Front Matter

of phospholipases as such. Here, the influence of experimental parameters (described

in Sections 13.3.1–13.3.3) on the properties of the carrier-bound enzymes and their

optimization with respect to high residual catalytic activity are investigated. From

the different immobilization methods described in Section 13.3.1, it was clear that

adsorption and covalent attachment were mainly used, and that the carrier materials

most frequently applied were porous glass and synthetic organic polymers. Until

now, immobilized phospholipases have not been used in industrial processes, as

for example the conversion of lecithin to lysolecithin in the presence of PLA 2 ,

nor in connection with the phospholipase-catalyzed synthesis of new phospholipids

on a preparative scale. By far the most investigations in this field have been carried

out with the immobilization of PLA 2.

13.4.1 Immobilization of phospholipase A 2

Fundamental research on this topic has been carried out by Dennis and co-workers.

In an early publication, they described the immobilization of a cobra venom PLA 2 on

porous glass beads by diazo coupling (Adamich et al., 1978). The products obtained

had residual activities of just 1 %. A few years later, Lombardo and Dennis (1985;

1986) reported on studies carried out with PLA 2 from the same source (Indian cobra;

Naja naja naja), but attached covalently to an agarose gel via tresyl chloride. The

protein binding yield was up to 87 %. For test reactions, substrates such as dipal-

mitoyl-PC, diheptanoyl-PC and the corresponding PE-derivatives were used. A se-

lection of data from these publications is listed in Table 3; these show that the activity

of immobilized PLA 2 towards dipalmitoyl-PC/Triton X-100 micelles again is just 1–

2 % of the specific activity of the soluble (native) PLA 2. The exchange of dipalmi-

toyl-PC by dipalmitoyl-PE leads to significantly lower activities, but a reduced ac-

tivity difference between the immobilized and the native species. Transition from the

monomeric to the micellar state of diheptanoyl-PC causes a 40-fold increase in ac-

tivity when the reaction is catalyzed by soluble PLA 2. In the presence of immobilized

PLA 2 , the reaction rate is merely enhanced by a factor of 3.5. Triton X-100 does not

274 13 Preparation and Application of Immobilized Phospholipases

Table 3.Activities of soluble and immobilized PLA 2. (Data from Lombardo and Dennis, 1986).

Substrate Triton X-100 Specific activities (llmol/(min
g))

soluble PLA 2 immobilized

PLA 2

(%)

Dipalmitoyl-PC (5 mM) 20 mM 1120 19 1.70

Dipalmitoyl-PE (5 mM) 20 mM 13 5.3 40.8

Diheptanoyl-PC (0.8 mM) – 86 77 87.5

Diheptanoyl-PC (3.2 mM) – 3400 280 8.24

Diheptanoyl-PE (0.2 mM) – 81 25 30.9

Diheptanoyl-PE (0.2 mM) 2 mM 71 25 32.5