The three species of the group 1 bacilli, Bacillus anthracis, B. cereus, and B. thuringiensis, are genetically very closely related. All inhabit soil habitats but exhibit different phenotypes. B. anthracis is the causative agent of anthrax and is phylogenetically monomorphic, while B. cereus and B. thuringiensis are genetically more diverse. An amplified fragment length polymorphism analysis described here demonstrates genetic diversity among a collection of non-anthrax-causing Bacillus species, some of which show significant similarity to B. anthracis. Suppression subtractive hybridization was then used to characterize the genomic differences that distinguish three of the non-anthrax-causing bacilli from B. anthracis Ames. Ninety-three DNA sequences that were present in B. anthracis but absent from the non-anthrax-causing Bacillus genomes were isolated. Furthermore, 28 of these sequences were not found in a collection of 10 non-anthrax-causing Bacillus species but were present in all members of a representative collection of B. anthracis strains. These sequences map to distinct loci on the B. anthracis genome and can be assayed simultaneously in multiplex PCR assays for rapid and highly specific DNA-based detection of B. anthracis.
Salmonella enterica serovar Enteritidis, a major cause of food poisoning, can be transmitted to humans through intact chicken eggs when the contents have not been thoroughly cooked. Infection in chickens is asymptomatic; therefore, simple, sensitive, and specific detection methods are crucial for efforts to limit human exposure. Suppression subtractive hybridization was used to isolate DNA restriction fragments present in Salmonella serovar Enteritidis but absent in other bacteria found in poultry environments. Oligonucleotide primers to candidate regions were used in polymerase chain reactions to test 73 non-Enteritidis S. enterica isolates comprising 34 different serovars, including Dublin and Pullorum, two very close relatives of Enteritidis. A primer pair to one Salmonella difference fragment (termed Sdf I) clearly distinguished serovar Enteritidis from all other serovars tested, while two other primer pairs only identified a few non-Enteritidis strains. These primer pairs were also useful for the detection of a diverse collection of clinical and environmental Salmonella serovar Enteritidis isolates. In addition, five bacterial genera commonly found with Salmonella serovar Enteritidis were not detected. By treating total DNA with an exonuclease that degrades sheared chromosomal DNA but not intact circular plasmid DNA, it was shown that Sdf I is located on the chromosome. The Sdf I primers were used to screen a Salmonella serovar Enteritidis genomic library and a unique 4,060-bp region was defined. These results provide a basis for developing a rapid, sensitive, and highly specific detection system for Salmonella serovar Enteritidis and provide sequence information that may be relevant to the unique characteristics of this serovar.
In Rhizobium meliloti, transcription of the key nitrogen-fixation regulatory genes nifA and fixK is induced in response to microaerobiosis through the action of the FixL and FixJ proteins. These two proteins are sensor and regulator homologues, respectively, of a large family of bacterial two-component systems involved in sensing and responding to environmental changes. A soluble, truncated form of the membrane protein FixL, FixL*, has been shown to be a hemoprotein that phosphorylates and dephosphorylates FixJ in response to oxygen tension. Here we use an in vitro transcription system to prove that FixJ is a transcriptional activator of both nifA and fixK and that phosphorylation of FixJ markedly increases its activity. Phosphorylation was achieved either by preincubating FixJ with FixL* and ATP or by exposing FixJ to the inorganic phospho donor ammonium hydrogen phosphoramidate. Both FixJ and FixJ-phosphate formed heparin-resistant complexes under the assay conditions used. Lastly, we were able to show that anaerobiosis, in the presence of FixL* and ATP, greatly stimulates FixJ activity at the nifA promoter with either Escherichia coli or R. meliloti RNA polymerase. This use of atmospheric oxygen to control nifA transcription in vitro represents a reconstitution of a bacterial two-component signal transduction system in its entirety, from effector to ultimate target, by the use of purified components.
The nifA gene of Rhizobium meliloti, the bacterial endosymbiont of alfalfa, is a regulatory nitrogen fixation gene required for the induction of several key nif and fix genes. Transcription of nifA is strongly induced in planta and under microaerobic conditions ex planta. Induction of nifA, in turn, is positively controlled by the flxL andfixj genes ofR. meliloti, the sensor and regulator, respectively, of a two-component system responsible for oxygen sensing by this bacterium. This system is also responsible for the positive induction of fixK. Here, we report that chemical and oligonucleotide site-directed mutageneses of the nifA promoter (nifAp) were conducted to identify nucleotides essential for induction. Nineteen mutants, including 14 single-point mutants,were analyzed for microaerobic induction of nifAp in R. meliloti. Critical residues were identified in an upstream region between base pairs -54 and -39 relative to the transcription start site. Attempts at separating the upstream and downstream regions of the nifA promoter so as to maintain fixj-dependent activity were unsuccessful. A 5' deletion of the fixK promoter (fixKp) to -67 indicates that sequences upstream of this position are not required for microaerobic induction. A sequence comparison of the -54 to -39 region of nifAp with the upstream sequences offixKp does not reveal a block of identical nucleotides that could account for the fixj-dependent microaerobic induction of both promoters. Many of the defective nifAp mutants in this region, however, are in residues with identity tofixKp in an alignment of the promoters according to their transcription start sites. Therefore, it is possible that there is a common sequence motif in the -54 to -39 region of the two promoters that is required forfixlj-dependent microaerobic induction.
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