Adriana Pérez Chaia

Fluorescence in situ hybridization for detection of classical propionibacteria with specific 16S rRNA-targeted probes and its application to enumeration in Gruyère cheese.

The classical or dairy propionibacteria have well-documented industrial applications and have been proposed for probiotic applications. Given their industrial importance it is necessary to employ fast and reliable techniques to monitor the growth during products elaboration, industrial fermentations or the intestinal transit. Therefore, the aim of this investigation was to design oligonucleotide probes targeting the 16S rRNA of dairy propionibacteria and optimise the fluorescence in situ hybridization (FISH) protocol to detect these bacteria. Two specific probes were in silico designed to detect Propionibacterium freudenreichii and P. jensenii, named Pfr435 and Pj446 respectively. The FISH protocol was optimised for the hybridisation of propionibacteria cells with the universal probe Eub338 and the designed probes. These probes were assayed in situ for their specificity to hybridise species of propionibacteria by observation using fluorescence microscopy and results were compared with the probe Pap446 previously designed for P. acidipropionici. Probes Pap446, Pfr435 and Pj446 were also evaluated by fluorescence spectrophotometry to assess the influence of cells physiological state during growth in batch culture in the fluorescence intensity. The maximum fluorescence intensity was observed at the onset of the stationary phase of growth and was then reduced. However, changes on the cells permeability did not reduce the efficiency of 16S rRNA hybridisation with the fluorescence-labelled probes. Propionibacteria counts obtained by FISH and plate count methods were compared in a commercial Gruyère cheese. The results showed that this method can be used as a rapid technique for the enumeration of these bacteria in cheese samples.

Selection of indigenous lactic acid bacteria to reinforce the intestinal microbiota of newly hatched chicken: relevance of in vitro and ex vivo methods for strains characterization.

Based on the natural benefits of the indigenous microbiota, lactic acid bacteria (LAB) from poultry origin were isolated from hens and broilers intestine, and their probiotic potential was further studied. The tolerance to digestion, adhesion, capture of a mannose-binding lectin, absence of virulent factors and antibiotic resistances were studied. Different in vitro and ex vivo assays were performed to select tolerant and adherent strains because standardized protocols have not been defined. Fourteen strains highly tolerant to gastrointestinal digestion were genetically identified. Hydrophobic surfaces were not required for the bacterial adhesion and only nine strains adhered ex vivo to the intestinal mucosa. Three strains captured a lectin of the same specificity of Type-1 fimbriae. Virulence factors were absent but some strains evidenced multiple antibiotic resistances. These results provide bases for a future standardization of methods for the selection of probiotic strains intended to reinforce the microbiota of newly hatched chickens.

Microtechnique for identification of lactic acid bacteria.

Certain gut species are pathogens, but a number of other resident bacteria may be of some benefit to host health. Examples include enterococci, lactobacilli, propionibacteria, and bifidobacteria, which are present in the colon in significant numbers. Identification and classification are not identical. A group can be identified only after it has been classified, based on a pattern of properties shown by all the members of the group that other groups do not possess. The properties used in identification are often different from those used in classification. Biochemical, nutritional, and physiological characterization tests (usually carried out in bottles and tubes of solid and liquid media and on plates) have been developed and modified since the earliest days of bacteriology. Generally, the characteristics chosen for an identification plan should be easily determinable, whereas those used for classification (such as DNA homology) may be quite difficult to determine. Genera and species identification might not be based on only a few tests, but rather on the pattern given by a whole battery of tests. The members of the family Lactobacillaceae represent one example of this. Some probiotic strains can be selected for their benefical properties as active antimicrobial agents against pathogenic microorganisms, hydrophobic ability, presence of substances with a capacity for adherence to epithelium, and so on. After isolation, identification is an important step before selecting probiotic strains. These identifications can be facilitated through microtechniques. To alleviate the need to inoculate large numbers of tubes with media (conventional test), some rapid multitest systems have been devised and are commercially available (such as the API or Biolog systems). Although they are expensive for large studies and not always sufficiently versatile, these kits do offer the advantages of convenience, miniaturization, rapidity, and, above all, strict standardization. Other methods such as ribotyping or randomly amplified polymorphic DNA do not take into account the phenotypic characteristics (biotyping). In this chapter, we describe a simple, rapid, and economical microplates technique to identify lactic acid bacteria and enterobacteria based on general metabolic characteristics, adapted for routine study of a large number of strains.