Processing of RNA in Escherichia coli is limited in the absence of ribonuclease III,ribonuclease E and ribonuclease P

A strain of Escherichia coli lacking RNAase III and containing thermolabile RNAase E and RNAase P was labeled with ³²P_i at a non-permissive temperature. RNA molecules were separated by two-dimensional polyacrylamide gel electrophoresis. Most of the small RNA species were isolated and analyzed for the presence of 5′ nucleoside triphosphates. In 16 of the 22 species analyzed a significant number of the individual molecules contained 5′ di or triphosphates. We conclude, therefore, that very little endonucleolytic RNA processing occurs in the absence of the three RNA processing enzymes RNAase III, RNAase E and RNAase P.     

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.     

Expression of human placental ribonuclease inhibitor in Escherichia coli

Human placental ribonuclease inhibitor (PRI) has been expressed in and isolated from Escherichia coli. Its apparent molecular weight, immunoreactivity and amino acid composition are virtually identical with those of native PRI. It inhibits the enzymatic activities of either angiogenin, a blood vessel inducing protein homologous to pancreatic RNase (RNase A), or RNase A in a stoichiometry of 1:1. Recombinant PRI binds to angiogenin and RNase A with Ki values of 2.9 x 10(-16) M and 6.8 x 10(-14) M, respectively, comparable to the affinities of native PRI for these enzymes. Thus, these results confirm that PRI inhibits angiogenin more effectively than RNase A.     

NMR evidence for dynamic secondary structure in helices II and III of the RNA of Escherichia coli

A new ribonuclease A (RNase A) resistant fragment of the 5S ribonucleic acid (RNA) from Escherichia coli has been isolated and characterized. This fragment comprises helix III and most of helix II of the parent molecule, a part of the 5S RNA molecule for which several energetically equivalent secondary structures have been proposed [De Wachter, R., Chen, M.-W., & Vandenberghe, A. (1984) Eur. J. Biochem. 143, 175-182]. The imino proton spectrum of this fragment has been studied by nuclear magnetic resonance methods at 500 MHz. The data obtained are readily rationalized in terms of one of the structures proposed for this region of 5S RNA. They also suggest that upon heating, this structure is replaced by a second, different one, consistent with the view that the helix II-helix III region of 5S RNA is able to switch between alternative structures. Among the products of the nucleolytic digestion of 5S RNA is a species whose sequence indicates that RNase A can ligate RNA as well as hydrolyze it.     

Mutational analysis of an RNA internal loop as a reactivity epitope for Escherichia coli ribonuclease III substrates

The enzymatic cleavage of double-stranded (ds) RNA is an obligatory step in the maturation and decay of many cellular and viral RNAs. The primary agents of dsRNA processing are members of the ribonuclease III (RNase III) superfamily, which are highly conserved in eukaryotic and bacterial cells. Escherichia coli RNase III participates in the maturation of the ribosomal RNAs and in the maturation and decay of cellular and phage mRNAs. E. coli RNase III-dependent cleavage events can regulate gene expression by controlling mRNA stability and translational activity. RNase III recognizes its substrates and selects the scissile phosphodiester(s) by recognizing specific RNA sequence and structural elements, termed reactivity epitopes. Some E. coli RNase III substrates contain an internal loop, in which is located the single scissile phosphodiester. The specific features of the internal loop that establish the pattern of single-strand cleavage are not known. A mutational analysis of the asymmetric [4 nt/5 nt] internal loop of the phage T7 R1.1 substrate reveals that cleavage reactivity is largely independent of internal loop sequence. Instead, the [4/5] asymmetry per se is the primary determinant of cleavage of a single bond within the 5 nt strand of the internal loop. The T7 R1.1 internal loop lacks elements of local tertiary structure, as revealed by sensitivity to cleavage by terbium ion and by the ability of the internal loop to destabilize a small model duplex. The internal loop functions as a discrete structural element in that the pattern of cleavage can be controlled by the specific type of asymmetry. The implications of these findings are discussed in light of RNase III substrate function as a gene regulatory element.     

Cleavage by ribonuclease III of the complex of 30 S pre-ribosomal RNA and ribosomal proteins of Escherichia coli

In lysates of Escherichia coli strain AB301-105, newly-formed 30 S pre-ribosomal RNA moved in a complex with protein, at 53 S. A 53 S particle also formed from the purified RNA and 30 S and 50 S ribosomal proteins, and could be cleaved by RNAase III to yield 30 S and 48 S particles.     

Characterization of RNA sequence determinants and antideterminants of processing reactivity for a minimal substrate of Escherichia coli ribonuclease III

Members of the ribonuclease III family are the primary agents of double-stranded (ds) RNA processing in prokaryotic and eukaryotic cells. Bacterial RNase III orthologs cleave their substrates in a highly site-specific manner, which is necessary for optimal RNA function or proper decay rates. The processing reactivities of Escherichia coli RNase III substrates are determined in part by the sequence content of two discrete double-helical elements, termed the distal box (db) and proximal box (pb). A minimal substrate of E.coli RNase III, μR1.1 RNA, was characterized and used to define the db and pb sequence requirements for reactivity and their involvement in cleavage site selection. The reactivities of μR1.1 RNA sequence variants were examined in assays of cleavage and binding in vitro. The ability of all examined substitutions in the db to inhibit cleavage by weakening RNase III binding indicates that the db is a positive determinant of RNase III recognition, with the canonical UA/UG sequence conferring optimal recognition. A similar analysis showed that the pb also functions as a positive recognition determinant. It also was shown that the ability of the GC or CG bp substitution at a specific position in the pb to inhibit RNase III binding is due to the purine 2-amino group, which acts as a minor groove recognition antideterminant. In contrast, a GC or CG bp at the pb position adjacent to the scissile bond can suppress cleavage without inhibiting binding, and thus act as a catalytic antideterminant. It is shown that a single pb+db ‘set’ is sufficient to specify a cleavage site, supporting the primary function of the two boxes as positive recognition determinants. The base pair sequence control of reactivity is discussed within the context of new structural information on a post-catalytic complex of a bacterial RNase III bound to the cleaved minimal substrate.     

DNA sequencing of the Escherichia coli ribonuclease III gene and its mutations

Summary A 0.7 kb DNA fragment of the Escherichia coli K12 chromosome was shown to contain the structural gene for RNAse III (rnc). The DNA sequence of the gene was determined and its alteration in an RNAse III defective mutant, AB301-105, was identified. DNA sequence analysis also showed that a secondary-site suppressor of a temperature-sensitive mutation in the E. coli ribosomal protein gene, rpsL, occurred within the rnc gene, providing genetic evidence for the interaction of ribosomal proteins with RNAse III, which in turn acts on the nascent ribosomal RNA during assembly of ribosomes in E. coli.     

Divalent metal cofactor binding in the kinetic folding trajectory of Escherichia coli ribonuclease HI

Proteins often require cofactors to perform their biological functions and must fold in the presence of their cognate ligands. Using circular dichroism spectroscopy. we investigated the effects of divalent metal binding upon the folding pathway of Escherichia coli RNase HI. This enzyme binds divalent metal in its active site, which is proximal to the folding core of RNase HI as defined by hydrogen/deuterium exchange studies. Metal binding increases the apparent stability of native RNase HI chiefly by reducing the unfolding rate. As with the apo-form of the protein, refolding from high denaturant concentrations in the presence of Mg2+ follows three-state kinetics: formation of a rapid burst phase followed by measurable single exponential kinetics. Therefore, the overall folding pathway of RNase HI is minimally perturbed by the presence of metal ions. Our results indicate that the metal cofactor enters the active site pocket only after the enzyme reaches its native fold, and therefore, divalent metal binding stabilizes the protein by decreasing its unfolding rate. Furthermore, the binding of the cofactor is dependent upon a carboxylate critical for activity (Asp10). A mutation in this residue (D10A) alters the folding kinetics in the absence of metal ions such that they are similar to those observed for the unaltered enzyme in the presence of metal.     

On the role of ATP in phosphodiester bond hydrolysis catalyzed by the recBC deoxyribonuclease of Escherichia coli.

The deoxyribonuclease specified by the recB and recC genes of Escherichia coli (recBC DNase; exonuclease V) has been purified to near homogeneity by a new procedure. Although hydrolysis of even a single nucleotide from a duplex DNA molecule by the pure enzyme is absolutely dependent upon ATP, the extent of phosphodiester hydrolysis is strongly inhibited by ATP concentrations of 0.2 mm or greater, and the initial rate is unaffected. Under these conditions, the extent of DNA hydrolysis is proportional to enzyme concentration. In contrast, neither the rate nor the extent of hydrolysis of single-stranded DNA nor ATP is affected by high concentrations of ATP. The amount of large single-stranded polynucleotide generated by the action of the recBC DNase increases as the ATP concentration increases and, at 0.5 mM ATP, becomes equivalent to the amount of acid-soluble nucleotide formed. These findings suggest that high intracellular concentrations of ATP affect the mechanism of the recBC DNase so as to limit the extent of hydrolysis of duplex DNA, while at the same time favoring the formation of single-stranded regions within the duplex. Such regions may be essential intermediates in the recombination process.     

Ethidium-dependent uncoupling of substrate binding and cleavage by Escherichia coli ribonuclease III

Ethidium bromide (EB) is known to inhibit cleavage of bacterial rRNA precursors by Escherichia coli ribonuclease III, a dsRNA-specific nuclease. The mechanism of EB inhibition of RNase III is not known nor is there information on EB-binding sites in RNase III substrates. We show here that EB is a reversible, apparently competitive inhibitor of RNase III cleavage of small model substrates in vitro. Inhibition is due to intercalation, since (i) the inhibitory concentrations of EB are similar to measured EB intercalation affinities; (ii) substrate cleavage is not affected by actinomycin D, an intercalating agent that does not bind dsRNA; (iii) the EB concentration dependence of inhibition is a function of substrate structure. In contrast, EB does not strongly inhibit the ability of RNase III to bind substrate. EB also does not block substrate binding by the C-terminal dsRNA-binding domain (dsRBD) of RNase III, indicating that EB perturbs substrate recognition by the N-terminal catalytic domain. Laser photocleavage experiments revealed two ethidium-binding sites in the substrate R1.1 RNA. One site is in the internal loop, adjacent to the scissile bond, while the second site is in the lower stem. Both sites consist of an A-A pair stacked on a CG pair, a motif which apparently provides a particularly favorable environment for intercalation. These results indicate an inhibitory mechanism in which EB site-specifically binds substrate, creating a cleavage-resistant complex that can compete with free substrate for RNase III. This study also shows that RNase III recognition and cleavage of substrate can be uncoupled and supports an enzymatic mechanism of dsRNA cleavage involving cooperative but not obligatorily linked actions of the dsRBD and the catalytic domain.     

Structural insight into the mechanism of double-stranded RNA processing by ribonuclease III

Members of the ribonuclease III (RNase III) family are double-stranded RNA (dsRNA) specific endoribonucleases characterized by a signature motif in their active centers and a two-base 3' overhang in their products. While Dicer, which produces small interfering RNAs, is currently the focus of intense interest, the structurally simpler bacterial RNase III serves as a paradigm for the entire family. Here, we present the crystal structure of an RNase III-product complex, the first catalytic complex observed for the family. A 7 residue linker within the protein facilitates induced fit in protein-RNA recognition. A pattern of protein-RNA interactions, defined by four RNA binding motifs in RNase III and three protein-interacting boxes in dsRNA, is responsible for substrate specificity, while conserved amino acid residues and divalent cations are responsible for scissile-bond cleavage. The structure reveals a wealth of information about the mechanism of RNA hydrolysis that can be extrapolated to other RNase III family members.