strategy requires the use of a cofactor regenerating enzyme and an inexpensive sacrificial
substrate (Figure 6.16a).
This enzyme uses the extra substrate to catalyse the regeneration of the cofactor that
was spent in the main reaction. The criteria used for the choice of the cofactor
regenerating
Figure 6.16 Cofactor regeneration by:
a) coupling of enzymes and b) coupled
substrate approach (S 1 —main
substrate, S2—auxiliary substrate, P 1 —
main product, P 2 —secondary product,
CoF—cofactor, CoF*—spent cofactor,
E 1 , E 2 and E—enzymes).
Table 6.6 Reactions with cofactors
Enzyme-reaction description Reference
Synthesis of L-methionine and L-phenylalanine from the N-acetyl-DL-
derivatives by acylase
Leuchtenberger et al.,
1984Synthesis of L-malic acid by the fumarase stereoselective addition of
water to fumaric acid
Leuchtenberger et al.,
1984Synthesis of L-leucine with NADH (PEG bound) regeneration by
leucine and formate dehydrogenases Leuchtenberger et al., 1984;
Ohshima et al., 1985;
Kragl et al., 1996a;
Wichmann et al., 2000Transformation of LD-lactate via pyruvate to L-alanine with NADH
(PEG bound) regeneration
Wandrey et al., 1984Synthesis of L-and D-2-hydroxyisocaproic acid by dehydrogenases
with NADH (PEG bound) regeneration
Wichmann et al., 1984Synthesis of glucose 6-phosphate by hexokinase with ATP regeneration
by acetate kinase
Berke et al., 1984, 1988Synthesis of L-lactate with NAD (PEG bound) regeneration by lactate
and malate dehydrogenases
Hayakawa et al., 1985Enzymatic membrane reactors 169