Phagocytosis of bacteria by olfactory ensheathing cells and Schwann cells.

Opportunistic bacterial infections of the nasal cavity could potentially lead to infection of the brain if the olfactory or trigeminal nerves are colonised. The olfactory nerve may be a more susceptible route because primary olfactory neurons are in direct contact with the external environment. Peripheral glia are known to be able to phagocytose some species of bacteria and may therefore provide a defence mechanism against bacterial infection. As the nasal cavity is frequently exposed to bacterial infections, we hypothesised that the olfactory and trigeminal nerves within the nasal cavity could be subjected to bacterial colonisation and that the olfactory ensheathing cells and Schwann cells may be involved in responding to the bacterial invasion. We have examined the ability of mouse OECs and Schwann cells from the trigeminal nerve and dorsal root ganglia to phagocytose Escherichia coli and Burkholderia thailandensis in vitro. We found that all three sources of glia were equally able to phagocytose E. coli with 75-85% of glia having phagocytosed bacteria within 24h. We also show that human OECs phagocytosed E. coli. In contrast, the mouse OECs and Schwann cells had little capacity to phagocytose B. thailandensis. Thus subtypes of peripheral glia have similar capacities for phagocytosis of bacteria but show selective capacity for the two different species of bacteria that were examined. These results have implications for the understanding of the mechanisms of bacterial infections as well as for the use of glia for neural repair therapies.

Identification of a novel two-partner secretion system from Burkholderia pseudomallei.

Two adjacent genes, bpaA and bpaB, whose products display significant similarity to a number of two-partner secretion (TPS) systems have been identified in Burkholderia pseudomallei strain 08, but are absent from the closely related avirulent species B. thailandensis. They possess a number of sequence features characteristic of TPS systems, including the presence of an NPNGI motif in a region of BpaA which strongly resembles a TPS secretion domain. BpaA is a very large protein (approximately 530 kDa) and contains three repeats, each 600-800-amino acids long. Putative membrane-spanning regions in BpaB were identified through alignment with TpsB family members, and this also revealed an N-terminal extension not found in other TpsB proteins. The bpaA gene was found to be absent from the majority of B. pseudomallei strains. It appears that bpaAB are located within a putative genomic island that is inserted in close proximity to a methionine tRNA(CAT)-encoding gene. Expression of BpaA was undetectable in cells grown in laboratory media. However, owing to the similarity of BpaA to known adhesin molecules, a potential role of BpaA in virulence was investigated in cell culture and in an animal model, but no evidence for such a role was found in these test systems.

The Escherichia coli orthologue of the Salmonella ushB gene (ushB(c)) produces neither UDP-sugar hydrolase activity nor detectable protein, but has an identical sequence to that of Escherichia coli cdh.

Salmonella ushB, which encodes a membrane-bound UDP-sugar hydrolase, has an Escherichia coli orthologue (ushB(c)) which does not detectably produce this activity. In this report, we show that ushB(c) does not produce any detectable protein either, despite being transcribed normally. Remarkably, ushB(c) is shown to have 100% sequence identity with E. coli cdh, previously characterised as encoding an active CDP-diglyceride hydrolase, an apparent contradiction with implications regarding enzyme evolution. We suggest that a useful gene designation is cdh (ushB(c)) rather than either ushB(c) or cdh, alone.

A strain of Pseudomonas fluorescens with two lipase-encoding genes, one of which possibly encodes cytoplasmic lipolytic activity.

AIMS: A lipase-encoding gene (lipA) from a psychrotrophic strain of Pseudomonas fluorescens C9 has previously been characterized. It was also shown that when this gene was insertionally-inactivated, lipase activity was retained, suggesting that a second lipase may be present in this strain. The aim of this study was to determine whether this was the case. METHODS AND RESULTS: Using molecular cloning, chromosomal mutagenesis and enzymatic analysis, the presence of a second lipase-encoding gene (lipB) has been confirmed. The molecular weights of the putative products of lipA and lipB are 33 and 64.5 kDa, respectively, and their sequences are quite dissimilar (< 10% sequence identity). The lipB gene encodes a secreted lipase and is solely responsible for the 'lipolytic phenotype' of Ps. fluorescens C9. Expression of the lipA gene can be detected when expressed using an expression vector, but activity was only detected intracellularly in Ps. fluorescens C9, and not in the culture medium. CONCLUSION: Pseudomonas fluorescens C9 contains two dissimilar lipases. One (LipB) is secreted and responsible for the lipolytic phenotype; the evidence suggests that the other (LipA) could be intracellular, but it could be secreted and not detectable. SIGNIFICANCE AND IMPACT OF THE STUDY: Bacteria may contain more than one lipase activity. Ascribing phenotypes to particular enzymes therefore requires mutational analysis. The notion of an intracellular lipase activity is novel, and, if further substantiated, begs the question as to its normal substrate and physiological role.

The role of the intracellular inhibitor of periplasmic UDP-sugar hydrolase (5'-nucleotidase) in Escherichia coli: cytoplasmic localisation of 5'-nucleotidase is conditionally lethal.

E. coli UshA, a bifunctional enzyme with UDP-sugar hydrolase and 5'-nucleotidase activities, is secreted to the periplasm but has a specific protein inhibitor located in the cytoplasm. It has been previously suggested that some 5'-nucleotidase, or a folded domain of this enzyme, may be active in the cytoplasm prior to export. If true, the intracellular inhibitor may have a role in protecting the cell from the likely deleterious effects of any intracellular UshA activity. Using deletion mutagenesis to remove the UshA signal peptide, we have shown that the resulting UshA derivative is an active cytoplasmic 5'-nucleotidase, and causes conditional lethality. Our results support the hypothesis that the physiological role of the UshA inhibitor is to protect the intracellular nucleotide pool from any cytoplasmic 5'-nucleotidase activity.

Identification of new transposable genetic elements in Burkholderia pseudomallei using subtractive hybridisation.

A subtraction library of Burkholderia pseudomallei was constructed by subtractive hybridisation of B. pseudomallei genomic DNA with Burkholderia thailandensis genomic DNA. Two clones were found to have significant sequence similarity to insertion sequences which have previously not been found in B. pseudomallei (designated ISA and ISB); and two clones showed sequence similarity to different regions of Burkholderia cepacia IS407 that has recently been detected in B. pseudomallei. The former, though possibly non-functional, represents new transposable genetic elements of B. pseudomallei. All three sequences were found to be present in multi-copy in the genomes of a number of B. pseudomallei strains and in B. thailandensis, which are the first transposable elements identified in this species.

Evolution of class I alcohol dehydrogenase genes in catarrhine primates: gene conversion, substitution rates, and gene regulation.

The three class I alcohol dehydrogenases (ADHs) in humans comprise homo- and heterodimers of three subunits (alpha, beta, and gamma) with greater than 90% sequence identity. These are encoded by distinct genes (ADH1, ADH2, and ADH3, respectively) and are all expressed in the liver. In baboons, only the beta ADH subunit is expressed in liver. A second class I ADH is expressed in the kidney; we isolated, cloned, and sequenced the cDNA corresponding to this ADH and conclude that it is of the gamma ADH lineage. We also amplified and sequenced the 5' noncoding regions of all three class I baboon ADH genes and the rhesus monkey ADH1 gene and compared their nucleotide sequences with the corresponding human sequences. There is clear evidence that the evolution of these genes has been reticulate. At least three gene conversion events, affecting the coding and 3' noncoding regions of the genes, are inferred from compatibility and partition matrices and phylogenetic analysis of the sequences. Our estimation of the evolutionary history of these genes provides a framework for the investigation of relative substitution rates and functional variation among the sequences. Relative-rate tests, designed to account for the reticulate evolution of these genes, indicate no difference in substitution rate either between genes encoding different subunits or between human and Old World monkey lineages. The human and baboon gamma ADH sequences do not show clear differences at functionally important sites within the coding region, but they do differ at a number of sites in regions previously proposed to be regulatory sites for transcriptional control. This variation may explain the different patterns of gene expression in humans and baboons.

Amylase and 16S rRNA genes from a hyperthermophilic archaebacterium.

A hyperthermophilic and amylolytic prokaryote, designated Rt3, was isolated from a thermal spring near Rotorua, New Zealand. The 16S rRNA gene of Rt3 was cloned and sequenced with the aim of determining its phylogenetic affiliations. The phylogenetic analysis of this sequence, which included a selection of archaebacterial and eubacterial 16S rRNA sequences, indicates that Rt3 most likely belongs to the archaebacterial order Thermococcales. An amylase gene (amyA) from Rt3, encoding a highly thermostable amylase activity, was cloned and its DNA sequence determined. Transcriptional signals typical of archaebacteria were evident in this sequence. The sequence is homologous to a broad range of enzymes from the AMY superfamily and contains a typical N-terminal signal peptide. Phylogenetic analysis and comparison of structural features with other AMY superfamily enzymes reveals that, firstly, the closest homologues of the Rt3 amylase are members of the Bacillus and Plant alpha-amylase groups; and secondly, that the Rt3 amylase is closely related to only one other currently known archaebacterial enzyme, i.e. an (AMY superfamily) alpha-amylase from Natronococcus.

The diversity of lipases from psychrotrophic strains of Pseudomonas: a novel lipase from a highly lipolytic strain of Pseudomonas fluorescens.

Strains of Pseudomonas fluorescens and Ps. fragi are the predominant psychrotrophs found in raw milk and may cause spoilage due to the secretion of hydrolytic enzymes such as lipase and protease. The diversity of lipases has been examined in Pseudomonas isolates from raw milk which represent different taxonomic groups (phenons). Significant diversity was found using both DNA hybridization and immunoblotting techniques, which has implications for the development of a diagnostic test. The lipase-encoding gene (lipA) was cloned from one strain, C9, of Ps. fluorescens biovar V. In contrast to previously reported lipase sequences from Ps. fluorescens, the gene encodes a lipase of M(r) 33 kDa. Alignment of all known Pseudomonas and Burkholderia lipase amino acid sequences indicates the existence of two major groups, one of M(r) approximately 30 kDa comprising sequences from Ps. fragi, Ps. aeruginosa, Ps. fluorescens C9 and Burkholderia, and one of approximately 50 kDa comprising Ps. fluorescens lipases. The lipase from C9 does not contain a signal peptide and is presumed to be secreted via a signal peptide-independent pathway. The lipA gene of strain C9 was disrupted by insertional mutagenesis. The mutant retained its lipolytic phenotype, strongly suggesting the presence of a second lipase in this strain.

Guinea pig serum L-asparaginase: purification, and immunological relationship to liver L-asparaginase and serum L-asparaginases in other mammals.

L-asparaginase, an enzyme used in the treatment of acute lymphocytic leukemia, is found in the serum of only a few mammalian groups, including the guinea pig and its close relatives in the superfamily Cavioidea. This report describes the purification and characterization of L-asparaginase from guinea pig serum. Antiserum against the purified enzyme cross-reacted with sera from other Cavioidean species but not with mouse serum. Relatively weak cross-reaction with unpurified L-asparaginase in guinea pig liver indicates a significant degree of evolutionary divergence.

Transcriptional co-activation at the ansB promoters: involvement of the activating regions of CRP and FNR when bound in tandem.

Previous work with semi-synthetic promoters containing a single CRP binding site centred at 41.5 bp from the transcription start site has demonstrated enhanced transcription (synergism) when a second binding site, for CRP or FNR, is placed upstream at around -91 bp. The ansB promoter in Escherichia coli is co-activated in a co-dependent manner by one dimer each of CRP and FNR protein whose binding sites are at around -91 and -41 bp, respectively, from the transcription start site. Similarly, the homologous ansB promoter in Salmonella is co-activated by two dimers of CRP which function synergistically. The binding sites at the E. coli promoter have been changed by mutation to provide a number of active promoter derivatives carrying other combinations of FNR and CRP binding sites. The co-dependent versus synergistic interaction of these activators and their requirement for known activating regions have been examined. The results demonstrate that FNR can co-activate when located upstream at around -91 bp in combination with either FNR or CRP downstream. When FNR occupies the downstream site the promoter is co-dependent on an upstream activator, but not when CRP occupies this site. Activating region 1 in CRP (defined by substitutions at residue H159) and its putative equivalent in FNR (defined by substitutions at S73) are mainly required in the upstream activator; the putative equivalent in FNR of activating region 3 of CRP (defined by substitutions at G85 and K52, respectively) is mainly required in the dimer which binds downstream. Activating region 1 of FNR is required only in the downstream subunit of the upstream activator in a promoter which is co-dependent on two FNR dimers. These data suggest that both bound upstream and downstream activators interact with RNA polymerase to promote transcription, and that co-dependence is determined by the nature of the activator plus the promoter context.

Silent genes in bacteria: the previously designated 'cryptic' ilvHI locus of 'Salmonella typhimurium LT2' is active in natural isolates.

Gene ilvG in Escherichia coli K-12 and ilvI in 'Salmonella typhimurium LT2' (S. enterica serotype Typhimurium, strain LT2) are inactive due to frameshift or nonsense mutations, respectively. These inactive genes have been suggested to be part of 'cryptic' genetic systems which are defined as being of long-term regulatory and evolutionary significance. We have shown that the nonsense mutation in ilvI is present only in derivatives of the laboratory strain 'S. typhimurium LT2'. All natural isolates of Salmonella examined have an arginine codon at the corresponding location of their ilvI sequences. Further, two randomly selected natural isolates of serotype Typhimurium are shown to each have an active ALS III isozyme. Our findings strongly suggest that the only Salmonella strains which lack a functional ilvHI locus are LT2 isolates. We suggest that the mutations leading to inactivation of both ilvI in 'S. typhimurium LT2' and ilvG in E. coli K-12 are more likely to have been acquired during laboratory storage and/or cultivation, rather than representing cryptic systems of gene regulation.

Degradation of triglycerides by a pseudomonad isolated from milk: the roles of lipase and esterase studied using recombinant strains over-producing, or specifically deficient in these enzymes.

The roles of lipase and esterase in causing hydrolytic spoilage of milk by a highly lipolytic psychrotrophic strain of Pseudomonas fluorescens, LS107d2, has been studied. Strains of LS107d2 have been constructed that over-produce, or are specifically deficient in, a lipase (encoded by lipA) and an esterase (encoded by estA). Southern blot analysis reveals that LS107d2 contains only one esterase and one lipase (encoded by estA and lipA) and this was confirmed by the phenotypes of mutants on triolein and tributyrin-containing agar. Analysis of broth cultures showed that the lipase is secreted into the culture medium; in contrast, the esterase is not secreted. Free fatty acid (FFA) levels in whole milk cultures of wild-type, over-producing and the mutant strains of LS107d2 have been examined. From these studies it is concluded that esterase is not involved in the accumulation of FFA by hydrolysing short chain fatty acid esters; that the highly lipolytic phenotype of LS107d2 is due solely to a single secreted lipase; and that the main FFA accumulated in milk cultures of LS107d2 are C4, C16, C18 and C18: 1. Evidence is also presented demonstrating that FFA degradation, as well as production, determines the level of FFA in milk contaminated with lipolytic organisms.

Human stomach class IV alcohol dehydrogenase: molecular genetic analysis.

A partial human stomach alcohol dehydrogenase (ADH) encoding cDNA has been isolated, cloned, and sequenced, which contains 222 nucleotides encoding amino acid residues 227-299 of the ADH subunit. The amino acid sequence deduced from this cDNA was highly homologous with the rat stomach class IV ADH sequence recently reported (81.1% sequence identity). Homology with other human ADH classes was also observed: class I, 58.1% sequence identity; class II, 39.2% sequence identity; class III, 55.4% sequence identity; and class V, 50.0% sequence identity. These results support a proposal that the isolated cDNA encodes a partial sequence for human stomach class IV ADH. This sequence retains val294 for all other human ADH classes reported, as compared with an ala294 at this position reported for rat class IV ADH. This ala residue may contribute to the very high Km values with ethanol for the latter enzyme. In addition, three substitutions are reported for key residues in the coenzyme binding site: 251, gln/ser; 260, gly/asn; and 261, gly/asn, which may contribute to the weak coenzyme binding properties reported for human class IV ADH.

Cloning and molecular analysis of the Salmonella enterica ansP gene, encoding an L-asparagine permease.

A gene (ansP), which encodes an L-asparagine permease, has been isolated from a cosmid library of Salmonella enterica during screening for recombinant clones which encode L-asparaginase. Nucleotide sequence analysis reveals that the gene product is a polypeptide of 497 amino acid residues, containing 12 putative transmembrane segments. The calculated molecular mass is 54 kDa, although maxicell analysis by SDS-PAGE gave an apparent molecular mass of 37 kDa. Comparison of the deduced amino acid sequence with sequence databases showed significant homology with a family of basic and aromatic amino acid permeases. Strains containing the cloned ansP gene demonstrated a many-fold increase in L-asparagine uptake in comparison with control strains.

UDP-sugar hydrolase isozymes in Salmonella enterica and Escherichia coli: silent alleles of ushA in related strains of group I Salmonella isolates, and of ushB in wild-type and K12 strains of E. coli, indicate recent and early silencing events, respectively.

Escherichia coli contains a single periplasmic UDP-glucose hydrolase (5'-nucleotidase) encoded by ushA. Salmonella enterica, serotype Typhimurium, also contains a single UDP-glucose hydrolase but, in contrast to E. coli, it is membrane-bound and is encoded by the non-homologous ushB gene; Salmonella enterica (Typhimurium) also contains a silent allele of the ushA gene (ushA0). In this report, we show that nearly all natural isolates of Salmonella contain both UDP-sugar hydrolases, i.e. they are UshA+ UshB+. The only exceptions are all from sub-group I (S. gallinarum, S. pullorum, and most Typhimurium strains), are UshA- UshB+, and several have been shown to contain an ushA0 allele. These data, together with the fact that these latter strains are closely related genetically, strongly suggests a recent silencing mutation(s). We also report the presence in E. coli K-12, and in natural isolates of E. coli, of a DNA sequence which is homologous to the ushB gene of Salmonella; since E. coli does not contain UshB activity, we tentatively refer to this sequence as ushB0. Since all E. coli strains investigated are UshB-, we conclude that the silencing mutation(s) occurred relatively early following the divergence of Escherichia coli and Salmonella from a common ancestor that was ushA+ ushB+.

Membrane localisation of a UDP-sugar hydrolase, in Salmonella, is by an uncleaved N-terminal signal peptide.

Most isolates of Salmonella contain two unrelated UDP-sugar hydrolases, one of which, encoded by the ushB gene, is inner membrane-associated. Previous studies showed that this enzyme contains a typical N-terminal signal peptide; the evidence also indicated, however, that this peptide is not cleaved, and serves to anchor the UshB protein in the inner membrane. In this report, we present strong evidence that this is indeed the case by using ushB'-'blaM fusions to demonstrate that this signal peptide is capable of localising beta-lactamase to the inner membrane. We also present evidence that UshB is located on the exterior (periplasmic) side of the membrane, and hence has an 'N-terminus inside/C-terminus outside' membrane orientation, consistent with a role in the degradation of external substrates.

Co-dependent positive regulation of the ansB promoter of Escherichia coli by CRP and the FNR protein: a molecular analysis.

Transcription of the ansB gene, encoding L-asparaginase II, is positively regulated by cAMP receptor protein (CRP) and by the product of the fnr gene, the FNR protein. These global regulatory proteins mediate the expression of ansB in Escherichia coli in response to carbon source and to anaerobiosis, respectively, and are required concurrently for optimal ansB expression. The mechanism whereby CRP and FNR interact co-operatively with the ansB promoter to achieve transcription has not previously been established. We have utilized an ansB'-'lacZ fusion, in conjunction with deletion analysis and site-directed mutagenesis, to identify two sites which interact with these regulatory proteins in the ansB promoter. The first is an FNR site, centred 41.5 bp upstream of the major transcriptional start site. The second site, located 28 bp upstream of the FNR site, is the site of CRP regulation. This site is homologous to both the CRP and FNR binding-site consensus sequences and may respond to both CRP and FNR. The concurrent requirement for CRP and FNR for optimal expression of ansB may be explained if, first, essentially no transcription occurs unless the FNR is bound at the downstream site, and, second, the level of transcription when FNR alone is present is enhanced when CRP binds at the upstream site.

Regulation of the ansB gene of Salmonella enterica.

The expression of L-asparaginase II (encoded by ansB) in Salmonella enterica was found to be positively regulated by the cAMP receptor protein (CRP) and anaerobiosis. The anaerobic regulation of the S. enterica ansB gene is not mediated by the anaerobic transcriptional activator FNR. This is unlike the situation of the ansB gene of Escherichia coli, which is dependent on both CRP and FNR. To investigate this fundamental difference in the regulation of L-asparaginase II expression in S. enterica, the ansB gene was cloned and the nucleotide sequence of the promoter region determined. Sequence analysis and transcript mapping of the 5' promoter region revealed a single transcriptional start point (tsp) and two regulatory sites with substantial homology with those found in E. coli. One site, centred -90.5 bp from the tsp, is homologous to a hybrid CRP/FNR ('CF') site which is the site of CRP regulation in the E. coli promoter. The other site, centred 40.5 bp upstream of the tsp, is homologous to the FNR binding site of the E. coli promoter. Significantly, however, a single base-pair difference exists in this site, at a position of the related CRP and FNR DNA-binding site consensus sequences known to be involved in CRP versus FNR specificity. Site-directed mutagenesis indicates that this single difference, relative to the homologous E. coli site, results in a CRP binding site and the observed FNR-independent ansB expression in S. enterica.(ABSTRACT TRUNCATED AT 250 WORDS)