Uncommonly isolated clinical Pseudomonas: identification and phylogenetic assignation.

Fifty-two Pseudomonas strains that were difficult to identify at the species level in the phenotypic routine characterizations employed by clinical microbiology laboratories were selected for genotypic-based analysis. Species level identifications were done initially by partial sequencing of the DNA dependent RNA polymerase sub-unit D gene (rpoD). Two other gene sequences, for the small sub-unit ribosonal RNA (16S rRNA) and for DNA gyrase sub-unit B (gyrB) were added in a multilocus sequence analysis (MLSA) study to confirm the species identifications. These sequences were analyzed with a collection of reference sequences from the type strains of 161 Pseudomonas species within an in-house multi-locus sequence analysis database. Whole-cell matrix-assisted laser-desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) analyses of these strains complemented the DNA sequenced-based phylogenetic analyses and were observed to be in accordance with the results of the sequence data. Twenty-three out of 52 strains were assigned to 12 recognized species not commonly detected in clinical specimens and 29 (56 %) were considered representatives of at least ten putative new species. Most strains were distributed within the P. fluorescens and P. aeruginosa lineages. The value of rpoD sequences in species-level identifications for Pseudomonas is emphasized. The correct species identifications of clinical strains is essential for establishing the intrinsic antibiotic resistance patterns and improved treatment plans.

Respiratory infection by Corynebacterium striatum: epidemiological and clinical determinants.

The increasing prevalence of advanced chronic respiratory disease, with frequent exposure to broad-spectrum antibiotics for repeated and prolonged hospitalizations, favours the emergence of nosocomial respiratory infection by Gram-positive bacteria, such as outbreaks of Corynebacterium striatum. There is little evidence about patterns of respiratory infection, transmission and adaptive ability of this pathogen. Seventy-two C. striatum isolates from 51 advanced respiratory patients, mainly chronic obstructive pulmonary disease, were studied during 38 months. Patients were 74.8 ± 8.6 years old and 81.9% were men, who had required an average of 2.2 hospitalizations and 63.5 days in the hospital in the previous year. Of 49 isolates from 42 patients we were able to identify 12 clones by multilocus sequence analysis (MLSA), nine phenotypic variants and 22 antibiotic susceptibility patterns, and we determined their clinical and epidemiological determinants. MLSA allows identification of the existence of nosocomial outbreaks by transmission of the same or different clones, the persistence of the same clone in the environment or in patient airways for months. The study showed the high variability and adaptive capacity of the isolates, the antibiotic multidrug-resistance in all of them, and their contribution to a high morbidity and mortality (41%) during the study period.

Identification and genomovar assignation of clinical strains of Pseudomonas stutzeri.

The identification of Pseudomonas stutzeri clinical isolates through conventional phenotypic methods was compared with identification through partial rpoD gene sequencing. We observed that commercial phenotypic systems easily confuse P. stutzeri with other Pseudomonas species. We also demonstrated that most of the clinical strains of P. stutzeri herein studied (79%) belonged to genomovar 1 of the species. We propose the use of partial rpoD gene sequence analysis as a complementary molecular tool for the precise routine identification and genomovar assignation of P. stutzeri clinical isolates, as well as for typing and epidemiological studies.

Taxonomic characterisation of ceftazidime-resistant Brevundimonas isolates and description of Brevundimonas faecalis sp. nov.

Three ceftazidime-resistant strains isolated from the sewage water of a municipal hospital in Palma de Mallorca, Spain, were analysed phenotypically and genotypically to clarify their taxonomic positions. Sequence determinations and phylogenetic analyses of the 16S rRNA genes indicated that strains CS20.3(T), CS39 and CS41 were affiliated with the species of the alphaproteobacterial genus Brevundimonas, most closely related to B. bullata, B. diminuta, B. naejangsanensis and B. terrae. Additional sequences analyses of the ITS1 region of the rRNA operon and the genes for the housekeeping enzymes DNA gyrase ß-subunit and RNA polymerase ß-subunit, genomic DNA-DNA hybridisation similarities, cell fatty acid profiles and physiological and biochemical characterizations supported the recognition of CS20.3(T) (CCUG 58127(T)=CECT 7729(T)) as a distinct and novel species, for which the name Brevundimonas faecalis sp. nov. is proposed. Strains CS39 and CS41 were ascribed to the species B. diminuta.

A molecular microbial ecology approach to studying hemodialysis water and fluid.

Bacteria, or bacteria-derived products, might be responsible for deleterious effects in hemodialysis patients. Most microorganisms in hemodialysis water, including potential pathogens, are difficult to isolate and might subsist in a 'viable but not culturable' state or may need specific culture media. A molecular culture-independent approach based on the analysis of the 16S rDNA obtained from total DNA has been used to better know the diversity of bacteria inhabiting hemodialysis water and fluid, and to address the possible health effects associated with their presence. Four clone libraries from 16S rDNA (274 clones) were analyzed to characterize the species or groups of bacteria present, to assess their distribution in the water circuit, and to compare the results with those previously obtained in culture-dependent analysis. One hundred and ninety-seven clones of four gene libraries were analyzed by sequencing, and were identified phylogenetically. Clones affiliated to the Alphaproteobacteria group led the diversity. The presence in several samples of Alpha-4-proteobacteria, recognized as sphingolipids producers, was to be noted. The most abundant clones were affiliated to the Betaproteobacteria branch, closely related to the genus Herbaspirillum. As known, Alphaproteobacteria and Betaproteobacteria genomes might present a manifest excess in CpG sequences and most of them show a lipopolysaccharide-rich outer membrane, both described as inducers of innate immunity responses. Another abundant group, belonging to the Cyanobacteria class, a possible source of cyanotoxins, was not related to any previously cultured bacterium. Possible risk implications for hemodialysis patients of the bacterial community detected are discussed.