BLBS102-c16 BLBS102-Simpson March 21, 2012 10:54 Trim: 276mm X 219mm Printer Name: Yet to Come
306 Part 3: Meat, Poultry and Seafoods
Muscle Lipases
Lysosomal acid lipase and acid phospholipase are located in
the lysosomes. Both have an optimal acid pH (4.5–5.5) and are
responsible for the generation of long-chain free fatty acids.
Lysosomal acid lipase has preference for the hydrolysis of tri-
acylglycerols at positions 1 or 3 (Fowler and Brown 1984). This
enzyme also hydrolyzes di- and monoacylglycerols but at a lower
rate (Imanaka et al. 1985, Negre et al. 1985). Acid phospholi-
pase hydrolyzes phospholipids at position 1 at the water-lipid
interface.
Phospholipase A and lysophospholipase have optimal pH in
the basic region and regulate the hydrolysis of phospholipids, at
positions 1 and 2, respectively. The activities of these enzymes
are higher in oxidative muscles than in glycolytic muscles, and
this fact would explain the high content of free fatty acids in
oxidative muscles. The increase in activity is about 10- to 25-
fold for phospholipase A and 4- to 5-fold for lysophospholipase
(Alasnier and Gandemer 2000).
Acid and neutral esterases are located in the lysosomes and
cytosol, respectively, and are quite stable (Motilva et al. 1992).
Esterases are able to hydrolyze short-chain fatty acids from tri-,
di-, and monoacylglycerols, but they exert poor action due to the
lack of adequate substrate.
Adipose Tissue Lipases
Hormone-sensitive lipase is the most important enzyme present
in adipose tissue. This enzyme is responsible for the hydrolysis
of stored adipocyte lipids. It has a high specificity and prefer-
ence for the hydrolysis of long-chain tri- and diacylglycerols
(Belfrage et al. 1984). This enzyme has positional specificity
since it hydrolyzes fatty acids at positions 1 or 3 in triacylglyc-
erols four times faster than it hydrolyzes fatty acids in position
2 (Belfrage et al. 1984). The hormone-sensitive lipase has a
molecular mass of 84 kDa and neutral optimal pH, around 7.0.
The monoacylglycerol lipase is mainly present in the adipocytes,
and very little is present in stromal and vascular cells. It has a
molecular mass of 32.9 kDa and hydrolyzes medium- and long-
chain monoacylglycerols resulting from previous hydrolysis by
the hormone-sensitive lipase (Tornquist et al. 1978). Lipopro-
tein lipase is located in the capillary endothelium and is able to
hydrolyze the acylglycerol components at the luminal surface
of the endothelium (Smith and Pownall 1984), with preference
for fatty acids at position 1 over those at position 3 (Fielding
and Fielding 1980). Lipoprotein lipase is an acylglycerol lipase
responsible for the degradation of lipoprotein triacylglycerol. Its
molecular mass is around 60 kDa and it has an optimal basic pH.
Unsaturated monoacylglycerols are more quickly hydrolyzed
than saturated compounds (Miller et al. 1981).
The lipolysis phenomenon in adipose tissue is not so complex
as in muscle. The hormone-sensitive lipase hydrolyzes tri- and
diacylglycerols, as a rate-limiting step (Xiao et al. 2010). The
resulting monoacylglycerols from this reaction or from lipopro-
tein lipase (Belfrage et al. 1984) are then further hydrolyzed by
the monoacylglycerol lipase. The end products are glycerol and
free fatty acids.
Acid and neutral esterases are also present in adipose tissue
(Motilva et al. 1992). During mobilization of depot lipids, es-
terases can participate by mobilizing stored cholesteryl esters.
Esterases can also degrade lipoprotein cholesteryl esters taken
up from the plasma (Belfrage et al. 1984).
Muscle Oxidative and Antioxidative Enzymes
Oxidative Enzymes
Lipoxygenase contains iron and catalyzes the incorporation of
molecular oxygen into polyunsaturated fatty acids, especially
arachidonic acid, and esters containing a Z,Z-1,4-pentadien
(Marczy et al. 1995). They receive different names, 5-, 12-,
or 15-lipoxygenase, depending on the position where oxygen
is introduced. The final product is a conjugated hydroperoxide.
They usually require millimolar concentrations of Ca+^2 , and
their activity is stimulated by ATP (Yamamoto 1992). Lipoxy-
genase has been found to be stable during frozen storage and is
responsible for rancidity development in chicken, especially in
the muscleGastrocnemius(Grossman et al. 1988).
Antioxidative Enzymes
Antioxidative enzymes and their regulation in the muscle consti-
tute a defense system against oxidative susceptibility (i.e., an in-
creased concentration of polyunsaturated fatty acids) and physi-
cal stress (Young et al. 2003). Glutathione peroxidase contains a
covalently bound selenium atom that is essential for its activity.
This enzyme catalyzes the dismutation of alkyl hydroperoxides
by reducing agents like phenols. Its activity has been reported to
be lower in oxidative muscles than in glycolytic muscles (Daun
et al. 2001). Superoxide dismutase is a copper metalloenzyme,
and catalase an iron metalloenyzme. Both enzymes catalyze the
dismutation of hydrogen peroxide to less harmful hydroxides.
These enzymes influence the shelf life of the meat and pro-
tect against the pro-oxidative effects of chloride during further
processing.
PROTEOLYSIS
Proteolysis constitutes an important group of reactions during
the processing of meat and meat products. In fact, proteolysis has
a high impact on texture, and thus meat tenderness, because it
contributes to the breakdown of the myofibrillar proteins respon-
sible for muscle network, but proteolysis also generates peptides
and free amino acids that have a direct influence on taste and
also act as substrates for further reactions contributing to aroma
(Toldr ́a 1998, 2002). In general, proteolysis has several consec-
utive stages (see Fig. 16.3) as follows: (1) action of calpains and
cathepsins on major myofibrillar proteins, generating protein
fragments and intermediate size polypeptides; (2) these gener-
ated fragments and polypeptides are further hydrolzyed to small
peptides by DPPs and TPPs; and (3) dipeptidases, aminopepti-
dases, and carboxypeptidases are the last proteolytic enzymes
that act on previous polypeptides and peptides to generate free
amino acids. The progress of proteolysis varies depending on