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676 Part 6: Health/Functional Foods
(e.g., isoflavones), and enzymes are but a few of the many com-
pounds have been suggested as being linked to functionality of
probiotics. In this chapter, the potential contribution of enzymes
produced by probiotic bacteria to their functionality will be ex-
amined. The critical contribution of enzymes will be addressed
from both a technological perspective (ability to grow and re-
main viable in a food product) and a health perspective (survival
to GI environments, effects on human functions).
BIOCHEMISTRY AND GROWTH OF
PROBIOTIC CULTURES IN FOODS
Several different metabolic pathways explain the biosynthetic
functions of microorganisms that could maintain their life. Each
metabolic pathway consists of many reactions that are regulated
by different enzyme systems, and so the level of enzymes and
their activity sustain and control the functions of the microbial
cell (Stanier et al. 1987). Breakdown of nutrients (carbohydrates,
proteins, lipids, and other minor constituents) present in the
growth medium results in the production of smaller molecules
that are subsequently consumed for buildup and division of the
microbial cells as well as energy requirements for survival.
In lactic acid bacteria (LAB) (i.e., the lactococci, leuconostoc,
lactobacilli, streptococci, and bifidobacteria), energy is mainly
supplied by the fermentation of carbohydrates (Lawrence et al.
1976). Hundreds of enzymes are required to sustain life in mi-
croorganisms. However, some are recognized as being more
critical in affecting growth rates and biomass levels on food
substrates. In general, the two most important biochemical re-
actions are carbohydrate assimilation and protein metabolism.
This justifies the focus that will be made of these particular
enzymatic activities.
Milk
In milk, “lactase” and “protease” activities of yogurt and pro-
biotic cultures are critical to growth and acidification rates
(Tamime and Robinson 1999).
Lactose is the main carbohydrate in milk and it can be
metabolized either through the homo- or heterofermentative
metabolic pathways.Streptococcus thermophilus, Lactobacil-
lus delbrueckii subsp. bulgaricus,andLactobacillus acidophilus
ferment lactose homofermentatively, lactic acid being the main
metabolite.Bifidobacteriumspp., on the other hand, ferments
the same sugar heterofermentatively, producing lactic and acetic
acid typically at a 2:3 ratio. Lactose must enter the cytoplasm to
be catabolized. A specific system is involved in lactose transport
in the lactococci and certain strains ofL. acidophilusand sugar is
phosphorylated by phosphoenolpyruvate (PEP) during translo-
cation by the PEP dependent phosphotransferase system (PTS)
(Kanatani and Oshimura 1994, Marshall and Tamime 1997).
This mechanism is known as PEP:PTS.β-Phosphogalactosidase
hydrolyses lactose-6-phosphate to its monosaccharide compo-
nents. The galactose and glucose thus released are then catab-
olized via Tagatose and Emden–Meyerhof–Parnas (EMP) path-
ways, respectively (Monnet et al. 1996, Marshall and Tamime
1997). Some organisms includingBifidobacteriumspp. have an
alternative system for lactose transport into the cells that in-
volves cytoplasmic proteins (permeases). This is to translocate
lactose without chemical modification and the mechanism could
be similar to the lactose permease system inEscherichia coli.
After lactose enters the cell, it is hydrolyzed byβ-galactosidase
(β-gal) to nonphosphorylated glucose and galactose. In many
yogurt cultures, glucose is catabolized to pyruvate and the galac-
tose is secreted from the cell. Less is known on the lactases of
probiotic bacteria. Some bifidobacteria seem to have two types
ofβ-gal and their level seem critical to rapid growth in milk.
Indeed, Desjardins et al. (1991) showed that the growth perfor-
mance of bifidobacteria in milk is linked to theirβ-gal levels.
L. acidophilusorBifidobacteriumsp. generally grows faster on
synthetic media than on milk (Misra and Kuila 1991, Gaudreau
et al. 2005). Therefore, it is not surprising that the addition of
β-gal to milk enhances the growth rate ofL. acidophilus(Khattab
et al. 1986). In an interesting variation of this concept, ruptured
cells of a yogurt culture were added to milk in order to promote
the development ofL. acidophilusandBifidobacterium longum
in the fermented product (Shah et al. 1997). Presumably, the
liberation ofβ-gal from the ruptured starter cells contributed
to the stimulation. This was also noted forLactobacillus rham-
nosus(Gaudreau et al. 2005). However, the ability of a strain
to synthesize enzymes essential in the assimilation of a carbo-
hydrate provides an incomplete picture of the ability to grow
rapidly on the food matrix. The activity of the enzymes will also
influence growth rates. Thus, for a given strain, growth rates
in identical media will vary as a function of the carbohydrate
(Table 35.1). There are numerous observations of variable en-
zyme activity levels between strains (Desjardins et al. 1991,
Donkor et al. 2007).
The protein fraction in milk is composed of casein and whey
proteins and the basic constituents of a protein molecule are
compounds from 21 amino acids (Tamime and Robinson 1999).
Since LAB cannot synthesize many amino acids (Marshall and
Law 1984), proteolytic activity is greatly involved in both nu-
trition and interactions between the two yogurt cultures as well
as with probiotic bacteria. Amino acids and peptones are good
supplements for bifidobacteria (Klaver et al. 1993). This would
suggest that high proteolytic activities would enhance growth
rates and levels. This is not always the limiting factor with
Table 35.1.Effect of the Nature of the Sugar on Growth
Rate (h−^1 ) of Two Probiotic Cultures in a Laboratory
Growth Medium (Peptones, Salts, Tween)
Carbohydrate
Lactobacillus
helveticusR0052
Bifidobacterium
longumR0175
Glucose 0.13 0.06
Stachyose 0 0.06
Lactose 0.15 0.07
Fructose 0.08 0
Sucrose 0.08 0
Raffinose 0 0.06
Source: Champagne et al. 2010.