Food Biochemistry and Food Processing (2 edition)

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BLBS102-c09 BLBS102-Simpson March 21, 2012 11:15 Trim: 276mm X 219mm Printer Name: Yet to Come


9 Enzymes in Food Processing 191

oryzaeknown as asperzyme and a liquid saccharifying amylase
for the production of fermentable sugars known as adjuzyme,
which is derived fromA. niger. An Enzeco glucoamylase powder
derived fromA. nigeris also commercially available for use in
baked goods to improve proofing in lean or frozen doughs, and
brewers amylase produced in powder form fromAspergillus
spandRhizopus oryzaeis used for the manufacture of light
beers. Others are Brewers Fermex derived fromAspergillus sp.
andRhizopus oryzaein powder form for use in increasing the
fermentability of wort and cookerzyme derived fromB. subtilis
for accelerated hydrolysis of starch adjuncts.

Galactosidases and Lactases

Galactosidases are those carbohydrases that catalyze the
hydrolysis of galactosides such as lactose, lactosylceramides,
ganglioside, and various glycoproteins into their constituent
monosaccharide units. Two types of galactosidases are
distinguished based on their mode of action asα-andβ-
galactosidases. Theα-galactosidases (also known asα-gal)
catalyze the hydrolytic cleavage of the terminalα-galactosyl
residues fromα-galactosides (including certain glycoproteins
and glycolipids) and they can catalyze the hydrolysis of the
disaccharide melibiose into galactose and glucose.α-Gal is used
as a dietary supplement (e.g., beano) to facilitate the breakdown
of complex sugars into simpler forms to permit easier digestion
and reduce intestinal gas and bloating. The enzyme may also be
used to reduce the complex carbohydrate content of the beer to
increase the simple sugar content and hence the alcohol content
of beer. Theβ-gals facilitate the hydrolysis ofβ-galactosides
such as lactose, various glycoproteins, and ceramides into
simpler forms.
Lactases belong to theβ-galactosidase family of enzymes;
they catalyze the breakdown of the milk sugar lactose into
its constituent monosaccharides, galactose and glucose units,
that is,

Lactose+H 2 O⇔Galactose+Glucose

Lactases are produced in commercial quantities from yeasts
such asK. fragilisandK. lactis,and from fungi such asA. niger
andA. oryza(Mustranta et al. 1981). Other lactase-producing
microorganisms include the bacteriaStreptococcus cremoris,
Lactobacillus bulgaricus,andLeuconostoc citrovorum(Ramana
Rao and Dutta 1978). Lactases are also found in the mucous
lining of the small intestines of cows and rabbits, and in the
walls of the small intestines of humans from as early as the
fifth month of intrauterine life. However, lactase levels tend to
be higher in younger animals and human infants, and the levels
generally decrease with age (Heilskov 1951). The enzyme is
also found in plants, e.g., from the calli and roots of gherkin,
pea, poppy, and eastern blue star seedlings (Neubert et al. 2004).
Lactase is commercially produced by Novozymes from the
dairy yeastK. lactisand marketed as Lactozym. Lactase as lac-
tozym is widely used in the dairy industry to produce fermented
milks, ice-cream, milk drinks, and lactose-reduced milk for peo-
ple who are lactose-intolerant and for household pets (e.g., cats)
that cannot utilize lactose. Milks treated with lactose tend to be

sweeter than their untreated counterparts because the monosac-
charides glucose and galactose produced in the treated milks are
sweeter than the disaccharide lactose in untreated milks. Crys-
tallization of lactose in condensed milk can also be prevented by
treating the milk first with lactase. Lactase-treated milks used for
the preparation of cultured milk products (e.g., cottage cheese
or yogurt) ferment faster than untreated milks, because lactose
in the latter ferment at a slower pace than the glucose and galac-
tose in the treated milks. As well, the cultured milk products
from the lactase-treated milks tend to be sweeter than the prod-
ucts prepared from the nontreated milks. Milk whey may also
be treated with lactase and concentrated to form syrups for use
as a sweetener in food products. Ice cream made from lactase-
treated milk (or whey) also has little or no lactose crystals, thus
the undesirable “sandy” feel due to lactose crystallization is
averted.

Maltases

Maltase is the carbohydrase that breaks down the disaccharide
maltose into glucose units as summarized in the reaction below:

Maltose+H 2 O⇔ 2 α-Glucose

Maltase is found in humans and other vertebrate animals,
plants, and microorganisms (bacteria and yeast). In humans,
digestion of starch commences in the mouth with ptyalin (saliva
enzyme) and pancreatic amylases breaking down the starch into
maltose. The maltose is subsequently hydrolyzed by intestinal
maltase into glucose for utilization by the body to produce energy
or for storage in the liver as glycogen. Maltase (from barley malt)
is used in brewing to increase the glucose content for conversion
into alcohol. Maltase fromA. oryzaeis used in the beet-sugar and
molasses distilleries, and in the industrial production of glucose
syrups (McWethy and Hartman 1979).

Cellulases

Cellulases are enzymes that potentiate the breakdown of theβ-
1,4-glycosidic bonds in cellulose. They are produced commonly
by bacteria (e.g., Clostridium thermocellum, Acidothermus
cellulolyticus(Tucker et al. 1988)), fungi (Trichoderma reesei,
T. hamatum,Fusarium roseum,Curvularia lunata(Sidhu et al.
1986)), and protozoa (e.g.,Trichomitopsis termopsidis(Odelson
and Breznak 1985),Eudiplodinium maggii, Epidinium ecauda-
tum caudatum,andOstracodinium obtusum bilobum(Coleman
1985)), although the enzymes are also found in plants (e.g., cress
and pepper (Ferrarese et al. 29)) and animals (e.g., termites, crus-
tacea, insects, and nematodes (Watanabe and Tokuda 2001)). A
simplified equation for the hydrolysis of cellulose by cellulases
may be summarized as

Cellulose+H 2 O⇔nβ-D-Glucose

Native cellulose is highly crystalline in nature and its com-
plete hydrolysis entails stepwise reactions catalyzed by a com-
plex of cellulase enzymes. It entails the preliminary unraveling
of the crystalline cellulose molecules into simple (or linear)
cellulose chains by endocellulases. The linear cellulose chains
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