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Microorganisms of Juice: Managing Competition in the Tank
Lucy JosephU.C. Davis
Department of Viticulture and Enology
Managed Ecosystem
Ecological Succession in Wine Fermentation
Which Microbes Are Found? –Vineyard to Must
Factors Affecting Grape Microflora
• Moisture/Humidity• Insect Vectors and Damage• Temperature• Vineyard Management Practices• Variety of Grape• Geography
Environmental Conditions that Affect the Microflora of Must
• pH - Low• Nutrients - high sugar, variable nitrogen• Temperature - fermentation creates heat• Oxygen - fermentation is low oxygen• Inhibitors - pesticides, sulfur, alcohol, acetic
acid, etc.• Winery Practices - additions, sanitation,
stylistic considerations
Fungi found on Grapes
• Botrytis cinerea – bunch rot
• Plasmopara viticola – downy mildew
• Erysiphe necator – powdery mildew
• Penicillium – green mold
• Aspergillus – black mold
• Alternaria – black smut
• Cladosporium – post-harvest
• Rhizopus – soft rot
Bacteria in the - Vineyard MustLactobacillus LactobacillusLactococcus PediococcusEnterococcus WeissellaWeissella GluconobacterGluconobacter AcetobacterPediococcus GluconacetobacterOenococcus Leuconostoc
Oenococcus
Yeast in the – Vineyard Harvested GrapesZygosaccharomyces HanseniasporaHanseniaspora MetschnikowiaIssatchenkia CandidaKluyveromycesMetschnikowiaPichiaCandidaRhodotorulaSporobolomycesSporidiobolus
Yeast Found in Must Hanseniaspora uvarum, guilliermondii, opuntiae Metschnikowia pulcherrima Candida zemplinina, glabrata, diversa Pichia anomala, fermentans, guilliermondii Clavispora lusitaniae Zygosaccharomyces bailii Kluveromyces thermotolerans Kazachstania species Issatchenkia occidentalis, orientalis, terricola Saccharomyces cerevisiae
Saccharomyces in the Vineyard
• Saccharomyces occurs in only about 1 sound berry in 1000 tested
• In damaged berries that increases to about 1 in 4 berries tested
• The number of Saccharomyces cells on damaged berries is about 104 to 105 cfu/ml
• The total microbial counts in damaged berries is 106 to 107 cfu/ml
Typical Saccharomyces Growth Curve vs Typical Wine Fermentation Curve
Saccharomyces and Non-Saccharomyces Growth Curves vs Typical Wine Fermentation Curve
How Certain Groups are Selected
Natural selection:•Low pH •High sugar concentration – high osmolarity•Other nutrients•High phenolic content•Low oxygen•Alcohol concentration
How Certain Groups are Selected
Artificial Selection:•Temperature•Potassium metabisulfite•pH - Tartaric acid•Lysozyme•Nutrients
What Are Some “Best Practices”?
• Harvest brix less than 27o brix• Harvest acid content – pH 3.2 to 3.6, TA 0.6 to
0.8• SO2 added at the crusher
• Temperatures less than 30oC• Pump overs to manage temperature oxygen
levels• Addition of nutrients only as needed
Why Do Best Practices Work?
What do they control?
Acid Adjustment
• High acid favors growth of yeasts early in fermentation
• Most microbes, especially bacteria, are not acid tolerant
• pH often increases during fermentation which favors the ML fermentation
• pH greater than 3.6 encourages spoilage lactics
• Brettanomyces is more tolerant to low pH
Addition of SO2
• Inhibits the growth of spoilage bacteria• Inhibits growth of wild yeasts including
Brettanomyces • Destroys thiamin• Inhibits oxidation
Inoculation• Directly adds the desirable organism in high
numbers
Engineering Practices
• Adjusting temperature– Cold soaks– Tank temperature, jacketed– Pump overs
• Adjusting oxygen – Cap Management– Pump overs – Rack and return– Punch down– Stirring or aeration– Micro-ox
Temperature
• Cold soaks (15-20oC) encourage growth of non-Saccharomyces yeast early in fermentation
• Cool temperatures during fermentation inhibit growth of spoilage bacteria and some yeasts
• Warm temperatures can favor ML bacteria• Cool storage temperatures discourage
spoilage organisms during storage
Low Oxygen
• Strict aerobic organisms cannot compete under low oxygen conditionsFilamentous fungiAcetic acid bacteria
• Anaerobic and facultative anaerobes grow under low oxygenSaccharomycesML bacteria
Risks and Rewards
• Long hang times of fruit allow for development of desirable flavor and color and adds complexity
• Over doing it results in higher sugars that can produce too much alcohol that can arrest fermentation, leave residual sugars, and leave nutrients for spoilage organisms
• Acidity may also suffer and be too low allowing spoilage organism to flourish
Risks and Rewards
• Cold soaks can allow growth of wild yeasts that produce desired esters and other flavor compounds that add complexity
• Typically yeasts like Hanseniaspora, Pichia, and Candida occur
• Wild yeasts can also produce acetic acid and ethyl acetate in large amounts and this can be particularly risky with damaged fruit
Risks and Rewards
• Low oxygen prevents the growth of strict aerobic organisms like acetic acid bacteria and filamentous fungi
• Too much oxygen allows a bloom of aerobic organisms that often occur as a film on the surface of the wine
• Micro-ox done incorrectly in the presence of microbes, for example wood, results in the bloom of atypical microbes in wine
Case Study 1
• A winemaker approached Dr. Bisson with a wine that had a mousey taste and low bacteria numbers by microscopic observation. No bacteria were found by plating or QPCR.
• The wine was filtered and filters plated on both bacterial (MLAB) and yeast (YM and WL) media.
Grenache Wine
Grenache Filter on Plate
What Is Causing the Contamination?
• There are many sources of bacterial contamination including: air, dust or soil, grapes, wood, water, and corks.
• The wines were typical except that the SO2 level was low to none.
• The wines showed contamination with many species of bacteria.
• All of these wines were treated by micro-oxidation in the presence of wood.
What Is Causing the Bacillus Contamination?
•In bottling lines, Bacillus spores can survive heat treatments that have replaced chemical sanitation measures.•Bacillus is a strict aerobe but is typically acid sensitive•Ethanol is effective at inducing sporulation in Bacillus
Case Study #2
• Wine was returned from the distributor due to high turbidity. Wine had no aroma or flavor defect, only high turbidity in some bottles.
• Bacteria were visible under the microscope but did not grow on plates and QPCR came back negative.
What was in the wine?
• Initial plating indicated Bacillus but the Bacillus didn’t look like what we saw under the microscope
• It might be Bacillus spores• Looking further we also found moderately
high levels of Staphylococcus pasteuri
The wine
• The wine was sweetened with added juice. I don’t know if the juice was filtered.
• Synthetic corks were used.• The pH of the wine was high.• The bottling line was cleaned with only hot
water, bleach was no longer being used.
Best Practices
• Developed over time because they work
• How and why they work has not always been understood
• Significant deviation from the best practices rarely goes well