Mycobacterium species identification--a new approach via dnaJ gene sequencing.

The availability of the dnaJ1 gene for identifying Mycobacterium species was examined by analyzing the complete dnaJ1 sequences (approximately 1200 bp) of 56 species (54 of them were type strains) and comparing sequence homologies with those of the 16S rRNA gene and other housekeeping genes (rpoB, hsp65). Among the 56 Mycobacterium species, the mean sequence similarity of the dnaJ1 gene (80.4%) was significantly less than that of the 16S rRNA, rpoB and hsp65 genes (96.6%, 91.3% and 91.1%, respectively), indicating a high discriminatory power of the dnaJ1 gene. Seventy-one clinical isolates were correctly clustered to the corresponding type strains, showing isolates belonging to the same species. In order to propose a method for strain identification, we identified an area with a high degree of polymorphism, bordered by conserved sequences, that can be used as universal primers for PCR amplification and sequencing. The sequence of this fragment (approximately 350 bp) allows accurate species identification and may be used as a new tool for the identification of Mycobacterium species.

Rapid and specific identification of 5 human pathogenic Vibrio species by multiplex polymerase chain reaction targeted to dnaJ gene.

A multiplex polymerase chain reaction (PCR) method, specifically designed for application in routine diagnostic laboratories, was developed for identifying 5 human pathogen Vibrio species: Vibrio cholerae, Vibrio parahaemolyticus, Vibrio vulnificus, Vibrio mimicus, and Vibrio alginolyticus. This assay directed toward the dnaJ gene was tested on a total of 355 strains representing 13 Vibrio species and 17 non-Vibrio species. Specific PCR fragments were produced in isolates belonging to the 5 target species and were absent from all strains other than these 5 species and non-Vibrio strains, indicating a high specificity of this multiplex PCR. The multiplex PCR for the detection of Vibrio pathogens in clinical specimens was experimentally applied to spiked stool samples. Only 1 specific amplicon was observed, corresponding to the pathogen spiked into the stool sample. The detection limitation was 10(5) to 10(6) cells per milliliter stool. Our data showed that this method represented a robust tool for the specific and rapid detection of the 5 major pathogenic Vibrio species.

The dnaJ gene as a novel phylogenetic marker for identification of Vibrio species.

The utility of the dnaJ gene for identifying Vibrio species was investigated by analyzing dnaJ sequences of 57 type strains and 22 clinical strains and comparing sequence homologies with those of the 16S rDNA gene and other housekeeping genes (recA, rpoA, hsp60). Among the 57 Vibrio species, the mean sequence similarity of the dnaJ gene (77.9%) was significantly less than that of the 16S rDNA gene (97.2%), indicating a high discriminatory power of the dnaJ gene. Most Vibrio species were, therefore, differentiated well by dnaJ sequence analysis. Compared to other housekeeping genes, the dnaJ gene showed better resolution than recA or rpoA for differentiating Vibrio coralliilyticus from Vibrio neptunius and Vibrio harveyi from Vibrio rotiferianus. Among the clinical strains, all 22 human pathogenic strains, including an atypical strain, were correctly identified by the dnaJ sequence. Our findings suggest that analysis of the dnaJ gene sequence can be used as a new tool for the identification of Vibrio species.