1 / 51

Lecture 13: Managing the Malolactic Fermentation

Lecture 13: Managing the Malolactic Fermentation. Reading Assignment: Chapter 6, pages 251-261. The Malolactic Fermentation. Requires NAD + , Mn ++ Occurs after exponential growth phase Used to generate energy. Energy Generation from the Malolactic Conversion. Lactate Malate.

serge
Télécharger la présentation

Lecture 13: Managing the Malolactic Fermentation

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Lecture 13: Managing the Malolactic Fermentation

  2. Reading Assignment: Chapter 6, pages 251-261

  3. The Malolactic Fermentation • Requires NAD+, Mn++ • Occurs after exponential growth phase • Used to generate energy

  4. Energy Generation from the Malolactic Conversion Lactate Malate H+ ATP ADP Lactate Malate Proton Motive Force The conversion of malate to lactate and accompanying “fixing” of a proton decreases the proton content of the cytoplasm upon efflux of lactate thereby creating a “proton motive force” across the membrane; the energy of the proton movement can then be captured in ATP.

  5. Factors Affecting the Malolactic Fermentation • pH

  6. pH • Affects which strains/species will grow • Affects rate of growth • Affects survival of organism • Affects metabolic behavior of strains that are growing

  7. Factors Affecting the Malolactic Fermentation • pH • SO2

  8. SO2 • Sulfur dioxide is inhibitory • All genera/species/strains appear to be equally sensitive • Even if SO2 is not added, it may be produced by yeast at an inhibitory concentration

  9. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition

  10. Nutrient Composition • Lactic acid bacteria are fastidious: numerous growth requirements • Aging on yeast lees increases micronutrient content via autolysis • Extended skin contact enhances lactic acid bacteria • Higher solids/less clarification enhances lactic acid bacteria

  11. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen

  12. Oxygen • Stimulatory to growth • Affects spectrum of end products • Can produce more energy (and acetic acid) in presence of oxygen

  13. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen • CO2

  14. Carbon dioxide • Stimulatory to malolatic fermentation • Mechanism unknown

  15. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen • CO2 • Alcohol

  16. Alcohol • High alcohol slows malolactic fermentation • Affects bacterial viability • Affects which species/strains are present

  17. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen • CO2 • Alcohol • Temperature

  18. Temperature • Growth of malolactic bacteria better at higher temperatures • Malolactic fermentation faster at higher temperatures

  19. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen • CO2 • Alcohol • Temperature • Organic acids

  20. Organic Acids • Fumarate inhibitory at low concentrations • Can be produced by yeast • Fatty acids can also be inhibitory • Malate stimulates growth prior to malolactic fermentation

  21. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen • CO2 • Alcohol • Temperature • Organic acids • Phenolic compounds

  22. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen • CO2 • Alcohol • Temperature • Organic acids • Phenolic acids • Presence of other lactic acid bacteria

  23. Presence of Other Lactic Acid Bacteria • Mixed cultures may yield “better” complexity • Can be stimulatory • Increase in pH • Can be inhibitory • Bacteriocin production • Competition for nutrients

  24. Factors Affecting the Malolactic Fermentation • pH • SO2 • Nutrient composition • Oxygen • CO2 • Alcohol • Temperature • Organic acids • Phenolic acids • Presence of other lactic acid bacteria • Bacteriophage

  25. Bacteriophage • Bacterial “viruses” that can be spread from one bacterium to another and that cause cell death • Not known if this is a problem in wine production or not; it is a problem in other lactic acid bacteria fermentations

  26. First Decision: Do you want the MLF?

  27. Reasons MLF Is Desirable • Acidity reduction • Addition of flavors • Bacterial stability of product

  28. Reasons MLF Is Undesirable • Acidity reduction • Addition of flavors

  29. MLF Stimulated By: • Low to no use of SO2 • Warm temperatures • Addition of nutrients • Use of inocula • Low ethanol (avoid late harvest wines) • Delay racking off yeast lees • Acid/pH adjustment

  30. MLF Inhibited By: • Use of SO2 • Early racking • Downward pH adjustment • Low temperature • Filtration/Fining • Addition of fumaric acid • Bacteriocin (lysozyme) addition

  31. Second Decision: Inoculated versus Spontaneous Malolactic Fermentation

  32. Inoculated MLF • Better control over both timing and organisms present • Difficult to maintain inocula • Starter culture must be “pure” • Percent inoculation: 1-50% depending upon vigor of culture

  33. Inoculum Preparation • Start culture from slant in medium supporting good growth of organism • Inoculate “diluted” juice (with water) from starter with addition of nutrients • Use #2 to inoculate full strength wine or juice with addition of nutrients • Use #3 to inoculate rest of wine

  34. Spontaneous MLF • Uncontrolled timing of process • Risk of unwanted species/strains • Off-characters can be produced if MLF occurs when undesired

  35. Third Decision: Timing of Malolactic Fermentation

  36. Timing of MLF: Options • Prior to yeast fermentation • Simultaneous with yeast fermentation • Mid-way through yeast fermentation • After yeast fermentation

  37. Timing of MLF: Pre-Fermentation Inoculation • Decreases yeast nutrients • Stuck/sluggish fermentation • Production of off-characters • May lead to production of inhibitory compounds (acetic acid) due to presence of oxygen

  38. Timing of MLF: Options • Prior to yeast fermentation • Simultaneous with yeast fermentation • Mid-way through yeast fermentation • After yeast fermentation

  39. Timing of MLF: Simultaneous with Yeast Inoculation • See increase in acetic acid • See a decrease in viability of both yeast and bacteria • Yeast “rebound” better than bacteria

  40. Timing of MLF: Options • Prior to yeast fermentation • Simultaneous with yeast fermentation • Mid-way through yeast fermentation • After yeast fermentation

  41. Timing of MLF: Mid-Fermentation • Nutrients left for bacteria • Ethanol low and not inhibitory • Yeast-produced SO2 may be inhibitory • May lead to arrest of yeast fermentation

  42. Timing of MLF: Options • Prior to yeast fermentation • Simultaneous with yeast fermentation • Mid-way through yeast fermentation • After yeast fermentation

  43. Timing of MLF: Post-Fermentation • Nutrients have been depleted • Add nutrients • Encourage yeast autolysis • Ethanol concentration high • Concentration of other yeast inhibitory compounds also high • Better temperature control

  44. Fourth Decision: Choice of Strain

  45. MLF: Choice of Strain • Compatible with yeast • Production of desirable characters • Ability to complete ML fermentation • Vigor • Availability as freeze-dried inoculum

  46. Fifth Decision: Method of Monitoring MLF

  47. Monitoring the MLF • By conversion of malate to lactate • Loss of malate not appearance of lactate* • HPLC, Enzymatic, Paper chromatography • By flavor changes • Tells you bacteria are active • Does not tell you when they are done * Lactate can be produced from other sources

  48. Sixth Decision: Alternative Method of Acid Reduction

  49. Alternative Methods of Acid Reduction • Immobilized enzyme • Immobilized cells • Yeast mediated conversion of malate to ethanol • Conducted by S. pombe • S. cerevisiae has been genetically engineered to perform this conversion • Expression of ML enzyme in Saccharomyces • Chemical precipitation

  50. Overall Goal: To have all microbial activity finished prior to bottling.

More Related