The nucleotide sequence of the 3-chlorobenzoate 3,4-dioxygenase genes, designated cbaAB, from the transposon Tn5271 was determined. FMN-isoalloxazine and NAD-ribose-binding domains and the orientation of these domains is conserved in all known class IA reductases. These results support the hypothesis that alternative fusions of the electron transfer modules of the reductases arose early in the divergence of oxygenase systems. The over-riding evolutionary constraint acting on the divergence of the class IA oxygenases would appear to be the requirement for a carboxyl group para to the site of oxygen insertion into the aromatic ring.
An Alcaligenes sp. BR60, isolated from surface runoff waters of the Hyde Park industrial landfill, contained a novel 85 kb catabolic plasmid (pBR60) functional in 3-chlorobenzoate (3Cba) degradation. The plasmid exhibited a spontaneous 3.2% frequency of deletion of a 14 kb fragment specifying 3Cba degradation. The deletion mutant BR 40 and mitomycin C cured strains were not able to grow on 3Cba and had reversion frequencies of less than 10(-10) cell-1 generation-1. Transformation or conjugation of pBR60 into cured strains restored catabolic activity. An EcoRI, BglII, HindIII and SalI restriction map of the deletion region was constructed, and EcoRI and HindIII fragments spanning the deletion region of the plasmid were cloned in pUC18. Conjugation of resistance plasmid R68.45 into Alcaligenes sp. BR 60, with selection on antibiotics, resulted in the elimination of pBR60 and maintenance of unaltered R68.45. In 30% of the exconjugants, 3Cba degradative capacity was retained, although variation in the regulation of 3Cba degradation was observed in these strains. Hybridization of deletion region fragments to BglII digested total DNA of BR60 and the R68.45 cured exconjugants revealed the presence of pBR60 deletion region sequences in the chromosome of exconjugants. Hybridization also revealed a repeated sequence flanking the deletion region of pBR60. Selection on 4-chlorobenzoate as a sole source of carbon and energy resulted in the isolation of 4Cba+ mutants of Alcaligenes sp. BR60.
A mixed community of bacteria from surface runoff waters of the Hyde Park industrial landfill was enriched on 3-chlorobenzoate. Alcaligenes and Pseudomonas species were dominant in the community. Alcaligenes sp. BR60 carried an unstable plasmid specifying 3-chlorobenzoate catabolism. Metabolites detected in culture supernatants included chlorocatechol and chloro-cis, cismuconic acid. Oxygen uptake in the presence of 3- and 4-substituted methyl-catechols revealed a catechol-1,2-oxygenase activity specific for substituted catechols with very limited activity for catechol. The isolate grew very slowly on benzoate. Alcaligenes sp. BR60 was isolated in co-culture with Pseudomonas fluorescens NR52. The latter contained no detectable plasmids and did not grow on benzoate or any of the chlorobenzoates in pure culture. Growth of the co-culture in Bloody Run Creek water supplemented with 3-chlorobenzoate indicated that phosphate concentrations in the water severely limited biodegradation. Under phosphate limited conditions in continuous culture, Pseudomonas fluorescens NR52 effectively scavenged available phosphate when it was present at a ratio of 1 cell to 20 of Alcaligenes sp. BR60. Under these conditions the growth of Alcaligenes sp. BR60 on 3-chlorobenzoate was reduced 5 fold, the frequency of plasmid deletion mutants increased, and 96% of the contaminant remained in the outflow in the form of the starting material or metabolites. No evidence was found for conjugation of the plasmid determining chlorobenzoate catabolism in Alcaligenes sp. BR60 to P. fluorescens NR52.
The sequence organization in the DNA of chicken (Gallus domesticus) was studied using hydroxyapatite-monitored reassociation kinetics. DNA 320-nucleotides long reassociates as though it is composed of three components, i.e., a very rapidly reacting fold-back fraction, a component composed of sequences repeated an average of 640 times in the genome, and a large unique fraction representing about 80% of the genome. The sizes of the fold back and repeated components increase only moderately with large increases in fragment size, indicating that these sequences are not extensively interspersed in the genome. Even at a fragment size of 4500 nucleotides, the unique component represents 68% of the DNA. Thus, the chicken genome is not organized in the short-period (Xenopus) interspersion pattern described for a large number of other organisms; rather, the DNA-sequence organization of this vertebrate bears more resemblance to the long-period interspersion pattern of Drosophila.
Chloroaromatic biodegradation was studied in samples of water and the sediment-water interface of Bloody Run Creek, a tributary of the Niagara River with a source adjacent to the Hyde Park Industrial Landfill in New York State. Alcaligenes spp. were found which metabolized chlorobenzoates by virtue of an 85 kilobase plasmid, pBR60. These isolates were obtained following continuous culture enrichment of populations from the sediment-water interface, selecting isolates for their metabolism of 3-chlorobenzoate as a carbon and energy source. To determine whether plasmid deoxyribonucleic acid (DNA) sequences were present in a significant number of organisms in the water and surface sediments of the creek, samples were diluted and spread on nitrocellulose niters overlying solid media containing chlorobenzoates and traces of yeast extract. A control creek with a similar superficial geology but lacking contaminants was also sampled. Colony hybridization with phosphorus-32 (32P)-labeled pBR60 revealed differences between samples from the two creeks in both the number of positive signals and the signal strength. Isolates, obtained from the creek water and surface sediments, which were capable of growth on 3-chlorobenzoate were screened by dot-blot hybridization using a specific probe, derived from pBR60, which detected sequences involved in chlorobenzoate catabolism. Evidence for the mobility of the plasmid between Alcaligenes and Pseudomonas species was also obtained. Technical problems with this approach, alternative methods, and applications are discussed.
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