The mode of action of divalent cations on the RNase catalyzed hydrolysis of RNA and uridylyl (3'-5') uridine

Pseudo first order rate constants (k′) have been measured for the RNase A catalyzed hydrolysis of uridylyl (3′–5′) uridine at several ionic strengths and compositions. The k′ values are independent of Mg²⁺ concentration between 0 and 10 mM. This shows that for hydrolysis of RNA, in which Mg²⁺ concentration does change k′, the perturbation must be through binding of Mg²⁺ to the substrate RNA rather than to the enzyme RNase.     

Mutations in the ribonuclease H active site of HIV-RT reveal a role for this site in stabilizing enzyme-primer-template binding

The RNase H activity of HIV-RT is coordinated by a catalytic triad (E478, D443, D498) of acidic residues that bind divalent cations. We examined the effect of RNase H deficient E(478)-->Q and D(549)-->N mutations that do not alter polymerase activity on binding of enzyme to various nucleic acid substrates. Binding of the mutant and wild-type enzymes to various nucleic acid substrates was examined by determining dissociation rate constants (k(off)) by titrating both Mg(2+) and salt concentrations. In agreement with the unaltered polymerase activity of the mutant, the k(off) values for the wild-type and mutant enzymes were essentially identical using DNA-DNA templates in the presence of 6 mM Mg(2+). However, with lower concentrations of Mg(2+) and in the absence of Mg(2+), although both enzymes dissociated more rapidly, the mutant enzymes dissociated several-fold more slowly than the wild type. This was also observed on RNA-DNA templates. These results indicate that alterations in residues essential for Mg(2+) binding have a pronounced positive effect on enzyme-template stability and that the negative residues in the RNase H region of the enzyme have a negative influence on binding in the absence of Mg(2+). In this regard RT is similar to other nucleic acid cleaving enzymes that show enhanced binding upon mutation of active site residues.     

Characterization of the mouse sperm plasma membrane zona-binding site sensitive to trypsin inhibitors

The first contact of mammalian gametes is the binding of the spermatozoon to the zona pellucida of the egg. Previous work has shown that binding of the spermatozoon to the zona in the mouse occurs prior to the acrosome reaction and that trypsin inhibitors block this initial binding. This suggests that the sperm surface contains a trypsinlike binding site that functions by an active site mechanism to effect initial zona binding. When suspensions of twice-washed spermatozoa were incubated with the serine protease active site titrant, 4-methylumbelliferyl p-guanidinobenzoate (MUGB), the titrant was hydrolyzed at a rate of 8 pmoles/min-10(6) cells. MUGB was found to inhibit the binding of spermatozoa to the zona pellucida. The degree of inhibition and the rate of hydrolysis of MUGB by washed spermatozoa depend on the concentration of titrant, with half maximal effects at 13 microM and a linear correlation with r = 0.99. The analogous lysyl and arginyl trypsin substrates containing 7-amino-4-methylcoumarin as the fluorogenic leaving group were not hydrolyzed under the same conditions and did not inhibit zona binding. Both binding of sperm to zona-intact eggs and the hydrolysis of MUGB by sperm are inhibited by p-nitrophenyl guanidinobenzoate, soybean trypsin inhibitor, and acid-solubilized zonae. The linear correlation coefficients of the inhibition of sperm binding and MUGB hydrolysis by these three substances are greater than 0.92. This "trypsinlike" sperm site is essential for sperm binding to the zona: its stereospecificity is unique in that it reacts with trypsin inhibitors but not with trypsin substrates.     

Partial characterization of ribonuclease (RNase) activity from the isolated and solubilized brush border of Hymenolepis diminuta

The isolated brush border membrane of Hymenolepis diminuta contained ribonuclease (RNase) activity which was demonstrable using yeast RNA or synthetic homopolymers of adenylic, cytidylic, inosinic, or uridylic acids as substrates. Polyguanylic acid was not hydrolyzed by worm RNase. RNase activity was inhibited by EDTA and divalent cations as well as sulfhydryl blocking and reducing agents. Polyguanylic acid and DNA were also inhibitors of RNase activity; these compounds were not hydrolyzed, but inhibited the hydrolysis of other substrates, possibly by nonproductive substrate binding. Data suggested that RNase (endonuclease) was probably the major enzyme activity in the degradation of long chain polyribonucleotides at the work's surface, while phosphodiesterase (exonuclease) activity did not contribute significantly to the hydrolysis of these compounds.     

Pre-steady-state and steady-state kinetic analysis of the low molecular weight phosphotyrosyl protein phosphatase from bovine heart.

The complete time course of the hydrolysis of p-nitrophenyl phosphate catalyzed by the low molecular weight (acid) phosphotyrosyl protein phosphatase from bovine heart was elucidated and analyzed in detail. Burst titration kinetics were demonstrated for the first time with this class of enzyme. At pH 7.0, 4.5 degrees C, a transient pre-steady-state "burst" of p-nitrophenol was formed with a rate constant of 48 s-1. The burst was effectively stoichiometric and corresponded to a single enzyme active site/molecule. The burst was followed by a slow steady-state turnover of the phosphoenzyme intermediate with a rate constant of 1.2 s-1. Product inhibition studies indicated an ordered uni-bi kinetic scheme for the hydrolysis. Partition experiments conducted for several substrates revealed a constant product ratio. Vmax was constant for these substrates, and the overall rate of hydrolysis was increased greatly in the presence of alcohol acceptors. An enzyme-catalyzed 18O exchange between inorganic phosphate and water was detected and occurred with kcat = 4.47 x 10(-3) s-1 at pH 5.0, 37 degrees C. These results were all consistent with the existence of a phosphoenzyme intermediate in the catalytic pathway and with the breakdown of the intermediate being the rate-limiting step. The true Michaelis binding constant Ks = 6.0 mM, the apparent Km = 0.38 mM, and the rate constants for phosphorylation (k2 = 540 s-1) and dephosphorylation (k3 = 36.5 s-1) were determined under steady-state conditions with p-nitrophenyl phosphate at pH 5.0 and 37 degrees C in the presence of phosphate acceptors. The energies of activation for the enzyme-catalyzed hydrolysis at pH 5.0 and 7.0 were 13.6 and 14.1 kcal/mol, respectively. The activation energy for the enzyme-catalyzed medium 18O exchange between phosphate and water was 20.2 kcal/mol. Using the available equilibrium and rate constants, an energetic diagram was constructed for the enzyme-catalyzed reaction.     

The pH-dependence of the Escherichia coli RNase HII-catalysed reaction suggests that an active site carboxylate group participates directly in catalysis

RNase HII specifically catalyses the hydrolysis of phosphate diester linkages contained within the RNA portion of DNA/RNA hybrids. The catalytic parameters of the enzyme derived from Escherichia coli BL21 have been measured using 5'-fluorescent oligodeoxynucleotide substrates containing embedded ribonucleotides. The products of the reaction and the chemistry of phosphate diester hydrolysis were assigned unequivocally using mass spectrometry. The pH-dependence of the catalytic parameters was measured under conditions of optimal magnesium ion concentration. The logarithm of the turnover number of the enzyme increases steeply with pH until a pH-independent region is reached close to neutrality. The slope of the pH-dependent region is 2, indicating that the catalytically proficient form of RNase HII is di-anionic. The pH-dependence of log 1/K(M) is a sigmoidal curve reaching a maximal value at higher pH, suggesting deprotonation of a residue stabilises substrate binding. Possible mechanisms for the RNase HII-catalysed reaction consistent with the pH-dependent behaviour of the enzyme are discussed. The active sites of RNase H enzymes contain a cluster of four strictly conserved carboxylate groups. Together, the data suggest a requirement for ionisation of an active site carboxylic acid for metal ion binding or correct positioning of metal ion(s) in the enzyme-substrate complex and a role for a second active site carboxylate in general base catalysis.     

Interaction kinetics of reversible inhibitors and substrates with acetylcholinesterase and its fasciculin 2 complex

Fasciculin 2 (Fas2), a three-fingered peptide of 61 amino acids, binds tightly to the peripheral site of acetylcholinesterases (AChE; EC ), occluding the entry portal into the active center gorge of the enzyme and inhibiting its catalytic activity. We investigated the mechanism of Fas2 inhibition by studying hydrolysis of cationic and neutral substrates and by determining the kinetics of interaction for fast equilibrating cationic and neutral reversible inhibitors with the AChE.Fas2 complex and free AChE. Catalytic parameters, derived by eliminating residual Fas2-resistant activity, reveal that Fas2 reduces k(cat)/K(m) up to 10(6)-fold for cationic substrates and less than 10(3)-fold for neutral substrates. Rate constants for association of reversible inhibitors with the active center of the AChE.Fas2 complex were reduced about 10(4)-fold for both cationic and neutral inhibitors, while dissociation rate constants were reduced 10(2)-to 10(3)-fold, compared with AChE alone. Rates of ligand association with both AChE and AChE.Fas2 complex were dependent on the protonation state of ionizable ligands but were also markedly reduced by protonation of enzyme residue(s) with pK(a) of 6.1-6.2. Linear free energy relationships between the equilibrium constant and the kinetic constants show that Fas2, presumably through an allosteric influence, markedly alters the position of the transition state in the reaction pathway. Since Fas2 complexation introduces an energetic barrier for hydrolysis of substrates that exceeds that found for association of reversible ligands, Fas2 influences catalytic parameters by a more complex mechanism than simple restriction of diffusional entry and exit from the active center. Conformational flexibility appears critical for facilitating ligand passage in the narrow active center gorge for both AChE and the AChE.Fas2 complex.     

Kinetics and thermodynamics of catalysis by the inorganic pyrophosphatase of Escherichia coli in both directions

Combined evidence obtained from the measurements of pyrophosphate hydrolysis and synthesis, oxygen exchange between phosphate and water, enzyme-bound pyrophosphate formation and Mg2+ binding enabled us to deduce the overall scheme of catalysis by Escherichia coli inorganic pyrophosphatase in the presence of Mg2+. We determined the equilibrium constants for Mg2+ binding to various enzyme species and forward and reverse rate constants for the four steps of the catalytic reaction, namely, binding/release of PPi, hydrolysis/synthesis of PPi and successive binding/release of two Pi molecules. Catalysis by the E. coli enzyme in both directions, in contrast to baker's yeast pyrophosphatase, occurs via a single pathway, which requires the binding of Mg2+ to the sites of four types. Three of them can be filled in the absence of the substrates, and the affinity of one of them to Mg2+ is increased by two orders of magnitude in the enzyme-substrate complexes. The distribution of 18O-labelled phosphate isotopomers during the exchange indicated that hydrolysis of pyrophosphate in the active site is appreciably reversible. The equilibrium constant for this process estimated from direct measurements is 5.0. The ratio of the maximal velocities of pyrophosphate hydrolysis and synthesis is 69. The rate of the synthesis is almost entirely determined by the rate of the release of pyrophosphate from the enzyme. In the hydrolytic reaction, enzyme-bound pyrophosphate hydrolysis and successive release of two phosphate molecules proceed with nearly equal rate constants.     

Kinetics and energetics of ligand binding determined by microcalorimetry: insights into active site mobility in a psychrophilic alpha-amylase

A new microcalorimetric method for recording the kinetic parameters k(cat), K(m) and K(i) of alpha-amylases using polysaccharides and oligosaccharides as substrates is described. This method is based on the heat released by glycosidic bond hydrolysis. The method has been developed to study the active site properties of the cold-active alpha-amylase produced by an Antarctic psychrophilic bacterium in comparison with its closest structural homolog from pig pancreas. It is shown that the psychrophilic alpha-amylase is more active on large macromolecular substrates and that the higher rate constants k(cat) are gained at the expense of a lower affinity for the substrate. The active site is able to accommodate larger inhibitory complexes, resulting in a mixed-type inhibition of starch hydrolysis by maltose. A method for recording the binding enthalpies by isothermal titration calorimetry in a low-affinity system has been developed, allowing analysis of the energetics of weak ligand binding using the allosteric activator chloride. It is shown that the low affinity of the psychrophilic alpha-amylase for chloride is entropically driven. The high enthalpic and entropic contributions of activator binding suggest large structural fluctuations between the free and the bound states of the cold-active enzyme. The kinetic and thermodynamic data for the psychrophilic alpha-amylase indicate that the strictly conserved side-chains involved in substrate binding and catalysis possess an improved mobility, responsible for activity in the cold, and resulting from the disappearance of stabilizing interactions far from the active site.     

Role of sugar hydroxyl groups in glycoside hydrolysis. Cleavage mechanism of deoxyglucosides and related substrates by beta-glucosidase A3 from Aspergillus wentii

The contribution of the hydroxyl groups at C-2 and C-4 and of the hydroxy-methyl group at C-5 of beta-glucopyranosides to their hydrolysis by beta-glucosidase A3 (beta-D-glucoside glucohydrolase, EC 3.2.1.21) from Aspergillus wentii was investigated with 4-methylumbelliferyl-beta-glucosides with appropriate structural modifications. Relative hydrolysis rates expressed by kcat/kcat (glucoside) are: 2-deoxy, 4. 10(-6); 2-deoxy-2-amino, 2.4 . 10(-4); 2-deoxy-2-ammonio, less than 1 . 10(-6); 4-deoxy, 1.8 . 10(-4); xyloside, 6.3 . 10(4); galactoside, less than 1 . 10(-6). Binding to the active site as measured by the Km value of these substrates or by the Ki value of the appropriate inhibitors is only moderately decreased by the above modifications. A temperature study with the 2-deoxyglucoside showed that the decrease in kcat is not due to a change in delta H but to a more negative delta S. The steady-state hydrolysis of the 2-deoxyglucoside is approached with a "burst" (rate constant 0.13 min-1) at pH 6 and 1 mM substrate; deglycosylation of the enzyme is partially rate-limiting. Rate constants for glycosylation and deglycosylation calculated from pre-steady-state kinetics were in good agreement with the constants calculated from experiments where the 2-deoxyglucoside was used as an inhibitor for the hydrolysis of the glucoside and where a slow approach to the steady state of the inhibited reaction is observed.     

Models for biological phosphoryl transfer

Quantifying the rate of phosphate monoester dianion hydrolysis under physiological conditions has implications for designing transition state mimics and understanding how catalysis is facilitated. Catalysis is energetically most efficient if the mechanistic pathway in solution is stabilised. Monoesters are believed to have a "dissociative" transition state that has little bonding to the nucleophile and leaving group. However, in many instances, it is suggested that enzymes catalyse monoester transfer through an associative (diester-like) pathway. This is perhaps easier to rationalise in terms of the active site residues available. For example, in the catalytic subunit of protein phosphatase 1 (PP1), these are metal ions and cationic side chains which might be expected to stabilise developing negative charge. By using multiple interactions simultaneously, cooperativity in catalysis may be achieved. However, this idea is difficult to demonstrate unambiguously in large, complex natural systems. This contribution examines the background reactivity of phosphate esters, and reports data showing that the substrates for serine/threonine phosphatases have slower intrinsic rate constants than any other enzyme substrates. Using model complexes, the characteristics of alternative (associative) mechanisms that have been proposed for the metallophosphatase catalysed reaction are explored. Finally, complementary catalytic groups are combined with this core complex to look for experimental evidence for possible cooperativity in this context.     

Kinetic analysis of the hydrolysis of GTP by p21N-ras. The basal GTPase mechanism

The rate constants have been determined for elementary steps in the basal GTPase mechanism of normal p21N-ras (Gly-12) and an oncogenic mutant (Asp-12): namely GTP binding, hydrolysis, phosphate release, and GDP release. By extrapolation from data at lower temperatures, the GTP association rate constant at 37 degrees C is 1.4 x 10(8) M-1 s-1 for the normal protein and 4.8 x 10(8) M-1 s-1 for the mutant. Other rate constants were measured directly at 37 degrees C, and three processes have similar slow values. GTP dissociation is at 1.0 x 10(-4) s-1 (normal) and 5.0 x 10(-4) s-1 (mutant). The hydrolysis step is at 3.4 x 10(-4) s-1 (normal) and 1.5 x 10(-4) s-1 (mutant). GDP dissociates at 4.2 x 10(-4) s-1 (normal) and 2.0 x 10(-4) s-1 (mutant). GDP association rate constants are similar to those for GTP, 0.5 x 10(8) M-1 s-1 for normal and 0.7 x 10(8) M-1 s-1 for mutant. Both hydrolysis and GDP release therefore contribute to rate limitation of the basal GTPase activity. There are distinct differences (up to 5-fold) between rate constants for the normal and mutant proteins at a number of steps. The values are consistent with the reduced GTPase activity for this mutant and suggest little difference between normal and mutant proteins in the relative steady-state concentrations of GTP and GDP complexes that may represent active and inactive states. The results are discussed in terms of the likely role of p21ras in transmembrane signalling.     

Gamma-glutamyltransferase of rat kidney. Simultaneous assay of the hydrolysis and transfer reactions with (glutamate-14C)glutathione.

1. The hydrolytic and transfer reactions catalysed by rat kidney-gamma-glutamyltransferase (EC 2.3.2.2) were studied in vitro with substrates [U-14C]glutamic acid-labelled glutathione and methionine. Initial-velocity patterns, isotope-exchange and binding studies were consistent with a branched non-sequential mechanism in which a gamma-glutamyl-enzyme intermediate may react either with water (hydrolysis) or with methionine (gamma-glutamyl transfer). 2. The Michaelis constant for glutathione in hydrolysis was 13.9 +/- 1.4 mum, for glutathione in transfer it was 113 +/- 15 muM and for methionine as substrate it was 4.7 +/- 0.7 mM. At substrate concentrations in the ranges of their respective Michaelis constants, the rate of transfer was about ten times higher than that of hydrolysis, but at concentrations of methionine approximating to the physiological (64 muM in rat plasma) the transfer is negligible. 3. The enzyme is reported to lie on the luminal surface of the proximal straight kidney tubule. In this situation, if the kinetic results obtained with the detergent-solubilized enzyme are relevant to the behavior of the enzyme in vivo, it appears likely that the main function of renal gamma-glutamyltransferase is not in amino acid transport, but rather to hydrolyse glutathione in the renal filtrate.     

Design principles for active transport systems

We have previously described simple models for active transport and have derived steady state equations for the unidirectional flux of substrate in terms of a minimal set of kinetic parameters. Here we consider how to maximize the pumping rate of a carrier-enzyme through the optimal utilization of the ATP hydrolysis reaction. The equations for net flux contain rate constants and dissociation constants and these determine the maximum velocities and affinities measured in transport kinetic analysis. It is assumed that the rate constants can evolve to the diffusion limited rate of substrate binding as has apparently occurred in the enzyme triosephosphate isomerase (Knowles & Albery, 1977). The dissociation constants of the rate limiting intermediates fit the affinities for substrates on different sides of the membrane and are dependent on the basic free energy levels (Hill, 1976) of the carrier substrate system. From our analysis it is clear that there are three ways to design a system with optimal affinities and that the choice is linked to the sequence of substrate binding. It is possible to use free energy differences of isomerization (Boyer, 1975) or ligand-ligand interactions (Weber, 1975) both of which have been described previously, but which are incorporated here into a unified treatment. A third possibility is to couple the binding step of a transported ligand to the progress of a chemical reaction as might occur, for example, if Na⁺ must be bound before the carrier can be phosphorylated. In this way the free energy of hydrolysis can be used not only to drive the overall pumping reaction, but also to fix differentially the affinity for substrate on either side of the membrane, as required for rapid pumping.     

Molecular requirements for degradation of a modified sense RNA strand by Escherichia coli ribonuclease H1

The structural requirements for DNA/RNA hybrids to be suitable substrates for RNase H1 are well described; however the tolerance level of this enzyme towards modifications that do not alter the duplex conformation is not clearly understood, especially with respect to the sense RNA strand. In order to investigate the molecular requirements of Escherichia coli RNase H1 (termed RNase H1 here) with respect to the sense RNA strand, we synthesized a series of oligonucleotides containing 2'-deoxy-2'-fluoro-beta-D-ribose (2'F-RNA) as a substitute for the natural beta-D-ribose sugars found in RNA. Our results from a series of RNase H1 binding and cleavage studies indicated that 2'F-RNA/DNA hybrids are not substrates of RNase H1 and ultimately led to the conclusion that the 2'-hydroxyl moiety of the RNA strand in a DNA/RNA hybrid is required for both binding and hydrolysis by RNase H1. Through the synthesis of a series of chimeric sense oligonucleotides of mixed RNA and 2'F-RNA composition, the gap requirements of RNase H1 within the sense strand were examined. Results from these studies showed that RNase H1 requires at least five or six natural RNA residues within the sense RNA strand of a hybrid substrate for both binding and hydrolysis. The RNase H1-mediated degradation patterns of these hybrids agree with previous suggestions on the processivity of RNase H1, mainly that the binding site is located 5' to the catalytic site with respect to the sense strand. They also suggest, however, that the binding and catalytic domains of RNase H1 might be closer than has been previously suggested. In addition to the above, physicochemical studies have revealed the thermal stabilities and relative conformations of these modified heteroduplexes under physiological conditions. These findings offer further insights into the physical binding and catalytic properties of the RNase H1-substrate interaction, and have been incorporated into a general model summarizing the mechanism of action of this unique enzyme.     

Mechanism for the hydrolysis of organophosphates by the bacterial phosphotriesterase

Phosphotriesterase (PTE) from Pseudomonas diminuta is a zinc metalloenzyme that hydrolyzes a variety of organophosphorus compounds. The kinetic parameters of Zn/Zn PTE, Cd/Cd PTE, and a mixed-metal Zn/Cd hybrid PTE were obtained with a variety of substrates to determine the role of each metal ion in binding and catalysis. pH-rate profiles for the hydrolysis of diethyl p-nitrophenyl phosphate (I) and diethyl p-chlorophenyl phosphate (II) demonstrated that the ionization of a single group in the pH range of 5-10 was critical for substrate turnover. The pK(a) values determined from the kinetic assays were dependent on the identity of the metal ion that occupied the alpha site within the binuclear metal center. These results suggest that the hydrolytic nucleophile is activated as a hydroxide via the ionization of a water molecule attached to the alpha-metal ion. The kinetic constants for the hydrolysis of II and diethyl p-chlorophenyl thiophosphate (IV) were determined for the metal substituted forms of PTE. The kinetic constants for IV were greater than those for II. The inverse thio effect is consistent with the polarization of the phosphoryl oxygen/sulfur bond via a direct ligation to the metal center. The rate enhancement is greater when Cd(2+) occupies the beta-metal-ion position. A series of alanine and asparagine mutations were used to characterize the catalytic roles of Asp233, His254, and Asp301. Mutations to either Asp233 or His254 resulted in an enhanced rate of hydrolysis for the sluggish substrate, diethyl p-chlorophenyl phosphate, and a decrease in the kinetic constants for paraoxon (I). These results are consistent with the existence of a proton relay from Asp301 to His254 to Asp233 that is used to ferry protons away from the active site with substrates that do not require activation of the leaving group phenol. A mechanism for the hydrolysis of organophosphates by the bacterial PTE has been proposed.     

Carboxymethylation of a minor ribonuclease from Aspergillus saitoi.

(1) RNase Ms was inactivated by iodoacetate. The inactivation was most rapid at pH 6.0, and was inhibited in the presence of a denaturant such as 8 m urea or 6 m guanidine-HCL. (2) Competitive inhibitors protected RNase Ms from inactivation by iodoacetate; the effect was in the order 2',(3')-GTP greater than 2',(3')-AMP, 2',(3')-UMP greater than or equal to 2',(3')-CMP. The order is not consistent with that of the binding constants of the 4 nucleotides towards RNase Ms (A is greater than C greater than G greater than U). (3) RNase Ms was inactivated with the concomitant incorporation of one molar equivalent of carboxymethly group. The following evidence indicated that the carboxymethyl group was incorporated into the carboxyl group of an aspartic acid or glutamic acid residue. (i) The carboxymethyl group incorporated into RNase Ms was liberated by treatment with 0.1 n NaOH or 1 m hydroxylamine. (ii) The amino acid composition of carboxymethylated RNase Ms (CM RNase Ms) after acid hydrolysis is similar to that of RNase Ms. (4) 14C-Labeled CM RNase Ms was digested successively with alkaline protease and amino-peptidase M. The radioactive amino acid released was eluted just before aspartate on an amino acid analyzer. After hydrolysis with 6 n HCL, glutamic acid was produced exclusively from the radioactive amino acid. The specific radioactivity of this amino acid calculated from the radioactivity and glutamic acid formed was practctically the same as that of CM RNase Ms. Thus, it was concluded that a carboxymethyl group was incorporated at the carboxyl group of a glutamic acid residue of RNnase Ms. (5) CM RNase Ms bound with 2'-AMP to the same extent as native RNase Ms, but bound to a lesser extent with 2',(3')-GMP. (6) Although the conformation of CM RNase Ms as judged from the CD spectrum was practically the same as that of native RNase Ms, the reactivity of CM RNase Ms towards dinitrofluorobenzene was different from that of native RNase Ms, indicating some difference in the conformation. (7) These results indicate that one glutamic acid residue is involved in the active of RNase Ms.