Application of whole genome amplification and quantitative PCR for detection and quantification of spoilage yeasts in orange juice.

Small cell numbers in complex food matrices and undefined PCR inhibitors often limit detection and identification of DNA species by molecular techniques. Thus in many industrial situations enrichment growths are performed. However, growth speed of different species in complex microbial mixtures in defined media is in most cases different, thus final results do not always reflect the starting situation. We tested DNA-strand displacement whole genome amplification as a possible substitute of enrichment growth. Using whole genome amplification on orange juice contaminated with Saccharomyces cerevisiae, we lowered detection level from 10(6) down to 10(2) cfu/ml. Whole genome amplification showed to be linear (R=0.992) and the relative yeast DNA copy number compared to other DNA templates did not change thus allowing quantitative estimation of initial contamination by quantitative PCR. Using melting point analysis, we were able to distinguish between the PCR products of the 5.8S-ITS region, obtained with universal primers from pure cultures of S. cerevisiae and Hanseniaspora uvarum, two major spoilage yeasts in orange juice and forming part of wine microbiota during fermentation. However, in mixed-contaminated samples, identification of both species was hampered by preferential appearance of the melting peak coinciding with H. uvarum, except when S. cerevisiae was the dominating species. Application of whole genome amplification did not prevent the preferential detection of H. uvarum. This handicap was resolved by applying an enrichment procedure up to saturation after which the melting peak of both species could clearly be identified.

Debaryomyces singareniensis sp. nov., a novel yeast species isolated from a coal mine soil in India.

Three strains (AP19, AP19-4 and AP19-6) of a novel yeast species were isolated from soil from the Singareni coal mines, Andhra Pradesh, India. They were morphologically, physiologically and phylogenetically identical and produced one to four spherical ascospores per ascus. Phylogenetic analysis using the D1/D2 variable domain of the large-subunit rRNA gene indicated that the closest relative of these strains is Debaryomyces etchellsii (2.6% divergence). Other species related to these strains are D. mycophilus (5.1% divergence) and species of the D. hansenii cluster (4.9-5.6% divergence). The novel species differs by 20 and 15 physiological tests from D. etchellsii and D. mycophilus, respectively. Phylogenetic analysis of the internal transcribed spacer (ITS) region also indicated that strains of the new species are related to D. etchellsii (7.7% divergence), followed by species of the D. hansenii cluster (9-10% divergence). In the small-subunit rRNA gene sequences, they differed from D. etchellsii by seven substitutions and one insertion or deletion of a base in a sequence (indel) and from D. mycophilus by 17 substitutions and 1 indel. The physiological, biochemical and molecular data suggest that these strains belong to a novel species, for which we propose the name Debaryomyces singareniensis sp. nov. The type strain of AP19(T) (=MTCC 7061(T)=CBS 10405(T)). The Mycobank number of the new species is MB510046.

Yeast species associated with the spontaneous fermentation of cider.

This paper reports the influence of cider-making technology (pneumatic and traditional pressing) on the dynamics of wild yeast populations. Yeast colonies isolated from apple juice before and throughout fermentation at a cider cellar of Asturias (Spain), during two consecutive years were studied. The yeast strains were identified by restriction fragment length polymorphism analysis of the 5.8S rRNA gene and the two flanking internal transcribed sequences (ITS). The musts obtained by pneumatic pressing were dominated by non-Saccharomyces yeasts (Hanseniaspora genus and Metschnikowia pulcherrima) whereas in the apple juices obtained by traditional pressing Saccharomyces together with non-Saccharomyces, were always present. The species Saccharomyces present were S. cerevisiae and S. bayanus. Apparently S. bayanus, was the predominant species at the beginning and the middle fermentation steps of the fermentation process, reaching a percentage of isolation between 33% and 41%, whereas S. cerevisiae took over the process in the final stages of fermentation. During the 2001 harvest, with independence of cider-making technology, the species Hanseniaspora valbyensis was always isolated at the end of fermentations.