A positive zymogram for distinguishing among RNase and phosphodiesterases I and II

The positive zymogram, which depends upon indirect production of a formazan from the adenosine released by action of RNase upon UpA, has been modified so that the phosphodiesterases I and II may also be detected. After electrophoretic separation of protein, each of three strips of supporting medium is overlayed with one of three agarose gels containing the enzyme train, adjuncts and (a) adenylyl (3′ → 5′)-uridine, (b) adenylyl (3′ → 5′)-adenosine, or (c), either uridylyl (3′ → 5′)-adenosine or cytidylyl (3′ → 5′)-adenosine or both. The location of purple spots is indicative of the various enzymes as follows: On both (a) and (b) phosphodiesterase I; on both (b) and (c), phosphodiesterase II; on (c) only, RNase (pancreatic type). Positive reactions on all three overlays suggest a combination of enzymes or “nothing dehydrogenase.” Presence of the latter is proved when formazan appears in a fourth overlay devoid of dinucleoside monophosphate.     

A covalent angiogenin/ribonuclease hybrid with a fourth disulfide bond generated by regional mutagenesis

Human angiogenin is a blood vessel inducing protein whose primary structure displays 33% identity to that of bovine pancreatic ribonuclease A (RNase A). Angiogenin catalyzes limited cleavage of 18S and 28S ribosomal RNA and is several orders of magnitude less potent than RNase A toward conventional substrates. A striking structural difference between angiogenin and RNase is the virtual absence of sequence similarity within the region of RNase that contains the Cys-65--Cys-72 disulfide bond. Indeed, angiogenin lacks this disulfide linkage. The present report describes the use of regional mutagenesis to generate a covalent angiogenin/RNase hybrid protein, ARH-I, where residues 58-70 of angiogenin have been replaced by the corresponding segment of RNase A (residues 59-73). The protein expressed in Escherichia coli readily folds at pH 8.5 to form the four expected disulfide bonds. The in vivo angiogenic potency of ARH-I is markedly diminished compared with that of angiogenin when examined using the chick chorioallantoic membrane assay. In contrast, its enzymatic activity is dramatically increased. With high molecular weight wheat germ RNA and tRNA, ARH-I is 660- and 300-fold more active than angiogenin, respectively, while with poly(uridylic acid), poly(cytidylic acid), cytidylyl(3'----5')adenosine (CpA), and uridylyl(3'----5')adenosine (UpA) activity is enhanced by about 200-fold. In addition, the specificity of ARH-I toward dinucleoside 3',5'-phosphates is qualitatively similar to RNase A; while angiogenin prefers cytidylyl(3'----5')guanosine (CpG) to UpA, both RNase and the hybrid prefer UpA to CpG. ARH-I also displays greater than 10-fold enhanced activity toward rRNA in intact ribosomes, while abolishing the capacity of the ribosome to support cell-free protein synthesis. The enhanced enzymatic properties of ARH-I parallel a 2-fold increase in chemical reactivity of active-site lysine and histidine residues based on rates of chemical modification. The data indicate that introduction of a region of RNase A containing the Cys-65--Cys-72 disulfide bond into angiogenin dramatically increases RNase-like enzymatic activity while reducing its angiogenicity.     

Improved method for ribonuclease zymogram

An improved method for ribonuclease zymogram in agarose overlays is described which enables significantly enhanced sensitivity and the avoidance of false-positive activity. Two critical aspects of the zymogram method—the fixation/staining technique and the RNA substrate concentration—were evaluated for the RNase activity in RNase A and in human serum and urine. The zymogram method is sensitive to at least 10 pg of RNase A and does not show a false-positive reaction from 1500 μg of non-RNase protein following electrophoresis in thin-layer polyacrylamide gel.     

Effects of substrate binding on the dynamics of RNase A: Molecular dynamics simulations of UpA bound and native RNase A

RNase A has been extensively used as a model protein in several biophysical and biochemical studies. Using the available structural and biochemical results, RNase A-UpA interaction has been computationally modeled at an atomic level. In this study, the molecular dynamics (MD) simulations of native and UpA bound RNase A have been carried out. The gross dynamical behavior and atomic fluctuations of the free and UpA bound RNase A have been characterized. Principal component analysis is carried out to identify the important modes of collective motion and to analyze the changes brought out in these modes of RNase A upon UpA binding. The hydrogen bonds are monitored to study the atomic details of RNase A-UpA interactions and RNase A-water interactions. Based on these analysis, the stability of the free and UpA bound RNase A are discussed. © 1997 John Wiley & Sons, Inc. Biopoly 42: 505–520, 1997     

Limits to Catalysis by Ribonuclease A

Bovine pancreatic ribonuclease A (RNase A) catalyzes the cleavage of the P-O(5') bond in RNA. Although this enzyme has been the object of much landmark work in bioorganic chemistry, the nature of its rate-limiting transition state and its catalytic rate enhancement had been unknown. Here, the value of k(cat)/K(m) for the cleavage of UpA by wild-type RNase A was found to be inversely related to the concentration of added glycerol. In contrast, the values of k(cat)/K(m) for the cleavage of UpA by a sluggish mutant of RNase A and the cleavage of the poor substrate UpOC(6)H(4)-p-NO(2) by wild-type RNase A were found to be independent of glycerol concentration. Yet, UpA cleavage by the wild-type and mutant enzymes was found to have the same dependence on sucrose concentration, indicating that catalysis of UpA cleavage by RNase A is limited by desolvation. The rate of UpA cleavage by RNase A is maximal at pH 6.0, where k(cat) = 1.4 × 10(3) s(-1) and k(cat)/K(m) = 2.3 × 10(6) M(-1)s(-1) at 25°C. At pH 6.0 and 25°C, the uncatalyzed rate of [5,6-(3)H]Up[3,5,8-(3)H]A cleavage was found to be k(uncat) = 5 × 10(-9) s(-1) (t(1/2) = 4 years). Thus, RNase A enhances the rate of UpA cleavage by 3 × 10(11)-fold by binding to the transition state for P-O(5') bond cleavage with a dissociation constant of <2 × 10(-15) M.     

Cleavage of 3',5'-pyrophosphate-linked dinucleotides by ribonuclease A and angiogenin

Recently, 3',5'-pyrophosphate-linked 2'-deoxyribodinucleotides were shown to be >100-fold more effective inhibitors of RNase A superfamily enzymes than were the corresponding monophosphate-linked (i.e., standard) dinucleotides. Here, we have investigated two ribo analogues of these compounds, cytidine 3'-pyrophosphate (P'-->5') adenosine (CppA) and uridine 3'-pyrophosphate (P'-->5') adenosine (UppA), as potential substrates for RNase A and angiogenin. CppA and UppA are cleaved efficiently by RNase A, yielding as products 5'-AMP and cytidine or uridine cyclic 2',3'-phosphate. The k(cat)/K(m) values are only 4-fold smaller than for the standard dinucleotides CpA and UpA, and the K(m) values (10-16 microM) are lower than those reported for any earlier small substrates (e.g., 500-700 microM for CpA and UpA). The k(cat)/K(m) value for CppA with angiogenin is also only severalfold smaller than for CpA, but the effect of lengthening the internucleotide linkage on K(m) is more modest. Ribonucleotide 3',5'-pyrophosphate linkages were proposed previously to exist in nature as chemically labile intermediates in the pathway for the generation of cyclic 2',3'-phosphate termini in various RNAs. We demonstrate that in fact they are relatively stable (t(1/2) > 15 days for uncatalyzed degradation of UppA at pH 6 and 25 degrees C) and that cleavage in vivo is most likely enzymatic. Replacements of the RNase A catalytic residues His12 and His119 by alanine reduce activity toward UppA by approximately 10(5)-and 10(3.3)-fold, respectively. Thus, both residues play important roles. His12 probably acts as a base catalyst in cleavage of UppA (as with RNA). However, the major function of His119 in RNA cleavage, protonation of the 5'-O leaving group, is not required for UppA cleavage because the pK(a) of the leaving group is much lower than that for RNA substrates. A crystal structure of the complex of RNase A with 2'-deoxyuridine 3'-pyrophosphate (P'-->5') adenosine (dUppA), determined at 1.7 A resolution, together with models of the UppA complex based on this structure suggest that His119 contributes to UppA cleavage through a hydrogen bond with a nonbridging oxygen atom in the pyrophosphate and through pi-pi stacking with the six-membered ring of adenine.     

A novel fluorogenic substrate for ribonucleases. Synthesis and enzymatic characterization.

The synthesis and enzymatic characterization of DUPAAA, a novel fluorogenic substrate for RNases of the pancreatic type is described. It consists of the dinucleotide uridylyl-3',5'-deoxyadenosine to which a fluorophore, o-aminobenzoic acid, and a quencher, 2,4-dinitroaniline, have been attached by means of phosphodiester linkages. Due to intramolecular quenching the intact substrate displayed very little fluorescence. Cleavage of the phosphodiester bond at the 3'-side of the uridylyl residue by RNase caused a 60-fold increase in fluorescence. This allowed the continuous and highly sensitive monitoring of enzyme activity. The substrate was turned over efficiently by RNases of the pancreatic type, but no cleavage was observed with the microbial RNase T1. Compared to the dinucleotide substrate UpA, the specificity constant with RNase A, RNase PL3 and RNase U(s) increased 6-, 18-, and 29-fold, respectively. These differences in increased catalytic efficiency most likely reflect differences in the importance of subsites on the enzyme in the binding of elongated substrates. Studies on the interactions of RNase inhibitor with RNase A using DUPAAA as a reporter substrate showed that it was well suited for monitoring this very tight protein-protein interaction using pre-steady-state kinetic methods.     

Phage display of RNase A and an improved method for purification of phages displaying RNases

Functional ribonuclease A was presented on the surface of the filamentous phage M13 by fusion to the minor coat protein. RNase activity of the fusion protein was shown by a zymogram assay. In addition, we established a modified method for preparing RNase-displaying phages without contaminating host RNases.     

CD studies on ribonuclease A - oligonucleotides interactions.

The interaction of ApU, Aps4U, Aps4Up, ApAps4Up and Gps4U with RNase A was studied by CD difference spectroscopy. The use of 4-thiouridine (s4U) containing oligonucleotides enables to distinguish between the interaction of the different components of the ligand with the enzyme. The mode of binding of the oligonucleotides to the enzyme is described. From this mode of binding it is explained why Aps4U, for example, inhibits RNase A, while s4UpA serves as a substrate.     

The zymogram method for detection of ribonucleases after isoelectric focusing: analysis of multiple forms of human, bovine, and microbial enzymes.

A zymogram method for detection of in situ ribonuclease (RNase) activity, combined with isoelectric focusing in a thin layer of polyacrylamide gel (IEF-PAGE), has been developed. After incubation with a dried agarose film containing substrate RNA, ethidium bromide, and an appropriate reaction buffer, which was placed tightly on the top of the focused gel, sharp and distinct dark bands corresponding to RNase isoenzymes on a fluorescent background appeared under uv light. Addition of urea to the IEF-PAGE gel at a final concentration of 4.8 M permitted optimal focusing of the RNases. This method had not only a high sensitivity of less than 0.1 ng purified RNase A, but also a high band resolution compared with the immunostaining method. It was also useful for analysis of purified enzymes, including bovine pancreatic RNases and two types of human urine RNase as mammalian enzymes, and RNases T1 and T2 as microbial enzymes, as well as for detection of RNases present in crude tissue extracts, resulting in more detailed elucidation of the multiplicity of these enzymes.     

Replacement of residues 8-22 of angiogenin with 7-21 of RNase A selectively affects protein synthesis inhibition and angiogenesis.

The region of human angiogenin containing residues 8-21 is highly conserved in angiogenins from four mammalian species but differs substantially from the corresponding region of the homologous protein ribonuclease A (RNase A). Regional mutagenesis has been employed to replace this segment of angiogenin with the corresponding RNase A sequence, and the activities of the resulting covalent angiogenin/RNase hybrid, designated ARH-III, have been examined. The ribonucleolytic activity of ARH-III is unchanged toward most substrates, including tRNA, naked 18S and 28S rRNA, CpA, CpG, UpA, and UpG. In contrast, the capacity of ARH-III to inhibit cell-free protein synthesis is decreased 20-30-fold compared to that of angiogenin. The angiogenic activity of ARH-III is also different; it is actually more potent. It induces a maximal response in the chick chorioallantoic membrane assay at 0.1 ng per egg, a 10-fold lower dose than required for angiogenin. In addition, binding of ARH-III to the placental ribonuclease inhibitor is increased by at least 1 order of magnitude (Ki less than or equal to 7 x 10(-17) M) compared to angiogenin. Thus, mutation of a highly conserved region of angiogenin markedly affects those properties likely involved in its biological function(s); it does not, however, alter ribonucleolytic activity toward most substrates.     

A hybrid of bovine pancreatic ribonuclease and human angiogenin: an external loop as a module controlling substrate specificity?

A comparison of the sequences of three homologous ribonucleases (RNase A, angiogenin and bovine seminal RNase) identifies three surface loops that are highly variable between the three proteins. Two hypotheses were contrasted: (i) that this variation might be responsible for the different catalytic activities of the three proteins; and (ii) that this variation is simply an example of surface loops undergoing rapid neutral divergence in sequence. Three hybrids of angiogenin and bovine pancreatic ribonuclease (RNase) A were prepared where regions in these loops taken from angiogenin were inserted into RNase A. Two of the three hybrids had unremarkable catalytic properties. However, the RNase A mutant containing residues 63-74 of angiogenin had greatly diminished catalytic activity against uridylyl-(3'----5')-adenosine (UpA), and slightly increased catalytic activity as an inhibitor of translation in vitro. Both catalytic behaviors are characteristic of angiogenin. This is one of the first examples of an engineered external loop in a protein. Further, these results are complementary to those recently obtained from the complementary experiment, where residues 59-70 of RNase were inserted into angiogenin [Harper and Vallee (1989) Biochemistry, 28, 1875-1884]. Thus, the external loop in residues 63-74 of RNase A appears to behave, at least in part, as an interchangeable 'module' that influences substrate specificity in an enzyme in a way that is isolated from the influences of other regions in the protein.     

Kinetic and product distribution analysis of human eosinophil cationic protein indicates a subsite arrangement that favors exonuclease-type activity.

With the use of a high yield prokaryotic expression system, large amounts of human eosinophil cationic protein (ECP) have been obtained. This has allowed a thorough kinetic study of the ribonuclease activity of this protein. The catalytic efficiencies for oligouridylic acids of the type (Up)nU>p, mononucleotides U>p and C>p, and dinucleoside monophosphates CpA, UpA, and UpG have been interpreted by the specific subsites distribution in ECP. The distribution of products derived from digestion of high molecular mass substrates, such as poly(U) and poly(C), by ECP was compared with that of RNase A. The characteristic cleavage pattern of polynucleotides by ECP suggests that an exonuclease-like mechanism is predominantly favored in comparison to the endonuclease catalytic mechanism of RNase A. Comparative molecular modeling with bovine pancreatic RNase A-substrate analog crystal complexes revealed important differences in the subsite structure, whereas the secondary phosphate-binding site (p2) is lacking, the secondary base subsite (B2) is severely impaired, and there are new interactions at the po, Bo, and p-1 sites, located upstream of the P-O-5' cleavable phosphodiester bond, that are not found in RNase A. The differences in the multisubsites structure could explain the reduced catalytic efficiency of ECP and the shift from an endonuclease to an exonuclease-type mechanism.     

Synthesis and characterization of fluorescent dinucleotide substrate for the DNA-dependent RNA polymerase from Escherichia coli

New fluorescent derivatives of dinucleoside monophosphates, (5'-AmNS)UpA/ApU/GpU/CpA, with a fluorophore, 1-aminonaphthalene-5-sulfonic acid (AmNS), attached to the first nucleotide of the dinucleoside monophosphates via a 5'-secondary amine linkage were synthesized in good yield. The chemical structure of (5'-AmNS)ApU was proved by the phosphodiesterase digestion followed by Whatman No. 3MM paper chromatographic and spectroscopic analysis of the digested products. The ability of these analogs to be incorporated into the 5' terminus of RNA chain forming fluorescent oligonucleotides by Escherichia coli RNA polymerase was studied in the presence of a synthetic DNA template. The enzymatic reaction of (5'-AmNS)UpA and [3H]UTP in the presence of poly(dA-dT) yielded (5'-AmNS)UpAp[3H]U in greater than 30% yield with the Km values of 5 and 2.5 microM and Vmax values of 17 and 25 nmol/min/mg of enzyme for (5'-AmNS)UpA and UpA, respectively. The structure of this fluorescent trinucleotide was identified by RNase A digestion and paper chromatographic analysis of the digested products. (5'-AmNS)UpA or (5'-AmNS)ApU exhibits two absorption maxima around 270 and 340-350 nm and a fluorescent emission maximum at 445 nm when excited at 340 nm. These spectral characteristics permit their use as energy donors for the transfer of energy to the intrinsic cobalt of the cobalt-substituted RNA polymerases. Upon hydrolysis of the phosphodiester bond of these analogs by venom phosphodiesterase, the absorption at 340 and 270 nm increased by 5 and 20%, respectively, while their fluorescence at 445 nm was enhanced by 25%. Thus, these analogs can be used for studying the dynamics of initiation and elongation reactions catalyzed by DNA-dependent RNA polymerases by absorption and fluorescence spectroscopies.     

Respective role of each of the purine N-6 amino groups of 5'-O-triphosphoryladenylyl(2'----5')adenylyl(2----5')adenosine in binding to and activation of RNase L

We have synthesized a series of 2-5A (ppp5'-A2'p5'A2'p5'A) analogs in which each adenosine residue has been sequentially replaced by inosine: viz., ppp5'I2'p5'A2'p5'A, ppp5'A2'p5'I2'p5'A, and ppp5'A2'p5'A2'p5'I. These transformations enabled us to delineate the role of each of the three purine N-6 amino groups of 2-5A in determining oligonucleotide binding to and activation of the 2-5A-dependent endoribonuclease, RNase L. With the RNase L activity of both mouse L cells and human Daudi lymphoblastoid cells, we found that the N-6 amino group of the first adenosine nucleotide residue (from the 5'-terminus) is of crucial importance in determining binding to the endonuclease; however, removal of the N-6 amino moieties of the second or third adenosine nucleotide residues resulted in only a minimal decrease in binding to the endonuclease. On the other hand, conversion of the third adenosine residue to inosine effected a dramatic (10,000-fold compared to 2-5A) loss in ability to activate the nuclease; however, execution of the same N-6 amino group conversion at either the first or second adenosine residue did not cause a major change in nuclease activation ability when the accompanying decreased endonuclease binding was considered. These results clearly demonstrate that the N-6 amino group of the first adenosine residue of 2-5A is critical in RNase L binding whereas the N-6 amino function of the third adenosine residue of 2-5A is crucial for the activation of RNase L.     

The Helicase Activity of Ribonuclease R Is Essential for Efficient Nuclease Activity

RNase R, which belongs to the RNB family of enzymes, is a 3′ to 5′ hydrolytic exoribonuclease able to digest highly structured RNA. It was previously reported that RNase R possesses an intrinsic helicase activity that is independent of its ribonuclease activity. However, the properties of this helicase activity and its relationship to the ribonuclease activity were not clear. Here, we show that helicase activity is dependent on ATP and have identified ATP-binding Walker A and Walker B motifs that are present in Escherichia coli RNase R and in 88% of mesophilic bacterial genera analyzed, but absent from thermophilic bacteria. We also show by mutational analysis that both of these motifs are required for helicase activity. Interestingly, the Walker A motif is located in the C-terminal region of RNase R, whereas the Walker B motif is in its N-terminal region implying that the two parts of the protein must come together to generate a functional ATP-binding site. Direct measurement of ATP binding confirmed that ATP binds only when double-stranded RNA is present. Detailed analysis of the helicase activity revealed that ATP hydrolysis is not required because both adenosine 5′-O-(thiotriphosphate) and adenosine 5′-(β,γ-imino)triphosphate can stimulate helicase activity, as can other nucleoside triphosphates. Although the nuclease activity of RNase R is not needed for its helicase activity, the helicase activity is important for effective nuclease activity against a dsRNA substrate, particularly at lower temperatures and with more stable duplexes. Moreover, competition experiments and mutational analysis revealed that the helicase activity utilizes the same catalytic channel as the nuclease activity. These findings indicate that the helicase activity plays an essential role in the catalytic efficiency of RNase R.     

Residues 36-42 of liver RNase PL3 contribute to its uridine-preferring substrate specificity. Cloning of the cDNA and site-directed mutagenesis studies.

Within the superfamily of homologous mammalian ribonucleases (RNases) 4 distinct families can be recognized. Previously, representative members of three of these have been cloned and studied in detail. Here we report on the cloning of a cDNA encoding a member of the fourth family, RNase PL3 from porcine liver. The deduced amino acid sequence showed the presence of a signal peptide, confirming the notion that RNase PL3 is a secreted RNase. Expression of the cDNA in Escherichia coli yielded 1.5 mg of purified protein/liter of culture. The recombinant enzyme was indistinguishable from the enzyme isolated from porcine liver based on the following criteria: amino acid analysis, N-terminal amino acid sequence, molecular weight, specific activity toward yeast RNA, and kinetic parameters for the hydrolysis of uridylyl(3',5')adenosine and cytidylyl(3',5')adenosine. Interestingly, the kinetic data showed that RNase PL3 has a very low activity toward yeast RNA, i.e., 2.5% compared to pancreatic RNase A. Moreover, using the dinucleotide substrates and homopolymers it was found that RNase PL3, in contrast to most members of the RNase superfamily, strongly prefers uridine over cytidine on the 5' side of the scissile bond. Replacement, by site-directed mutagenesis, of residues 36-42 of RNase PL3 by the corresponding ones from bovine pancreatic RNase A resulted in a large preferential increase in the catalytic efficiency for cytidine-containing substrates. This suggests that this region of the molecule contains some of the elements that determine substrate specificity.     

Alkaline hydrolysis of oligoribonucleotides on chromatographic paper

A method is described which permits the alkaline hydrolysis of oligoribonucleotides while on chromatography paper. In one example of this technique, the dinucleotides from a pancreatic RNase digest are characterized. In the second example, some new information about the diversity of sequences found at the 5′-triphosphate termini of bacterial RNA is obtained. There are at least three different pancreatic RNase fragments beginning with adenosine, two with guanosine, and at least three RNase T1 fragments beginning with adenosine.     

Investigations of Sso7d catalytic residues by NMR titration shifts and electrostatic calculations

Sso7d is a small basic protein consisting of 62 amino acids isolated from the thermoacidophilic archeobacterium Sulfolobus solfataricus. The protein is endowed with DNA binding properties, RNase activity, and the capability of rescuing aggregated proteins in the presence of ATP. In this study, the electrostatic properties of Sso7d are investigated by using the Poisson-Boltzmann calculation of the surface potential distribution and following by NMR spectroscopy the proton chemical shift pH titration of acidic residues. Although the details of the catalytic mechanism still have to be defined, the results from NMR experiments confirm the possible involvement of Glu35 as the proton acceptor in the catalytic reaction, as seen by its abnormally high pK(a) value. Poisson-Boltzmann calculations and NMR titration shifts suggest the presence of a possible hydrogen bond between Glu35 and Tyr33, with a consequent rather rigid arrangement at these positions. Comparison with RNase T1 suggests that Tyr7 may be a good candidate for acting as a proton donor in the active site of Sso7d as shown by its low phenolic pK(a) of approximately 9.3. Titration experiments performed with the UpA, a RNA dinucleotide model, showed that the protein residues affected by the interaction are mainly located in a different region with respect to the surface affected by DNA recognition, in good agreement with the surface potential distribution found with electrostatic calculations.