Sequencing of CJIE1 prophages from Campylobacter jejuni isolates reveals the presence of inserted and (or) deleted genes

Bacteriophages capable of integrating into host bacterial genomes as prophages affect the biology and virulence of their bacterial hosts. Previously, partial sequencing of 12 prophages similar to CJIE1 from Campylobacter jejuni RM1221 did not show the presence of inserted nonphage genes. Therefore, four of these prophages were sequenced completely, and indels were found in at least two different regions of the prophage genome. Putative proteins from one indel appeared to be members of two new families of proteins, with proteins within each family related to each other by a common domain. Further heterogeneity was found adjacent to the CJE0270 homolog, creating difficulty locating the end of the prophage on this side and in determining the composition of the core prophage. These prophages appear to comprise a family that has heterogeneity in gene content resulting from insertion or deletion of additional genes at three locations in their genomes. In addition, members of the CJIE1 phage family may differ somewhat in their biology from phage Mu. Further investigations of these Campylobacter prophages can be expected to provide interesting insights into the biology of the phages themselves and into the role of these phages in the biology of their hosts.     

molecular mechanism of lysidine synthesis that determines tRNA identity and codon recognition

Lysidine (2-lysyl cytidine) is a lysine-containing cytidine derivative commonly found at the wobble position of bacterial AUA codon-specific tRNA(Ile). This modification determines both codon and amino acid specificities of tRNA(Ile). We previously identified tRNA(Ile)-lysidine synthetase (tilS) that synthesizes lysidine, for which it utilizes ATP and lysine as substrates. Here, we show that lysidine synthesis consists of two consecutive reactions that involve an adenylated tRNA intermediate. A mutation study revealed that Escherichia coli TilS discriminates tRNA(Ile) from the structurally similar tRNA(Met) having the same anticodon loop by recognizing the anticodon loop, the anticodon stem, and the acceptor stem. TilS was shown to bind to the anticodon region and 3' side of the acceptor stem, which cover the recognition sites. These findings reveal a dedicated mechanism embedded in tRNA(Ile) that controls its recognition and discrimination by TilS, and indicate the significance of this enzyme in the proper deciphering of genetic information.     

Bacteriophage T12 of Streptococcus pyogenes integrates into the gene encoding a serine tRNA

The region of temperate bacteriophage T12 responsible for integration into the chromosome of Streptococcus pyogenes has been identified. The integrase gene ( int ) and the phage attachment site ( attP ) are found immediately upstream of the gene for speA , the latter of which is known to be responsible for the production of erythrogenic toxin A (also known as pyrogenic exotoxin A). The integrase gene has a coding capacity for a protein of 41 457 Da, and the C-terminus of the deduced protein is similar to other conserved C-terminal regions typical of phage integrases. Upstream of int is a second open reading frame, which is capable of encoding an acidic protein of 72 amino acids (8744 Da); the position of this region in relation to int suggests it to be the phage excisionase gene ( xis ). The arms flanking the integrated prophage ( attL and attR ) were identified, allowing determination of the sequences of the phage ( attP ) and bacterial ( attB ) attachment sites. A fragment containing the integrase gene and attP was cloned into a streptococcal suicide vector; when introduced into S. pyogenes by electrotransformation, this plasmid stably integrated into the bacterial chromosome at attB . The insertion site for the phage into the S. pyogenes chromosome was found to be in the anticodon loop of a putative type II gene for a serine tRNA. attP and attB share a region of identity that is 96 bp in length; this region of identity corresponds to the 3' end of the tRNA gene such that the coding sequence remains intact after integration of the prophage. The symmetry of the core region of att may set this region apart from previously described phage attachment sites (Campbell, 1992), and may play a role in the biology of this medically important bacteriophage.     

Frameshift suppressor mutations outside the anticodon in yeast proline tRNAs containing an intervening sequence.

Extragenic suppressors of +1 frameshift mutations in proline codons map in genes encoding two major proline tRNA isoacceptors. We have shown previously that one isoacceptor encoded by the SUF2 gene (chromosome 3) contains no intervening sequence. SUF2 suppressor mutations result from the base insertion of a G within a 3'-GGA-5' anticodon, allowing the tRNA to read a 4-base code word. In this communication we describe suppressor mutations in genes encoding a second proline tRNA isoacceptor (wild-type anticodon 3'-GGU-5') that result in a novel mechanism for translation of a 4-base genetic code word. The genes that encode this isoacceptor include SUF7 (chromosome 13), SUF8 (chromosome 8), trn1 (chromosome 1), and at least two additional unmapped genes, all of which contain an intervening sequence. We show that suppressor mutations in the SUF7 and SUF8 genes result in G-to-U base substitutions at position 39 that disrupted the normal G . C base pairing in the last base pair of the anticodon stem adjacent to the anticodon loop. These anticodon stem mutations might alter the size of the anticodon loop and permit the use of a 3'-GGGU-5' sequence within the loop to read 4-base proline codons. Uncertainty regarding the exact structure of the mature suppressor tRNAs results from the possibility that anticodon stem mutations might affect sites of intervening sequence removal. The possible role of the intervening sequence in the generation of mature suppressor tRNA is discussed. Besides an analysis of suppressor tRNA genes, we have extended previous observations of the apparent relationship between tRNA genes and repetitive delta sequences found as solo elements or in association with the transposable element TY1. Hybridization studies and a computer analysis of the DNA sequence surrounding the SUF7 gene revealed two incomplete, inverted delta sequences that form a stem and loop structure located 165 base pairs from the 5' end of the tRNA gene. In addition, sequences beginning 164 base pairs from the 5' end of the trn1 gene also exhibit partial homology to delta. These observations provide further evidence for a nonrandom association between tRNA genes and delta sequences.     

Identification of prophages in bacterial genomes by dinucleotide relative abundance difference

Background

Prophages are integrated viral forms in bacterial genomes that have been found to contribute to interstrain genetic variability. Many virulence-associated genes are reported to be prophage encoded. Present computational methods to detect prophages are either by identifying possible essential proteins such as integrases or by an extension of this technique, which involves identifying a region containing proteins similar to those occurring in prophages. These methods suffer due to the problem of low sequence similarity at the protein level, which suggests that a nucleotide based approach could be useful.

Methodology

Earlier dinucleotide relative abundance (DRA) have been used to identify regions, which deviate from the neighborhood areas, in genomes. We have used the difference in the dinucleotide relative abundance (DRAD) between the bacterial and prophage DNA to aid location of DNA stretches that could be of prophage origin in bacterial genomes. Prophage sequences which deviate from bacterial regions in their dinucleotide frequencies are detected by scanning bacterial genome sequences. The method was validated using a subset of genomes with prophage data from literature reports. A web interface for prophage scan based on this method is available at http://bicmku.in:8082/prophagedb/dra.html. Two hundred bacterial genomes which do not have annotated prophages have been scanned for prophage regions using this method.

Conclusions

The relative dinucleotide distribution difference helps detect prophage regions in genome sequences. The usefulness of this method is seen in the identification of 461 highly probable loci pertaining to prophages which have not been annotated so earlier. This work emphasizes the need to extend the efforts to detect and annotate prophage elements in genome sequences.     

Analysis of magnesium, europium and lead binding sites in methionine initiator and elongator tRNAs by specific metal-ion-induced cleavages

The specificity of cleavages in yeast and lupin initiator and elongator methionine tRNAs induced by magnesium, europium and lead has been analysed and compared with known patterns of yeast tRNA(Phe) hydrolysis. The strong D-loop cleavages occur in methionine elongator tRNAs at similar positions and with comparable efficiency to those found in tRNA(Phe), while the sites of weak anticodon loop cuts, identical in methionine elongator tRNAs, differ from those found in tRNA(Phe). Methionine initiator tRNAs differ from their elongator counterparts: (a) they are cleaved in the D-loop with much lower efficiency; (b) they are cleaved in the variable loop which is completely resistant to hydrolysis in elongator tRNAs; (c) cleavages in the anticodon loop are stronger in initiator tRNAs and they are located mostly at the 5' side of the loop whereas in elongator tRNAs they occur mostly at the opposite, 3' side of the loop. The distinct pattern of the anticodon loop cleavages is considered to be related to different conformations of the anticodon loop in the two types of methionine tRNAs.     

Effect of ribosome binding and translocation on the anticodon of tRNAPhe as studied by wybutine fluorescence.

The complexes of N-AcPhe-tRNAPhe (or non-aminoacylated tRNAPhe) from yeast with 70S ribosomes from E. coli have been studied fluorimetrically utilizing wybutine, the fluorophore naturally occurring next to the 3' side of the anticodon, as a probe for conformational changes of the anticodon loop. The fluorescence parameters are very similar for tRNA bound to both ribosomal sites, thus excluding an appreciable conformational change of the anticodon loop upon translocation. The spectral change observed upon binding of tRNAPhe to the P site even in the absence of poly(U) is similar to the one brought about by binding of poly(U) alone to the tRNA. This effect may be due to a hydrophobic binding site of the anticodon loop or to a conformational change of the loop induced by binding interactions of various tRNA sites including the anticodon.     

Subclassification and targeted characterization of prophage-encoded two-component cell lysis cassette

Bacteriophage induced lysis of host bacterial cell is mediated by a two component cell lysis cassette comprised of holin and lysozyme. Prophages are integrated forms of bacteriophages in bacterial genomes providing a repertoire for bacterial evolution. Analysis using the prophage database (http://bicmku.in:8082) constructed by us showed 47 prophages were associated with putative two component cell lysis genes. These proteins cluster into four different subgroups. In this process, a putative holin (essd) and endolysin (ybcS), encoded by the defective lambdoid prophage DLP12 was found to be similar to two component cell lysis genes in functional bacteriophages like p21 and P1. The holin essd was found to have a characteristic dual start motif with two transmembrane regions and C-terminal charged residues as in class II holins. Expression of a fusion construct of essd in Escherichia coli showed slow growth. However, under appropriate conditions, this protein could be over expressed and purified for structure function studies.The second component of the cell lysis cassette, ybcS, was found to have an N-terminal SAR (Signal Arrest Release) transmembrane domain. The construct of ybcS has been over expressed in E.coli and the purified protein was functional, exhibiting lytic activity against E.coli and Salmonella typhi cell wall substrate. Such targeted sequence- structure-function characterization of proteins encoded by cryptic prophages will help understand the contribution of prophage proteins to bacterial evolution.     

Temperature jump relaxation studies on the interactions between transfer RNAs with complementary anticodons. The effect of modified bases adjacent to the anticodon triplet

We have used the temperature-jump relaxation technique to determine the kinetic and thermodynamic parameters for the association between the following tRNAs pairs having complementary anticodons: tRNA(Ser) with tRNA(Gly), tRNA(Cys) with tRNA(Ala) and tRNA(Trp) with tRNA(Pro). The anticodon sequence of E. coli tRNA(Ser), GGA, is complementary to the U*CC anticodon of E. coli tRNA(Gly(2] (where U* is a still unknown modified uridine base) and A37 is not modified in none of these two tRNAs. E. coli tRNA(Ala) has a VGC anticodon (V is 5-oxyacetic acid uridine) while tRNA(Cys) has the complementary GCA anticodon with a modified adenine on the 3' side, namely 2-methylthio N6-isopentenyl adenine (mS2i6A37) in E. Coli tRNA(Cys) and N6-isopentenyl adenine (i6A37) in yeast tRNA(Cys). The brewer yeast tRNA(Trp) (anticodon CmCA) differs from the wild type E. coli tRNA(Trp) (anticodon CCA) in several positions of the nucleotide sequence. Nevertheless, in the anticodon loop, only two interesting differences are present: A37 is not modified while C34 at the first anticodon position is modified into a ribose 2'-O methyl derivative (Cm). The corresponding complementary tRNA is E.coli tRNA(Pro) with the VGG anticodon. Our results indicate a dominant effect of the nature and sequence of the anticodon bases and their nearest neighbor in the anticodon loop (particularly at position 37 on the 3' side); no detectable influence of modifications in the other tRNA stems has been detected. We found a strong stabilizing effect of the methylthio group on i6A37 as compared to isopentenyl modification of the same residue. We have not been able so far to assess the effect of isopentenyl modification alone in comparison to unmodified A37. The results obtained with the complex yeast tRNA(Trp)-E.coli tRNA(Pro) also suggest that a modification of C34 to Cm34 does not significantly increase the stability of tRNA(Trp) association with its complementary anticodon in tRNA(Pro). The observations are discussed in the light of inter- and intra-strand stacking interactions among the anticodon triplets and with the purine base adjacent to them, and of possible biological implications.     

Prophage genomics.

The majority of the bacterial genome sequences deposited in the National Center for Biotechnology Information database contain prophage sequences. Analysis of the prophages suggested that after being integrated into bacterial genomes, they undergo a complex decay process consisting of inactivating point mutations, genome rearrangements, modular exchanges, invasion by further mobile DNA elements, and massive DNA deletion. We review the technical difficulties in defining such altered prophage sequences in bacterial genomes and discuss theoretical frameworks for the phage-bacterium interaction at the genomic level. The published genome sequences from three groups of eubacteria (low- and high-G+C gram-positive bacteria and gamma-proteobacteria) were screened for prophage sequences. The prophages from Streptococcus pyogenes served as test case for theoretical predictions of the role of prophages in the evolution of pathogenic bacteria. The genomes from further human, animal, and plant pathogens, as well as commensal and free-living bacteria, were included in the analysis to see whether the same principles of prophage genomics apply for bacteria living in different ecological niches and coming from distinct phylogenetical affinities. The effect of selection pressure on the host bacterium is apparently an important force shaping the prophage genomes in low-G+C gram-positive bacteria and gamma-proteobacteria.     

Anticodon-dependent conservation of bacterial tRNA gene sequences

The residues in tRNA that account for its tertiary fold and for its specific aminoacylation are well understood. In contrast, relatively little is known about the residues in tRNA that dictate its ability to transit the different sites of the ribosome. Yet protein synthesis cannot occur unless tRNA properly engages with the ribosome. This study analyzes tRNA gene sequences from 145 fully sequenced bacterial genomes. Grouping the sequences according to the anticodon triplet reveals that many residues in tRNA, including some that are distal to the anticodon loop, are conserved in an anticodon-dependent manner. These residues evade detection when tRNA genes are grouped according to amino acid family. The conserved residues include those at positions 32, 38, and 37 of the anticodon loop, which are already known to influence tRNA translational performance. Therefore, it seems likely that the newly detected anticodon-associated residues also influence tRNA performance on the ribosome. Remarkably, tRNA genes that belong to the same amino acid family and therefore share identical residues at the second and third anticodon positions have diverged, during bacterial evolution, into highly conserved groups that are defined by the residue at the first (wobble) anticodon position. Current ideas about the properties of tRNA and the translation mechanism do not fully account for this phenomenon. The results of the present study provide a foundation for studying the adaptation of individual tRNAs to the translation machinery and for future studies of the translation mechanism.     

Seven, eight and nine-membered anticodon loop mutants of tRNA(2Arg) which cause +1 frameshifting. Tolerance of DHU arm and other secondary mutations.

The mutant tRNA(2Arg) encoded by the genetically-selected frameshift suppressor, sufT621, inserts arginine and causes a +1 reading-frame shift at the proline codon, CCG(U). There is an extra base, G36.1, in argV beta, one of the four identical genes for tRNA(2Arg) in the position between bases 36 and 37, corresponding to the 3' side of the anticodon. The new four-base anticodon, predicted from DNA sequencing to be 3' GGCA 5', is complementary to the four-base codon CCGU. Quadruplet translocation promoted by mutant argV does not require perfect complementarity between the codon and the anticodon since synthetic genes encoding derivatives of tRNA(2Arg) and tRNA(1Pro), with four-base anticodons complementary to three out of the four bases of CCGU, were also shown to be capable of frameshifting. Two other mutants of argV, inferred to have normal-size, seven-base anticodon loops, were also found to be capable of four-base-decoding demonstrating that quadruplet translocation promoted by mutant argV does not require an enlarged anticodon loop. Other alleles of argV, predicted to have nine bases in the anticodon loop, were also found to cause frameshifting. The DNA sequence of two of these showed in addition, either a deletion of G24, or a ten-base duplication in the region corresponding to the TFC arm. A general finding is that mutations in the DHU arm of tRNA(2Arg) are compatible with, and in one case necessary for, frameshifting.     

Induction of multiple prophages from a marine bacterium: a genomic approach

Approximately 70% of sequenced bacterial genomes contain prophage-like structures, yet little effort has been made to use this information to determine the functions of these elements. The recent genomic sequencing of the marine bacterium Silicibacter sp. strain TM1040 revealed five prophage-like elements in its genome. The genomes of these prophages (named prophages 1 to 5) are approximately 74, 30, 39, 36, and 15 kb long, respectively. To understand the function of these prophages, cultures of TM1040 were treated with mitomycin C to induce the production of viral particles. A significant increase in viral counts and a decrease in bacterial counts when treated with mitomycin C suggested that prophages were induced from TM1040. Transmission electron microscopy revealed one dominant type of siphovirus, while pulsed-field gel electrophoresis demonstrated two major DNA bands, equivalent to 35 and 75 kb, in the lysate. PCR amplification with primer sets specific to each prophage detected the presence of prophages 1, 3, and 4 in the viral lysate, suggesting that these prophages are inducible, but not necessarily to the same level, while prophages 2 and 5 are likely defective or non-mitomycin C-inducible phages. The combination of traditional phage assays and modern microbial genomics provides a quick and efficient way to investigate the functions and inducibility of prophages, particularly for a host harboring multiple prophages with similar sizes and morphological features.     

Induction of Multiple Prophages from a Marine Bacterium: a Genomic Approach

Approximately 70% of sequenced bacterial genomes contain prophage-like structures, yet little effort has been made to use this information to determine the functions of these elements. The recent genomic sequencing of the marine bacterium Silicibacter sp. strain TM1040 revealed five prophage-like elements in its genome. The genomes of these prophages (named prophages 1 to 5) are approximately 74, 30, 39, 36, and 15 kb long, respectively. To understand the function of these prophages, cultures of TM1040 were treated with mitomycin C to induce the production of viral particles. A significant increase in viral counts and a decrease in bacterial counts when treated with mitomycin C suggested that prophages were induced from TM1040. Transmission electron microscopy revealed one dominant type of siphovirus, while pulsed-field gel electrophoresis demonstrated two major DNA bands, equivalent to 35 and 75 kb, in the lysate. PCR amplification with primer sets specific to each prophage detected the presence of prophages 1, 3, and 4 in the viral lysate, suggesting that these prophages are inducible, but not necessarily to the same level, while prophages 2 and 5 are likely defective or non-mitomycin C-inducible phages. The combination of traditional phage assays and modern microbial genomics provides a quick and efficient way to investigate the functions and inducibility of prophages, particularly for a host harboring multiple prophages with similar sizes and morphological features.     

酱香型白酒发酵中地衣芽孢杆菌前噬菌体的鉴别

【背景】噬菌体是微生物群落的重要组成部分,但传统白酒发酵中噬菌体的分类和存在尚不清楚。【目的】通过检测公共数据库和酱香型白酒发酵中地衣芽孢杆菌(Bacillus licheniformis)基因组中的前噬菌体整合区域,探究传统酱香型白酒发酵中关键功能菌株的前噬菌体分类和侵染情况。【方法】使用未培养(细菌全基因组分析)和可培养(菌株筛选和特异性PCR反应)技术对不同环境来源和来自酱香型白酒发酵的地衣芽孢杆菌前噬菌体的分类和存在进行解析。【结果】细菌全基因组分析显示,30株来自不同环境的地衣芽孢杆菌基因组中共注释到165个前噬菌体,其中63.6%(105/165)为完整前噬菌体序列。97.1%感染地衣芽孢杆菌的噬菌体属于长尾噬菌体科(Siphoviridae),2.9%属于肌尾噬菌体科(Myoviridae),53.0%完整前噬菌体的基因功能未知。在来自酱香型白酒发酵的B. licheniformis MT-B06中检测到7个前噬菌体整合序列,其中57.1%(4/7)为完整前噬菌体序列,来自酱香型白酒发酵的地衣芽孢杆菌存在多种不同前噬菌体的共感染。来自酱香型白酒发酵的地衣芽孢杆菌前噬菌体存在来自细菌基因组上相邻CotD孢子外壳蛋白(CotD family spore coat protein)基因的水平基因转移。在26株来自酱香型白酒发酵的地衣芽孢杆菌中,69.2%(18/26)存在噬菌体编码主要衣壳蛋白的基因,100.0%(26/26)存在噬菌体编码CotD孢子外壳蛋白的基因。【结论】来自不同环境的地衣芽孢杆菌和酱香型白酒发酵的地衣芽孢杆菌中存在高水平的前噬菌体整合,来自酱香型白酒发酵的地衣芽孢杆菌前噬菌体中广泛存在来源于宿主的CotD孢子外壳蛋白基因的水平基因转移。本研究为首次对传统发酵白酒中噬菌体的分类和存在进行探究,有助于对发酵微生物群落中噬菌体-细菌相互作用加深理解。     

Specific interaction between anticodon nuclease and the tRNA(Lys) wobble base

The bacterial tRNA(Lys)-specific PrrC-anticodon nuclease cleaves its natural substrate 5' to the wobble base, yielding 2',3'-cyclic phosphate termini. Previous work has implicated the anticodon of tRNA(Lys) as a specificity element and a cluster of amino acid residues at the carboxy-proximal half of PrrC in its recognition. We further examined these assumptions by assaying unmodified and hypomodified derivatives of tRNA(Lys) as substrates of wild-type and mutant alleles of PrrC. The data show, first, that the anticodon sequence and wobble base modifications of tRNA(Lys) play major roles in the interaction with anticodon nuclease. Secondly, a specific contact between the substrate recognition site of PrrC and the tRNA(Lys) wobble base is revealed by PrrC missense mutations that suppress the inhibitory effects of wobble base modification mutations. Thirdly, the data distinguish between the anticodon recognition mechanisms of PrrC and lysyl-tRNA synthetase.