Ribonuclease III cleavage of a bacteriophage T7 processing signal. Divalent cation specificity, and specific anion effects

Structural Insights into the Advances and Mechanistic Understanding of Human Dicer

The RNase III endoribonuclease Dicer was discovered to be associated with cleavage of double-stranded RNA in 2001. Since then, many advances in our understanding of Dicer function have revealed that the enzyme plays a major role not only in microRNA biology but also in multiple RNA interference-related pathways. Yet, there is still much to be learned regarding Dicer structure-function in relation to how Dicer and Dicer-like enzymes initiate their cleavage reaction and release the desired RNA product. This Perspective describes the latest advances in Dicer structural studies, expands on what we have learned from this data, and outlines key gaps in knowledge that remain to be addressed. More specifically, we focus on human Dicer and highlight the intermediate processing steps where there is a lack of structural data to understand how the enzyme traverses from pre-cleavage to cleavage-competent states. Understanding these details is necessary to model Dicer's function as well as develop more specific microRNA-targeted therapeutics for the treatment of human diseases.

A ribonuclease III involved in virulence of Mucorales fungi has evolved to cut exclusively single-stranded RNA

Members of the ribonuclease III (RNase III) family regulate gene expression by processing double-stranded RNA (dsRNA). This family includes eukaryotic Dicer and Drosha enzymes that generate small dsRNAs in the RNA interference (RNAi) pathway. The fungus Mucor lusitanicus, which causes the deadly infection mucormycosis, has a complex RNAi system encompassing a non-canonical RNAi pathway (NCRIP) that regulates virulence by degrading specific mRNAs. In this pathway, Dicer function is replaced by R3B2, an atypical class I RNase III, and small single-stranded RNAs (ssRNAs) are produced instead of small dsRNA as Dicer-dependent RNAi pathways. Here, we show that R3B2 forms a homodimer that binds to ssRNA and dsRNA molecules, but exclusively cuts ssRNA, in contrast to all known RNase III. The dsRNA cleavage inability stems from its unusual RNase III domain (RIIID) because its replacement by a canonical RIIID allows dsRNA processing. A crystal structure of R3B2 RIIID resembles canonical RIIIDs, despite the low sequence conservation. However, the groove that accommodates dsRNA in canonical RNases III is narrower in the R3B2 homodimer, suggesting that this feature could be responsible for the cleavage specificity for ssRNA. Conservation of this activity in R3B2 proteins from other mucormycosis-causing Mucorales fungi indicates an early evolutionary acquisition.

Transcript degradation and codon usage regulate gene expression in a lytic phage

Many viral genomes are small, containing only single- or double-digit numbers of genes and relatively few regulatory elements. Yet viruses successfully execute complex regulatory programs as they take over their host cells. Here, we propose that some viruses regulate gene expression via a carefully balanced interplay between transcription, translation, and transcript degradation. As our model system, we employ bacteriophage T7, whose genome of approximately sixty genes is well annotated and for which there is a long history of computational models of gene regulation. We expand upon prior modeling work by implementing a stochastic gene expression simulator that tracks individual transcripts, polymerases, ribosomes, and ribonucleases participating in the transcription, translation, and transcript-degradation processes occurring during a T7 infection. By combining this detailed mechanistic modeling of a phage infection with high-throughput gene expression measurements of several strains of bacteriophage T7, evolved and engineered, we can show that both the dynamic interplay between transcription and transcript degradation, and between these two processes and translation, appear to be critical components of T7 gene regulation. Our results point to targeted degradation as a generic gene regulation strategy that may have evolved in many other viruses. Further, our results suggest that detailed mechanistic modeling may uncover the biological mechanisms at work in both evolved and engineered virus variants.

The archaeology of coding RNA

Different theories concerning the origin of RNA (and, in particular, mRNA) point to the concatenation and expansion of proto-tRNA-like structures. Different biochemical and biophysical tools have been used to search for ancient-like RNA elements with a specific structure in genomic viral RNAs, including that of the hepatitis C virus, as well as in cellular mRNA populations, in particular those of human hepatocytes. We define this method as "archaeological," and it has been designed to discover evolutionary patterns through a nonphylogenetic and nonrepresentational strategy. tRNA-like elements were found in structurally or functionally relevant positions both in viral RNA and in one of the liver mRNAs examined, the antagonist interferon-alpha subtype 5 (IFNA5) mRNA. Additionally, tRNA-like elements are highly represented within the hepatic mRNA population, which suggests that they could have participated in the formation of coding RNAs in the distant past. Expanding on this finding, we have observed a recurring dsRNA-like motif next to the tRNA-like elements in both viral RNAs and IFNA5 mRNA. This suggested that the concatenation of these RNA motifs was an activity present in the RNA pools that might have been relevant in the RNA world. The extensive alteration of sequences that likely triggered the transition from the predecessors of coding RNAs to the first fully functional mRNAs (which was not the case in the stepwise construction of noncoding rRNAs) hinders the phylogeny-based identification of RNA elements (both sequences and structures) that might have been active before the advent of protein synthesis. Therefore, our RNA archaeological method is presented as a way to better understand the structural/functional versatility of a variety of RNA elements, which might represent "the losers" in the process of RNA evolution as they had to adapt to the selective pressures favoring the coding capacity of the progressively longer mRNAs.

Sinorhizobium meliloti YbeY is an endoribonuclease with unprecedented catalytic features, acting as silencing enzyme in riboregulation

Structural and biochemical features suggest that the almost ubiquitous bacterial YbeY protein may serve catalytic and/or Hfq-like protective functions central to small RNA (sRNA)-mediated regulation and RNA metabolism. We have biochemically and genetically characterized the YbeY ortholog of the legume symbiont Sinorhizobium meliloti (SmYbeY). Co-immunoprecipitation (CoIP) with a FLAG-tagged SmYbeY yielded a poor enrichment in RNA species, compared to Hfq CoIP-RNA uncovered previously by a similar experimental setup. Purified SmYbeY behaved as a monomer that indistinctly cleaved single- and double-stranded RNA substrates, a unique ability among bacterial endoribonucleases. SmYbeY-mediated catalysis was supported by the divalent metal ions Mg²⁺, Mn²⁺ and Ca²⁺, which influenced in a different manner cleavage efficiency and reactivity patterns, with Ca²⁺ specifically blocking activity on double-stranded and some structured RNA molecules. SmYbeY loss-of-function compromised expression of core energy and RNA metabolism genes, whilst promoting accumulation of motility, late symbiotic and transport mRNAs. Some of the latter transcripts are known Hfq-binding sRNA targets and might be SmYbeY substrates. Genetic reporter and in vitro assays confirmed that SmYbeY is required for sRNA-mediated down-regulation of the amino acid ABC transporter prbA mRNA. We have thus discovered a bacterial endoribonuclease with unprecedented catalytic features, acting also as gene silencing enzyme.

Mechanism of Ribonuclease III Catalytic Regulation by Serine Phosphorylation

Ribonuclease III (RNase III) is a conserved, gene-regulatory bacterial endonuclease that cleaves double-helical structures in diverse coding and noncoding RNAs. RNase III is subject to multiple levels of control, reflective of its global regulatory functions. Escherichia coli (Ec) RNase III catalytic activity is known to increase during bacteriophage T7 infection, reflecting the expression of the phage-encoded protein kinase, T7PK. However, the mechanism of catalytic enhancement is unknown. This study shows that Ec-RNase III is phosphorylated on serine in vitro by purified T7PK, and identifies the targets as Ser33 and Ser34 in the N-terminal catalytic domain. Kinetic experiments reveal a 5-fold increase in k_cat and a 1.4-fold decrease in K_m following phosphorylation, providing a 7.4–fold increase in catalytic efficiency. Phosphorylation does not change the rate of substrate cleavage under single-turnover conditions, indicating that phosphorylation enhances product release, which also is the rate-limiting step in the steady-state. Molecular dynamics simulations provide a mechanism for facilitated product release, in which the Ser33 phosphomonoester forms a salt bridge with the Arg95 guanidinium group, thereby weakening RNase III engagement of product. The simulations also show why glutamic acid substitution at either serine does not confer enhancement, thus underscoring the specific requirement for a phosphomonoester.

Revealing a new activity of the human Dicer DUF283 domain in vitro

The ribonuclease Dicer is a multidomain enzyme that plays a fundamental role in the biogenesis of small regulatory RNAs (srRNAs), which control gene expression by targeting complementary transcripts and inducing their cleavage or repressing their translation. Recent studies of Dicer's domains have permitted to propose their roles in srRNA biogenesis. For all of Dicer's domains except one, called DUF283 (domain of unknown function), their involvement in RNA substrate recognition, binding or cleavage has been postulated. For DUF283, the interaction with Dicer's protein partners has been the only function suggested thus far. In this report, we demonstrate that the isolated DUF283 domain from human Dicer is capable of binding single-stranded nucleic acids in vitro. We also show that DUF283 can act as a nucleic acid annealer that accelerates base-pairing between complementary RNA/DNA molecules in vitro. We further demonstrate an annealing activity of full length human Dicer. The overall results suggest that Dicer, presumably through its DUF283 domain, might facilitate hybridization between short RNAs and their targets. The presented findings reveal the complex nature of Dicer, whose functions may extend beyond the biogenesis of srRNAs.

ClRTL1 Encodes a Chinese Fir RNase III-Like Protein Involved in Regulating Shoot Branching

Identification of genes controlling shoot branching is crucial for improving plant architecture and increasing crop yield or biomass. A branching mutant of Chinese fir named “Dugansha” (Cunninghamia lanceolata var. dugan.) has been isolated in our laboratory. We chose the cDNA-AFLP technique and an effective strategy to screen genes that potentially regulate shoot branching in Chinese fir using this mutant. An RNase III-like1 cDNA fragment named ClRTL1 was identified as a potential positive regulator. To investigate the function of ClRTL1 in regulating shoot branching, we cloned the full-length cDNA sequence from C. lanceolata (Lamb.) Hook, deduced its secondary structure and function, and overexpressed the coding sequence in Arabidopsis. The ClRTL1 cDNA is 1045 bp and comprises an open reading frame of 705 bp. It encodes a protein of 235 amino acids. The deduced secondary structure of the ClRTL1 indicates that it is a mini-RNase III-like protein. The expression analysis and phenotypes of 35S: ClRTL1 in A. thaliana implies that ClRTL1 plays a role in promoting shoot branching in Chinese fir.

Exoribonucleases and Endoribonucleases

This review provides a description of the known Escherichia coli ribonucleases (RNases), focusing on their structures, catalytic properties, genes, physiological roles, and possible regulation. Currently, eight E. coli exoribonucleases are known. These are RNases II, R, D, T, PH, BN, polynucleotide phosphorylase (PNPase), and oligoribonuclease (ORNase). Based on sequence analysis and catalytic properties, the eight exoribonucleases have been grouped into four families. These are the RNR family, including RNase II and RNase R; the DEDD family, including RNase D, RNase T, and ORNase; the RBN family, consisting of RNase BN; and the PDX family, including PNPase and RNase PH. Seven well-characterized endoribonucleases are known in E. coli. These are RNases I, III, P, E, G, HI, and HII. Homologues to most of these enzymes are also present in Salmonella. Most of the endoribonucleases cleave RNA in the presence of divalent cations, producing fragments with 3'-hydroxyl and 5'-phosphate termini. RNase H selectively hydrolyzes the RNA strand of RNA?DNA hybrids. Members of the RNase H family are widely distributed among prokaryotic and eukaryotic organisms in three distinct lineages, RNases HI, HII, and HIII. It is likely that E. coli contains additional endoribonucleases that have not yet been characterized. First of all, endonucleolytic activities are needed for certain known processes that cannot be attributed to any of the known enzymes. Second, homologues of known endoribonucleases are present in E. coli. Third, endonucleolytic activities have been observed in cell extracts that have different properties from known enzymes.

Sequence-specific cleavage of dsRNA by Mini-III RNase

Ribonucleases (RNases) play a critical role in RNA processing and degradation by hydrolyzing phosphodiester bonds (exo- or endonucleolytically). Many RNases that cut RNA internally exhibit substrate specificity, but their target sites are usually limited to one or a few specific nucleotides in single-stranded RNA and often in a context of a particular three-dimensional structure of the substrate. Thus far, no RNase counterparts of restriction enzymes have been identified which could cleave double-stranded RNA (dsRNA) in a sequence-specific manner. Here, we present evidence for a sequence-dependent cleavage of long dsRNA by RNase Mini-III from Bacillus subtilis (BsMiniIII). Analysis of the sites cleaved by this enzyme in limited digest of bacteriophage Φ6 dsRNA led to the identification of a consensus target sequence. We defined nucleotide residues within the preferred cleavage site that affected the efficiency of the cleavage and were essential for the discrimination of cleavable versus non-cleavable dsRNA sequences. We have also determined that the loop α5b-α6, a distinctive structural element in Mini-III RNases, is crucial for the specific cleavage, but not for dsRNA binding. Our results suggest that BsMiniIII may serve as a prototype of a sequence-specific dsRNase that could possibly be used for targeted cleavage of dsRNA.

Characterization of the biochemical properties of Campylobacter jejuni RNase III

Campylobacter jejuni is a foodborne bacterial pathogen, which is now considered as a leading cause of human bacterial gastroenteritis. The information regarding ribonucleases in C. jejuni is very scarce but there are hints that they can be instrumental in virulence mechanisms. Namely, PNPase (polynucleotide phosphorylase) was shown to allow survival of C. jejuni in refrigerated conditions, to facilitate bacterial swimming, cell adhesion, colonization and invasion. In several microorganisms PNPase synthesis is auto-controlled in an RNase III (ribonuclease III)-dependent mechanism. Thereby, we have cloned, overexpressed, purified and characterized Cj-RNase III (C. jejuni RNase III). We have demonstrated that Cj-RNase III is able to complement an Escherichia coli rnc-deficient strain in 30S rRNA processing and PNPase regulation. Cj-RNase III was shown to be active in an unexpectedly large range of conditions, and Mn²⁺ seems to be its preferred co-factor, contrarily to what was described for other RNase III orthologues. The results lead us to speculate that Cj-RNase III may have an important role under a Mn²⁺-rich environment. Mutational analysis strengthened the function of some residues in the catalytic mechanism of action of RNase III, which was shown to be conserved.

Functional conservation of RNase III-like enzymes: studies on a Vibrio vulnificus ortholog of Escherichia coli RNase III

Bacterial ribonuclease III (RNase III) belongs to the RNase III enzyme family, which plays a pivotal role in controlling mRNA stability and RNA processing in both prokaryotes and eukaryotes. In the Vibrio vulnificus genome, one open reading frame encodes a protein homologous to E. coli RNase III, designated Vv-RNase III, which has 77.9 % amino acid identity to E. coli RNase III. Here, we report that Vv-RNase III has the same cleavage specificity as E. coli RNase III in vivo and in vitro. Expressing Vv-RNase III in E. coli cells deleted for the RNase III gene (rnc) restored normal rRNA processing and, consequently, growth rates of these cells comparable to wild-type cells. In vitro cleavage assays further showed that Vv-RNase III has the same cleavage activity and specificity as E. coli RNase III on RNase III-targeted sequences of corA and mltD mRNA. Our findings suggest that RNase III-like proteins have conserved cleavage specificity across bacterial species.

A conserved loop in polynucleotide phosphorylase (PNPase) essential for both RNA and ADP/phosphate binding

Polynucleotide phosphorylase (PNPase) reversibly catalyzes RNA phosphorolysis and polymerization of nucleoside diphosphates. Its homotrimeric structure forms a central channel where RNA is accommodated. Each protomer core is formed by two paralogous RNase PH domains: PNPase1, whose function is largely unknown, hosts a conserved FFRR loop interacting with RNA, whereas PNPase2 bears the putative catalytic site, ∼20 Å away from the FFRR loop. To date, little is known regarding PNPase catalytic mechanism. We analyzed the kinetic properties of two Escherichia coli PNPase mutants in the FFRR loop (R79A and R80A), which exhibited a dramatic increase in Km for ADP/Pi binding, but not for poly(A), suggesting that the two residues may be essential for binding ADP and Pi. However, both mutants were severely impaired in shifting RNA electrophoretic mobility, implying that the two arginines contribute also to RNA binding. Additional interactions between RNA and other PNPase domains (such as KH and S1) may preserve the enzymatic activity in R79A and R80A mutants. Inspection of enzyme structure showed that PNPase has evolved a long-range acting hydrogen bonding network that connects the FFRR loop with the catalytic site via the F380 residue. This hypothesis was supported by mutation analysis. Phylogenetic analysis of PNPase domains and RNase PH suggests that such network is a unique feature of PNPase1 domain, which coevolved with the paralogous PNPase2 domain.

Survival of the fittest: a role for phage-encoded eukaryotic-like kinases

Phages are often thought of as mortal enemies of bacteria. This dynamic relationship has led to the evolution of a number of processes in bacteria designed to defeat these attacks. Examples of these include blocking phage attachment, CRISPR, and restriction modification systems. Temperate phages provide another source of protection by excluding infection of heterologous phage, thwarting phage production and further infection. This strategy protects the rest of the bacterial population from attack. The lambdoid phage 933W, a source of the genes encoding Shiga toxin in the highly pathogenic O157:H7 enterohemorrhagic E. coli strain, also carries a gene encoding a eukaryotic-like tyrosine kinase, Stk. In this issue of Molecular Microbiology, Friedman et al. (2011) show that Stk, through its kinase activity, excludes infection by another lambdoid phage HK97. This exclusion is very specific as it does not affect a number of other lambdoid phages. HK97 contributes to its own demise by expressing the product of an open reading frame, orf41, which is required for Stk activation. The authors further show that autophosphorylation increases the stability of Stk and suggest that autophosphorylation contributes to Stk activity. Whether or not this exclusion activity provides a selective advantage through maintenance of Stk activity is yet to be explored.

An Arabidopsis RNase III-like protein, AtRTL2, cleaves double-stranded RNA in vitro

Class 1 ribonuclease III (RNase III), found in bacteria and yeast, is involved in processing functional RNA molecules such as ribosomal RNAs (rRNAs). However, in Arabidopsis thaliana, the lack of an obvious phenotype or quantitative change in mature rRNAs in class 1 RNase III (AtRTL2) mutants and overexpressing plants suggests that AtRTL2 is not involved in rRNA maturation. We characterized the in vitro activity of AtRTL2 to consider its in vivo function. AtRTL2 cleaved double-stranded RNA (dsRNA) specifically in vitro, yielding products of approximately 25 nt or longer in length, in contrast to 10-20 nt long products in bacteria and yeasts. Although dsRNA-binding activity was not detected, the dsRNA-binding domains in AtRTL2 were essential for its dsRNA-cleaving activity. Accumulation of small RNAs derived from transgene dsRNAs was increased when AtRTL2 was transiently expressed in Nicotiana benthamiana leaves by agroinfiltration. These results raise the possibility that AtRTL2 has functions distinct from those of other class 1 RNase IIIs in vivo.

Short RNA duplexes guide sequence-dependent cleavage by human Dicer

Dicer is a member of the double-stranded (ds) RNA-specific ribonuclease III (RNase III) family that is required for RNA processing and degradation. Like most members of the RNase III family, Dicer possesses a dsRNA binding domain and cleaves long RNA duplexes in vitro. In this study, Dicer substrate selectivity was examined using bipartite substrates. These experiments revealed that an RNA helix possessing a 2-nucleotide (nt) 3'-overhang may bind and direct sequence-specific Dicer-mediated cleavage in trans at a fixed distance from the 3'-end overhang. Chemical modifications of the substrate indicate that the presence of the ribose 2'-hydroxyl group is not required for Dicer binding, but some located near the scissile bonds are needed for RNA cleavage. This suggests a flexible mechanism for substrate selectivity that recognizes the overall shape of an RNA helix. Examination of the structure of natural pre-microRNAs (pre-miRNAs) suggests that they may form bipartite substrates with complementary mRNA sequences, and thus induce seed-independent Dicer cleavage. Indeed, in vitro, natural pre-miRNA directed sequence-specific Dicer-mediated cleavage in trans by supporting the formation of a substrate mimic.

Thermotoga maritima ribonuclease III. Characterization of thermostable biochemical behavior and analysis of conserved base pairs that function as reactivity epitopes for the Thermotoga 23S rRNA precursor

The cleavage of double-stranded (ds) RNA by ribonuclease III is a conserved early step in bacterial rRNA maturation. Studies on the mechanism of dsRNA cleavage by RNase III have focused mainly on the enzymes from mesophiles such as Escherichia coli. In contrast, neither the catalytic properties of extremophile RNases III nor the structures and reactivities of their cognate substrates have been described. The biochemical behavior of RNase III of the hyperthermophilic bacterium Thermotoga maritima was analyzed using purified recombinant enzyme. T. maritima (Tm) RNase III catalytic activity exhibits a broad optimal temperature range of approximately 40-70 degrees C, with significant activity at 95 degrees C. Tm-RNase III cleavage of substrate is optimally supported by Mg(2+) at >or=1 mM concentrations. Mn(2+), Co(2+), and Ni(2+) also support activity but with reduced efficiencies. The enzyme functions optimally at pH 8 and approximately 50-80 mM salt concentrations. Small RNA hairpins that incorporate the 16S and 23S pre-rRNA stem sequences are efficiently cleaved by Tm-RNase III at sites that are consistent with production in vivo of the immediate precursors to the mature rRNAs. Analysis of pre-23S substrate variants reveals a dependence of reactivity on the base-pair (bp) sequence in the proximal box (pb), a site of protein contact that functions as a positive recognition determinant for Escherichia coli (Ec) RNase III substrates. The dependence of reactivity on the pb sequence is similar to that observed with Ec-RNase III substrates. In fact, Tm-RNase III cleaves an Ec-RNase III substrate with identical specificity and is inhibited by antideterminant bp that also inhibit Ec-RNase III. These results indicate the conservation, across a broad phylogenetic distance, of positive and negative determinants of reactivity of bacterial RNase III substrates.

The glutamate effect on DNA binding by pol I DNA polymerases: osmotic stress and the effective reversal of salt linkage

The significant enhancing effect of glutamate on DNA binding by Escherichia coli nucleic acid binding proteins has been extensively documented. Glutamate has also often been observed to reduce the apparent linked ion release (Deltan(ions)) upon DNA binding. In this study, it is shown that the Klenow and Klentaq large fragments of the Type I DNA polymerases from E. coli and Thermus aquaticus both display enhanced DNA binding affinity in the presence of glutamate versus chloride. Across the relatively narrow salt concentration ranges often used to obtain salt linkage data, Klenow displays an apparently decreased Deltan(ions) in the presence of Kglutamate, while Klentaq appears not to display an anion-specific effect on Deltan(ions). Osmotic stress experiments reveal that DNA binding by Klenow and Klentaq is associated with the release of approximately 500 to 600 waters in the presence of KCl. For both proteins, replacing chloride with glutamate results in a 70% reduction in the osmotic-stress-measured hydration change associated with DNA binding (to approximately 150-200 waters released), suggesting that glutamate plays a significant osmotic role. Measurements of the salt-DNA binding linkages were extended up to 2.5 M Kglutamate to further examine this osmotic effect of glutamate, and it is observed that a reversal of the salt linkage occurs above 800 mM for both Klenow and Klentaq. Salt-addition titrations confirm that an increase of [Kglutamate] beyond 1 M results in rebinding of salt-displaced polymerase to DNA. These data represent a rare documentation of a reversed ion linkage for a protein-DNA interaction (i.e., enhanced binding as salt concentration increases). Nonlinear linkage analysis indicates that this unusual behavior can be quantitatively accounted for by a shifting balance of ionic and osmotic effects as [Kglutamate] is increased. These results are predicted to be general for protein-DNA interactions in glutamate salts.

Staphylococcus aureus endoribonuclease III purification and properties

Staphylococcus aureus ribonuclease III (Sa-RNase III) belongs to the enzyme family known to process double-stranded RNAs consisting of two turns of the RNA helix. Although the enzyme is thought to play a role in ribosomal RNA processing and gene regulation, the deletion of the rnc gene in S. aureus does not affect cell growth in rich medium. S. aureus RNase III acts in concert with regulatory RNAIII to repress the expression of several mRNAs encoding virulence factors. The action of the RNase is most likely to initiate the degradation of repressed mRNAs leading to an irreversible repression. In this chapter, we describe the overexpression and purification of recombinant RNase III from S. aureus, and we show that its biochemical properties are similar to the orthologous enzyme from Escherichia coli. Both enzymes similarly recognize and cleave different RNA substrates and RNA-mRNA duplexes.

Heterodimer-based analysis of subunit and domain contributions to double-stranded RNA processing by Escherichia coli RNase III in vitro

Members of the RNase III family are the primary cellular agents of dsRNA (double-stranded RNA) processing. Bacterial RNases III function as homodimers and contain two dsRBDs (dsRNA-binding domains) and two catalytic sites. The potential for functional cross-talk between the catalytic sites and the requirement for both dsRBDs for processing activity are not known. It is shown that an Escherichia coli RNase III heterodimer that contains a single functional wt (wild-type) catalytic site and an inactive catalytic site (RNase III[E117A/wt]) cleaves a substrate with a single scissile bond with a k(cat) value that is one-half that of wt RNase III, but exhibits an unaltered K(m). Moreover, RNase III[E117A/wt] cleavage of a substrate containing two scissile bonds generates singly cleaved intermediates that are only slowly cleaved at the remaining phosphodiester linkage, and in a manner that is sensitive to excess unlabelled substrate. These results demonstrate the equal probability, during a single binding event, of placement of a scissile bond in a functional or nonfunctional catalytic site of the heterodimer and reveal a requirement for substrate dissociation and rebinding for cleavage of both phosphodiester linkages by the mutant heterodimer. The rate of phosphodiester hydrolysis by RNase III[E117A/wt] has the same dependence on Mg(2+) ion concentration as that of the wt enzyme, and exhibits a Hill coefficient (h) of 2.0+/-0.1, indicating that the metal ion dependence essentially reflects a single catalytic site that employs a two-Mg(2+)-ion mechanism. Whereas an E. coli RNase III mutant that lacks both dsRBDs is inactive, a heterodimer that contains a single dsRBD exhibits significant catalytic activity. These findings support a reaction pathway involving the largely independent action of the dsRBDs and the catalytic sites in substrate recognition and cleavage respectively.

Characterization of the reactivity determinants of a novel hairpin substrate of yeast RNase III

RNase III enzymes form a conserved family of proteins that specifically cleave double-stranded (dsRNA). These proteins are involved in a variety of cellular functions, including the processing of many non-coding RNAs, mRNA decay, and RNA interference. Yeast RNase III (Rnt1p) selects its substrate by recognizing the structure generated by a conserved NGNN tetraloop (G2-loop). Mutations of the invariant guanosine stringently inhibit binding and cleavage of all known Rnt1p substrates. Surprisingly, we have found that the 5' end of small nucleolar RNA 48 is processed by Rnt1p in the absence of a G2-loop. Instead, biochemical and structural analyses revealed that cleavage, in this case, is directed by a hairpin capped with an AAGU tetraloop, with a preferred adenosine in the first position (A1-loop). Chemical probing indicated that A1-loops adopt a distinct structure that varies at the 3' end where Rnt1p interacts with G2-loops. Consistently, chemical footprinting and chemical interference assays indicate that Rnt1p binds to G2 and A1-loops using different sets of nucleotides. Also, cleavage and binding assays showed that the N-terminal domain of Rnt1p aids selection of A1-capped hairpins. Together, the results suggest that Rnt1p recognizes at least two distinct classes of tetraloops using flexible protein RNA interactions. This underscores the capacity of double-stranded RNA binding proteins to use several recognition motifs for substrate identification.

RNase III cleavage demonstrates a long range RNA: RNA duplex element flanking the hepatitis C virus internal ribosome entry site

Here, we show that Escherichia coli Ribonuclease III cleaves specifically the RNA genome of hepatitis C virus (HCV) within the first 570 nt with similar efficiency within two sequences which are ∼400 bases apart in the linear HCV map. Demonstrations include determination of the specificity of the cleavage sites at positions C²⁷ and U³³ in the first (5′) motif and G⁴³⁹ in the second (3′) motif, complete competition inhibition of 5′ and 3′ HCV RNA cleavages by added double-stranded RNA in a 1:6 to 1:8 weight ratio, respectively, 50% reverse competition inhibition of the RNase III T7 R1.1 mRNA substrate cleavage by HCV RNA at 1:1 molar ratio, and determination of the 5′ phosphate and 3′ hydroxyl end groups of the newly generated termini after cleavage. By comparing the activity and specificity of the commercial RNase III enzyme, used in this study, with the natural E.coli RNase III enzyme, on the natural bacteriophage T7 R1.1 mRNA substrate, we demonstrated that the HCV cuts fall into the category of specific, secondary RNase III cleavages. This reaction identifies regions of unusual RNA structure, and we further showed that blocking or deletion of one of the two RNase III-sensitive sequence motifs impeded cleavage at the other, providing direct evidence that both sequence motifs, besides being far apart in the linear RNA sequence, occur in a single RNA structural motif, which encloses the HCV internal ribosome entry site in a large RNA loop.

The absB Gene Encodes a Double Strand-specific Endoribonuclease That Cleaves the Read-through Transcript of the rpsO-pnp Operon in Streptomyces coelicolor

The absB locus of Streptomyces coelicolor encodes a homolog of bacterial RNase III. We cloned and overexpressed the absB gene product and purified a decahistidine-tagged version of the protein. We show here that AbsB is active against double-stranded RNA transcripts derived from synthetic DNAs but is inactive with single-stranded homopolymers. We thus designate the absB product RNase IIIS. Using T7 RNA polymerase and a cloned template containing the rpsO-pnp intergenic region, we synthesized an RNA substrate representing a portion of the read-through transcript normally produced in S. coelicolor. This transcript contains the sequences that form the putative rpsO terminator and those that form an intergenic stem-loop structure thought to be the site for RNase IIIS processing of the read-through transcript. We show that RNase IIIS does cleave that model transcript, with primary and secondary cleavage sites in an internal loop in the stem-loop structure. We have identified the primary and secondary cleavage sites by primer extension and demonstrate the further processing of the initial cleavage products. Thus, as is the case in Escherichia coli, the read-through transcript from rpsO-pnp is cleaved by RNase IIIS in S. coelicolor. However, the cleavage sites are different in the two systems. The positions of the cleavage sites in the stem-loop of the S. coelicolor transcript are more akin to those identified in the processing of bacteriophage T7 mRNAs. A kinetic assay for RNase IIIS was developed, and kinetic parameters for the reaction utilizing the model transcript from rpsO-pnp were determined.

Catalytic mechanism of Escherichia coli ribonuclease III: kinetic and inhibitor evidence for the involvement of two magnesium ions in RNA phosphodiester hydrolysis

Escherichia coli ribonuclease III (RNase III; EC 3.1.24) is a double-stranded(ds)-RNA-specific endonuclease with key roles in diverse RNA maturation and decay pathways. E.coli RNase III is a member of a structurally distinct superfamily that includes Dicer, a central enzyme in the mechanism of RNA interference. E.coli RNase III requires a divalent metal ion for activity, with Mg²⁺ as the preferred species. However, neither the function(s) nor the number of metal ions involved in catalysis is known. To gain information on metal ion involvement in catalysis, the rate of cleavage of the model substrate R1.1 RNA was determined as a function of Mg²⁺ concentration. Single-turnover conditions were applied, wherein phosphodiester cleavage was the rate-limiting event. The measured Hill coefficient (n_H) is 2.0 ± 0.1, indicative of the involvement of two Mg²⁺ ions in phosphodiester hydrolysis. It is also shown that 2-hydroxy-4H-isoquinoline-1,3-dione—an inhibitor of ribonucleases that employ two divalent metal ions in their catalytic sites—inhibits E.coli RNase III cleavage of R1.1 RNA. The IC₅₀ for the compound is 14 μM for the Mg²⁺-supported reaction, and 8 μM for the Mn²⁺-supported reaction. The compound exhibits noncompetitive inhibitory kinetics, indicating that it does not perturb substrate binding. Neither the O-methylated version of the compound nor the unsubstituted imide inhibit substrate cleavage, which is consistent with a specific interaction of the N-hydroxyimide with two closely positioned divalent metal ions. A preliminary model is presented for functional roles of two divalent metal ions in the RNase III catalytic mechanism.

Cleavage of double-stranded RNA by RNase HI from a thermoacidophilic archaeon, Sulfolobus tokodaii 7

ST0753, the orthologous gene of Type 1 RNase H found in a thermoacidophilic archaeon, Sulfolobus tokodaii, was analyzed. The recombinant ST0753 protein exhibited RNase H activity in both in vivo and in vitro assays. The protein expressed in an RNase H-deficient mutant Escherichia coli strain functioned to suppress the temperature-sensitive phenotype associated with the lack of RNase H. The in vitro characteristics of the gene's RNase H activity were similar to those of Halobacterium RNase HI, the first archaeal Type 1 RNase H to be characterized. Surprisingly, the S.tokodaii RNase HI cleaved not only the RNA strand of an RNA/DNA hybrid but also an RNA strand of an RNA/RNA duplex in the presence of Mn2+ or Co2+. The result of gel filtration column chromatography showed this double-stranded RNA-dependent RNase (dsRNase) activity was coincident with S.tokodaii RNase HI. A site-directed mutagenesis study of essential amino acids for RNase H activity indicated that this activity also affected dsRNase activity. A single amino acid replacement of Asp-125 by Asn resulted in loss of dsRNase activity but not RNase H activity, suggesting that amino acid residues required for dsRNase activity seemed slightly different from those of RNase H activity. Some reverse transcriptases from retroelements can cleave double-stranded RNA, and this activity requires the RNase H domain. Similarities in primary structure and biochemical characteristics between S.tokodaii RNase HI and reverse transcriptases imply that the S.tokodaii enzyme might be derived from the RNase H domain of reverse transcriptase.

Importance of transient structures during post-transcriptional refolding of the pre-23S rRNA and ribosomal large subunit assembly

An important step of ribosome assembly is the folding of the rRNA into a functional structure. Despite knowledge of the folded state of rRNA in the ribosomal subunits, there is very little information on the rRNA folding pathway. We are interested in understanding how the functional structure of rRNA is formed and whether the rRNA folding intermediates have a role in ribosome assembly. To this end, transient secondary structures around both ends of pre-23S rRNA were analyzed by a chemical probing approach, using pre-23S rRNA transcripts. Metastable hairpin loop structures were found at both ends of 23S rRNA. The functional importance of the transient structures around the ends of 23S rRNA was tested by mutations that alter only the transient structure. The effect of mutations on 23S rRNA folding was tested in vitro and in vivo. It was found that both stabilization and destabilization of the transient structure around the 5' end of 23S rRNA inhibits post-transcriptional refolding in vitro and ribosome formation in vivo. The data suggest that the transient structure of rRNA has a function during 23S rRNA folding and thereby in ribosome assembly.

Molecular requirements for duplex recognition and cleavage by eukaryotic RNase III: discovery of an RNA-dependent DNA cleavage activity of yeast Rnt1p

Members of the double-stranded RNA (dsRNA) specific RNase III family are known to use a conserved dsRNA-binding domain (dsRBD) to distinguish RNA A-form helices from DNA B-form ones, however, the basis of this selectivity and its effect on cleavage specificity remain unknown. Here, we directly examine the molecular requirements for dsRNA recognition and cleavage by the budding yeast RNase III (Rnt1p), and compare it to both bacterial RNase III and fission yeast RNase III (Pac1). We synthesized substrates with either chemically modified nucleotides near the cleavage sites, or with different DNA/RNA combinations, and investigated their binding and cleavage by Rnt1p. Substitution for the ribonucleotide vicinal to the scissile phosphodiester linkage with 2'-deoxy-2'-fluoro-beta-d-ribose (2' F-RNA), a deoxyribonucleotide, or a 2'-O-methylribonucleotide permitted cleavage by Rnt1p, while the introduction of a 2', 5'-phosphodiester linkage permitted binding, but not cleavage. This indicates that the position of the phosphodiester link with respect to the nuclease domain, and not the 2'-OH group, is critical for cleavage by Rnt1p. Surprisingly, Rnt1p bound to a DNA helix capped with an NGNN tetraribonucleotide loop indicating that the binding of at least one member of the RNase III family is not restricted to RNA. The results also suggest that the dsRBD may accommodate B-form DNA duplexes. Interestingly, Rnt1p, but not Pac1 nor bacterial RNase III, cleaved the DNA strand of a DNA/RNA hybrid, indicating that A-form RNA helix is not essential for cleavage by Rnt1p. In contrast, RNA/DNA hybrids bound to, but were not cleaved by Rnt1p, underscoring the critical role for the nucleotide located at 3' end of the tetraloop and suggesting an asymmetrical mode of substrate recognition. In cell extracts, the native enzyme effectively cleaved the DNA/RNA hybrid, indicating much broader Rnt1p substrate specificity than previously thought. The discovery of this novel RNA-dependent deoxyribonuclease activity has potential implications in devising new antiviral strategies that target actively transcribed DNA.

Characterization of a chlorella virus PBCV-1 encoded ribonuclease III

Sequence analysis of the 330-kb genome of chlorella virus PBCV-1 revealed an open reading frame, A464R, which encodes a protein with 30-35% amino acid identity to ribonuclease III (RNase III) from many bacteria. The a464r gene was cloned and the protein was expressed in Escherichia coli using the chitin-binding intein system. The recombinant PBCV-1 RNase III cleaves model dsRNA substrates, in a Mg(2+)-dependent manner, into a defined set of products. The substrate cleavage specificity overlaps, but is nonidentical to that of E. coli RNase III. The a464r gene is expressed very early during PBCV-1 infection, within 5-10 min p.i. The RNase III protein appears at 15 min p.i. and disappears by 120 min p.i. The a464r gene is highly conserved among the chlorella viruses. Phylogenetic analyses indicate that the PBCV enzyme is most closely related to Mycoplasma pneumoniae RNase III.

Functional significance of intermediate cleavages in the 3'ETS of the pre-rRNA from Schizosaccharomyces pombe

Pathways for the maturation of ribosomal RNAs are complex with numerous intermediate cleavage sites that are not always conserved closely in the course of evolution. Both in eukaryotes and bacteria genetic analyses and in vitro studies have strongly implicated RNase III-like enzymes in the processing of rRNA precursors. In Schizosacharomyces pombe, for example, the RNase III-like Pac1 nuclease has been shown to cleave the free 3'ETS at two known intermediate sites but, in the presence of RAC protein, the same RNA also is cleaved at the 3'-end of the 25 S rRNA sequence. In this study normal and mutant 3'ETS sequences were digested with the Pac1 enzyme to further evaluate its role in rRNA processing. Accurate cleavage at the known intermediate processing sites was dependent on the integrity of the helical structure at these sites as well as a more distal upper stem region in the conserved extended hairpin structure of the 3'ETS. The cleavage of mutant 3'ETS sequences also generally correlated with the known effects of these mutations on rRNA production, in vivo. One mutant, however, was efficiently processed in vivo but was not a substrate for the Pac1 nuclease, in vitro. In contrast, in the presence of RAC protein, the same RNA remained susceptible to Pac1 nuclease cleavage at the 3'-end of the 25 rRNA sequence, indicating that the removal of the 3'ETS does not require cleavage at the intermediate sites. These results suggest that basic maturation pathways may be less complex than previously reported raising similar questions about other intermediate processing sites, which have been identified by analyses of termini, and/or processing, in vitro.

Ribonuclease III-mediated processing of specific Neisseria meningitidis mRNAs

Approx. 2% of the Neisseria meningitidis genome consists of small DNA insertion sequences known as Correia or nemis elements, which feature TIRs (terminal inverted repeats) of 26-27 bp in length. Elements interspersed with coding regions are co-transcribed with flanking genes into mRNAs, processed at double-stranded RNA structures formed by TIRs. N. meningitidis RNase III (endoribonuclease III) is sufficient to process nemis+ RNAs. RNA hairpins formed by nemis with the same termini (26/26 and 27/27 repeats) are cleaved. By contrast, bulged hairpins formed by 26/27 repeats inhibit cleavage, both in vitro and in vivo. In electrophoretic mobility shift assays, all hairpin types formed similar retarded complexes upon incubation with RNase III. The levels of corresponding nemis+ and nemis- mRNAs, and the relative stabilities of RNA segments processed from nemis+ transcripts in vitro, may both vary significantly.

Divalent metal-dependent catalysis and cleavage specificity of CSP41, a chloroplast endoribonuclease belonging to the short chain dehydrogenase/reductase superfamily

CSP41 is a ubiquitous chloroplast endoribonuclease belonging to the short chain dehydrogenase/reductase (SDR) superfamily. To help elucidate the role of CSP41 in chloroplast gene regulation, the mechanisms that determine its substrate recognition and catalytic activity were investigated. A divalent metal is required for catalysis, most probably to provide a nucleophile for cleavage 5' to the phosphodiester bond, and may also participate in cleavage site selection. This requirement distinguishes CSP41 from other Rossman fold-containing proteins from the SDR superfamily, including several RNA-binding proteins and endonucleases. CSP41 is active only in the presence of MgCl2 and CaCl2. Although Mg2+- and Ca2+-activated CSP41 cleave at identical sites in the single-stranded regions of a stem-loop-containing substrate, Mg2+-activated CSP41 was also able to cleave within the double-stranded region of the stem-loop. Mixed metal experiments with Mg2+ and Ca2+ suggest that CSP41 contains a single divalent metal-binding site which is non-selective, since Mn2+, Co2+ and Zn2+ compete with Mg2+ for binding, although there is no activity in their presence. Using site-directed mutagenesis, we identified three residues, Asn71, Asp89 and Asp103, which may form the divalent metal-binding pocket. The activation constant for Mg2+ (K(A,Mg) = 2.1 +/- 0.4 mM) is of the same order of magnitude as the stromal Mg2+ concentrations, which fluctuate between 0.5 and 10 mM as a function of light and of leaf development. These changes in stromal Mg2+ concentration may regulate CSP41 activity, and thus cpRNA stability, during plant development.

RNA structure-dependent uncoupling of substrate recognition and cleavage by Escherichia coli ribonuclease III

Members of the ribonuclease III superfamily of double-strand-specific endoribonucleases participate in diverse RNA maturation and decay pathways. Ribonuclease III of the gram-negative bacterium Escherichia coli processes rRNA and mRNA precursors, and its catalytic action can regulate gene expression by controlling mRNA translation and stability. It has been proposed that E.coli RNase III can function in a non-catalytic manner, by binding RNA without cleaving phosphodiesters. However, there has been no direct evidence for this mode of action. We describe here an RNA, derived from the T7 phage R1.1 RNase III substrate, that is resistant to cleavage in vitro by E.coli RNase III but retains comparable binding affinity. R1.1[CL3B] RNA is recognized by RNase III in the same manner as R1.1 RNA, as revealed by the similar inhibitory effects of a specific mutation in both substrates. Structure-probing assays and Mfold analysis indicate that R1.1[CL3B] RNA possesses a bulge- helix-bulge motif in place of the R1.1 asymmetric internal loop. The presence of both bulges is required for uncoupling. The bulge-helix-bulge motif acts as a 'catalytic' antideterminant, which is distinct from recognition antideterminants, which inhibit RNase III binding.

Dehydrogenases from all three domains of life cleave RNA

Specific interactions of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) with RNA have been reported both in vitro and in vivo. We show that eukaryotic and bacterial GAPDH and two proteins from the hyperthermophilic archaeon Sulfolobus solfataricus, which are annotated as dehydrogenases, cleave RNA producing similar degradation patterns. RNA cleavage is most efficient at 60 degrees C, at MgCl(2) concentrations up to 5 mm, and takes place between pyrimidine and adenosine. The RNase active center of the putative aspartate semialdehyde dehydrogenase from S. solfataricus is located within the N-terminal 73 amino acids, which comprise the first mononucleotide-binding site of the predicted Rossmann fold. Thus, RNA cleavage has to be taken into account in the ongoing discussion of the possible biological function of RNA binding by dehydrogenases.

Human Dicer preferentially cleaves dsRNAs at their termini without a requirement for ATP

Dicer is a multi-domain RNase III-related endonuclease responsible for processing double-stranded RNA (dsRNA) to small interfering RNAs (siRNAs) during a process of RNA interference (RNAi). It also catalyses excision of the regulatory microRNAs from their precursors. In this work, we describe the purification and properties of a recombinant human Dicer. The protein cleaves dsRNAs into approximately 22 nucleotide siRNAs. Accumulation of processing intermediates of discrete sizes, and experiments performed with substrates containing modified ends, indicate that Dicer preferentially cleaves dsRNAs at their termini. Binding of the enzyme to the substrate can be uncoupled from the cleavage step by omitting Mg(2+) or performing the reaction at 4 degrees C. Activity of the recombinant Dicer, and of the endogenous protein present in mammalian cell extracts, is stimulated by limited proteolysis, and the proteolysed enzyme becomes active at 4 degrees C. Cleavage of dsRNA by purifed Dicer and the endogenous enzyme is ATP independent. Additional experiments suggest that if ATP participates in the Dicer reaction in mammalian cells, it might be involved in product release needed for the multiple turnover of the enzyme.

Ribonuclease activity and RNA binding of recombinant human Dicer

RNA silencing phenomena, known as post-transcriptional gene silencing in plants, quelling in fungi, and RNA interference (RNAi) in animals, are mediated by double-stranded RNA (dsRNA) and mechanistically intersect at the ribonuclease Dicer. Here, we report cloning and expression of the 218 kDa human Dicer, and characterization of its ribonuclease activity and dsRNA-binding properties. The recombinant enzyme generated approximately 21-23 nucleotide products from dsRNA. Processing of the microRNA let-7 precursor by Dicer produced an apparently mature let-7 RNA. Mg(2+) was required for dsRNase activity, but not for dsRNA binding, thereby uncoupling these reaction steps. ATP was dispensable for dsRNase activity in vitro. The Dicer.dsRNA complex formed at high KCl concentrations was catalytically inactive, suggesting that ionic interactions are involved in dsRNA cleavage. The putative dsRNA-binding domain located at the C-terminus of Dicer was demonstrated to bind dsRNA in vitro. Human Dicer expressed in mammalian cells colocalized with calreticulin, a resident protein of the endoplasmic reticulum. Availability of the recombinant Dicer protein will help improve our understanding of RNA silencing and other Dicer-related processes.

One functional subunit is sufficient for catalytic activity and substrate specificity of Escherichia coli endoribonuclease III artificial heterodimers

To study the intersubunit communication required for the activity of the normally homodimeric enzyme endoribonuclease III of Escherichia coli we have constructed and analysed an artificial heterodimer. This heterodimer is composed of one wild-type and one catalytically inactive subunit. The inactive subunit has one amino acid exchanged (E117K, rnc70 mutant) which abolishes cleavage activity but still allows substrate binding of a rnc70-homodimer. Our results show that one functional active site is sufficient for cleavage activity of the heterodimer.

Pre-steady-state and stopped-flow fluorescence analysis of Escherichia coli ribonuclease III: insights into mechanism and conformational changes associated with binding and catalysis

To better understand substrate recognition and catalysis by RNase III, we examined steady-state and pre-steady-state reaction kinetics, and changes in intrinsic enzyme fluorescence. The multiple turnover cleavage of a model RNA substrate shows a pre-steady-state burst of product formation followed by a slower phase, indicating that the steady-state reaction rate is not limited by substrate cleavage. RNase III catalyzed hydrolysis is slower at low pH, permitting the use of pre-steady-state kinetics to measure the dissociation constant for formation of the enzyme-substrate complex (K(d)=5.4(+/-0.6) nM), and the rate constant for phosphodiester bond cleavage (k(c)=1.160(+/-0.001) min(-1), pH 5.4). Isotope incorporation analysis shows that a single solvent oxygen atom is incorporated into the 5' phosphate of the RNA product, which demonstrates that the cleavage step is irreversible. Analysis of the pH dependence of the single turnover rate constant, k(c), fits best to a model for two or more titratable groups with pK(a) of ca 5.6, suggesting a role for conserved acidic residues in catalysis. Additionally, we find that k(c) is dependent on the pK(a) value of the hydrated divalent metal ion included in the reaction, providing evidence for participation of a metal ion hydroxide in catalysis, potentially in developing the nucleophile for the hydrolysis reaction. In order to assess whether conformational changes also contribute to the enzyme mechanism, we monitored intrinsic tryptophan fluorescence. During a single round of binding and cleavage by the enzyme we detect a biphasic change in fluorescence. The rate of the initial increase in fluorescence was dependent on substrate concentration yielding a second-order rate constant of 1.0(+/-0.1)x10(8) M(-1) s(-1), while the rate constant of the second phase was concentration independent (6.4(+/-0.8) s(-1); pH 7.3). These data, together with the unique dependence of each phase on divalent metal ion identity and pH, support the hypothesis that the two fluorescence transitions, which we attribute to conformational changes, correlate with substrate binding and catalysis.

Escherichia coli ribonuclease III: affinity purification of hexahistidine-tagged enzyme and assays for substrate binding and cleavage

It is now evident that members of the RNase III family of nucleases have central roles in prokaryotic and eukaryotic RNA maturation and decay pathways. Ongoing research is uncovering new roles for RNase III homologs. For example, the phenomena of RNA interference (RNAi) and posttranscriptional gene silencing (PTGS) involve dsRNA processing, carried out by an RNase III homolog. We anticipate an increased focus on the mechanism, regulation, and biological roles of RNase III orthologs. Although the differences in the physicochemical properties of RNase III orthologs, and distinct substrate reactivity epitopes and ionic requirements for optimal activity, may mean that the protocols describe here are not strictly transferrable, the affinity purification methodology, and substrate preparation and use should be generally applicable.

Purification and characterization of Saccharomyces cerevisiae Rnt1p nuclease

In this article, we have described methods used to purify Rnt1p and study its biochemical properties. Rnt1p can be easily purified from bacteria as N-terminal His6-tagged protein and its activity may be monitored in vitro. Rnt1p cleaves the RNA by binding to a cleavage site followed by hydrolysis and product release. The kinetic parameters of Rnt1p are similar to those of other nucleases, including bacterial RNase III. The ability of Rnt1p to bind substrate without cleaving it in the absence of divalent metal ions provides a convenient means to study RNA recognition and binding independent of catalysis. The gel mobility shift and in-the-gel cleavage assays described here reveal the formation of two Rnt1p-RNA complexes with different cleavage activities, suggesting that the protein may bind the substrate in two different forms or through a two-step binding reaction.

Ribonuclease III: new sense from nuisance

RNases play an important role in the processing of precursor RNAs, creating the mature, functional RNAs. The ribonuclease III family currently is one of the most interesting families of endoribonucleases. Surprisingly, RNase III is involved in the maturation of almost every class of prokaryotic and eukaryotic RNA. We present an overview of the various substrates and their processing. RNase III contains one of the most prominent protein domains used in RNA-protein recognition, the double-stranded RNA binding domain (dsRBD). Progress in the understanding of this domain is summarized. Furthermore, RNase III only recently emerged as a key player in the new exciting biological field of RNA silencing, or RNA interference. The eukaryotic RNase III homologues which are likely involved in this process are compared with the other members of the RNase III family.

Both N-terminal catalytic and C-terminal RNA binding domain contribute to substrate specificity and cleavage site selection of RNase III

The double-stranded RNA-specific endoribonuclease III (RNase III) of bacteria consists of an N-terminal nuclease domain and a double-stranded RNA binding domain (dsRBD) at the C-terminus. Analysis of two hybrid proteins consisting of the N-terminal half of Escherichia coli RNase III fused to the dsRBD of the Rhodobacter capsulatus enzyme and vice versa reveals that both domains in combination with the particular substrate determine substrate specificity and cleavage site selection. Extension of the spacer between the two domains of the E. coli enzyme from nine to 20 amino acids did not affect cleavage site selection.

The N-terminal domain that distinguishes yeast from bacterial RNase III contains a dimerization signal required for efficient double-stranded RNA cleavage

Yeast Rnt1 is a member of the double-stranded RNA (dsRNA)-specific RNase III family identified by conserved dsRNA binding (dsRBD) and nuclease domains. Comparative sequence analyses have revealed an additional N-terminal domain unique to the eukaryotic homologues of RNase III. The deletion of this domain from Rnt1 slowed growth and led to mild accumulation of unprocessed 25S pre-rRNA. In vitro, deletion of the N-terminal domain reduced the rate of RNA cleavage under physiological salt concentration. Size exclusion chromatography and cross-linking assays indicated that the N-terminal domain and the dsRBD self-interact to stabilize the Rnt1 homodimer. In addition, an interaction between the N-terminal domain and the dsRBD was identified by a two-hybrid assay. The results suggest that the eukaryotic N-terminal domain of Rnt1 ensures efficient dsRNA cleavage by mediating the assembly of optimum Rnt1-RNA ribonucleoprotein complex.

Identification of the minimal essential RNA sequences responsible for site-specific targeting of the Leishmania RNA virus 1-4 capsid endoribonuclease

The Leishmania RNA virus 1-4 capsid protein possesses an endoribonuclease activity responsible for single-site-specific cleavage within the 450-nucleotide 5' untranslated region of its own viral RNA transcript. To characterize the minimal essential RNA determinants required for site-specific cleavage, mutated RNA transcripts were examined for susceptibility to cleavage by the virus capsid protein in an in vitro assay. Deletion analyses revealed that all determinants necessary for accurate cleavage are encoded in viral nucleotides 249 to 342. Nuclease mapping and site-specific mutagenesis of the minimal RNA sequence defined a stem-loop structure that is located 40 nucleotides upstream from the cleavage site (nucleotide 320) and that is essential for accurate RNA cleavage. Abrogation of cleavage by disruption of base pairing within the stem-loop was reversed through the introduction of complementary nucleotide substitutions that reestablished the structure. We also provide evidence that divalent cations, essential components of the cleavage reaction, stabilized the stem-loop structure in solution. That capsid-specific antiserum eliminated specific RNA cleavage provides further evidence that the virus capsid gene encodes the essential endoribonuclease activity.

Absence of RNASE III alters the pathway by which RNAI, the antisense inhibitor of ColE1 replication, decays

RNAI is a short RNA, 108 nt in length, which regulates the replication of the plasmid ColE1. RNAI turns over rapidly, enabling plasmid replication rate to respond quickly to changes in plasmid copy number. Because RNAI is produced in abundance, is easily extracted and turns over quickly, it has been used as a model for mRNA in studying RNA decay pathways. The enzymes polynucleotide phosphorylase, poly(A) polymerase and RNase E have been demonstrated to have roles in both messenger and RNAI decay; it is reported here that these enzymes can work independently of one another to facilitate RNAI decay. The roles in RNAI decay of two further enzymes which facilitate mRNA decay, the exonuclease RNase II and the endonuclease RNase III, are also examined. RNase II does not appear to accelerate RNAI decay but it is found that, in the absence of RNase III, polyadenylated RNAI, unprocessed by RNase E, accumulates. It is also shown that RNase III can cut RNAI near nt 82 or 98 in vitro. An RNAI fragment corresponding to the longer of these can be found in extracts of an mc+ pcnB strain (which produces RNase III) but not of an rnc pcnB strain, suggesting that RNAI may be a substrate for RNase III in vivo. A possible pathway for the early steps in RNAI decay which incorporates this information is suggested.

Ribonuclease III processing of coaxially stacked RNA helices

The RNase III family of endoribonucleases participates in maturation and decay of cellular and viral transcripts by processing of double-stranded RNA. RNase III degradation is inherent to most antisense RNA-regulated gene systems in Escherichia coli. In the hok/sok system from plasmid R1, Sok antisense RNA targets the hok mRNA for RNase III-mediated degradation. An intermediate in the pairing reaction between Sok RNA and hok mRNA forms a three-way junction. A complex between a chimeric antisense RNA and hok mRNA that mimics the three-way junction was cleaved by RNase III both in vivo and in vitro. Footprinting using E117A RNase III binding to partially complementary RNAs showed protection of the 13 base pairs of interstrand duplex and of the bottom part of the transcriptional terminator hairpin of the antisense RNA. This suggests that the 13 base pairs of RNA duplex are coaxially stacked on the antisense RNA terminator stem-loop and that each stem forms a monomer half-site, allowing symmetrical binding of the RNase III dimer. This processing scheme shows an unanticipated diversity in RNase III substrates and may have a more general implication for RNA metabolism.

Function, mechanism and regulation of bacterial ribonucleases

The maturation and degradation of RNA molecules are essential features of the mechanism of gene expression, and provide the two main points for post-transcriptional regulation. Cells employ a functionally diverse array of nucleases to carry out RNA maturation and turnover. Viruses also employ cellular ribonucleases, or even use their own in their reproductive cycles. Studies on bacterial ribonucleases, and in particular those from Escherichia coli, are providing insight into ribonuclease structure, mechanism, and regulation. Ongoing biochemical and genetic analyses are revealing that many ribonucleases are phylogenetically conserved, and exhibit overlapping functional roles and perhaps common catalytic mechanisms. This article reviews the salient features of bacterial ribonucleases, with a focus on those of E. coli, and in particular, ribonuclease III. RNase III participates in a number of RNA maturation and RNA decay pathways, and is regulated by phosphorylation in the T7 phage-infected cell. Plasmid and phage RNAs, in addition to cellular transcripts, are RNase III targets. RNase III orthologues occur in eukaryotic cells, and play key functional roles. As such, RNase III provides an important model with which to understand mechanisms of RNA maturation, RNA decay, and gene regulation.

Targeted RNases: a feasibility study for use in HIV gene therapy

A targeted RNase would be ideal for gene therapy of several acquired and inherited disorders. Such an RNase may be engineered to contain a ribonucleolytic domain and a specific target RNA binding domain. To demonstrate the feasibility of this approach, an RNase targeted against human immunodeficiency virus (HIV) RNA--Tev-RNase T1--was designed and tested for its use in HIV-1 gene therapy. A human CD4+ T lymphoid (MT4) cell line and human peripheral blood lymphocytes (PBLs) were transduced with retroviral vectors lacking or expressing the tevT1 gene. Expression of enzymatically functional Tev-RNase T1 protein and its lack of toxicity was demonstrated in stable MT4 transductants. Compared with control cells lacking this protein, both transduced MT4 cells and PBLs expressing Tev-RNase T1 delayed HIV-1 replication. Tev-RNase T1 was shown to act after integration, since HIV-1 proviral DNA could be detected, but the amount of HIV-1 RNA produced in MT4 cells and PBLs was significantly decreased. This study demonstrates the feasibility of a targeted RNase strategy for therapeutic use.