Project description:Cellular exposure to free fatty acids (FFA) is implicated in the pathogenesis of obesity-associated diseases. However, there are no scalable approaches to comprehensively assess the diverse FFAs circulating in human plasma. Furthermore, assessing how FFA-mediated processes interact with genetic risk for disease remains elusive. Here we report the design and implementation of FALCON (Fatty Acid Library for Comprehensive ONtologies), an unbiased, scalable and multimodal interrogation of 61 structurally diverse FFAs. We identified a subset of lipotoxic monounsaturated fatty acids associated with decreased membrane fluidity. Furthermore, we prioritized genes that reflect the combined effects of harmful FFA exposure and genetic risk for type 2 diabetes (T2D). We found that c-MAF inducing protein (CMIP) protects cells from FFA exposure by modulating Akt signaling. In sum, FALCON empowers the study of fundamental FFA biology and offers an integrative approach to identify much needed targets for diverse diseases associated with disordered FFA metabolism.

Project description:Free fatty acids (FFAs) are often stored in lipid droplet (LD) depots for eventual metabolic and/or synthetic use in many cell types, such a muscle, liver, and fat. In pancreatic islets, overt LD accumulation was detected in humans but not mice. LD buildup in islets was principally observed after roughly 11 years of age, increasing throughout adulthood under physiologic conditions, and also enriched in type 2 diabetes. To obtain insight into the role of LDs in human islet β cell function, the levels of a key LD scaffold protein, perilipin2 (PLIN2), were manipulated by lentiviral-mediated knock-down (KD) or over-expression (OE) in EndoCβH2-Cre cells, a human cell line with adult islet β-like properties. Glucose stimulated insulin secretion was blunted in PLIN2KD cells and improved in PLIN2OE cells. An unbiased transcriptomic analysis revealed that limiting LD formation induced effectors of endoplasmic reticulum (ER) stress that compromised the expression of critical β cell function and identity genes. These changes were essentially reversed by PLIN2OE or using the ER stress inhibitor, tauroursodeoxycholic acid. These results strongly suggest that LDs are essential for adult human islet β cell activity by preserving FFA homeostasis.

Project description:Background: High-energy-density biofuels are typically derived from the fatty acid biosynthesis pathway, thus establishing free fatty acids (FFAs) as important fuel precursors. FFA production using photosynthetic microorganisms like cyanobacteria allows for direct conversion of carbon dioxide into fuel precursors. Recent studies investigating cyanobacterial FFA production have demonstrated the potential of this process, yet FFA production was also shown to have negative physiological effects on the cyanobacterial host, ultimately limiting high yields of FFAs. Results: Cyanobacterial FFA production was shown to generate reactive oxygen species (ROS) and lead to increased cell membrane permeability. To identify genetic targets that may mitigate these toxic effects, RNA-seq analysis was used to investigate the host response of Synechococcus elongatus PCC 7942. Stress response, nitrogen metabolism, photosynthesis, and protein folding genes were up-regulated during FFA production while genes involved in carbon and hydrogen metabolisms were down-regulated. Select genes were targeted for mutagenesis to confirm their role in mitigating FFA toxicity. Gene knockout of two porins and the overexpression of ROS-degrading proteins and hypothetical proteins reduced the toxic effects of FFA production, allowing for improved growth, physiology, and FFA production. Comparative transcriptomics, analyzing gene expression changes associated with FFA production and other stress conditions, identified additional key genes involved in cyanobacterial stress response. Conclusions: A total of 15 gene targets were identified to reduce the toxic effects of FFA production. While single-gene targeted mutagenesis led to minor increases in FFA production, the combination of these targeted mutations may yield additional improvement, advancing the development of high-energy-density fuels derived from cyanobacteria.

Project description:<p>Lipid droplet (LD) growth mechanisms and the roles of LD-associated lipid transfer proteins remain poorly understood. Here, we show that the autophagy lipid transfer protein ATG2A has an anabolic role and promotes LD expansion by transferring diacylglycerol (DAG), and potentially triacylglycerol (TAG) and phosphatidic acid (PA), from the endoplasmic reticulum (ER) to LDs. In ATG2A deficiency, synthesized lipids are incorporated inefficiently into LDs and assemble new LDs. Additionally, diacylglycerol acyltransferase 2 (DGAT2), which synthesizes TAG and expands LD, fails to relocate to LDs. In vitro, DAG recruits DGAT2 to LDs. These findings support the idea that ATG2A-mediated DAG transfer recruits DGAT2 to LDs, promoting LD expansion. ATG2A alone promotes LD growth by transferring TAG and DAG, but its effectiveness in LD expansion is reduced when DGAT2 is inhibited. This synergistic action with DGAT2 prevents the buildup of non-membrane lipids within the ER and favors TAG synthesis on the LD surface.</p>

Project description:Yarrowia lipolytica has been considered one of the most promising platforms for the microbial production of fatty acids and derived products. The deletion of the faa1 gene coding for an acyl-CoA synthetase leads to the accumulation and secretion of free fatty acids (FFAs) into the extracellular space. The secretion of products is beneficial for the development of microbial cell factories to avoid intracellular inhibitory effects and reduce downstream processing costs. However, the mechanism behind the secretion of fatty acids is not well known. In this research, we compared the transcriptome of this mutant showing FFA secretion to a wildtype-like strain not showing this phenotype. Both toxicity and growth assays, as well as deletion and overexpression mutants of candidate genes were used to assess the effects of candidate genes on the export of FFAs. Although no clear transporter of fatty acids was identified, the analysis of the transcriptomic data revealed an overrepresentation of cell wall-related proteins. Based on this results, a literature search allowed to retrieve proteins related to the cell wall previously associated to lipid. Experiments performed on these candidates proved their involvement in resistance to FFAs toxicity, with one of them being a potential acyl-CoA export protein.

Project description:Non-alcoholic fatty liver disease (NAFLD) is a major public health burden and it covers a spectrum of diseases. NAFLD starts with the accumulation of lipid droplets (LDs) within hepatocytes (steatosis). Part of the challenge of studying the mechanistic processes involved in LD accumulation and their implications on the pathogenesis of human NAFLD is due to the available models. Investigating hepatic LDs in humans is challenging and relies on liver biopsies, meaning only cross-sectional data be obtained. On the other hand, LD patterns in in vitro models are poorly defined and rarely reported. Diacylgylcerol acyltransferase (DGAT)2 is one of two enzymes that carry out the final committed step in triacylglycerol (TAG) synthesis. It is unclear whether the enzymes are able to compensate for each other or whether they have distinct roles. It has been hypothesised that DGAT1 primarily utilises exogenous fatty acids and DGAT2 uses de novo-derived fatty acids. Given the important role of this enzyme in TAG synthesis and accumulation, the aims of this study are first to create a cellular model of intrahepatocellular TAG accumulation by manipulating nutritional substrates and to investigate intracellular metabolism in wildtype and DGAT2 knockout cells under these conditions. The experimental workflow for this study is as follows: Huh7 cells (either wild type or knockout) were grown in media containing 11 mM glucose and 2% human serum (HS) for seven days before additional sugars and fatty acids (FAs) were added for a further seven days. All treatments contained 11 mM glucose and 2% HS, either with 200 µM FAs (low fat low sugar; LFLS), 5.5 mM fructose + 200 µM FAs (low fat high sugar; LFHS) or 5.5 mM fructose + 800 µM FAs (high fat high sugar; HFHS). FA metabolism, lipid droplet characteristics and transcriptomic signatures were investigated.

Project description:The phospholipid and free fatty acid (FFA) composition of neuronal membranes plays a crucial role in learning and memory, but the mechanisms through which neuronal activity affects the brain's lipid landscape remain largely unexplored. Saturated FFAs, particularly myristic acid (C14:0), strongly increase during neuronal stimulation and memory acquisition, suggesting the involvement of phospholipase A1 (PLA1) activity in synaptic plasticity. Here, we show that genetic ablation of the DDHD2 isoform of PLA1 in mice markedly reduced saturated FFAs across the brain and memory performance in reward-based learning and spatial memory models prior to the development of neuromuscular deficits. DDHD2 was shown to bind to the key synaptic protein STXBP1. Using STXBP1/2 knockout neurosecretory cells and a haploinsufficient STXBP1+/- mouse model of STXBP1 encephalopathy that is also associated with intellectual disability and motor dysfunction, we show that STXBP1 controls the targeting of DDHD2 to the plasma membrane and the generation of saturated FFAs in the brain. Our findings suggest key roles for DDHD2 and STXBP1 in the lipid metabolism underlying synaptic plasticity, learning and memory.

Project description:Methionine adenosyltransferase (MAT) enzymes generate SAMe (S-adenosylmethionine), the main biological methyl donor. There are two MAT encoding genes in mammals (Mat1a and Mat2a), which show different activities and cellular distribution. Mat1a encodes the enzyme mainly expressed in normal liver. Mat1a ablation in mice results in the spontaneous development of non-alcoholic steatohepatitis (NASH). We observed that SAMe depletion in Mat1a KO mice had three main effects on hepatic lipid metabolism: 1) impaired TG (triglyceride) export via VLDL; 2) impaired mitochondrial FA (fatty acid) oxidation (as evidenced by membrane depolarization, downregulation of Phb1 (prohibitin 1, a mitochondrial chaperone protein) and Mcj/Dnajc15 (endogenous mitochondrial repressor of respiratory chain), and accumulation of long-chain acylcarnitines); and 3) increased FA uptake. The convergence of these three factors induced TG accumulation in LD (lipid droplets). LD expansion confronts hepatocytes with a high demand of PC (phosphatidylcholine) molecules to cover the LD surface since other phospholipids, such as PE (phosphatidylethanolamine), cannot stabilize LD and prevent coalescence. In Mat1a KO this situation is aggravated, since SAMe-dependent PC synthesis via PE methylation is decreased, the PC/PE ratio reduced and mitochondrial FA oxidation impaired. To put a brake to this drain of PC molecules to LD, FA are rerouted in Mat1a KO mice liver to other catabolic (endoplasmic reticulum and peroxisome oxidation) and biosynthetic (ceramides synthesis) pathways, causing oxidative stress, inflammation and fibrosis. SAMe treatment for two months in 8-9 month old Mat1a KO mice ameliorated mitochondrial dysfunction (reduces membrane depolarization, improves Phb1 and Mcj expression, and increases SAMe transport to mitochondria) improving FA oxidation efficiency (FA and acylcarnitine levels decrease), which results in a drastic reduction in TG accumulation. SAMe treatment in Mat1a KO mice resulted in more PC available for proper membrane function, improving liver lipid homeostasis, histology (H&E, Sudan red, Sirius red) and liver injury (ALT, AST).

Project description:Methionine adenosyltransferase (MAT) enzymes generate SAMe (S-adenosylmethionine), the main biological methyl donor. There are two MAT encoding genes in mammals (Mat1a and Mat2a), which show different activities and cellular distribution. Mat1a encodes the enzyme mainly expressed in normal liver. Mat1a ablation in mice results in the spontaneous development of non-alcoholic steatohepatitis (NASH). We observed that SAMe depletion in Mat1a KO mice had three main effects on hepatic lipid metabolism: 1) impaired TG (triglyceride) export via VLDL; 2) impaired mitochondrial FA (fatty acid) oxidation (as evidenced by membrane depolarization, downregulation of Phb1 (prohibitin 1, a mitochondrial chaperone protein) and Mcj/Dnajc15 (endogenous mitochondrial repressor of respiratory chain), and accumulation of long-chain acylcarnitines); and 3) increased FA uptake. The convergence of these three factors induced TG accumulation in LD (lipid droplets). LD expansion confronts hepatocytes with a high demand of PC (phosphatidylcholine) molecules to cover the LD surface since other phospholipids, such as PE (phosphatidylethanolamine), cannot stabilize LD and prevent coalescence. In Mat1a KO this situation is aggravated, since SAMe-dependent PC synthesis via PE methylation is decreased, the PC/PE ratio reduced and mitochondrial FA oxidation impaired. To put a brake to this drain of PC molecules to LD, FA are rerouted in Mat1a KO mice liver to other catabolic (endoplasmic reticulum and peroxisome oxidation) and biosynthetic (ceramides synthesis) pathways, causing oxidative stress, inflammation and fibrosis. SAMe treatment for two months in 8-9 month old Mat1a KO mice ameliorated mitochondrial dysfunction (reduces membrane depolarization, improves Phb1 and Mcj expression, and increases SAMe transport to mitochondria) improving FA oxidation efficiency (FA and acylcarnitine levels decrease), which results in a drastic reduction in TG accumulation. SAMe treatment in Mat1a KO mice resulted in more PC available for proper membrane function, improving liver lipid homeostasis, histology (H&E, Sudan red, Sirius red) and liver injury (ALT, AST).

Project description:Disturbances in lipid homeostasis can cause mitochondrial dysfunction and lipotoxicity requiring tight regulation of intracellular lipid metabolism and fatty acid (FA) flux. Perilipin 5 (PLIN5) decorates intracellular lipid droplets (LD) in oxidative tissues and controls triacylglycerol (TG) turnover via its interactions with Adipose triglyceride lipase (ATGL) and the ATGL co-activator Comparative gene identification-58 (CGI-58). Furthermore, PLIN5 anchors mitochondria to the LD membrane via its carboxyl-terminal domain. However, the role of this LD-mitochondria coupling (LDMC) in cellular FA flux and energy catabolism is less established. In this study, we investigated the impact of abolished LDMC on cellular FA flux, mitochondrial respiration and protein interaction. To do so, we established novel PLIN5 truncation variants lacking LDMC while maintaining normal interactions with lipolytic key players. Radiotracer studies with transgenic cell lines stably overexpressing either wild type or truncated PLIN5 revealed that LDMC has no significant impact on FA esterification upon lipid loading or TG catabolism during stimulated lipolysis. Moreover, we found that LDMC is not essential for FA shuttling into mitochondria, which was in line with only minor effects of disrupted LDMC on FA oxidation. In contrast, LDMC significantly improved the mitochondrial respiratory capacity and metabolic flexibility of lipid-challenged cardiomyocytes, which was corroborated by LDMC-dependent interactions of PLIN5 with mitochondrial proteins involved in mitochondrial respiration, dynamics and cristae organization. Taken together, this study suggests that PLIN5 preserves mitochondrial function by adjusting FA supply via the regulation of TG hydrolysis and that LDMC is a vital part of mitochondrial integrity.