Jean-Claude Bakala N'Goma scite author profile

Cutinases are extracellular enzymes that are able to degrade cutin, a polyester protecting plant leaves and many kinds of lipids. Although cutinases are mainly found in phytopathogenic fungi or bacteria, 7 genes related to the cutinase family have been predicted in the genome of Mycobacterium tuberculosis. These genes may encode proteins that are involved in the complex lipid metabolism of the bacterium. Here, we report on the biochemical characterization of two secreted proteins of M. tuberculosis, Rv1984c and Rv3452, belonging to the cutinase family. Although their amino acid sequence shows 50% identity with that of the well-characterized cutinase from Fusarium solani pisi, and a high level of homology has been found to exist between these two enzymes, they show distinct substrate specificities. Rv1984c preferentially hydrolyzes medium-chain carboxylic esters and monoacylglycerols, whereas Rv3452 behaves like a phospholipase A(2), and it is able to induce macrophage lysis. The tetrahydrolipstatin inhibitor, a specific lipase inhibitor, abolishes the activity of both enzymes. Site-directed mutagenesis was performed to identify the catalytic triad of Rv1984c. Structural models for Rv1984c and Rv3452 were built, based on the crystal structure of F. solani cutinase, with a view to investigating the contribution of specific residues to the substrate specificity. Our findings open new prospects for investigating the physiological roles of cutinase-like proteins in the lipid metabolism and virulence of M. tuberculosis.

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Understanding the lipid-digestion Processes in the GI Tract Before Designing lipid-based drug-delivery Systems

N'Goma

Amara

Dridi

et al. 2011

Therapeutic Delivery

134

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Many of the compounds present in lipid-based drug-delivery systems are esters, such as acylglycerols, phospholipids, polyethyleneglycol mono- and di-esters and polysorbate, which can be hydrolyzed by the various lipolytic enzymes present in the GI tract. Lipolysis of these compounds, along with dietary fats, affects the solubility, dispersion and bioavailibity of poorly water-soluble drugs. Pharmaceutical scientists have been taking a new interest in fat digestion in this context, and several studies presenting in vitro gastrointestinal lipolysis models have been published. In most models, it is generally assumed that pancreatic lipase is the main enzyme involved in the gastrointestinal lipolysis of lipid formulations. It was established, however, that gastric lipase, pancreatic carboxyl ester hydrolaze and pancreatic lipase-related protein 2 are the major players involved in the lipolysis of lipid excipients containing acylglycerols and polyethyleneglycol esters. These findings have shown that the lipolysis of lipid excipients may actually start in the stomach and involve several lipolytic enzymes. These findings should therefore be taken into account when testing in vitro the dispersion and bioavailability of poorly water-soluble drugs formulated with lipids. In this review, we present the latest data available about the lipolytic enzymes involved in gastrointestinal lipolysis and suggest tracks for designing physiologically relevant in vitro digestion models.

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Hepatic PEMT activity mediates liver health, weight gain, and insulin resistance

Wan¹,

Veen²,

N'Goma³

et al. 2019

FASEB j.

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Phosphatidylethanolamine (PE) N‐methyltransferase (PEMT) accounts for ∼30% of hepatic phosphatidylcholine (PC) biosynthesis. Pemt−/− mice fed a high‐fat diet are protected against diet‐induced obesity (DIO) and insulin resistance (IR) but develop nonalcoholic fatty liver disease (NAFLD) associated with a decreased POPE ratio. We investigated whether the lack of hepatic PEMT or the lack of PEMT in other tissues (where it is expressed at low levels) is responsible for or contributes to the protection against DIO and IR in Pemt−/− mice. Furthermore, we investigated whether decreasing PEMT expression with antisense oligonucleotides (ASOs) would result in metabolic benefits in both lean and obese mice without negatively impacting liver health. We both restored hepatic PEMT in Pemt−/− mice via adeno‐associated virus delivery and decreased hepatic PEMT with ASOs in wild‐type and ob/ob mice. Weight gain, insulin sensitivity, and indices of liver function were determined. We report that the protection against DIO and IR and the development of NAFLD is dependent on hepatic PEMT activity. NAFLD, associated with a significant decrease in the hepatic PC:PE ratio, was exacerbated by PEMT deficiency in obese mice, suggesting that phospholipid insufficiency promotes NAFLD progression during obesity or overnutrition. Hepatic PEMT is critical for maintaining phospholipid balance, which is crucial for a healthy liver.—Wan, S., van der Veen, J. N., Bakala N'Goma, J.‐C., Nelson, R. C., Vance, D. E., Jacobs, R. L. Hepatic PEMT activity mediates liver health, weight gain, and insulin resistance. FASEB J. 33, 10986–10995 (2019). http://www.fasebj.org

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IR spectroscopy analysis of pancreatic lipase-related protein 2 interaction with phospholipids: 1. Discriminative recognition of mixed micelles versus liposomes

Mateos-Diaz

N'Goma

Byrne

et al. 2018

Chemistry and Physics of Lipids

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