Biotechnological applications of Candida antarctica lipase A: State-of-the-art

The yeast Candida antarctica produces two different lipases, lipases A and B. While lipase B (CAL-B) is probably the mostly employed hydrolase in the biocatalysis field, the use of the lipase A (CAL-A) has been rather scarce and consequently its tridimensional structure has not been elucidated yet. However, CAL-A is a useful biocatalyst with many different applications that have been described especially in the last few years. Its attractiveness results from its unique features among hydrolases: the high thermostability, allowing operation at T > 90 °C; the ability to accept tertiary and sterically hindered alcohols, which has recently been attributed to the existence of a specific aminoacidic sequence in the active site; the sn-2 recognition in hydrolysis of triglycerides; the selectivity towards trans-fatty acids; the stability in the acidic pH range. Furthermore, it is considered to be an excellent biocatalyst for the asymmetric synthesis of amino acids/amino esters, due to its chemoselectivity towards amine groups. Considering all these aspects, in the present review, the origin, the properties and the applications of the CAL-A are briefly described and discussed, pointing out the unique characteristics of this biocatalyst

Hydrolase-catalysed synthesis of peroxycarboxylic acids: Biocatalytic promiscuity for practical applications

The enzymatic promiscuity concept involves the possibility that one active site of an enzyme can catalyse several different chemical transformations. A rational understanding of the mechanistic reasons for this catalytic performance could lead to new practical applications. The capability of certain hydrolases to perform the perhydrolysis was described more than a decade ago, and recently its molecular basis has been elucidated. Remarkably, a similarity between perhydrolases (cofactor-free haloperoxidases) and serine hydrolases was found, with both groups of enzymes sharing a common catalytic triad, which suggests an evolution from a common ancestor. On the other hand, several biotechnological applications derived from the capability of hydrolases to catalyse the synthesis of peracids have been reported: the use of hydrolases as bleaching agents via in situ generation of peracids; (self)-epoxidation of unsaturated fatty acids, olefins, or plant oils, via Prileshajev epoxidation; Baeyer-Villiger reactions. In the present review, the molecular basis for this promiscuous hydrolase capability, as well as identified applications are reviewed and described in detail