Biotransformation of corn bran derived ferulic acid to vanillic acid using engineered Pseudomonas putida KT2440

Abstract

Ferulic acid is a fraction of the phenolics present in cereals such as rice and corn as a component of the bran. Substantial amounts of waste bran are generated by the grain processing industry and this can be valorized via extraction, purification and conversion of phenolics to value added chemical products. Alkaline alcohol based extracted and purified ferulic acid from corn bran was converted to vanillic acid using engineered Pseudomonas putida KT2440. The strain was engineered by rendering the vanAB gene nonfunctional and obtaining the mutant defective in vanillic acid metabolism. Biotransformation of ferulic acid using resting Pseudomonas putida KT2440 mutant cells resulted in more than 95?±?1.4% molar yield from standard ferulic acid; while the corn bran derived ferulic acid gave 87?±?0.38% molar yield. With fermentation time of less than 24?h the mutant becomes a promising candidate for the stable biosynthesis of vanillic acid at industrial scale.     

Cytolethal distending toxin (CLDT) production by enteropathogenic Eschrichia coli (EPEC)

Culture supernates of 16 strains of EPEC belonging to 6 different serogroups, when assayed on Chinese Hamster Ovary (CHO) cells up to 96-120 h, induced distinct morphological changes. The supernate activities were heat-labile, unrelated to heat-labile enterotoxin (LT), verotoxin (VT), or hemolysin, did not show necrosis in rabbit skin and caused no fluid secretion in the rabbit ileal loop assay (RILA). Simultaneous production of CLDT and heat-stable enterotoxin (ST) were detected in four EPEC strains.     

Metabolic engineering of Yarrowia lipolytica for the production of isoprene

Yarrowia lipolytica has recently emerged as a prominent microbial host for production of terpenoids. Its robust metabolism and growth in wide range of substrates offer several advantages at industrial scale. In the present study, we investigate the metabolic potential of Y. lipolytica to produce isoprene. Sustainable production of isoprene has been attempted through engineering several microbial hosts; however, the engineering studies performed so far are challenged with low titers. Engineering of Y. lipolytica, which have inherent high acetyl-CoA flux could fuel precursors into the biosynthesis of isoprene and thus is an approach that would offer sustainable production opportunities. The present work, therefore, explores this opportunity wherein a codon-optimized IspS gene (single copy) of Pueraria montana was integrated into the Y. lipolytica genome. With no detectable isoprene level during the growth or stationary phase of modified strain, attempts were made to overexpress enzymes from MVA pathway. GC-FID analyses of gas collected during stationary phase revealed that engineered strains were able to produce detectable isoprene only after overexpressing HMGR (or tHMGR). The significant role of HMGR (tHMGR) in diverting the pathway flux toward DMAPP is thus highlighted in our study. Nevertheless, the final recombinant strains overexpressing HMGR (tHMGR) along with Erg13 and IDI showed isoprene titers of ~500 μg/L and yields of ~80 μg/g. Further characterization of the recombinant strains revealed high lipid and squalene content compared to the unmodified strain. Overall, the preliminary results of our laboratory-scale studies represent Y. lipolytica as a promising host for fermentative production of isoprene.     

Identification of Glyceryl MonoRicinoleate (GMR) isomers using RP-HPLC and regio-specificity of lipases

Abstract

In the present study, we report a reverse-phase high-performance liquid chromatography (RP-HPLC) method for separation of the regio-isomers of Glyceryl MonoRicinoleate (GMR) identified using position specificity of lipases. The approaches explored to identify these regio-isomers include LC-mass spectrometry, UV spectroscopy, and selective hydrolysis with lipases. A distinct UV absorption spectrum and λ_max values for each isomer were noted, and mass spectral analysis further revealed their molecular weight. Lastly, the purified regio-isomers were subjected to hydrolysis with two distinctive regio-specific lipases to identified as sn-2 and sn-1(3) GMR. The current methodology of using analytic tool and enzyme specificity provides a useful platform for identifying regio-isomers for structured lipid synthesis.