Identification by Mn2+ rescue of two residues essential for the proton transfer of tRNase Z catalysis

Thermotoga maritima tRNase Z cleaves pre-tRNAs containing the ₇₄CCA₇₆ sequence precisely after the A₇₆ residue to create the mature 3′ termini. Its crystal structure has revealed a four-layer αβ/βα sandwich fold that is typically found in the metallo-β-lactamase superfamily. The well-conserved six histidine and two aspartate residues together with metal ions are assumed to form the tRNase Z catalytic center. Here, we examined tRNase Z variants containing single amino acid substitutions in the catalytic center for pre-tRNA cleavage. Cleavage by each variant in the presence of Mg²⁺ was hardly detected, although it is bound to pre-tRNA. Surprisingly, however, Mn²⁺ ions restored the lost Mg²⁺-dependent activity with two exceptions of the Asp52Ala and His222Ala substitutions, which abolished the activity almost completely. These results provide a piece of evidence that Asp-52 and His-222 directly contribute the proton transfer for the catalysis.     

Identification of Asp218 and Asp326 as the principal Mg2+ binding ligands of the homing endonuclease PI-SceI

The monomeric homing endonuclease PI-SceI harbors two catalytic centers which cooperate in the cleavage of the two strands of its extended recognition sequence. Structural and biochemical data suggest that catalytic center I contains Asp218, Asp229, and Lys403, while catalytic center II contains Asp326, Thr341, and Lys301. The analogy with I-CreI, for which the cocrystal structure with the DNA substrate has been determined, suggests that Asp218 and Asp229 in catalytic center I and Asp326 and Thr341 in catalytic center II serve as ligands for Mg(2+), the essential divalent metal ion cofactor which can be replaced by Mn(2+) in vitro. We have carried out a mutational analysis of these presumptive Mg(2+) ligands. The variants carrying an alanine or asparagine substitution bind DNA, but (with the exception of the D229N variant) are inactive in DNA cleavage in the presence of Mg(2+), demonstrating that these residues are important for cleavage. Our finding that the PI-SceI variants carrying single cysteine substitutions at these positions are inactive in the presence of the oxophilic Mg(2+) but active in the presence of the thiophilic Mn(2+) suggests that the amino acid residues at these positions are involved in cofactor binding. From the fact that in the presence of Mn(2+) the D218C and D326C variants are even more active than the wild-type enzyme, it is concluded that Asp218 and Asp326 are the principal Mg(2+) ligands of PI-SceI. On the basis of these findings and the available structural information, a model for the composition of the two Mg(2+) binding sites of PI-SceI is proposed.     

Identification of the magnesium ion binding site in the catalytic center of Escherichia coli primase by iron cleavage

Magnesium is essential for the catalysis reaction of Escherichia coli primase, the enzyme synthesizing primer RNA chains for initiation of DNA replication. To map the Mg(2+) binding site in the catalytic center of primase, we have employed the iron cleavage method in which the native bound Mg(2+) ions were replaced with Fe(2+) ions and the protein was then cleaved in the vicinity of the metal binding site by adding DTT which generated free hydroxyl radicals from the bound iron. Three Fe(2+) cleavages were generated at sites designated I, II, and III. Adding Mg(2+) or Mn(2+) ions to the reaction strongly inhibited Fe(2+) cleavage; however, adding Ca(2+) or Ba(2+) ions had much less effect. Mapping by chemical cleavage and subsequent site-directed mutagensis demonstrated that three acidic residues, Asp345 and Asp347 of a conserved DPD sequence and Asp269 of a conserved EGYMD sequence, were the amino acid residues that chelated Mg(2+) ions in the catalytic center of primase. Cleavage data suggested that binding to D345 is significantly stronger than to D347 and somewhat stronger than to D269.     

Mechanism of action of Escherichia coli ribonuclease III. Stringent chemical requirement for the glutamic acid 117 side chain and Mn2+ rescue of the Glu117Asp mutant

Escherichia coli ribonuclease III (EC 3.1.24) is a double-strand- (ds-) specific endoribonuclease involved in the maturation and decay of cellular, phage, and plasmid RNAs. RNase III is a homodimer and requires Mg(2+) to hydrolyze phosphodiesters. The RNase III polypeptide contains an N-terminal catalytic (nuclease) domain which exhibits eight highly conserved acidic residues, at least one of which (Glu117) is important for phosphodiester hydrolysis but not for substrate binding [Li and Nicholson (1996) EMBO J. 15, 1421-1433]. To determine the side chain requirements for activity, Glu117 was changed to glutamine or aspartic acid. The mutant proteins were purified as (His)(6)-tagged species, and both exhibited normal homodimeric behavior as shown by chemical cross-linking. The Glu117Gln mutant is unable to cleave substrate in vitro under all tested conditions but can bind substrate. The Glu117Asp mutant also is defective in cleavage while able to bind substrate. However, low level activity is observed at extended reaction times and high enzyme concentrations, with an estimated catalytic efficiency approximately 15 000-fold lower than that of RNase III. The activity of the Glu117Asp mutant but not that of the Glu117Gln mutant can be greatly enhanced by substituting Mn(2+) for Mg(2+), with the catalytic efficiency of the Glu117Asp-Mn(2+) holoenzyme approximately 400-fold lower than that of the RNase III-Mn(2+) holoenzyme. For RNase III, a Mn(2+) concentration of 1 mM provides optimal activity, while concentrations >5 mM are inhibitory. In contrast, the Glu117Asp mutant is not inhibited by high concentrations of Mn(2+). Finally, high concentrations of Mg(2+) do not inhibit RNase III nor relieve the Mn(2+)-dependent inhibition. In summary, these experiments establish the stringent functional requirement for a precisely positioned carboxylic acid group at position 117 and reveal two classes of divalent metal ion binding sites on RNase III. One site binds either Mg(2+) or Mn(2+) and supports catalysis, while the other site is specific for Mn(2+) and confers inhibition. Glu117 is important for the function of both sites. The implications of these findings on the RNase III catalytic mechanism are discussed.     

Metal requirements and phosphodiesterase activity of tRNase Z enzymes

The endonuclease tRNase Z from A. thaliana (AthTRZ1) was originally isolated for its tRNA 3' processing activity. Here we show that AthTRZ1 also hydrolyzes the phosphodiester bond in bis(p-nitrophenyl) phosphate (bpNPP) with a kcat of 7.4 s-1 and a KM of 8.5 mM. We analyzed 22 variants of AthTRZ1 with respect to their ability to hydrolyze bpNPP. This mutational mapping identified fourteen variants that lost the ability to hydrolyze bpNPP and seven variants with reduced activity. Surprisingly, a single amino acid change (R252G) resulted in a ten times higher activity compared to the wild type enzyme. tRNase Z enzymes exist in long and short forms. We show here that in contrast to the short tRNase Z enzyme AthTRZ1, the long tRNase Z enzymes do not have bpNPP hydrolysis activity pointing to fundamental differences in substrate cleavage between the two enzyme forms. Furthermore, we determined the metal content of AthTRZ1 and analyzed the metal requirement for bpNPP hydrolysis. AthTRZ1 shows a high affinity for Zn2+ ions; even upon incubation with metal chelators, 0.76 Zn2+ ions are retained per dimer. In contrast to bpNPP hydrolysis, pre-tRNA processing requires additional metal ions, Mn2+ or Mg2+, as Zn2+ ions alone are insufficient.     

Residues in two homology blocks on the amino side of the tRNase Z His domain contribute unexpectedly to pre-tRNA 3' end processing

tRNase Z, which can endonucleolytically remove pre-tRNA 3'-end trailers, possesses the signature His domain (HxHxDH; Motif II) of the beta-lactamase family of metal-dependent hydrolases. Motif II combines with Motifs III-V on its carboxy side to coordinate two divalent metal ions, constituting the catalytic core. The PxKxRN loop and Motif I on the amino side of Motif II have been suggested to modulate tRNase Z activity, including the anti-determinant effect of CCA in mature tRNA. Ala walks through these two homology blocks reveal residues in which the substitutions unexpectedly reduce catalytic efficiency. While substitutions in Motif II can drastically affect k(cat) without affecting k(M), five- to 15-fold increases in k(M) are observed with substitutions in several conserved residues in the PxKxRN loop and Motif I. These increases in k(M) suggest a model for substrate binding. Expressed tRNase Z processes mature tRNA with CCA at the 3' end approximately 80 times less efficiently than a pre-tRNA possessing natural sequence of the 3'-end trailer, due to reduced k(cat) with no effect on k(M), showing the CCA anti-determinant to be a characteristic of this enzyme.     

tRNase Z catalysis and conserved residues on the carboxy side of the His cluster

tRNAs are transcribed as precursors and processed in a series of required reactions leading to aminoacylation and translation. The 3'-end trailer can be removed by the pre-tRNA processing endonuclease tRNase Z, an ancient, conserved member of the beta-lactamase superfamily of metal-dependent hydrolases. The signature sequence of this family, the His domain (HxHxDH, Motif II), and histidines in Motifs III and V and aspartate in Motif IV contribute seven side chains for the coordination of two divalent metal ions. We previously investigated the effects on catalysis of substitutions in Motif II and in the PxKxRN loop and Motif I on the amino side of Motif II. Herein, we present the effects of substitutions on the carboxy side of Motif II within Motifs III, IV, the HEAT and HST loops, and Motif V. Substitution of the Motif IV aspartate reduces catalytic efficiency more than 10,000-fold. Histidines in Motif III, V, and the HST loop are also functionally important. Strikingly, replacement of Glu in the HEAT loop with Ala reduces efficiency by approximately 1000-fold. Proximity and orientation of this Glu side chain relative to His in the HST loop and the importance of both residues for catalysis suggest that they function as a duo in proton transfer at the final stage of reaction, characteristic of the tRNase Z class of RNA endonucleases.     

Studies on the metal binding sites in the catalytic domain of beta1,4-galactosyltransferase

The catalytic domain of bovine beta1,4-galactosyltransferase (beta4Gal-T1) has been shown to have two metal binding sites, each with a distinct binding affinity. Site I binds Mn(2+) with high affinity and does not bind Ca(2+), whereas site II binds a variety of metal ions, including Ca(2+). The catalytic region of beta4Gal-T1 has DXD motifs, associated with metal binding in glycosyltransferases, in two separate sequences: D(242)YDYNCFVFSDVD(254) (region I) and W(312)GWGGEDDD(320) (region II). Recently, the crystal structure of beta4Gal-T1 bound with UDP, Mn(2+), and alpha-lactalbumin was determined in our laboratory. It shows that in the primary metal binding site of beta4Gal-T1, the Mn(2+) ion, is coordinated to five ligands, two supplied by the phosphates of the sugar nucleotide and the other three by Asp254, His347, and Met344. The residue Asp254 in the D(252)VD(254) sequence in region I is the only residue that is coordinated to the Mn(2+) ion. Region II forms a loop structure and contains the E(317)DDD(320) sequence in which residues Asp318 and Asp319 are directly involved in GlcNAc binding. This study, using site-directed mutagenesis, kinetic, and binding affinity analysis, shows that Asp254 and His347 are strong metal ligands, whereas Met344, which coordinates less strongly, can be substituted by alanine or glutamine. Specifically, substitution of Met344 to Gln has a less severe effect on the catalysis driven by Co(2+). Glu317 and Asp320 mutants, when partially activated by Mn(2+) binding to the primary site, can be further activated by Co(2+) or inhibited by Ca(2+), an effect that is the opposite of what is observed with the wild-type enzyme.     

Two archaeal tRNase Z enzymes: similar but different

The endoribonuclease tRNase Z plays an essential role in tRNA metabolism by removal of the 3' trailer element of precursor RNAs. To investigate tRNA processing in archaea, we identified and expressed the tRNase Z from Haloferax volcanii, a halophilic archaeon. The recombinant enzyme is a homodimer and efficiently processes precursor tRNAs. Although the protein is active in vivo at 2-4 M KCl, it is inhibited by high KCl concentrations in vitro, whereas 2-3 M (NH(4))(2)SO(4) do not inhibit tRNA processing. Analysis of the metal content of the metal depleted tRNase Z revealed that it still contains 0.4 Zn(2+) ions per dimer. In addition tRNase Z requires Mn(2+) ions for processing activity. We compared the halophilic tRNase Z to the homologous one from Pyrococcus furiosus, a thermophilic archaeon. Although both enzymes have 46% sequence similarity, they differ in their optimal reaction conditions. Both archaeal tRNase Z proteins process mitochondrial pre-tRNAs. Only the thermophilic tRNase Z shows in addition activity toward intron containing pre-tRNAs, 5' extended precursors, the phosphodiester bis(p-nitrophenyl)phosphate (bpNPP) and the glyoxalase II substrate S-D: -lactoylglutathion (SLG).     

Identification of single Mn(2+) binding sites required for activation of the mutant proteins of E.coli RNase HI at Glu48 and/or Asp134 by X-ray crystallography

Escherichia coli RNase HI has two Mn(2+)-binding sites. Site 1 is formed by Asp10, Glu48, and Asp70, and site 2 is formed by Asp10 and Asp134. Site 1 and site 2 have been proposed to be an activation site and an attenuation site, respectively. However, Glu48 and Asp134 are dispensable for Mn(2+)-dependent activity. In order to identify the Mn(2+)-binding sites of the mutant proteins at Glu48 and/or Asp134, the crystal structures of the mutant proteins E48A-RNase HI*, D134A-RNase HI*, and E48A/D134N-RNase HI* in complex with Mn(2+) were determined. In E48A-RNase HI*, Glu48 and Lys87 are replaced by Ala. In D134A-RNase HI*, Asp134 and Lys87 are replaced by Ala. In E48A/D134N-RNase HI*, Glu48 and Lys87 are replaced by Ala and Asp134 is replaced by Asn. All crystals had two or four protein molecules per asymmetric unit and at least two of which had detectable manganese ions. These structures indicated that only one manganese ion binds to the various positions around the center of the active-site pocket. These positions are different from one another, but none of them is similar to site 1. The temperature factors of these manganese ions were considerably larger than those of the surrounding residues. These results suggest that the first manganese ion required for activation of the wild-type protein fluctuates among various positions around the center of the active-site pockets. We propose that this fluctuation is responsible for efficient hydrolysis of the substrates by the protein (metal fluctuation model). The binding position of the first manganese ion is probably forced to shift to site 1 or site 2 upon binding of the second manganese ion.     

Catalytic mechanism of endonuclease v: a catalytic and regulatory two-metal model

The enzyme endonuclease V initiates repair of deaminated DNA bases by making an endonucleolytic incision on the 3' side one nucleotide from a base lesion. In this study, we have used site-directed mutagenesis to characterize the role of the highly conserved residues D43, E89, D110, and H214 in Thermotoga maritima endonuclease V catalysis. DNA cleavage and Mn(2+)-rescue analysis suggest that amino acid substitutions at D43 impede the enzymatic activity severely while mutations at E89 and D110 may be tolerated. Mutations at H214 yield enzyme that maintains significant DNA cleavage activity. The H214D mutant exhibits little change in substrate specificity or DNA cleavage kinetics, suggesting the exchangeability between His and Asp at this site. DNA binding analysis implicates the involvement of the four residues in metal binding. Mn(2+)-mediated cleavage of inosine-containing DNA is stimulated by the addition of Ca(2+), a metal ion that does not support catalysis. The effects of Mn(2+) on Mg(2+)-mediated DNA cleavage show a complexed initial stimulatory and later inhibitory pattern. The data obtained from the dual metal ion analyses lead to the notion that two metal ions are involved in endonuclease V-mediated catalysis. A catalytic and regulatory two-metal model is proposed.     

Effects of active site mutations on the metal binding affinity, catalytic competence, and stability of the family II pyrophosphatase from Bacillus subtilis

Family II inorganic pyrophosphatases (PPases) have been recently found in a variety of bacteria. Their primary and tertiary structures differ from those of the well-known family I PPases, although both have a binuclear metal center directly involved in catalysis. Here, we examined the effects of mutating one Glu, four His, and five Asp residues forming or close to the metal center on Mn(2+) binding affinity, catalysis, oligomeric structure, and thermostability of the family II PPase from Bacillus subtilis (bsPPase). Mutations H9Q, D13E, D15E, and D75E in two metal-binding subsites caused profound (10(4)- to 10(6)-fold) reductions in the binding affinity for Mn(2+). Most of the mutations decreased k(cat) for MgPP(i) by 2-3 orders of magnitude when measured with Mn(2+) or Mg(2+) bound to the high-affinity subsite and Mg(2+) bound to both the low-affinity subsite and pyrophosphate. In the E78D variant, the k(cat) for the Mn-bound enzyme was decreased 120-fold, converting bsPPase from an Mn-specific to an Mg-specific enzyme. K(m) values were less affected by the mutations, and, interestingly, were decreased in most cases. Mutations of His(97) and His(98) residues, which lie near the subunit interface, greatly destabilized the bsPPase dimer, whereas most other mutations stabilized it. Mn(2+), in sharp contrast to Mg(2+), conferred high thermostability to wild-type bsPPase, although this effect was reduced by all of the mutations except D203E. These results indicate that family II PPases have a more integrated active site structure than family I PPases and are consequently more sensitive to conservative mutations.     

The role of Asp42 in Escherichia coli inorganic pyrophosphatase functioning.

Excess of Mg2+ ions is known to inhibit the soluble inorganic pyrophosphatases (PPases). In contrast, the mutant Escherichia coli inorganic pyrophosphatase Asp42-->Asn is three times more active than native and retains its activity at high Mg2+ concentration. In this paper, another two mutant variants with Asp42 replaced by Ala or Glu were investigated to characterize the role of Asp42 in catalysis. pH-independent kinetic parameters of MgPPi hydrolysis and the dissociation constants for the activating and inhibitory Mg2+ ions were calculated. It was shown that Mg2+ inhibition of MgPPi hydrolysis by native PPase exhibited uncompetitive kinetics under the saturating substrate concentration. All three substitutions of Asp42 lead to a sharp decrease of inhibitory Mg2+ affinity to the enzyme. These findings allow determination of the sites of inhibitory and substrate Mg2+ ions binding to PPase. Common features of these mutants allow the conclusion that the function of Asp42 is to accurately coordinate the residues implicated in the substrate and the inhibitory Mg2+ ion binding to PPase active site. Structural analysis of PPase complexed with Mg2+ compared with PPase complexed with Mn2+ and reaction products confirms this supposition.     

Site-directed mutagenesis of the bacterial metalloamidase UDP-(3-O-acyl)-N-acetylglucosamine deacetylase (LpxC). Identification of the zinc binding site

UDP-3-O-(acyl)-N-acetylglucosamine deacetylase (LpxC) catalyzes the second step in the biosynthesis of lipid A in Gram-negative bacteria. Compounds targeting this enzyme are proposed to chelate the single, essential zinc ion bound to LpxC and have been demonstrated to stop the growth of Escherichia coli. A comparison of LpxC sequences from diverse bacteria identified 10 conserved His, Asp, and Glu residues that might play catalytic roles. Each amino acid was altered in both E. coli and Aquifex aeolicus LpxC and the catalytic activities of the variants were determined. Three His and one Asp residues (H79, H238, D246, and H265) are essential for catalysis based on the low activities (<0.1% of wild-type LpxC) of mutants with alanine substitutions at these positions. H79 and H238 likely coordinate zinc; the Zn(2+) content of the purified variant proteins is low and the specific activity is enhanced by the addition of Zn(2+). The third side chain to coordinate zinc is likely either H265 or D246 and a fourth ligand is likely a water molecule, as indicated by the hydroxamate inhibition, suggesting a His(3)H(2)O or His(2)AspH(2)O Zn(2+)-polyhedron in LpxC. The decreased zinc inhibition of LpxC mutants at E78 suggests that this side chain may coordinate a second, inhibitory Zn(2+) ion. Given the absence of any known Zn(2+) binding motifs, the active site of LpxC may have evolved differently than other well-studied zinc metalloamidases, a feature that should aid in the design of safe antibiotics.     

Insights into the interaction of human arginase II with substrate and manganese ions by site-directed mutagenesis and kinetic studies. Alteration of substrate specificity by replacement of Asn149 with Asp

To examine the interaction of human arginase II (EC 3.5.3.1) with substrate and manganese ions, the His120Asn, His145Asn and Asn149Asp mutations were introduced separately. About 53% and 95% of wild-type arginase activity were expressed by fully manganese activated species of the His120Asn and His145Asn variants, respectively. The K(m) for arginine (1.4-1.6 mM) was not altered and the wild-type and mutant enzymes were essentially inactive on agmatine. In contrast, the Asn149Asp mutant expressed almost undetectable activity on arginine, but significant activity on agmatine. The agmatinase activity of Asn149Asp (K(m) = 2.5 +/- 0.2 mM) was markedly resistant to inhibition by arginine. After dialysis against EDTA, the His120Asn variant was totally inactive in the absence of added Mn(2+) and contained < 0.1 Mn(2+).subunit(-1), whereas wild-type and His145Asn enzymes were half active and contained 1.1 +/- 0.1 Mn(2+).subunit(-1) and 1.3 +/- 0.1 Mn(2+).subunit(-1), respectively. Manganese reactivation of metal-free to half active species followed hyperbolic kinetics with K(d) of 1.8 +/- 0.2 x 10(-8) M for the wild-type and His145Asn enzymes and 16.2 +/- 0.5 x 10(-8) m for the His120Asn variant. Upon mutation, the chromatographic behavior, tryptophan fluorescence properties (lambda(max) = 338-339 nm) and sensitivity to thermal inactivation were not altered. The Asn149-->Asp mutation is proposed to generate a conformational change responsible for the altered substrate specificity of arginase II. We also conclude that, in contrast with arginase I, Mn(2+) (A) is the more tightly bound metal ion in arginase II.     

Crystal structures of undecaprenyl pyrophosphate synthase in complex with magnesium, isopentenyl pyrophosphate, and farnesyl thiopyrophosphate: roles of the metal ion and conserved residues in catalysis

Undecaprenyl pyrophosphate synthase (UPPs) catalyzes the consecutive condensation reactions of a farnesyl pyrophosphate (FPP) with eight isopentenyl pyrophosphates (IPP), in which new cis-double bonds are formed, to generate undecaprenyl pyrophosphate that serves as a lipid carrier for peptidoglycan synthesis of bacterial cell wall. The structures of Escherichia coli UPPs were determined previously in an orthorhombic crystal form as an apoenzyme, in complex with Mg(2+)/sulfate/Triton, and with bound FPP. In a further search of its catalytic mechanism, the wild-type UPPs and the D26A mutant are crystallized in a new trigonal unit cell with Mg(2+)/IPP/farnesyl thiopyrophosphate (an FPP analogue) bound to the active site. In the wild-type enzyme, Mg(2+) is coordinated by the pyrophosphate of farnesyl thiopyrophosphate, the carboxylate of Asp(26), and three water molecules. In the mutant enzyme, it is bound to the pyrophosphate of IPP. The [Mg(2+)] dependence of the catalytic rate by UPPs shows that the activity is maximal at [Mg(2+)] = 1 mm but drops significantly when Mg(2+) ions are in excess (50 mm). Without Mg(2+), IPP binds to UPPs only at high concentration. Mutation of Asp(26) to other charged amino acids results in significant decrease of the UPPs activity. The role of Asp(26) is probably to assist the migration of Mg(2+) from IPP to FPP and thus initiate the condensation reaction by ionization of the pyrophosphate group from FPP. Other conserved residues, including His(43), Ser(71), Asn(74), and Arg(77), may serve as general acid/base and pyrophosphate carrier. Our results here improve the understanding of the UPPs enzyme reaction significantly.     

Identification of essential acidic residues of outer membrane protease OmpT supports a novel active site

Escherichia coli outer membrane protease OmpT has previously been classified as a serine protease with Ser(99) and His(212) as active site residues. The recently solved X-ray structure of the enzyme was inconsistent with this classification, and the involvement of a nucleophilic water molecule was proposed. Here, we substituted all conserved aspartate and glutamate residues by alanines and measured the residual enzymatic activities of the variants. Our results support the involvement of a nucleophilic water molecule that is activated by the Asp(210)/His(212) catalytic dyad. Activity is also strongly dependent on Asp(83) and Asp(85). Both may function in binding of the water molecule and/or oxyanion stabilization. The proposed mechanism implies a novel proteolytic catalytic site.     

Dispensability of glutamic acid 48 and aspartic acid 134 for Mn2+-dependent activity of Escherichia coli ribonuclease HI

The activities of the eight mutant proteins of Escherichia coli RNase HI, in which the four carboxylic amino acids (Asp(10), Glu(48), Asp(70), and Asp(134)) involved in catalysis are changed to Asn (Gln) or Ala, were examined in the presence of Mn(2+). Of these proteins, the E48A, E48Q, D134A, and D134N proteins exhibited the activity, indicating that Glu(48) and Asp(134) are dispensable for Mn(2+)-dependent activity. The maximal activities of the E48A and D134A proteins were comparable to that of the wild-type protein. However, unlike the wild-type protein, these mutant proteins exhibited the maximal activities in the presence of >100 microM MnCl(2), and their activities were not inhibited at higher Mn(2+) concentrations (up to 10 mM). The wild-type protein contains two Mn(2+) binding sites and is activated upon binding of one Mn(2+) ion at site 1 at low ( approximately 1 microM) Mn(2+) concentrations. This activity is attenuated upon binding of a second Mn(2+) ion at site 2 at high (>10 microM) Mn(2+) concentrations. The cleavage specificities of the mutant proteins, which were examined using oligomeric substrates at high Mn(2+) concentrations, were identical to that of the wild-type protein at low Mn(2+) concentrations but were different from that of the wild-type protein at high Mn(2+) concentrations. These results suggest that one Mn(2+) ion binds to the E48A, E48Q, D134A, and D134N proteins at site 1 or a nearby site with weaker affinities. The binding analyses of the Mn(2+) ion to these proteins in the absence of the substrate support this hypothesis. When Mn(2+) ion is used as a metal cofactor, the Mn(2+) ion itself, instead of Glu(48) and Asp(134), probably holds water molecules required for activity.     

Unstructured RNA is a substrate for tRNase Z

tRNase Z, which exists in almost all cells, is believed to be working primarily for tRNA 3' maturation. In Escherichia coli, however, the tRNase Z gene appears to be dispensable under normal growth conditions, and its physiological role is not clear. Here, to investigate a possibility that E. coli tRNase Z cleaves RNAs other than pre-tRNAs, we tested several unstructured RNAs for cleavage. Surprisingly, all these substrates were cleaved very efficiently at multiple sites by a recombinant E. coli enzyme in vitro. tRNase Zs from Bacillus subtilis and Thermotoga maritima also cleaved various unstructured RNAs. The E. coli and B. subtilis enzymes seem to have a tendency to cleave after cytidine or before uridine, while cleavage by the T. maritima enzyme inevitably occurred after CCA in addition to the other cleavages. Assays to determine optimal conditions indicated that metal ion requirements differ between B. subtilis and T. maritima tRNase Zs. There was no significant difference in the observed rate constant between unstructured RNA and pre-tRNA substrates, while the K(d) value of a tRNase Z/unstructured RNA complex was much higher than that of an enzyme/pre-tRNA complex. Furthermore, eukaryotic tRNase Zs from yeast, pig, and human cleaved unstructured RNA at multiple sites, but an archaeal tRNase Z from Pyrobaculum aerophilum did not.