Abstract
Lipases (E.C. 3.1.1.3) are serine-hydrolases, and act on long chain fatty acid ester bonds. They exhibit specific and enantioselective activities, which are desirable for many industrial applications. This study aimed at screening and optimizing the production of lipases by wild yeast strains from a variety of substrates, as well as characterizing the enzyme. An initial selection was made in oxygenated oil-supplemented minimum medium, and the enzymatic activity of the supernatant was tested over p- nitrophenyl palmitate. One-hundred and twenty-four yeast strains from different substrates were tested, and twenty-three showed significantly higher lipolytic activity (p <0.01). One yeast in particular, QU110, showed best lipase production and therefore was selected for the optimization and characterization processes. This yeast exhibits enzyme secretion in initial pH 6.0, with olive oil and tryptone as carbon and nitrogen sources, respectively. There was a strong interaction between nitrogen source and initial pH, and pH 9.0 seems to inhibit enzyme secretion. The crude enzyme (cell-free supernatant) shows stability in surfactants and n-hexane, but not in ethanol or methanol. A Response Surface Model was created and optimal enzyme activity conditions were observed at 36°C and pH 8.0. The lipase is appropriate for transesterification reactions, as the enzyme is more stable in strong apolar solvents than moderately apolar ones. Also, secretion by pH was not reported elsewhere, which should be further investigated and contribute for other yeast bioprocesses as well.
Highlights
Lipases (E.C. 3.1.1.3) catalyze hydrolysis and synthesis reactions over triacylglycerol esters
Candida parapsilosis QU110 was selected for optimization of lipase production due to its higher lipase activity when compared to the others, and consistency between the replicates
This yeast was isolated from an artisanal Caccio Cavalo cheese sample (Landell et al, 2006), and was identified as Candida parapsilosis by sequencing the D1/D2 region of the 26S rDNA
Summary
Lipases (E.C. 3.1.1.3) catalyze hydrolysis and synthesis reactions over triacylglycerol esters. The typical structure involves a catalytic triad (Ser-His-Asp), and the main residue, Serine, is commonly found in a (SerX-His-X-Asp) sequence (Jain & Naik, 2018). Lipases are distinguished from other esterases especially by the interfacial activity, given by a hydrophobic “lid” that covers the catalytic center and prevents it from acting on water soluble substrates (Gupta, Kumari, Syal, & Singh, 2015). Lipases can hydrolyze many substrates of esterases, and the opposite occurs (Lopes, Fraga, Fleuri, & Macedo, 2011). Lipases possess interesting properties such as chemo-, regio- and stereoselectivity. A broad range of applications is possible, such as detergents and emulsifiers, biodiesel transesterification, paper pulp and leather cleaning, resolution of racemic solutions, food nutrition and flavor enhancement (Navvabi, Razzaghi, Fernandes, Karami, & Homaei, 2018; Sharma et al, 2012)
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