detection of DNA which is complementary to the viral RNA in leukaemic cells transformed by avian myeloblastosis virus (AMV)² and in cells transformed in vitro by avian sarcoma viruses, Schmidt-Ruppin (SR-RSV) and B-77 (ref. 3). If this DNA serves as a template for the viral RNA, it must be a copy of the entire viral genome. One of the necessary requirements for this function is that the homologous DNA has the same nucleotide composition as the viral RNA. In this study, the average base composition of the RNA which had been hybridized to homologous DNA from transformed cells was compared with the base composition of the input viral RNA. Two experimental conditions had to be met: (1) the recovery of all the ribonucleotides which had been hybridized and (2) the absence of partially hybridized ribonucleotide sequences. The first requirement called for the deletion of the treatment of DNA-RNA hybrids with pancreatic ribonuclease fraction A and ribonuclease T₁ which had been used in our previous experiments because such a treatment can cause the non-random loss of hybridized nucleotides⁴. The second requirement called for a hybridization and washing procedure in which only specifically hybridized ribonucleotide sequences would remain bound to the filters. Both of these conditions were met by using fragmented viral RNA and a modified washing procedure which excluded the use of ribonuclease. The results show that the average nucleotide composition of the hybridized RNA is identical to that of the input viral RNA.     

A role for ribonuclease III in synthesis of bacteriophage T4 transfer RNAs.

Synthesis of T4 tRNA^Gln depends on normal levels of $\text{Escherichia}\text{coli}$ ribonuclease III. Infection of cell strains carrying a mutation in the gene for this enzyme resulted in severe depression in tRNA^Gln production, as revealed by chemical and suppressor tRNA analyses. The remaining seven T4 tRNAs were synthesized in the mutant cells. The requirement of ribonuclease III for synthesis of tRNA^Gln points to an essential cleavage by the enzyme of a precursor RNA containing tRNA^Gln.     

Ribonuclease activity of vaccinia DNA topoisomerase IB: kinetic and high-throughput inhibition studies using a robust continuous fluorescence assay

Vaccinia type I DNA topoisomerase exhibits a strong site-specific ribonuclease activity when provided a DNA substrate that contains a single uridine ribonucleotide within a duplex DNA containing the sequence 5' CCCTU 3'. The reaction involves two steps: attack of the active site tyrosine nucleophile of topo I at the 3' phosphodiester of the uridine nucleotide to generate a covalent enzyme-DNA adduct, followed by nucleophilic attack of the uridine 2'-hydroxyl to release the covalently tethered enzyme. Here we report the first continuous spectroscopic assay for topoisomerase that allows monitoring of the ribonuclease reaction under multiple-turnover conditions. The assay is especially robust for high-throughput screening applications because sensitive molecular beacon technology is utilized, and the topoisomerase is released during the reaction to allow turnover of multiple substrate molecules by a single molecule of enzyme. Direct computer simulation of the fluorescence time courses was used to obtain the rate constants for substrate binding and release, covalent complex formation, and formation of the 2',3'-cyclic phosphodiester product of the ribonuclease reaction. The assay allowed rapid screening of a 500 member chemical library from which several new inhibitors of topo I were identified with IC(50) values in the range of 2-100 microM. Three of the most potent hits from the high-throughput screening were also found to inhibit plasmid supercoil relaxation by the enzyme, establishing the utility of the assay in identifying inhibitors of the biologically relevant DNA relaxation reaction. One of the most potent inhibitors of the vaccinia enzyme, 3-benzo[1,3]dioxol-5-yl-2-oxoproprionic acid, did not inhibit the closely related human enzyme. The inhibitory mechanism of this compound is unique and involves a step required for recycling the enzyme for steady-state turnover.     

Immobilization and stabilization of d-hydantoinase from Vigna angularis and its use in the production of N-carbamoyl-d-phenylglycine. Improvement of the reaction yield by allowing chemical racemization of the substrate

This work reports the immobilization of a multimeric d-hydantoinase (DHTase) from Vigna angularis (E.C. 3.5.2.2.) on agarose beads activated with glyoxyl groups aiming to improve its stability via multipoint covalent attachment. The final reduction with sodium borohydride resulted in a drop in enzyme activity that could be decreased by adding Zn²⁺ or Mg²⁺. The optimal preparation with high activity (58 % recovered activity) and stability (around 86-fold more stable than the free enzyme) was obtained by DHTase immobilization on glyoxyl agarose for 24 h at 25 °C and pH 10.05, and a borohydride reduction step in the presence of 10 mM Zn²⁺ (DHTase-Glx). The enzyme was almost fully immobilized on glyoxyl agarose (19.8 mg/g of support) when offering 20 mg/g. This immobilized biocatalyst was used to catalyze the hydrolysis of d,l-phenylhydantoin under substrate racemization conditions, which produced 99 % of N-carbamoyl-d-phenylglycine after 9 h reaction.     

19F NMR of the 5-fluorodeoxyuridylate-thymidylate synthetase binary complex.

Formation of the 5-fluorodeoxyuridylate-thymidylate synthetase binary complex generates a ¹⁹F nmr resonance 1.3–1.4 ppm to higher shielding from free ligand, probably as the result of rotation of the pyrimidine ring about the glycosyl bond. Addition of sodium dodecyl sulfate to the complex produces the spectrum of free ligand indicating that in contrast to the ternary complex of enzyme:nucleotide:cofactor, the binary complex does not contain a covalent bond linking the nucleotide to the enzyme. In the presence of a 2.5 molar excess of nucleotide, 1.55 moles were bound per mole of enzyme in Tris-Cl buffer. Under comparable conditions in sodium phosphate, 0.64 moles were bound, suggesting a specific buffer effect by phosphate.     

Rossmann-fold motifs can confer multiple functions to metabolic enzymes: RNA binding and ribonuclease activity of a UDP-glucose dehydrogenase

Metabolic enzymes are usually characterized to have one specific function, and this is the case of UDP-glucose dehydrogenase that catalyzes the twofold NAD⁺-dependent oxidation of UDP-glucose into UDP-glucuronic acid. We have determined that this enzyme is also capable of participating in other cellular processes. Here, we report that the bacterial UDP-glucose dehydrogenase (UgdG) from Sphingomonas elodea ATCC 31461, which provides UDP-glucuronic acid for the synthesis of the exopolysaccharide gellan, is not only able to bind RNA but also acts as a ribonuclease. The ribonucleolytic activity occurs independently of the presence of NAD⁺ and the RNA binding site does not coincide with the NAD⁺ binding region. We have also performed the kinetics of interaction between UgdG and RNA. Moreover, computer analysis reveals that the N- and C-terminal domains of UgdG share structural features with ancient mitochondrial ribonucleases named MAR. MARs are present in lower eukaryotic microorganisms, have a Rossmannoid-fold and belong to the isochorismatase superfamily. This observation reinforces that the Rossmann structural motifs found in NAD⁺-dependent dehydrogenases can have a dual function working as a nucleotide cofactor binding domain and as a ribonuclease.     

UDP-N-Acetyl-D-glucosamine-Asparagine sequon N-Acetyl-β-D-Glucosaminyl -Transferase-Activity in Human serum

Serum contains a sugar transferase which is able to catalyse the glycosylation in in vitro of the asparagine residue present in the sequence Asn.Leu.Thr in bovine pancreatic ribonuclease. UDP-2-Acetamido-2-deoxy-D-glucose (UDP-N-acetyl-D- glucosamine) acts as the donor, although the mechanism of the transfer is unexplored. Spermidine and Mn²⁺, as well as CDP-choline, can act as activators for the reaction. Monoglycosylated ribonuclease (ribonuclease-GIcNAc) has been separated (23% yield) from unreacted ribonuclease A by affinity chromatography on a colunm of wheat-germ agglutinin bound to Sepharose, and characterised. A possible reason for the presence of the enzyme in serum is suggested.     

Extracellular ribonuclease formation in Bacillus subtilis and its stimulation by actinomycin D

1. Extracellular ribonuclease is produced linearly for at least 3hr. by washed post-logarithmic-phase cells of Bacillus subtilis suspended in a medium containing maltose (1%) and casein hydrolysate (0·5%). 2. Low concentrations of actinomycin D (less than 2μg./ml.) stimulate ribonuclease formation, the maximum effect being observed with a concentration of 1μg./ml. Concentrations greater than 2μg./ml. are inhibitory. There is no parallel stimulation of α-amylase formed under the same conditions, and [¹⁴C]uracil incorporation into a perchloric acid-insoluble form is inhibited. 3. The actinomycin D-induced stimulation is not due to the presence of an activator, nor is the inhibition due to the release of an inhibitor by the cells. The effect is on the amount of ribonuclease produced in the medium. 4. Extracellular ribonuclease formation is partially inhibited by anaerobiosis, 2,4-dinitrophenol, sodium azide and by chloramphenicol and puromycin. 5. High concentrations of antibiotic do not completely inhibit ribonuclease formation, but a basal amount of enzyme representing 20min. synthesis in an uninhibited system is always produced. This `antibiotic-insensitive' enzyme could possibly represent preformed enzyme `in the pipe-line' en route to secretion. 6. The stimulated appearance of ribonuclease in the presence of 1μg. of actinomycin D/ml. is shown to be dependent on enzyme synthesis. The mechanism of this effect is discussed.     

Heterofunctional Magnetic Metal‐Chelate‐Epoxy Supports for the Purification and Covalent Immobilization of Benzoylformate Decarboxylase From Pseudomonas Putida and Its Carboligation Reactivity

In this study, the combined use of the selectivity of metal chelate affinity chromatography with the capacity of epoxy supports to immobilize poly‐His‐tagged recombinant benzoylformate decarboxylase from Pseudomonas putida (BFD, E.C. 4.1.1.7) via covalent attachment is shown. This was achieved by designing tailor‐made magnetic chelate–epoxy supports. In order to selectively adsorb and then covalently immobilize the poly‐His‐tagged BFD, the epoxy groups (300 µmol epoxy groups/g support) and a very small density of Co²⁺‐chelate groups (38 µmol Co²⁺/g support) was introduced onto magnetic supports. That is, it was possible to accomplish, in a simple manner, the purification and covalent immobilization of a histidine‐tagged recombinant BFD. The magnetically responsive biocatalyst was tested to catalyze the carboligation reactions. The benzoin condensation reactions were performed with this simple and convenient heterogeneous biocatalyst and were comparable to that of a free‐enzyme‐catalyzed reaction. The enantiomeric excess (ee) of (R)‐benzoin was obtained at 99 ± 2% for the free enzyme and 96 ± 3% for the immobilized enzyme. To test the stability of the covalently immobilized enzyme, the immobilized enzyme was reused in five reaction cycles for the formation of chiral 2‐hydroxypropiophenone (2‐HPP) from benzaldehyde and acetaldehyde, and it retained 96% of its original activity after five reaction cycles. Chirality 27:635–642, 2015. © 2015 Wiley Periodicals, Inc.     

Reaction of ethanol radicals with ribonuclease.

Ribonuclease was irradiated under conditions such that ethanol radicals were the main reactive species in solution. Sephadex gel filtration of the irradiated solution demonstrated that ethanol radicals had reacted with the ribonuclease and had become firmly bound to the enzyme molecule. The number of ethanol molecules bound to ribonuclease was a function of dose and correlated with the loss of enzymatic activity and with the changes in the molecular configuration of the enzyme molecule.     

Structural design of the active site for covalent attachment of the heme to the protein matrix: studies on a thermostable cytochrome P450

The molecular basis of the post-translational modification involving covalent attachment of the heme with a glutamic acid observed in some enzymes of the CYP4 family of heme monooxygenases has been investigated using site-directed mutagenesis of CYP175A1 from Thermus thermophilus. Earlier studies of CYP4 as well as the G248E mutant of CYP101A1 showed covalent linkage of the heme to a conserved glutamic acid of helix I. We have introduced Glu/Asp at the Leu80 position in the β-turn of CYP175A1, on the basis of molecular modeling studies, to assess whether formation of such a covalent linkage is limited only to helix I or whether such modification may also take place with the residue that is spatially located at a position appropriate for activation by the heme peroxidase reaction. Tandem mass spectrometry analyses of the tryptic digest of the wild type and mutants of CYP175A1 were conducted to identify any heme-bound peptide. Tryptic digestion of the L80E mutant of CYP175A1 preincubated with H(2)O(2) showed formation of GLE(-heme)TDWGESWKEARK supporting covalent linkage of Glu80 with the heme in the mutant enzyme. No such heme-bound peptides were found if the sample was not preincubated in H(2)O(2), indicating no activation of the Glu by the heme peroxidase reaction, as proposed earlier. The wild type or L80D mutant of the enzyme did not give any heme-bound peptide. Thus, the results support the idea that covalent attachment of the heme to an amino acid in the protein matrix depends on the structural design of the active site.     

Affinity labeling of phenylalanyl-tRNA synthetase from E.coli MRE-600 by E.coli tRNAphe containing photoreactive group

The photoinduced reaction of phenylalanyl-tRNA synthetase (E.C. 6.1.1.20) from E.coli MRE-600 with tRNA^phe containing photoreative p-N₃-C₆H₄-NHCOCH₂-group attached to 4-thiouridine sU₈ (azido-tRNA^phe) was investigated. The attachment of this group does not influence the dissociation constant of the complex of Phe-tRNA^phe with the enzyme,however it results in sevenfold increase of K_m in the enzymatic aminoacylation of tRNA^phe. Under irradiation at 300 nm at pH 5.8 the covalent binding of [¹⁴C]-Phe-azido-tRNA^phe to the enzyme takes place 0.3 moles of the reagent being attached per mole of the enzyme. tRNA prevents the reaction. Phenylalanine, ATP,ADP,AMP, adenosine and pyrophosphate (2.5 × x 10⁻³ M) don't affect neither the stability of the tRNA-enzyme complex nor the rate of the affinity labelling. The presence of the mixture of either phenylalanine or phenylalaninol with ATP as well as phenylalaninol adenylate exibits 50% inhibition of the photoinduced reaction. Therefore, the reaction of [¹⁴C]-Phe-azido-tRNA with the enzyme is significantly less sensitive to the presence of the ligands than the reaction of chlorambucilyl-tRNA with the reactive group attached to the acceptor end of the tRNA studied in ¹. It has been concluded that the kinetics of the affinity labelling does permit to discriminate the influence of the low molecular weight ligands of the enzyme on the different sites of the tRNA - enzyme interaction.