To investigate the applicability of rpoB gene, which encodes the beta subunit of RNA polymerase, to be used as an alternative to 16S rRNA for sequence similarity analysis in the thermophilic genus Geobacillus. Rapid and reproducible repetitive extragenic palindromic fingerprinting techniques (REP- and BOX-polymerase chain reaction) were also used. rpoB DNA (458 bp) were amplified from 21 Geobacillus- and Bacillus type strains, producing different BOX- and REP-PCR profiles, in addition to 11 thermophilic isolates of Geobacillus and Bacillus species from a Santorini volcano habitat. The sequences and the phylogenetic tree of rpoB were compared with those obtained from 16S rRNA gene analysis. The results demonstrated between 90-100% (16S rRNA) and 74-100% (rpoB) similarity among examined bacteria. BOX- and REP-PCR can be applied for molecular typing within Geobacillus genus. rpoB sequence similarity analysis permits a more accurate discrimination of the species within the Geobacillus genus than the more commonly used 16S rRNA. The obtained results suggested that rpoB sequence similarity analysis is a powerful tool for discrimination between species within the ecologically and industrially important strains of Geobacillus genus.

This report describes efficient plasmid uptake by the thermophile Geobacillus kaustophilus HTA426 by means of a ternary conjugation system, which was used to construct thermophile DNA libraries for G. kaustophilus and to identify the genes for orotidine-5'-phosphate decarboxylase by in vivo functional screening. The results indicate that the conjugation system is useful in constructing G. kaustophilus libraries, which are practical in identifying thermophile genes.

The nosZ gene encodes nitrous oxide reductase, a key enzyme in the nitrous oxide reduction that occurs during complete denitrification. Many conventional approaches have used Proteobacteria-based primers to detect nosZ in environmental samples. However, these primers often fail to detect nosZ in non-Proteobacteria strains, including Firmicutes (Gram-positive) and Bacteroidetes. In this study, newly designed nosZ primers successfully amplified this gene from five Geobacillus species (Firmicutes). The primers were used to construct nosZ clone libraries from DNA extracted from sludge and domestic animal feedlot soils, all with high organic carbon contents. After DNA sequencing, phylogenetic analysis identified many new nosZ sequences with high levels of homology to nosZ from Bacteroidetes, probably because of the high sequence similarity of nosZ from Firmicutes and Bacteroidetes, and a predominance of Bacteroidetes in feedlot environments. Three sets of new quantitative real-time PCR (qPCR) primers based on our clone library sequences were designed and tested for their specificities. Our data showed that only Bacteroidetes-related nosZ sequences were amplified, whereas conventional Proteobacteria-based primers amplified only Proteobacteria-related nosZ. Quantitative analysis of nosZ with the new qPCR primers recovered ~10(4) copies per 100 ng DNA. Thus, it appears that amplification with conventional primers is insufficient for developing an understanding of the diversity and abundance of nosZ genes in the environment.