Sequence Diversity of the oprI Gene,Coding for Major Outer Membrane Lipoprotein I,among rRNA Group I Pseudomonads

The sequence of oprI, the gene coding for the major outer membrane lipoprotein I, was determined by PCR sequencing for representatives of 17 species of rRNA group I pseudomonads, with a special emphasis on Pseudomonas aeruginosa and Pseudomonas fluorescens. Within the P. aeruginosa species, oprI sequences for 25 independent isolates were found to be identical, except for one silent substitution at position 96. The oprI sequences diverged more for the other rRNA group I pseudomonads (85 to 91% similarity with P. aeruginosa oprI). An accumulation of silent and also (but to a much lesser extent) nonsilent substitutions in the different sequences was found. A clustering according to the respective presence and/or positions of the HaeIII, PvuII, and SphI sites could also be obtained. A sequence cluster analysis showed a rather widespread distribution of P. fluorescens isolates. All other rRNA group I pseudomonads clustered in a manner that was in agreement with other studies, showing that the oprI gene can be useful as a complementary phylogenetic marker for classification of rRNA group I pseudomonads.Pseudomonads are increasingly being recognized as important microorganisms in our biosphere, and Pseudomonas aeruginosa and Pseudomonas fluorescens are two important representatives of this genus. As a typical opportunist, P. aeruginosa is more and more involved in a variety of often fatal nosocomial infections, in which it accounts for more than 11% of all isolates recovered (29). In cystic fibrosis, one of the most common autosomal recessive genetic diseases, it is a characteristic pathogen responsible for most of the cases of morbidity and mortality (16, 38). In general, fluorescent pseudomonads, including P. aeruginosa, Pseudomonas putida, P. fluorescens, and other species, are frequently found as rhizosphere microorganisms, in some cases promoting plant growth (11, 19, 20).P. fluorescens and P. aeruginosa are also found as inherent flora of mineral water (14, 39). Identification of fluorescent pseudomonads is often tedious and not reliable. Indeed, the present taxonomy of this group is far from clear at the finer taxonomic level, as polyphasic investigations have demonstrated (4, 13, 18, 26). Ribosomal RNAs have been applied as molecular markers with great success to unravel the rough phylogenetic structure which, at the finer level, is not always in complete agreement with the genotypic and phenotypic similarities deduced from other parts of the genome. Horizontal gene transfer, chromosomal mutation hot spots, and internal genomic rearrangements are probably the bases of these discrepancies at the species and subspecies levels. These arguments, together with the importance of discriminating phenotypic tests in routine identifications, support a polyphasic approach in bacterial taxonomy (2, 8–10, 13, 37, 40). Additional phylogenetic information requires the identification of molecules, like the recA or the gyrB genes, that are widely distributed, large enough to contain a substantial amount of information, and conserved to an appropriate degree (24, 46). In the phylogenetic tree published by Woese (43), species with the same generic name were allocated in phylogenetically distant groups. This was the case for the “genus” Pseudomonas, which is known to be a dump of assemblages of distantly related species (3, 8–10, 17). Taxonomic rearrangements of the genus Pseudomonas sensu stricto resulted in the splitting of the genus and as a logical consequence, the present genus Pseudomonas is restricted to the rRNA group I organisms, with P. aeruginosa as the type species in this group (27, 28, 37, 42, 44, 45).The oprI gene, coding for the outer membrane lipoprotein I of P. aeruginosa (5), was found to be conserved among the fluorescent pseudomonads and was considered to be a possible phylogenetic marker (6, 31). In this study, we tested whether the oprI gene could be a useful detection and identification target molecule as well as a complementary phylogenetic marker for rRNA group I pseudomonads. Also, we examined to what extent the sequence variation of the oprI gene reflects the species diversity in P. aeruginosa and P. fluorescens.