Daniel Ramón

A Comparative Study of Different Methods of Yeast Strain Characterization

Summary An extensive survey of different methods of yeast strain identification (classical microbiological tests, whole-cell protein electrophoresis, chromosomal patterns, DNA hybridization and mitochondrial DNA restriction analysis) has been carried out in order to differentiate, with industrial purposes, strains present in the Alicante wine ecosystem. Only chromosomal patterns and mitochondrial DNA (mtDNA) restriction analysis show differences between strains. Both techniques are very complex to be used in bio technological industries. For this reason, we have developed a new, simple, unexpensive and rapid method based on mtDNA restriction analysis.

Study of the authenticity of commercial wine yeast strains by molecular techniques

mtDNA restriction analysis has been carried out with 45 different commercial Saccharomyces wine yeast strains. The analysis with Hinf I provided unique profiles for 17 of the 45 strains and can therefore be considered as individual strains. Nevertheless, among the remaining 28 strains, only eight mtDNA restriction patterns appeared. These strains were subjected to electrophoretic karyotyping and PCR amplification of delta sequences. We concluded that the maximum discriminatory power was obtained when the results of the three techniques were combined, giving 13 different composite patterns for the 28 strains under study. The results showed evidence of mistakes during production or fraudulent practices by yeast producers, since only 30 individual strains have been identified among the 45 Saccharomyces wine yeast strains commercialised by different companies. Additionally, commercial starters of Saccharomyces uvarum and Saccharomyces bayanus have been re-identified as Saccharomyces cerevisiae.

Cloning and characterization of the isopenicillin N synthetase gene mediating the formation of the β-lactam ring in Aspergillus nidulans

Genomic clones containing an Aspergillus nidulans isopenicillin N synthetase (IPNS) gene have been identified by heterologous hybridization with a Cephalosporium acremonium DNA probe. The open reading frame encodes a 331 amino acid polypeptide with extensive homology with the genes of other beta-lactam-producing fungi. The gene product has been overexpressed in Escherichia coli and shown to have activity of IPNS. This represents the first evidence at the molecular level that the biosynthesis of penicillins in A. nidulans occurs by the same pathway as in other beta-lactam-producing microorganisms. Comparison of available nucleotide sequences from IPNS genes suggests a horizontal transmission of the gene between the prokaryotic beta-lactam producers of the genus Streptomyces and the filamentous fungi.

The application of molecular techniques in wine microbiology

Many winemakers use pure Saccharomyces cerevisiae cultures, sometimes isolated from their own region, to produce wine of a more reproducible quality. As most of the industrial yeast strains belong to the S. cerevisiae group, and cannot be distinguished and identified by classical microbiological methods, molecular techniques have recently been employed. Techniques such as mitochondrial DNA restriction analysis and chromosome electrophoretic analysis have been used to study the dynamics of both natural and inoculated wine fermentations. Natural fermentation is a complex process during which it is possible to observe sequential substitutions of many different S. cerevisiae strains as the process proceeds. However, in inoculated fermentations, the inoculated strain prepared from active dried yeast clearly dominates. This microbiological simplification, together with advances in biotechnology, opens the way for the genetic modification of active dried yeast and thus the construction of strains that express metabolic activities that have consistent effects on the organoleptic characteristics of the resulting wines.

Population dynamics of natural Saccharomyces strains during wine fermentation

Using mitochondrial DNA restriction endonuclease analysis, the dynamics of the natural Saccharomyces cerevisiae strains present in spontaneous wine fermentations have been studied. We observed a sequential substitution of Sacch. cerevisiae strains along fermentation agreeing with different fermentation phases. When the restriction patterns similarity (measured as the fraction of shared restriction fragments) was high, a clear sequential substitution of the strains was seen. However, when the similarity was low, although a sequential substitution could be also observed between secondary strains, a clearly predominant strain was present along the whole fermentation process.

A simplified procedure to analyse mitochondrial DNA from industrial yeasts.

A rapid method based on mtDNA restriction analysis is described for yeast strain identification. The method is an adaptation of that devised by Querol et a]. [Syst. Appl. Microbiol. 15 (1992) 439] for Saccharomyces cerevisiae wine strains, and consists of the standard miniprep isolation of yeast total DNA, and the use of restriction endonucleases that recognise a large number of sites in yeast nuclear DNA, but few sites in the mitochondrial DNA. In the adapted method, the propagation of yeast cells and restriction analysis were the steps mainly affected: cell growth was reduced to 36 h by using microfuge tubes, and the restriction analysis was carried out in just 33 min using a microwave oven for DNA digestion, and minigels for restriction fragment separation. The DNA extraction procedure was performed in the same way as in the original protocol. but slightly reducing the duration of each step and scaling down the volumes of the different solutions. enzymes and reagents used. As result, a large time reduction (52.5 h) was obtained compared to the original method. The DNA obtained can be directly digested with endonucleases displaying clear restriction patterns useful for S. cerevisiae yeast strain differentiation. In addition, strains belonging to other foodborne yeast species, including spoilage yeast species, can also be identified.

Description of Bacillus toyonensis sp. nov., a novel species of the Bacillus cereus group, and pairwise genome comparisons of the species of the group by means of ANI calculations

Strain BCT-7112(T) was isolated in 1966 in Japan from a survey designed to obtain naturally occurring microorganisms as pure cultures in the laboratory for use as probiotics in animal nutrition. This strain, which was primarily identified as Bacillus cereus var toyoi, has been in use for more than 30 years as the active ingredient of the preparation TOYOCERIN(®), an additive for use in animal nutrition (e.g. swine, poultry, cattle, rabbits and aquaculture). Despite the fact that the strain was initially classified as B. cereus, it showed significant genomic differences from the type strains of the B. cereus group that were large enough (ANI values below 92%) to allow it to be considered as a different species within the group. The polyphasic taxonomic study presented here provides sufficient discriminative parameters to classify BCT-7112(T) as a new species for which the name Bacillus toyonensis sp. nov. is proposed, with BCT-7112(T) (=CECT 876(T); =NCIMB 14858(T)) being designated as the type strain. In addition, a pairwise comparison between the available genomes of the whole B. cereus group by means of average nucleotide identity (ANI) calculations indicated that besides the eight classified species (including B. toyonensis), additional genomospecies could be detected, and most of them also had ANI values below 94%. ANI values were on the borderline of a species definition only in the cases of representatives of B. cereus versus B. thuringiensis, and B. mycoides and B. weihenstephanensis.

CreA mediates repression of the regulatory gene xlnR which controls the production of xylanolytic enzymes in Aspergillus nidulans

The Aspergillus nidulans xlnR gene encodes a Zn(2)Cys(6) transcription activator necessary for the synthesis of the main xylanolytic enzymes, i.e. endo-xylanases X(22), X(24) and X(34), and beta-xilosidase XlnD. Expression of xlnR is not sufficient for induction of genes encoding the xylanolytic complex, the presence of xylose is absolutely required. It has been established previously that the wide-domain carbon catabolite repressor CreA indirectly represses xlnA (encodes X(22)) and xlnB (encodes X(24)) genes as well as exerting direct repression on xlnA. This work provides evidence that CreA-mediated indirect repression occurs through repression of xlnR: (i) the xlnR gene promoter is repressed by glucose and this repression is abolished in creA(d)30 mutant strains and (ii) deregulated expression of xlnR completely relieves glucose repression of xlnA and xlnB. Thus, CreA and XlnR form a transcriptional cascade regulating A. nidulans xylanolytic genes.

Mycobiota and mycotoxin producing fungi from cocoa beans

The present study reports on the natural mycobiota occurring in cocoa beans, paying special attention to the incidence of fungal species that are potential producers of mycotoxins. The results show that predominant fungi were different species of the genus Aspergillus belonging to section Flavi and Nigri. Of the 214 strains of Aspergillus section Flavi collected from cocoa beans, 120 were identified as A. flavus and 94 as A. tamarii. Of Aspergillus section Nigri 138 strains were isolated, with 132 belonging to A. niger aggregate and 6 to A. carbonarius species. Potential ability to produce aflatoxins (AFs) B1, B2, G1 and G2, cyclopiazonic acid (CPA) and ochratoxin A (OTA) was studied by isolate culture followed by HPLC analysis of these mycotoxins in the culture extracts. Results indicated that 64.1% and 34.2% of the A. flavus strains produced AFs and CPA, respectively. Most of the A. flavus strains presented moderate toxigenicity with mean levels of AFs ranging from 100 ng g(-1) to 1000 ng g(-1). All the CPA-producing strains of A. flavus were highly toxigenic producing >30 microg g(-1) of CPA. Furthermore, 98% of A. tamarii strains produced CPA and over 50% of them were highly CPA toxigenic. With respect to OTA-producing fungi, a high percentage of black aspergilli strains (49.2%) were able to produce OTA. Additionally, most of the OTA-producing isolates were of moderate toxigenicity, producing amounts of OTA from 10 microg g(-1) to 100 microg g(-1). These results indicate that there is a possible risk factor posed by AFs, CPA and OTA contamination of cocoa beans, and consequently, cocoa products.

Screening of non-Saccharomyces wine yeasts for the production of β-D-xylosidase activity

Fifty-four yeast strains belonging to the genera Candida, Dekkera, Hanseniaspora, Metschnikowia, Pichia, Rhodotorula, Schizosaccharomyces and Zygosaccharomyces, mainly isolated from grapes and wines, were screened for the production of beta-D-xylosidase activity. Beta-D-xylosidase activity was only detected in eight yeast strains belonging to the genera Hanseniaspora (H. osmophila and H. uvarum) and Pichia (P. anomala). Beta-D-xylosidase preparations active against p-nitrophenyl-beta-D-xyloside were characterised with respect to their optimal pH and temperature conditions. H. uvarum 11105 and 11107 and P. anomala 10320 beta-D-xylosidase preparations were active at pH and temperature ranges and at concentrations of glucose and ethanol usually found during winemaking processes.