Characterization and technological properties of Oenococcus oeni strains from wine spontaneous malolactic fermentations: a framework for selection of new starter cultures

Aims:  To characterize the genetic and phenotypic diversity of 135 lactic acid bacteria (LAB) strains isolated from Italian wines that undergone spontaneous malolactic fermentation (MLF) and propose a multiphasic selection of new Oenococcus oeni malolactic starters.
Methods and Results:  One hundred and thirty-five LAB strains were isolated from 12 different wines. On the basis of 16S amplified ribosomal DNA restriction analysis (ARDRA) with three restriction enzymes and 16S rRNA gene sequencing, 120 O. oeni strains were identified. M13-based RAPD analysis was employed to investigate the molecular diversity of O. oeni population. Technological properties of different O. oeni genotypes were evaluated in synthetic medium at increasing selective pressure, such as low pH (3·5, 3·2 and 3·0) and high ethanol values (10, 11 and 13% v/v). Finally, the malolactic activity of one selected strain was assessed in wine by malolactic trial in winery.
Conclusions:  The research explores the genomic diversity of wine bacteria in Italian wines and characterizes their malolactic metabolism, providing an efficient strategy to select O. oeni strains with desirable malolactic performances and able to survive in conditions simulating the harsh wine environment.
Significance and Impact of the Study:  This article contributes to a better understanding of microbial diversity of O. oeni population in Italian wines and reports a framework to select new potentially O. oeni starters from Italian wines during MLF.     

Genomic diversity of Oenococcus oeni from different winemaking regions of Portugal

Oenococcus oeni is an alcohol-tolerant, acidophilic lactic acid bacterium that plays an important role in the elaboration of wine. It is often added as a starter culture to carry out malolactic conversion. Given the economic importance of this reaction, the taxonomic structure of this species has been studied in detail. In the present work, phenotypic and molecular approaches were used to identify 121 lactic acid bacteria strains isolated from the wines of three winemaking regions of Portugal. The strains were differentiated at the genomic level by M13-PCR fingerprinting. Twenty-seven genomic clusters represented by two or more isolates and 21 single-member clusters, based on an 85% similarity level, were recognized by hierarchic numerical analysis. M13-PCR fingerprinting patterns revealed a high level of intraspecific genomic diversity in O. oeni. Moreover, this diversity could be partitioned according to the geographical origin of the isolates. Thus, M13-PCR fingerprint analysis may be an appropriate methodology to study the O. oeni ecology of wine during malolactic fermentation as well as to trace new malolactic starter cultures and evaluate their dominance over the native microbiota.     

Intraspecific genetic diversity of Oenococcus oeni as derived from DNA fingerprinting and sequence analyses.

The intraspecific genetic diversity of Oenococcus oeni, the key organism in the malolactic fermentation of wine, has been evaluated by random amplified polymorphic DNA (RAPD), ribotyping, small-plasmid content, and sequencing of RAPD markers with widespread distribution among the strains. Collection strains representing the diversity of this species have been studied together with some new isolates, many of which were obtained from wines produced by spontaneous malolactic fermentation. The RAPD profiles were strain specific and discerned two main groups of strains coincident with clusters obtained by macrorestriction typing in a previous work. Ribotyping and the conservation of RAPD markers indicates that O. oeni is a relatively homogeneous species. Furthermore, identical DNA sequences of some RAPD markers among strains representative of the most divergent RAPD clusters indicates that O. oeni is indeed a phylogenetically tight group, probably corresponding to a single clone, or clonal line of descent, specialized to grow in the wine environment and universally spread.     

Allelic diversity and population structure in Oenococcus oeni as determined from sequence analysis of housekeeping genes

Oenococcus oeni is the organism of choice for promoting malolactic fermentation in wine. The population biology of O. oeni is poorly understood and remains unclear. For a better understanding of the mode of genetic variation within this species, we investigated by using multilocus sequence typing (MLST) with the gyrB, pgm, ddl, recP, and mleA genes the genetic diversity and genetic relationships among 18 O. oeni strains isolated in various years from wines of the United States, France, Germany, Spain, and Italy. These strains have also been characterized by ribotyping and restriction fragment length polymorphism (RFLP) analysis of the PCR-amplified 16S-23S rRNA gene intergenic spacer region (ISR). Ribotyping grouped the strains into two groups; however, the RFLP analysis of the ISRs showed no differences in the strains analyzed. In contrast, MLST in oenococci had a good discriminatory ability, and we have found a higher genetic diversity than indicated by ribotyping analysis. All sequence types were represented by a single strain, and all the strains could be distinguished from each other because they had unique combinations of alleles. Strains assumed to be identical showed the same sequence type. Phylogenetic analyses indicated a panmictic population structure in O. oeni. Sequences were analyzed for evidence of recombination by split decomposition analysis and analysis of clustered polymorphisms. All results indicated that recombination plays a major role in creating the genetic heterogeneity of O. oeni. A low standardized index of association value indicated that the O. oeni genes analyzed are close to linkage equilibrium. This study constitutes the first step in the development of an MLST method for O. oeni and the first example of the application of MLST to a nonpathogenic food production bacteria.     

Genomic analysis of Oenococcus oeni PSU-1 and its relevance to winemaking

Oenococcus oeni is an acidophilic member of the Leuconostoc branch of lactic acid bacteria indigenous to wine and similar environments. O. oeni is commonly responsible for the malolactic fermentation in wine and due to its positive contribution is frequently used as a starter culture to promote malolactic fermentation. In collaboration with the Lactic Acid Bacteria Genome Consortium the genome sequence of O. oeni PSU-1 has been determined. The complete genome is 1,780,517 nt with a GC content of 38%. 1701 ORFs could be predicted from the sequence of which 75% were functionally classified. Consistent with its classification as an obligately heterofermentative lactic acid bacterium the PSU-1 genome encodes all the enzymes for the phosphoketolase pathway. Moreover, genes related to flavor modification in wine, such as malolactic fermentation capacity and citrate utilization were readily identified. The completion of the O. oeni genome marks a significant new phase for wine-related research on lactic acid bacteria in which the physiology, genetic diversity and performance of O. oeni starter cultures can be more rigorously examined.     

Functional divergence in the genus Oenococcus as predicted by genome sequencing of the newly-described species, Oenococcus kitaharae

Oenococcus kitaharae is only the second member of the genus Oenococcus to be identified and is the closest relative of the industrially important wine bacterium Oenococcus oeni. To provide insight into this new species, the genome of the type strain of O. kitaharae, DSM 17330, was sequenced. Comparison of the sequenced genomes of both species show that the genome of O. kitaharae DSM 17330 contains many genes with predicted functions in cellular defence (bacteriocins, antimicrobials, restriction-modification systems and a CRISPR locus) which are lacking in O. oeni. The two genomes also appear to differentially encode several metabolic pathways associated with amino acid biosynthesis and carbohydrate utilization and which have direct phenotypic consequences. This would indicate that the two species have evolved different survival techniques to suit their particular environmental niches. O. oeni has adapted to survive in the harsh, but predictable, environment of wine that provides very few competitive species. However O. kitaharae appears to have adapted to a growth environment in which biological competition provides a significant selective pressure by accumulating biological defence molecules, such as bacteriocins and restriction-modification systems, throughout its genome.     

Development of a sequence-characterized amplified region marker-targeted quantitative PCR assay for strain-specific detection of Oenococcus oeni during wine malolactic fermentation

Control over malolactic fermentation (MLF) is a difficult goal in winemaking and needs rapid methods to monitor Oenococcus oeni malolactic starters (MLS) in a stressful environment such as wine. In this study, we describe a novel quantitative PCR (QPCR) assay enabling the detection of an O. oeni strain during MLF without culturing. O. oeni strain LB221 was used as a model to develop a strain-specific sequence-characterized amplified region (SCAR) marker derived from a discriminatory OPA20-based randomly amplified polymorphic DNA (RAPD) band. The 5' and 3' flanking regions and the copy number of the SCAR marker were characterized using inverse PCR and Southern blotting, respectively. Primer pairs targeting the SCAR sequence enabled strain-specific detection without cross amplification of other O. oeni strains or wine species of lactic acid bacteria (LAB), acetic acid bacteria (AAB), and yeasts. The SCAR-QPCR assay was linear over a range of cell concentrations (7 log units) and detected as few as 2.2 × 10(2) CFU per ml of red wine with good quantification effectiveness, as shown by the correlation of QPCR and plate counting results. Therefore, the cultivation-independent monitoring of a single O. oeni strain in wine based on a SCAR marker represents a rapid and effective strain-specific approach. This strategy can be adopted to develop easy and rapid detection techniques for monitoring the implantation of inoculated O. oeni MLS on the indigenous LAB population, reducing the risk of unsuccessful MLF.     

Typification of Oenococcus oeni strains by multiplex RAPD-PCR and study of population dynamics during malolactic fermentation

AIMS: The goal of this study was to develop a reproducible method for molecular typing strains of Oenococcus oeni, and also to apply it in the study of population dynamics of these strains during malolactic fermentation of wine. METHODS AND RESULTS: A new method of multiplex randomly amplified polymorphic DNA (RAPD)-PCR has been developed, based on the combination of one random 10-mer and one specific 23-mer oligonucleotide in a single PCR. This method generates unique and discriminant DNA profiles for strains of O. oeni. The strains of this species were also clearly distinguished from other species of lactic acid bacteria. The method was applied to study the dynamics of O. oeni strains during malolactic fermentation, in three vintages in the same cellar. CONCLUSIONS: A fast and reliable method for typing strains of O. oeni has been designed and optimized. It improves the reproducibility and rapidity of conventional RAPD-PCR, and it has been validated monitoring the population dynamics during malolactic fermentation. SIGNIFICANCE AND IMPACT OF THE STUDY: This method will be a good tool to study the population dynamics of bacteria during malolactic fermentation and to evaluate the performance of new malolactic starter cultures and their dominance over the native microbiota.     

Genotypic diversity in Oenococcus oeni by high-density microarray comparative genome hybridization and whole genome sequencing

Many bacteria display substantial intra-specific genomic diversity that produces significant phenotypic variation between strains of the same species. Understanding the genetic basis of these strain-specific phenotypes is especially important for industrial microorganisms where these characters match individual strains to specific industrial processes. Oenococcus oeni, a bacterium used during winemaking, is one such industrial species where large numbers of strains show significant differences in commercially important industrial phenotypes. To ascertain the basis of these phenotypic differences, the genomic content of ten wine strains of O. oeni were mapped by array-based comparative genome hybridization (aCGH). These strains comprised a genomically diverse group in which large sections of the reference genome were often absent from individual strains. To place the aCGH results in context, whole genome sequence was obtained for one of these strains and compared with two previously sequenced, unrelated strains. While the three strains shared a core group of conserved ORFs, up to 10% of the coding potential of any one strain was specific to that isolate. The genome of O. oeni is therefore likely to be much larger than that present in any single strain and it is these strain-specific regions that are likely to be responsible for differences in industrial phenotypes.     

Arginine and citrulline do not stimulate growth of two Oenococcus oeni strains in wine

Arginine metabolism by wine lactic acid bacteria (LAB) may lead to wine quality degradation. While arginine is essential for growth of the wine relevant LAB Oenococcus oeni , it remains unclear whether it also stimulates its growth. This study evaluated the effect of arginine and citrulline, the partially metabolized intermediate of the arginine deiminase pathway, on the growth of two commercial O. oeni strains in comparison with a Lactobacillus buchneri strain in wine and at wine pH values. Neither arginine nor citrulline increased growth of both O. oeni strains in comparison with the L. buchneri strain. However, arginine and citrulline were partially degraded in all incubations. The extent of citrulline degradation correlated with lower pH values in oenococcal cultivations but with higher pH values in those of the L. buchneri strain. The degradation kinetics of O. oeni and L. buchneri for malic acid and arginine differed and the latter grew in sterile filtered post-malolactic fermentation wine. This study shows that arginine and citrulline did not stimulate growth of the two O. oeni strains studied, and that their physiological role differed among the wine LAB considered. While arginine may play a role in wine microbiological stability, other nutrients should be investigated for their suitability to create a selective ecological advantage for O. oeni strains in wine.     

Lactobacillic Acid Accumulation in the Plasma Membrane of Oenococcus oeni: A Response to Ethanol Stress?

It is known that ethanol strongly interferes with the development and activity of lactic acid bacteria in wine. In this work, it was observed that membrane composition was dependent of ethanol concentration and cell physiological state. The protein electrophoretic profile was modified in the membranes of Oenococcus oeni cultured in presence of 8 and 10% ethanol. Concerning the membrane lipid composition, it was observed that O. oeni maintained a high level of phospholipid biosynthesis via the relative increased biosynthesis of phosphoethanolamine and sphingomyelin in presence of ethanol. On the other hand, ethanol induced an increase in the membrane lactobacillic acid percentage at the expense of cis-vaccenic acid. This increased synthesis of lactobacillic acid appears as the more significant change induced by ethanol in O. oeni membrane. The increase of lactobacillic acid in the membrane of O. oeni clearly appears as a factor that provides protection against the toxic effect of ethanol, balancing the increase of membrane fluidity normally attributed to ethanol. The results presented in this paper constitute evidence that lactobacillic acid may have a part in the survival and or adaptive mechanisms developed by O. oeni under culture adverse conditions, allowing these bacteria to maintain their activity in the presence of ethanol, namely performing malolactic fermentation in wine.     

Intraspecific diversity of Oenococcus oeni isolated during red wine-making in Japan

Using molecular and chemotaxonomic techniques, we studied the intraspecific diversity of Oenococcus oeni, a lactic acid bacterium isolated during red wine-making in Japan. The results confirmed high values of DNA-DNA relatedness and strong similarity among 16S rDNA sequences of the isolates with the O. oeni-type strain. Pulsed-field gel electrophoresis (PFGE) by NotI identified four patterns among the strains. Three different patterns of lactate dehydrogenase mobility were seen and there was a strong correlation between PFGE pattern and mobility. The present results suggest that the different strains of O. oeni comprise one species, and that variations in the genomic profiles of the different strains of O. oeni, including Japanese isolates are well correlated.     

Rapid detection of Oenococcus oeni in wine by real-time quantitative PCR

AIMS: To develop a real-time polymerase chain reaction (PCR) method for rapid detection and quantification of Oenococcus oeni in wine samples for monitoring malolactic fermentation. METHODS AND RESULTS: Specific primers and fluorogenic probe targeted to the gene encoding the malolactic enzyme of O. oeni were developed and used in real-time PCR assays in order to quantify genomic DNA either from bacterial pure cultures or wine samples. Conventional CFU countings were also performed. The PCR assay confirmed to be specific for O. oeni species and significantly correlated to the conventional plating method both in pure cultures and wine samples (r = 0.902 and 0.96, respectively). CONCLUSIONS: The DNA extraction from wine and the real-time PCR quantification assay, being performed in ca 6 h and allowing several samples to be concurrently processed, provide useful tools for the rapid and direct detection of O. oeni in wine without the necessity for sample plating. SIGNIFICANCE AND IMPACT OF THE STUDY: Rapid quantification of O. oeni by a real-time PCR assay can improve the control of malolactic fermentation in wines allowing prompt corrective measures to regulate the bacterial growth.     

Whole-genome comparison reveals novel genetic elements that characterize the genome of industrial strains of Saccharomyces cerevisiae

Human intervention has subjected the yeast Saccharomyces cerevisiae to multiple rounds of independent domestication and thousands of generations of artificial selection. As a result, this species comprises a genetically diverse collection of natural isolates as well as domesticated strains that are used in specific industrial applications. However the scope of genetic diversity that was captured during the domesticated evolution of the industrial representatives of this important organism remains to be determined. To begin to address this, we have produced whole-genome assemblies of six commercial strains of S. cerevisiae (four wine and two brewing strains). These represent the first genome assemblies produced from S. cerevisiae strains in their industrially-used forms and the first high-quality assemblies for S. cerevisiae strains used in brewing. By comparing these sequences to six existing high-coverage S. cerevisiae genome assemblies, clear signatures were found that defined each industrial class of yeast. This genetic variation was comprised of both single nucleotide polymorphisms and large-scale insertions and deletions, with the latter often being associated with ORF heterogeneity between strains. This included the discovery of more than twenty probable genes that had not been identified previously in the S. cerevisiae genome. Comparison of this large number of S. cerevisiae strains also enabled the characterization of a cluster of five ORFs that have integrated into the genomes of the wine and bioethanol strains on multiple occasions and at diverse genomic locations via what appears to involve the resolution of a circular DNA intermediate. This work suggests that, despite the scrutiny that has been directed at the yeast genome, there remains a significant reservoir of ORFs and novel modes of genetic transmission that may have significant phenotypic impact in this important model and industrial species.     

Genetic variation at the O-antigen biosynthetic locus in Pseudomonas aeruginosa

The outer carbohydrate layer, or O antigen, of Pseudomonas aeruginosa varies markedly in different isolates of these bacteria, and at least 20 distinct O-antigen serotypes have been described. Previous studies have indicated that the major enzymes responsible for O-antigen synthesis are encoded in a cluster of genes that occupy a common genetic locus. We used targeted yeast recombinational cloning to isolate this locus from the 20 internationally recognized serotype strains. DNA sequencing of these isolated segments revealed that at least 11 highly divergent gene clusters occupy this region. Homology searches of the encoded protein products indicated that these gene clusters are likely to direct O-antigen biosynthesis. The O15 serotype strains lack functional gene clusters in the region analyzed, suggesting that O-antigen biosynthesis genes for this serotype are harbored in a different portion of the genome. The overall pattern underscores the plasticity of the P. aeruginosa genome, in which a specific site in a well-conserved genomic region can be occupied by any of numerous islands of functionally related DNA with diverse sequences.     

The genome sequence of the wine yeast VIN7 reveals an allotriploid hybrid genome with Saccharomyces cerevisiae and Saccharomyces kudriavzevii origins

The vast majority of wine fermentations are performed principally by Saccharomyces cerevisiae. However, there are a growing number of instances in which other species of Saccharomyces play a predominant role. Interestingly, the presence of these other yeast species generally occurs via the formation of interspecific hybrids that contain genomic contributions from both S.?cerevisiae and non-S.?cerevisiae species. However, despite the large number of wine strains that are characterized at the genomic level, there remains limited information regarding the detailed genomic structure of hybrids used in winemaking. To address this, we describe the genome sequence of the thiol-releasing commercial wine yeast hybrid VIN7. VIN7 is shown to be an almost complete allotriploid interspecific hybrid that is comprised of a heterozygous diploid complement of S.?cerevisiae chromosomes and a haploid Saccharomyces kudriavzevii genomic contribution. Both parental strains appear to be of European origin, with the S.?cerevisiae parent being closely related to, but distinct from, the commercial wine yeasts QA23 and EC1118. In addition, several instances of chromosomal rearrangement between S.?cerevisiae and S.?kudriavzevii sequences were observed that may mark the early stages of hybrid genome consolidation.     

The ftsH gene of the wine bacterium Oenococcus oeni is involved in protection against environmental stress

The wine bacterium Oenococcus oeni has to cope with harsh environmental conditions, including an acidic pH, a high alcoholic content, nonoptimal growth temperatures, and growth-inhibitory compounds such as fatty acids, phenolic acids, and tannins. We describe the characterization and cloning of the O. oeni ftsH gene, encoding a protease belonging to the ATP binding cassette protein superfamily. The O. oeni FtsH protein is closest in sequence similarity to the FtsH homologue of Lactococcus lactis. The O. oeni ftsH gene proved to be stress-responsive, since its expression increased at high temperatures or under osmotic shock. O. oeni FtsH protein function was tested in an Escherichia coli ftsH mutant strain, and consistent with the O. oeni ftsH gene expression pattern, the O. oeni FtsH protein provided protection for the E. coli ftsH mutant against heat shock. O. oeni and Bradyrhizobium japonicum FtsH proteins also triggered E. coli resistance to wine toxicity. Genes homologous to O. oeni ftsH were detected in many other lactic acid bacteria found in wine, suggesting that this type of gene constitutes a well-conserved stress-protective molecular device.     

rpoB gene: a target for identification of LAB cocci by PCR-DGGE and melting curves analyses in real time PCR

Lactic acid bacteria (LAB) are essential in the quality of many fermented beverages like beer, cider and wine. In the two later cases, they convert malic acid into lactic acid during the malolactic fermentation. After fermentation, microbial stabilization is needed to prevent the development of spoilage bacteria species. Among them, cocci lead to different alterations: Pediococcus sp., and some strains of Leuconostoc mesenteroides and Oenococcus oeni can produce exopolysaccharides which modify wine viscosity and lead to ropiness. They also can produce acetic acid, biogenic amine, ethyl carbamate and volatile phenols. Therefore detection and identification are crucial. Results of phenotypic tests and DNA-DNA probes are not accurate enough. 16S RNA gene which is currently used for bacterial species identification presents intraspecies heterogeneity. The rpoB gene is an alternative to this limitation. However previous PCR targeting partial sequence of rpoB gene could not delimit cocci species. Therefore we compared the rpoB gene sequence of the six main cocci species found in fermented beverages: P. damnosus, P. dextrinicus, P. parvulus, P. pentosaceus, L. mesenteroides and O. oeni. The most discriminating partial sequence of the rpoB gene was chosen for designing primers. By PCR-DGGE the reliability of these primers was verified. It was controlled in a mixture of several cocci and other lactic acid bacteria (Lactobacillus sp.). Then we adapted the primers and the PCR conditions in order to achieve the identification of cocci species by real time PCR program including the fluorescent dye SYBR Green I, which gives faster results. PCR melt curves were established and a specific T(m) was attributed to each species.