Expression of the chemically synthesized gene for ribonuclease T1 in Escherichia coli using a secretion cloning vector

The gene for ribonuclease T1 from Aspergillus oryzae has been chemically synthesized using the segmental support technique. An Escherichia coli clone producing the ribonuclease at high levels was constructed by linking the gene downstream to the region coding for the signal peptide of the OmpA protein (a major outer membrane protein of E. coli), using the secretion cloning vector pIN-III-ompA2. This strategy was employed in order to circumvent a possible toxic effect of the gene product on the host cell. Active ribonuclease containing four additional amino acids at the N-terminus could be isolated from the periplasmic fraction of the host. The final yield after purification was 20 mg enzyme/l liquid culture. With respect to immunological, catalytic and specific behaviour, no qualitative differences could be detected between the enzyme from the over-producing E. coli strain and ribonuclease T1 isolated from A. oryzae.     

Genetic analysis of the structure and function of RNase P fromE. coli

A brief review of the genetic studies on ribonuclease P (RNase P) fromEscherichia coli is presented. Temperature-sensitive mutants ofE. coli defective in tRNA processing were isolated by screening cells which were unable to synthesize a suppressor tRNA at restrictive temperature. Structural analysis of accumulated tRNA precursors showed that the isolated mutants were defective in RNase P activity. Analyses of the mutants revealed that the enzyme is essential for the synthesis of all tRNA molecules in cells and that the enzymes consists of two subunits. Analyses of the isolated mutants revealed a possible domain structure of the RNA subunit of the enzyme.Abbreviations E. coli Escherichia coli - RNase P ribonuclease P     

Chemical crosslinking of elongation factor G to the 23S RNA in 70S ribosomes from Escherichia coli

Elongation factor G was crosslinked to the 23S RNA of 70S Escherichia coli ribosomes with the bifunctional, cleavable reagent diepoxybutane (DEB). The EF-G-23S RNA complex was isolated and digested with ribonuclease A. After digestion, an RNA fragment, protected by EF-G was cleaved from the complex and isolated. The nucleotide sequence of this RNA fragment was determined by partial ribonuclease digestion. It proved to be 27 nucleotides long and it could be identified with residues 1055 to 1081 of the nucleotide sequence of E. coli 23S RNA. In the presence of thiostrepton, which prevents binding of EF-G to the ribosome, there was a dramatic decrease in the yield of this complex.     

The binding site for ribosomal protein L11 within 23 S ribosomal RNA of Escherichia coli

Ribosomal protein L11 of Escherichia coli was bound to 23 S rRNA and the resultant complex was digested with ribonuclease T1. A single RNA fragment, protected by protein L11, was isolated from such digests and was shown to rebind specifically to protein L11. The nucleotide sequence of this RNA fragment was examined by two-dimensional fingerprinting of ribonuclease digests. It proved to be 61 residues long and the constituent oligonucleotides could be fitted perfectly between residues 1052 and 1112 of the nucleotide sequence of E. coli 23 S rRNA.     

Detection of RNA nucleoside modifications with the uridine-specific ribonuclease MC1 from Momordica charantia

A codon-optimized recombinant ribonuclease, MC1 is characterized for its uridine-specific cleavage ability to map nucleoside modifications in RNA. The published MC1 amino acid sequence, as noted in a previous study, was used as a template to construct a synthetic gene with a natural codon bias favoring expression in Escherichia coli. Following optimization of various expression conditions, the active recombinant ribonuclease was successfully purified as a C-terminal His-tag fusion protein from E. coli [Rosetta 2(DE3)] cells. The isolated protein was tested for its ribonuclease activity against oligoribonucleotides and commercially available E. coli tRNA^{Tyr I}. Analysis of MC1 digestion products by ion-pairing reverse phase liquid-chromatography coupled with mass spectrometry (IP-RP-LC-MS) revealed enzymatic cleavage of RNA at the 5′-termini of uridine and pseudouridine, but cleavage was absent if the uridine was chemically modified or preceded by a nucleoside with a bulky modification. Furthermore, the utility of this enzyme to generate complementary digestion products to other common endonucleases, such as RNase T1, which enables the unambiguous mapping of modified residues in RNA is demonstrated.     

An experimentally-derived model for the secondary structure of the 16S ribosomal RNA from Escherichia coli

Ribonucleoprotein fragments are isolated by mild ribonuclease digestion of E. coli 30S ribosomal subunits, and are deproteinized and subjected to a second partial digestion. Base-pairing between the resulting small RNA fragments is investigated using the two-dimensional gel electrophoresis procedure already reported (see Ref. 1). The interactions thus found are incorporated into a secondary structure model covering approximately 80% of the 16S RNA.     

Induction by mercuric ion of extensive degradation of cellular ribonucleic acid in Escherichia coli

Low concentrations of HgCl(2) were found to induce extensive degradation of ribonucleic acid (RNA) in exponentially growing Escherichia coli cells but not in stationary-phase cells. Whereas 80% of cellular RNA was degraded during 90 min of incubation with 10(-5)m HgCl(2) at 37 C, HgCl(2) caused only slight degradation in stationary cells, even when present at concentrations higher than 5 x 10(-5)m. Inhibition of RNA synthesis occurred at almost the same concentration of HgCl(2) as degradation, and the ability of stationary-phase cells to synthesize RNA was also resistant to HgCl(2). The transition of cells from complete sensitivity to HgCl(2) to a fully insensitive state took place simultaneously with the cessation of growth. p-Chloromercuribenzoate was also found to induce remarkable degradation of RNA. In E. coli Q13, a mutant deficient for ribonuclease I, no degradation of RNA was evident, even in the exponential growth phase. 3'-Mononucleotides but not 5'-mononucleotides were found among the degradation products of cellular RNA. 2',3'-Cyclic mononucleotides were produced when RNA was degraded by the cell-free extracts of the Hg treated cells. Almost complete unmasking of the latent ribonuclease occurred in the particle fraction containing subribosomal particles of the Hg-treated cells. These data suggest that the incubation of exponentially growing E. coli cells with HgCl(2) led to the unmasking of ribonuclease I, which resulted in the extensive degradation of cellular RNA. The activation of ribonuclease by HgCl(2) in the isolated particulate fraction of E. coli K-12 which occurred in vitro suggested the presence of an Hg-sensitive inhibitor for ribonuclease I.     

Inhibition of a ribosome-inactivating ribonuclease: the crystal structure of the cytotoxic domain of colicin E3 in complex with its immunity protein

BACKGROUND: The cytotoxicity of most ribonuclease E colicins towards Escherichia coli arises from their ability to specifically cleave between bases 1493 and 1494 of 16S ribosomal RNA. This activity is carried by the C-terminal domain of the colicin, an activity which if left unneutralised would lead to destruction of the producing cell. To combat this the host E. coli cell produces an inhibitor protein, the immunity protein, which forms a complex with the ribonuclease domain effectively suppressing its activity. RESULTS: We have solved the crystal structure of the cytotoxic domain of the ribonuclease colicin E3 in complex with its immunity protein, Im3. The structure of the ribonuclease domain, the first of its class, reveals a highly twisted central beta-sheet elaborated with a short N-terminal helix, the residues of which form a well-packed interface with the immunity protein. CONCLUSIONS: The structure of the ribonuclease domain of colicin E3 is novel and forms an interface with its inhibitor which is significantly different in character to that reported for the DNase colicin complexes with their immunity proteins. The structure also gives insight into the mode of action of this class of enzymatic colicins by allowing the identification of potentially catalytic residues. This in turn reveals that the inhibitor does not bind at the active site but rather at an adjacent site, leaving the catalytic centre exposed in a fashion similar to that observed for the DNase colicins. Thus, E. coli appears to have evolved similar methods for ensuring efficient inhibition of the potentially destructive effects of the two classes of enzymatic colicins.     

Expression and purification of recombinant rat protein disulfide isomerase from Escherichia coli.

Rat liver protein disulfide isomerase (PDI) catalyzes the oxidative folding of proteins containing disulfide bonds. We have developed an efficient method for its overproduction in Escherichia coli. Using a T7 RNA polymerase expression system, isolated yields of 15-30 mg/liter of recombinant rat PDI are readily obtained. Convenient purification of the enzyme from E. coli lysates involves ion-exchange (DEAE) chromatography combined with zinc chelate chromatography. The recombinant PDI shows catalytic activity identical to that of PDI isolated from bovine liver in both the reduction of insulin and the oxidative folding of ribonuclease A. The enzyme is expressed in E. coli as a soluble, cytoplasmic protein. After complete reduction and denaturation in 6 M guanidinium hydrochloride, PDI regains complete activity within 3 min after removal of the denaturant, implying that disulfide bonds are not essential for the maintenance of PDI tertiary structure. Both the protein isolated from E. coli and the protein isolated from liver contained free cysteine residues (1.8 +/- 0.2 and 1.4 +/- 0.3 SH/monomer, respectively).     

The isolation and partial characterization of ribonuclease A from Bison bison

1. Bison ribonuclease was isolated from pancreas glands of Bison bison by acid extraction, (NH(4))(2)SO(4) fractionation, affinity chromatography on Sepharose-5'-(4-aminophenylphosphoryl)uridine 2',3'-phosphate and ion-exchange chromatography on Bio-Rex-70. 2. The selectivity of the affinity column towards bison ribonuclease in heterogeneous protein solutions was greatly improved by employing piperazine buffers at pH5.3, which decreased non-specific interactions of other proteins. Rapid desorption from the affinity column was obtained with sodium phosphate buffer (pH3). 3. Bison ribonuclease has a total amino acid content very similar to ox ribonuclease. Inactivation of bison ribonuclease with iodoacetic acid leads to the formation of 0.62 residues of pi-carboxymethylhistidine and 0.36 residues of tau-carboxymethylhistidine. The amino acid composition of peptides isolated from diagonal peptide ;maps' and also of peptides isolated after pH1.6 and 2.4 two-dimensional high-voltage electrophoresis of a digest of bison ribonuclease labelled with pyridoxal 5-phosphate indicates that there is complete homology between ox and bison ribonucleases. 4. The Schiff-base attachment site of pyridoxal 5-phosphate was identified as lysine-41 by NaBH(4) reduction followed by peptide isolation.     

Purification of ribonuclease H as a factor required for initiation of in vitro Co1E1 DNA replication.

Escherichia coli ribonuclease H was purified to near-homogeneity and identified as the only additional factor required for initiation of in vitro Co1E1 DNA replication from the unique origin by RNA polymerase and DNA polymerase I. Both ribonuclease H activity and stimulating activity for Co1E1 DNA synthesis comigrate with the single protein band in gel electrophoresis. These two activities coincide throughout the process of purification. Some DNA synthesis takes place on covalently closed-circular DNA molecules other than Co1E1 DNA with the three purified enzymes. This DNA synthesis is suppressed by an Escherichia coli single-strand DNA binding protein and/or a high concentration of ribonuclease H. Negative superhelicity of template DNA is required for efficient primer formation. No evidence that supports involvement of ribonuclease III in initiation of Co1E1 DNA replication or its regulation was found.     

A new member of the bacterial ribonuclease inhibitor family from Saccharopolyspora erythraea

We have identified Sti, the gene of a ribonuclease inhibitor from Saccharopolyspora erythraea, by using a T7 phage display system. A specific phage has been isolated from a genome library by a biopanning procedure, using RNase Sa3, a ribonuclease from Streptomyces aureofaciens, as bait. Sti, a protein of 121 amino acid residues, with molecular mass 13059 Da, is a homolog of barstar and other microbial ribonuclease inhibitors. To overexpress its gene in Escherichia coli, we optimized the secondary structure of its mRNA by introducing a series of silent mutations. Soluble protein was isolated and purified to homogeneity. Inhibition constants of complex of Sti and RNase Sa3 or barnase were determined at pH 7 as 5 x 10(-12) or 7 x 10(-7), respectively.     

Purification of the messenger ribonucleic acid for the lipoprotein of the Escherichia coli outer membrane.

The mRNA for the lipoprotein of the Escherichia coli outer membrane has been purified to 85% homogeneity. The purification procedure involved phenol extraction, NaCl extraction, gel filtration on Sephadex G-100 and Sephadex G-200, and reversed-phase column chromatography on RPC-5. The purity of the final product was estimated to be 85% by analysis of the ribonuclease T1 fingerprint of the mRNA. The purified mRNA was able to direct the synthesis of cross-reactive material with antilipoprotein serum in both the E. coli and the wheat germ cell-free protein-synthesizing systems. The size of the mRNA was determined to be 8.2 S from its mobility in polyacrylamide--agrose gels. During the purification, two other RNA species, similar in size to the lipoprotein mRNA, were also isolated. Their sizes were determined to be 8.7 and 9.1 S. They both were inactive in an E. coli cell-free protein-synthesizing system.     

Regions of RNase E important for 5'-end-dependent RNA cleavage and autoregulated synthesis

RNase E is an important regulatory enzyme that plays a key role in RNA processing and degradation in Escherichia coli. Internal cleavage by this endonuclease is accelerated by the presence of a monophosphate at the RNA 5' end. Here we show that the preference of E. coli RNase E for 5'-monophosphorylated substrates is an intrinsic property of the catalytically active amino-terminal half of the enzyme and does not require the carboxy-terminal region. This property is shared by the related E. coli ribonuclease CafA (RNase G) and by a cyanobacterial RNase E homolog derived from Synechocystis, indicating that the 5'-end dependence of RNase E is a general characteristic of members of this ribonuclease family, including those from evolutionarily distant species. Although it is dispensable for 5'-end-dependent RNA cleavage, the carboxy-terminal half of RNase E significantly enhances the ability of this ribonuclease to autoregulate its synthesis in E. coli. Despite similarities in amino acid sequence and substrate specificity, CafA is unable to replace RNase E in sustaining E. coli cell growth or in regulating RNase E production, even when overproduced sixfold relative to wild-type RNase E levels.     

In vitro selection of RNA aptamers that bind to colicin E3 and structurally resemble the decoding site of 16S ribosomal RNA

Colicin E3 is a ribonuclease that specifically cleaves at the site after A1493 of 16S rRNA in Escherichia coli ribosomes, thus inactivating translation. To analyze the interaction between colicin E3 and 16S rRNA, we used in vitro selection to isolate RNA ligands (aptamers) that bind to the C-terminal ribonuclease domain of colicin E3, from a degenerate RNA pool. Although the aptamers were not digested by colicin E3, they specifically bound to the protein (K(d) = 2-14 nM) and prevented the 16S rRNA cleavage by the C-terminal ribonuclease domain. Among these aptamers, aptamer F2-1 has a sequence similar to that of the region around the cleavage site from residue 1484 to 1506, including the decoding site, of E. coli 16S rRNA. The secondary structure of aptamer F2-1 was determined by the base pair covariation among the variants obtained by a second in vitro selection, using a doped RNA pool based on the aptamer F2-1 sequence. The sequence and structural similarities between the aptamers and 16S rRNA provide insights into the recognition of colicin E3 by this specific 16S rRNA region.     

A ubiquitin-protein ligase specific for type III protein substrates

A previously studied species of ubiquitin-protein ligase contains specific sites for the binding of basic (Type I) and bulky hydrophobic (Type II) NH2-terminal amino acid residues of protein substrates. We now describe another enzyme that ligates ubiquitin specifically to proteins that have NH2-terminal residues other than the above two categories (Type III substrates). The new species of ligase, that we call E3 beta, is separable from the formerly described ligase (termed E3 alpha) by affinity chromatography on protein substrate columns. E3 beta was partially purified from extracts of rabbit reticulocytes and was shown to be required for the breakdown of Type III proteins. Apart from its different substrate specificity, it resembles E3 alpha in some physical properties, in a requirement for ubiquitin carrier protein (E2) for conjugate formation, and in its action to ligate multiple ubiquitin units to the substrate protein. The denatured derivative of bovine pancreatic ribonuclease is a specific substrate for E3 alpha, while that of ribonuclease S-protein is a good substrate for E3 beta. Since S-protein is formed by the removal from ribonuclease of NH2-terminal S-peptide, it is suggested that E3 beta interacts with an NH2-terminal determinant exposed in ribonuclease S-protein.     

Max-Planck-Institut für Molekulare Genetik, Abteilung Wittmann, Berlin-Dahlem, GFR.

It is well established that when E. coli 30S ribosomal subunits are irradiated with ultraviolet light under mild conditions a specific cross-link is formed between protein S7 and the 16S RNA. Methodology is presented for the analysis of the single nucleotide residue concerned in this cross-link. Firstly, the identity of the ribonuclease T1 octanucleotide attached to S7 is confirmed by a new method, which involves isolation and analysis of S7-polynucleotide complexes containing 30 -- 40 nucleotides. Secondly, the isolated S7-octanucleotide complex is digested successively with ribonuclease A, proteinase K and ribonuclease T2, and the nucleotides liberated are identified. The results show unambiguously that uridine residue number 1239 in the 16S RNA sequence is cross-linked to protein S7.     

Purification and characterization of bovine aorta ribonucleases

1. Two ribonucleases (aorta ribonuclease I and aorta ribonuclease II) from bovine aorta were purified 4611-fold and 667-fold respectively. Ethanolic precipitation, acid extraction, isoionic precipitation at pH3.5 and Bio-Rex 70 column chromatography were the methods employed. 2. Aorta ribonuclease I exhibited no deoxyribonuclease or alkaline phosphatase activity. 3. Aorta ribonuclease I appeared to be homogeneous when subjected to discontinuous gel electrophoresis. 4. Aorta ribonuclease II exhibited the same properties as aorta ribonuclease previously isolated. 5. The activities of the aorta ribonucleases and pancreatic ribonuclease on homopolymers and dinucleoside phosphates were compared. 6. Aorta ribonuclease I exhibited optimum pH7.5 and, under the assay conditions used, optimum temperature 60 degrees .