Enhanced cleavage of RNA mediated by an interaction between substrates and the arginine-rich domain of E. coli ribonuclease E

Endonucleolytic cutting by the essential Escherichia coli ribonuclease RNaseE has a central role in both the processing and decay of RNA. Previously, it has been shown that an oligoribonucleotide corresponding in sequence to the single-stranded region at the 5' end of RNAI, the antisense regulator of ColE1-type plasmid replication, is efficiently cut by RNaseE. Combined with the knowledge that alteration of the structure of stem-loops within complex RNaseE substrates can either increase or decrease the rate of cleavage, this result has led to the notion that stem-loops do not serve as essential recognition motifs for RNaseE, but can affect the rate of cleavage indirectly by, for example, determining the single-strandedness of the site or its accessibility. We report here, however, that not all oligoribonucleotides corresponding to RNaseE-cleaved segments of complex substrates are sufficient to direct efficient RNaseE cleavage. We provide evidence using 9 S RNA, a precursor of 5 S rRNA, that binding of structured regions by the arginine-rich RNA- binding domain (ARRBD) of RNaseE can be required for efficient cleavage. Binding by the ARRBD appears to counteract the inhibitory effects of sub-optimal cleavage site sequence and overall substrate conformation. Furthermore, combined with the results from recent analyses of E. coli mutants in which the ARRBD of RNase E is deleted, our findings suggest that substrate binding by RNaseE is essential for the normal rapid decay of E. coli mRNA. The simplest interpretation of our results is that the ARRBD recruits RNaseE to structured RNAs, thereby increasing the localised concentration of the N-terminal catalytic domain, which in turn leads to an increase in the rate of cleavage.     

Short-strong hydrogen bonds and a low barrier transition state for the proton transfer reaction in RNase A catalysis: a quantum chemical study

There is growing evidence that some enzymes catalyze reactions through the formation of short-strong hydrogen bonds as first suggested by Gerlt and Gassman. Support comes from several experimental and quantum chemical studies that include correlation energies on model systems. In the present study, the process of proton transfer between hydroxyl and imidazole groups, a model of the crucial step in the hydrolysis of RNA by the enzymes of the RNase A family, is investigated at the quantum mechanical level of density functional theory and perturbation theory at the MP2 level. The model focuses on the nature of the formation of a complex between the important residues of the protein and the hydroxyl group of the substrate. We have also investigated different configurations of the ground state that are important in the proton transfer reaction. The nature of bonding between the catalytic unit of the enzyme and the substrate in the model is investigated by Bader's atoms in molecule theory. The contributions of solvation and vibrational energies corresponding to the reactant, the transition state and the product configurations are also evaluated. Furthermore, the effect of protein environment is investigated by considering the catalytic unit surrounded by complete proteins--RNase A and Angiogenin. The results, in general, indicate the formation of a short-strong hydrogen bond and the formation of a low barrier transition state for the proton transfer model of the enzyme.     

Ribozyme inhibitors: deoxyguanosine and dideoxyguanosine are competitive inhibitors of self-splicing of the Tetrahymena ribosomal ribonucleic acid precursor

The intervening sequence (IVS) of the Tetrahymena rRNA precursor catalyzes its own splicing. During splicing the 3'-hydroxyl of guanosine is ligated to the 5' terminus of the IVS. One catalytic strategy of the IVS RNA is to specifically bind its guanosine substrate. Deoxyguanosine (dG) and dideoxyguanosine (ddG) are found to be competitive inhibitors of self-splicing. Comparison of the kinetic parameters (Ki = 1.1 mM for dG; Ki = 5.4 mM for ddG; Km = 0.032 mM for guanosine) indicates that the ribose hydroxyls are necessary for optimal binding of guanosine to the RNA. dG is not a substrate for the reaction even at very high concentrations. Thus, in addition to aiding in binding, the 2'-hydroxyl is necessary for reaction of the 3'-hydroxyl. A second catalytic strategy of the IVS RNA is to enhance the reactivity of specific bonds. For example, the phosphodiester bond at the 3' splice site is extremely labile to hydrolysis. We find that dG and ddG, as well as 2'-O-methylguanosine and 3'-O-methylguanosine, reduce hydrolysis at the 3' splice site. These data are consistent with an RNA structure that brings the 5' and 3' splice sites proximal to the guanosine binding site.     

Chloroplast ribonuclease P does not utilize the ribozyme-type pre-tRNA cleavage mechanism

The transfer RNA 5' maturation enzyme RNase P has been characterized in Bacteria, Archaea, and Eukarya. The purified enzyme from all three kingdoms is a ribonucleoprotein containing an essential RNA subunit; indeed, the RNA subunit of bacterial RNase P RNA is the sole catalytic component. In contrast, the RNase P activity isolated from spinach chloroplasts lacks an RNA component and appears to function as a catalytic protein. Nonetheless, the chloroplast enzyme recognizes a pre-tRNA substrate for E. coli RNase P and cleaves it as efficiently and precisely as does the bacterial enzyme. To ascertain whether there are differences in catalytic mechanism between an all-RNA and an all-protein RNase P, we took advantage of the fact that phosphodiester bond selection and hydrolysis by the E. coli RNase P ribozyme is directed by a Mg2+ ion coordinated to the nonbridging pro-Rp oxygen of the scissile bond, and is blocked by sulfur replacement of this oxygen. We therefore tested the ability of the chloroplast enzyme to process a precursor tRNA containing this sulfur substitution. Partially purified RNase P from spinach chloroplasts can accurately and efficiently process phosphorothioate-substituted pre-tRNAs; cleavage occurs exclusively at the thio-containing scissile bond. The enzymatic throughput is fivefold slower, consistent with a general chemical effect of the phosphorothioate substitution rather than with a metal coordination deficiency. The chloroplast RNase P reaction mechanism therefore does not involve a catalytic Mg2+ bonded to the pro-Rp phosphate oxygen, and hence is distinct from the mechanism of the bacterial ribozyme RNase P.     

The protonation state of the cross-linked tyrosine during the catalytic cycle of cytochrome c oxidase

Cytochrome c oxidase is the terminal complex of the respiratory chain in mitochondria and some aerobic bacteria and is responsible for most of the O(2) consumption in biology. The key reaction in the catalysis of O(2) reduction is O-O bond scission that requires four electrons and a proton. In our recent work (Gorbikova, E. A., Belevich, I., Wikstrom, M., and Verkhovsky, M. I. (2008) Proc. Natl. Acad. Sci. U. S. A. 105, 10733-10737), it was shown that the cross-linked Tyr-280 (Paracoccus denitrificans numbering) provides the proton for O-O bond cleavage. The deprotonated Tyr-280 must be reprotonated later on in the catalytic cycle to serve as a proton donor for the next oxygen reduction event. To find the reaction step at which the cross-linked Tyr-280 becomes reprotonated, all further steps of the catalytic cycle after O-O bond cleavage were followed by infrared spectroscopy. We found that complete reprotonation of the tyrosine is linked to the formation of the one-electron reduced state coupled to reduction of the Cu(B) site.     

The ribosomal peptidyl transferase

Peptide bond formation on the ribosome takes place in an active site composed of RNA. Recent progress of structural, biochemical, and computational approaches has provided a fairly detailed picture of the catalytic mechanism of the reaction. The ribosome accelerates peptide bond formation by lowering the activation entropy of the reaction due to positioning the two substrates, ordering water in the active site, and providing an electrostatic network that stabilizes the reaction intermediates. Proton transfer during the reaction appears to be promoted by a concerted proton shuttle mechanism that involves ribose hydroxyl groups on the tRNA substrate.     

Reactions of the intervening sequence of the Tetrahymena ribosomal ribonucleic acid precursor: pH dependence of cyclization and site-specific hydrolysis

During self-splicing of the Tetrahymena rRNA precursor, the intervening sequence (IVS) is excised as a unique linear molecule and subsequently cyclized. Cyclization involves formation of a phosphodiester bond between the 3' end and nucleotide 16 of the linear RNA, with release of an oligonucleotide containing the first 15 nucleotides. We find that the rate of cyclization is independent of pH in the range 4.7-9.0. A minor site of cyclization at nucleotide 20 is characterized. Cyclization to this site becomes more prominent at higher pHs, although under all conditions examined it is minor compared to cyclization at nucleotide 16. The circular IVS RNAs are unstable, undergoing hydrolysis at the phosphodiester bond that was formed during cyclization. We find that the rate of site-specific hydrolysis is first order with respect to hydroxide ion concentration, with a rate constant 10(3)-10(4)-fold greater than that of hydrolysis of strained cyclic phosphate esters. On the basis of these results, we propose that circular IVS RNA hydrolysis involves direct attack of OH- on the phosphate at the ligation junction, that particular phosphate being made particularly reactive by the folding of the RNA molecule. Cyclization, on the other hand, appears to occur by direct attack of the 3'-terminal hydroxyl group of the linear IVS RNA without prior deprotonation.     

Histidine triad-like motif of the rotavirus NSP2 octamer mediates both RTPase and NTPase activities

Rotavirus NSP2 is an abundant non-structural RNA-binding protein essential for forming the viral factories that support replication of the double-stranded RNA genome. NSP2 exists as stable doughnut-shaped octamers within the infected cell, representing the tail-to-tail interaction of two tetramers. Extending diagonally across the surface of each octamer are four highly basic grooves that function as binding sites for single-stranded RNA. Between the N and C-terminal domains of each monomer is a deep electropositive cleft containing a catalytic site that hydrolyzes the gamma-beta phosphoanhydride bond of any NTP. The catalytic site has similarity to those of the histidine triad (HIT) family of nucleotide-binding proteins. Due to the close proximity of the grooves and clefts, we investigated the possibility that the RNA-binding activity of the groove promoted the insertion of the 5'-triphosphate moiety of the RNA into the cleft, and the subsequent hydrolysis of its gamma-beta phosphoanhydride bond. Our results show that NSP2 hydrolyzes the gammaP from RNAs and NTPs through Mg(2+)-dependent activities that proceed with similar reaction velocities, that require the catalytic His225 residue, and that produce a phosphorylated intermediate. Competition assays indicate that although both substrates enter the active site, RNA is the preferred substrate due to its higher affinity for the octamer. The RNA triphosphatase (RTPase) activity of NSP2 may account for the absence of the 5'-terminal gammaP on the (-) strands of the double-stranded RNA genome segments. This is the first report of a HIT-like protein with a multifunctional catalytic site, capable of accommodating both NTPs and RNAs during gammaP hydrolysis.     

Self-catalyzed linkage of poliovirus terminal protein VPg to poliovirus RNA

The poliovirus terminal protein, VPg, was covalently linked to poliovirus RNA in a reaction that required synthetic VPg, Mg2+, and a replication intermediate synthesized in vitro. The VPg linkage reaction did not require the viral polymerase, host factor, or ribonucleoside triphosphates and was specific for template-linked minus-strand RNA synthesized on poliovirion RNA. The covalent nature of the bond between VPg and the RNA was demonstrated by the isolation of VPg-pUp from VPg-linked RNA. A model is proposed in which the tyrosine residue in VPg forms a phosphodiester bond with the 5'UMP in minus-strand RNA in a self-catalyzed transesterification reaction. It appears that either the RNA, VPg, or a combination of both forms the catalytic center for this reaction.     

Diversification of function in the haloacid dehalogenase enzyme superfamily: The role of the cap domain in hydrolytic phosphoruscarbon bond cleavage

Phosphonatase functions in the 2-aminoethylphosphonate (AEP) degradation pathway of bacteria, catalyzing the hydrolysis of the C-P bond in phosphonoacetaldehyde (Pald) via formation of a bi-covalent Lys53ethylenamine/Asp12 aspartylphosphate intermediate. Because phosphonatase is a member of the haloacid dehalogenase superfamily, a family predominantly comprised of phosphatases, the question arises as to how this new catalytic activity evolved. The source of general acid-base catalysis for Schiff-base formation and aspartylphosphate hydrolysis was probed using pH-rate profile analysis of active-site mutants and X-ray crystallographic analysis of modified forms of the enzyme. The 2.9 A X-ray crystal structure of the mutant Lys53Arg complexed with Mg2+ and phosphate shows that the equilibrium between the open and the closed conformation is disrupted, favoring the open conformation. Thus, proton dissociation from the cap domain Lys53 is required for cap domain-core domain closure. The likely recipient of the Lys53 proton is a water-His56 pair that serves to relay the proton to the carbonyl oxygen of the phosphonoacetaldehyde (Pald) substrate upon addition of the Lys53. The pH-rate profile analysis of active-site mutants was carried out to test this proposal. The proximal core domain residues Cys22 and Tyr128 were ruled out, and the role of cap domain His56 was supported by the results. The X-ray crystallographic structure of wild-type phosphonatase reduced with NaBH4 in the presence of Pald was determined at 2.4A resolution to reveal N epsilon-ethyl-Lys53 juxtaposed with a sulfate ligand bound in the phosphate site. The position of the C2 of the N-ethyl group in this structure is consistent with the hypothesis that the cap domain N epsilon-ethylenamine-Lys53 functions as a general base in the hydrolysis of the aspartylphosphate bi-covalent enzyme intermediate. Because the enzyme residues proposed to play a key role in P-C bond cleavage are localized on the cap domain, this domain appears to have evolved to support the diversification of the HAD phosphatase core domain for catalysis of hydrolytic P-C bond cleavage.     

Modified 5'-nucleotides resistant to 5'-nucleotidase: isolation of 3-(3-amino-3-carboxypropyl) uridine 5'-phosphate and N2, N2-dimethylguanosine 5'-phosphate from snake venom hydrolysates of transfer RNA.

A procedure for the quantitative measurement of the O2'-methylnucleoside constitutents of RNA has recently been developed in this laboratory (Gray, M.W. Can. J. Biochem. 53, 735-746 (1975)). This assay method is based on the resistance of O2'-methylnucleoside 5'-phosphates (pNm) (generated by phosphodiesterase hydrolysis of RNA) to subsequent dephosphorylation by venom 5'-nucleotidase (EC 3.1.3.5). In the present investigation, two base-modified 5'-nucleotides, each displaying an unusual resistance to 5'-nucleotidase, have been identified. These compounds have been characterized by a variety of techniques as N2, N2-dimethylguanosine 5'-phosphate (pm2/2G) and 3-(3-amino-3-carboxypropyl)uridine 5'-phosphate (p4abu3U). Because of their resistance to 5'-nucleotidase, pm2/2G and p4abu3U are isolated along with the pNm in the mononucleotide fraction of venom hydrolysates of transfer RNA. Under hydrolysis conditions, the stability of p4abu3U is comparable to that of a pNm, allowing quantitative assay of the nucleotide. The proportion (mean +/- SD) of p4abu3U in venom hydrolysates of wheat embryo and Escherichia coli tRNA has been determined to be 0.35 +/- 0.03 (n=5) and 0.14 +/- 0.02 (n=4) mol%, respectively. The absence of p4abu3U in venom hydrolysates of yeast tRNA implies the absence of the corresponding nucleoside in yeast tRNA, in agreement with existing data. The variable recovery of pm2/2G from venom hydrolysates of wheat embryo and yeast tRNA indicates that under hydrolysis conditions, this base-modified nucleotide is only partially resistent to 5'-nucleotidase. The complete absence of pm2/2G in venom hydrolysates of E. coli tRNA is consistent with the known absence of N2, N2-dimethylguanosine in this RNA. These observations demonstrate that resistance to 5'-nucleotidase is a necessary but not sufficient criterion for concluding that a 5'-nucleotide is O2'-methylated. When applied to wheat embryo ribosomal RNA, the analytical methods described in this report failed to reveal any compound having the distinctive charge properties of p4abu3U. It therefore appears that 1-methyl-3-(3-amino-3-carboxypropyl)pseudouridine, recently characterized as a constituent of the 18 S rRNA of Chinese hamster cells (Saponara, A.G. & Enger, M.D. Biochim. Biophys. Acta 349, 61-77 (1974)), may not be present in wheat embryo ribosomal RNA.     

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.     

Several peculiarities of the purine-base fixation of the substrate in the active sites of myosin Ca2+-ATPase

A comparative study of kinetic parameters (Km and V) of hydrolysis by heavy meromyosin of several synthetic ATP analogs with substituents at positions N(1) and N(C6) of the purine ring was carried out. Analysis of changes in the Km values suggests that the purine base of ATP is fixed in the active center due to the formation of a hydrogen bond between N1 and the proton donor group of the protein as well as between the 6-NH2-amino group of the nucleotide and the proton acceptor group of the protein. It was shown that the rate of catalytic conversion of the substrate is determined by the mode of binding of its purine ring. Depending on the properties of the substituent radical, the latter either prevents the binding by causing little or no increase in the rate of hydrolysis or causes the displacement of the whole substrate molecule in the active center, which leads to the deceleration of hydrolysis.     

A new mechanism of post-transfer editing by aminoacyl-tRNA synthetases: catalysis of hydrolytic reaction by bacterial-type prolyl-tRNA synthetase

Aminoacyl tRNA synthetases are enzymes that specifically attach amino acids to cognate tRNAs for use in the ribosomal stage of translation. For many aminoacyl tRNA synthetases, the required level of amino acid specificity is achieved either by specific hydrolysis of misactivated aminoacyl-adenylate intermediate (pre-transfer editing) or by hydrolysis of the mischarged aminoacyl-tRNA (post-transfer editing). To investigate the mechanism of post-transfer editing of alanine by prolyl-tRNA synthetase from the pathogenic bacteria Enterococcus faecalis, we used molecular modeling, molecular dynamic simulations, quantum mechanical (QM) calculations, site-directed mutagenesis of the enzyme, and tRNA modification. The results support a new tRNA-assisted mechanism of hydrolysis of misacylated Ala-tRNA^Pro. The most important functional element of this catalytic mechanism is the 2′-OH group of the terminal adenosine 76 of Ala-tRNA^Pro, which forms an intramolecular hydrogen bond with the carbonyl group of the alanine residue, strongly facilitating hydrolysis. Hydrolysis was shown by QM methods to proceed via a general acid-base catalysis mechanism involving two functionally distinct water molecules. The transition state of the reaction was identified. Amino acid residues of the editing active site participate in the coordination of substrate and both attacking and assisting water molecules, performing the proton transfer to the 3′-O atom of A76.     

The 2'-hydroxyl group of the guanosine nucleophile donates a functionally important hydrogen bond in the tetrahymena ribozyme reaction

In the first step of self-splicing, group I introns utilize an exogenous guanosine nucleophile to attack the 5'-splice site. Removal of the 2'-hydroxyl of this guanosine results in a 10 (6)-fold loss in activity, indicating that this functional group plays a critical role in catalysis. Biochemical and structural data have shown that this hydroxyl group provides a ligand for one of the catalytic metal ions at the active site. However, whether this hydroxyl group also engages in hydrogen-bonding interactions remains unclear, as attempts to elaborate its function further usually disrupt the interactions with the catalytic metal ion. To address the possibility that this 2'-hydroxyl contributes to catalysis by donating a hydrogen bond, we have used an atomic mutation cycle to probe the functional importance of the guanosine 2'-hydroxyl hydrogen atom. This analysis indicates that, beyond its role as a ligand for a catalytic metal ion, the guanosine 2'-hydroxyl group donates a hydrogen bond in both the ground state and the transition state, thereby contributing to cofactor recognition and catalysis by the intron. Our findings continue an emerging theme in group I intron catalysis: the oxygen atoms at the reaction center form multidentate interactions that function as a cooperative network. The ability to delineate such networks represents a key step in dissecting the complex relationship between RNA structure and catalysis.     

RNaseE and RNA helicase B play central roles in the cytoskeletal organization of the RNA degradosome

The RNA degradosome of Escherichia coli is a multiprotein complex that plays an essential role in normal RNA processing and decay. It was recently shown that the major degradosome constituents are organized in a coiled cytoskeletal-like structure that extends along the length of the cell. Here we show that the endoribonuclease E (RNaseE) and RNA helicase B (RhlB) components of the degradosome can each independently form coiled structures in the absence of the other degradosome proteins. In contrast, the cytoskeletal organization of the other degradosome proteins required the presence of the RNaseE or RhlB coiled elements. Although the RNaseE and RhlB structures were equally competent to support the helical organization of polynucleotide phosphorylase, the cytoskeletal-like organization of enolase occurred only in the presence of the RNaseE coiled structure. The results indicate that the RNA degradosome proteins are components of the bacterial cytoskeleton rather than existing as randomly distributed multiprotein complexes within the cell and suggest a model for the cellular organization of the components within the helical degradosomal structure.     

Structural analysis of O2'-methyl-5-carbamoylmethyluridine, a newly discovered constituent of yeast transfer RNA.

A compound tentatively identified as O2-methyl-5-carboxymethyluridine (cm5Um) was recently isolated in this laboratory from bulk yeast transfer RNA (Gray, M. W. (1975), Can, J. Biochem. 53, 735-746). Alkaline hydrolysis of yeast tRNA releases this nucleoside as part of an alkali-stable dinucleotide, cm5Um-Ap, from which sufficient cm5Um was prepared in the present investigation for a detailed examination of its properties. The ultraviolet absorption spectra and chromatographic and electrophoretic properties of cm5Um were consistent with the proposed structure, which was confirmed by characterization of the base and sugar moieties as 5-carboxymethyluracil and 2-O-methylribose, respectively. Snake venom hydrolysis of yeast tRNA releases cm5Um in the form of a carboxyl-blocked 5'-nucleotide, designated pU-2. Identification of the alkali-labile blocking group in pU-2 as an amide was based on quantitative assay for ammonia released upon acid hydrolysis of the corresponding nucleoside, U-2, and by chromatographic comparison of U-2 with the semisynthetic methyl ester and amide derivatives of cm5Um (mcm5Um and ncm5Um, respectively). Quantitative analysis has indicated that ncm5Um may be confined to a single species of yeast tRNA. In view of the unique localization (the "Wobble" position of the anticodon sequence) and coding properties (pairing with A but not with G) of other cm5U derivatives in transfer RNA, the dinucleotide cm5Um-Ap may be derived from the first two positions of the anticodon sequence of a yeast tRNA species recognizing an NUA codon. This predicts that O2-methyl-5-carbamoylmethyluridine will be found in an isoleucine, leucine, or valine isoacceptor.     

The Escherichia coli major exoribonuclease RNase II is a component of the RNA degradosome

Multiprotein complexes that carry out RNA degradation and processing functions are found in cells from all domains of life. In Escherichia coli, the RNA degradosome, a four-protein complex, is required for normal RNA degradation and processing. In addition to the degradosome complex, the cell contains other ribonucleases that also play important roles in RNA processing and/or degradation. Whether the other ribonucleases are associated with the degradosome or function independently is not known. In the present work, IP (immunoprecipitation) studies from cell extracts showed that the major hydrolytic exoribonuclease RNase II is associated with the known degradosome components RNaseE (endoribonuclease E), RhlB (RNA helicase B), PNPase (polynucleotide phosphorylase) and Eno (enolase). Further evidence for the RNase II-degradosome association came from the binding of RNase II to purified RNaseE in far western affinity blot experiments. Formation of the RNase II–degradosome complex required the degradosomal proteins RhlB and PNPase as well as a C-terminal domain of RNaseE that contains binding sites for the other degradosomal proteins. This shows that the RNase II is a component of the RNA degradosome complex, a previously unrecognized association that is likely to play a role in coupling and coordinating the multiple elements of the RNA degradation pathways.     

Antisense RNA based down-regulation of RNaseE in E.coli

Background  

Messenger RNA decay is an important mechanism for controlling gene expression in all organisms. The rate of the mRNA degradation directly affects the steady state concentration of mRNAs and therefore influences the protein synthesis. RNaseE has a key importance for the general mRNA decay in E.coli. While RNaseE initiates the degradation of most mRNAs in E.coli, it is likely that the enzyme is also responsible for the degradation of recombinant RNAs. As RNaseE is essential for cell viability and knockout mutants cannot be cultured, we investigated the possibility for a down-regulation of the intracellular level of RNaseE by antisense RNAs. During this study, an antisense RNA based approach could be established which revealed a strong reduction of the intracellular level of RNaseE in E.coli.     

Catalytic cycle of the phosphatidylcholine-preferring phospholipase C from Bacillus cereus. Solvent viscosity, deuterium isotope effects, and proton inventory studies

The phosphatidylcholine-preferring phospholipase C from Bacillus cereus (PLCBc) is a 28.5 kDa enzyme with three zinc ions in its active site. Although much is known about the roles that various PLCBc active site amino acids play in binding and catalysis, there is little information about the rate-determining step of the PLCBc-catalyzed hydrolysis of phospholipids and the catalytic cycle of the enzyme. To gain insight into these aspects of the hydrolysis, solvent viscosity variation experiments were conducted to determine whether an external step (substrate binding or product release) or an internal step (hydrolysis) is rate-limiting. The data indicate that the PLCBc-catalyzed reaction is unaffected by changes in solvent viscosity. This observation is inconsistent with the notion of substrate binding or product release being rate-determining and supports the hypothesis that a chemical step is rate-limiting. Furthermore, a deuterium isotope effect of 1.9 and a linear proton inventory plot indicate one proton is transferred in the rate-determining step. These data may be used to formulate a comprehensive catalytic cycle that is for the first time based on experimental evidence. In this mechanism, Asp55 of PLCBc activates an active site water molecule for attack on the phosphodiester bond, the hydrolysis of which is rate-limiting. The phosphorylcholine product is the first to leave the active site, followed by diacylglycerol.