The importance of knowing juice composition Nutrient assimilation
- Slides: 22
The importance of knowing juice composition Nutrient assimilation, methods of analyses and interpretation as a guide to what additions should be made March, the 18 th 2011 University of California, Davis Creating Character
Reminder: Must nutrients Macro and micronutrients – Related effects Type Macronutrients (Cell material renewal) Micronutrients (Biochemical reactions catalysts) Category Nature Effects Carbon Glu/Fru, Sucrose Energy sources (glycolytic pathway) Nitrogen Amino acids, ammonia, nucleotides, peptides Protein synthesis : Production of biomass, Fermentation rate-time-flavors Phosphate* / Sulfur Inorganic and organic P/S Cell growth (biomass) fermentation rate compounds S-volatiles flavors Survival factors Oxygen Fatty acids Sterols (ergosterols) Yeast growth: Energy, fermentation rate Glycogen and threalose (stress protecting factors) high content maintaining Stimulate lipid biosynthesis Strengthen yeast membrane (integrity, permeability) viability Decrease production of toxic medium chain fatty acids Vitamins* Most important: Biotin, Thiamine, Pantothenate Growth factors, Co-factors in enzymatic conversions Minerals* Most important: Mg, K, Mn, Zn, Fe, Cu Co-factors for glycolytic and other enzymatic reactions * Generally sufficient in grape musts
Focus on Nitrogen YAN definition YAN: Yeast Assimilable or Available Nitrogen that will be taken up and used by the yeast for its metabolism: Growth and fermentative power = Primary or alpha amino acids FAN (Free Amino Nitrogen) without proline + Ammonium ions FAN! Free Amino Nitrogen or Free Assimilable/Available Nitrogen
Focus on Nitrogen Must composition in yeast available nitrogen compounds • Ammonium ions • Up to 30% of YAN • Amino acids (AA) • Most prevalent form in must Up to 90% of YAN • Major sources: • Proline and arginine (30 to 65% of total AA content), located mostly in grapes skin Importance of grape processing practices • Alanine, glutamine (increased with fertilization), serine and threonine YAN measurements directly on juice sample at inoculation Avoid over estimation (processing losses) Juice samples taken form grape musts can underestimate total berry YAN (important grape skin aa content)
Focus on Nitrogen compounds use • Ammonium ions • Preferred nitrogen source as small and directly available • Converted into amino acids with energy • Amino acids • Second nitrogen source: protein building blocks • Incorporated as is, • Transformed into a different AA (transamination based on key compound: glutamate) • Broken down as a source of nitrogen or sulfur when ammonia nitrogen source is limiting. • Storage inside the cell (vacuole, cytoplasm) for later usage in protein synthesis • Uptake of glutamine first (easier and break down to glutamate and ammonia) • Asparagine, second preferred N source.
Focus on Nitrogen Yeast assimilation process Plasma membrane not freely permeable to N compounds 1 st step: Transport Ammonia: easy uptake AA: 2 mechanisms • General amino acid permases but not proline • Adaptative uptake systems under stress conditions Assimilation mechanism: Every AA uptake H+ uptake [Et. OH] increase Membrane permeabilization Difficult p. H maintaining Shut down of AA uptake first then NH 4+ Source Salmon (1998)
Focus on Nitrogen Assimilation particularities NH 4+ assimilation consequences • NH 4+ reduce catabolic enzyme levels and transport activities for non preferred N sources. • Alternative N-assimilatory pathways not expressed when NH 4+ is present. • As NH 4+ is consumed, amino acids are taken up relatively to cell needs (concentration gradient) Particular AA Proline: No assimilation during fermentation Uptake inhibition by other aa and oxygen needed Arginine: Less readily utilized source of N Uptake during active fermentation and stationary phase • 3 of its 4 N atoms assimilated, 4 th N incorporated into proline • Breakdown results in the formation of urea and ammonia. possible ethyl carbamate production
YAN measurement assays Different measurements Different indications Assay Base principle N compounds measured Advantages / Disadvantages Kjeldahl method Heat mineralization in acidic medium All N form transformed in NH 3. Radical and fast Take into account all N compounds and not only available N compounds Formol titration Amino group and NH 4+ blocked by formol addition. Resulted acid dosed by Na. OH. Amino acids, peptides and NH 4+ Fast global YAN analysis Carcinogenic and bronchial irritant agent (well trained analyst and suitable lab) Adjustment of formaldehyde p. H critical to method consistency ~17% of proline and ~85% of NH 4+ recovery HPLC Liquid Chromatography Each single amino acids Very accurate but expensive and too slow For research purpose
YAN measurement assays Different measurements Different indications Assay Base principle N compounds measured Advantages / Disadvantages Mid-infrared /IRTF Spectrophotometry illustrating organic links absorption in near and mid IR Amino acids and NH 4+ separately Very fast and accurate (N compounds in isolated spectrum area) Difficulty of calibration (mastering reference data base, well trained analyst) Ammonia selective gas sensing electrode NH 3(aq) and NH 4+ NH 3(aq) by raising p. H >11 with a strong base. NH 3(aq) diffuses through membrane and changes internal solution p. H sensed by a p. H electrode. NH 4+ only High degree of accuracy and low limit of detection Inexpensive, rapid Calibration and interference
YAN measurement assays Measurement methods of choice Assay Base principle N compounds measured Advantages / Disadvantages NOPA Derivatization of primary amino groups with o -phthaldialdehyde/N-acetyl-L-cysteine reagent to form an isoindole derivative which can be conveniently measured at the near ultraviolet wavelength of 335 nm Yeast available free amino acids Accurate and fast (well correlated with HPLC) Insensitive to proline and 3, 5% NH 4+ recovery real Free Amino Nitrogen Low toxic reagents Necessary reagent blank as flavonoids absorb at 335 nm Enzymatic NH 4+ Ammonia reacts with α-ketoglutarate and NADH in the presence of glutamate dehydrogenase (Gl. DH) to form L-glutamate and NAD. Amount of NADH consumed measured at 340 nm and related to the amount of NH 4+ present. NH 4+ only Fast and specific Best association for YAN measurement!
Is YAN enough? YAN interpretation and other important factors Minimum YAN is considered to be about 140 -150 mg N/L (ppm) Optimum/maximum fermentation rate: 800 -900 ppm (only 400 -500 ppm assimilated) Adding a standard number is NOT the best solution As • Overaddition of N could be detrimental in terms of N uptake, fermentation progress and flavors • N extra addition function of potential Et. OH yield increase More functional proteins and more resistant cell wall necessary But first of all Differences in assimilable nitrogen and oxygen demands account for most of the differences between yeast strains
Is YAN enough? Yeast specific N requirements Commercial strain 1 Commercial strain 2
Is YAN enough? Other important factors Low YAN means low nutrient content Yes, BUT • p. H (too low: cell viability, too high: microbiological spoilage) • Low turbidity Low nutrient level, low lipid supply and low nucleation sites for decreasing concentration of dissolved CO 2 • Temperature management is always critical (too low: activity/growth, too high: Eto. H toxicity) and affects yeast nitrogen requirements in terms for both quantities and quality • O 2 required at the end of the growth phase To synthesize sterols and safe fermentation membrane strength yeast viability To avoid toxic medium chain fatty acid production
Importance of assuring completion Speed or Dryness Vmax N requirements Ethanol inhibition Viability = O 2 Combination N/O 2 to speed but also secure fermentation! Source Sablayrolles (2010)
Timing of N addition Crucial timing of N addition • Inoculation time yeast growth • Start of the stationnary phase, existing yeasts reactivation while increasing consumption rate of sugar 3 -5% alcohol: best addition time as • No cellular growth • Fermentative activity increase (increase of hexose transporter quantity) • Constant addition effect O 2 N Source Sablayrolles (2010) But not everything at the same time N assimilation processes!
Dangers of under/over N addition YAN Limitation • Not enough production of yeast biomass • Decrease of fermentation rate and slow down of fermentation time • Production of off-flavors • H 2 S accumulation and production • Too much higher alcohol production
Dangers of under/over N addition YAN Excess • At fermentation start: too much yeast growth • Increase in overall N demand later in fermentation • Heat peak cell damages, loss volatile aromas • Over addition of ammonium ions • Prevention of aa and cysteine conjugates uptake • If DAP used: acidification and salty taste because of phosphate excess • Presence of non assimilated N at the end of AF • Brettanomyces growth • Possible health risk ethyl carbamate production • Possible biogenic amines production by bacteria • Over production of ethyl acetate, acetic acid (VA) and succinic acid
Addition guidelines Importance of selected yeast strains Yeast choice: Type of wines/ alcohol and temperature resistance Function of Selected Yeast Bonus: Sterol source
Addition guidelines Importance of selected nutrients • Example: Round and fruity Pinot Noir Initial YAN: Function of Must Sequential additions: No detrimental effect Not after the middle of fermentation: No uptake
Addition guidelines Nutrient addition calculation guidelines PA limit for extra nutrient addition: Function of Selected Yeast! Ex: CK S 102 limit
Questions?
Thank you for your attention For further information: Etienne DORIGNAC Fermentis Division of S. I. Lesaffre Cell : + 33 6 26 65 17 90 E-mail : edorignac. fermentis@lesaffre. fr Homepage : http: //www. fermentis. com
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