Front Matter

1.2.2 Hydrolysis using fatty acid-selective lipases

Reduction of the saturated fatty acid content in oil

Another application of a specific lipase in triglyceride hydrolysis is the production of

a low-SAFA oil. For many decades, the lowering of blood cholesterol by changing

dietary fat consumption has been a hot issue. Nowadays, it is recommended that the

intake of total fat is limited, and especially that from saturated fats (American Die-

tetic Association, 1998); hence, there is considerable interest in low saturated fat

products.

Based on the typical selectivity of lipases fromFusarium oxysporum, it should be

possible to lower the level of saturated fatty acids in oil via selective hydrolysis. Both

intracellular and extracellular lipases from this microorganism have been described

which are reported to have a high affinity towards saturated fatty acids.

The extracellular lipase was shown to hydrolyze tristearin at a higher rate as com-

pared to triolein, both as single substrates. However, when mixed triglycerides were

tested, no significant selectivity for the saturated fatty acids was actually observed

(Hoshino et al., 1992).

Using an intracellular lipase fromFusarium oxysporum, hydrolysis of cotton seed

oil or groundnut oil yielded high levels of saturated fatty acids in the free fatty acid

fraction (Joshi and Dhar, 1987). Recalculation of the experimental data suggests that

this lipase even has an overall specificity factor in the range of 40^1.

Unfortunately, no more data are available on any further attempts to exploit this

rare fatty acid selectivity.

Another option for producing a low-SAFA oil is a two-step process based on the

high selectivity of Lipase B (Charton and Macrae, 1992) or Lipase I (Holmqvist et

al., 1997) fromGeotrichum candidum. This B-lipase has a very distinct preference

for handling unsaturated free fatty acids with acis-D-9 double bond, e.g., oleic or

linoleic acid.

For example, taking sunflower oil [
88 % (w/w) unsaturated fatty acids] as sub-

strate,>99 % unsaturated fatty acids were obtained upon hydrolysis in a 1 : 1 oil/

water emulsion (Diks and Lee, 1999). From the experimental data it was derived that

the so-called ‘specificity factor’ was approximately 30. It was shown that the lipase

maintained its high selectivity up to 70 % degree of hydrolysis.

Of practical importance is the rather low stability of the lipase observed during

hydrolysis in emulsion. In solution, the lipase appeared quite stable, even at 40 8 C.

Once added to the oil/water emulsion, the lipase lost most of its activity within hours

at only 30 8 C. This discrepancy was attributed to a reduced stability of the lipase at

the oil/water interface (Diks and Lee, 1999).

Immobilization was shown not to effect the selectivity of theGeotrichumB-lipase

(Charton and Macrae, 1993). Moreover, the catalyst was active in organic solvents.

1.2 Free fatty acids 5

(^1) Specificity factor defined as S¼(S/U)
FFA/(S/U) (Diks and Lee, 1999), in which S is the fraction of
saturated fatty acids and U the fraction of unsaturated fatty acids. The specificity factor reflects the
relative net rate of hydrolysis of the saturated over the unsaturated fatty acid, corrected for their con-
centration difference in the starting oil.