Microbiological Analysis (Type-IV)

OIV-MA-AS4-01 Microbiological analysis of wines and musts- Detection, differentiation and counting of micro-organisms

Type IV method

Objective:

Microbiological analysis is aimed at following alcoholic fermentation and/or malolactic fermentation and detecting microbiological infections, and allowing the detection of any abnormality, not only in the finished product but also during the different phases of manufacture.

Comments:

All experiments must be carried out under normal microbiological aseptic conditions, using sterilized material, close to a Bunsen burner flame or in a laminar flow room and flaming the openings of pipettes, tubes, flasks, etc. Before carrying out microbiological analysis, it is necessary to ensure that the samples to be analyzed are taken correctly.

Field of application:

Microbiological analysis can be applied to wines, musts, mistelles and all similar products even when they have been changed by bacterial activity. These methods may also be used in the analysis of industrial preparations of selected microorganisms, such as dry active yeasts and lactic bacteria.

Microbiological analysis techniques:

Reagents and materials
Installations and equipment
Sampling
Quality tests
1. Objective
2. Principle
3. Procedure
  1. air quality tests
  2. incubator quality tests
Microscopic techniques for the detection, differentiation of micro-organisms and direct counting of yeasts
1. Microscopic examination of liquids or deposits
2. Gram staining for the differentiation of bacteria isolated from colonies (see paragraph 6)
3. Catalase Test for the differentiation of bacteria isolated from colonies (see paragraph 6)
4. Yeast cell count – haemocytometry
5. Yeast cell count – methylene blue staining of yeast cells
Counting of micro-organisms by culture
1. Detection, differentiation and enumeration of microorganisms (plate count)
2. Culture in liquid environment - "Most Probable Number" (MPN).

Reagents and materials

Current laboratory equipment and apparatus, as listed in ISO 7218:2007 - Microbiology of food and animal feeding stuff - General rules for microbiological examinations.

The following ones are recommended:

Common laboratory materials and glassware, sterile (sterilized or ready-to-use sterile).
Tubes (16x160 mm or similar) containing 9 ml sterile peptone water (Tryptone: 1 g/l) or other diluents to be used for serial sample dilutions.
Ethanol to flame spreaders and tweezers.
Hydrogen peroxide 3% solution.
Micropipette holding sterile tips: 1 ml and 0.2 ml.
L-shaped or triangular-shaped bent glass rods (hockey sticks) or plastic spreaders.
Stainless steel tweezers, with flat edges.
Sterile cellulose ester membranes (or equivalent) porosity 0.2 and 0.45 µm, 47 mm or 50 mm diameter, possibly with a printed grid on the surface, and packed singularly.
Sterile cylinders.
10 ml sterile pipettes.

Installations and equipment

Current laboratory equipment and apparatus, as listed in ISO 7218:2007 - Microbiology of food and animal feeding stuff - General rules for microbiological examinations.

The following ones are recommended:

Microbiological cabinet or laminar flow cabinet. In the absence of this device, work in the proximity (within 50 cm) of a gas burner.
Balance, with an accuracy of ± 0.01 g.
Autoclave.
Incubator with settings ranging from 25°C to 37°C.
pH meter, with an accuracy of ± 0,1 pH units and a minimum measuring threshold of 0,01 pH units.
Refrigerator(s), set at 5 ± 3°C, and freezer(s), which temperature shall be below –18°C, preferably equal to – 24 ± 2°C.
Thermostatically controlled bath, set at 45 1°C
Microwave oven.
Optical microscope.
Gas burner.
Colony-counting device.
Equipment for culture in a modified atmosphere (a sealed jar in which anaerobiosis can be made).
Filtering apparatus with 47 mm or 50 mm diameter filters.
"Vortex" stirrer or equivalent.
Incubator for dry heat sterilisation
Centrifuge
Pump

Sampling

The sample must reproduce the microbiology of the whole mass of must or wine to be analyzed. As far as possible, the mass must be homogenized before sampling, in order to resuspend microorganisms that tend to set down to the bottom of the container. In case the homogenization is undesirable, samples must be taken from where the microorganisms are likely (or suspected) to be present (i.e. when searching for yeasts lying in the bottom of tanks or barrels), but in this case results are not quantitative. Before taking a sample from a tap, this latter must be flamed, and 2-3 litres liquid must be flushed. The sample must be put in a sterile.

The sample must be kept refrigerated and analysed as quickly as possible.

The following amounts of samples are required for the microbiological examination:

Must, or fermenting must or wine in storage: not less than 250 ml;

Bottled or packed wine: not less than one unit, whateverthe capacity;

Quality tests

4.1. Objective

These tests are aimed at detecting the risk of microbial infection in advance.

4.2. Principle

This technique is based on organoleptic and appearance changes (clouds, films, deposits, unusual colors) shown by wine when subjected to certain aeration and temperature conditions which can bring about microbiological activity. The nature of the changes should be confirmed by microscopic examination.

4.3. Operating method

4.3.1. Air quality tests

A 50 mL wine sample after filtration on coarse sterile filter paper is placed in a 150 mL sterile conical flask stoppered with cotton and left at an ambient temperature for at least 3 days. The clarity, color and possible presence of clouds, deposits and films are examined over this time. A microscopic examination is carried out in the case of cloud, deposit or film or a color change.

4.3.2. Incubator quality tests

A 100 mL wine sample, after filtration on coarse sterilized filter paper, is placed in 300 mL sterile conical flask stopped with cotton, put in an incubator at 30°C and examined after at least 72 hours. Organoleptic or visible changes can be indicative of microbial development. A microscopic examination must therefore be made.

Microscopic techniques for the detection and differentiation of micro-organisms, and for the direct counting of yeasts

5.1. Microscopic examination of liquids or deposits

Objective:

Microscopic examination under cool conditions is aimed at detecting and differentiating the yeasts from the bacteria that might be present, in terms of their size and shape. Microscopic observation cannot distinguish between viable and non-viable microorganisms.

Comment:

With appropriate staining (see below), an estimation of the viable yeasts can be made.

Principle:

This technique is based on the magnification made by a microscope that allows the observation of micro-organisms, whose size is on the order of a micron.

Operation method:

Microscopic examination can be carried out directly on the liquid or on the deposit.

Direct observation of the liquid will only be useful when the population is sufficiently high (more than 5 x 10⁵ cells/mL).

When wine shows a lower microorganism population, it is necessary to concentrate the sample. Thus, about 10 mL of homogenized wine is centrifuged at 3000 - 5000 rpm for 5 to 15 minutes. After decanting the supernatant, the deposit is re-suspended in the liquid remaining at the bottom of the centrifugation tube.

To carry out the microscopic observation, a drop of the liquid sample or the homogenized deposit is placed on a clean glass slide with a Pasteur pipette or a sterilized wire. It is covered with a cover glass and placed on a slide on the stage of the microscope. Observation is made in a clear field, or preferably in phase contrast, which allows a better observation of detail. A magnification of x400 - x1000 is generally used.

5.2. Gram staining for the differentiation of bacteria isolated from colonies (see paragraph 6)

Objective:

Gram staining is used to differentiate between lactic bacteria (Gram positive) and acetic bacteria (Gram negative) and also to observe their morphology.

Comments:

It must be remembered that Gram staining is not sufficient to reach a conclusion, as other bacteria in addition to lactic and acetic bacteria may be present.

Principle:

This color is based on the difference in the structure and chemical composition of the cell walls between Gram positive and Gram negative bacteria. In Gram negative bacteria, the cell walls that are rich in lipids have a much reduced quantity of peptidoglycan. This allows the penetration of alcohol and the elimination of the gentian-violet-iodine complex, forming when the colorless cell is left, which will then be re-colored in red by saffron. Conversely, the cell walls of Gram positive bacteria contain a large quantity of peptidoglycan and a low concentration of lipids. Thus, the thick peptidoglycan wall and the dehydration caused by the alcohol do not allow the alcohol to eliminate the coloring of the gentian-violet-iodine complex.

Gram staining loses its usefulness if it is performed on a culture that is too old. Thus, the bacteria must be in an exponential growth phase within 24 to 48 hours. Gram staining is carried out after isolating the colonies and liquid cultivation.

Solutions:

The water used must be distilled.

1. Gentian violet solution

Preparation: Weigh 2g of gentian violet (or crystal violet), and put into a 100 mL conical flask and dissolve in 20 mL of 95% vol. alcohol. Dissolve 0.8g of ammonium oxalate in 80 mL of distilled water. Mix the two solutions together and only use after a period of 24 hours. Filter through paper at time of use. Keep out of light in a dark flask.

2. Lugol solution

Preparation: Dissolve 2g of potassium iodide in a minimal quantity of water (4 to 5 mL) and dissolve 1g of iodine in this saturated solution. Make the volume up to 300 mL with distilled water. Keep out of light in a dark flask.

3. Saffranin solution:

Preparation: Weigh 0.5g of saffranin in a 100 mL conical flask, dissolve with 10 mL of 95% vol. alcohol and add 90 mL of water. Stir. Keep out of light in a dark flask.

Operating method:

Smear preparation

Make a subculture of the bacteria in liquid or solid medium. Collect the young culture bacteria from the deposit (after centrifugation of the liquid culture) or directly from the solid medium with a loop or wire and mix in a drop of sterilized water.

Make a smear on a slide, spreading a drop of the microbial suspension. Let the smear dry, and then carry out fixation, rapidly passing the slide 3 times through the flame of a Bunsen burner, or equivalent. After cooling, perform staining.

Staining

Pour a few drops of gentian violet solution onto the fixed smear. Leave to react for 2 minutes and wash off with water.

Pour in 1 to 2 drops of lugol solution. Leave to react for 30 seconds. Wash with water and dry with filter paper.

Pour on 95% vol. alcohol, leave for 15 seconds. Rinse with water and dry with filter paper.

Pour on a few drops of saffranin solution, leave to react for 10 seconds. Wash with water and dry with filter paper.

Place a drop of immersion oil on the smear.

With the immersion objective, observe through a microscope in clear field.

Results:

Lactic bacteria remain violet or dark blue colored (Gram positive). Acetic bacteria are red colored (Gram negative).

5.3. Catalase Test for the differentiation of bacteria isolated from colonies (see paragraph 6)

Objective:

This test is aimed at making a distinction between acetic and lactic bacteria. The yeasts and acetic bacteria have a positive reaction. Lactic bacteria give a negative response.

Comments:

It must be taken into account that the catalase test is insufficient as other bacteria in addition to lactic and acetic bacteria may be present.

Principle:

The catalase test is based on the property that aerobic micro-organisms have of decomposing hydrogen peroxide with release of oxygen:

Reagent:

12 Volume hydrogen peroxide solution (3%)

Preparation: Measure 10 mL of 30% by volume hydrogen peroxide in a 100 mL calibrated flask and fill with freshly boiled distilled water. Stir and keep in the refrigerator in a dark flask. The solution must be freshly prepared.

Operating method:

Place a drop of 3% by volume hydrogen peroxide on a slide and add a small sample of young colony. If gas is released, it can be concluded that catalase activity is occurring in the culture . It is sometimes difficult to observe gas clearing immediately, particularly with bacterial colonies. It is therefore advisable to examine the culture through a microscope (objective x10).

5.4. Yeast cell count – Haemocytometry

5.4.1. Scope

Determination of yeast cell concentration in fermenting musts or wines, and ADY (Active Dry Yeast). A high cell concentration is required: at least 5 × 10⁶ cells/ml. Fermenting musts and wines can be counted directly, ADY must be diluted 1000 or 10 000 times. Musts or wines containing fewer cells must be centrifuged (3000 g, 5 minutes) and the sediment resuspended in a known volume.

5.4.2. Principle

A drop of yeast cell suspension is placed on the surface of a slide with a counting chamber. The counting chamber has a defined volume and is subdivided in squares on the surface of the slide. Counting is made under a microscope in light field. Phase contrast is not indicated if cells are stained,

5.4.3. Reagents and materials

-Haemocytometer, double chamber, preferably with clips: Bürker, Thoma, Malassez, Neubauer.
Haemocytometer cover slip: common (0.17 mm width) cover slips are not suitable to this use, because they are flexible and do not guarantee that the chamber width is constant.
Pipettes, fine tips, 1 and 10 ml volume.
Volumetric flask, 100 ml.
Beaker, 250 ml.
1. Installations and equipment

Microscope with bright field illumination: magnification 250-500 x. Phase contrast is contraindicated.
Magnetic plate and stirring bar.

Haemocytometers are available with different counting chambers: Bürker, Thoma, Malassez, Neubauer. Confirm the identity and the volume of the counting chamber to be used. Bürker, Thoma and Neubauer chambers have 0.1 mm depth, Malassez chamber is 0.2 mm deep.

Thoma chamber has one central large (1 mm²) square, so its volume is 0.1 mm³ (10^-4 ml). This large square is subdivided in 16 squares, themselves further divided in 16 smaller squares. Thes small squares each have 0.05 mm x 0.05 side and 0.1 mm depth, so that the volume of each small square is 0.00025 mm³ (25 x 10^-8 ml). It is also possible to count in the medium squares, each medium square having 16 small squares 0.2 x 0.2 mm, and 0.004 mm³ area, or 4 x 10^-6 ml volume.

Bürker chamber contains 9 large 1mm² squares, which are divided into 16 0.2mm sided medium squares, separated by double lines with a 0.05mm spacing. The area of the medium squares is 0.04mm² and the volume is 0.004mm³. The area of the small squares formed by the double lines have an area of 0.025mm².

Big, medium and small squares of Neubauer, Thoma and Bürker chambers have the same size. Bürker chamber medium squares do not contain other lines inside; therefore they are probably the easiest to count.

5.4.5. Examination techniques

The counting chamber and the cover slip must be clean and dry before use. It may be necessary to scrub the ruled area, as dirty chambers influence the sample volume. Clean with demineralised water, or ethanol, and dry with soft paper.

If flocculent yeast has to be counted, the suspension medium must be 0.5% sulphuric acid, in order to avoid flocculation, but this impairs the possibility of methylene blue staining and the count of viable and dead cells. Resuspension can be carried out by sonification.

Put the sample on the slide using a fine tip pipette, following one of the two following procedures.

Procedure 1

Mix well the yeast suspension. If dilutions are required, make decimal dilutions, as usual. If a methylene blue stain is performed, make it on the most diluted sample and mix 1 ml sample with 1 ml methylene blue solution.

Constantly shake the yeast suspension. Take a sample with a fine tip pipette, expel away 4-5 drops of suspension and place a small drop of yeast suspension (diluted if necessary) on each of the two ruled areas of the slide. Cover it with the cover slip within 20 seconds and press firmly with the clips. The counting area should be completely filled, but no liquid should extend to the moat.

Procedure 2

Place the rigid cover slip so that both counting chambers are equally covered. Use the clips to press the cover slip against the support areas until iridescence lines (the Newton rings) appear. When there are no clips, do not move the cover slip when filling the chamber.

Constantly shake the yeast suspension. Take a sample with a fine tip pipette, expel away 4-5 drops of suspension and allow a small drop of sample to flow between the haemocytometer and the cover slip. Do the same in the other part of the slip. The counting area should be completely filled, but no liquid should extend to the moat.

Let the prepared slide stand for three minutes for the yeast cells to settle, and place it under the microscope.

Count 10 medium squares in each ruled area, standardizing procedures must be set, in order to avoid counting twice the same square. Cells touching or resting on the top or right boundary lines are not counted, those resting on bottom or left boundary lines are counted. Budding yeast cells are counted as one cell if the bud is less than one-half the size of the mother cell, otherwise both cells are counted.

To obtain accurate cell counts, it is advisable to count 200 – 500 total yeast cells, on average. Counts from both sides of the slide should agree within 10%. If a dilution is used, the dilution factor must be used in the calculation.

5.4.6. Expression of results

If C is the average number of cells counted in one medium square with 0.2 mm sides, the population T total in the sample is :

Expressed as cells/mL

T= C x 0.25 x10⁶ x dilution factor

If C is the average number of cells counted in one small square with 0.05mm sides, the population T total in the sample is:

Expressed as cells/mL

T= C x 4 x10⁶ x dilution factor

5.4.7. References

European Brewery Convention. Analytica Microbiologica – EBC. Fachverlag Hans Carl, 2001

5.5. Yeast cell count – Methylene blue staining of yeast cells

5.5.1. Scope

This method allows a rapid estimation of the percentage of viable yeast cells, which are not stained, because dead cells are blue-stained. The method is applicable to all samples containing yeasts, except musts containing more than 100 g/l sugar. Bacteria are too small and their staining is not visible with this method.

Note: a good focus should be achieved at various depths, in order to properly see their coloring with methylene blue.

5.5.2. Principle

Methylene blue is converted into its colourless derivative by the reducing activity of viable yeast cells. Dead yeast cells will be stained blue.

Viability is calculated from the ratio between the number of viable cells and the total number of cells. The method overestimates “real” viability when viable cells are less than 80%, because it does not distinguish between “live” cells and their ability to reproduce (Viable But Not Culturable cells).

If the sugar concentration is higher than 100 g/l, most cells are light blue, therefore this method is not recommended.

If wine has low pH and is strongly buffered, the dye cannot work properly. In this case the count must be applied at least to the first decimal dilution.

5.5.3. Reagents and materials

Solution A: Methylene blue distilled water solution, 0.1 g/500 ml.
Solution B: , distilled water solution, 13.6 g/500 ml.
Solution C: x 12 distilled water solution, 2.4 g/100 ml
Solution D: 498.75 ml Solution B + 1.25 ml solution C.
Solution E: Mix the 500 ml of solution D with 500 ml solution A to give final buffered methylene blue solution, with pH approximately 4.6.

5.5.4. Installations and equipment

Microscope, 250-500 x magnifications. Phase contrast is contraindicated.

Microscope slides and cover slips, or haemocytometer (Thoma, Bürker or Neubauer chamber).

Test tube and stirring rod.

Pipettes, fine tips.

5.5.5. Examination techniques

Viability determination

Dilute the suspension of yeast with methylene blue solution in a test tube until the suspension has approximately 100 yeast cells in a microscopic field. Place a small drop of well-mixed suspension on a microscope slide and cover with a cover slip.

Examine microscopically using a magnification of 400 x within 10 minutes contact with the stain.

Count a total of 400 cells (T), noting the number of blue coloured (C) dead, broken, shrivelled and plasmolyzed cells. Budded yeast cells are counted as one cell if the bud is less than one half the size of the mother cell. If the bud is equal or greater than one half the size of the mother cell, both are counted. Cell stained light blue should be considered alive.

5.5.6. Expression of results

If T is the total cell number and C the blue coloured cell number, then the percentage of viable cells is

5.5.7. References

European Brewery Convention. Analytica Microbiologica – EBC. Fachverlag Hans Carl, 2001

Counting of micro-organisms by culture

Objective:

The purpose of counting of microorganisms by culture is to evaluate the level of contamination of the sample, that is to say, to estimate the quantity of viable microorganisms. According to the culture media used and the culture conditions, four types of microorganisms can be counted, namely, yeasts, lactic bacteria, acetic bacteria and mould.

Principle:

Enumeration by culture is based on the fact that micro-organisms are able to grow in a nutrient medium and incubation conditions suitable to form colonies on the medium solidified by agar, or turbidity in a liquid medium. On an agar medium a cell produces bv proliferation a cluster of cells visible to the naked eye called colony.

6.1. Detection, differentiation and enumeration of microorganisms (plate count).

6.1.1. Scope

This standard gives general guidance for the enumeration of viable yeasts, moulds and lactic or acetic bacteria in musts, concentrated musts, partially fermented musts, wines (including sparkling wines) during their manufacture and after bottling, by counting the colonies grown on a solid medium after suitable incubation. The purpose of microbiological analysis is to control the winemaking process and prevent microbial spoilage of musts or wines.

6.1.2. Terms and definitions

The terms “plate” and “Petri dish” are used as synonyms.

CFU = Colony Forming Units.

6.1.3. Method

The number of viable microorganisms present in musts or wines is determined by spreading a small known volume of sample on the surface of a culture medium or adding it as per the incorporation method (see par. 9.5 6.1.7.4), and incubating the plates for the required time in the better conditions for the growth of the microorganisms. Each cell, or cluster of cells, divides and gathers into a cluster and becomes visible as a colony. The number of colonies found on the surface of a plate states for the cells occurring in the original sample so that the results are reported as CFU. If the number of cells in a sample is supposed to be high, suitable serial decimal dilutions are performed in order to obtain colonies ranging from 15 10 to 300 per plate. If the number of CFU in a sample is supposed to be low, they are collected on the surface of a sterile 0.45 to 0.88 μm filter for yeasts of 0.22 to 0.45 µm and for bacteria, which is then placed in the Petri dish on the surface of the culture medium.

The measuring range of this method rises from < 1 CFU/(analyzed volume) to 10⁹ CFU/ml or 10¹⁰ CFU/g in the original sample.

6.1.4. Reagents and materials

As indicated in paragraph 1 of the resolution, plus:

Tubes (16x160 mm or similar) containing 9 ml sterile peptone water (Tryptone: 1 g/l) or other diluents to be used for serial sample dilutions (Appendix 4). An indicative number of tubes required for the following samples is reported below:

Unfermented musts: 4 / sample.

Fermenting musts:7 / sample.

Wines in storage: 2 / sample.

Micropipette holding sterile tips: 1 ml and 0.2 ml.

L-shaped or triangular-shaped bent glass rods (Drigalski rods) or plastic spreaders.

90-mm diameter Petri dishes (56 cm²) (with 15-20 ml of growth medium) for pour plate technique, and 90-mm or 60-mm diameter plates (with 6-8ml of growth medium)for membrane filter technique, filled 18-24 h in advance with 15-20 ml of culture medium (simple or double dishes are required for each sample tested):

For yeasts counts use: YM, YEPD, WL Nutrient Agar, YM Agar or TGY Agar. If searching non-Saccharomyces yeasts, Lysine Agar and WL Differential Agar plates (AppendixAppendix 5, culture medium) or equivalent if validated.

For acetic acid bacteria counts use: GYC agar, G2 or Kneifel medium (AppendixAppendix 5, culture medium) or equivalent if validated

For lactic acid bacteria counts use: MRS plus 20% tomato (or apple- or grape-) juice, or modified ATB Agar (medium for Oenococcus oeni), or TJB plus agar, or Milieu Lafon-Lafourcade, milieu 104, MTB agar (AppendixAppendix 5 culture medium) or equivalent if validated

For filamentous fungi counts use Czapek-Dox modified agar, DRBC agar or MEA added with tetracycline (100 mg/l) and streptomycin (100 mg)l). (Appendix 5 culture medium) or equivalent if validated

Antibiotics must be added in order to make the counting selective since all the microorganisms are together in wine.(see Appendix I culture media)

6.1.5. Installations and equipment

As indicated in paragraph 2 of the resolution.

6.1.6. Sampling

As indicated in paragraph 3 of the resolution

The following amounts of samples are required for the plate counting:

Must, or fermenting must or wine in storage: not less than 250 ml;

Bottled or packed wine: not less than one unit,whatever the capacity;

6.1.7. Examination techniques

6.1.7.1. Preliminary requisites

All the materials and equipments used in the tests must be sterile, and aseptic condition must be kept during all operations.

The laminar flow cabinet must be switched on 5 minutes before starting the work, in order to have a sterile and stable air flow.

6.1.7.2. Sterilization

Culture media must be sterilized in autoclave at 121°C for at least 15 minutes (20 minutes for large volumes). Single-use sterile materials and glassware must be opened and used under laminar flow cabinet. Tweezers and spreading devices must be immersed in ethanol and flamed before use. Stainless steel funnels must be flamed with ethanol after each use, while glass- and polycarbonate funnels must be autoclaved before use, so these ones must be available in the same number as the tested samples.

6.1.7.3. Sample dilution (Appendix 1)

One ml of sample is pipetted in a sterile 9 ml peptone water tube. The tube is stirred with the aid of a “vortex” shaker for 20 seconds. This is the first (decimal) dilution, from which 1 ml is transferred to the next 9-ml sterile peptone water tube, which is the second dilution. After 20 seconds shaking, the operation is repeated until necessary.

The indicative number of serial dilutions required for the following samples is reported below:

Unfermented musts: 4 decimal dilutions.

Fermenting musts: 7 decimal dilutions.

Unfiltered wines during ageing (Yeast counts): 2 decimal dilutions.

Unfiltered wines during ageing (Lactic Acid Bacteria counts) : 6 decimal dilutions.

Filtered wines or packed (bottled) wines No dilution.

Concentrated musts Dilute 10 ml in 100 ml peptone water (or 100ml in 1000ml).

Bottled or filtered wines, and concentrated musts after dilution in sterile peptone water, are analyzed with membrane filter technique.

6.1.7.4. Plating

The necessary serial dilutions are prepared for the number of samples to be plated. Multiple serial dilutions can be prepared, if many samples have to be plated, but any dilution must be plated within 20 minutes.

Inoculate each plate with 0.1 or 0.2 ml of the three lowest dilutions prepared, as follows:

Unfermenting musts: dilutions -2; -3; -4.

Fermenting musts: dilutions -5; -6; -7.

Unfiltered wines during ageing :dilutions 0; -1; -2.

In doubt, inoculate a higher number of dilutions, never a lower.

Under aseptic conditions (preferably under a laminar flow cabinet) spread the sample on the surface of the culture media before the liquid is absorbed (usually within 1-2 minutes) with a sterile bent glass rod (Drigalski rods) or a single-use one. A separate “hockey stick” must be used for each plate, or the plate must be spread starting with the most diluted sample and proceeding to the least dilute ones. Leave the plates some minutes under sterile air flow, until the liquid is absorbed.

Note 1: Plating 0.,2 ml instead of 0.1 ml, as frequently reported, allows an easier spreading and a delayed one. Calculations must consider this.

Note 2: For the enumeration of yeast Bacterial growth is avoided by adding 50 mg/l chloramphenicol (or equivalent if validated) to growth media, after autoclaving it, and the mold by adding biphenyl 150mg/L (or equivalent if validated).

Note 3: For the enumeration of lactic acid bacteria, yeasts growth is prevented by the addition of natamycin (pimaricin) (0.1 g/L) (or equivalent if validated) and acetic bacteria by anaerobic incubation.

Note 4: For the enumeration of acetic bacteria, the growth of yeast is prevented by the addition of natamycin (pimaricin) (0.1 g/L) (or equivalent if validated) and that of lactic acid bacteria with the addition of penicillin (12.5 mg/L) (or equivalent if validated).

The addition of antibiotics is done after the autoclave sterilization.

If a specific research of non-Saccharomyces yeast is performed, inoculate as previously described, three Lysine Agar plates and three WL Differential Agar plates with the appropriate dilutions

Incorporation method (alternative method).

Prepare and sterilize 15 ml of medium in tubes, and keep the tubes in a water bath (or equivalent if validated) at 471°C.

Pour 1 ml of sample or dilution in an empty Petri dish.

Add 15 ml culture medium and stir gently the Petri dish, so as to obtain a homogeneous distribution of microorganisms within the mass of the medium.

Allow to cool and solidify by placing the Petri dishes on a cool horizontal surface (the solidification time of the agar shall not exceed 10 min).

6.1.7.5. Enumeration with concentration by membrane filtration

Membrane porosity must be 0.45 or 0.8 µm for yeast counting; 0.2 or 0.45 μm for counting bacteria. Membrane surface must be preferably be cross-hatched, in order to facilitate the colony counting.

The plates, on which the membranes are put, can contain an agar nutrient medium or a pad, in which the dry medium is dispersed, that must be soaked with sterile water just before the use. Some suppliers give sterile plates containing a sterile pad, on which the content of 2-ml of single-use sterile liquid medium is poured just before the use.

Aseptically assemble the filtration equipment, sterilize the funnel according to 9.2, and connect to the vacuum-producing system.

Dip the tweezers in ethanol and flame them: when the flame is extinguished, wait some seconds and put the membrane, with the tweezers, on its holder of the filtration unit.

Before opening the bottle, shake it well; dip the bottleneck upside-down in ethanol (1-2 cm) and flame to sterilize it.

Of each sample sample three amounts: 10 ml with a sterile 10-ml pipette, 100 ml with a sterile cylindrical 100-ml pipette, and the rest direct from the bottle, if possible. To filter the wine, pour the wine into the funnel.

When the desired amount of wine has been filtered, release the vacuum, flame the tweezers, open the funnel, keep the membrane with the tweezers, put its opposite edge on the solid medium of a plate and make it adhere to the medium surface, avoiding bubble formation beneath.

6.1.7.6. Sample incubation

Incubate the plates, upside-down, aerobically 4 days at 25 2 C, for yeast or for acetic acid bacteria. If temperature is < 23°C extend incubation one more day, if temperature is < 20°C extend three more days. The maximum temperature must not exceed 28°C.

In case of performing Brettanomyces (or Dekkera) yeast counts, increase twofold the incubation time.

In case of performing LAB count, put the plates in an anaerobic jar or bag, and incubate the plates upside-down 10 days at 30 2 C. If temperature is < 28°C extend incubation one more day, if it is < 25°C extend three more days. The maximum temperature must not exceed 33°C.

6.1.8. Expression of results

6.1.8.1. Counting yeast colonies and bacteria.

Count the colonies grown in 4 days for the yeast and acetic acid bacteria (8 days for Brettanomyces/Dekkera yeasts), and 10 days for lactic bacteria, if necessary with the aid of a colony counter, ignoring the different colony morphology if performing a total yeast count, or considering it, if required.

The media and incubation conditions are specific enough for it to be possible to count the different types of micro-organisms in the colonies visible to the naked eye.

6.1.8.2. Calculation of results.

The most reliable results come from counting plates containing from 10 to 300 colonies (ISO 7218:2007 - Microbiology of food and animal feeding stuff - General rules for microbiological examinations).

Calculate the number N of microorganisms present in the test sample as a weighted mean from two successive dilutions using the following equation:

where

is the sum of colonies counted on the two dishes retained from two successive dilutionns, at least one of which contains a minimum of 10 colonies.
V is the volume of the inoculum placed in each dish, in millilitres.
d is the dilution corresponding to the first dilution retained [d=1 when the undiluted liquid product (test sample) is retained].

In other words, if plates from two consecutive decimal dilutions contain 10-300 colonies, compute the number of CFU/ml for each dilution, and then the average of the two values: this is the CFU/ml value of the sample. If one value is greater than the double of the other, keep the lower one as CFU/ml.

Round off the results to two significant figures only at the time of conversion to CFU/ml, and express the results as a number between 1,0 and 9,9 multiplied by the appropriate power of 10 (ISO 7218:2007 - Microbiology of food and animal feeding stuff - General rules for microbiological examinations).

If samples were inoculate in duplicate series, and one or two plates, inoculated with the same dilution, contain colonies, compute the average of the number of colonies and multiply by the reciprocal of the dilution factor, to obtain the number of CFU/ml.

If there is no plate containing 10-300 colonies, and all plates contain more than 300 colonies, count the less crowded ones. If they contain less than 10 colonies/cm², count 12 squares of 1 cm² and multiply the average by 56 (the area of a 90-mm diameter plate); if colonies are more crowded, count 4 squares of 1 cm² and multiply the average by 56. Express the results as “Estimated CFU/ml”. Do not express the results as TNTC (Too numerous to count) whenever possible.

If the only plates containing colonies contains less than 10 colonies, but at least 4, calculate the result as given in the general case, and report it as “Estimated CFU/ml”.

If the total is from 3 to 1, the precision of the result is too low, and the result shall be reported as “(the searched microorganisms) are present but less than 4 × d CFU/ml”.

If plates from all dilutions of any sample have no colonies, report the results as “less than 1/d CFU/ml”, but consider the possible presence of inhibitors in the sample.

When performing membrane filtration technique, express the results referring to the amount of filtered liquid, e.g. CFU/bottle, CFU/100 ml, or CFU/10ml.

6.1.9. Uncertainity of measure

6.1.9.1. Criteria of controlling the results.

For each lot of medium, one plate is used as sterility control after sterilization. One plate per each culture medium used during the tests, is left opened under laminar flow cabinet during all operations, as a sterility check of the working environment. That plate will be incubated as the inoculated ones.

Periodically, one sample is inoculated in double, and the experimental K_p is calculated with the following equation:

where and are the results of the two counts.

If Kp < 1.96 ≈ 2.,0 the results are acceptable: the average of the two counts can be used as the result.

If 2.0<Kp ≤ 2.576 ≈ 2.6 the difference of the two counts is critical, and must be carefully evaluated before accepting the results as the average of the two counts.

If Kp >2.6 the difference of the two counts is anomalous. The result is rejected and the test must be repeated. In such event the person in charge of the laboratory must examine all the results obtained after the last acceptable ones.

6.1.9.2. Uncertainty of measure

If the number of counted colonies in the countable plate is lower than 10, the result is acceptable, but the population of colonies is considered to follow the Poisson distribution. The 95% confidence level, and consequently the uncertainty of measure, of the estimated count made on a single Petri dish, is reported in the following table.

	Number of. colonies		Confidence limit at 95% level				Percent error of the limit *
			Lower		Upper		Lower		Upper
	1		<1		6		-97		457
	2		<1		7		-88		261
	3		<1		9		-79		192
	4		1		10		-73		156
	5		2		12		-68		133
	6		2		13		-63		118
	7		3		14		-60		106
	8		3		16		-57		97
	9		4		17		-54		90
10		5		18		-52		84
11		6		20		-50		79
12		6		21		-48		75
13		7		22		-47		71
14		8		24		-45		68
15		8		25		-44		65
* Compared to the microrganism count (1^st column)

If the colony count is >10, the confidence limit at a p probability level is calculated with the following equation:

where is the number of colonies on the plate, and K_p is the coverage factor. Usually the coverage factor is 2, or 1.96. C value is calculated from each plate and multiplied by the number of dilutions, together with the result of the count.

6.2. Culture in liquid medium- "Most Probable Number" (MPN)

6.2.1. Objective

The purpose of this technique is to evaluate the number of viable microorganisms in wines having high contents of solid particles in suspension and/or high incidence of plugging.

6.2.2. Principle

This technique is based on the estimation of the number of viable microorganisms in liquid medium, starting from the principle of its normal distribution in the sample.

6.2.3. Diluents and liquid culture media (see Appendices 4 and 5)

6.2.4. Operating method

Several quantitative and successive solutions are prepared and following this, after incubation, a certain proportion of tests will not lead to any growth (negative tests), while others will begin to grow (positive tests). If the sample and the dilutions are homogeneous, and if the number of dilutions is sufficiently high, it is possible to treat the results statistically, using suitable tables (tables based on McCrady's probability calculations), and to extrapolate this result to the initial sample.

6.2.5. Preparation of dilutions

Starting from a sample of homogenized wine, prepare a series of decimal dilutions (¹/₁₀) in the diluent.

Take 1 mL of wine and add to 9 mL of diluent in the first tube. Homogenize. Take 1 mL of this dilution to add to 9 mL of diluent in the second tube. Continue this dilution protocol until the last suitable dilution, according to the presumed microbial population, using sterilized pipettes for each dilution. The dilutions must

be made until extinction, i.e. the absence of development in the lowest dilutions (appendix 2).

6.2.6. Preparation of inoculations

Inoculate 1 mL of wine and 1 mL of each of the prepared dilutions, mixed at the time, in, respectively, 3 tubes with the appropriate culture medium (appendix 5). Mix thoroughly.

Incubate the inoculated tubes in the incubator at 25°C for yeasts (3 days, up to 10 days), under aerobic conditions, and for lactic bacteria, under anaerobic or microaerophilic conditions (8 days, up to 10 days), making periodic observations up to the last day of incubation.

6.2.7. Results

All those tubes that show a microbial development leading to the formation of a whitish deposit, more or less evident and/or with a more or less marked disturbance are considered as positive. The results must be confirmed by observation through a microscope. Specify the incubation period.

The reading of the tubes is made by noting the number of positive or negative tubes in each combination of three tubes (in each dilution). For example, "3-1-0" signifies: 3 positive tubes in the 10⁰ dilution (wine), 1 in the 10^-1 dilution and zero in the 10^-2 dilution.

For a number of dilutions higher than 3, only 3 of these results are significant. To select the results allowing for the determination of the "MPN", it is necessary to determine the "typical number" according to the examples in the following table:

Table:

Number of positive tubes for each dilution						Typical number
Example	10	10	10	10	10	3-1-0
a	3	3	3	1	0	3-2-0
a	3	3	2	0	0	3-2-1
a	3	2	1	0	0	3-0-1
a	3	0	1	0	0	3-2-3
b	3	2	2	1	0	3-2-3
b	3	2	1	1	0	3-2-2
c	2	2	2	2	0	2-2-2
d	0	1	0	0	0	0-1-0
Example a : take the greatest dilution for which all the tubes are positive and the two following ones. Example b : if a positive result is achieved for a dilution that is bigger than the last chosen dilution, it must be added. Example c : if no dilution achieves three positive tubes, take the dilutions that correspond to the last three positive tubes. Example d : instance of a very small number of positive tubes. Choose the typical number so that the positive dilution is in the ten’s row.

Adapted from Bourgeois, C.M. and Malcoste, R. in : Bourgeois,

C.M. et Leveau, J.Y. (1991).

Calculation of the Most Probable Number (MPN)

Taking account of the typical number obtained, the MPN is determined through Table A (Appendix 3) based on McCrady's probability calculations, considering the dilution made. If the dilution series is 10⁰ ; 10^-1 ; 10^-2 the reading is direct. If the dilution series is 10¹; 10⁰; 10^-1 the reading is 0.1 times this value. If the dilution series is 10^-1; 10^-2; 10^-3; the reading is 10 times this value.

Comment:

If there is a need to increase the sensitivity, a concentration 10¹ of wine can be used. To obtain this concentration of microorganisms in 1 mL, centrifuge 10 mL of wine and take 1 mL of deposit (after having taken 9 mL of excess liquid) and inoculate according to the previously described method.

6.2.8. Expression of Results

The microorganism content of wine must be expressed in cells per mL, in scientific notation to one decimal place. If the content is lower than 1.0 cells per mL, the result must be presented as "<1.0 cells per/mL".

(See annexes on following pages)

Bibliography

ISO 4833:2003. Microbiology of food and animal feeding stuffs – Horizontal medium for the enumeration of microorganisms – Colony count technique at 30°C.
ISO 7218:2007 - Microbiology of food and animal feeding stuff - General rules for microbiological examinations.
ISO 7667:1983. Microbiology - Standard layout for methods of microbiological examination.
Pallman, C., J. B. Brown, T. L. Olineka, L. Cocolin, D. A. Mills and L. F. Bisson. 2001. Use of WL medium to profile native flora fermentations. American Journal of Enology and Viticulture 52:198-203;
A. Cavazza, M. S. Grando, C. Zini, 1992. Rilevazione della flora microbica di mosti e vini. Vignevini, 9-1992 17-20.- ANDREWS, W. et MESSER, J. (1990). Microbiological Methods. in : AOAC Official Methods of Analysis, 15th edition, 1, 425-497, Association of Analytical Chemist, Washington.
BIDAN, P. (1992). Analyses Microbiologiques du Vin. F.V. O.I.V. nº 910, Paris.
BOURGEOIS, C.M. et LEVEAU, J.Y. (1991). Techniques d'analyse et de contrôle dans les industries agro alimentaires, 2ème édition, 3. Le Contrôle Microbiologique Lavoisier, Tec. & Doc., APRIA Ed. Paris.
CARR, J. G. (1959). Acetic acid bacteria in ciders. Ann. Rep. Long Ashton Res. Sta., 160.
DE MAN, J. C. (1975). The probability of most probable number. European Journal of Applied Microbiology, 1, 67-78.
LAFON-LAFOURCADE, S. et al. (1980). Quelques observations sur la formation d'acide acétique par les bactéries lactiques. Conn. Vigne Vin, 14, 3, 183-194.
MAUGENET, J. (1962). Les Acétobacter du cidre. Identification de quelques souches. An. Technol. Agric., 11, 1, 45-53.
PLARIDIS et LAFON-LAFOURCADE, S. (1983). Contrôle microbiologique des vins. Bull. O.I.V., 618, 433-437, Paris.
RIBÉREAU-GAYON, J. et PEYNAUD, E. (2004). Traité d'Oenologie, Tome 2, Librairie Polytechnique CH. Béranger, Paris et Liège.
Standard Methods for the Examination of Water and Waste Water (1976). 14th edition, American Public Health Association, Incorporated, New York.
Standard Methods for the Examination of Water and Waste Water (1985). 16th edition, American Public Health Association, DC 20005, Washington.
VAZ OLIVEIRA, M., BARROS, P. et LOUREIRO, V. (1995). Analyse microbiologique du vin. Technique des tubes multiples pour l'énumération de micro-organismes dans les vins - "Nombre le plus probable" (NPP), F.V. O.I.V. nº 987, Paris.
VAZ OLIVEIRA, M. et LOUREIRO, V. (1993). L'énumération de micro-organismes dans les vins ayant un indice de colmatage élevé, Compte rendu des travaux du groupe d'experts "Microbiologie du Vin" de l'O.I.V., 12ème session, annexe 2, Paris.
VAZ OLIVEIRA, M. et LOUREIRO, V. (1993). L'énumération de micro-organismes dans les vins ayant un indice de colmatage élevé, 2ème partie, Doc. Travail du groupe d'experts "Microbiologie du Vin" de l'O.I.V., 13ème session, Paris.

Appendix 2 : Preparation of dilutions and inoculatons

Appendix 3 Table A

"Most Probable Number" (MPN) for 1 mL sample utilizing 3 tubes

with 1 mL, 0.1 mL et 0.01 mL

	Positive tubes					Positive tubes				Positive tubes
1 mL			0,1 mL	0,01 mL	MPN 1 mL	1 mL	0,1 mL	0,01 mL	MPN 1 mL	1 mL	0.1 mL	0,01 mL	MPN 1 mL
		0	0	0	0,0	2	0	2	2,0	1	1	1	7,5
		0	0	1	0,3	2	1	0	1,5	3	1	2	11,5
		0	1	0	0,3	2	1	1	2,0	3	1	3	16,0
		0	1	1	0,6	2	1	2	3,0	3	2	0	9,5
		0	2	0	0,6	2	2	0	2,0	3	2	1	15,0
		1	0	0	0,4	2	2	1	3,0	3	2	2	20,0
		1	0	1	0,7	2	2	2	3,5	3	2	3	30,0
		1	0	2	1,1	2	2	3	4,0	3	3	0	25,0
		1	1	0	0,7	2	3	0	3,0	3	3	1	45,0
		1	1	1	1,1	2	3	1	3,5	3	3	2	110,0
		1	2	0	1,1	2	3	2	4,0	3	3	3	>140,0
		1	2	1	1,5	3	0	0	2,5
		1	3	0	1,6	3	0	1	4,0
		2	0	0	0,9	3	0	2	6,5
		2	0	1	1,4	3	1	0	4,5

Adapted from the “ Standard Methods for the Examination of Water and Waste Water ” (1976)

Appendix 4

Diluents:

Diluents are indicated by way of example. The water to be used must be distilled, double distilled or deionized, with no traces of metals, inhibitors or other anti- microbial substances.

Physiological water

Preparation: Weigh 8.5g of sodium chloride in a 1000 mL calibrated flask. After it has dissolved in the water, adjust the reference volume. Mix thoroughly. Filter. Distribute 9 mL in the test tubes. Stop with carded cotton and autoclave for 20 min at 121°C.

Ringer's solution 1/4

Preparation: Weigh 2.250g of sodium chloride, 0.105g of potassium chloride, 0.120g of calcium chloride (CaCl2.6H2O) and 0,050g of sodium hydrogen carbonate in a 1000 mL calibrated flask. After it has dissolved in water, make up to the mark. Mix thoroughly. Distribute 9 mL in the test tubes. Stop with carded cotton and autoclave for 15 min at 121°C. (This solution is available commercially)

Peptone water

Preparation: Weigh 1g of peptone in a 1000 mL calibrated flask. After it has dissolved in the water, adjust the reference volume. Mix thoroughly. Distribute 9 mL in the test tubes. Stop with carded cotton and autoclave for 20 min at 121°C.

Appendix 5

Culture media

Culture media and antimicrobials are indicated by way of example.

The water to be used must be distilled, double distilled or deionized with no traces of metals, inhibitors or other antimicrobial substances.

Solid culture media

If not otherwise stated, pH of all media should be adjusted to pH 5.5 -6.0

Media for yeast count

1.1. YM

Glucose: 50 g

Peptone: 5 g

Yeast extract: 3 g

Malt extract: 3 g

Agar-agar: 20 g

Water: up to 1000 ml

If necessary add 100 mg chloramphenicol to suppress bacterial growth and 150 mg biphenyl to suppress mould growth.

1.2. YEPD

Glucose: 20 g

Peptone: 20 g

Yeast extract: 10 g

Agar-agar: 20 g

Water: up to: 1000 ml

If necessary add 100 mg chloramphenicol to suppress bacterial growth and 150 mg biphenyl to suppress mould growth.

1.3. WL Nutrient Agar

Glucose: 50 g

Peptone: 5 g

Yeast extract: 4 g

Potassium phosphate monobasic ():0.55 g

Potassium chloride (KCl): 0.425 g

Calcium chloride (Ca):0.125 g

Magnesium sulphate (Mg): 0.125 g

Ferric chloride (Fe):0.0025 g

Manganese sulphite (Mn):0.0025 g

Bromcresol green: 0.022 g

Agar bacteriological: 12 g

Water: up to: 1000 ml

pH: 5.5

WL Differential agar is made by adding 4 mg/l cycloheximide to WL Nutrient Agar.

If necessary add 100 mg chloramphenicol to suppress bacterial growth.

1.4. Lysine Agar ASBC

Solution A:

Yeast Carbon Bass: 2.35 g

Water: up to: 100 ml

Sterilize by membrane filtration.

Solution B:

Lysine-HCl: 0.5 g

Agar agar: 4 g

Water: up to: 100 ml

Sterilize in 20 min. at 121C.

If necessary add 100 mg chloramphenicol to suppress bacterial growth.

Media for lactic acid bacteria count

2.1. M.R.S. + tomato (or apple) juice.

Glucose: 20 g

Peptone: 10 g

Beef extract: 8 g

Yeast extract: 4 g

Potassium phosphate, dibasic (): 2 g

Sodium acetate 3O: 5 g

Ammonium citrate: 2 g

Magnesium sulphate 6O: 0.2 g

Manganese sulphate 4O: 0.05 g

"Tween 80": 1 ml

Agar agar: 12 g

Tomato (or apple, or grape) juice: 200 ml

Water up to : 1000 ml

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, after autoclaving, just before use.

2.2. Tomato Juice Agar

Tomato juice (dry extract from 400 ml): 20 g

Peptone: 10 g

Peptonized milk: 10 g

Agar-agar: 14 g

Water : 1000 ml

pH: 6.1

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, after autoclaving, just before use.

2.3. Modified ATB medium, or Oenococcus oeni medium (formerly Leuconostoc oenos medium).

Solution A:

Glucose: 10 g

Yeast extract : 5 g

Peptone : 10 g

Magnesium sulphate: 0.2 g

Manganese sulphate: 0.050 g

Tomato juice (or apple juice or grape juice): 250 ml

Agar agar: 12 g

Water: 750 ml

Sterilize by autoclaving 20 min. at 121C.

Solution B:

Cysteine HCl: 1 g

Water: up to: 100 ml

pH : 4.8

Sterilize by membrane filtration.

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, just before use.

Add 1 ml of solution B to 20 ml of solution A at the moment of use

2.4. Lafon-Lafourcade medium

Glucose: 20 g

Yeast extract: 5 g

Beef extract: 10 g

Peptone: 10 g

Sodium acetate: 5 g

Tri-ammonium citrate: 2 g

Magnesium sulphate 6O: 0.2 g

Manganese sulphate  4O 0.05 g

"Tween 80": 1 ml

Agar-agar: 20 g

Water: up to: 1000 ml

pH: 5.4

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, after autoclaving, just before use.

2.5. Dubois medium (Medium 104)

Tomato juice: 250 ml

Yeast extract: 5 g

Peptone: 5 g

Malic acid: 3 g

Magnesium sulphate  6O:0.05 g

Manganese sulphate  4O: 0.05 g

Agar-agar: 20 g

Water: up to: 1000 ml

pH: 4.8

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, after autoclaving, just before use.

2.6. MTb.

Glucose: 15 g

Lab-Lemco Powder (Oxoid): 8 g

Hydrolyzed casein: 1 g

Yeast extract: 5 g

Tomato juice: 20 ml

Sodium acetate: 3 g

Ammonium citrate: 2 g

Malic acid: 6 g

Magnesium sulphate: 0.2 g

Manganese sulphate: 0.035 g

"Tween 80": 1 mg

TC Vitamins Minimal Eagle, 100x (BD-Difco) 10 ml*

pH (con KOH): 5.0

Water up to: 1000 ml

* add after sterilization.

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, after autoclaving, just before use.

Media for acetic acid bacteria count

3.1. GYC

Glucose: 50 g

Yeast extract: 10 g

Calcium carbonate (Ca): 30 g

Agar: 25 g

Water: up to: 1000 ml

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, and 12.5 mg/L of penicillin to eradicate the growth of lactic acid bacteria, after autoclaving, just before use.

3.2. Medium G2

Yeast extract: 1.2 g

Ammonium phosphate: 2 g

Apple juicE: 500 ml

Agar: 20 g

Water: up to: 1000 ml

pH: 5.0

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, and 12.5 mg/L of penicillin to eradicate the growth of lactic acid bacteria after autoclaving, just before use.

3.3. Kneifel medium

Yeast extract: 30 g

EthanoL: 20 ml*

Agar: 20 g

Bromocresol green 2.2%: 1mL

Water: up to1000 ml

* to be added after sterilization.

Add 100mg / L natamycin (pimaricin) to inhibit the growth of yeasts, and 12.5 mg/L of penicillin to eradicate the growth of lactic acid bacteria after autoclaving, just before use.

Blue colonies: Acetobacter, Gluconacetobacter

Green colonies: Gluconobacter

Media for mould count

4.1. Czapek-Dox, Modified

Sucrose: 30 g

NaNO₃: 3 g

K₂HPO₄: 1 g

MgSO₄: 0.5 g

KCl: 0.5 g

FeSO₄ : 0.01g

Agar 15 g

Final pH (at 25°C) 7.3 0.2

Add 10 mg/l cycloheximide to suppress yeast growth (cycloheximide-resistant yeast growth is usually slower than mould growth).

Note: This medium allows the growth only of nitrate-growing moulds.

Add tetracycline (100 mg/l) and streptomycin (100 mg/l) to suppress growth of bacteria.

4.2. Dichloran Rose Bengal Chloramphenicol Agar (DRBC Agar)

Glucose: 10 g

Peptone : 5 g

KH₂PO₄: 1 g

MgSO₄ :0.5 g

Rose Bengal: 0.025 g

Dichloran (2,6 dichloro-4-nitroaniline) : 0.002g

Chloramphenicol solution (0.1 g/10ml)*: 10 ml

Agar : 15 g

Final pH (at 25°C) 5.6 0.2

* To be added after sterilization.

4.3. Malt Extract Agar (MEA)

Glucose: 20 g

Malt extract : 20 g

Peptone: 5 g

Agar : 15 g

Final pH (at 25°C) 5.5 0.2

Add tetracycline (100 mg/l) and streptomycin (100 mg/l) to suppress growth of bacteria.

Liquid culture media
1. For yeasts

YEPD medium (Yeast Extract, Peptone, Dextrose) + chloramphenicol

Preparation: Weigh 10.0g of yeast extract (Difco or equivalent), 20g of peptone, 20g of glucose and 100 mg of chloramphenicol. Dissolve, make up to 1000 mL volume with water and mix.

Distribute 5 mL portions of this medium in the test tubes and autoclave for 15 minutes at 121°C.

5.2. For lactic bacteria

MTJ medium (50% MRS medium "Lactobacilli Man Rogosa and Sharpe

Broth" + 50% TJB medium "Tomato Juice Broth") + actidione

Preparation: Weigh 27.5g of MRS "Lactobacilli Man Rogosa and Sharpe Broth" (Difco or equivalent). Add 500 mL of water, heat to boiling to permit complete dissolution and add 20.5g of TJB "Tomato Juice Broth" (Difco or equivalent). Add 50g of actidione. Dissolve with water in order to obtain 1000 mL of solution having first corrected the pH to 5 with 1N hydrochloric acid and mix.

Distribute 10 mL portions of this medium [3)] in the tubes and autoclave for 15 minutes at 121°C.

Appendix 6: Recognition of specific microorganisms

6.1. Yeast colony recognition on WL Nutrient Agar.

The use of this medium does not want to be a method to identify species, but can offer to non-specialized laboratories a quick and cheap way to predict the genus of viable and culturable yeasts. After 4-days incubation evaluate the colony morphology as follows (Pallman, C., J. B. Brown, T. L. Olineka, L. Cocolin, D. A. Mills and L. F. Bisson. 2001. Use of WL medium to profile native flora fermentations. American Journal of Enology and Viticulture 52:198-203; A. Cavazza, M. S. Grando, C. Zini, 1992. Rilevazione della flora microbica di mosti e vini. Vignevini, 9-1992 17-20):

Saccharomyces spp.: Colonies grow well in 4 days on WL Nutrient Agar giving circular cream-coloured to pale greenish colonies. Different colour shades do not necessary indicate the presence of different strains, but the presence of petite mutants; colonies are umbonated, smooth and dull surface, the consistency is butyrous. It doesn’t grow on Lysine Agar.

Torulaspora spp.: the colonies are similar to those of Saccharomyces spp. It grows on Lysine Agar.

Hanseniaspora spp. (Kloeckera spp.) Grows on WL Nutrient Agar in 4 days, giving deep green flat, smooth and butyrous colonies. It grows on Lysine Agar and on WL Differential Agar.

Candida stellata Grows on WL Nutrient Agar in 4 days, giving pea-green, smooth and butyrous colonies, becoming darker in the centre with the age. It grows on Lysine Agar.

Saccharomycodes spp.Grows on WL Nutrient Agar in 4 days, giving light green, smooth and butyrous convex colonies. It grows on Lysine Agar, not on WL differential agar.

Note: its cells, viewed under the microscope, are very large (up to 25 m).

Schizosaccharomyces pombe Grows on WL Nutrient Agar in 4 days, giving deep green pinpoint size, smooth colonies. It grows on Lysine Agar.

Note: its cells, under the microscope are easily recognised because of typical scission division.

Rhodotorula spp. Grows on WL Nutrient Agar in 4 days, giving deep pink, smooth and mucous surface and butyrous colonies. It grows on Lysine Agar.

Metschnikowia spp. Grows on WL Nutrient Agar in 4 days, giving clear, smooth and butyrous little colonies. A reddish pigment diffuses in the medium below the colonies. It grows on Lysine Agar.

Pichia membranifaciens Grows on WL Nutrient Agar in 4 days, giving greyish- or bluish-shaded rough and powdery convex colonies. It grows on Lysine Agar.

Pichia anomala (formerly Hansenula anomala) grows on WL Nutrient Agar in 4 days, giving cream-colored or bluish colonies, distinctly bluish after 8 days. Colonies are circular, the surface is smooth and the consistency is butyrous, but sometimes clearly mucous. It grows on Lysine Agar.

Dekkera spp. or Brettanomyces spp. Grows on WL Nutrient Agar in 8 days, giving small dome-shaped, cream-coloured, smooth and butyrous colonies. It produces high amounts of acetic acid, clearly perceivable by smell that turns the medium to yellow. It grows on Lysine Agar and on WL Differential Agar. The growth on this last medium makes it possible to distinguish it from Zygosaccharomyces bailii.

Note: a confirmation is possible with microscopical examination: Dekkera has small cells, some of them have a typical ogival shape.

Zygosaccharomyces bailii Grows on WL Nutrient Agar in 4 days, giving small circular cream-coloured, smooth and butyrous colonies. It grows on Lysine Agar but not on WL Differential Agar. A yellowish halo is often present around young colonies.

Note: when grown on bottled wine it produces brown 0,5-1 mm clusters. Its cells do not have ogival shape.

Acetic acid bacteria grow on WL Nutrient Agar with small to pinpoint-size deeply green and brilliant colonies that are strongly positive to catalase test. (Note – This medium is not suitable for their count).

Lactic Acid Bacteria grow on WL Nutrient Agar in 10 days with pinpoint size clear catalase-negative colonies. (Note – This medium is not suitable for their count).

6.2. Lactic Acid Bacteria colony recognition.

LAB colonies are translucent and range in size from a pinpoint to a few mm in diameter. They are gram-positive and catalase-negative. Oenococcus oeni grow in short chains, pediococci form tetrads and diplococci, lactobacilli form long or short bacilli.

6.3. Acetic Acid Bacteria colony recognition.

AAB colonies are catalase positive and gram-negative, and are strong acid-producers: this can be seen by a clear zone around their colonies in media containing calcium carbonate or by a different colour if the medium contains a pH indicator. Their cells are cocci or bacilli, generally a little larger than LAB.

[3)] The 10 mL volume is used instead of the 5 mL volume as with yeasts, due to the greater sensitivity of lactic bacteria to oxygen.

Detection of preservatives and fermentation inihibitors (Fermentability Test) (Type-IV)

OIV-MA-AS4-02A Detection of preservatives and fermentation inhibitors

Type IV method

Fermentability Test

1.1. Objective

To show without specifying their nature, the possible presence of one or several substances which act as fermentation inhibitors in wine.

1.2. Principle

The wine, whose free sulfur dioxide has been bound by addition of an aqueous solution of acetaldehyde, is brought to 10% (v/v) alcohol. Glucose is added in order for the sugar concentration to be between 20 and 50 g/L in the nutrient solutions.

After inoculation with a yeast strain resistant to alcohol, the fermentation is followed by weighing the quantity of carbon dioxide released.

The fermentation rate is compared to that of an authentic natural wine similar in make up to the wine analyzed, and also to that of the test wine whose pH has been adjusted to 6 (the majority of the mineral and organic acids are not active in fermentation at this pH). These two reference wines are inoculated in the same manner as the test wine.

1.3. Apparatus

90 mL flask sealed with a rubber stopper with a hole into which is placed a narrow tube tapered at the uppermost portion.

1.4. Reagents and media

1.4.1. Aqueous acetaldehyde solution:

Solution prepared from acetaldehyde obtained by distillation of metaldehyde or paraldehyde, in the presence of sulfuric acid, and standardized by the method using sodium sulfite. Adjust the concentration of the solution to 6.9 g/L.

1 mL of this solution fixes 10 mg of sulfur dioxide.

1.4.2. Nutrient Solutions:

Ammonium Sulfate, :25 g/L

Asparagine 20 g/L

These solutions must be stored in the refrigerator.

1.4.3. Culture Medium:

Solid medium: malt agar.

Powdered malt 3 g

Glucose 10 g

Pancreatic peptone 5 g

Powdered yeast extract 3 g

Agar 20 g

Water 1 L

pH 6

Sterilize for 20 min. at 118 °C.

This mixture exists in a commercial prepared form.

Liquid medium (an option):

Divide the grape juice containing 170 to 200 g/L of sugar, in tubes stoppered with cotton, at a rate of 10 mL per tube; sterilize in a water bath at 100 °C for 15 min.
Liquid malt: same medium as the solid medium, but without agar.
1. Culture and maintenance of the Saccharomyces bayanus strain and preparation of the yeast.

a) Culture and maintenance of the strain on solid medium: From a collection strain, inoculate in lines (streak) onto tubes of solid medium. These tubes are put in an incubator at 25°C until the culture is very visible (about 3 days); the tubes can be stored in the refrigerator. This is sufficient for 6 months.

b) Preparation of the yeast:

One of the tubes of the liquid medium is inoculated in accordance with proper microbiological techniques from the strain cultivated on solid medium; after growth (24 to 48 h), repeat 2 times successively into the same medium enriched with 10% alcohol (v/v), to acclimate the strain.

The second culture when actively fermenting will contain about 50 million yeast per milliliter. This culture will serve to inoculate the wine to be studied. Perform a count and inoculate at a rate of yeast/mL.

1.5. Procedure

Preparation of the wine:

100 mL of wine is treated with the necessary quantity of acetaldehyde calculated in accordance with the amount of free sulfur dioxide (44 mg of aldehyde binds 64 mg of sulfur dioxide). Wait 24 hours and check that the wine contains less 20 mg free sulfur dioxide per liter.

If the alcoholic strength is greater than 10% (v/v), the wine should be diluted with one of the solutions of glucose and water in amounts calculated to result in a sugar concentration between 20 and 50 g/L, and to reduce the strength to about 10% (v/v). For wines containing less than 10% vol., add solid glucose to bring without dilution the amount of sugar between these values, so the fermentation rate is not altered by the amount of sugar.

Fermentability test:

In a 90 mL flask, place 60 mL of wine prepared as above, 2.4 mL of ammonium sulfate solution and 2.4 mL of asparagine solution. Inoculate with 3 drops of a 3 day old culture of Saccharomyces bayanus, to obtain an initial population close to 10⁵ yeast/mL. Install the stopper with the pointed tube, weigh the assembly to the nearest 10 mg and place in an oven at 25°C.

Weigh daily for at least 8 days.

Run each time concurrently, a wine of comparable make up and origin which does not contain any preservative along with the test wine which has been adjusted to pH 6.

A flask of non-inoculated wine indicates loss by evaporation.

1.6. Interpretation

In most cases, the fermentation begins within 48 hours and the daily liberation of gas is greatest between the 3rd and the 5th day.

One can confirm the presence of a fermentation inhibitor only in the following conditions:

a) If the fermentation does not begin or is delayed at least 2 days compared to one of the 2 controls. When the delay is brief, it is difficult to ascertain the presence because there may be "false positive" results, since certain natural sweet wines sometimes behave as if they contained traces of inhibitors (in particular sweet wines made from grapes having noble rot).

b) If the maximum daily release has not taken place between the 3rd and 5th day, but after the 7th day, this release must be greater than or equal to 50 mg for 60 mL of wine.

Plotting the fermentation curve and the curve of daily release of as a function of time can facilitate the interpretation in a difficult case.

Detection of preservatives and fermentation inihibitors (Detection of the following acids: sorbic, benzoic, p-chlorobenzoic, salicylic, phydroxybenzoic and its esters) (Type-IV)

OIV-MA-AS4-02B Detection of preservatives and fermentation inhibitors

Type IV method

Detection of the following acids: sorbic, benzoic, p-chlorobenzoic, salicylic, phydroxybenzoic and its esters

1.1. Thin layer chromatography

1.1.1. Principle

The preservatives are extracted with ether from the previously acidified wine. After separation by thin layer chromatography with polyamide powder, they are located and characterized by examining the chromatogram under ultraviolet light.

1.1.2. Apparatus

Chromatography bath.

20 x 20 cm glass plates.

Preparation of the plates - Mix thoroughly 12 g of dry polyamide powder with 0.3 g fluorescent indicator; add, while stirring, 60 mL of methanol; spread on plates to a thickness of 0.3 mm. Dry at normal temperature.

Note:Commercially prepared plates can be used.

1.1.3. Reagents

Diethyl ether

Methanol

Ethanol, 96% (v/v).

Sulfuric acid diluted to 20% (v/v)

Anhydrous sodium sulfate

Polyamide powder for chromatography (e.g., Macherey-Nagel or Merck).

Fluorescent indicator (F₂₅₄ Merck or equivalent).

Solvent:

n-Pentane :10 vol.

n-Hexane :10 vol.

Glacial acetic acid :3 vol.

Standard solutions:

Prepare standard solutions containing 0.1 g/100 mL of 96% ethanol (v/v) of the following acids: sorbic, p-chlorobenzoic, salicylic, p-hydroxybenzoic and its esters.
Prepare a solution of 0.2 g benzoic acid per 100 mL of 96% ethanol (v/v).
1. Procedure

Place 50 mL of wine in a separatory funnel; acidify with dilute 20% sulfuric acid (1.1.3.4), and extract 3 times using 20 mL diethyl ether (1.1.3.1) per extraction. Combine the washed solutions in a separatory funnel and wash with a few milliliters of distilled water. Dry the ether with the anhydrous sodium sulfate (1.1.3.2). Evaporate the ether dry using a 100°C water bath, or a rotary evaporator. If the evaporation is accomplished on a water bath, it is advisable to hasten the evaporation using a mild current of air until 2 or 3 milliliters remain, then finish the evaporation cold.

Dissolve the residue in 1 mL ethanol, deposit 3 to 5 μL of this solution on the polyamide plate, as well as 3 to 5 μL of the various preservative standard alcoholic solutions (1.1.3.9). Place the plate in a chromatography tank, and saturate with solvent vapors. Let the solvent migrate to a height of about 15 cm, which takes from 1.5 to 2.5 hours.

Remove the plate from the tank and allow to dry at normal temperature. Examine in ultraviolet light, at a wavelength of 254 nm. The preservatives appear from the bottom of the plate upward in the following order: p-hydroxybenzoic acid, esters of p-hydroxybenzoic, salicylic acid, p-chlorobenzoic acid, benzoic acid, sorbic acid.

With the exception of salicylic acid, which has a light blue fluorescence, other preservatives give dark spots on a fluorescent yellow-green background.

Sensitivity - This technique allows determination of the following minimum quantities of the miscellaneous preservatives expressed in milligrams per liter:

Salicylic acid 3

Sorbic acid 5

Esters of p-hydroxybenzoic acid 5

p-hydroxybenzoic acid 5-10

p-chlorobenzoic acid 5-10

Benzoic acid 20

1.2. High performance liquid chromatography

1.2.1. Procedure

The method is performed directly on the wine, without sample preparation. It is necessary to dilute red wines before injecting them in order to preserve the column.

Using this method, the detection threshold of preservatives in the solution analyzed is about 1 mg/L.

1.2.2. Operating conditions

Conditions which are appropriate are the following:

For the determination of sorbic and benzoic acid

Proceed according to the sorbic, benzoic, salicylic acid assay method in wines by high performance liquid chromatography (AS313-20-SOBESA) provided in the Compendium

B. For the determination of p-chlorobenzoic acid, p-hydroxybenzoic acid and its esters

Column: see A

Mobile phase:

Solution of ammonium acetate, 0.01 M + methanol (60 : 40)

pH: 4.5 - 4.6

Flow rate: see A

Injected volume: see A

Detector: UV, 254 nm

Temperature: see A

Bibliography

Junge Ch., Zeits. Unters. Lebensmit., 1967, 133, 319

Detection of preservatives and fermentation inihibitors (Detection of the monohalogen derivatives of acetic acid) (Type-IV)

OIV-MA-AS4-02C Detection of preservatives and fermentation inhibitors

Type IV method

Detection of the monohalogen derivatives of acetic acid

1.1. Principle

The monohalogen derivatives of acetic acid are extracted with ether from acidified wine. The ether is then extracted using a 0.5 M sodium hydroxide solution. The extraction solution must have the alkalinity maintained between 0.4 and 0.6 M. After the addition of thiosalicylic acid, the synthesis of the thioindigo is implemented by the following steps:

a) Condensation of the monohalogen derivative with thiosalicylic acid and formation of ortho-carboxylic phenylthioglycolic acid;

b) Cyclization of the acid formed in a heated alkaline medium, with the formation of thioindoxyl;

c) Oxidation of the thioindoxyl with potassium ferricyanide in an alkaline medium with formation of thioindigo, soluble in chloroform, in which it gives a red color.

1.2. Apparatus

Water bath at 100°C.

Mechanical stirrer.

Oven with a temperature of 200 2°C.

1.3. Reagents

Diethyl ether.

Hydrochloric acid solution diluted to 1/3 (v/v). Mix one part pure hydrochloric acid, ρ₂₀ = 1.19 g/mL, with 2 parts of distilled water.

Anhydrous sodium sulfate.

Thiosalicylic acid solution: thiosalicylic acid 3 g in 100 mL sodium hydroxide solution, 1.5 M.

Sodium hydroxide solution, 0.5 M

Potassium ferricyanide solution containing 2 g of per 100 mL of water.

Chloroform.

1.4. Procedure

Place 100 mL of test wine in an extraction flask with a ground glass stopper; add 2 mL hydrochloric acid (1.3.2) and 100 mL diethyl ether (1.3.1). Shake the contents vigorously for a few seconds by hand, then for 1 h with a mechanical stirrer (1.2.2). Transfer to a separating funnel, allow to separate and recover the ether layer.

Shake the ether extract with 8 to 10 g of anhydrous sodium sulfate (1.3.3) for a few seconds.

Transfer the extract to the separating funnel, add 10 mL sodium hydroxide solution, 0.5 M (1.3.5); shake for 1 min. Allow to settle.

Remove 0.5 mL of the alkaline extract and check, by titration with sulfuric acid, 0.05 M, so that the strength falls between 0.4 and 0.6 M. Transfer the alkaline extract contained in the separating funnel into a test tube containing 1 mL of thiosalicylic acid solution. Adjust, if necessary the strength of the alkaline extract in order to bring it to the limits indicated, using a stronger sodium hydroxide solution of known strength. Shake the contents of the test tube for 30 seconds and transfer to an evaporating dish.

Place the dish on a water bath at 100°C blowing its surface with a current of cold air. Maintain the dish on the water bath at 100°C for exactly 1 hour; the residue may become practically dry in a shorter amount of time. If a crust forms on the surface of the residue during the evaporation, it is advisable to break or grind it up with a thin glass rod to facilitate the evaporation.

Place the dish in an oven maintained at 200 2°C for exactly 30 minutes. After cooling, recover the contents of the dish with 4 mL of water; transfer into a separation funnel, add to the dish 3 mL of potassium ferricyanide solution to fully dissolve any remaining residue and add to the separating funnel. Shake for 30 seconds to facilitate oxidation. Add 5 mL chloroform, mix using 3 to 4 inversions. Allow to separate.

A pink or red color (according to the quantity of thioindigo formed) indicates the presence of monohalogen derivatives of acetic acid.

Sensitivity - The method allows detection of 1.5 to 2 mg monochloroacetic acid per liter of wine and corresponding quantities of the other derived monohalogens. Since the yield of miscellaneous extractions is not quantitative, this method cannot be used for determining the amount of these monohalogen derivatives in the wines.

Bibliography

Friedlander, Ber. Deutsch. Chem. Gesell., 1906, 39, 1062.
Ramsey L.L., Patterson W.I., J. Ass. Off. Agr. Chem., 1951, 34, 827.
Peronnet M., Rocques S., Ann. Fals. Fraudes, 1953, 21-23.
Traité de chimie organique, edited by V. Grignard, 1942, 19, 565-566.
Official Methods of Analysis of the Association of Official Analytical Chemists, 11th édition, publiée par l'Association of Official Analytical Chemists, Washington, 1970, 340-341.
TERCERO C., F.V., O.I.V., 1967, n° 224.

Detection of preservatives and fermentation inihibitors (determination of ethyl pyrocarbonate) (Type-IV)

OIV-MA-AS4-02D Detection of preservatives and fermentation inhibitors

Type IV method

Examination and determination of ethyl pyrocarbonate (diethyl dicarbonate)

1.1. Principle

The diethyl carbonate formed by degradation of ethyl pyrocarbonate (diethyl ester of pyrocarbonic acid) in the presence of ethanol is extracted from wine using carbon disulfide and the quantity determined by gas chromatography. Either of the procedures described below may be used.

1.2. Apparatus

1.2.1. Gas chromatography with flame ionization detector.

1.2.2. Columns:

Capillary column coated with Carbowax 1540
Column length: 15.24 m
Inside diameter: 0.51 mm
Polypropyleneglycol on Celite 545 (15:100), 60‑100 mesh
Column length: 2 m
Interior diameter: 3 mm
1. Reagents
  1. Anhydrous sodium sulfate
  2. Carbon disulfide

The carbon disulfide must contain no impurities in the critical retention zone (5 to 7 min.) for maximum sensitivity in accordance with the conditions of gas chromatography as indicated in paragraph 1.4.2.

1.4. Procedure

1.4.1. Use of the capillary column.

Place 100 mL wine in a 250 mL separating funnel with 1 mL of carbon disulfide (1.3.2). Mix vigorously for 1 min. The carbon disulfide phase separated is rapidly centrifuged, then dried with anhydrous sodium sulfate (1.3.1).

Inject 10 μl of the clear liquid supernatant into the chromatograph.

Chromatography conditions:

Detector gases:

hydrogen: 37 mL/min.
air: 250 mL/min.

Gas flow:

nitrogen: 40 mL/min.
A 1/10 splitter sends to the detector the gas mixture with a flow rate of 3 to 5 mL/min.
Temperature:
injector: 150 °C; oven: 80 °C; detector: 150 °C

Detection limits:

0.05 mg/L of wine

1.4.2. Use of the column for polypropyleneglycol.

Add 20 mL of wine and 1 mL of carbon disulfide (1.3.2) into a conical centrifuge tube with a stopper. Agitate vigorously for 5 minutes, then centrifuge for 5 minutes applying a centrifugal force of 1000 to 1200 g. The liquid supernatant produced is aspirated by a thin-tipped pipette; the carbon disulfide phase is dried with a small quantity of anhydrous sodium sulfate, added while stirring with a glass rod. Inject 1 µL of the clear liquid into the gas chromatograph.

Chromatography conditions.

Detector gas:

hydrogen: 35 mL/min.
air: 275 mL/min.

Carrier gas flow:

nitrogen: 25 mL/min.

Temperature:

injector: 240 °C
oven: 100 °C
detector: 240 °C

Sensitivity range:

12 x 10-11 A to 3 x 10-11 A

Chart speed:

1 cm/min.

Detection limit:

0.10 - 0.05 mg/L of wine

Under these exact conditions, diethyl carbonate displays a retention time of about 6 min.

The calibration of the apparatus is carried out using solutions of 0.01 and 0.05% (m/v) diethyl carbonate in carbon disulfide (1.3.2).

1.5. Calculation

Quantitative determination of diethyl carbonate is carried out preferably using the internal standard method, referring to the peaks of the iso-butyl alcohol or iso-amyl alcohol which are close to that of diethyl carbonate.

Prepare two samples of test wine: one of wine with 10 mL 10% ethanol (v/v) added, the other the same wine to which has been added 1 mg diethyl carbonate per liter using 10 mL of a 100 mg/L solution of diethyl carbonate in 10% ethanol (v/v).

Treat these two samples according to one or the other of the techniques above according to the column used.

Let:

S = the peak area of the diethyl carbonate in the spiked wine

= the peak area of the diethyl carbonate in the wine,

i = the peak area of internal standard in the wine,

I = the peak area of internal standard in the spiked wine .

The concentration of diethyl carbonate in mg/L of wine is:

In the case where standardization is carried out using a pure standard solution of diethyl carbonate, it is necessary to predetermine the yield of the extraction with carbon disulfide in accordance with the procedure utilized. This yield is expressed by the extraction factor F, with a decimal number less than or equal to 1 (yield 100%).

Let:

= the peak area of diethyl carbonate given by the wine,

= the peak area given by the injection of the same volume of a standard solution of diethyl carbonate of concentration C in mg/L,

= the volume of wine used in the extraction with carbon disulfide,

= the volume of carbon disulfide used for the extraction,

= the sensitivity for the recording of

The concentration of diethyl carbonate in mg/L of wine is:

If the concentration of the two solutions injected in the chromatograph is similar, the response is the same for the recording of Sx and of Se; the formula is simplified and becomes:

Bibliography

Kielhofer E., Wurdig G., Dtsch. Lebensmit. Rdsch., 1963, 59, 197-200 & 224-228.
Prillinger F., Weinberg u. Keller, 1967, 14, 5-15.
Reinhard C., Dtsch. Lebensmit. Rdsch., 1967, 5, 151-153.
Bandion F., Mitt. Klosterneuburg, Rebe u. Wein, 1969, 19, 37-39.

Detection of preservatives and fermentation inihibitors (Examination of dehydroacetic acid) (Type-IV)

OIV-MA-AS4-02E Detection of preservatives and fermentation inhibitors

Type IV method

Examination of dehydroacetic acid

1.1. Principle

Wine acidified with sulfuric acid is extracted with a mixture of equal parts of diethyl ether and petroleum ether. After evaporation of the solvent, the extract, recovered with a small quantity of 96% ethanol (v/v) is deposited on a thin layer of polyamide and silica gel with fluorescent indicator and subjected to the action of the mobile solvent (benzene-acetone-acetic acid). The dehydroacetic acid is identified and characterized by ultraviolet examination of the chromatogram.

1.2. Apparatus

1.2.1. Equipment for thin layer chromatography

1.2.2. Oven

1.2.3. Rotary evaporator

1.2.4. UV lamp 254 nm.

1.3. Reagents

1.3.1. Diethyl ether

1.3.2. Petroleum ether (boiling point  40 °C)

1.3.3. Methanol

1.3.4. Sulfuric acid, 20% (v/v)

1.3.5. Anhydrous sodium sulfate.

1.3.6. Ethanol, 96% (v/v).

1.3.7. Chromatographic separation layer: 10 g polyamide powder with fluorescent indicator(e.g. polyamide DC II UV₂₅₄ from Macherey-Nagel) mixed vigorously with 60 mL methanol. Add while stirring, 10 ml of water and 10ml of silica gel (with fluorescent indicator), e.g. Kiesselgel GF₂₅₄ Merck. Spread this mixture on 5 plates (200 x 200 mm) to a thickness of 0.25 mm. Dry the plates at room temperature for 30 minutes, then place in a 70°C oven for 10 min.

1.3.8. Migration solvent:

Crystallizable benzene :60 vol.

Acetone :3 vol.

Crystallizable acetic acid :1 vol.

1.3.9. Reference solutions:

Dehydroacetic acid and benzoic acid, 0.2%, in alcoholic solution.

Sorbic acid, p-chlorobenzoic acid, salicylic acid, p-hydroxybenzoic acid and its propyl, methyl and ethyl esters, 0.1 % (m/v), in alcoholic solution.

1.4. Procedure

Acidify 100 mL of wine using 10 mL of 20% sulfuric acid (1.3.3), then proceed to extract 3 times using 50 mL of a (50:50) diethyl ether-petroleum ether mixture for each extraction. Remove the clear aqueous phase leaving an aqueous emulsion and the ether phase. Mix again the remaining liquid in the separation flask composed of an emulsion and the ether phase. The remaining aqueous phase usually separates clearly from the ether phase. If there is any residual emulsion, it should be eliminated by the addition of a few drops of ethanol.

The diethyl ether-petroleum ether phases recovered are washed with 50 mL water, dried using sodium sulfate, then evaporated by rotary evaporator, at 30 - 35 °C. The residue is recovered with 1 mL of ethanol.

Deposit 20 μL of this solution on the starting line in a 2 cm wide band, or 10 μL in a circular spot. For a comparison standard, deposit 5 μL of each of the reference solutions described above. After the chromatography (ascending height of migration 15 cm, duration 1 hour 15 min. to 1 hour 45 min., at normal saturation of the chamber), the plate is dried at room temperature. Any dehydroacetic acid and other preservatives present show up under a UV lamp at 254 nm.

When the examination of the chromatogram has revealed the presence of para-chlorobenzoic acid, the propyl or methyl esters of para-hydroxybenzoic acid which are only partly separated by this method may be identified consequently on the extract above, following the method described in Examination of Sorbic, Benzoic, Parachlorobenzoic Acids, 2.1. Thin layer chromatography.

Bibliography

Haller H.E., Junge Ch., F.V., O.I.V., 1972, n° 397, Mitt. Bl. der Gd CH, Fachgruppe, Lebensmitt. u. gerichtl. Chem., 1971, 25, n° 5, 164-166.

Detection of preservatives and fermentation inihibitors (Sodium Azide by HPLC) (Type-IV)

OIV-MA-AS4-02F Detection of preservatives and fermentation inhibitors

Type IV method

Sodium Azide

1.1. Method by high performance liquid chromatography

1.1.1. Principle

Hydrazoic acid isolated in wine using double distillation is identified after derivatization with 3,5-dinitrobenzoyl chloride, by high performance liquid chromatography. Detection is carried out by ultraviolet absorption spectrophotometry at 240 nm.

1.1.2. Apparatus

1.1.2.1. Distillation apparatus (distillation apparatus for determination of alcoholic strength); the end of the condenser terminating in a tampered tube

1.1.2.2. 500 mL spherical flasks with ground glass necks

1.1.2.3. 10 mL flask with a ground glass stopper

Operating conditions:

Column: , 25 cm long.
Mobile Phase: acetonitrile-water (50:50)
Flow rate: 1 mL/min.
Volume injected: 20 μL
Detector: ultraviolet absorption spectrophotometer at 240 nm
Temperature: ambient
1. Reagents
  1. Sodium hydroxide, 5% (m/v).
  2. Sulfuric acid solution, 10% (m/v).
  3. Indicator reagent: methyl red 100 mg, and methylene blue 50 mg, 100 mL alcohol, 50% (v/v).
  4. Acetonitrile for chromatography.
  5. Derivatizing reagent: 3,5-dinitrobenzoyle chloride, 10% (m/v), in acetonitrile.
  6. Buffer solution of sodium acetate, pH 4.7: mix 1 volume of sodium acetate solution, Na, 1 M, with 1 volume acetic acid solution, 1 M.
  7. Sodium azide, Na.
2. Procedure
  1. Preparation of the sample.

Into a spherical flask with a ground glass neck, place 100 mL of wine, distill by plunging the end of the condenser in 10 mL of 5% sodium hydroxide solution (1.1.3), to which are added a few drops of reagent indicator. Distill until 40‑50 mL of distillate is recovered.

Transfer the distillate into another spherical flask (1.1.2.2), rinse the flask twice with 20 mL of water and add water to bring to 100 mL. To eliminate the ethanol, attach the flask to the distillation apparatus and eliminate about 50 mL of distillate (reduce the volume by half).

Cool the flask completely. Acidify with 10% sulfuric acid. Distill, recover the distillate into a 10 mL flask with a ground glass stopper containing 1 mL of water, and immerse in an iced bath. Stop the distillation when the total volume reaches 10 mL.

1.1.4.2. Derivitization

Mix 1 mL distillate (1.1.4.1), 0.5 mL of acetonitrile, 0.2 mL buffer solution and 30 μL of derivatizing reagent and stir vigorously; leave for five minutes.Chromatography

1.1.4.3. Inject 20 μL in accordance with the conditions specified, the hydrazoic acid derivative has a retention time of about 11 minutes. Detection limit: 0.01 mg/L.

Note : Sometimes another substance not derivatized can simulate hydrazoic acid. It is necessary to verify a positive result as follows: inject 20 μL of distillate directly; a disappearance of the peak indicates the presence of hydrazoic acid.

1.1.5. Calculation

To determine the concentration of sodium azide, compare the sample response to that of the standard solution after derivatization. Take into account the concentration factor 10 of the sample of wine at the time of analysis.

1.2. Colorimetric method

1.2.1. Principle

Hydrazoic acid, which is very volatile, is separated by double distillation, permitting the elimination of ethanol, acetic acid and sulfur dioxide. Then the amount is determined colorimetrically after forming a colored complex with ferric chloride (maximum absorbance at 465 nm).

1.2.2. Apparatus

1.2.2.1. Simple distillation apparatus, consisting of a 500 mL flask with a ground glass neck and a condenser ending in a pointed tube

1.2.2.2. Spectrophotometer with optical glass cells 1 cm path length

1.2.3. Reagents

1.2.3.1. Sodium hydroxide solution, 1 M

1.2.3.2. Sulfuric acid, 1 M

1.2.3.3. Hydrogen peroxide, 3% (v/v), whose strength must be adjusted just before use using a solution of potassium permanganate, 0.02 M; where p mL equals the volume which oxidizes 1 mL of the hydrogen peroxide solution, 3%

1.2.3.4. Ferric chloride solution at 20 g per liter of Fe III: (weigh 96.6 g of Fe.6, or more as this salt is very hygroscopic; control the concentration of Fe III of the solution and adjust if necessary to 20 0.5 g per liter)

1.2.3.5. Stock solution of sodium azide, NaN₃, at 1 g per liter in distilled water

1.2.3.6. 200 mg per liter sodium azide solution prepared by dilution of the solution at 1 g per liter

1.2.4. Procedure

a) Into a 500 mL flask with a ground glass neck, place 200 mL of wine, distill, recover the distillate in a 50 mL volumetric flask, containing 5 mL water, which is immersed in an iced bath. Stop the distillation when the total volume reaches about 50 mL.

b) Transfer quantitatively the distillate into another 500 mL flask with a stopper and rinse the 50 mL flask twice with 20 mL of water.

Neutralize using 1 M sodium hydroxide solution (1.2.3.1) (using pH indicator paper).

Acidify using 10 mL 1 M sulfuric acid (1.2.3.2), mix, then oxidize the sulfur dioxide by adding 3% hydrogen peroxide solution (1.2.3.3.).

If the wine contains S mg per liter of sulfur dioxide, and if p mL is the volume of 0.02 M potassium permanganate solution necessary to oxidize 1 mL of 3% hydrogen peroxide solution, then for 200 mL of wine use the following calculation:

Bring the volume to about 200 mL by addition of distilled water.

Distill, recover the distillate in a 50 mL glass flask containing 5 mL distilled water, which is immersed in an ice bath; stop the distillation before the measurement line, bring back to ambient temperature and adjust the volume to 50 mL.

c) Add 0.5 mL (measured exactly) of ferric chloride solution, mix and measure immediately (maximum delay 5 min.) the absorbance at 465 nm in a 1 cm

cell; the zero of the apparatus is set using a blank composed of 50 mL of water added to 0.5 mL of ferric chloride solution.

d) Preparation of the standard curve.

Into each of five 50 mL volumetric flasks add 1, 2, 3, 4, and 5 mL of 200 mg/L sodium azide solution respectively, bring the volume to 50 mL with distilled water, add 0.5 mL of ferric chloride solution and measure the absorbance at 465 nm.

These solutions contain 4, 8, 12, 16, 20 mg of sodium azide per liter. The corresponding concentrations are 1, 2, 3, 4, and 5 mg per liter of wine.

The typical curve of absorbance variation as a function of concentration is a straight line passing through the origin.

1.2.5. Calculation

Plot the absorbance read for the sample analyzed on the straight line and interpolate the concentration of sodium azide in mg/L of wine.

Bibliography

HPLC method:

Searin S.J. & Waldo R.A., J. Liquid. Chrom., 1982, 5(4), 597-604.
Battaglia R. & Mitiska J., Z. Lebensm. Unters. Forsch., 1986, 182, 501-502.

Colorimetric method:

Clermont S. & Chretien D., F.V., O.I.V., 1977, n° 627.

Enumerating yeasts of the species Brettanomyces bruxellensis using qPCR (Type-IV)

OIV-MA-AS4-03 Enumerating yeasts of the species Brettanomyces bruxellensis using qPCR

Type IV method

Warning to users

Phenol: All handling procedures involving phenol must be performed under a fume hood and gloves must be worn. All phenol-contaminated residues must be collected in suitable containers.

SYBR Green: This displays a non-zero mutagenicity, but one which is lower than that of ethidium bromide. The precautions for use must nevertheless be adhered to.

Scope of application

This protocol describes a method for enumerating yeasts of the species Brettanomyces bruxellensis in wine in bulk or bottled wines, using real-time qPCR (quantitative polymerase chain reaction) (qPCR). The analysis of wines during AF (alcoholic fermentation) and of musts has not yet been validated.

Definition

The micro-organisms enumerated by this method are Brettanomyces bruxellensis yeasts which have a copy of the target gene

Principle

The PCR technique amplifies, by multiple repetition of an enzymatic reaction, a target DNA (deoxyribonucleic acid) region identified by two primers. The process involves repeating a three-step cycle:

Denaturing the DNA by heating
Hybridization of the primers
Polymerization, carried out by the Taq (Thermophilus aquaticus) polymerase

However, unlike traditional PCR, qPCR can quantify the DNA amplified during the amplification process through the use of a fluorophore.

Until now two regions specific to the species have been used as targets. One region is the encoding gene for the 26S ribosomal RNA (ribonucleic acid) and the other the RAD4 gene [2, 3]. As with the FISH method, PCR is specific to Brettanomyces bruxellensis but has the advantage of being less expensive.

The distinctive feature of qPCR is that it is possible to read, after each amplification cycle, the fluorescence which increases exponentially as the DNA amplification proceeds. Many fluorescence techniques have been developed for this application. The SYBR^®Green fluorophore has been found to be suitable for use with Brettanomyces.

SYBR^® Green fluorophore

This agent fluoresces strongly when it inserts itself non-specifically between the nucleotides in the double-stranded DNA. In contrast, it fluoresces only weakly when unbound. Using this technology, a merged curve can be generated at the end of the amplification that validates the specificity of the reaction.

Internal standard

In order to validate the DNA extraction and amplification stages, an internal standard has been integrated into the method (Lip4 Yarrowia lipolytica).

Reagents and products

All plastic consumables must be autoclaved beforehand to destroy any DNases (deoxyribonucleases), as must the Tris-HCl and TE (Tris EDTA, ethylene diamine tetra-acetic acid) buffer solutions, the ammonium acetate and the ultrapure water ( 18 M). All the aqueous solutions are prepared using ultrapure water (18 M). Some solutions are sterilized in an autoclave (indicated as "autoclaved"). Sterile ultrapure water (18 M) is used, if possible, to prepare any solutions which are not autoclaved. It is not then necessary to work under sterile conditions.

PVPP (eg: ISP Polyclar Super R or Sigma P6755-100G),

Solutions at room temperature: Tris-HCl buffer, 10mM pH8, solution I (Tris-HCl 10mM pH8, EDTA 1mM, NaCl 100mM, SDS 1% (sodium dodecyl sulfate), Triton X-100 2%), TE (Tris-HCl 10 mM pH8, EDTA 1mM) autoclaved, 4M ammonium acetate, absolute ethanol,

Provide one autoclaved, sterilized ultrapure (18 M) water bottle (20mL) per qPCR plate,

Solutions at 4°C: saturated phenol pH8: chloroform: IAA (isoamyl alcohol 24:25:1) and Rnase (ribonuclease) 1 μg/ μL

Suspension at –20°C: internal standard, SYBR Green (e.g. iQ SBYR Green Supermix Bio-Rad 170-8884), primers 4 μM Brett rad3, Brett rad4, YAL-F and YAL-R each one.

Dry bath, set to 37°C.

All handling procedures involving phenol must be performed under a fume hood and gloves must be worn. All phenol-contaminated residues must be collected in suitable containers.

PCR substances	Specifications	CAS Number
4.1 ammonium acetate	>98%	631-61-8
4.2 phenol:chloroform:IAA (24:25:1)	Ultra	136112-00-0
4.3 proteinase K	1215 U/mg proteins (16.6 ng/ml)	39450-01-6
4.4 SDS	>99% Ultra	151-21-3
4.5 Tris base	>99.8% Ultra	77-86-1
4.6 BSA	Molecular biology grade	9048-46-8
4.7 saturated phenol pH 8		108-95-2
4.8 PVPP 360kDa		9003-39-8
4.9 RNase A	70 U/mg in solution	9001-99-4
4.10 TE pH8	Ultra	Tris : 77-86-1 EDTA : 60-00-4
4.11 Primers 25nmol		-

Apparatus

Plastic consumables: 2mL screw-capped microtubes, 1.5 and 1.7mL microtubes, white (10 μL), yellow (200 μL) and blue (1000 μL) pipette tips for micropipettes P20, P200, P1000, P5000, 96-well PCR microplates and optical film, non-powdered gloves

Glass beads (Ø 500 µm)

Bottle (20mL) autoclaved (for ultrapure [18 M] sterilized water, one per qPCR plate),

15 and 50 mL Centrifuge tubes

Equipment:

automatic pipettes (P20, P200, P1000, P5000)
microtube centrifuge
automatic stirrer to split cells (eg. GenieDisruptor)

Thermocycler coupled to a spectrofluorimeter (optical system to detect the fluorescence generated during the real-time PCR reactions)

Magnetic stirrer

Stop watch

dry bath set to 37°C

autoclave

100mL volumetric flasks
50mL volumetric flasks
10mL volumetric flasks
100mL beakers
50mL beakers
10mL beakers

Magnetic stirring bars

Sampling (sample preparation)

6.1. Enumerating the samples:

The samples are removed either directly into bottles for analysis or into pre-sterilized sample flasks.

No interference with the method has been observed from the yeasts tested (including K1 and L2056) when the yeast populations are not greater than 5.10⁶CFU/mL (colony forming units). There is no data for populations larger than this figure; consequently, avoid measuring wines during AF.

NB: When enumerating yeasts using standard microbiology methods of analysis (growth in agar growth medium , optical density), the results are expressed in CFU/mL (colony forming unit). Conversely, enumeration resulting from the analysis by qPCR is expressed in GU/mL (genetic unit).

6.2. Preparing the internal standard

Grow Yarrowia in liquid YPD (yeast peptone dextrose) at 28°C up to an O(optical density at 600 nm)of 1 (approximately 48 hrs).

After estimating the O dilute to 1.0 x 10⁶CFU/mL in isotonic saline solution (1 OD = 1.0 x 10⁷CFU/mL).

Transfer a 110 μL sample of the 1.0 x 10⁶CFU/mL culture into a 1.7mL microtube and add 110 μL of 40 % glycerol to obtain a population of 5.0 x 10⁵CFU/mL. Mix and store at -80°C. One tube can be used to process 5 wine samples.

Perform an enumeration simultaneously to check the titer of the suspension.

6.3. Preparing the solutions

100mL of Tris-HCl pH8 10 mM: weigh 0.121 g of tris base (eg.Trizma base) and dissolve in 80mL of ultrapure [18 M] water. Adjust the pH using HCl. Make up to 100mL. Autoclave.
100mL TE: weigh 0.121 g of tris base and dissolve in 80mL of water. Adjust the pH using HCl. Add 37.2 mg of EDTA. Adjust the pH to 8 (to assist the dissolution of the EDTA) then make up to 100mL. Autoclave.
100mL solution I: prepare 50mL of TE 2x and add 10mL of 1M NaCl, 10mL of SDS 10% (dissolved by heating gently) and 2 g of Triton X100, then make up to volume.
4M ammonium acetate: dissolve 15.4 g of ammonium acetate in 50 mL ultrapure [18 M] water qs to 50mL.
100mL phenol:chloroform:IAA (25:24:1): add 48mL of chloroform and 2mL of isoamyl alcohol to 50mL of phenol saturated with TE buffer pH8. Store at 4°C.
RNase A 1 μg/µL: dilute a 70U/mg solution of RNase A (e.g. Sigma, R4642-50MG, stored at –20°C) with ultrapure [18 M] water. The specified concentration of the RNase stock is indicated on the tube and in the specification sheet for the batch. The diluted solution should be kept at not more than 4°C for up to 3 weeks.
Brett 4 μM primers: using 100 µM stock solutions of primers (in the supplier’s tubes), mix 4 μM Brett rad3 (GTTCACACAATCCCCTCGATCAAC) and 4 μM Brett rad4 (TGCCAACTGCCGAATGTTCTC) qs to 1mL with ultrapure [18 M] water). Store for up to 1 year at –20°C.
YAL 4 μM primers: using 100 µM stock solutions of primers (in the supplier’s tubes), mix 4 µM YAL-F (ACGCATCTGATCCCTACCAAGG) and 4 μM YAL-R (CATCCTGTCGCTCTTCCAGGTT) qs to 1mL with ultrapure [18 M] water). Store for up to 1 year at –20°C.

Procedure

Sample to be analyzed: shake the bottle to homogenize its contents.

For a corked bottle: disinfect the neck of the bottle with 70% alcohol and uncork over a naked flame, using a corkscrew disinfected with 70% alcohol.

Transfer a 15-20mL sample of the wine into a 30-mL, sterile, plastic, single-use bottle.

The steps at which the protocol may be paused are identified by a .

7.1. Separating the cells

This step must be duplicated.

The handling procedures must be carried out under a confined microbiological safety cabinet dedicated to this purpose.

take a 1mL sample of wine and transfer to a 2mL screw-capped microtube

add 20 μL of internal standard, at a concentration of 5.0 x 10⁵CFU/mL

centrifuge for 30 sec. at 9,300g

eliminate the supernatant by gently inverting the microtube

suspend the pellet in 1mL of Tris-HCl 10 mM pH 8

centrifuge for 30 sec. at 9,300g and eliminate the supernatant.

vortex briefly to suspend the pellet in the residual fluid .

One tube will be used for extracting the DNA and the other will be stored at –20°C until validated results have been obtained.

7.2. Extracting the DNA

From a fresh or frozen pellet. Do not process more than 24 samples at the same time.

add PVPP (1% of final mass/volume) by weighing add 0.3 g of 200-500 μm glass beads
add 200 μL of solution I
add 200 μL of phenol:chloroform:IAA (24:25:1)
disrupt the cells with the automatic stirrer (for example a GenieDisruptor) 4x80 sec. with cold intervals (-20°C refrigerated unit) lasting for about 80sec between each disruption phase
add 200 μL of TE
centrifuge for 5min at 15700g.
carefully collect 400 μL of the upper aqueous phase in a 1.7mL microtube. If the two phases mix, repeat the centrifugation step.
add 1mL of absolute ethanol and mix the tube by inversion 4-5 times
centrifuge for 5 minutes at 15700g and eliminate the supernatant by inverting the microtube
suspend the pellet in 400 μL of TE and 30µL of RNase at a concentration of 1 μg/ μL
incubate the solution at 37°C for 5 minutes (then readjust to 48°C)
add 10 μL of 4M ammonium acetate + 1mL of absolute ethanol; mix by inversion
centrifuge for 5 minutes at 15700g
eliminate the supernatant by inversion; use filterpaper to absorb the final drops
dry the pellet (leave the open tube in the dry bath at 48°C, for approximately 1 hour)
add 25 μL of TE to the pellet, vortex and leave at 4°C for between 1 and 18 hrs (to assist the solubilisation of the DNA). Mix using the automatic stirrer
1. qPCR

For each sample of wine, provide 2 wells with Brett rad3/4 primers and 2 internal standard wells with YAL primers. For each plate, provide a negative control with TE for each pair of primers to be carried out as the final operation. Also perform a positive control on the Brettanomyces bruxellensis DNA available at -20°C. To prepare the positive control, add 5 μL stock solution (4.5 UG / ml) in a final reaction volume of 25 μL.

PCR amplification programme:

Cycle number	Time (seconds)	Temperature (°C)
1	180	95
40	30	95
40	10	64.6
The merged curve is established after 90°C by reducing the heat by 0.5°C every 10 seconds

Num. of Brett wells = Num. of YAL wells = 2 x no. of samples + 2

The table below indicates, as a function of the number of samples, the number of wells and the quantity of each constituent of the mixture.

number of samples	number of wells	water at18 M (μL)	iQ SYBR Green Supermix (μL)	Mixture of 4 μM primers (μL)
1	4	26.3	65.6	13.1
2	6	36.8	91.9	18.4
3	8	47.3	118.1	23.6
4	10	57.8	144.4	28.9
5	12	68.3	170.6	34.1
6	14	78.8	196.9	39.4
7	16	89.3	223.1	44.6
8	18	99.8	249.4	49.9
9	20	110.3	275.6	55.1
10	22	120.8	301.9	60.4
11	24	131.3	328.1	65.6
12	26	141.8	354.4	70.9
13	28	152.3	380.6	76.1
14	30	162.8	406.9	81.4
15	32	173.3	433.1	86.6
16	34	183.8	459.4	91.9
17	36	194.3	485.6	97.1
18	38	204.8	511.9	102.4
19	40	215.3	538.1	107.6
20	42	225.8	564.4	112.9
21	44	236.3	590.6	118.1
22	46	246.8	616.9	123.4
23	48	257.3	643.1	128.6

remove the Brett 4 μM and the YAL 4 μM primers from the freezer
remove the SYBR Green (4°C if tube in current use, otherwise –20°C)
prepare a Brett mixture and a YAL mixture using the quantities shown in the table above as a function of the number of samples.
apply 20 μL of mixture to the bottom of each well
add 5 μL of homogenized DNA solution to the automatic stirrer (or 5 μL of water for the negative controls)
adjust the optical film and load the plate
1. Reading the results

remove the plate and place it directly in the bag for disposal (do not open it)

set the baseline to 100.

analyze (in the order indicated below):

the negative controls, which should not produce a signal. If a Ct of less than 37 is observed, repeat the process, changing all the solutions,

the positive control on Brett: its Ct must be approximately 25, with a melting point of 82.5°C ( 0.5°C),

YAL internal standards: if a Ct is obtained, check the melting point of the product (84°C 0.5°C). If the product does not conform, the absence of a Brett signal cannot be interpreted,

samples: check the Tm of the Brettanomyces bruxellensis product (82°C 0.5°C). If and only if the Tm is acceptable, check the exponential profile of the amplification. Then record the Ct values and plot them onto the standard curve.

NB: the Ct represents the time needed for the fluorescence of the target sequence to reach a threshold value. Consequently, it is the minimum number of PCR cycles required for the fluorescent signal to emerge from the background noise.

Calculations (Results)

Five Brettanomyces bruxellensis strains were inoculated at different concentrations, from 3,1 x 10⁵to 3 UFC/mL, on 14 wines (3 white wines, 2 rosé wines, 9 red wines whose phenolic compound content varied widely). The DNA was then extracted in the presence of 1% PVPP

A standard curve was established from the set of results obtained on the different combinations of wines and strains.

The results are obtained in GU/mL (genetic unit/mL) from the standard curve

Method characteristics: intra-laboratory validation parameters

9.1. Linearity, repeatability and reproducibility [4]

The six-point calibration curve was prepared in the range of 0 to 2x10⁵CFU/mL of the L02I1 strain in a wine with four replicates. This population range was selected according to the usual levels of Brettanomyces bruxellensis in wines. The measured log GU vs. theoretical log GU relationship was described by simple regression analysis. Regression parameters, slope and intercept were determined as shown in the Table below. The regression model was accepted with a risk α=1% and the chosen linearity domain validated since no model error was detected.

Fidelity of the method was compared to that obtained with the classical culture method. Three operators prepared DNA extracted from a wine inoculated with the L02I1 strain at two levels: 1.9x10⁴ (high) or 1.9x10² (low) CFU/mL. Four repeats of PCR were performed for each DNA extract. The standard deviation for repeatability and reproducibility, respectively S_rand S_R, were calculated from log GU values for both levels (table below). For the qPCR method, both S_rand S_Rwere similar for the low population level, but S_R was greater than S_r at high population levels. Both standard deviations were twice as high as those obtained with the classical microbiology method. This effect was attributed to the increased number of steps during the qPCR method.

Table

Parameter	Values
Regression equation
Range (CFU/mL)	0 to 2x10⁵
Slope (SD)	0.957 (0.044)
Intercept (SD)	-0.049 (0.142)
Regression model	F_obs>F(1.18) : Linear model accepted
Model error	F_obs<F(4.18) : No model error

Fidelity
qPCR (low/high)	0.26/0.25
microbio (low/high)	0.17/0.04
qPCR (low/high)	0.29/0.41
microbio (low/high)	0.17/0.04

Accuracy
Mean 43 samples (D)	2.39 (qPCR)/2.25 (microbio)
D	1.18
Equality test W=D/S_R D	0.11<3 accuracy acceptable

9.2. Limit of detection (LoD) and limit of quantification (LoQ) [4]

LoD and LoQ indicate the sensitivity of the method. LoD is the lowest population detected by the method; LoQ is the minimum of the population that can be quantified accurately. In food product analysis, these parameters are calculated from the background. However in qPCR there is no

background. We thus used two other approaches to evaluate LoD and LoQ. The first method uses slope, intercept and standard error on intercept obtained from linearity validation experiments. With this method, LoD and LoQ values of 3 and 31 GU/mL respectively were obtained. In the second approach, the LD was obtained from the population level resulting in one negative result from 10 independent measurements. Analysis of our data obtained from 14 wines inoculated with five strains revealed that 96% of samples (48/50) containing 101 to 250 CFU/mL resulted in positive signals, while 83% (49/59) were positive if they contained 26 to 100 CFU/mL and 65% (44/68) if 5 to 25 CFU/mL. Thus the limit of detection evaluated from this method would be in the range of 26-100 CFU/mL. By the systematic repetition of each PCR assay, an LoD of 5 CFU/mL was certified thanks to probability calculations (1 – p)². Indeed for 5 CFU/mL, 88% of samples were positive. This increased to 97% for 25 CFU/mL.

References

Phister T.G., Mills D.A., 2003. Real-time PCR assay for detection and enumeration of Dekkera bruxellensis in wine. Applied and Environmental Microbiology, 69: 7430-7434.
Cocolin L., Rantsiou K., Iacumin L., Zironi R., Comi G., 2003. Molecular detection and identification of Brettanomyces/Dekkera bruxellensis Brettanomyces/Dekkera anomalus in spoiled wines. Applied and Environmental Microbiology, 70: 1347-1355.
Ibeas J.I., Lozano I., Perdigones F., Jimenez J., 1996. Detection of Dekkera-Brettanomyces strains in sherry by a nested PCR method. Applied and Environmental Microbiology, 62: 998-1003.
Tessonnière H., Vidal S., Barnavon L., Alexandre H., Remize F., 2009. Design and performance testing of a real-time PCR assay for sensitive and reliable direct quantification of Brettanomyces in wine. International Journal of Food Microbiology, 129: 237-243.

SECTION 4 - MICROBIOLOGICAL ANALYSIS

OIV-MA-AS4-01 Microbiological analysis of wines and musts- Detection, differentiation and counting of micro-organisms

OIV-MA-AS4-02A Detection of preservatives and fermentation inhibitors

OIV-MA-AS4-02B Detection of preservatives and fermentation inhibitors

OIV-MA-AS4-02C Detection of preservatives and fermentation inhibitors

OIV-MA-AS4-02D Detection of preservatives and fermentation inhibitors

OIV-MA-AS4-02E Detection of preservatives and fermentation inhibitors

OIV-MA-AS4-02F Detection of preservatives and fermentation inhibitors

OIV-MA-AS4-03 Enumerating yeasts of the species Brettanomyces bruxellensis using qPCR