90 R. Peinado and J. Mauricio
Acetic
AcidGlycerol EthanolL-ProlineAcetic
AcidEthanolDihydroxyacetoneAcetaldehydePiruvic acidOxalacetic AcidAcetoin
Butanedione2,3 ButanediolPolysaccharide Hexose +CO 2Fumaric Acid Aconitic Acid2-Ketoglutaric AcidMalic Acid Citric AcidSuccinic Acid Isocitric Acid
Glutamic AcidCO 2 + H 2 O + ATPAcetic AcidAcetyl-CoA + CO 2Fatty Acids CycleFatty Acid SaturatedFatty Acid UnsaturatedSterolsCO 2 +H 2 OGlycerolPhospholipidsAmino Acids
ProteinL-ProlineO 2 O 2O 2O 2O 2O 2O 2Fig. 3B.4General scheme of the flor yeast metabolism
diacetyl and acetoin, and theremainder is metabolizedvia the tricarboxylic acid
pathway for incorporation as carbohydrates, lipids and proteins into cellular material
(Su ́arez-Lepe and I ̃nigo-Leal 2004). The ethanol uptake is governed by various fac-
tors such as the dominant yeast race in the flor film, film formation stage and aging
stage. Thus, ethanol is consumed in increased amounts at the film formation stage,
and also in the scales containing the youngest wine (Mart ́ınez et al. 1993, 1998).
Usually, up to 1 vol.% ethanol can be used during the aging process - nearly 4 vol.%
has been lost in some laboratory tests.
3B.3.2 Glycerol
Glycerol is the third most abundant component of wine after water and ethanol.
Yeasts use it as a carbon source and reduce its concentration with time. This has
prompted the use of the glycerol content of wine as a measure of its degree of aging
(Cort ́es et al. 1998; Moreno et al. 2001).
3B.3.3 Acetaldehyde
Acetaldehyde is one of the most special compounds in the biological aging process
and influences the sensory properties of wines by introducing a typical pungent