Phenotypic and molecular methods used for identification of oral streptococci and related microorganisms.

The oral cavity contains the greatest biodiversity, over 70 species being isolated from mouth mucosa, saliva, denture surfaces and/or dental-plaque. The oral streptococci, representing over 80% of the mouth micro flora, are able to synthesize glucosyl-transferases, enzymes involved in glucans production. Glucans are involved in production of an extracellular slime layer promoting adhesion and formation of a dental plaque biofilm. The 43 isolates studied obtained from partially and/or totally edentulous, were identified by VITEK system using gram-positive identification cards. Species-specific regions within the genes coding for glucosyl-transferases (gtf genes) were targeted for PCR identification of isolates. Sequencing of 16S rRNA was used as gold standard for strain confirmation. VITEK system identified a number of 11 strains as S. mitis/oralis, 12 strains as S. anginosus/gordonii, 12 strains as S. sanguinis/parasanguinis, 3 strains as S. salivarius, 3 strains as S. plurianimalium, 1 strain as S. cristatus and 1 strain as S. alactolyticus, respectively. The PCR system targeting gtf genes was able to identify S. oralis, S. salivarius and S. gordonii strains. Sequence of 16S rRNA discriminated among streptococci species and revealed 16 strains of Leuconostoc mesenteroides. Many studies are needed in order to select the most reliable phenotypic and genotypic methods in order to improve the identification algorithm for oral streptococci used by clinical laboratories. Their accurate identification is mandatory for better understanding their role in human infections.

[Bacterial enteric pathogens' resistance to fluoroquinolones and last generation cephalosporines]. / Rezistenta patogenilor enterici bacterieni la fluoroquinolone si cefalosporine de ultima generatie.

The increase of incidence of resistance to the antibiotics became the most worrisome subject within the clinical and research communities in the medical fields. Intrinsic resistance genetic mutations, horizontal transfer of mobile structures carrying genes coding for resistance to the antibiotics within the pan-microbial genome are representing the bacterial resistome which is bearing the genetic information regarding the defensive mechanisms developed by micro-organisms to protect themselves against antibiotics. Rice in the resistance of enteric bacteria, pathogens involved in a large number of human infections, to the cephalosporin of last generation and to the fluoroquinolones is a very actual subject in the medical area. Production of beta-lactamases with extended spectrum is the most important enzymatic defence system, developed by micro-organisms, consisting in the inactivation of beta-lactam antibiotics by destroying the beta-lactam ring. Enterobacteria are able to produce beta-lactamases of type TEM, SHV and/or CTX-M. Punctual mutations in nucleotide structure of bla genes, coding for beta-lactamases synthesis, are leading on production of a large diversity of enzymes with enlarged spectrum of activity (ESBL). At the beginning of 90's the first beta-lactamases resistance to clavulanic acid were detected and in our days more then 170 TEM, 120 SVH and 90 CTX-MESBLs are known. Escherichia coli strains are producing, firstly, TEM ESBLs, Klebsiella pneumoniae SHV ESBLs. and both are producing CTX-M type ESBLs, are resistant to the fluoroquinolones due to punctual mutations in nucleotide structure of gyr gene coding for gyrases production, enzymes involved in nucleic acids replication. Resistance to the antibiotics with extended activity is a public health threat due to their capacity of large spreading within bacterial population, when the coding structures are located on mobile genetic structures. The menace increase when genes coding for fluoroquinolones resistance (qnr) are identified on such of structures.

A multiple typing approach is recommended for the laboratory-based surveillance of salmonellosis in Romania.

In Romania, Salmonella enterica serovar Typhimurium isolates are currently typed by antimicrobial resistance profiles and phage typing, as part of the national laboratory-based surveillance system of human enteric infections. The aim of the present study was to assess the added value of complementing this approach with molecular fingerprinting, namely pulsed-field gel electrophoresis (PFGE) and multiple-locus variable-number tandem-repeats analysis (MLVA). Thirty-six S. Typhimurium isolates received by the Reference Center for Human Salmonella Infections for confirmation and typing from the Microbiology Departments of three Public Health Authorities, were selected for this study. Phage typing revealed that 14 isolates (39%) were nontypeable (NT). Twenty-two isolates were assigned to 5 phage types: DT193 (11 isolates), U302 (7 isolates), DT116 (2 isolates), DT41 (1 isolate) and DT86 (1 isolate). Antimicrobial susceptibility testing showed that all the NT and DT116 isolates were multidrug resistant and extended-spectrum betalactamase producers. All the examined isolates were typeable when using the molecular approach. Both methods gave conclusive and comparable results, documenting the genetic relatedness and discriminating the outbreak isolates from sporadic cases. We conclude that in order to improve outbreak investigation and surveillance of salmonellosis in Romania, the current routine typing of Salmonella isolates should be complemented with at least one of these DNA fingerprinting methods.