Lysyl-tRNA synthetase gene of Campylobacter jejuni

The crystal structures of the α-subunit of the α(2)β (2) tetrameric Glycyl-tRNA synthetase

Aminoacyl-tRNA synthetases (AARSs) are ligases (EC.6.1.1.-) that catalyze the acylation of amino acids to their cognate tRNAs in the process of translating genetic information from mRNA to protein. Their amino acid and tRNA specificity are crucial for correctly translating the genetic code. Glycine is the smallest amino acid and the glycyl-tRNA synthetase (GlyRS) belongs to Class II AARSs. The enzyme is unusual because it can assume different quaternary structures. In eukaryotes, archaebacteria and some bacteria, it forms an α(2) homodimer. In some bacteria, GlyRS is an α(2)β(2) heterotetramer and shows a distant similarity to α(2) GlyRSs. The human pathogen eubacterium Campylobacter jejuni GlyRS (CjGlyRS) is an α(2)β(2) heterotetramer and is similar to Escherichia coli GlyRS; both are members of Class IIc AARSs. The two-step aminoacylation reaction of tetrameric GlyRSs requires the involvement of both α- and β-subunits. At present, the structure of the GlyRS α(2)β(2) class and the details of the enzymatic mechanism of this enzyme remain unknown. Here we report the crystal structures of the catalytic α-subunit of CjGlyRS and its complexes with ATP, and ATP and glycine. These structures provide detailed information on substrate binding and show evidence for a proposed mechanism for amino acid activation and the formation of the glycyl-adenylate intermediate for Class II AARSs.

RpoD promoters in Campylobacter jejuni exhibit a strong periodic signal instead of a -35 box

We have used a hidden Markov model (HMM) to identify the consensus sequence of the RpoD promoters in the genome of Campylobacter jejuni. The identified promoter consensus sequence is unusual compared to other bacteria, in that the region upstream of the TATA-box does not contain a conserved -35 region, but shows a very strong periodic variation in the AT-content and semi-conserved T-stretches, with a period of 10-11 nucleotides. The TATA-box is in some, but not all cases, preceded by a TGx, similar to an extended -10 promoter. We predicted a total of 764 presumed RpoD promoters in the C.jejuni genome, of which 654 were located upstream of annotated genes. A similar promoter was identified in Helicobacter pylori, a close phylogenetic relative of Campylobacter, but not in Escherichia coli, Vibrio cholerae, or six other Proteobacterial genomes, or in Staphylococcus aureus. We used upstream regions of high confidence genes as training data (n=529, for the C.jejuni genome). We found it necessary to limit the training set to genes that are preceded by an intergenic region of >100bp or by a gene oriented in the opposite direction to be able to identify a conserved sequence motif, and ended up with a training set of 175 genes. This leads to the conclusion that the remaining genes (354) are more rarely preceded by a (RpoD) promoter, and consequently that operon structure may be more widespread in C.jejuni than has been assumed by others. Structural predictions of the regions upstream of the TATA-box indicates a region of highly curved DNA, and we assume that this facilitates the wrapping of the DNA around the RNA polymerase holoenzyme, and offsets the absence of a conserved -35 binding motif.

Expression of the flgFG operon of Campylobacter jejuni in Escherichia coli yields an extra fusion protein

Two Campylobacter jejuni genes with homology to the Escherichia coli flgF and flgG genes encoding two of the basal body rod proteins were isolated, and the nucleotide sequence was determined and analyzed. These two C. jejuni genes were shown, by Northern hybridization analysis, to function as a single operon (flgFG). Two transcriptional start sites were detected upstream of flgF, corresponding to the two RNA transcripts detected in the Northern blot. Western blot immunoassays using anti-FlgF and anti-FlgG antibodies demonstrated the synthesis of FlgF and FlgG proteins in C. jejuni and in Escherichia coli containing the C. jejuni flgF and flgG genes. Maxicell analysis and Western immunoblots using anti-FlgF antibodies to probe flgFG-encoded proteins in E. coli revealed the presence of a protein with a molecular mass of approximately the combined mass of the FlgF and FlgG proteins. Anti-FlgF antibodies detected in C. jejuni cell extracts the native FlgF protein and also a higher-molecular-weight protein that is likely encoded by the flgF and part of the flgG sequences.

Iron-responsive gene regulation in a campylobacter jejuni fur mutant

The expression of iron-regulated systems in gram-negative bacteria is generally controlled by the Fur protein, which represses the transcription of iron-regulated promoters by using Fe2+ as a cofactor. Mutational analysis of the Campylobacter jejuni fur gene was carried out by generation of a set of mutant copies of fur which had a kanamycin or chloramphenicol resistance gene introduced into the regions encoding the N and C termini of the Fur protein. The mutated genes were recombined into the C. jejuni NCTC 11168 chromosome, and putative mutants were confirmed by Southern hybridization. C. jejuni mutants were obtained only when the resistance genes were transcribed in the same orientation as the fur gene. The C. jejuni fur mutant grew slower than the parental strain. Comparison of protein profiles of fractionated C. jejuni cells grown in low- or high-iron medium indicated derepressed expression of three iron-regulated outer membrane proteins with molecular masses of 70, 75, and 80 kDa. Characterization by N-terminal amino acid sequencing showed the 75-kDa protein to be identical to CfrA, a Campylobacter coli siderophore receptor homologue, whereas the 70-kDa protein was identified as a new siderophore receptor homologue. Periplasmic fractions contained four derepressed proteins with molecular masses of 19, 29, 32, and 36 kDa. The 19-kDa protein has been previously identified, but its function is unknown. The cytoplasmic fraction contained two iron-repressed and two iron-induced proteins with molecular masses of 26, 55, 31, and 40 kDa, respectively. The two iron-repressed proteins have been previously identified as the oxidative stress defense proteins catalase (KatA) and alkyl hydroperoxide reductase (AhpC). AhpC and KatA were still iron regulated in the fur mutant, suggesting the presence of Fur-independent iron regulation. Further analysis of the C. jejuni iron and Fur regulons by using two-dimensional gel electrophoresis demonstrated the total number of iron- and Fur-regulated proteins to be lower than for other bacterial pathogens.

Campylobacter upsaliensis: waiting in the wings

Despite strong epidemiological evidence supporting an important role for Campylobacter upsaliensis as a human enteropathogen, it remains relatively unknown in the realm of clinical microbiology. Clinical studies indicate that infection with this organism usually is associated with benign self-limiting diarrhea. However, more serious illnesses, including spontaneous abortion and hemolytic-uremic syndrome, recently have been associated with human infections. Understanding of the virulence properties and molecular biology of C. upsaliensis is beginning to evolve. There is now a pressing need for controlled, prospective epidemiologic studies in addition to further in-depth investigation of the pathogenesis of this enteric campylobacter to more precisely define its role in human disease. Furthermore, since C. upsaliensis is sensitive to the antibiotics routinely used in Campylobacter selective media, widespread appreciation of the importance of this organism will rely on the development of widely applicable, effective techniques for its isolation.

Identification of Campylobacter jejuni promoter sequences

A promoterless lacZ shuttle vector, which allowed screening of promoters by beta-galactosidase activity in Campylobacter jejuni and Escherichia coli, was developed. Chromosomal DNA fragments from C. jejuni were cloned into this vector; 125 of 1,824 clones displayed promoter activity in C. jejuni. Eleven clones with strong promoter activity in C. jejuni were further characterized. Their nucleotide sequences were determined, and the transcriptional start sites of the putative promoters in C. jejuni were determined by primer extension. Only 6 of these 11 promoters were functional in E. coli. The 11 newly characterized and 10 previously characterized C. jejuni promoters were used to establish a consensus sequence for C. jejuni promoters. The 21 promoters were found to be very similar. They contain three conserved regions, located approximately 10, 16, and 35 bp upstream of the transcriptional start point. The -10 region resembles that of a typical sigma70 E. coli promoter, but the -35 region is completely different. In addition a -16 region typical for gram-positive bacteria was identified.

Human lysyl-tRNA synthetase accepts nucleotide 73 variants and rescues Escherichia coli double-defective mutant

The nucleotide 73 (N73) "discriminator" base in the acceptor stem is a key element for efficient and specific aminoacylation of tRNAs and of microhelix substrates derived from tRNA acceptor stems. This nucleotide was possibly one of the first to be used for differentiating among groups of early RNA substrates by tRNA synthetases. In contrast to many other synthetases, we report here that the class II human lysyl-tRNA synthetase is relatively insensitive to the nature of N73. We cloned, sequenced, and expressed the enzyme, which is a close homologue of the class II yeast aspartyl-tRNA synthetase whose co-crystal structure (with tRNAAsp) is known. The latter enzyme has a strong requirement for G73, which interacts with 4 of the 14 residues within the "motif 2" loop of the enzyme. Even though eukaryotic lysine tRNAs also encode G73, the motif 2 loop sequence of lysyl-tRNA synthetase differs at multiple positions from that of the aspartate enzyme. Indeed, the recombinant human lysine enzyme shows little preference for G, and even charges human tRNA transcripts encoding the A73 found in E. coli lysine tRNAs. Moreover, while the lysine enzyme is the only one in E. coli to be encoded by two separate genes, a double mutant that disables both genes is complemented by a cDNA expressing the human protein. Thus, the sequence of the loop of motif 2 of human lysyl-tRNA synthetase specifies a structural variation that accommodates nucleotide degeneracy at position 73. This sequence might be used as a starting point for obtaining highly specific interactions with any given N73 by simple amino acid replacements.

A root-specific iron-regulated gene of tomato encodes a lysyl-tRNA-synthetase-like protein

The tomato mutant chloronerva exhibits a defect in iron-uptake regulation. Despite high apoplastic and symplastic iron concentrations, the mutant shows characteristic symptoms of iron deficiency. Using a subtractive-hybridisation approach, we have screened for cDNA clones specific for genes with altered expression in wild-type versus mutant root tissue. Based on this clone collection, we have isolated and characterised a 2075-bp full-length cDNA encoding a lysyl-tRNA-synthetase-like protein. The corresponding gene is localised as a single copy on chromosome 10. Its expression is strongly induced by changes in the iron status of the plant. This iron-dependent regulation is superimposed upon a strict root specificity of gene expression. Possible functions of the gene product other than in protein biosynthesis will be discussed.

Characterization of Campylobacter upsaliensis fur and its localization in a highly conserved region of the Campylobacter genome

Despite increasing recognition of the importance of Campylobacter upsaliensis in human disease little is known about either the virulence properties or genetics of this enteric pathogen. The complete coding sequence of a C. upsaliensis gene has yet to be published. We have cloned and sequenced the complete iron-uptake regulatory (fur) gene from the type strain of this species. The C. upsaliensis fur homolog was isolated from a genomic library of C. upsaliensis ATCC 43954 constructed in phage lambdaGEM-11. The open reading frame identified encodes a polypeptide consisting of 156 amino acids. The 5'-flanking region of the C. upsaliensis fur gene contains 3 putative Fur-binding sequences and two catabolite activator-binding sequences indicating the potential for autogenous and cAMP-mediated regulation, respectively. Primer extension analysis identified a single transcription start site 262 nt upstream from the AUG initiation codon. Sequence analysis indicates that the Fur protein of C. upsaliensis is highly homologous (87% amino acid identity) to Campylobacter jejuni Fur. Furthermore, the arrangement of the lysS and glyA genes downstream of fur is precisely conserved in both C. upsaliensis ATCC 43954 and C. jejuni TGH9011. Using the polymerase chain reaction close linkage of fur with lysS and glyA was also observed among multiple isolates of C. upsaliensis, C. jejuni and C. coli suggesting a possible functional relevance for this conserved genetic arrangement in campylobacteria.

The aroA gene of Campylobacter jejuni

The gene for 5-enolpyruvylshikimate-3-phosphate (EPSP) synthase (aroA) cloned from Campylobacter jejuni (Cj) strain 81116 was identified by complementation of an Escherichia coli (Ec) auxotrophic aroA mutant. The Cj aroA gene has been sequenced. It encodes an enzyme of 428 amino acids (aa), that is homologous to other bacterial EPSP synthases, especially that of Bacillus subtilis with which it has a 39% aa identity. The transcriptional start point was mapped. It is present in an upstream open reading frame (ORF) that has a strong homology to the gene encoding phenylalanine tRNA synthetase (pheS). Downstream from aroA another ORF is present which is homologous to the lytB gene of Ec. The stop codon of the aroA gene overlaps the start codon of lytB.

Expanded genomic map of Campylobacter jejuni UA580 and localization of 23S ribosomal rRNA genes by I-CeuI restriction endonuclease digestion

The genomic map of Campylobacter jejuni UA580 was expanded and more precisely constructed using I-CeuI, Sal/I and SmaI restriction endonucleases in conjunction with pulsed-field gel electrophoresis (PFGE). The presence of three fragments after digestion with I-CeuI confirmed the presence of three copies of the 23S ribosomal rRNA (rrl) gene. The genome size of Campylobacter jejuni UA580 was determined to be 1725 +/- 5.9 kbp by I-CeuI with fragment sizes of 1053 +/- 4.4, 361 +/- 2.7 and 311 +/- 3.6 kbp. Analysis of a PCR product from C. jejuni UA580 23S rRNA gene showed that I-CeuI did cut within the gene. The precise locations of the three genes were determined using I-CeuI with two copies of the 23S and 5S rRNA genes located separately from the 16S rRNA gene whereas the third copy of the 23S and 5S rRNA genes had a closer linkage to a 16S rRNA gene copy. Homologous gene probes were used to map additional genes and allowed the realignment of a few previously mapped genes on the chromosome. Other strains of C. jejuni were also cut into three fragments with I-CeuI, which generated variable PFGE patterns.

Identification of Campylobacter jejuni and C. coli using the rpoB gene and a cryptic DNA fragment from C. jejuni

Campylobacter jejuni (Cj) and C. coli (Cc) clinical isolates, obtained from three different sources, were characterized using two Cj DNA probes, CJ01 and CJ02. These probes were selected at random by virtue of their stability in Escherichia coli (Ec). CJ01 hybridized specifically with DNA from Cj reference strains, but not with DNA from Cc, C. lari (Cl) nor C. fetus (Cf) reference strains. Using clinical isolates characterized by genome-genome hybridization and biotype, CJ01 hybridized with DNA derived from all Cj strains. However, DNA from four out of ten Cc strains, from three different sources, also hybridized with CJ01, suggestive of this region being heterogeneous between clinical isolates of both species. The nucleotide sequence analysis of CJ01 reveals two incomplete open reading frames (ORFs) that did not show significant homology with any other known sequences. CJ02 hybridized specifically with DNA from Cj and Cc reference strains, but not with DNA from Cl and Cf reference strains. The specificity and sensitivity were maintained upon hybridization with DNA from 31 clinical isolates. CJ02 has an uninterrupted ORF whose deduced amino-acid sequence showed extensive homology with the central region of the Ec and Salmonella typhimurium (St) RNA polymerase beta subunits (52 and 66% similarity, respectively). The most conserved segments correspond to putative functional domains.

Cloning and transcription regulation of the ferric uptake regulatory gene of Campylobacter jejuni TGH9011

A Campylobacter jejuni (Cj) TGH9011 (ATCC 43431) gene homologous to the Escherichia coli ferric uptake regulatory gene (fur) has been cloned and characterized. Cj fur encodes a polypeptide consisting of 157 amino acids (aa) (18.1 kDa). The 5'-flanking region of the Cj fur gene contains two putative catabolite activator protein (CAP)-binding sequences and four Fur boxes or Fur-binding sequences (FBS), implicating cAMP and autogenous regulation respectively. A major and a minor transcription start point (tsp) were active in Fe(+) and Fe(-) media and three tsp were suppressed in Fe(+) condition. The major transcript has an unusually short leader sequence. The homology of the Cj Fur to other Proteobacteria Fur proteins is moderately low with identity ranging from 36.3% for Yersinia pestis to 31.8% for Legionella pneumophila. Multiple alignments of the Fur sequences identified three conserved motifs, I [aGLKvTlpR1KiL], II [eiGlATvYR] and III [HHDHlvCldcGeviEf] (uppercase aa are identical in 12 or all 13 Fur sequences and lowercase aa are identical in six or more sequences). A truncated TGFH9011 Fur missing 18 aa of the N terminus but retaining all three conserved motifs was shown to bind all four FBS sequences. The binding and transcription studies support autoregulation of fur expression in Cj.

Lysyl-tRNA synthetase

Lysyl-tRNA synthetase catalyses the formation of lysyl-transfer RNA, Lys-tRNA(Lys), which then is ready to insert lysine into proteins. Lysine is important for proteins since it is one of only two proteinogenic amino acids carrying an alkaline functional group. Seven genes of lysyl-tRNA synthetases have been localized in five organisms, and the nucleotide and the amino acid sequences have been established. The lysyl-tRNA synthetase molecules are of average chain lengths among the aminoacyl-tRNA synthetases, which range from about 300 to 1100 amino acids. Lysyl-tRNA synthetases act as dimers; in eukaryotes they can be localized in multienzyme complexes and can contain carbohydrates or lipids. Lysine tRNA is recognized by lysyl-tRNA synthetase via standard identity elements, namely anticodon region and acceptor stem. The aminoacylation follows the standard two-step mechanism. However the accuracy of selecting lysine against the other amino acids is less than average. The first threedimensional structure of a lysyl-tRNA synthetase worked out very recently, using the enzyme from the Escherichia coli lysU gene which binds one molecule of lysine, is similar to those of other class II synthetases. However, none of the reaction steps catalyzed by the enzyme is clarified to atomic resolution. Thus surprising findings might be possible. Lysyl-tRNA synthetase and its precursors as well as its substrates and products are targets and starting points of many regulation circuits, e.g. in multienzyme complex formation and function, dinucleoside polyphosphate synthesis, heat shock regulation, activation or deactivation by phosphorylation/dephosphorylation, inhibition by amino acid analogs, and generation of antibodies against lysyl-tRNA synthetase. None of these pathways is clarified completely.

Expression and characterization of Campylobacter jejuni benzoylglycine amidohydrolase (Hippuricase) gene in Escherichia coli

The basis for the difference between Campylobacter jejuni and Campylobacter coli is the presence and expression of the N-benzoylglycine amidohydrolase (hippuricase) gene only in C. jejuni. A pBR322 recombinant clone (pHIP-O) of C. jejuni TGH9011 capable of converting hippuric acid into benzoic acid and glycine, the hallmark of hippuricase activity, was characterized and sequenced. The hippuricase gene (hipO) was identified by use of deletion subclones and insertional inactivation. The transcription start point of the hippuricase gene was determined by primer extension analysis. A hippuricase-specific gene fragment was used to determine the presence of the gene in Campylobacter species. Maxicell analysis of recombinant plasmid pHIP-O by sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated the production of a 42-kDa protein corresponding to the HipO gene product, in excellent agreement with the predicted molecular mass of the protein.

Iron-responsive genetic regulation in Campylobacter jejuni: cloning and characterization of a fur homolog

The Fur protein of Escherichia coli represses transcription from Fur-responsive genes in an iron-dependent manner. We have demonstrated a Fur-like iron-responsive genetic regulatory activity operating in Campylobacter jejuni by using a chloramphenicol acetyl transferase reporter gene separated from its promoter by a synthetic Fur-responsive operator. A fur-like gene has been cloned from C. jejuni by partial functional complementation of an E. coli fur mutation. Sequence analysis has shown that, at the amino acid level, the C. jejuni Fur protein is 35% identical with its E. coli counterpart.

Genetic organization of the region upstream from the Campylobacter jejuni flagellar gene flhA

Campylobacter jejuni (Cj) is a Gram-bacterium that causes a diarrheal disease in humans. A Cj homolog of the LcrD/FlhA family of proteins was recently described [Miller et al., Infect. Immun. 61 (1993) 2930-2936]. This family includes proteins that are involved in flagellar biogenesis, such as the Cj FlhA protein, but also includes proteins found in invasive pathogens, such as the Yersinia pestis LcrD protein, that play a role in the regulation and/or secretion of virulence-related proteins. Hybridization studies indicated that both the flhA gene and upstream DNA are present in several bacterial species closely related to Cj, including C. fetus, C. lari, C. upsaliensis and C. hyointestinalis. The presence of a second flhA/lcrD homolog was not detected in Cj, indicating that a a separate homolog involved in secretion of virulence proteins may not be present. The 4-kb region immediately upstream from Cj flhA was analyzed. Three open reading frames (ORFs) were found: a 408-nucleotide (nt) gene encoding a homolog of proteins present in Escherichia coli and Desulfovibrio vulgaris, but of unknown function, a 266-nt rpsO gene and a 2823-nt gene encoding a homolog of the Bacillus subtilis SpoIIIE protein. The Cj SpoIIIE homolog had 53% similar or identical amino acids when compared to the B. subtilis protein, and like the B. subtilis protein contained a nt-binding domain and potential transmembrane (TM) regions. All three ORFs were expressed in E. coli minicells, apparently from their own promoters.(ABSTRACT TRUNCATED AT 250 WORDS)

Properties of the lysyl-tRNA synthetase gene and product from the extreme thermophile Thermus thermophilus

A DNA region carrying lysS, the gene encoding the lysyl-tRNA synthetase, was cloned from the extreme thermophile prokaryote Thermus thermophilus VK-1 and sequenced. The analysis indicated an open reading frame encoding a protein of 492 amino acids. This putative protein has significant homologies to previously sequenced lysyl-tRNA synthetases and displays the three motifs characteristic of class II aminoacyl-tRNA synthetases. The T. thermophilus lysS gene was overexpressed in Escherichia coli by placing it downstream of the E. coli beta-galactosidase gene promoter on plasmid pBluescript and by changing the ribosome-binding site. The overproduced protein was purified by heat treatment of the crude extract followed by a single anion-exchange chromatography step. The protein obtained is remarkably thermostable, retaining nearly 60% of its initial tRNA aminoacylation activity after 5 h of incubation at 93 degrees C. Finally, lethal disruption of the lysRS genes of E. coli could not be compensated for by the addition in trans of the T. thermophilus lysS gene despite the fact that this gene was overexpressed and that its product specifically aminoacylates E. coli tRNA(Lys) in vitro.

Cloning, characterization, and nucleotide sequence analysis of the argH gene from Campylobacter jejuni TGH9011 encoding argininosuccinate lyase

The complete structural gene for argininosuccinate lyase (argH) from Campylobacter jejuni TGH9011 has been cloned into Escherichia coli by complementation of an E. coli argH auxotrophic mutant. The gene has been subcloned for sequencing on a 4.1-kb DNA segment and localized by the complementing activity of deletion mutants. The complete DNA sequence of the C. jejuni argH gene was determined. The transcription start point for argH mRNA was determined by primer extension analysis and found to be within the coding sequence of the upstream gene, identified as the phosphoenolpyruvate carboxykinase gene (ppc). The argininosuccinate lyase and the phosphoenolpyruvate carboxykinase reading frames overlap by one base, the second example of this phenomenon in C. jejuni chromosomal genes. The enzyme has a deduced subunit molecular weight of 51,831. Recombinant plasmids containing the argH gene generate a 56-kDa protein and a 43-kDa protein in E. coli maxicells. An alternate translation initiation producing a polypeptide with a deduced molecular mass of 42 kDa may account for the smaller protein observed in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The C. jejuni argH gene shows nucleotide homology to both yeast and human argininosuccinate lyase genes, and conserved amino acid domains are evident between the corresponding proteins.

Characterization of a Mycoplasma hominis gene encoding lysyl-tRNA synthetase (LysRS)

The gene encoding lysyl-tRNA synthetase (lysS) in Mycoplasma hominis was cloned and sequenced. The gene was found to have an open reading frame of 1466 bp encoding a polypeptide with a predicted molecular mass of 57 kDa. The amino acid sequence showed 44.3% and 43.7% identity to the Escherichia coli lysyl-tRNA synthetases, encoded by lysS and lysU. Only one lysyl-tRNA synthetase encoding gene was found in M. hominis. The G + C content of the gene was found to be 28.6%, which is significantly lower than in other prokaryotes. The gene was located 4 kb upstream of the M. hominis PG21 rRNA B operon.

Development and characterization of recA mutants of Campylobacter jejuni for inclusion in attenuated vaccines

Isogenic recA mutants of Campylobacter jejuni have been constructed for evaluation of their usefulness in attenuated vaccines against this major worldwide cause of diarrhea. The recA+ gene of C. jejuni 81-176 was cloned by using degenerate primers to conserved regions of other RecA proteins in a PCR. The C. jejuni recA+ gene encodes a predicted protein with an M(r) of 37,012 with high sequence similarity to other RecA proteins. The termination codon of the recA+ gene overlaps with the initiation codon of another open reading frame which encodes a predicted protein which has > 50% identity with the N terminus of the Escherichia coli enolase protein. A kanamycin resistance gene was inserted into the cloned recA+ gene in E. coli and returned to C. jejuni VC83 by natural transformation, resulting in allelic replacement of the wild-type recA gene. The resulting VC83 recA mutant displayed increased sensitivity to UV light and a defect in generalized recombination as determined by natural transformation frequencies. The mutated recA gene was amplified from VC83 recA by PCR, and the product was used to transfer the mutation by natural transformation into C. jejuni 81-176 and 81-116, resulting in isogenic recA mutants with phenotypes similar to VC83 recA. After oral feeding, strain 81-176 recA colonized rabbits at levels comparable to wild-type 81-176 and was capable of eliciting the same degree of protection as wild-type 81-176 against subsequent homologous challenge in the RITARD (removable intestinal tie adult rabbit diarrhea) model.

A gene encoding arginyl-tRNA synthetase is located in the upstream region of the lysA gene in Brevibacterium lactofermentum: regulation of argS-lysA cluster expression by arginine

The Brevibacterium lactofermentum argS gene, which encodes an arginyl-tRNA synthetase, was identified in the upstream region of the lysA gene. The cloned gene was sequenced; it encodes a 550-amino-acid protein with an M(r) of 59,797. The deduced amino acid sequence showed 28% identical and 49% similar residues when compared with the sequence of the Escherichia coli arginyl-tRNA synthetase. The B. lactofermentum enzyme showed the highly conserved motifs of class I aminoacyl-tRNA synthetases. Expression of the argS gene in B. lactofermentum and E. coli resulted in an increase in aminoacyl-tRNA synthetase activity, correlated with the presence in sodium dodecyl sulfate-polyacrylamide gels of a clear protein band that corresponds to this enzyme. One single transcript of about 3,000 nucleotides and corresponding to the B. lactofermentum argS-lysA operon was identified. The transcription of these genes is repressed by lysine and induced by arginine, showing an interesting pattern of biosynthetic interlock between the pathways of both amino acids in corynebacteria.

Fine mapping of the three rRNA operons on the updated genomic map of Campylobacter jejuni TGH9011 (ATCC 43431)

The three rRNA gene loci of Campylobacter jejuni TGH9011 (ATCC 43431) were cloned. All three rRNA operons were shown to possess a contiguous 16S-23S structure and contain intercistronic tRNA(Ala) and tRNA(Ile). The three RNA operons and additional 14 genetic markers were mapped in the updated genomic map of C. jejuni TGH9011, which now has a total of 24 genetic markers.

Cloning and characterization of the gamma-glutamyl phosphate reductase gene of Campylobacter jejuni

The gamma-glutamyl phosphate reductase gene, proA, of Campylobacter jejuni was isolated from a recombinant pBR322 clone. A HindIII fragment of the insert containing the gene was subcloned into pUC19 and sequenced in both orientations. The deduced amino acid sequence of gamma-glutamyl phosphate reductase (EC 1.2.1.41) of C. jejuni exhibits 36.4% identity to that of Escherichia coli and 36.0% identity to Serratia marcescens. Two highly conserved regions in the amino acid sequence were identified from the alignment of the three available gamma-glutamyl phosphate reductase gene sequences. The gene was expressed from its own promoter and the transcription start site was mapped. The proline biosynthetic genes of C. jejuni are not located tandemly and thus differ in this respect from those of E. coli and S. marcescens, where gamma-glutamyl phosphate reductase and gamma-glutamyl kinase (proB) are located in a single operon.

Physical map of Campylobacter jejuni TGH9011 and localization of 10 genetic markers by use of pulsed-field gel electrophoresis

The physical map of Campylobacter jejuni TGH9011 (ATCC 43430) was constructed by mapping the three restriction enzyme sites SacII (CCGCGG), SalI (GTCGAC), and SmaI (CCCGGG) on the genome of C. jejuni by using pulsed-field gel electrophoresis and Southern hybridization. A total of 25 restriction enzyme sites were mapped onto the C. jejuni chromosome. The size of the genome was reevaluated and was shown to be 1,812.5 kb. Ten C. jejuni genetic markers that have been isolated in our laboratory were mapped to specific restriction enzyme fragments. Furthermore, we have accurately mapped one of the three rRNA operons (rrnA) and have demonstrated a separation of the 16S and 23S rRNA-encoding sequences in one of the rRNA operons.