Posted by Albert Bordons
2nd May 2015
The vine growers believe that the land on which they grow vines gives the wines a unique quality, and that is called terroir. We can consider that the physiological response of the vines to the type of soil and climatic conditions, together with the characteristics of the variety and form of cultivation, result in a wine organoleptic properties that define their terroir (Zarraonaindia et al 2015 ). However, it is not known if there could be a very specific microbiota of each terroir, as this subject has been barely studied.
Wine microorganisms in the grapes? Saccharomyces is not there or it has not been found there
The main protagonists of wine fermentations, alcoholic one (yeast Saccharomyces cerevisiae) and malolactic one (lactic acid bacteria Oenococcus oeni) usually do not appear until the must grape is fermenting to wine, in the cellar. In normal healthy grapes, S. cerevisiae is hardly found.
Oenococcus oeni in the grapes ? We have found it !
Regarding O. oeni, so far very little has been published about its presence and isolation from the grapes. In some works, as Sieiro et al (1990), or more recently Bae et al (2006), some lactic acid bacteria (LAB) have been isolated from the surface of grapes, but not O. oeni. Only Garijo et al (2011) were able to isolate a colony (only one) of O. oeni from Rioja grapes. Moreover, DNA of O. oeni has been detected in a sample of grapes from Bordeaux (Renouf et al 2005, Renouf et al 2007) by PCR-DGGE of rpoB gene, although in these works no Oenococcus has been isolated.
I am pleased to mention that recently our team have managed to isolate O. oeni from grapes, and typify them, and we are now working on a publication about it (Franquès et al 2015). Indeed, our research team of lactic acid bacteria (BL-URV), together with colleagues working on yeasts from the same group “Oenological Biotechnology” (Faculty of Oenology at the Universitat Rovira i Virgili in Tarragona, Catalonia, Spain) is working on a European project, called “Wildwine “(FP7-SME-2012 -315065), which aims to analyse the autochthonous microorganisms of Priorat area (South Catalonia), and select strains with oenological potential. This project also involves the Priorat Appellation Council and the cellar Ferrer-Bobet, as well as research groups and associations wineries from Bordeaux, Piedmont and Greece. In the framework of this project we took samples of grapes (Grenache and Carignan) from several vineyards of Priorat (Figure 1), as well as samples of wines doing malolactic fermentation. From all them we got 1900 isolates of LAB. We optimized isolation from grapes from the pulp and juice with various methods of enrichment, and so we got 110 isolated bacteria from grapes, identified as O. oeni by specific molecular techniques. Once typified, we have found that the molecular profiles of these strains do not coincide with commercial strains and so they are autochthonous. In addition, some of these strains from grapes were also found in the corresponding wine cellars.
Figure 1. Taking samples of Grenache (left) and Carignan (right) in Priorat area to isolate lactic acid bacteria such as Oenococcus (Pictures Albert Bordons).
The microbiota of grapes
The grapes have a complex microbial ecology, including yeasts, mycelial fungi and bacteria. Some are found only in grapes, such as parasitic fungi and environmental bacteria, and others have the ability to survive and grow in wines: especially yeasts, lactic acid bacteria (LAB) and acetic acid bacteria. The proportion of all them depends on the maturation of the grapes and the availability of nutrients.
When the fruits are intact, the predominant microbiota are basidiomycetous yeasts as Cryptococcus and Rhodotorula, but when they are more mature, they begin to have micro fissures that facilitate the availability of nutrients and explain the predominance just before the harvest of slightly fermentative ascomycetes as Candida, Hanseniaspora, Metschnikowia and Pichia. When the skin is already damaged more damaging yeasts may appear, as Zygosaccharomyces and Torulaspora, and acetic acid bacteria. Among the filamentous fungi occasionally there may have some very harmful as Botrytis (bunch rot) or Aspergillus producing ochratoxin. Although they are active only in the vineyard, their products can affect wine quality.
On the other hand, environmentally ubiquitous bacteria have been isolated from the grapes skin, as various Enterobacteriaceae, Bacillus and Staphylococcus, but none of them can grow in wine (Barata et al 2012).
Coming back to the possible specific microbiota of terroir, it has been found that some volatile compounds contributing to the aroma of the wine, such as 2-methyl butanoic acid and 3-methyl butanol, are produced by microorganisms isolated in the vineyards, as Gram-positive bacterium Paenibacillus, or the basidiomycetous fungus Sporobolomyces or the ascomycetous Aureobasidium. Therefore, there could be a relationship between some of the microbial species found in grapes and some detected aromas in wine, coming from the must of course (Verginer et al 2010).
Metagenomics as analytical tool of microbiota from grapes
Since conventional methods of isolation and cultivation of microorganisms are slow, laborious and some microbes cannot be grown up in the usual isolation media, massive sequencing methods or metagenomics are currently used. These consist of analysing all the DNA of a sample, and deducing which are the present microorganisms by comparing the sequences found with those of the databases. For bacteria the amplified DNA of V4 fragment from 16S RNA gene is used (Caporaso et al 2012).
This technique has been used with samples of botrytized wines (Bokulich et al 2012) and various LAB have been found (but not Oenococcus), including some not normally associated with wine. It has also been used to see the resident microbiota in wineries and how it changes with the seasons, resulting that in the surfaces of tanks and machinery of the cellar there is a majority of microorganisms neither related with wine nor harmful (Bokulich et al 2013).
With this technique Bokulich et al (2014) have also analysed the grapes and they have seen clear differences between the proportions of bacterial groups (and fungi) from different places, different varieties, as well as environmental or bio geographical conditions. For example, when analysing 273 samples of grape musts from California, the 3 varieties (Cabernet, Chardonnay and Zinfandel) are quite discriminated in a principal components analysis with respect to the bacterial communities found in each sample (Figure 2).
Thus, the dominant bacterial taxa or groups in a variety or given environment could provide some specifics traits on those wines, and this could explain some regional or terroir patterns in the organoleptic properties of these wines (Bokulich et al 2014).
Figure 2. Principal component analysis of bacterial communities of grape musts samples of Sonoma (California) from 3 varieties (Cabernet in red, Chardonnay in green and Zinfandel in blue) (Bokulich et al 2014).
We have also carried out a massive sequencing study with the same grape samples from which we have obtained isolates of O. oeni, as said before (Franquès et al 2015), and in more than 600,000 analysed sequences of 16S rRNA, we have found mainly Proteobacteria and Firmicutes. Among these gram-positive, we have found sequences of lactic acid bacteria (15%) and from these we have successfully confirmed the presence of O. oeni in 5% of the sequences. Therefore, we have isolated O. oeni from grapes and we have detected their DNA in the samples.
The bacterial microbiota of the vineyards and soil
As we see, microbiota of grapes and wine has been studied a little, but the soil microbiota has not been characterized. This one can define more clearly the terroir, which is influenced by the local climate and characteristics of the vineyard.
In Figure 3 the main genera found in different parts of the vine and soil are summarized (Gilbert et al 2014).
Figure 3. Main bacteria and fungi associated with organs and soil of Vitis vinifera (Gilbert et al 2014)
Recently an interesting scientific work (Zarraonaindia et al 2015) has been published on this subject, with the aim to see if the soil could be the main original source of bacteria that colonize the grapes. These authors took samples of soil, roots, leaves, flowers and grapes from Merlot vines, from different areas and years, of Suffolk, New York, and they analysed the bacterial DNA by 16S rRNA sequencing. They found that 40% of the species found were present in all samples of soil and roots, while there was more variability in leaves and fruits, and moreover, 40% of those found in leaves and fruits were also found in soils. All this suggests that many bacteria originate in the soil.
Regarding the type of bacteria, they found that Proteobacteria (especially Pseudomonas and Methylobacterium) predominated (Figure 4), mainly in the aerial parts of the plant. There were also Firmicutes as expected, and Acidobacteria and Bacteroides.
Figure 4. Composition of the bacterial community, at Phylum level, in samples from different organs of the vine and its soil (Zarraonaindia et al 2015).
Although variations were observed in all samples depending on the year (there may be different climatic conditions) and according to different edaphic factors (pH, C: N, humidity), the principal-components analysis (Figure 5) showed that the main types of samples (soil, roots, leaves, grapes) differ quite well, and bacterial taxon composition in samples of grape juice before fermentation is similar to that of grapes.
Figure 5. Principal-components analysis showing the similarities in terms of the composition of bacterial taxonomic groups, among sample types, including musts (Zarraonaindia et al 2015).
This suggests that the bacterial community found in grapes remains relatively stable until the processing to musts, and that it is more stable than the differences between organs. At the same time, a large number of representatives of bacterial phyla of the grapes come from the soil. This can be explained because when grapes are harvested by hand, they are often placed in boxes that are left on the ground, or for mechanical harvest, the machinery used removes the soil and generates dust, which can colonize the grapes.
Therefore, the soil microbiota is a source of bacteria associated with vines and may play a role in the must and therefore in the wine, and potentially in the formation of the terroir characteristics. Some of these bacteria may have some roles not yet known in productivity or disease resistance of the plant, or contribute to the organoleptic characteristics of wine (Zarraonaindia et al 2015).
In addition, and thinking in wine microorganisms responsible for fermentations, as said, in our laboratory we have confirmed that there are some O. oeni strains in grapes and we have confirmed this by detecting their DNA in the same grapes.
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