BLBS102-c13 BLBS102-Simpson March 21, 2012 13:15 Trim: 276mm X 219mm Printer Name: Yet to Come
252 Part 2: Biotechnology and EnzymologyTMA is further discussed in the food microbiology literature
(e.g., Barrett and Kwan 1985, Dalgaard 2000).The Trimethylamine-N-Oxide
Aldolase ReactionTMAO is also the precursor of the formation of dimethylamine
(DMA) and formaldehyde:CH 3 CH (^3) O
ONCH 3 → HNCH 3 HC
CH 3 H
=.
This reaction is catalyzed by trimethylamine-N-oxide aldolase
(TMAOase or TMAO demethylase, EC 4.1.2.32) but may also
to some extent be nonenzymatic, catalyzed by iron and various
reductants (Vaisey 1956, Spinelli and Koury 1981, Nitisewojo
and Hultin 1986, Kimura et al. 2002). In most cases in which
significant amounts of formaldehyde and DMA are accumu-
lated, however, species possessing TMAOase enzyme activity
are involved. The reaction leads to cleavage of a C-N bond and
the elimination of an aldehyde, resulting in the classification of
TMAOase as a lyase (EC 4.1.2.32) and the International Union
of Biochemistry and Molecular Biology name aldolase.
DMA is a reactive secondary amine with a milder odor than
TMA. Formaldehyde is highly reactive and strongly affects the
texture of fish meat by making it tougher, harder, more fibrous,
and less juicy, as well as increasing the drip loss in the thawed
products. The quality changes are associated with a loss in pro-
tein solubility and in particular the solubility of the myofibrillar
proteins. For reviews, see Sikorski and Kostuch (1982), Hultin
(1992), Mackie (1993), Sikorski and Kolakowska (1994), and
Sotelo et al. (1995).
Formaldehyde can react with a number of chemical groups,
including some protein amino acid residues and terminal amino
groups, resulting in denaturation and possibly in the cross-
linking of proteins, both of which are believed to be the cause
of the observed effects on seafood products. The formaldehyde
concentration in severely damaged seafood products may reach
240 μg/g (Nielsen and Jørgensen 2004). These concentrations
are generally considered nontoxic, but may still exceed various
national trade barrier limits.
Whereas TMAO is widespread, TMAOase is only found in a
limited number of animals, many of which belong to the order
of gadiform fish (pollock, cod, etc.). In gadiform species, the
highest levels of enzyme activity are found in the inner organs
(kidney, spleen, and intestine), while the enzyme activity in the
large white muscle is low. The formation of DMA and formalde-
hyde in various tissues of certain nongadiform fish, as well as of
crustaceans and mollusks, has also been reported, as reviewed
by Sotelo and Rehbein (2000), although the taxonomic distri-
bution of the enzyme has not been investigated systematically.
The TMAOase content of gadiform fish exhibits large individual
variation, probably due to the influence of biological factors that
have not yet been adequately studied (Nielsen and Jørgensen
2004).The enzyme is stable and tolerates both high salt concentra-
tions and freezing. The accumulation of DMA and formalde-
hyde progresses only slowly, and most of the accumulation is
produced during prolonged frozen storage or cold storage of
the salted fish (e.g., salted cod and bacalao). During freezing,
the enzymatic reaction proceeds as long as liquid water and
substrate are available. In practice, the formation of DMA and
formaldehyde is found at temperatures down to approximately
− 30 ◦C (Sotelo and Rehbein 2000). At higher temperatures, the
rate of formation of formaldehyde is also higher; thus, freezing
of gadiform fish at insufficiently low temperatures may result in
dramatic changes in the solubility of myofibrillar proteins within
a few weeks (Nielsen and Jørgensen 2004).
Despite the TMAOase concentration of the white muscle be-
ing low, it is the enzyme activity of the white muscle that is
responsible for the accumulation of formaldehyde in whole fish
and in fillets (Nielsen and Jørgensen 2004). In the case of minced
products, even minor contamination by TMAOase-rich tissues
leads to a marked rise in the rate of accumulation (Dingle et al.
1977, Lundstrøm et al. 1982, Rehbein 1988, Rehbein et al. 1997).
Despite its dependency upon other factors, such as cofactors, the
rate of accumulation of formaldehyde can to a large extent be
predicted from the TMAOase enzyme activity of fish meat alone
(Nielsen and Jørgensen 2004).
The physiological function of TMAOase remains unknown.
The formation of formaldehyde could have a digestive func-
tion, yet this would not explain the high TMAOase content of
the kidney and spleen. Accordingly, it has been speculated that
TMAO may not even be its primary natural substrate (Sotelo
and Rehbein 2000).
The in vitro reaction rate is low without the presence of a num-
ber of redox-active cofactors. Although the overall TMAOase
reaction is not a redox reaction, its dependency on redox agents
shows that the reaction mechanism must include redox steps.
Little is known about the in vivo regulation of TMAOase,
but studies suggest the importance of nucleotide coenzymes
and iron (Hultin 1992). TMAOase appears to be membrane
bound and is only partly soluble in aqueous solutions. This has
complications for its purification and is one of the main reasons
why the complete characterization of the enzyme remains yet to
be done.POSTMORTEM PROTEOLYSIS
IN FRESH FISHPostmortem proteolysis is an important factor in many changes
in seafood quality. During cold storage, the postmortem prote-
olysis of myofibrillar and connective tissue proteins contributes
to deterioration in texture. Despite the natural tenderness of
seafood, texture is an important quality parameter, in fish
and shellfish alike. Deterioration in seafood quality through
proteolysis involves a softening of the muscle tissue. This re-
duces the cohesiveness of the muscle segments in fillets, which
promotes gaping, a formation of gaps and slits between muscle
segments. The negative character of this effect contrasts with
the effect of postmortem proteolysis on the meat of cattle and