tina sui
(Tina Sui)
#1
378 C, whereas the degree of PE- and PC- hydrolysis was about 50 % after 60 h under
the same conditions.
Since the early 1980s many reports have been published about the catalytic ac-
tivity of hydrolytic enzymes in (nearly) water-free organic solvents of low polarity.
Pernas et al. (1990) showed that extracellular PLA 2 (fromNaja najavenom, bee
venom, porcine and bovine pancreas andStreptomyces violaceoruber) is capable
of catalyzing the esterification of lyso-PC with [^3 H]-oleic acid. They made use
of the findings of Zaks and Klibanov (1988) that enzymes incubated in a buffer
solution at a pH value necessary for optimum activity (in this case a Tris/HCl-buffer
of pH 9 containing 10 mMol CaCl 2 ) prior to lyophilization exhibit the so-called pH-
memory effect. The synthesis was carried out in solvents such as benzene, toluene
and chloroform, which did not affect the activity of the PLA 2. The highest degree of
transesterification was 6.5 % obtained withNaja najaPLA 2. Adding methanol to the
reaction mixture causes a suppression of the PC synthesis, which gives rise to the
assumption (stated earlier by others) that the small amount of water left after lyo-
philization is essential for the catalytic effect, and that this water is removed from the
microenvironment of the enzyme in the presence of small amounts of polar solvents.
Lin et al. (1993) also investigated the behavior of PLA 2 in apolar organic solvents
such as chloroform with low water content. With regard to the hydrolysis of 1,2
dimyristoyl-sn-glycerophosphocholine (DMPC), they found that bee-venom PLA 2
showed the highest activity followed byNaja najaandNaja mocambiquevenom
PLA 2 , whereas pancreatic PLA 2 yielded only poor activities. A small amount of
methanol added to chloroform with 1.7 % water increased the rate of the bee venom
enzyme-catalyzed hydrolysis by a factor of 4, in contrast to the normally observed
effect of this solvent on phospolipase activity. This is possibly due to the fact that
removal of residual water from the microenvironment of the enzyme takes time, and
that the positive influence of methanol on the solubility of the substrate is initially
predominant. Similar findings were reported by Campanella et al. (1998a) in con-
nection with the use of immobilized PLD for analytical purposes (see Section
13.4.2). The course of hydrolysis rate as a function of temperature had a minimum
at T¼ 458 C due to conformational changes of DMPC in 2-position, as proved by
NMR spectroscopy. Furthermore, the authors described a novel route for a venom
PLA 2 -catalyzed transacylation ofL-lyso-PC with long-chain acyl donors. The best
results (37 % yield) were obtained with palmitic anhydride in chloroform-water
(100/1, v/v) at 37 8 C. Ha ̈rro ̈d and Elfman (1995) developed a high-pressure reaction
unit for the synthesis of new phospholipids in isooctane, carbon dioxide and propane
as solvents. The products were obtained by the reaction of lyso-PC with polyunsa-
turated fatty acids (PUFA) of fish oil origin (mainly consisting of eicosapentaenoic
and docosahexaenoic acids) and PLA 2 from porcine pancreatic glands immobilized
to the polysiloxane matrix Deloxan as catalyst. Optimum results with a yield of 25 %
were achieved in a solvent mixture of 91 % PUFA and 9 % propane.
280 13 Preparation and Application of Immobilized Phospholipases
