Abstract
Microbial lipases represent one of the most important groups of biotechnological biocatalysts. However, the high-level production of lipases requires an understanding of the molecular mechanisms of gene expression, folding, and secretion processes. Stable, selective, and productive lipase is essential for modern chemical industries, as most lipases cannot work in different process conditions. However, the screening and isolation of a new lipase with desired and specific properties would be time consuming, and costly, so researchers typically modify an available lipase with a certain potential for minimizing cost. Improving enzyme properties is associated with altering the enzymatic structure by changing one or several amino acids in the protein sequence. This review detailed the main sources, classification, structural properties, and mutagenic approaches, such as rational design (site direct mutagenesis, iterative saturation mutagenesis) and direct evolution (error prone PCR, DNA shuffling), for achieving modification goals. Here, both techniques were reviewed, with different results for lipase engineering, with a particular focus on improving or changing lipase specificity. Changing the amino acid sequences of the binding pocket or lid region of the lipase led to remarkable enzyme substrate specificity and enantioselectivity improvement. Site-directed mutagenesis is one of the appropriate methods to alter the enzyme sequence, as compared to random mutagenesis, such as error-prone PCR. This contribution has summarized and evaluated several experimental studies on modifying the substrate specificity of lipases.
Highlights
The most widely used biocatalysts for oil and fat modification are lipases (EC 3.1.1.3, triglycerol hydrolases) [1]
Addition, the homologous isoforms of C. rugosa lipase vary in their specificity of the fatty acids chain the homologous isoforms of C. rugosa lipase vary in their specificity of the fatty acids chain length, length, due to differences in their tunnel-shaped binding site as differing in their amino acids [90]
This approach is based on the knowledge of possible relationships of structure, sequence, function, and catalytic mechanisms of protein to allow the prediction of amino acid residues needed for mutation
Summary
The most widely used biocatalysts for oil and fat modification are lipases (EC 3.1.1.3, triglycerol hydrolases) [1]. Ideal tools for organic chemistry due to many factors, such as their availability in large quantities, as many are produced by microbial organisms, including bacteria and fungi. They display exquisite stereoselectivity, chemoselectivity, regioselectivity, and do not catalyze side reactions, or cofactors are necessitated. Certain applications require specific modifications of an enzyme’s properties to meet the application requirements. This generally includes catalyst stereo-chemoselectivity, regioselectivity, activity at high substrate concentration, elevated temperature or extreme pH. Many structural enzyme parts are used as the main target, such as altering the amino acid sequence by mutation in the active site-substrate binding area or lid region, which has been shown to mediate enzyme chain length selectivity [7]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
