Rapid identification of Zygosaccharomyces with genus-specific primers.

There has been a recent and rapid increase in the number of species of the genus Zygosaccharomyces which now comprises Z. bailii, Z. bisporus, Z. gambellarensis, Z. kombuchaensis, Z. lentus, Z. machadoi, Z. mellis, Z. parabaillii, Z. pseudobailii, Z. pseudorouxii, Z. rouxii, Z. sapae, and Z. siamensis. Z. pseudorouxii is an unofficial name given to isolates closely related to the newly-described species Z. sapae. The Zygosaccharomyces genus contains species that are important as food and beverage spoilage organisms and others are associated with fermentations and sweet foodstuffs, such as honey. Their economic significance means that the ability to identify them rapidly is of significant importance. Although Z. rouxii and Z. bailii have been genome-sequenced the extent of sequence data for the others, especially the newly-discovered species, is sometimes extremely limited which makes identification slow. However, parts of the ITS1/5.8S/ITS2 rDNA region contain sequences of sufficient similarity within the genus and of sufficient difference with outgroups, to be potential regions for the design of genus-wide specific primers. We report here the development of genus-specific primers that can detect all the major Zygosaccharomyces species including all those associated with foods; the rare and localised species Z. machadoi and Z. gambellarensis are not detected. The size of the single amplicon produced varies between species and in some cases is sufficiently different to assign provisional species identification. Sequence data from rDNA regions are available for virtually all described yeast species in all genera, thus, prior to having sufficient sequence data from structural genes, rDNA regions may provide more generally suitable candidates for both genus-specific and species-specific primer design.

Synteny analysis provides a route to design genus-specific PCR primers for rapid identification of all Saccharomyces species.

The genus Saccharomyces comprises seven single-genome species (S. arboricola, S. cerevisiae, S. eubayanus, S. kudriavzevii, S. mikatae, S. paradoxus and S. uvarum) and two hybrid species - S. pastorianus (S. cerevisiae plus S. eubayanus) and S. bayanus (mostly S. uvarum plus S. eubayanus). Species-specific primers have already been developed for the identification of each of the single-genome species, and these primers can usually detect both genomes in hybrids. It would be advantageous if a single reaction could detect any member of the clade. We have investigated three potentially generic approaches to design genus-specific primers. Two methods that both use sequence alignment differences for primer design were only partly successful. A third method used synteny data to identify 136 target genes that are potentially present only in all species of the Saccharomyces clade. HSP30 (YCR021C) was fully successful; different primer pairs were developed with high G+C content for use at 63 °C. In < 3 h, using a robust colony-PCR followed by gel electrophoresis, the method can reliably detect any member of the genus. This novel approach still uses conventional sequence alignment mismatches but relies principally on the presence of the target gene only within the genus Saccharomyces.

Rapid identification of Saccharomyces eubayanus and its hybrids.

The Saccharomyces species Saccharomyces eubayanus was recently discovered in Patagonia. Genomic, genetic and phylogenetic data all suggest that it is one of the two parents of the hybrid yeast S. pastorianus (S. cerevisiae being the other). Saccharomyces eubayanus genomes can also be found in strains of the hybrid species S. bayanus. Here, we describe a novel pair of PCR primers targeted against the S. eubayanus FSY1 gene that will specifically detect S. eubayanus and hybrids containing this allele of the gene. The primer pair can be used to identify the species using a rapid, inexpensive colony PCR method suitable for a preliminary identification of wild isolates.

A multiplex set of species-specific primers for rapid identification of members of the genus Saccharomyces.

The Saccharomyces genus (previously Saccharomyces sensu stricto) formally comprises Saccharomyces arboricola, Saccharomyces bayanus, Saccharomyces cariocanus, Saccharomyces cerevisiae, Saccharomyces kudriavzevii, Saccharomyces mikatae, Saccharomyces paradoxus and Saccharomyces pastorianus. Species-specific primer pairs that produce a single band of known and different product size have been developed for each member of the clade with the exception of S. pastorianus, which is a polyphyletic allopolyploid hybrid only found in lager breweries, and for which signature sequences could not be reliably created. Saccharomyces cariocanus is now regarded as an American variant of S. paradoxus, and accordingly a single primer pair that recognizes both species was developed. A different orthologous and essential housekeeping gene was used to detect each species, potentially avoiding competition between PCR primers and overlap between amplicons. In multiplex format, two or more different species could be identified in a single reaction; double and triple hybrids could not always be correctly identified. Forty-two unidentified yeasts from sugar cane juice fermentations were correctly identified as S. cerevisiae. A colony PCR method was developed that is rapid, robust, inexpensive and capable of automation, requires no mycological expertise on the part of the user and is thus useful for large-scale preliminary screens.

Species-specific PCR primers for the rapid identification of yeasts of the genus Zygosaccharomyces.

Species-specific primer pairs that produce a single band of known product size have been developed for members of the Zygosaccharomyces clade including Zygosaccharomyces bailii, Zygosaccharomyces bisporus, Zygosaccharomyces kombuchaensis, Zygosaccharomyces lentus, Zygosaccharomyces machadoi, Zygosaccharomyces mellis and Zygosaccharomyces rouxii. An existing primer pair for the provisional new species Zygosaccharomyces pseudorouxii has been confirmed as specific. The HIS3 gene, encoding imidazole-glycerolphosphate dehydratase, was used as the target gene. This housekeeping gene evolves slowly and is thus well conserved among different isolates, but shows a significant number of base pair changes between even closely related species, sufficient for species-specific primer design. The primers were tested on type and wild strains of the genus Zygosaccharomyces and on members of the Saccharomycetaceae. Sequencing of the D1/D2 region of rDNA was used to confirm the identification of all nonculture collection isolates. This approach used extracted genomic DNA, but in practice, it can be used efficiently with a rapid colony PCR protocol. The method also successfully detected known and new hybrid strains of Z. rouxii and Z. pseudorouxii. The method is rapid, robust and inexpensive. It requires little expertise by the user and is thus useful for preliminary, large-scale screens.

Detection of Candida albicans DNA from blood samples using a novel electrochemical assay.

The genus Candida contains a number of yeast species which are opportunistic pathogens and are associated with life-threatening infections in immunocompromised individuals. Provision of appropriate therapy relies on the rapid identification of the infecting species, and existing methods of identifying Candida species in clinical samples are time and resource intensive and are not always specific enough to differentiate between drug-susceptible and drug-resistant species. We have previously developed a system for the rapid detection of yeast pathogens in clinical samples using PCR followed by hybridization with a suite of five species-specific, electrochemically labelled DNA probes. The limit of detection of the assay was shown to be 37 fg (∼1 genome) per reaction using extracted genomic DNA. We carried out a study to test the limit of detection of one of the probes, CA PR3, using blood samples from a healthy donor that were spiked with genomic DNA or with C. albicans cells. Our results demonstrated a limit of detection of 37 fg (ml blood)(-1) (∼1 genome ml(-1)) using extracted DNA or 10 c.f.u. (ml blood)(-1) using C. albicans cells, indicating that the assay is capable of detecting C. albicans nucleic acid at levels that are encountered in clinical samples.

Rapid electrochemical identification of pathogenic Candida species.

This study describes the development of a novel assay to detect fungal DNA and identify the most clinically relevant invasive human pathogenic fungi to the species level using oligonucleotide probes, labelled with electrochemically active groups, and solid-state electrodes. A panfungal probe designed against the 18S rRNA gene region, capable of detecting all fungal pathogens tested, and species-specific probes, designed against the ITS2 region for detection of the five Candida species most commonly encountered in the clinical setting (Candida albicans, Candida glabrata, Candida parapsilosis species complex, Candida krusei and Candida tropicalis), are described. When tested with PCR-amplified DNA from both type and clinical strains of the relevant species, the probes were able to positively identify the relevant fungi, indicated by production of a current significantly elevated above the background reading. No cross-reactivity was observed with any of the species-specific probes when compared with nine non-target Candida species or in the presence of human DNA equivalent to an equal number of ITS2 targets. The panfungal probe gave results that were similarly positive against 15 other fungal species and also did not cross-react with human DNA. The limit of detection of the assay was shown to be approximately 1 genome equivalent for all probes using extracted genomic DNA.

Ser/Thr-rich domains are associated with genetic variation and morphogenesis in Saccharomyces cerevisiae.

Proteins containing regions of amino acid bias are often found in eukaryotes and are associated with particular functional groups. We have carried out a genomic analysis of yeast proteins containing regions with a significant bias of Ser and Thr residues. Our findings reveal that a high number are cell surface proteins or regulatory proteins involved in many aspects of cell differentiation. Furthermore, in Saccharomyces-related species, a highly significant correlation exists between the frequency of Ser-rich regions and DNA repeats, indicating that their generation may rely on similar factors. Cluster analysis shows that Ser/Thr-rich regions, located within the tandem repeats of cell surface proteins, are encoded to an increased frequency by UCU (Ser) and ACU/ACC (Thr), implying that mutational events that generate iterations could involve these codons. Replication slippage is proposed to be a contributing factor, as mounting evidence suggests that repeat generation in cell surface proteins can occur independently of meiosis. To reinforce this argument, we have discovered a premeiotic association between Mre11p, a nuclease involved in DNA repair, and ORFs encoding Ser/Thr-rich regions. Several macromolecules involved in the glycosylation and phosphorylation of proteins require Ser and Thr residues as binding sites. Ser/Thr-rich regions, through polymorphisms, are associated with the evolution of functional sites, particularly in providing motifs for glycosylation and phosphorylation. These results point to a Ser/Thr-biased somatic mutation mechanism that contributes to rapid evolution in yeast.

Evidence that protein length expansion and contraction is partly due to mutational events in premeiotic cells.

Studies on the rate of evolution of proteins typically concentrate on rates of change of orthologous amino acids rather than on changes in size (i.e., generation of nonorthologous domains). Recent work has focused attention on Ser/Thr-rich regions in yeast as these tend to undergo size changes rapidly, with size polymorphisms commonly being found, especially in proteins with cell-surface localization. The underlying mechanism generating the indels is presently unclear though, due to a lack of correlation with the location of meiotic double-strand breaks, it has, by exclusion, been conjectured to be replication slippage. Here we provide new evidence to support this possibility. Notably, we show that Ser/Thr-rich repeat regions are more generally associated with the location of Mre11p in premeiotic cells. This is to be expected if the repeats were produced by mutational events in mitotic cells possibly through replication slippage.

Patterns of polymorphism and divergence in stress-related yeast proteins.

Yeast genomes contain variable number tandem repeats (VNTRs) within coding regions of DNA. A significant number of these genes are involved in cell rescue, defence and virulence and are regulated by genetic elements associated with stress. Alleles that encode variable length, single amino acid tracts, are mainly associated with transcription and proteins localized within the nucleus. Alleles that encode proteins containing oligopeptide repeats or minisatellites are over-represented in cell wall and extracellular space locations. Functional analysis of the latter group reveals that these proteins are involved in biogenesis of cellular components and in interaction with the cellular environment, especially in relation to stress resistance, heat shock response, temperature perception and adhesion. A significantly high number of these proteins have regions rich in threonine and/or serine that contain repeated sequences, variable in length within yeast species. DNA sequences encoding serine- and/or threonine-rich regions give rise to polymorphic alleles and therefore may confer a selective advantage to cells. We propose that these regions are the focus of mutational and recombination events that, when coupled with directed selection, may contribute to genetic variation within stress-related genes.

Conidial anastomosis tubes in filamentous fungi.

Conidial anastomosis tubes (CATs) can be recognized in 73 species of filamentous fungi covering 21 genera, and develop in culture and in host-pathogen systems. They have been shown to be morphologically and physiologically distinct from germ tubes in Colletotrichum and Neurospora, and under separate genetic control in Neurospora. CATs are short, thin, usually unbranched and arise from conidia or germ tubes. Their formation is conidium-density dependent, and CATs grow towards each other. MAP kinase mutants of Neurospora are blocked in CAT induction. Nuclei pass through fused CATs and are potential agents of gene exchange between individuals of the same and different species. CAT fusion may also serve to improve the chances of colony establishment.

Conidial anastomosis fusion between Colletotrichum species.

Colletotrichum lindemuthianum is a pathogen of the common bean plant (Phaseolus vulgaris) causing anthracnose. Large numbers of isolates can rapidly arise with different genetic and chromosomal compositions but their origin is unknown since sexual fruit bodies have only been found in the laboratory. We have recently described the occurrence of special kinds of hyphae that create anastomoses directly between conidia. In this work we show that conidial anastomoses can occur between two different Colletotrichum species. The implications of this observation on the generation of genetic diversity in these species are discussed.

The microbiology of cocoa fermentation and its role in chocolate quality.

The first stage of chocolate production consists of a natural, seven-day microbial fermentation of the pectinaceous pulp surrounding beans of the tree Theobroma cacao. There is a microbial succession of a wide range of yeasts, lactic-acid, and acetic-acid bacteria during which high temperatures of up to 50 degrees C and microbial products, such as ethanol, lactic acid, and acetic acid, kill the beans and cause production of flavor precursors. Over-fermentation leads to a rise in bacilli and filamentous fungi that can cause off-flavors. The physiological roles of the predominant micro-organisms are now reasonably well understood and the crucial importance of a well-ordered microbial succession in cocoa aroma has been established. It has been possible to use a synthetic microbial cocktail inoculum of just 5 species, including members of the 3 principal groups, to mimic the natural fermentation process and yield good quality chocolate. Reduction of the amount of pectin by physical or mechanical means can also lead to an improved fermentation in reduced time and the juice can be used as a high-value byproduct. To improve the quality of the processed beans, more research is needed on pectinase production by yeasts, better depulping, fermenter design, and the use of starter cultures.

Incorporation of Sed1p into the cell wall of Saccharomyces cerevisiae involves KRE6.

KRE6 (YPR159W) encodes a Golgi membrane protein required for normal beta-1,6-glucan levels in the cell wall. A functional Kre6p is necessary for cell wall protein accumulation in response to changing metabolic conditions. The product of the SED1 (YDR077W) gene is a stress-induced GPI-cell wall protein. Successful incorporation of HA-tagged Sed1p into the cell wall involves KRE6. The double-mutant sed1 kre6 has a reduced growth rate, increased flocculation and increased sensitivity to Zymolyase. A similar phenotype is found in mutants defective in glycosyl-phosphatidyl-insositol (GPI) anchor assembly. These findings support the theory that Kre6p could function as a transglucosylase that allows the incorporation of proteins with a GPI anchor into the cell wall.

Conidial anastomosis tubes in Colletotrichum.

We describe the occurrence of special kinds of hyphae that create anastomoses directly between conidia. They can be found both in the laboratory and on infected plants. They first appear within asexual fruiting bodies approximately 15 days after conidiation has begun leading to the appearance of chains of connected conidia. Coincident with this we demonstrate in Colletotrichum lindemuthianum nuclear dynamics, including fragmentation, with cytoplasmic flow and passage of nuclei and organelles between conidia through the anastomosis tubes. We propose that conidial anastomosis tubes play an important role in the life cycle of these fungi.

Acquisition of flocculation phenotype by Kluyveromyces marxianus when overexpressing GAP1 gene encoding an isoform of glyceraldehyde-3-phosphate dehydrogenase.

The use of flocculating yeast strains has been considered as a convenient approach to obtain high cell densities in bioreactors with increasing productivity in continuous operations. In Kluyveromyces marxianus ATTC 10022, the GAP1 gene encodes an isoform of glyceraldehyde-3-phosphate dehydrogenase-p37-that is accumulated in the cell wall and is involved in flocculation. To test the use of p37 as a tool for engineering Kluyveromyces cells to display a flocculation phenotype, K. marxianus CCT 3172 was transformed with an expression vector containing GAP1. This vector is based on the pY37 previously described, harbouring a S11 Kluyveromyces origin of replication, and the expression of GAP1 is under the control of GAL1. Kluyveromyces cells overexpressing GAP1 acquired a flocculent phenotype together with the accumulation of p37 in the cell wall. The results support the use of GAP1 gene as a molecular tool for inducing flocculation.

Toxigenic fungi associated with processed (green) coffee beans (Coffea arabica L.).

Processed (green) coffee beans from Coffea arabica in Brazil were assessed for the presence of Aspergillus and Penicillium species both before and after surface sterilisation, the aflatoxigenic and ochratoxigenic potential of the isolates and ochratoxin A levels. Contamination by Aspergillus and Penicillium species was found on 96% and 42%, respectively, of 45 samples from 11 localities. After disinfection with 1% sodium hypochlorite, the levels fell to 47% and 24%, respectively. One hundred and eighty isolates were identified to species level and comprised Aspergillus sections Circumdati (10 species), Flavi (3), Nigri (3), Versicolores (4), while two were teleomorphic species. Eight species of Penicillium were isolated. Within section Circumdati, 75% of the isolates produced ochratoxin A and all except Aspergillus elegans and Aspergillus insulicola have previously been reported to produce ochratoxin A. One-third of the 18 isolates of Aspergillus flavus produced aflatoxin B1 and B2. None of the isolates belonging to Aspergillus section Nigri or Penicillium produced ochratoxin A. Of the 40 bean samples analysed, 58% were infected with potentially ochratoxigenic fungi but only 22% of these were contaminated with ochratoxin A at levels that varied from 0.47 to 4.82 ng/g, with an average contamination level of 2.45 ng/g.

Template preparation for rapid PCR in Colletotrichum lindemuthianum

Isolation of DNA for PCR is time-consuming and involves many reagents. The aim of this work was to optimise a rapid and easy PCR methodology without previous DNA isolation. Different strains of the phytopathogenic fungus Colletotrichum lindemuthianum were used. Protoplasts were generated using lytic enzymes under high incubation temperatures using different methodologies to obtain the template. A rapid (10 minute) methodology was successful for smaller amplicons (<750 bp).

SED1 gene length and sequence polymorphisms in feral strains of Saccharomyces cerevisiae.

The SED1 gene (YDR077W), coding for the major cell wall glycoprotein of Saccharomyces cerevisiae stationary-phase cells, contains two blocks of tandem repeat units located within two distinct regions of the nucleotide sequence. A PCR survey of the SED1 open reading frames (ORFs) of 186 previously uncharacterized grape must isolates of S. cerevisiae yielded 13 PCR profiles arising from different combinations of seven SED1 length variants in individuals homozygous or heterozygous for the gene. Comparison of the nucleotide sequences of a group of representatives of each of the seven length variants with those of S288C and the type strain, CBS1171, unequivocally identified them as SED1 alleles and provided evidence for the presence of two minisatellite-like sequences, variable in length, within the ORF of an S. cerevisiae gene. The segregation analyses of the SED1 length variants and other genetic markers in 13 isolates representative of each PCR profile suggested that molecular mechanisms involved in minisatellite expansion and contraction may be responsible for SED1 heterozygosities within a population of homothallic must isolates of S. cerevisiae.

Disruption of six Saccharomyces cerevisiae ORFs on chromosome XII results in three lethal disruptants.

Six ORFs of unknown function from the left arm of chromosome XII of Saccharomyces cerevisiae were chosen for a reverse genetic approach to provide materials to assist in assignment of function. A two-step PCR using long-flanking homology was employed to amplify disruption cassettes consisting of a kanMX gene as selectable marker flanked by 250-350 bp long regions homologous to the target gene. The diploid strains FY1679 and CEN.PK2 were transformed with the replacement cassettes and transformants were selected for geneticin (G418) resistance. Correct targeting of the replacement cassettes at the genomic locus was verified by Southern blot analysis with the kanMX gene as a probe. Disruption cassettes were cloned in pUG7 plasmid for systematic gene inactivation in other yeast strains and the cognate genes were cloned in pRS416 plasmid for gene complementation studies. Sporulation and tetrad analysis of heterozygous disruptants showed that three of the six ORFs [YLR141w (RRN5), YLR145w and YLR147c (SMD3)] were essential genes that were complemented by their cognate genes. ylr146c Delta (spe4) homozygous diploids showed enhanced sporulation efficiency, whereas ylr147c Delta heterozygous diploids failed to sporulate in the FY1679 but not in the CEN.PK2 genetic background. The other two disruptants [ylr143w and ylr144c (acf2)] gave no phenotype.