5'-C-methylnucleoside triphosphates in the reaction of RNA synthesis catalyzed by Escherichia coli RNA-polymerase

It was shown that RNA-polymerase is able to discriminate diastereoisomers of 5'-methyl-substituted analogs of ribonucleoside triphosphates (rNTP). Under conditions of soil substrate reactions when the analog is added to the presynthesized ternary complexes, D-allo- and L-talo-stereoisomers incorporate into RNA 100 and 1000 times, respectively, less effectively, then the natural rNTP. The effectivities of incorporation of other 2'- and 3'-substituted analogs of rNTP were measured under the same conditions and compared with that for 5'-Me-rNTP. It was shown also that RNA-polymerase does not support long-chain RNA synthesis from 5'-Me-rNTP in the absence of natural rNTP. No more then two analog residues can be attached to the 3'-end of the presynthesized RNA under such conditions. Addition of one natural rNTP to this reaction mixture results in the synthesis of long alternating RNA containing D-allo-stereoisomer and natural rNTP residues. In the case of L-talo-stereoisomer RNA elongation is not inhibited, if the distance between the analog residues in the RNA chain is not shorter then five nucleotide residues. The rate of pyrophosphorolysis from the RNA of the analogs studied was the same as for the natural rNTP residues.     

Manganese ions induce miscleavage in the Escherichia coli RNase P RNA-catalyzed reaction.

Cleavage by the endoribonuclease RNase P requires the presence of divalent metal ions, of which Mg2+ promotes most efficient cleavage. Here we have studied the importance of there being Mg2+ in RNase P RNA catalysis. It is demonstrated that addition of Mn2+ resulted in a shift of the cleavage site and that this shift was associated with a change in the kinetic constants, in particular kcat. Our data further suggest that the influence of Mn2+ on cleavage site recognition depends on the -1/+73 base-pair in the substrate and the +73/294 base-pair in the RNase P RNA-substrate (RS)-complex. Based on our data we suggest that cleavage in the presence of Mg2+ as the only divalent metal ion proceeds through an intermediate which involves the establishment of the +73/294 base-pair in the RS-complex. By contrast, addition of Mn2+ favours an alternative pathway which results in a shift of the cleavage site. We also studied the influence of Mn2+ on cleavage site recognition and the kinetics of cleavage using various RNase P RNA derivatives carrying substitutions in the region of RNase P RNA that base-pair with the 3' terminal end of the substrate. From these results we conclude that a change in the structure of this RNase P RNA domain influences the involvement of a divalent metal ion(s) in the chemistry of cleavage.     

The precursor tRNA 3'-CCA interaction with Escherichia coli RNase P RNA is essential for catalysis by RNase P in vivo

The L15 region of Escherichia coli RNase P RNA forms two Watson-Crick base pairs with precursor tRNA 3'-CCA termini (G292-C75 and G293-C74). Here, we analyzed the phenotypes associated with disruption of the G292-C75 or G293-C74 pair in vivo. Mutant RNase P RNA alleles (rnpBC292 and rnpBC293) caused severe growth defects in the E. coli rnpB mutant strain DW2 and abolished growth in the newly constructed mutant strain BW, in which chromosomal rnpB expression strictly depended on the presence of arabinose. An isosteric C293-G74 base pair, but not a C292-G75 pair, fully restored catalytic performance in vivo, as shown for processing of precursor 4.5S RNA. This demonstrates that the base identity of G292, but not G293, contributes to the catalytic process in vivo. Activity assays with mutant RNase P holoenzymes assembled in vivo or in vitro revealed that the C292/293 mutations cause a severe functional defect at low Mg2+ concentrations (2 mM), which we infer to be on the level of catalytically important Mg2+ recruitment. At 4.5 mM Mg2+, activity of mutant relative to the wild-type holoenzyme, was decreased only about twofold, but 13- to 24-fold at 2 mM Mg2+. Moreover, our findings make it unlikely that the C292/293 phenotypes include significant contributions from defects in protein binding, substrate affinity, or RNA degradation. However, native PAGE experiments revealed nonidentical RNA folding equilibria for the wild-type versus mutant RNase P RNAs, in a buffer- and preincubation-dependent manner. Thus, we cannot exclude that altered folding of the mutant RNAs may have also contributed to their in vivo defect.     

Metal ion requirements and other aspects of the reaction catalyzed by M1 RNA, the RNA subunit of ribonuclease P from Escherichia coli

M1 RNA, the RNA subunit of ribonuclease P from Escherichia coli, can under certain conditions catalytically cleave precursors to tRNA in the absence of C5, the protein moiety of RNase P. M1 RNA itself is not cleaved during the reaction, nor does it form any covalent bonds with its substrate. Only magnesium and, to a lesser extent, manganese ions can function at the catalytic center of M1 RNA. Several other ions either inhibit the binding of magnesium ion at the active site or function as structural counterions. The reaction rate of cleavage of precursors to tRNAs by M1 RNA is enhanced in the presence of poly-(ethylene glycol) or 2-methyl-2,4-pentanediol. Many aspects of the reaction catalyzed by M1 RNA are compatible with a mechanism in which phosphodiester bond cleavage is mediated by metal ion.     

Complementation of an RNase P RNA (rnpB) gene deletion in Escherichia coli by homologous genes from distantly related eubacteria.

We report the construction of a strain of Escherichia coli in which the only functional gene for the RNA moiety of RNase P (rnpB) resides on a plasmid that is temperature sensitive for replication. The chromosomal RNase P RNA gene was replaced with a chloramphenicol acetyltransferase gene. The conditionally lethal phenotype of this strain was suppressed by plasmids that carry RNase P RNA genes from some distantly related eubacteria, including Alcaligenes eutrophus, Bacillus subtilis, and Chromatium vinosum. Thus, the rnpB genes from these organisms are capable of functioning as the sole source of RNase P RNA in E. coli. The rnpB genes of some other organisms (Agrobacterium tumefaciens, Pseudomonas fluorescens, Bacillus brevis, Bacillus megaterium, and Bacillus stearothermophilus) could not replace the E. coli gene. The significance of these findings as they relate to RNase P RNA structure and function and the utility of the described strain for genetic studies are discussed.     

G350 of Escherichia coli RNase P RNA contributes to Mg2+ binding near the active site of the enzyme

G350 of Escherichia coli RNase P RNA is a highly conserved residue among all bacteria and lies near the known magnesium binding site for the RNase P ribozyme, helix P4. Mutations at G350 have a dramatic effect on substrate cleavage activity for both RNA alone and holoenzyme; the G350C mutation has the most severe phenotype. The G350C mutation also inhibits growth of cells that express the mutant RNA in vivo under conditions of magnesium starvation. The results suggest that G350 contributes to Mg(2+) binding at helix P4 of RNase P RNA.     

Substrate properties of C'-methylnucleoside triphosphates in a reaction of RNA synthesis catalyzed by Escherichia coli RNA-polymerase

2 theta-C-methyl substituted and phosphonate analogs of UTP were prepared and together with the synthesized earlier 3'-C-methyl-UTP were investigated in the RNA synthesis reaction catalysed by Escherichia coli RNA-polymerase. Substrate properties of UTP analogs were studied in the presence of all natural triphosphates, in the absence of UTP and under conditions of soil substrate reaction. It was shown that UTP(3'CH3) is incorporated into the RNA chain and terminates further RNA elongation. Another analog UTP (2'CH3) may substitute natural UTP in RNA synthesis, but the effectivity of its incorporation is diminished. Phosphonate analog UTP(5'CH2) is a pseudoterminator of RNA synthesis. The conformational analysis of 2'- and 3'C-methylnucleosides by force-field method of calculation was carried out in order to find energetically forbidden conformations of these analogs due to the collision of bulky methyl group and a heterocyclic base. An attempt was made to fix the conformation of the substrate during its enzymatic transformation.     

Monitoring the structure of Escherichia coli RNase P RNA in the presence of various divalent metal ions

Lead(II)-induced cleavage can be used as a tool to probe conformational changes in RNA. In this report, we have investigated the conformation of M1 RNA, the catalytic subunit of Escherichia coli RNase P, by studying the lead(II)-induced cleavage pattern in the presence of various divalent metal ions. Our data suggest that the overall conformation of M1 RNA is very similar in the presence of Mg(2+), Mn(2+), Ca(2+), Sr(2+) and Ba(2+), while it is changed compared to the Mg(2+)-induced conformation in the presence of other divalent metal ions, Cd(2+) for example. We also observed that correct folding of some M1 RNA domains is promoted by Pb(2+), while folding of other domain(s) requires the additional presence of other divalent metal ions, cobalt(III) hexamine or spermidine. Based on the suppression of Pb(2+) cleavage at increasing concentrations of various divalent metal ions, our findings suggest that different divalent metal ions bind with different affinities to M1 RNA as well as to an RNase P hairpin-loop substrate and yeast tRNA(Phe). We suggest that this approach can be used to obtain information about the relative binding strength for different divalent metal ions to RNA in general, as well as to specific RNA divalent metal ion binding sites. Of those studied in this report, Mn(2+) is generally among the strongest RNA binders.     

Interaction between Escherichia coli RNase P RNA and the discriminator base results in slow product release.

We suggested previously that a purine at the discriminator base position in a tRNA precursor interacts with the well-conserved U294 in M1 RNA, the catalytic subunit of Escherichia coli RNase P. Here we investigated this interaction and its influence on the kinetics of cleavage as well as on cleavage site selection. The discriminator base in precursors to tRNA(Tyr)Su3 and tRNA(Phe) was changed from A to C and cleavage kinetics were studied by wild-type M1 RNA and a mutant M1 RNA carrying the compensatory substitution of a U to a G at position 294 in M1 RNA. Our data suggest that the discriminator base interacts with the residue at position 294 in M1 RNA. Although product release is a rate-limiting step both in the absence and in the presence of this interaction, its presence results in a significant reduction in the rate of product release. In addition, we studied cleavage site selection on various tRNA(His) precursor derivatives. These precursors carry a C at the discriminator base position. The results showed that the mutant M1 RNA harboring a G at position 294 miscleaved a wild-type tRNA(His) precursor and a tRNA(His) precursor carrying an inosine at the cleavage site. The combined data suggest a functional interaction between the discriminator base and the well-conserved U294 in M1 RNA. This interaction is suggested to play an important role in determining the rate of product release during multiple turnover cleavage of tRNA precursors by M1 RNA as well as in cleavage site selection.     

Mechanism of the reaction catalyzed by isoaspartyl dipeptidase from Escherichia coli

Isoaspartyl dipeptidase (IAD) is a member of the amidohydrolase superfamily and catalyzes the hydrolytic cleavage of beta-aspartyl dipeptides. Structural studies of the wild-type enzyme have demonstrated that the active site consists of a binuclear metal center positioned at the C-terminal end of a (beta/alpha)(8)-barrel domain. Steady-state kinetic parameters for the hydrolysis of beta-aspartyl dipeptides were obtained at pH 8.1. The pH-rate profiles for the hydrolysis of beta-Asp-Leu were obtained for the Zn/Zn-, Co/Co-, Ni/Ni-, and Cd/Cd-substituted forms of IAD. Bell-shaped profiles were observed for k(cat) and k(cat)/K(m) as a function of pH for all four metal-substituted forms. The pK(a) of the group that must be unprotonated for catalytic activity varied according to the specific metal ion bound in the active site, whereas the pK(a) of the group that must be protonated for catalytic activity was relatively independent of the specific metal ion present. The identity of the group that must be unprotonated for catalytic activity was consistent with the hydroxide that bridges the two divalent cations of the binuclear metal center. The identity of the group that must be protonated for activity was consistent with the free alpha-amino group of the dipeptide substrate. Kinetic constants were obtained for the mutant enzymes at conserved residues Glu77, Tyr137, Arg169, Arg233, Asp285, and Ser289. The catalytic properties of the wild-type and mutant enzymes, coupled with the X-ray crystal structure of the D285N mutant complexed with beta-Asp-His, are consistent with a chemical reaction mechanism for the hydrolysis of dipeptides that is initiated by the polarization of the amide bond via complexation to the beta-metal ion of the binuclear metal center. Nucleophilic attack by the bridging hydroxide is facilitated by abstraction of its proton by the side chain carboxylate of Asp285. Collapse of the tetrahedral intermediate and cleavage of the carbon-nitrogen bond occur with donation of a proton from the protonated form of Asp285.     

Distinct modes of mature and precursor tRNA binding to Escherichia coli RNase P RNA revealed by NAIM analyses

We have analyzed by nucleotide analog interference mapping (NAIM) pools of precursor or mature tRNA molecules, carrying a low level of Rp-RMPalphaS (R = A, G, I) or Rp-c7-deaza-RMPalphaS (R = A, G) modifications, to identify functional groups that contribute to the specific interaction with and processing efficiency by Escherichia coli RNase P RNA. The majority of interferences were found in the acceptor stem, T arm, and D arm, including the strongest effects observed at positions G19, G53, A58, and G71. In some cases (interferences at G5, G18, and G71), the affected functional groups are candidates for direct contacts with RNase P RNA. Several modifications disrupt intramolecular tertiary contacts known to stabilize the authentic tRNA fold. Such indirect interference effects were informative as well, because they allowed us to compare the structural constraints required for ptRNA processing versus product binding. Our ptRNA processing and mature tRNA binding NAIM analyses revealed overlapping but nonidentical patterns of interference effects, suggesting that substrate binding and cleavage involves binding modes or conformational states distinct from the binding mode of mature tRNA, the product of the reaction.     

Maturation of precursor 10Sa RNA in Escherichia coli is a two-step process: the first reaction is catalyzed by RNase III in presence of Mn2+.

A precursor to 10Sa RNA accumulates in an rne mutant. However, the present studies indicate that RNase III is the enzyme that processes this RNA. Cell extracts prepared from an rne mutant failed to cleave p10Sa RNA, whereas E coli wild type, rne and rnp cell extracts processed p10Sa RNA under specific assay conditions that require the presence of Mn2+ but not under the customary conditions used for assaying RNase III. That the p10Sa cleaving activity is solely RNase III was confirmed by comparing the increase in p10Sa and poly(A).poly(U) cleaving activities in a strain harboring a plasmid carrying an RNase III gene as compared to a normal E coli strain. It is of interest that these 2 substrates are cleaved by RNase III efficiently, but under 2 different assay conditions. In all strains tested, with normal or elevated levels of RNase III, RNase III fractionates predominantly with the membrane. Further characterization of the maturation of 10Sa RNA revealed that the processing of 10Sa RNA is a 2 step reaction involving 2 separate activities, both sensitive to heat and proteinase K treatment. The first step is catalyzed by RNase III, and results in the formation of a molecule, p10Sa', which is larger than the mature 10Sa RNA. The second activity catalyzes the conversion of p10S' to 10Sa RNA, and this step does not require a divalent cation. The second activity is not any of the known processing endoribonucleases, RNase III, E or P, but could be a new enzyme having no obligate requirement for a divalent cation.     

Protein synthesis inhibitors and catalytic RNA. Effect of puromycin on tRNA precursor processing by the RNA component of Escherichia coli RNase P

RNase P and ribosomes must interact with similar substrate molecules, tRNA precursors in the case of RNase P and aminoacyl-, peptidyl- or free tRNAs in the case of ribosomes. In order to compare the substrate recognition mechanisms between ribosomes and RNase P, protein synthesis inhibitors have been assayed for their effect on the catalytic activity of the RNA component of Escherichia coli RNase P (M1 RNA). Puromycin has an inhibitory effect that could be related to similar substrate recognition mechanisms by rRNA in the ribosome and by M1 RNA in RNase P.     

Product release is a rate-limiting step during cleavage by the catalytic RNA subunit of Escherichia coli RNase P.

The kinetic constants for cleavage of the tRNA(Tyr)Su3 precursor by the M1 RNA of E. coli RNase P were determined in the absence and presence of the C5 protein under single and multiple (steady state) turnover conditions. The rate constant of cleavage in the reaction catalyzed by M1 RNA alone was 5 times higher in single turnover than in multiple turnovers, suggesting that a rate-limiting step is product release. Cleavage by M1 RNA alone and by the holoenzyme under identical buffer conditions demonstrated that C5 facilitated product release. Addition of different product-like molecules under single turnover reaction conditions inhibited cleavage both in the absence and presence of C5. In the presence of C5, the Ki value for matured tRNA was approximately 20 times higher than in its absence, suggesting that C5 also reduces the interaction between the 5'-matured tRNA and the enzyme. In a growing cell the number of tRNA molecules is approximately 1000 times higher than the number of RNase P molecules. A 100-fold excess of matured tRNA over enzyme clearly inhibited cleavage in vitro. We discuss the possibility that RNase P is involved in the regulation of tRNA expression under certain growth conditions.     

RNA processing enzymes RNase III, E and P in Escherichia coli are not ribosomal enzymes.

We recently showed that RNase III can process a small stable RNA, precursor 10Sa RNA, that accumulates in an rne (RNase E) strain at non-permissive temperatures. Precursor 10Sa (p10Sa) RNA is processed to 10Sa RNA in two steps, the first step is catalyzed by RNase III in the presence of Mn2+ but not Mg2+. It was shown that RNase III cosediments with membrane preparation from wild type as well as RNase III overexpressing cells. However, the possibility of membrane preparation contamination with ribosomes could not be ruled out. Here we show that RNase III, E and P are not associated with ribosomes. E. coli cells were opened either by alumina grinding or by sonication and fractionated into cytosolic and pellet fractions. The characterization of membrane preparations was done by assaying NADH oxidase, a bona fide membrane enzyme. Ribosomes prepared by alumina grinding were found to be contaminated with small fragments of membrane which contained RNase III activity. RNase III and NADH oxidase activities were present in the ribosomal preparations which could be solubilized by reagents that dissolve the inner membrane. Isopycnic sucrose gradient centrifugation of the membrane and ribosomal preparations also confirmed that RNase III fractionated with the inner membrane. Similarly RNase P activity was found in the corresponding fractions when isopycnic centrifugation of membrane and ribosome preparations was carried out. RNase E activity was also found to be present mostly in the post-ribosomal supernatant. These findings show that RNase III, E and P are not ribosomal enzymes.     

Multiple binding modes of substrate to the catalytic RNA subunit of RNase P from Escherichia coli.

M1 RNA that contained 4'-thiouridine was photochemically cross-linked to different substrates and to a product of the reaction it governs. The locations of the cross-links in these photochemically induced complexes were identified. The cross-links indicated that different substrates share some contacts but have distinct binding modes to M1 RNA. The binding of some substrates also results in a substrate-dependent conformational change in the enzymatic RNA, as evidenced by the appearance of an M1 RNA intramolecular cross-link. The identification of the cross-links between M1 RNA and product indicate that they are shared with only one of the three cross-linked E-S complexes that were identified, an indication of noncompetitive inhibition by the product. We also examined whether the cross-linked complexes between M1 RNA and substrate(s) or product are altered in the presence of the enzyme's protein cofactor (C5 protein) and in the presence of different concentrations of divalent metal ions. C5 protein enhanced the yield of certain M1 RNA-substrate cross-linked complexes for both wild-type M1 RNA and a deletion mutant of M1 RNA (delta[273-281]), but not for the M1 RNA-product complex. High concentrations of Mg2+ increased the yield of all M1 RNA-substrate complexes but not the M1 RNA-product complex.