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     

RNase P from bacteria. Substrate recognition and function of the protein subunit

RNase P recognizes many different precursor tRNAs as well as other substrates and cleaves all of them accurately at the expected position. RNase P recognizes the tRNA structure of the precursor tRNA by a set of interactions between the catalytic RNA subunit and the T- and acceptor-stems mainly, although residues in the 5-leader sequence as well as the 3-terminal CCA are important. These conclusions have been reached by several studies on mutant precursor tRNAs as well as cross-linking studies between RNase P RNA and precursor tRNAs. The protein subunit of RNase P seems also to affect the way that the substrate is recognized as well as the range of substrates that can be used by RNase P, although the protein does not seem to interact directly with the substrates. The interaction between the protein and RNA subunits of RNase P has been extensively studiedin vitro. The protein subunit sequence is not highly conserved among bacteria, however different proteins are functionally equivalent as heterologous reconstitution of the RNase P holoenzyme can be achieved in many cases.Abbreviations C5 protein protein subunit fromE. coli RNase P - EGS external guide sequence - M1 RNA RNA subunit formE. coli RNase P - ptRNA precursor tRNA - RNase P ribonuclease P     

Escherichia coli tRNAs Are Resistant to the Hyperprocessing Reaction of Homologous E. coli Ribonuclease P Ribozyme

Bacterial ribonuclease P RNA ribozyme can do the hyperprocessing reaction, the internal cleavage reaction of some floppy eukaryotic tRNAs. The hyperprocessing reaction can be used as a detection tool to examine the stability of the cloverleaf shape of tRNA. Until now, the hyperprocessing reaction has been observed in the heterologous combination of eukaryotic tRNAs and bacterial RNase P enzymes. In this paper, we examined the hyperprocessing reaction of Escherichia coli tRNAs by homologous E. coli RNase P, to find that these homologous tRNAs were resistant to the toxic hyperprocessing reaction. Our results display the evidence for molecular co-evolution between homologous tRNAs and RNase P in the bacterium E. coli.     

Effects of <Emphasis Type="Italic">Escherichia coli</Emphasis> RraA Orthologs of <Emphasis Type="Italic">Vibrio vulnificus</Emphasis> on the Ribonucleolytic Activity of RNase E In Vivo

RraA is a recently discovered protein inhibitor of RNase E that catalyzes the initial step in the decay and processing of numerous RNAs in Escherichia coli. In the genome of Vibrio vulnificus, two open reading frames that potentially encode proteins homologous to E. coli, RraA-designated RraAV1 and RraAV2, have respectively 80.1% and 59.0% amino acid identity to RraA. The authors report that coexpression of RraAV1 protein in E. coli cells overproducing RNase E rescued these cells from growth arrest and restored their normal growth, whereas coexpression of RraAV2 protein further inhibited the growth of E. coli cells, whose growth was already impaired by overproduction of RNase E. Analyses of the steady-state level of various RNase E substrates indicated that the coexpression of RraAV1 more efficiently inhibited RNase E action than coexpression of RraA, and consequently resulted in the more increased abundance of each RNA species tested in vivo. The inhibitory effect by RraAV2 coexpression on RNase E was observed only in the case of trpA mRNA, indicating the possibility of RNA substrate-dependent inhibition of RraAV2 on RNase E. The findings suggest that these regulators of ribonuclease activity have both a conserved inhibitory function and a differential inhibitory activity on RNase E-like enzymes across the species.     

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.     

Porphyrins and porphines bind strongly and specifically to tRNA, precursor tRNA and to M1 RNA and inhibit the ribonuclease P ribozyme reaction

Porphyrins and porphines strongly inhibit the action of the RNA subunit of the Escherichia coli ribonuclease P (M1 RNA). Meso-tetrakis(N-methyl-pyridyl)porphine followed linear competitive kinetics with pre-tRNA(Gly1) from E. coli as variable substrate (Ki 0.960 microM). Protoporphyrin IX showed linear competitive inhibition versus pre-tRNA(Gly1) from E. coli (Ki 1.90 microM). Inhibition by meso-tetrakis[4-(trimethylammonio)phenyl]porphine versus pre-tRNA(Gly1) from E. coli followed non-competitive kinetics (Ki 4.1 microM). The porphyrins bound directly to E. coli tRNAVal, E. coli pre-tRNAGly1 and M1 RNA and dissociation constants for the 1:1 complexes were determined using fluorescence spectroscopy. Dissociation constants (microM) against E. coli tRNAVal and E. coli pre-tRNAGly were: meso-tetrakis(N-methyl-pyridyl)porphine 1.21 and 0.170; meso-tetrakis[4-(trimethylammonio)phenyl]porphine, 0.107 and 0.293; protoporphyrin IX, 0.138 and 0.0819. For M1 RNA, dissociation constants were 32.8 nM for meso-tetrakis(N-methyl-pyridyl)porphine and 59.8 nM for meso-tetrakis[4-(trimethylammonio)phenyl]porphine and excitation and emission spectra indicate a binding mode with strong pi-stacking of the porphine nucleus and base pairs in a rigid low-polarity environment. Part of the inhibition of ribonuclease P is from interaction with the pre-tRNA substrate, resulting from porphyrin binding to the D-loop/T-loop region which interfaces with M1 RNA during catalysis, and part from the porphyrin binding to the M1 RNA component.     

Expression,purification and characterization of the interferon-inducible,antiviral and tumour-suppressor protein,human RNase L

The interferon (IFN)-inducible, 2′,5′-oligoadenylate (2-5A)-dependent ribonuclease L (RNase L) plays key role in antiviral defense of mammalian cells. Induction by IFN and activation by double-stranded RNA lead to 2-5A cofactor synthesis, which activates RNase L by causing its dimerization. Active RNase L degrades single-stranded viral as well as cellular RNAs causing apoptosis of virus-infected cells. Earlier, we had reported that expression of recombinant human RNase L caused RNA-degradation and cell-growth inhibition in E. coli without the need for exogenous 2-5A. Expression of human RNase L in E. coli usually leads to problems of leaky expression, low yield and degradation of the recombinant protein, which demands number of chromatographic steps for its subsequent purification thereby, compromising its biochemical activity. Here, we report a convenient protocol for expression of full-length, soluble and biochemically active recombinant human RNase L as GST-RNase L fusion protein from E. coli utilizing a single-step affinity purification with an appreciable yield of the highly purified protein. Recombinant RNase L was characterized by SDS-PAGE, immunoblotting and MALDI-TOF analysis. A semi-quantitative agarose-gel-based ribonuclease assay was developed for measuring its 2-5A-dependent RNase L activity against cellular large rRNAs as substrates. The optimized expression conditions minimized degradation of the protein, making it a convenient method for purification of RNase L, which can be utilized to study effects of various agents on the RNase L activity and its protein–protein interactions.     

Identification of Escherichia coli and Bacillus stearothermophilus ribosomal protein binding sites on Escherichia coli 5S RNA.

Summary E. coli [³²P]-labelled 5S RNA was complexed with E. coli and B. stearothermophilus 50S ribosomal proteins. Limited T₁ RNase digestion of each complex yielded three major fragments which were analysed for their sequences and rebinding of proteins. The primary binding sites for the E. coli binding proteins were determined to be sequences 18 to 57 for E-L5, 58 to 100 for E-L18 and 101 to 116 for E-L25. Rebinding experiments of purified E. coli proteins to the 5S RNA fragments led to the conclusion that E-L5 and E-L25 have secondary binding sites in the section 58 to 100, the primary binding site for E-L18. Since B. stearothermophilus proteins B-L5 and BL22 were found to interact with sequences 18 to 57 and 58 to 100 it was established that the thermophile proteins recognize and interact with RNA sequences similar to those of E. coli. Comparison of the E. coli 5S RNA sequence with those of other prokaryotic 5S RNAs reveals that the ribosomal proteins interact with the most conserved sections of the RNA.Paper number 12 on structure and function of 5S RNA.Preceding paper: Wrede, P. and Erdmann, V.A. Proc. Natl. Acad. Sci. USA 74, 2706–2709 (1977)     

Enhancement of RNA annealing and strand displacement found in archaeal ribonuclease P proteins is conserved in Escherichia coli protein C5 and yeast protein Rpr2

We analyzed modes of action of ribonuclease P (RNase P) proteins, C5 in Escherichia coli and Rpr2 in Saccharomyces cerevisiae, using a pair of complementary fluorescence-labeled oligoribonucleotides. Fluorescence resonance energy transfer-based assays revealed that RNA annealing and strand displacement activities found in archaeal RNase P proteins are prevalent in eubacterial (C5) and eukaryotic (Rpr2) RNase P proteins.     

抗菌肽P7抑制大肠杆菌的非膜作用机制北大核心CSCD

【目的】研究抗菌肽P7抑制大肠杆菌的非膜作用机制。【方法】P7与溴化乙锭竞争结合大肠杆菌基因组DNA的荧光光谱,分析P7与DNA的结合方式;流式细胞术分析P7与大肠杆菌基因组DNA结合对细菌细胞周期的影响;采用磁珠富集和PCR扩增相结合的方法分析P7特异结合的DNA序列;通过实时荧光定量PCR分析P7对大肠杆菌DNA复制和SOS损伤修复基因表达的影响;核酸染料的荧光分析研究P7对大肠杆菌DNA和RNA合成的影响。【结果】P7以嵌插的方式作用于大肠杆菌基因组DNA碱基对并形成肽-DNA复合物,使溴化乙锭-DNA复合体系的荧光强度减弱。P7可以显著增加大肠杆菌细胞周期中S期细胞数目,抑制大肠杆菌DNA复制。P7特异性结合rnh A使该基因表达水平显著下调2.24倍。同时,在肽的影响下参与大肠杆菌DNA复制相关的ssb、dna G、lig B和rnh A基因的表达水平显著下调(P<0.05),DNA损伤修复的rec A和rec N基因显著上调(P<0.05)。P7可降低大肠杆菌DNA和RNA的合成。【结论】P7特异性地结合rnh A序列引起大肠杆菌DNA的损伤并抑制大肠杆菌的DNA复制。在P7的影响下,参与大肠杆菌DNA复制相关的基因的表达水平下调,DNA损伤修复基因显著上调,同时抑制大肠杆菌DNA和RNA的合成。     

Molecular cloning of tobacco chloroplast ribosomal RNA genes

Summary Tobacco chloroplast ribosomal RNAs were shown to be hybridized with two EcoRI fragments of tobacco chloroplast DNA. These DNA fragments having molecular weights of 1.9x10⁶ and 2.8x10⁶ daltons were cloned using the bacterial plasmid pMB9 as a vector and E. coli HB101 as host bacteria. The recombinant plasmids containing either or both of these fragments were constructed and characterized.Abbreviations rRNA ribosomal RNA - EDTA ethylenediamine tetraacetic acid - SSC 0.15 M NaCl-0.015 M sodium citrate - EcoRI and HindIII restriction endonucleases isolated from E. coli RY13 and Haemophilus influenzae Rd, respectively     

RNase P: role of distinct protein cofactors in tRNA substrate recognition and RNA-based catalysis

The Escherichia coli ribonuclease P (RNase P) has a protein component, termed C5, which acts as a cofactor for the catalytic M1 RNA subunit that processes the 5′ leader sequence of precursor tRNA. Rpp29, a conserved protein subunit of human RNase P, can substitute for C5 protein in reconstitution assays of M1 RNA activity. To better understand the role of the former protein, we compare the mode of action of Rpp29 to that of the C5 protein in activation of M1 RNA. Enzyme kinetic analyses reveal that complexes of M1 RNA–Rpp29 and M1 RNA–C5 exhibit comparable binding affinities to precursor tRNA but different catalytic efficiencies. High concentrations of substrate impede the activity of the former complex. Rpp29 itself exhibits high affinity in substrate binding, which seems to reduce the catalytic efficiency of the reconstituted ribonucleoprotein. Rpp29 has a conserved C-terminal domain with an Sm-like fold that mediates interaction with M1 RNA and precursor tRNA and can activate M1 RNA. The results suggest that distinct protein folds in two unrelated protein cofactors can facilitate transition from RNA- to ribonucleoprotein-based catalysis by RNase P.     

The nucleotide sequences of some large ribonuclease T1 products from bacteriophage R17 ribonucleic acid

A method of `fingerprinting' high-molecular-weight <sup>32</sup>P-labelled RNA species, using a two-dimensional thin-layer-chromatographic separation of ribonuclease T<sub>1</sub> digestion products, has been applied to RNA from the Escherichia coli bacteriophage R17. The `fingerprinting' technique, besides giving a unique pattern that can be used as a characterization of the RNA, has made it possible to isolate a number of the larger oligonucleotides and to determine their nucleotide sequences.     

Fingerprinting nonradioactive ribonucleic acid with the aid of polynucleotide phosphorylase

We describe a method for obtaining radioactive fingerprints from nonradioactive ribonucleic acid. Fragments derived by T1 ribonuclease digestion of RNA are dephosphorylated with bacterial alkaline phosphatase. When these fragments are used as primers for the reaction of primer dependent polynucleotide phosphorylase with [α-³²P]GDP in the presence of T1 ribonuclease the 3′-hydroxyl group of each fragment becomes phosphorylated. The degree of phosphorylation is reasonably uniform. The method has been applied to T1 ribonuclease digests of Escherichia coli tRNA^Met_f; the oligonucleotides were further analyzed by spleen phosphodiesterase digestion. In a similar manner fingerprints of pancreatic ribonuclease digests of RNA can be obtained, when [α-³²P]UDP, polynucleotide phosphorylase and pancreatic ribonuclease are used.     

Enzymatic cleavage of RNA by RNA

The discovery and characterization of the catalytic RNA subunit of the enzyme ribonuclease P ofEscherichia coli is described.Nobel lecture given on December 8, 1989, by Professor Sidney Altman, and published in LES PRIX NOBEL 1989, printed in Sweden by Norstedts Tryckeri, Stockholm, Sweden, 1990, republished here with the permission of the Nobel Foundation, the copyright holder.     

Rescue of the fission yeast snRNA synthesis mutant snm1 by overexpression of the double-strand-specific Pac1 ribonuclease

The Schizosaccharomyces pombe temperature-sensitive mutant snm1 maintains reduced steady-state quantities of the spliceosomal small nuclear RNAs (snRNAs) and the RNA subunit of the tRNA processing enzyme RNase P. We report here the isolation of the pac1 ⁺ gene as a multi-copy suppressor of snm1. The pac1 ⁺ gene was previously identified as a suppressor of the ran1 mutant and by its ability to cause sterility when overexpressed. The pac1 ⁺ gene encodes a double-strand-specific ribonuclease that is similar to RNase III, an RNA processing and turnover enzyme in Escherichia coli. To investigate the essential structural features of the Pac1 RNase, we altered the pac1 ⁺ gene by deletion and point mutation and tested the mutant constructs for their ability to complement the snm1 and ran1 mutants and to cause sterility. These experiments identified four essential amino acids in the Pac1 sequence: glycine 178, glutamic acid 251, and valines 346 and 347. These amino acids are conserved in all RNase III-like proteins. The glycine and glutamic acid residues were previously identified as essential for E. coli RNase III activity. The valines are conserved in an element found in a family of double-stranded RNA binding proteins. Our results support the hypothesis that the Pac1 RNase is an RNase III homolog and suggest a role for the Pac1 RNase in snRNA metabolism.     

Cleavage of RNA in hybrid duplexes by theE. coli ribonuclease H: II. Substrate properties of oligonucleotides containing nonnucleotide linkers

The 20-mer bridged oligodeoxynucleotides containing short oligomers joined by the hexamethylenediol and hexaethylene glycol linkers were shown to form complementary DNA/DNA and RNA/DNA complexes whose thermostability depends on the length and number of the nonnucleotide linkers. Hybrid complexes of the bridged oligonucleotides proved to be substrates for theE. coli ribonuclease H. The presence of one-three nonnucleotide linkers in a 20-mer decreased the hydrolysis efficacy only 1.2–1.4-fold. It is the composition of the RNA cleavage products that was influenced the most significantly by the nonnucleotide linkers. RNase H simultaneously hydrolyzed the RNA 3′-ends of each hybrid duplex involving a bridged oligonucleotide. The presence of an inverted 3′-3′-phosphodiester bond at the 3′-end of the oligodeoxyribonucleotide only slightly affected the RNase H activity. For the previous report, see [1].     

Secreted β-galactosidase from a Flavobacterium sp. isolated from a low-temperature environment

The bacterial strain Flavobacterium sp. 4214 isolated from Greenland was found to express β-galactosidase (EC 3.2.1.23) at temperatures below 25°C. A chromosomal library of Flavobacterium sp. 4214 was constructed in Escherichia coli, and the gene gal4214-1 encoding a β-galactosidase of 1,046 amino acids (114.3 kDa) belonging to glycosyl hydrolase family 2 was isolated. This was the only gene encoding β-galactosidase activity that was identified in the chromosomal library. Expression levels in both Flavobacterium sp. 4214 and in initial recombinant E. coli strains were insufficient for biochemical characterization. However, a combination of T7 promoter expression and introduction of an E. coli host that complemented rare transfer RNA genes yielded 15 mg of β-galactosidase per liter of culture. Gal4214-1-His protein was found to be active in monomeric conformation. The protein was secreted from the cytoplasm, probably through an N-terminal signaling sequence. The Gal4214-1-His protein was found to have optimum activity at a temperature of 42°C, but with short-term stability at temperatures above 25°C.