Examination of the Brassica napus β-Keto-acyl carrier protein reductase promoter for regulatory cis-acting elements

Young, Clare Elisabeth

January 2002

Major interest has focused on the identification of regulatory factors involved in lipid biosynthesis. This study examined the B.napus β-Keto-ACP reductase 5' sequence for potential regulatory cis-acting elements. The 5' sequence of the most highly expressed Brassica napus β-Keto-ACP reductase isoform was fused to the reporter gene β-glucuronidase (GUS) and its expression pattern examined within transgenic Arabidopsis. The construct was shown to act as a functional promoter and direct transcription within embryos, cotyledons and roots. There was no apparent staining within the true leaves, but staining was visible within the cotyledons. Overlapping fragments of the promoter were analysed in gel mobility shift assays and all six showed the formation of protein-DNA complexes. Competition analysis suggested that the same trans-acting factor binds to a number of regions along the promoter. The protein-DNA complex appeared to be competed away by the Arabidopsis enoyl-ACP reductase (EnR) promoter sequence, but not the lipid transfer protein (LTP) promoter. A common 9bp cis-element (CGCANTAAA) was identified in four of the six promoter fragments. Deletion analysis of the β-Keto-ACP reductase promoter intransient expression experiments into B.napus tissue, suggested the promoter could still direct transcription upon deletion to 132bp within embryos. The GUS expression appeared to show more than one decrease in expression upon subsequent deletions of the promoter within embryos, suggesting that more than one cis-element may be involved in the control of transcription. At least one of these suspected decreases con elated with the deletion of one of the 9bp boxes identified. Differences were observed for expression of the constructs within leaves and embryos suggesting that different elements may be involved in transcriptional control within these tissues. The identification of a potential cis-acting element within this study could be used to isolate a potential regulatory trans-acting factor that binds to the B.napus β-Keto-ACP reductase promoter.

572

Plant lipid biosynthesis

Identification of Plant Transcription Factors that Play a Role in Triacylglycerol Biosynthesis

Dabbs, Parker

01 May 2015

This work identifies transcription factors (TF) controlling triacylglycerol (TAG) synthesis and accumulation in plant tissues. TAG plays vital role in plants and are used by humans. Most plants accumulate oil in the seed, but some species accumulate oil in other tissues. The Wrinkled1 (WRI1) TF has been shown to regulate oil accumulation in multiple species and tissues. Here, four WRI homologues in avocado were identified, their phylogeny was examined and three of them were cloned into expression vectors for further characterization. However, WRI1 likely does not act alone in regulation of TAG accumulation in plants. Additional candidate TFs were identified by using transcriptome data from a variety of species, and cloned into expression vectors. Future studies will be able to use this information to better understand regulation of TAG accumulation, which will allow increased oil accumulation in plants for various human uses.

avocado

triacylglycerol

lipid biosynthesis

mesocarp

WRINKLED

Biology

The effect of 2E,4E-decadienal on lipid-related gene expression in Phaeodactylum tricornutum

Beck, Emily Christine

10 December 2013

Microalgae have been proposed as a potential feedstock for biofuel production, and as a result, interest in the biology of these organisms has intensified. These organisms also synthesize lipids that are vital to human health and nutrition. Stress has been shown to have an effect on lipid composition and gene expression in microalgae, but many studies have focused on the effects of abiotic stressors. The purpose of this study was to investigate the effect of biotic stress on lipid-related gene expression in Phaeodactylum tricornutum, a model species of microalgae. The source of biotic stress used in this study was 2E,4E/Z-decadienal, a diatom-derived oxylipin that has been shown to function as a stress signal among diatoms. Real-time RT-qPCR analysis revealed that expression of a patatin-like phospholipase was significantly decreased in decadienal-treated cultures as compared to a solvent control. The expression of a delta-9 desaturase gene believed to be responsible for production of 16:1 fatty acids was increased by a factor of 12. FabI, a gene involved in fatty acid biosynthesis, and PtD5a, which codes for an ER-localized desaturase, were both down-regulated in cells exposed to decadienal. However, changes in expression were only shown to be significant for the patatin-like phospholipase gene. Increased expression of the delta-9 desaturase gene may be a protective mechanism against infection from pathogens, since 16:1 fatty acids have been shown to have antibacterial properties. Regulation of membrane desaturation may also serve to stabilize photosynthetic membranes during times of stress. The down-regulation of the phospholipase gene was surprising, since the release of fatty acids from membrane lipids for oxylipin production is a common response to stress. It is recommended that this experiment be improved upon and expanded in order to determine whether the results obtained are reproducible and how these changes in gene expression correlate with physiological effects. / text

Phaeodactylum

Tricornutum

Desaturase

Lipid biosynthesis

Decadienal

Microalgae

Cytosolic Lysophosphatidic Acid Acyltransferase : Implications in Lipid Biosynthesis in Yeast, Plants and Human

Ghosh, Ananda Kumar

07 1900

Cytosolic LPA acyltransferase in yeast An isooctane tolerant strain of S. cerevisiae KK-12 was reported to have increased saturated fatty acid content (Miura et. al., 2000). Amongst the various genes upregulated on isooctane treatment, ICT1 (Increased Copper Tolerance 1) was found to have maximal expression (Miura et. al., 2000; Matsui et. al., 2006). This gene in S. cerevisiae is encoded by YLR099C annotated as Ict1p. However, the physiological significance of Ict1p was not understood. Here we showed that an increase in the synthesis of phosphatidic acid (PA) is responsible for enhanced phospholipid synthesis, which confers organic solvent tolerance to S. cerevisiae. This increase in the PA formation is due to the upregulation of Ict1p, a soluble oleoyl-CoA dependent lysophosphatidic acid (LPA) specific acyltransferase. Analysis of Δict1 strain by in vivo [32P]orthophosphate labeling showed a drastic reduction in PA, suggesting the role of Ict1p in phospholipid biosynthesis. Overexpression of Ict1p in S. cerevisiae showed an increase in PA and the overall phospholipid content on organic solvent exposure. The purified recombinant enzyme was found to specifically acylate LPA. Specific activity of Ict1p was found to be higher for oleoyl-CoA as compared to palmitoyl-CoA and stearoyl-CoA. The study therefore, provides a mechanistic basis of solvent tolerance in S. cerevisiae.It is well known that phosphatidic acid (PA) is formed by the acylation of LPA by LPA acyltransferase. However, all the LPA acyltransferases characterized till date have distinct transmembrane domains and form a member of membrane bound biosynthetic machinery of phospholipid biosynthesis. They have a conserved signature motif, H(X)4D. Phosphatidic acid is an important precursor for the synthesis of glycerophospholipids and triacylglycerols. PA enters the biosynthetic pathway of phospholipids through a CTP-dependent activation catalyzed by CDPdiacylglycerol synthase. This enzyme forms CDP-diacylglycerol, which serves as a direct precursor for phosphatidylinositol, phosphatidylglycerol and cardiolipin. PA can also be dephosphorylated by phosphatidic acid phosphatase yielding diacylglycerol, which serves as a precursor for the formation of PE and PC through the CDP-ethanolamine and CDP-choline pathway or for the triacylglycerol synthesis through a dephosphorylation step followed by an acylation establishing it as a supreme molecule for the acylglycerol biosynthesis. Since, PA is an important intermediate and that there are mechanisms to synthesize PA, other than the conventional membrane bound pathways, we wanted to understand whether such a mechanism of PA biosynthesis is conserved across the plant and animal kingdom. Therefore, we resorted to analyze Ict1p like proteins in Arabidopsis and human whose complete genome sequence is available. Cytosolic LPA acyltransferase in Arabidopsis Homology search with ICT1 in Arabidopsis thaliana genome, led to the identification of At4g24160 as a close relative. In order to gain an insight into the significance of such proteins in plants we performed a genome wide survey of At4g24160 like proteins in Arabidopsis. We identified that A. thaliana genome encodes twenty four At4g24160 like proteins, most of which belong to the α/β- hydrolase family of proteins and possess a distinct lipase motif (GXS/NXG). Interestingly, amongst these twenty four, only At4g24160 has a conserved HX4D motif. Domain analysis of these proteins suggests a wide functional diversification during evolution. Gene expression studies revealed their importance during various abiotic stress. Bacterial expression of At4g24160 followed by its purification using Ni2+-NTA column chromatography and characterization revealed it to be a LPA acyltransferase. Expression analysis showed that it is highly expressed in the pollen grains followed by the root cap. In addition, the gene was found to be upregulated under salt stress conditions. Direct correlation between salt stress and phospholipid biosynthesis is well known in the literature. We envisage that At4g24160 might be one of the gene products involved in membrane repair when exposed to such a stressCytosolic LPA acyltransferase in human Homology search with Ict1p revealed another interesting candidate protein in Homo sapiens known as Comparative Gene Identification–58 (cgi-58). Mutations in CGI- 58 are known to be the causative reason for a rare autosomal recessive genetic disorder known as Chanarin-Dorfman syndrome characterized by the excessive TG accumulation and defective membrane phospholipid regulation in several tissues. It is known to be a coactivator of adipose triglyceride lipase (ATGL), promoting lipolysis of TG (Lass et. al., 2006). However, the exact biochemical role remains unknown. To understand the biochemical function of cgi-58, the gene was overexpressed in E. coli and the purified, recombinant protein was found to specifically acylate lysophosphatidic acid in an acyl-CoA dependent manner. Overexpression of CGI-58 in Δict1 rescued the metabolic defect of the strain. Heterologous overexpression of CGI-58 in S. cerevisiae followed by metabolic labeling with [32P]orthophosphate showed an increased biosynthesis of membrane phospholipids. Analysis of neutral lipid biosynthesis by [14C]acetate labeling showed an increase in DG and free fatty acids. However, marked decrease in the TG biosynthesis was seen. Decrease in TG was confirmed by ESI-MS. In addition, physiological significance of cgi-58 in the mice white adipose tissue is reported in this thesis. We found soluble lysophosphatidic acid acyltransferase activity in the mice white adipose tissue. Immunoblot with anti-Ict1p antibodies followed by MALDI-TOF analysis of the cross reacting protein in lipid droplets revealed its identity as cgi-58. These observations suggest the existence of an alternate cytosolic phosphatidic acid biosynthetic pathway in the white adipose tissue. Collectively, our observations suggest a possible involvement of cgi-58 in the phospholipid biosynthesis of adipocytes and its probable role in maintaining the TG homeostasis. In conclusion, the study reveals the significance of cytosolic lipid metabolic enzymes having conserved biochemical function, in maintaining homeostasis in living organisms across phylogeny.

Lipid Biosynthesis

Cytosolic LPA Acyltransferase

Arabidopsis

Human Cytosolic LPA Acyltansferse

Yeast - Lipid Biosynthesis

Plants - Lipid Biosynthesis

Human Lipid Biosynthesis

Lysophosphatidic Acid Acyltransferase

Biochemistry

Characterization of Acyltransferases to Understand Lipid Biosynthesis in Nonseed Tissues

Rahman, Md Mahbubar, Campbell, Andrew, Shockey, J., Kilaru, Aruna

08 April 2015

Triacylglycerol (TAG) is the main storage lipid in plants, found both in seed and non-seed tissues (e.g. root, leaves, mesocarp etc.). Plants use TAGs as a carbon and energy source during seed germination while humans use plant lipids for biofuel production, industrial feedstocks and nutrition. It is expected that by 2030 the demand for biodiesel will be doubled. To meet this demand it is important to understand the regulation of rate limiting reactions involved in TAG accumulation in nonseed tissues because of their higher biomass relative to the seed tissues. In this study, avocado (Persea americana) is used as a model organism because it is a basal angiosperm and can store up to 70% oil content in the form of TAG in its mesocarp, a nonseed tissue. Typically, the last acylation of diacylglycerol (DAG) to form TAG in seed tissues is catalyzed by diacylglycerol acyltransferases (DGAT) and/or phospholipid:diacylglycerol acyltransferases (PDAT). Based on the transcriptome of avocado, it is hypothesized that both DGAT and PDAT are responsible for catalyzing the terminal step of TAG biosynthesis in mesocarp of avocado. Fulllength coding sequences for DGAT1 and PDAT1 were identified based on the avocado transcriptome data and expressed in TAG-deficient yeast strain (SCY-1998) for complementation. Total lipid extracts from complemented yeast lines will be analyzed for presence of TAG. Furthermore, the enzyme activity and substrate specificity for PaDGAT1 and PaPDAT1 will be determined from microsomal preparations of avocado and eukaryotic expression systems containing the avocado transgenes. This study is expected to identify the enzymes responsible for the terminal acylation step in TAG synthesis in avocado, thereby contributing to the basic understanding of TAG accumulation in nonseed tissues.

acyltransferases

lipid biosynthesis

nonseed tissues

Biological Sciences

Biology

Characterization of Acyltransferases to Understand Lipid Biosynthesis in Nonseed Tissues

Rahman, Md Mahbubar, Campbell, A., Shockey, Jay, Kilaru, Aruna

01 January 2015

No description available.

acyltransferases

lipid biosynthesis

nonseed tissues

Biological Sciences

Biology

Diversité et biosynthèse des lipides chez les palmiers / Lipid diversity and biosynthesis in palms

Guérin, Chloé

10 December 2015

Le palmier à huile, Elaeis guineensis (Eg), produit deux huiles d’une importance économique majeure, l’huile de palme et l’huile de palmiste, extraites respectivement du mésocarpe et de l’albumen. Alors que l’acide laurique (12:0) prédomine dans l’huile de l’albumen, les acides gras (AG) majoritaires de l’huile du mésocarpe sont les acides palmitique (16:0) et oléique (18:1). Par ailleurs, la teneur en huile à maturité est très différente entre ces tissus. Dans la première partie de ce travail, leur transcriptome a été comparé afin d’identifier les mécanismes qui gouvernent leurs différences de composition lipidique. Les contributions des voies plastidiale et cytosolique de la glycolyse diffèrent considérablement entre le mésocarpe et l’albumen. L’accumulation de 12:0 repose sur la surexpression d’un paralogue codant pour une isoforme spécialisée d’acyl-ACP thioestérase (FatB), et le recrutement concerté d’isoformes spécifiques des enzymes impliquées dans l’assemblage des triacylglycérols. Trois paralogues du facteur de transcription (FT) WRI1 ont été identifiés, parmi lesquels EgWRI1-1 et EgWRI1-2 sont transcrits massivement dans respectivement le mésocarpe et l’albumen. Les changements de composition lipidique de feuilles de tabac agro-infiltrées avec plusieurs combinaisons des paralogues de FatB et de WRI1 identifiés valident leur fonction.Le palmier à huile Américain, E. oleifera (Eo), accumule aussi de l’huile dans le mésocarpe, mais en quantité moindre que chez Eg. La composition en AG de l’huile est également très différente entre Eg et Eo, notamment la teneur en 16:0 qui est deux fois moins élevée chez Eo que chez Eg. Dans la deuxième partie de ce travail, des analyses de coexpression génique, des mesures de l’expression allélique spécifique et des analyses multivariées conjointes de données transcriptomiques et lipidiques, ont été conduites dans une population d’hybrides rétrocroisés entre Eg et Eo. Le réseau de coexpression génique construit révèle une coordination transcriptionnelle étroite entre la voie plastidiale de la glycolyse, le métabolisme de l’amidon, des voies de recapture du carbone, la perception des sucres et la synthèse des AG. La biogénèse des plastes et le transport auxinique sont les deux autres processus les plus étroitement reliés à la synthèse des AG. En plus de WRI1, deux nouveaux FT, appelés NF-YB-1 et ZFP-1, ont été trouvés au cœur du module de synthèse des AG. Les analyses de coexpression identifient également de nouveaux gènes potentiellement impliqués dans la synthèse des lipides. Enfin, la teneur en 16:0 de l’huile semble principalement contrôlée par le niveau de transcription du gène codant pour la beta-kétoacyl-acyl carrier protein (ACP) synthase, qui catalyse l’élongation du 16:0-ACP en 18:0-ACP dans le plaste.Enfin, la troisième partie de ce travail vise à explorer les relations entre la composition lipidique des graines, d’une part, et des paramètres phylogénétiques, biogéographiques et écologiques, d’autre part, au sein de la famille des Arécacées. La teneur en lipides et la composition en AG ont été caractérisées chez 177 espèces de palmiers, révélant une diversité considérable à l’intérieur de cette famille. Les espèces dont les graines accumulent le plus d’huile appartiennent à la tribu Cocoseae. En revanche, des espèces qui accumulent du 12:0 existent dans toutes les tribus. Les analyses multivariées basées sur la composition en AG regroupent de manière satisfaisante les espèces appartenant à une même tribu. Cependant, ces classifications présentent une topologie qui concorde peu avec la phylogénie. Aucune association claire n’a été identifiée entre les paramètres biogéographiques et écologiques et la composition en AG. Néanmoins, une corrélation significative entre la teneur en AG insaturés et l’altitude maximale de l’aire d’origine a été trouvée dans certaines tribus. / Oil palm, Elaeis guineensis (Eg) produces two oils of major economic importance, commonly referred to as palm oil and palm kernel oil, extracted from the mesocarp and the endosperm, respectively. While lauric acid (12:0) predominates in endosperm oil, the major fatty acids (FA) of mesocarp oil are palmitic (16:0) and oleic (18:1) acids. In addition, the two tissues display high variation for oil content at maturity. In the first part of this PhD work, tissue transcriptome and lipid composition were compared during development to gain insight into the mechanisms that govern such differences in oil content and FA composition. The contribution of the cytosolic and plastidial glycolytic routes differs markedly between the mesocarp and seed tissues. Accumulation of lauric acid (12:0) relies on the dramatic upregulation of a specialized acyl-ACP thioesterase paralog and the concerted recruitment of specific isoforms of triacylglycerol assembly enzymes. Three paralogs of the WRI1 transcription factor were identified, of which EgWRI1-1 and EgWRI1-2 were massively transcribed during oil deposition in the mesocarp and the endosperm, respectively. Changes in triacylglycerol content and FA composition of Nicotiana benthamiana leaves infiltrated with various combinations of WRI1 and FatB paralogs from oil palm validate functions inferred from transcriptome analysis.The American oil palm, E. oleifera (Eo), also stores oil in the mesocarp, but in lower amount than in Eg. Mesocarp oil fatty acid (FA) composition also differs considerably between Eg and Eo, especially the 16:0 content which is two-times lower in Eo than in Eg. In the second part of this work, the mechanisms that govern oil synthesis and FA composition in the two species were investigated. Gene-to-gene coexpression analysis, quantification of allele-specific expression, and joint multivariate analysis of transcriptomic and lipid data, were carried out in an interspecific backcross population between Eg and Eo. The gene coexpression network built reveals the tight transcriptional coordination of the plastidial glycolytic route, starch metabolism, carbon recapture pathways and sugar sensing with fatty acid synthesis (FAS). Plastid biogenesis and auxin transport are the two other biological processes the most tightly connected to FAS in the network. In addition to WRI1, two novel TFs, termed NF-YB-1 and ZFP-1, were found at the core of the FAS module. Coexpression analysis also identifies novel genes likely involved in lipid biosynthesis pathways. Finally, the level of 16:0 in oil seems primarily controlled by the level of transcription of the gene coding for beta-ketoacyl-acyl carrier protein (ACP) synthase II, which catalyzes the elongation of 16:0-ACP to 18:0-ACP in the plastid.Finally, the third part of this work aimed to explore relationships between seed lipid composition on one hand, and phylogenetic, biogeographic and ecological parameters on the other, in the family Arecaceae. Oil content and FA composition were characterized for 177 species of the palm family, revealing a considerable intra-family diversity for seed lipid composition. Species whose seeds store the highest amounts of oil belong to the tribe Cocoseae. By contrast, species that accumulate 12:0 in their seeds occur in all tribes. Multivariate analyses based on FA composition satisfactorily group species belonging to the same tribe. However, only a few of the groups display topologies that are congruent with phylogenetic data. No clear associations were identified between biogeographic and ecological traits and FA composition. However, a tribe-dependent significant correlation was observed between unsaturated FA content and maximum elevation in native area.

Palmiers

Acide gras

Biosynthèse des lipides

Fruit

Graine

Transcriptome

Palms

Fatty acid

Lipid biosynthesis

Fruit

Seed

Transcriptome

Glucose and Altered Ceramide Biosynthesis Impact the Transcriptome and the Lipidome of Caenorhabditis elegans

Ladage, Mary Lee

08 1900

The worldwide rise of diabetes and obesity has spurred research investigating the molecular mechanisms that mediate the deleterious effects associated with these diseases. Individuals with diabetes and/or obesity are at increased risk from a variety of health consequences, including heart attack, stroke and peripheral vascular disease; all of these complications have oxygen deprivation as the central component of their pathology. The nematode Caenorhabditis elegans has been established as a model system for understanding the genetic and molecular regulation of oxygen deprivation response, and in recent years methods have been developed to study the effects of excess glucose and altered lipid homeostasis. Using C. elegans, I investigated transcriptomic profiles of wild-type and hyl-2(tm2031) ( a ceramide biosynthesis mutant) animals fed a standard or a glucose supplemented diet. I then completed a pilot RNAi screen of differentially regulated genes and found that genes involved in the endobiotic detoxification pathway (ugt-63 and cyp-25A1) modulate anoxia response. I then used a lipidomic approach to determine whether glucose feeding or mutations in the ceramide biosynthesis pathway or the insulin-like signaling pathway impact lipid profiles. I found that gluocose alters the lipid profile of daf-2(e1370) (an insulin-like receptor mutant) animals. These studies indicate that a transcriptomic approach can be used to discover novel pathways involved in oxygen deprivation response and further validate C. elegans as a model for understanding diabetes and obesity.

Lipid Biosynthesis

Glucose Toxicity

Xenobiotic and Endobiotic Detoxification

Biology, Genetics

Biology, Bioinformatics

Identification of Acyltransferases Associated with Triacylglycerol Biosynthesis in Avocado

Sung, Ha-Jung

01 December 2013

A variety of plants synthesize and store oil in the form of triacylglycerols (TAG) in their seed and nonseed tissues that are commonly used as vegetable oils. In seed tissues, an acyl CoA-dependent diacylglycerol (DAG) acyltransferase (DGAT) and/or -independent phospholipid:DGAT (PDAT) catalyze the conversion of DAG to TAG. In avocado fruit, which stores up to 70% oil by dry weight in mesocarp, it is hypothesized that both DGAT and PDAT are likely involved in TAG synthesis. To investigate, TAG content and composition and transcript levels for the acyltransferases in avocado fruit were quantified by gas chromatography and real-time polymerase chain reaction, respectively. Temporal, tissue-specific and phenotypic comparisons revealed that while DGAT1 gene expression was specifically associated with TAG accumulation, PDAT also correlated with higher levels of polyunsaturated fatty acid; DGAT2 was barely detectable. These studies suggest that TAG biosynthesis in nonseed tissues of avocado involves acyl CoA-dependent and -independent reactions.

avocado

diacylglycerol acyltransferase

lipid biosynthesis

mesocarp

triacylglycerol

Biochemistry

Fruit Science

Plant Biology

<b>INVESTIGATING THE INFLUENCE OF EFFLUX PUMP INHIBITORS ON BIOFILM FORMATION, ANTIBIOTIC RESISTANCE AND LIPID BIOSYNTHESIS IN MYCOBACTERIUM ABSCESSUS</b>

Toe Ko Ko Htay (18423819)

23 April 2024

<p dir="ltr">Mycobacterium abscessus (Mab) is a type of mycobacterium that is known for its remarkable resistance to a variety of antibiotics. This pathogen poses a significant risk for individuals with weakened immune systems as it can cause skin and soft tissue infections, pulmonary disease and disseminated infections. Mab's ability to expel antibiotics through efflux pumps and form strong biofilms makes it even more challenging to treat infections. Lipids form a major part of the extracellular matrix of Mab biofilms. Efflux pumps have been shown to export lipids to the cell surface. Despite ongoing research into Mab's antibiotic tolerance, there is still much to learn about the impact of efflux pump inhibitors (EPIs) on antibiotic resistance and lipid biosynthesis during biofilm development in Mab. In this study, we investigated the impact of the EPIs; CCCP (carbonyl cyanide m-chlorophenyl hydrazone), piperine (PIP), reserpine (RES), berberine (BER), and verapamil (VER) on efflux activity, biofilm formation, antibiotic resistance, and lipid biosynthesis in Mab during planktonic and biofilm growth conditions. We found that Mab cells had a higher tolerance to EPIs in biofilm-stimulating medium and that the presence of EPIs led to a decrease in minimum inhibitory concentrations of frontline antibiotics, reduced efflux activity within Mab cells, and significantly inhibited biofilm formation. We examined the effects of EPIs that inhibited biofilm formation on lipid metabolism in Mab using radiolabeling with 14C?palmitic acid and 14C-acetic acid which are precursors of lipid biosynthesis. We observed that the EPI berberine inhibited the incorporation of 14C-palmitic acid into glycopeptidolipids in the surface lipids of planktonic cells and increased cellular glycopeptidolipid (GPL) in biofilm cells. Verapamil-treated cells showed a 55 % increase in cellular trehalose monomycolate (TMM) compared to controls. Piperine-treated cells exhibited a 50 % increase in cardiolipin. The incorporation of 14C-acetate into biofilm cells showed that piperine-treated biofilm cells showed a 146 % increase in surface glycopeptidolipids. Overall, our study enhances our understanding of lipid biosynthesis in Mab, the effects of EPIs on Mab biofilms, efflux mechanisms, and antibiotic resistance and offers insights for combating Mab-related infections.</p>

Bacteriology

MYCOBACTERIUM ABSCESSUS

BIOFILM FORMATION

ANTIBIOTIC RESISTANCE

LIPID BIOSYNTHESIS

CCCP

PIPERINE

RESERPINE

BERBERINE

VERAPAMIL