Macrowine 2021
IVES 9 IVES Conference Series 9 New biological tools to control and secure malolactic fermentation in high pH wines

New biological tools to control and secure malolactic fermentation in high pH wines

Abstract

Originally, the role of the malolactic fermentation (MLF) was simply to improve the microbial stability of wine via biological deacidification. However, there is an accumulation of evidence to support the fact that lactic acid bacteria (LAB) also contribute positively to the taste and aroma of wine. Many different LAB enter into grape juice and wine from the surface of grape berries, cluster stems, vine leaves, soil and winery equipment. Due to the highly selective environment of juices and wine, only a few types of LAB are able to grow. Wine pH is most selective, and at pH below 3.5 generally only strains of Oenococcus oeni can survive and express malolactic activity, while wines with pH above 3.5 can contain various species of Pediococcus, as well as strains of Lactobacillus. The trend toward harvesting higher maturity grapes has resulted in the processing of higher pH musts and the production of wines containing increased levels of alcohol. These conditions favor the growth of indigenous bacteria and often O. oeni does not prevail at the end of alcoholic fermentation. More Lactobacillus sp. predominate and are often responsible for spontaneous MLF (du Toit et al. 2011). Some L. plantarum strains can tolerate the high alcohol concentrations and SO2 levels normally encountered in wine. Due to their very complex and diverse metabolism a range of compositional changes can be induced, which may affect the quality of the final product positively or negatively. A recent isolate have shown most interesting results, not only for its capacity to induce MLF after direct inoculation in freeze-dried form, but also for their positive contribution to the wine aroma. Co-inoculation (inoculation of selected wine LAB 24 hours after the yeast) can ensure the early implantation and dominance of the selected strain, the early onset and completion of MLF, and can possibly prevent the appearance of the spoilage yeast and bacteria. Applying an important L. plantarum inoculum with high malolactic activity assures an immediate dominance, as well as predictable and complete MLF in short time and allows an early stabilization of the wine. Since it degrades hexose sugars by the homo-fermentative pathway, which poses no risk of acetic acid production from the residual sugars that may be present in high pH wines, it is an interesting alternative to control MLF in high pH wines.

Publication date: May 17, 2024

Issue: Macrowine 2016

Type: Poster

Authors

Sibylle Dr. Krieger-Weber*, Anthony Silvano, Magali Deleris-Bou

*Lallemand SAS

Contact the author

Tags

IVES Conference Series | Macrowine | Macrowine 2016

Citation

Related articles…

Use of computational modelling for selecting adsorbents for improved fining of wine

The occurrence of faults and taints in wine, such as those caused by microbial spoilage or various taints, have resulted in significant financial losses to wine producers. The wine industry commits significant financial resources towards fining and taint removal processes each year. Fining involves the addition of one or more adsorptive substrates to juice or wine to bind certain components, thus reducing their concentration [1]. However, these processes are often not selective and can also remove desirable flavour and aroma compounds.

HEAT BERRY : Sensitivity of berries ripening to higher temperature and impact on phenolic compounds in wine

The grapevine is an important economical crop that is very sensitive to climate changes and microclimate. The observations made during the last decades at a vineyard scale all concur to show the impact of climate change on vine physiology, resulting in accelerated phenology and earlier harvest (Jones and Davis 2000). It is well-known that berry content is affected by the ambient temperature. While the first experiences were primarily conducted on the impact of temperature on anthocyanin accumulation in the grape, few studies have focused on others component of phenolic metabolism, such as tannins.

Using combinations of recombinant pectinases to elucidate the deconstruction of the polysaccharide‐rich grape cell wall during winemaking

The effectiveness of enzyme-mediated maceration processes in red winemaking relies on a clear picture of the target (berry cell wall structure) to achieve the optimum combination of specific enzymes to be used. However, we lack the information on both essential factors of the reaction (i.e. specific activities in commercial enzyme preparation and the cell wall structure of berry tissue). In this study, the different combinations of pure recombinant enzymes and the recently validated high throughput cell wall profiling tools were applied to extend our knowledge on the grape berry cell wall polymeric deconstruction during the winemaking following a combinatorial enzyme treatment design.

DNA and type of grain: which factor does better explain sensory differences of sessile and pedunculate oaks?

Sessile oak and pedunculate oak have shown several differences of interest for enological purposes. Tannic and aromatic composition among sessile oak or pedonculate oak has been well studied. Sessile oak is generally more aromatic than pedunculated, while the later is more tannic. This scientific point of view is rarely applied to classify oak in cooperages. Most coopers use the type of grain to distinguish wide and thin grain.

Extraction of pathogenesis-related proteins and phenolics in Sauvignon Blanc as affected by different

The composition of wine is largely determined by the composition of pre-fermentation juice, which is influenced by extraction of grape components. Different grape harvesting and processing conditions could affect the extraction of grape components into juice. Among these grape components, pathogenesis-related (PR) proteins are of great concern for white wine maker as they are the main cause of haze formation in finished white wine. If not removed before bottling, these PR proteins may progress into haze through the formation of complex with phenolics under certain conditions. Thaumatin-like proteins (TLPs) and chitinases are the main constituents of PR proteins found in protein haze.