Twenty-Six Chromosomal Genes Needed to Maintain the Killer Double-Stranded RNA Plasmid of SACCHAROMYCES CEREVISIAE

The double-stranded RNA killer plasmid gives yeast strains carrying it both the ability to secret a protein toxin and immunity to that toxin. This report describes a new series of mutants in chromsomal genes needed for killer plasmid maintenance (mak genes). These mutants comprise 12 complementation groups. There are a total of at least 26 mak genes. Each mak gene product is needed for plasmid maintenance in diploids as well as in haploids. None of these mak mutations prevent the killer plasmid from entering the mak- spores in the process of meiotic sporulation. Complementation between mak mutants can be performed by mating meitoic spores from a makx/+ plasmid-carrying diploid with a maky haploid. If x = y, about half the diploid clones formed lose the killer plasmid. If x not equal to y, complementation occurs, and all of the diploid clones are killers.     

Glyphosate Resistance as a Novel Select-Agent-Compliant,Non-Antibiotic-Selectable Marker in Chromosomal Mutagenesis of the Essential Genes asd and dapB of Burkholderia pseudomallei

Genetic manipulation of the category B select agents Burkholderia pseudomallei and Burkholderia mallei has been stifled due to the lack of compliant selectable markers. Hence, there is a need for additional select-agent-compliant selectable markers. We engineered a selectable marker based on the gat gene (encoding glyphosate acetyltransferase), which confers resistance to the common herbicide glyphosate (GS). To show the ability of GS to inhibit bacterial growth, we determined the effective concentrations of GS against Escherichia coli and several Burkholderia species. Plasmids based on gat, flanked by unique flip recombination target (FRT) sequences, were constructed for allelic-replacement. Both allelic-replacement approaches, one using the counterselectable marker pheS and the gat-FRT cassette and one using the DNA incubation method with the gat-FRT cassette, were successfully utilized to create deletions in the asd and dapB genes of wild-type B. pseudomallei strains. The asd and dapB genes encode an aspartate-semialdehyde dehydrogenase (BPSS1704, chromosome 2) and dihydrodipicolinate reductase (BPSL2941, chromosome 1), respectively. Mutants unable to grow on media without diaminopimelate (DAP) and other amino acids of this pathway were PCR verified. These mutants displayed cellular morphologies consistent with the inability to cross-link peptidoglycan in the absence of DAP. The B. pseudomallei 1026b Δasd::gat-FRT mutant was complemented with the B. pseudomallei asd gene on a site-specific transposon, mini-Tn7-bar, by selecting for the bar gene (encoding bialaphos/PPT resistance) with PPT. We conclude that the gat gene is one of very few appropriate, effective, and beneficial compliant markers available for Burkholderia select-agent species. Together with the bar gene, the gat cassette will facilitate various genetic manipulations of Burkholderia select-agent species.Members of the genus Burkholderia, comprising more than 40 different species, are extremely diverse gram-negative, non-spore-forming bacilli. Many Burkholderia species exist as innocuous soil saprophytes or plant pathogens (47), while others cause human and animal diseases. Among these human and animal pathogens are the etiological agents of melioidosis (Burkholderia pseudomallei) and glanders (Burkholderia mallei) (9, 50, 51). Melioidosis is an emerging infectious disease generally considered endemic to Southeast Asia and Northern Australia (12). Positive diagnoses in many tropical countries around the world have expanded the global awareness of melioidosis (3, 15, 24, 25, 28, 35, 39, 42, 52). In contrast to the ubiquitous nature of B. pseudomallei, B. mallei is also a highly infectious agent causing glanders, a predominantly equine disease (34, 50). B. mallei, a clone derived from genomic downsizing of B. pseudomallei, has been used in biowarfare (17). This historical significance, along with the low infectious dose and the route of infection, has contributed to the decision by the Centers for Disease Control and Prevention (CDC) to classify these two microbes as category B select agents (43).Classification of B. pseudomallei as a select agent has stimulated interest and research into the pathogenesis of melioidosis, necessitating the development of appropriate tools for genetic manipulation. In the struggle to elucidate the molecular mechanisms of pathogenesis, selectable markers are indispensable genetic tools (45). Current CDC regulations prohibit the cloning of clinically important antibiotic resistance genes into human, animal, or plant select-agent pathogens if the transfer could compromise the ability to treat or control the disease. The only antibiotic markers currently approved for use in B. pseudomallei are based on resistance to aminoglycosides (gentamicin, kanamycin, and zeocin) (45). However, the efficacy of these markers is limited, due to high levels of aminoglycoside resistance inherent within the Burkholderia genus and high levels of spontaneous aminoglycoside resistance in B. pseudomallei (10, 19, 41). In addition, the use of aminoglycosides (e.g., gentamicin) for selection may require aminoglycoside efflux pump mutants (10, 33). Another potential drawback is that efflux pumps play a major role in bacterial physiology, and mutating them may change the pathogenic traits under investigation (7, 40). A more logical approach employs alternative, non-antibiotic-selectable markers conferring resistance to compounds that are not potentially important in clinical treatment.Very few non-antibiotic resistance markers have been utilized successfully for Burkholderia species. A non-antibiotic-selectable-marker based on tellurite resistance (Tel^r) has been successfully developed and used with Pseudomonas putida, Pseudomonas fluorescens, and Burkholderia thailandensis (2, 27, 44). The engineering of Tel^r-FRT (flip recombination target) cassettes, coupled to FRT sequences, could be used to generate unmarked mutations and allow recycling of the Tel^r selectable-marker (2). In addition, utilization of Flp-FRT resistance cassettes to generate mutants allows downstream modification and manipulation such as fusion integration (29). However, the disadvantage of the Tel^r-cassette is the number of genes required (kilA-telA-telB) and the large size (>3 kb), making it less likely to obtain PCR products for allelic replacement by natural transformation (46). Another potentially useful non-antibiotic-selectable marker is based on the bar gene, encoding resistance to bialaphos or its degradation product, phosphinothricin (PPT) (49). PPT inhibits glutamine synthetase in plants (48), starving the cell for glutamine, and the bar gene has been used successfully as a selection marker in gram-negative bacteria (21). For select-agent Burkholderia species, however, the PPT MIC was found to be greater than 1,024 μg/ml (M. Frazier, K. Choi, A. Kumar, C. Lopez, R. R. Karkhoff-Schweizer, and H. P. Schweizer, presented at the American Society for Microbiology Biodefense and Emerging Diseases Research Meeting, Washington, DC, 2007). We have found the effective concentration of PPT for B. pseudomallei and B. mallei to be ∼2.5% (25,000 μg/ml [data not shown]). The high concentration of PPT required for selection in these species may be costly, considering that purified PPT costs ∼$380 per g. Therefore, further development of non-antibiotic resistance markers, as well as a more economical source of herbicide for use with restricted select-agent species, is needed.Work by Castle et al. (5) generated a highly active glyphosate N-acetyltransferase (GAT) enzyme for plant engineering, making it possible to utilize the gat gene as an effective non-antibiotic resistance marker for bacterial selection with glyphosate (GS). The commonly used herbicide GS inhibits the 5-enolpyruvylshikimate-3-phospate synthase (EPSPS) of plants through competition with phosphoenolpyruvate for overlapping binding sites on EPSPS (14), depriving plants of three aromatic amino acids (Fig. ​(Fig.1).1). Since humans and animals obtain tryptophan and phenylalanine (giving rise to tyrosine) through dietary intake, GS is relatively nontoxic. Like plants, bacteria must make these amino acids, when they are lacking, from basic precursors. GS has been found to be inhibitory to a variety of bacteria, including Pseudomonas aeruginosa, Escherichia coli, Bacillus subtilis, and Bradyrhizobium japonicum (16, 55), while other bacterial strains are able to metabolize low concentrations of GS (26, 31). Although B. pseudomallei has been reported to have two genes (glpA and glpB) for GS degradation and metabolism (38), our searches of all available genomes of Burkholderia species in GenBank yielded no glpA or glpB genes within this genus. GS resistance by bacteria has been documented through EPSPS target mutations or GS detoxification mechanisms (36). However, these mechanisms did not confer resistance to relatively high GS concentrations. More recently, directed evolution of the gat gene, based on various bacterial gat sequences and selection in E. coli, yielded a very active GAT protein sequence with an efficiency increase of nearly 4 orders of magnitude (5), holding promise as an appropriate non-antibiotic resistance marker for select-agent species.Open in a separate windowFIG. 1.(A) A 946-ml bottle of the “superconcentrated” herbicide Roundup used in this study, available for ∼$50 from most local hardware stores and garden or farm supply centers. The active ingredient, 50% GS, is indicated on the label, and the chemical structure of GS is shown. GAT, encoded by the gat gene, catalyzes the inactivation of GS via N acetylation. (B) Pathways of aromatic amino acid biosynthesis. GS inhibits the enzyme EPSPS, which is required for the biosynthesis of aromatic amino acids, thus starving bacteria for tyrosine, phenylalanine, and tryptophan. PEP, phosphoenolpyruvate; TCA cycle, tricarboxylic acid cycle.Here we engineered and tested a novel non-antibiotic-selectable-marker (gat) for use in the select agent B. pseudomallei. GS is the active ingredient in Roundup, which was used for selection (Fig. ​(Fig.1).1). The effective compound GS is readily available, inexpensive, relatively nontoxic, very soluble, and not clinically important, and it yields tight selection. The engineered gat marker (563 bp) was optimized for Burkholderia codon usage and adapted (with a Burkholderia rpsL promoter) for use in the select agent B. pseudomallei. Effective concentrations of GS for several species of Burkholderia, including the select agents B. pseudomallei and B. mallei, were determined. Using the gat gene, we created deletion mutants of the essential B. pseudomallei asd and B. pseudomallei dapB (asd_Bp and dapB_Bp) genes (encoding aspartate-semialdehyde dehydrogenase and dihydrodipicolinate reductase, respectively) in two wild-type B. pseudomallei strains. The Δasd_Bp mutant of B. pseudomallei showed a phenotypic defect consistent with the lack of diaminopimelate (DAP) for cell wall cross-linking. Complementation of the B. pseudomallei Δasd_Bp mutant with the asd_Bp gene located on a site-specific transposon, mini-Tn7-bar, was successful by using an inexpensive source of PPT for selection.     

Use of Pulsed Field Gel Electrophoresis and Transposon Mutagenesis to Estimate the Minimal Number of Genes Required for Motility in Caulobacter Crescentus

To facilitate the mapping of transposon insertion mutations in Caulobacter crescentus, we have used pulsed field gel electrophoresis to construct a detailed physical and genetic map of the C. crescentus genome. Restriction fragments were generated by DraI, AseI, or SpeI which cleave the C. crescentus 40, 13, and 26 times, respectively, and Tn5 insertions were used to align the restriction fragments generated by each of the enzymes. The utility of the resulting map was demonstrated by determining the chromosomal locations of a collection of flagellar mutations. As a result of this study, we were able to identify ten new flagellar genes at various locations on the chromosome. Thus, at least 48 genes are required for the assembly of a functional flagellum in C. crescentus.     

Transition from Anaerobic to Aerobic Growth Conditions for the Sulfate-Reducing Bacterium Desulfovibrio oxyclinae Results in Flocculation

A chemostat culture of the sulfate-reducing bacterium Desulfovibrio oxyclinae isolated from the oxic layer of a hypersaline cyanobacterial mat was grown anaerobically and then subjected to gassing with 1% oxygen, both at a dilution rate of 0.05 h⁻¹. The sulfate reduction rate under anaerobic conditions was 370 nmol of SO₄²⁻ mg of protein⁻¹ min⁻¹. At the onset of aerobic gassing, sulfate reduction decreased by 40%, although viable cell numbers did not decrease. After 42 h, the sulfate reduction rate returned to the level observed in the anaerobic culture. At this stage the growth yield increased by 180% compared to the anaerobic culture to 4.4 g of protein per mol of sulfate reduced. Protein content per cell increased at the same time by 40%. The oxygen consumption rate per milligram of protein measured in washed cell suspensions increased by 80%, and the thiosulfate reduction rate of the same samples increased by 29% with lactate as the electron donor. These findings indicated possible oxygen-dependent enhancement of growth. After 140 h of growth under oxygen flux, formation of cell aggregates 0.1 to 3 mm in diameter was observed. Micrometer-sized aggregates were found to form earlier, during the first hours of exposure to oxygen. The respiration rate of D. oxyclinae was sufficient to create anoxia inside clumps larger than 3 μm, while the levels of dissolved oxygen in the growth vessel were 0.7 ± 0.5 μM. Aggregation of sulfate-reducing bacteria was observed within a Microcoleus chthonoplastes-dominated layer of a cyanobacterial mat under daily exposure to oxygen concentrations of up to 900 μM. Desulfonema-like sulfate-reducing bacteria were also common in this environment along with other nonaggregated sulfate-reducing bacteria. Two-dimensional mapping of sulfate reduction showed heterogeneity of sulfate reduction activity in this oxic zone.     

The Origin of Dihydroorotate Dehydrogenase Genes of Kinetoplastids, with Special Reference to Their Biological Significance and Adaptation to Anaerobic, Parasitic Conditions

Trypanosoma cruzi dihydroorotate dehydrogenase (DHOD), the fourth enzyme of the de novo pyrimidine biosynthetic pathway, is localized in the cytosol and utilizes fumarate as electron acceptor (fumarate reductase activity), while the enzyme from other various eukaryotes is mitochondrial membrane-linked. Here we report that DHOD-knockout T. cruzi did not express the enzyme protein and could not survive even in the presence of pyrimidine nucleosides, substrates for the potentially active salvage pathway, suggesting a vital role of fumarate reductase activity in the regulation of cellular redox balance. Cloning and phylogenetic analysis of euglenozoan DHOD genes showed that the euglenoid Euglena gracilis had a mitochondrial DHOD and that biflagellated bodonids, a sister group of trypanosomatids within kinetoplastids, harbor the cytosolic DHOD. Further, Bodo saliens, a bodonid, had an ACT/DHOD gene fusion encoding aspartate carbamoyltransferase (ACT), the second enzyme of the de novo pyrimidine pathway, and DHOD. This is the first report of this novel gene structure. These results are consistent with suggestions that an ancient common ancestor of Euglenozoa had a mitochondrial DHOD whose descendant exists in E. gracilis and that a common ancestor of kinetoplastids (bodonids and trypanosomatids) subsequently acquired a cytosolic DHOD by horizontal gene transfer. The cytosolic DHOD gene thus acquired may have contributed to adaptation to anaerobiosis in the kinetoplastid lineage and further contributed to the subsequent establishment of parasitism in a trypanosomatid ancestor. Different molecular strategies for anaerobic adaptation in pyrimidine biosynthesis, used by kinetoplastids and by euglenoids, are discussed. Evolutionary implications of the ACT/DHOD gene fusion are also discussed.Sequence availability: The nucleotide sequence data reported here appear in the GenBank, EMBL, and DDBJ databases with the accession numbers AB120414, AB159227, and AB159228 for Euglena gracilis dihydroorotate dehydrogenase (DHOD), Bodo saliens aspartate carbamoyltransferase/dihydroorotate dehydrogenase (ACT/DHOD), and B. caudatus DHOD, respectively.Reviewing Editor: Dr. Patrick Keeling     

Identification of Genes Involved in Biofilm Formation and Respiration via Mini-Himar Transposon Mutagenesis of Geobacter sulfurreducens

Electron transfer from cells to metals and electrodes by the Fe(III)-reducing anaerobe Geobacter sulfurreducens requires proper expression of redox proteins and attachment mechanisms to interface bacteria with surfaces and neighboring cells. We hypothesized that transposon mutagenesis would complement targeted knockout studies in Geobacter spp. and identify novel genes involved in this process. Escherichia coli mating strains and plasmids were used to develop a conjugation protocol and deliver mini-Himar transposons, creating a library of over 8,000 mutants that was anaerobically arrayed and screened for a range of phenotypes, including auxotrophy for amino acids, inability to reduce Fe(III) citrate, and attachment to surfaces. Following protocol validation, mutants with strong phenotypes were further characterized in a three-electrode system to simultaneously quantify attachment, biofilm development, and respiratory parameters, revealing mutants defective in Fe(III) reduction but unaffected in electron transfer to electrodes (such as an insertion in GSU1330, a putative metal export protein) or defective in electrode reduction but demonstrating wild-type biofilm formation (due to an insertion upstream of the NHL domain protein GSU2505). An insertion in a putative ATP-dependent transporter (GSU1501) eliminated electrode colonization but not Fe(III) citrate reduction. A more complex phenotype was demonstrated by a mutant containing an insertion in a transglutaminase domain protein (GSU3361), which suddenly ceased to respire when biofilms reached approximately 50% of the wild-type levels. As most insertions were not in cytochromes but rather in transporters, two-component signaling proteins, and proteins of unknown function, this collection illustrates how biofilm formation and electron transfer are separate but complementary phenotypes, controlled by multiple loci not commonly studied in Geobacter spp.Geobacter sulfurreducens is a member of the metal-reducing Geobacteraceae family and was originally isolated based on its ability to transfer electrons from internal oxidative reactions to extracellular electron acceptors such as insoluble Fe(III) or Mn(IV) oxides (5). G. sulfurreducens is also able to use an electrode as its sole electron acceptor for respiration, a phenotype which has many possible biotechnological applications (28, 29), and serves as a useful tool for direct measurement of electron transfer rates (2, 31). As G. sulfurreducens was the first Geobacteraceae genome sequence available (34) and the only member of this family with a robust genetic system (7), it serves as a model organism for extracellular electron transfer studies.The proteins facilitating electron transfer to insoluble Fe(III) oxides by individual Geobacter cells and how these cells interact in multicellular biofilms are not fully understood. Many genes implicated in Fe(III) and electrode reduction were identified based on proteomic and microarray analysis of cultures grown with fumarate versus Fe(III) citrate as a terminal electron acceptor (9, 15, 35). More recently, similar expression data from Fe(III) oxide and electrode-grown cultures have also become available (8, 12, 16). In most extracellular electron transfer studies, outer membrane proteins (such as c-type cytochromes) have been the focus (4, 23, 27, 32), leading to targeted knockout studies of at least 14 cytochromes to date.To reduce an insoluble electron acceptor, Geobacter spp. must achieve direct contact with the substrate (36). While contact with small Fe(III) oxide particles may be transient, growth on Fe(III)-coated surfaces or electron-accepting electrodes requires biofilm formation (31, 39). For example, when G. sulfurreducens produces an exponentially increasing rate of electron transfer at an electrode, this demonstrates that all newly divided cells remain embedded in the growing, conductive biofilm (2, 31). Thus, in addition to the need for an array of outer membrane cytochromes, there is also a need for control of both cell-cell contact and cell-surface contact.While a genetic system for G. sulfurreducens has been developed, conjugal transfer of a plasmid or a transposon has not been reported (7). The broad-host-range cloning vector pBBR1MCS-2 has previously been electroporated into G. sulfurreducens, but its mobilization capabilities were not utilized (7). Similarly, a number of suicide vectors have been identified for G. sulfurreducens, but none have been used to deliver transposons for mutagenesis. mariner-based transposon mutagenesis systems have been successful in a variety of Bacteria and Archaea, producing random insertions (20, 25, 40, 41, 43, 46, 48, 49). For example, genes involved in Shewanella oneidensis cytochrome maturation were discovered using the modified transposon mini-Himar RB1 (3).In this work, we describe a system for the conjugal transfer of the pBBR1MCS family of plasmids from Escherichia coli to G. sulfurreducens, which allowed transposon mutagenesis based on pMiniHimar RB1. Under strictly anaerobic conditions, a library of insertion mutants was constructed and screened to identify genes putatively involved in attachment and Fe(III) citrate reduction. Approximately 8,000 insertion mutants were isolated, with insertions distributed throughout the G. sulfurreducens chromosome. Subsequent characterization revealed mutants defective in metal reduction but unaffected in all aspects of electrode reduction, as well as mutants able to reduce metals but incapable of electrode reduction. These observations greatly expand the list of Geobacter mutants with defects in respiration or biofilm formation, and this library serves as a resource for further screening of extracellular electron transfer phenotypes.     

Isolation and Genetic Analysis of an Agrobacterium tumefaciens Avirulent Mutant with a Chromosomal Mutation Produced by Transposon Mutagenesis

A transposon 5 (Tn5) insertion was introduced into the genome of A. tumefaciens (A-208 strain harbouring a nopaline type Ti-plasmid) using a conjugative pJB4JI plasmid containing Tn5. Five thousand transconjugants were assayed for virulence on carrot (Daucus carota L.) disks; 54 isolates were avirulent or very attenuated. The cellular localization (plasmid or chromosome) of the Tn5 insertion in those isolates were identified by Southern hybridization analysis. An avirulent- mutant (B-90 strain) with the Tn5 insertion in the chromosome was selected and characterized. The mutant had the same growth rate as that of the parent strain in L-broth. The mutant and the parent strain had similar attachment ability to carrot root cells. Tn5 was inserted into one site of the chromosome. The wild-type target chromosomal region (1281 base pairs) was cloned and sequenced. An open reading frame (ORF) consisting of 395 base pairs was identified. The wild-type DNA fragment (1.6 kb) containing the ORF introduced into B-90 strain complemented the avirulent phenotype of the strain. A soluble protein was predicted from the ORF. The Tn5 was inserted near the 3′-terminal of the ORF. Homology search of this ORF found no significant homology to known genes and proteins. Thus, the ORF identified in this paper seems to be a new chromosomal virulence gene of A. tu?efaciens.     

Transposon Mutagenesis and Excision of R' Plasmids by Conjugative, Chimeric Plasmid pUW942 in Extra-Slow-Growing Rhizobium japonicum Strains

Transposons Tn501 (specifying mercury resistance) and Tn7 (specifying resistance to trimethoprim and streptomycin) were introduced into extra-slow-growing Rhizobium japonicum by conjugal transfer of the 82 kilobase chimeric plasmid pUW942. Mercury-resistant transconjugants were obtained at a frequency of 10 to 10. The transfer frequency of streptomycin resistance was lower than that of mercury resistance, and Tn7 was relatively unstable. pUW942 was not maintained as an autonomously replicating plasmid in R. japonicum strains. However, some of the Hg transconjugants from the RJ19FY, RJ17W, and RJ12S strains acquired antibiotic markers of the vector plasmid pUW942. Southern hybridization of plasmid and chromosomal DNA of R. japonicum strains with P-labeled pUW942 and pAS8Rep-1, the same plasmid as pUW942 except that it does not contain Tn501, revealed the formation of cointegrates between pUW942 and the chromosome of R. japonicum. More transconjugants with only Tn501 insertions in plasmids or the chromosome were obtained in crosses with strains RJ19FY and RJ17W than with RJ12S. These retained stable Hg both in plant nodules and under nonselective in vitro growth conditions. One of the RJ19FY and two of the RJ12S Hg transconjugants with vector plasmid-chromosome cointegrates conjugally transferred plasmids of 82, 84 or 86, and 90 kilobases, respectively, into plasmidless Escherichia coli C. These plasmids strongly hybridized to pUW942 and EcoRI digests of total DNA of each respective R. japonicum strain but not to indigenous plasmid DNA of the R. japonicum strains. These R' plasmids consisted of pUW942-specific EcoRI fragments and an additional one or two new fragments derived from the R. japonicum chromosome.     

Genome-Wide Transposon Mutagenesis Identifies a Role for Host Neuroendocrine Stress Hormones in Regulating the Expression of Virulence Genes in Salmonella

Bacterial sensing of environmental signals plays a key role in regulating virulence and mediating bacterium-host interactions. The sensing of the neuroendocrine stress hormones epinephrine (adrenaline) and norepinephrine (noradrenaline) plays an important role in modulating bacterial virulence. We used MudJ transposon mutagenesis to globally screen for genes regulated by neuroendocrine stress hormones in Salmonella enterica serovar Typhimurium. We identified eight hormone-regulated genes, including yhaK, iroC, nrdF, accC, yedP, STM3081, and the virulence-related genes virK and mig14. The mammalian α-adrenergic receptor antagonist phentolamine reversed the hormone-mediated effects on yhaK, virK, and mig14 but did not affect the other genes. The β-adrenergic receptor antagonist propranolol had no activity in these assays. The virK and mig14 genes are involved in antimicrobial peptide resistance, and phenotypic screens revealed that exposure to neuroendocrine hormones increased the sensitivity of S. Typhimurium to the antimicrobial peptide LL-37. A virK mutant and a virK mig14 double mutant also displayed increased sensitivity to LL-37. In contrast to enterohemorrhagic Escherichia coli (EHEC), we have found no role for the two-component systems QseBC and QseEF in the adrenergic regulation of any of the identified genes. Furthermore, hormone-regulated gene expression could not be blocked by the QseC inhibitor LED209, suggesting that sensing of hormones is mediated through alternative signaling pathways in S. Typhimurium. This study has identified a role for host-derived neuroendocrine stress hormones in downregulating S. Typhimurium virulence gene expression to the benefit of the host, thus providing further insights into the field of host-pathogen communication.Bacterial sensing of environmental signals plays a key role in regulating virulence gene expression and bacterium-host interactions. It is increasingly recognized that detection of host-derived molecules, such as the neuroendocrine stress hormones (catecholamines) epinephrine (adrenaline) and norepinephrine (noradrenaline), plays an important role in modulating bacterial virulence (29, 42).Physical and psychological stress has been linked to increased severity and susceptibility to infection in humans and other animals (23, 42), and epinephrine/norepinephrine levels are an important factor in this. Stress triggers an increase in plasma epinephrine levels (31), and plasma levels of epinephrine and norepinephrine have been reported to increase with patients suffering from postoperative sepsis compared to patients with no complications (32). Administration of norepinephrine and epinephrine to otherwise healthy subjects increases the severity of bacterial infections, including Clostridium perfringens in humans and enterohemorrhagic Escherichia coli (EHEC) in calves (42, 63, 65). Treatment with norepinephrine also increases the virulence of Salmonella enterica serovar Enteritidis in chicks and Salmonella enterica serovar Typhimurium in mice, with a substantial increase in bacterial numbers recovered from the cecum and liver in both cases (47, 65).Norepinephrine is found in large concentrations in the gut due to release by gastrointestinal neurones; indeed up to half the norepinephrine in the body may be produced in the enteric nervous system (ENS) (3). Epinephrine, while not normally found in the gut, is present in the bloodstream and is also produced by macrophages in response to bacteria-derived lipopolysaccharide (LPS) (12, 26). S. Typhimurium is an enteropathogen, can also cross the epithelial barrier to cause systemic infection, and will therefore encounter both these molecules in the normal infection cycle.Phenotypes induced by stress hormones in bacteria include increased adherence of EHEC to bovine intestinal mucosa (63), upregulation of type III secretion and Shiga toxin production in EHEC (22, 60), upregulation of type III secretion in Vibrio parahaemolyticus (51), increase in invasion of epithelial cells and breakdown of epithelial tight junctions by Campylobacter jejuni (15), affected motility and expression of iron uptake genes in S. Typhimurium (8, 9, 36), and modulated virulence in Borrelia burgdorferi (59). Epinephrine and norepinephrine can overcome the growth inhibition of many bacteria, including Salmonella, in serum-containing media (13, 43), due to the ability to act as a siderophore to facilitate iron uptake (13, 28, 47).Norepinephrine and epinephrine also interact with bacterial quorum-sensing (QS) systems. QS is a process of bacterial cell-cell communication in which each cell produces small signal molecules termed “autoinducers” (AIs), which regulate gene expression when a critical threshold concentration and therefore population density have been reached. QS affects diverse processes, including motility, virulence, biofilm formation, type III secretion, and luminescence (6, 64).The EHEC AI-3 QS system is important for motility and expression of the type III secretion system encoded by the locus of enterocyte effacement (LEE) (60). AI-3 sensing and signal transduction are mediated via the QseBC and QseEF two-component systems, respectively. Epinephrine and norepinephrine can substitute for AI-3, causing cross talk between the two signaling systems and induction of type III secretion and motility (57, 60). The sensor kinase QseC is autophosphorylated upon binding either epinephrine or norepinephrine (14), demonstrating the presence of adrenergic receptors in bacteria. These adrenergic phenotypes can also be blocked by the mammalian α- and β-adrenergic antagonists phentolamine and propranolol, although it should be noted that QseC is blocked only by the former (14, 60). This suggests the occurrence of cross talk between bacterial and mammalian cell signaling systems and the existence of multiple bacterial adrenergic sensors.To elucidate the role of host-derived stress hormones in the physiology and pathogenicity of S. Typhimurium, we used MudJ transposon mutagenesis to screen globally for epinephrine- and norepinephrine-regulated genes in S. Typhimurium.     

海洋细菌9912肽抗生素发酵条件优化研究

对海洋细菌 9912肽抗生素发酵培养基及培养条件进行了研究。结果表明 ,采用廉价的玉米粉、豆饼粉和葡萄糖即可得到良好的效果 ,比实验室培养基提高效价 11%。培养条件为 2 8℃ ,种龄 12h ,接种量 5 % ,发酵周期 2 0h。     

Transposon Mutagenesis and Excision of R′ Plasmids by Conjugative, Chimeric Plasmid pUW942 in Extra-Slow-Growing Rhizobium japonicum Strains

Transposons Tn501 (specifying mercury resistance) and Tn7 (specifying resistance to trimethoprim and streptomycin) were introduced into extra-slow-growing Rhizobium japonicum by conjugal transfer of the 82 kilobase chimeric plasmid pUW942. Mercury-resistant transconjugants were obtained at a frequency of 10⁻⁷ to 10⁻⁹. The transfer frequency of streptomycin resistance was lower than that of mercury resistance, and Tn7 was relatively unstable. pUW942 was not maintained as an autonomously replicating plasmid in R. japonicum strains. However, some of the Hg^r transconjugants from the RJ19FY, RJ17W, and RJ12S strains acquired antibiotic markers of the vector plasmid pUW942. Southern hybridization of plasmid and chromosomal DNA of R. japonicum strains with ³²P-labeled pUW942 and pAS8Rep-1, the same plasmid as pUW942 except that it does not contain Tn501, revealed the formation of cointegrates between pUW942 and the chromosome of R. japonicum. More transconjugants with only Tn501 insertions in plasmids or the chromosome were obtained in crosses with strains RJ19FY and RJ17W than with RJ12S. These retained stable Hg^r both in plant nodules and under nonselective in vitro growth conditions. One of the RJ19FY and two of the RJ12S Hg^r transconjugants with vector plasmid-chromosome cointegrates conjugally transferred plasmids of 82, 84 or 86, and 90 kilobases, respectively, into plasmidless Escherichia coli C. These plasmids strongly hybridized to pUW942 and EcoRI digests of total DNA of each respective R. japonicum strain but not to indigenous plasmid DNA of the R. japonicum strains. These R′ plasmids consisted of pUW942-specific EcoRI fragments and an additional one or two new fragments derived from the R. japonicum chromosome.     

Changes in Cellular States of the Marine Bacterium Deleya aquamarina under Starvation Conditions

In this study, we have used different fluorescent dyes and techniques to characterize the heterogeneity and changes of the physiological states encountered by the marine bacterium Deleya aquamarina during a 92-day starvation survival experiment at 20 and 5(deg)C. Changes of physiological states were investigated on a single-cell basis by flow cytometry and epifluorescence microscopy in conjunction with fluorescent dyes specific for various cellular functions and constituents. Heterogeneities within populations with regard to functions (respiration, substrate responsiveness, enzymatic activity, and cytoplasmic membrane permeability), constituent (DNA), and cell volume (light scatter) were compared to the evolution of viable plate counts (CFU). At 20(deg)C, CFU changes were divided into three stages corresponding to stability up to day 13 followed by a rapid drop between days 13 and 42 and then by stabilization at a level of 10 to 20% during the remaining survival period. Most of the cellular fractions showing a metabolic activity were close to the evolution of the culturable cells, suggesting the absence of viable but nonculturable cells. On the other hand, cells with selective cytoplasmic membrane permeability but without any metabolic activity were observed, and this stage was followed by DNA alteration occurring at different rates after the loss of membrane cytoplasmic permeability. We observed a greater maintenance of culturability, physiological functions, DNA, and cellular volume at the lower temperature. These results have different ecological implications from both methodological and conceptual viewpoints.