Isolation and proof of structure of wildfire toxin

DNA sequence and transcriptional analysis of the tblA gene required for tabtoxin biosynthesis by Pseudomonas syringae

The tblA gene of Pseudomonas syringae is required for tabtoxin biosynthesis and is under the control of a regulatory gene, lemA. We have determined the nucleotide sequence of the tblA gene and identified the 5' end of the tblA gene transcript. The sequence of the tblA gene was identified to that of the recently reported open reading frame 1 gene of the tabA region of the BR2 chromosome. The open reading frame of the tblA gene potentially encodes a protein of 231 amino acids. mRNA from the tblA gene was detected at all phases of cells grown in minimal medium. This result is correlated with the constitutive production of tabtoxinine-beta-lactam (the biologically active part of the toxin) by P. syringae BR2R in minimal medium, as quantitated by a phenylisothiocyanate derivatization method.

Regulation of tabtoxin production by the lemA gene in Pseudomonas syringae

Pseudomonas syringae pv. coronafaciens, a pathogen of oats, was mutagenized with Tn5 to generate mutants defective in tabtoxin production. From a screen of 3,400 kanamycin-resistant transconjugants, seven independent mutants that do not produce tabtoxin (Tox-) were isolated. Although the Tn5 insertions within these seven mutants were linked, they were not located in the previously described tabtoxin biosynthetic region of P. syringae. Instead, all of the insertions were within the P. syringae pv. coronafaciens lemA gene. The lemA gene is required by strains of P. syringae pv. syringae for pathogenicity on bean plants (Phaseolus vulgaris). In contrast to the phenotype of a P. syringae pv. syringae lemA mutant, the Tox- mutants of P. syringae pv. coronafaciens were still able to produce necrotic lesions on oat plants (Avena sativa), although without the chlorosis associated with tabtoxin production. Northern (RNA) hybridization experiments indicated that a functional lemA gene was required for the detection of a transcript produced from the tblA locus located in the tabtoxin biosynthetic region. Marker exchange mutagenesis of the tblA locus resulted in loss of tabtoxin production. Therefore, both the tblA and lemA genes are required for tabtoxin biosynthesis, and the regulation of tabtoxin production by lemA probably occurs at the transcriptional level.

Isolation and characterization of pathogenicity genes of Pseudomonas syringae pv. tabaci

Pseudomonas syringae pv. tabaci BR2 produces tabtoxin and causes wildfire disease on tobacco and bean plants. Approximately 2,700 Tn5 insertion mutants of a plasmid-free strain, PTBR 2.024, were generated by using suicide plasmid pGS9. Of these Tn5 mutants, 8 were no longer pathogenic on tobacco plants and 10 showed reduced symptoms. All of the eight nonpathogenic mutants caused typical wildfire disease symptoms on bean plants. Two of the nonpathogenic mutants failed to produce tabtoxin. The eight nonpathogenic mutants have Tn5 insertions into different EcoRI and SalI restriction fragments. The EcoRI fragments containing Tn5 from the eight nonpathogenic mutants were cloned into vector pTZ18R or pLAFR3. A genomic library of the parent strain was constructed in the broad-host-range cosmid pLAFR3. Three different cosmid clones that hybridized to the cloned Tn5-containing fragment from one of the nonpathogenic mutants, PTBR 4.000, were isolated from the genomic library. These clones contained six contiguous EcoRI fragments (a total of 57 kilobases [kb]). A 7.2-kb EcoRI fragment common to all three restored pathogenicity to mutant PTBR 4.000. None of the six EcoRI fragments hybridized to Tn5-containing fragments from the other seven mutants. The 7.2-kb fragment was conserved in P. syringae pv. tabaci and P. syringae pv. angulata, but not in other pathovars or strains. Because the mutants retained pathogenicity on bean plants and because of the conservation of the 7.2-kb EcoRI fragment only in pathovars of tobacco, we suggest that genes on the fragment might be related to host specificity.

Cloning and characterization of Saccharomyces cerevisiae genes that confer L-methionine sulfoximine and tabtoxin resistance

Pseudomonas tabaci produces a toxin, tabtoxin, that causes wildfire disease in tobacco. The primary target of tabtoxin is presumed to be glutamine synthetase. Some effects of tabtoxin in tobacco can be mimicked by methionine sulfoximine (MSO), a compound that is known to inactivate glutamine synthetase. To understand how organisms can be made resistant to tabtoxin and MSO, we used Saccharomyces cerevisiae. We demonstrate that yeast strains carrying the glutamine synthetase gene, GLN1, on a multicopy plasmid overproduced glutamine synthetase and showed increased drug resistance. These and other data indicate that glutamine synthetase is the primary target of tabtoxin and MSO in S. cerevisiae. We also isolated three S. cerevisiae DNA inserts of 2.1, 2.3, and 2.8 kilobases that conferred tabtoxin and MSO resistance when the inserts were present on a multicopy plasmid. These plasmids conferred resistance to MSO by blocking intracellular transport of the drug. Transport appeared to occur by one or more methionine permeases. Resistance to tabtoxin could also occur by blockage of intracellular transport, but the drug was transported by some permease other than a methionine permease. These drug resistance plasmids did not block transport of citrulline, indicating that they did not affect the general amino acid permease.

Self-protection of Pseudomonas syringae pv. "tabaci" from its toxin, tabtoxinine-beta-lactam

An extracellular toxin, tabtoxinine-beta-lactam (T beta L), is produced by Pseudomonas syringae pv. "tabaci." This toxin irreversibly inhibits its target, glutamine synthetase; yet P. syringae pv. "tabaci" retains significant amounts of glutamine synthetase activity during toxin production in culture. As part of our investigation of the self-protection of P. syringae pv. "tabaci," we compared the effects of T beta L on Tox+ (T beta L-producing, insensitive to T beta L) and Tox- (T beta L nonproducing, sensitive to T beta L) strains. The extent of protection afforded to the Tox- strain when induced to adenylylate glutamine synthetase was tested. We concluded that an additional protection mechanism was required. A detoxification activity was found in the Tox+ strain which opens the beta-lactam ring of T beta L to produce the inactive, open-chain form, tabtoxinine. Whole cells of the Tox+ strain incubated for 24 h with [14C]T beta L (0.276 mumol/3 X 10(10) cells) contained [14C]tabtoxinine (0.056 mumol), and the medium contained T beta L (0.226 mumol). Extracts of spheroplasts of the Tox+ stain also converted T beta L to tabtoxinine, whereas extracts of the Tox- strain did not alter T beta L. The conversion was time dependent and stoichiometric and was destroyed by boiling for 30 min or by the addition of 5 mM EDTA. Penicillin, a possible substrate and competitive inhibitor of this lactamase activity, inhibited the conversion of T beta L to tabtoxinine. Periplasmic fluid did not catalyze the conversion of T beta L.

Sulfazecin and isosulfazecin, novel beta-lactam antibiotics of bacterial origin

In the long history of screening for antibiotics, fungi and actinomycetes have been the only producers of beta-lactam antibiotics although several phytopathogenic bacteria have been reported to produce toxins with a beta-lactam structure. We report here the first evidence that novel monocyclic beta-lactam antibiotics, sulfazecin and isosulfazecin, are produced by new species of Pseudomonas.