Simple conjugation and outgrowth procedures for tagging vibrios with GFP, and factors affecting the stable expression of the gfp tag.

AIM: Our goal was to develop a simple system for tagging wild-type marine bacteria with gfp. METHODS AND RESULTS: Escherichia coli strain CC118lambdapir carrying the conjugative helper plasmid pEVS104 and the gfp-containing plasmid pKV111 was used to transfer gfp to Vibrio recipients. Four different media were tested for their ability to support the growth of recipients, but not the E. coli donor, to allow powerful enrichment of gfp-tagged wild-type vibrios from mating mixes. Forty-three vibrio strains, representing 39 different species, were successfully tagged with gfp using the conjugative transfer from E. coli followed by selective outgrowth at 15 degrees C on ZoBell 2216E agar containing 0.5% sodium alginate. Using this outgrowth medium, colonies of GFP-expressing vibrio clones were detectable within 4 days. The percentage of visibly fluorescent cells in three representative GFP-tagged vibrios was higher at 15 degrees C than at 20 or 25 degrees C (c. 50% vs. 45% or 40%, respectively), and was also higher during the aerobic rather than the anaerobic culturing (c. 50% vs. 35%, respectively). CONCLUSIONS: We found a simple selective outgrowth technique that enabled us to isolate a wide variety of GFP-tagged marine vibrios following the conjugative transfer of gfp from E. coli. SIGNIFICANCE AND IMPACT OF THE STUDY: Tagging cells with GFP and related fluorescent proteins is a powerful approach for investigating the bacteria in situ, particularly during the colonization of hosts. The simple and cost-effective outgrowth condition described in this study could be applied to construct a wide variety gfp-tagged marine bacteria.

Complete genome sequence of Vibrio fischeri: a symbiotic bacterium with pathogenic congeners.

Vibrio fischeri belongs to the Vibrionaceae, a large family of marine gamma-proteobacteria that includes several dozen species known to engage in a diversity of beneficial or pathogenic interactions with animal tissue. Among the small number of pathogenic Vibrio species that cause human diseases are Vibrio cholerae, Vibrio parahaemolyticus, and Vibrio vulnificus, the only members of the Vibrionaceae that have had their genome sequences reported. Nonpathogenic members of the genus Vibrio, including a number of beneficial symbionts, make up the majority of the Vibrionaceae, but none of these species has been similarly examined. Here we report the genome sequence of V. fischeri ES114, which enters into a mutualistic symbiosis in the light organ of the bobtail squid, Euprymna scolopes. Analysis of this sequence has revealed surprising parallels with V. cholerae and other pathogens.

Vibrio fischeri genes hvnA and hvnB encode secreted NAD(+)-glycohydrolases.

HvnA and HvnB are proteins secreted by Vibrio fischeri ES114, an extracellular light organ symbiont of the squid Euprymna scolopes, that catalyze the transfer of ADP-ribose from NAD(+) to polyarginine. Based on this activity, HvnA and HvnB were presumptively designated mono-ADP-ribosyltransferases (ARTases), and it was hypothesized that they mediate bacterium-host signaling. We have cloned hvnA and hvnB from strain ES114. hvnA appears to be expressed as part of a four-gene operon, whereas hvnB is monocistronic. The predicted HvnA and HvnB amino acid sequences are 46% identical to one another and share 44% and 34% identity, respectively, with an open reading frame present in the Pseudomonas aeruginosa genome. Four lines of evidence indicate that HvnA and HvnB mediate polyarginine ADP-ribosylation not by ARTase activity, but indirectly through an NAD(+)-glycohydrolase (NADase) activity that releases free, reactive, ADP-ribose: (i) like other NADases, and in contrast to the ARTase cholera toxin, HvnA and HvnB catalyzed ribosylation of not only polyarginine but also polylysine and polyhistidine, and ribosylation was inhibited by hydroxylamine; (ii) HvnA and HvnB cleaved 1, N(6)-etheno-NAD(+) and NAD(+); (iii) incubation of HvnA and HvnB with [(32)P]NAD(+) resulted in the production of ADP-ribose; and (iv) purified HvnA displayed an NADase V(max) of 400 mol min(-1) mol(-1), which is within the range reported for other NADases and 10(2)- to 10(4)-fold higher than the minor NADase activity reported in bacterial ARTase toxins. Construction and analysis of an hvnA hvnB mutant revealed no other NADase activity in culture supernatants of V. fischeri, and this mutant initiated the light organ symbiosis and triggered regression of the light organ ciliated epithelium in a manner similar to that for the wild type.

Establishment of an animal-bacterial association: recruiting symbiotic vibrios from the environment.

While most animal-bacterial symbioses are reestablished each successive generation, the mechanisms by which the host and its potential microbial partners ensure tissue colonization remain largely undescribed. We used the model association between the squid Euprymna scolopes and Vibrio fischeri to examine this process. This light organ symbiosis is initiated when V. fischeri cells present in the surrounding seawater enter pores on the surface of the nascent organ and colonize deep epithelia-lined crypts. We discovered that when newly hatched squid were experimentally exposed to natural seawater, the animals responded by secreting a viscous material from the pores of the organ. Animals maintained in filtered seawater produced no secretions unless Gram-negative bacteria, either living or dead, were reintroduced. The viscous material bound only lectins that are specific for either N-acetylneuraminic acid or N-acetylgalactosamine, suggesting that it was composed of a mucus-containing matrix. Complex ciliated fields on the surface of the organ produced water currents that focused the matrix into a mass that was tethered to, and suspended above, the light organ pores. When V. fischeri cells were introduced into the seawater surrounding the squid, the bacteria were drawn into its fluid-filled body cavity during ventilation and were captured in the matrix. After residing as an aggregate for several hours, the symbionts migrated into the pores and colonized the crypt epithelia. This mode of infection may be an example of a widespread strategy by which aquatic hosts increase the likelihood of successful colonization by rarely encountered symbionts.

Target range of zwittermicin A, an aminopolyol antibiotic from Bacillus cereus.

Zwittermicin A is a novel antibiotic produced by Bacillus cereus UW85, which suppresses certain plant diseases in the laboratory and in the field. We developed a rapid method for large-scale purification of zwittermicin A and then studied the in vitro activity of zwittermicin A against bacteria, fungi, and protists. Zwittermicin A was highly active against the Oomycetes and their relatives, the algal protists, and had moderate activity against diverse Gram-negative bacteria and certain Gram-positive bacteria as well as against a wide range of plant pathogenic fungi. Zwittermicin A was more active against bacteria and fungi at pH 7-8 than at pH 5-6. When zwittermicin A was combined with kanosamine, another antibiotic produced by B. cereus, the two acted synergistically against Escherichia coli and additively against Phytophthora medicaginis, an Oomycete. The results indicate that there are diverse potential applications of this new class of antibiotic.

Genetic analysis of zwittermicin A resistance in Escherichia coli: effects on membrane potential and RNA polymerase.

Zwittermicin A is a novel aminopolyol antibiotic that represents a new structural class of antibiotic and has diverse biological activities, including the suppression of plant disease and the ability to inhibit prokaryotic and eukaryotic cells. To enhance our fundamental understanding and applications of zwittermicin A, we elucidated mechanisms of zwittermicin A resistance in Escherichia coli. Two classes of zwittermicin A-resistant mutants of E. coli were selected and characterized. One class included mutants altered in hemA, hemB, hemL, ubi, cydAB or atp, which were defective in generating a proton motive force (PMF) and resistant to aminoglycosides. The mutant analysis, coupled with physiological data, indicated an association between the electrical membrane potential (deltapsi) component of PMF and zwittermicin A sensitivity. A second class of zwittermicin A-resistant mutants was aminoglycoside sensitive and was affected in rpoB and rpoC, genes that encode subunits of RNA polymerase. The rpoB and rpoC mutants suggested that zwittermicin A might inhibit transcription, DNA replication, DNA gyrase or topoisomerase I; however, we found no further evidence to support any of these as the target for zwittermicin A. This study elucidated the genetic mechanisms of zwittermicin A resistance in E. coli. The results suggest that deltapsi drives zwittermicin A uptake, and that, unlike other antibiotics for which resistance maps in rpoB or rpoC, zwittermicin A does not cause the rapid cessation of DNA or RNA synthesis, suggesting a unique mechanism of antibiosis.

Genotypic and phenotypic analysis of zwittermicin A-producing strains of Bacillus cereus.

Many strains of Bacillus cereus produce zwittermicin A, a novel antibiotic that contributes to the ability of B. cereus to suppress certain plant diseases. The purpose of this study was to identify molecular indicators of zwittermicin A production in B, cereus strains, contribute to an understanding of the ecology and evolution of this group of bacteria, and identify potential agents for control of plant disease. The fatty acid composition of 20 strains known to be zwittermicin A producers and 20 strains known to be non-producers was determined. Cluster analysis of the fatty acid methyl ester (FAME) profiles revealed that zwittermicin A producers grouped together in two clusters, apart from most non-producers. Discriminant analysis of the FAME profiles generated models that correctly predicted the zwittermicin A-production phenotype in 17 of 20 zwittermicin A producers and 17 of 20 non-producers. Sixteen random oligonucleotide primers were tested in PCR, and one primer was identified that generated a fragment of 0.48 kb or 0.49 kb from total DNA from 26 of 28 strains known to produce zwittermicin A, whereas PCR with this primer did not generate bands of that size from 16 of 20 non-producing strains. PCR with primers designed to amplify zmaR, a gene from B. cereus that confers resistance to zwittermicin A, generated DNA fragments of 1.1 kb and 1.0 kb in all 29 zwittermicin A-producing strains tested, amplified a fragment of 0.3 kb in some of the zwittermicin A-producing strains, and amplified no fragments in 20 of 23 non-producing strains in a stock collection of B. cereus strains. The zmaR primers were tested for their ability to identify new zwittermicin A-producing isolates of B. cereus from two soils. All 12 of the isolates that produced the banding pattern characteristic of this primer pair produced zwittermicin A, and none of the 12 isolates that did not have the banding pattern produced detectable zwittermicin A. Seven of the 12 isolates initially identified as zwittermicin A producers with the zmaR primers significantly suppressed damping-off of alfalfa, whereas only one of the non-producers suppressed this disease. The results show that FAME and PCR analyses distinguish B. cereus strains that produce zwittermicin A from other B. cereus strains, that PCR with the primers designed to amplify zmaR is the most reliable method of those tested for identification of zwittermicin A producers, and that this method can be used to identify new strains with disease-suppressive activity.

Zwittermicin A-producing strains of Bacillus cereus from diverse soils.

Bacillus cereus UW85 produces a novel aminopolyol antibiotic, zwittermicin A, that contributes to the ability of UW85 to suppress damping-off of alfalfa caused by Phytophthora medicaginis. UW85 produces a second antibiotic, provisionally designated antibiotic B, which also contributes to suppression of damping-off but has not been structurally defined yet and is less potent than zwittermicin A. The purpose of this study was to isolate genetically diverse strains of B. cereus that produce zwittermicin A and suppress disease. We found that most isolates of B. cereus that were sensitive to phage P7 or inhibited the growth of Erwinia herbicola produced zwittermicin A; therefore, phage typing and E. herbicola inhibition provided indirect, but rapid screening tests for identification of zwittermicin A-producing isolates. We used these tests to screen a collection of 4,307 B. cereus and Bacillus thuringiensis isolates obtained from bacterial stock collections and from diverse soils collected in Honduras, Panama, Australia, The Netherlands, and the United States. A subset of the isolates screened by the P7 sensitivity and E. herbicola inhibition tests were assayed directly for production of zwittermicin A, leading to the identification of 57 isolates that produced zwittermicin A; 41 of these isolates also produced antibiotic B. Eight isolates produced antibiotic B but not zwittermicin A. The assay for phage P7 sensitivity was particularly useful because of its simplicity and rapidity and because 22 of the 23 P7-sensitive isolates tested produced zwittermicin A. However, not all zwittermicin A-producing isolates were sensitive to P7, and the more labor-intensive E. herbicola inhibition assay identified a larger proportion of the zwittermicin A producers.(ABSTRACT TRUNCATED AT 250 WORDS)

Regions of Rhodobacter sphaeroides cytochrome c2 required for export, heme attachment, and function.

Cytochrome c2 is a periplasmic redox protein involved in both the aerobic and photosynthetic electron transport chains of Rhodobacter sphaeroides. The process of cytochrome c2 maturation has been analyzed in order to understand the protein sequences involved in attachment of the essential heme moiety to the cytochrome c2 polypeptide and localization of the protein to the periplasm. To accomplish this, five different translational fusions which differ only in the cytochrome c2 fusion junction were constructed between cytochrome c2 and the Escherichia coli periplasmic alkaline phosphatase. All five of the fusion proteins are exported to the periplasmic space. The four fusion proteins that contain the NH2-terminal site of covalent heme attachment to cytochrome c2 are substrates for heme binding, suggesting that the COOH-terminal region of the protein is not required for heme attachment. Three of these hybrids possess heme peroxidase activity, which indicates that they are functional as electron carriers. Biological activity is possessed by one hybrid protein constructed five amino acids before the cytochrome c2 COOH terminus, since synthesis of this protein restores photosynthetic growth to a photosynthetically incompetent cytochrome c2-deficient derivative of R. sphaeroides. Biochemical analysis of these hybrids has confirmed CycA polypeptide sequences sufficient for export of the protein (A. R. Varga and S. Kaplan, J. Bacteriol. 171:5830-5839, 1989), and it has allowed us to identify regions of the protein sufficient for covalent heme attachment, heme peroxidase activity, docking to membrane-bound redox partners, or the capability to function as an electron carrier.

The place of bone scan in the diagnosis of renal cell carcinoma.

We herein review 12 cases of renal cell carcinoma evaluated by bone scan and skeletal survey. Comparison of these techniques revealed a high incidence of falsely negative results (42 per cent) when using skeletal survey alone. It is now our policy to include the bone scan in our initial evaluation of patients with renal cell carcinoma.