Screening of Gastrointestinal Lipase Inhibitors Produced by Microorganisms Isolated from Soil and Lake Sediments.

Gastrointestinal lipase inhibitors are molecules of pharmaceutical interest due to their use as anti-obesity drugs. In this study, forty strains isolated from soil and sediments were identified with the ability to produce inhibition of gastrointestinal lipase activity. The biomass extract of these strains showed at least 50% inhibition in the hydrolysis of tributyrin by recombinant human pancreatic lipase (rHPL) or rabbit gastric lipase (RGL) by in vitro assays. Based on gene sequencing, the isolates were identified mainly as Streptomycetes. Moreover, none of the identified strains has been reported to be lipase inhibitor producers, so they can be viewed as potential sources for obtaining new drugs. IC50 values of the three best inhibitor extracts showed that AC104-10 was the most promising strain for production of gastrointestinal lipase inhibitors. AC104-10 shows 99% homology (16S rRNA gene fragment) to Streptomyces cinereoruber strain NBRC 12756. An inhibitory study over trypsin activity revealed that AC104-10 extract, as well as THL, had no significant effect on the activity of this protease, showing its specificity for lipases. In addition, analyzes by MALDI-TOF mass spectrometry of the enzyme-inhibitor complex revealed that there is a covalent interaction of the AC104-10 inhibitor with the catalytic serine of the pancreatic lipase, and that the molecular weight of the inhibitor is approximately 686.19 Da.

Comparative features between recombinant lipases CALA-like from U. maydis and CALA from C. antarctica in thermal stability and selectivity.

OBJECTIVES: Ustilago maydis lipase A (UMLA) expressed in Pichia pastoris was compared with Candida antarctica lipase A (CALA) to study its biochemical properties such as thermostability and selectivity. RESULTS: UMLA had similar behavior to its homologue CALA regarding the effect of pH and temperature on enzymatic activity, substrate preference and selectivity. Both lipases were active on insoluble triglycerides as well as natural oils and hydrolyzed preferably esters with short and medium acyl and alkyl chains. Both enzymes were slightly selective for the (S)-glycidyl butyrate enantiomer and had a remarkable preference for the sn-2 position of triglycerides. The optimal activity was 40 and 50 °C for UMLA and CALA, respectively. However, temperature had a greater effect on the stability of UMLA compared to CALA, observing a half-life at 50 °C of 2.07 h and 12.83 h, respectively. CONCLUSIONS: UMLA shares some biochemical properties with CALA such as the sn-2 preference on triglyceride hydrolysis and transesterification. However, the high thermostability attributed to CALA was not observed in UMLA; this can be due to the lack of stabilization via AXXXA motifs in helices and fewer proline residues at the surface.