Phenotypic and genotypic within-host diversity of Pseudomonas aeruginosa urinary isolates.

This study aimed to assess phenotypic and molecular inter-patient and within-host diversity of Pseudomonas aeruginosa isolates responsible for urinary tract infection (UTI) or asymptomatic bacteriuria (AB). Clinical data of 120 consecutive P. aeruginosa UTI (n = 40) and AB (n = 80) were prospectively analyzed. Up to five P. aeruginosa isolates per sample were collected. Antimicrobial susceptibility testing (AST) was determined for all isolates (n = 591); a subset of 358 was characterized by multilocus sequence typing. 444 isolates (75%) were non-multidrug resistant (MDR), 113 (19%) were MDR, and 34 (6%) were extensively drug resistant. A genetically highly diverse population was observed (64 sequence types [STs]), without strict correlation between genotypes and clinical settings. 35 patients (28%; 12 UTIs and 23 ABs) presented distinct antimicrobial resistance (AMR) profiles within a given urine sample, significantly associated with previous carbapenem and fluroquinolones exposure; five of them also exhibited polyclonal UTI or AB (with isolates belonging to two STs). P. aeruginosa urinary isolates of these 120 patients were highly diverse, in terms of AMR as well as genetic background. Both within-host AMR and molecular diversity can complicate AST, treatment and control of P. aeruginosa UTI.

Monitoring Urban Beach Quality on a Summer Day: Determination of the Origin of Fecal Indicator Bacteria and Antimicrobial Resistance at Prophète Beach, Marseille (France).

A highly frequented beach in Marseille, France, was monitored on an hourly basis during a summer day in July 2018, to determine possible water and sand fecal pollution, in parallel with influx of beach users from 8 a.m. to 8 p.m. Fecal indicator bacteria were enumerated, together with four host-associated fecal molecular markers selected to discriminate human, dog, horse, or gull/seagull origins of the contamination. The antimicrobial resistance of bacteria in water and sand was evaluated by quantifying (i) the class 1, 2, and 3 integron integrase genes intI, and (ii) bla TEM, bla CTX-M, and bla SHV genes encoding endemic beta-lactamase enzymes. The number of beach users entering and leaving per hour during the observation period was manually counted. Photographs of the beach and the bathing area were taken every hour and used to count the number of persons in the water and on the sand, using a photo-interpretation method. The number of beach users increased from early morning to a peak by mid-afternoon, totaling more than 1,800, a very large number of users for such a small beach (less than 1 ha). An increase in fecal contamination in the water corresponded to the increase in beach attendance and number of bathers, with maximum numbers observed in the mid-afternoon. The human-specific fecal molecular marker HF183 indicated the contamination was of human origin. In the water, the load of Intl2 and 3 genes was lower than Intl1 but these genes were detected only during peak attendance and highest fecal contamination. The dynamics of the genes encoding B-lactamases involved in B-lactams resistance notably was linked to beach attendance and human fecal contamination. Fecal indicator bacteria, integron integrase genes intI, and genes encoding B-lactamases were detected in the sand. This study shows that bathers and beach users can be significant contributors to contamination of seawater and beach sand with bacteria of fecal origin and with bacteria carrying integron-integrase genes and beta lactamase encoding genes. High influx of users to beaches is a significant factor to be considered in order to reduce contamination and manage public health risk.

Intragenomic and intraspecific heterogeneity in rrs may surpass interspecific variability in a natural population of Veillonella.

As well as intraspecific heterogeneity, intragenomic heterogeneity between 16S rRNA gene copies has been described for a range of bacteria. Due to the wide use of 16S rRNA gene sequence analysis for taxonomy, identification and metagenomics, evaluating the extent of these heterogeneities in natural populations is an essential prerequisite. We investigated inter- and intragenomic 16S rRNA gene heterogeneity of the variable region V3 in a population of 149 clinical isolates of Veillonella spp. of human origin and in 13 type or reference Veillonella strains using PCR-temporal temperature gel electrophoresis (TTGE). 16S rRNA gene diversity was high in the studied population, as 45 different banding patterns were observed. Intragenomic heterogeneity was demonstrated for 110 (74 %) isolates and 8 (61.5 %) type or reference strains displaying two or three different gene copies. Polymorphic nucleotide positions accounted for 0.5-2.5 % of the sequence and were scattered in helices H16 and H17 of the rRNA molecule. Some of them changed the secondary structure of H17. Phylotaxonomic structure of the population based on the single-copy housekeeping gene rpoB was compared with TTGE patterns. The intragenomic V3 heterogeneity, as well as recombination events between strains or isolates of different rpoB clades, impaired the 16S rRNA-based identification for some Veillonella species. Such approaches should be conducted in other bacterial populations to optimize the interpretation of 16S rRNA gene sequences in taxonomy and/or diversity studies.

What to expect from molecular tools for non-documented pediatric infectious diseases.

OBJECTIVE: Evaluation of the contribution of molecular tools to the overall diagnosis of infectious diseases in children. METHODS: Results of 16S rDNA analysis (179 children; 228 specimens), combined to specific amplification of Kingella kingae (126 children; 166 osteoarticular specimens), were retrospectively analyzed for samples with inconclusive cultures. RESULT: The overall positive yield in diagnosis was 12.8% of the patients for 16S rDNA PCR, 40.5% for K. kingae PCR and 45.2% for combined use of both methods. Results were related to clinical and biological data (direct examination, certainty/uncertainty of clinical diagnosis, fever, biological markers, previous antibiotics), and to the number of samples analyzed per patient, allowing the identification of specific situations with significant contribution of PCR methods. CONCLUSION: Molecular techniques constitute valuable tools to improve the bacterial infection diagnosis in children; however, specific indications, dedicated samples, and number of analyzed samples per patient are key points to optimize their contribution.

Phylogeny, diversity and host specialization in the phylum Synergistetes with emphasis on strains and clones of human origin.

Members of the phylum Synergistetes have been demonstrated in several environmental ecosystems and mammalian microflorae by culture-independent methods. In the past few years, the clinical relevance of some uncultivated phylotypes has been demonstrated in endodontic infections, and uncultured Synergistetes have been demonstrated in human mouth, gut and skin microbiota. However, Synergistetes are rarely cultured from human samples, and only 17 isolates are currently reported. Twelve members of Synergistetes isolated in the course of various infectious processes, including 3 Jonquetella anthropi, 2 Cloacibacillus evryensis, 2 Pyramidobacter piscolens and 5 unidentified strains, as well as 56 clones obtained by specific PCR from the normal vaginal microflora, were studied. 16S rRNA gene-based phylogeny showed that the clones were grouped into 3 clusters, corresponding to the genus Jonquetella, P. piscolens and one novel Synergistetes taxon. The presence and diversity of Synergistetes were reported for the first time in the vaginal microflora. Synergistetes were found in healthy patients, suggesting that they could play a functional role in human microflorae, but may also act as opportunistic pathogens. Studying the phylogenetic relationships between environmental and mammalian strains and clones revealed clearly delineated independent lineages according to the origin of the sequences.

Optimized PCR-Temporal Temperature Gel Electrophoresis compared to cultivation to assess diversity of gut microbiota in neonates.

Temporal Temperature Gel Electrophoresis of amplified 16S rRNA gene sequences (16S rDNA PCR-TTGE) constitutes a culture-independent molecular method used to study bacterial communities. All the technical steps are crucial for quality and exhaustiveness of the results obtained by such approach. Careful optimization of the protocols used is ideally needed for each ecosystem studied. We present here the strategy used to construct an optimized protocol for a 16S rDNA PCR-TTGE-based analysis of gut microflora in neonates. Improvement of the different steps, i.e. total DNA extraction, amplification in terms of efficiency and reduction of heteroduplex formation, TTGE migration conditions and bacterial identification from TTGE patterns, was performed. The optimized protocol was used for the subsequent analysis of 14 stool samples comparatively to a culture-based method. We showed that a specifically designed ladder representative of the diversity of the studied microflora is a useful tool for the identification of bacterial taxa despite biases inherent to 16S rRNA genes, including intra-genomic heterogeneity. Cultivation and PCR-TTGE gave congruent results but cultivation was more efficient for the detection of minor populations whereas PCR-TTGE gave a more complete description of the major populations. Finally, we demonstrated the reliability, the detection sensitivity and the convenience of the optimized 16S rDNA PCR-TTGE method compared with cultural approaches for studying the premature neonate gut microbiota.