FATP1 mediates fatty acid-induced activation of AMPK in 3T3-L1 adipocytes

Fatty acid transport proteins are integral membrane acyl-CoA synthetases implicated in adipocyte fatty acid influx and esterification. FATP-dependent production of AMP was evaluated using FATP4 proteoliposomes, and fatty acid-dependent activation of AMP-activated protein kinase (AMPK) was assessed in 3T3-L1 adipocytes. Insulin-stimulated fatty acid influx (palmitate or arachidonate) into cultured adipocytes resulted in an increase in the phosphorylation of AMPK and its downstream target acetyl-CoA carboxylase. Consistent with the activation of AMPK, palmitate uptake into 3T3-L1 adipocytes resulted in an increase in intracellular [AMP]/[ATP]. The fatty acid-induced increase in AMPK activation was attenuated in a cell line expressing shRNA targeting FATP1. Taken together, these results demonstrate that, in adipocytes, insulin-stimulated fatty acid influx mediated by FATP1 regulates AMPK and provides a potential regulatory mechanism for balancing de novo production of fatty acids from glucose metabolism with influx of preformed fatty acids via phosphorylation of acetyl-CoA carboxylase.     

Functional Analysis of Long-chain Acyl-CoA Synthetase 1 in 3T3-L1 Adipocytes

ACSL1 (acyl-CoA synthetase 1), the major acyl-CoA synthetase of adipocytes, has been proposed to function in adipocytes as mediating free fatty acid influx, esterification, and storage as triglyceride. To test this hypothesis, ACSL1 was stably silenced (knockdown (kd)) in 3T3-L1 cells, differentiated into adipocytes, and evaluated for changes in lipid metabolism. Surprisingly, ACSL1-silenced adipocytes exhibited no significant changes in basal or insulin-stimulated long-chain fatty acid uptake, lipid droplet size, or tri-, di-, or monoacylglycerol levels when compared with a control adipocyte line. However, ACSL1 kd adipocytes displayed a 7-fold increase in basal and a ∼15% increase in forskolin-stimulated fatty acid efflux without any change in glycerol release, indicating a role for the protein in fatty acid reesterification following lipolysis. Consistent with this proposition, ACSL1 kd cells exhibited a decrease in activation and phosphorylation of AMP-activated protein kinase and its primary substrate acetyl-CoA carboxylase. Moreover, ACSL1 kd adipocytes displayed an increase in phosphorylated protein kinase Cθ and phosphorylated JNK, attenuated insulin signaling, and a decrease in insulin-stimulated glucose uptake. These findings identify a primary role of ACSL1 in adipocytes not in control of lipid influx, as previously considered, but in lipid efflux and fatty acid-induced insulin resistance.Fatty acid influx and efflux mechanisms and their regulation affect lipid storage and metabolism in adipocytes. Imbalances in adipose lipid metabolism have been shown to significantly contribute to the development of obesity and associated metabolic diseases, such as type 2 diabetes, hypertension, and cardiovascular disease (1–3). Although the molecular mechanisms involved in fatty acid efflux are still undefined, several proteins implicated in fatty acid influx have been proposed: CD36 (fatty acid translocase), acyl-CoA synthetases (fatty acid transport protein (FATP)² and acyl-CoA synthetase (ACSL) family members), plasma membrane fatty acid-binding protein, and caveolin-1 (4–9).FATPs and long-chain ACSLs are membrane-bound enzymes that catalyze the ATP-dependent esterification of long chain (ACSL) and very long-chain (FATP) fatty acids to their acyl-CoA derivatives (10, 11). Both types of CoA synthetases have common ATP/AMP binding and fatty acid binding signature motifs. In mammals, six different isoforms of FATP (FATP1–FATP6) and five different isoforms of ACSL (ACSL1, -3, -4, -5, and -6) have been identified with tissue-specific expression patterns (12). White adipose tissue predominantly express FATP1, FATP4, and ACSL1, whereas brown adipose tissue in addition expresses ACSL5. Our recent results have confirmed a major role of FATP1 and CD36, but not FATP4, in insulin-stimulated LCFA uptake in 3T3-L1 adipocytes (6).ACSL1 is a ∼78-kDa intrinsic membrane protein localized to multiple sites in a variety of different cells. In liver, ACSL1 has been shown to be localized to the endoplasmic reticulum and mitochondria-associated membranes, whereas in adipocytes, ACSL1 was also found associated with the plasma membrane, the lipid droplet surface (13), and glucose transporter 4-containing vesicles (14, 15). Recent studies have postulated a cooperative role of FATP1 and ACSL1 in the movement of LCFAs across the plasma membrane via a process termed vectoral acylation (16), in which the CoA- and ATP-dependent esterification of internalized fatty acid provides the thermodynamic force necessary for net lipid influx. Evidence supporting this hypothesis came from a functional cloning strategy that identified mouse ACSL1 along with FATP1 as proteins involved in LCFA transport (17). In contrast to the role of ACSL1 in LCFA uptake and triglyceride synthesis in adipocytes, overexpression of ACSL1 in rat primary hepatocytes channeled fatty acids toward diacylglycerol and phospholipids synthesis and increased reacylation of hydrolyzed fatty acids into triglyceride (18).Since lipid flux is defined by the location and activity of its regulatory enzymes and proteins, overexpression strategies can result in changes in metabolism potentially distinct from the endogenous function. To that end, our laboratory has recently undertaken a gene silencing approach to the evaluation of proteins implicated in adipocyte fatty acid influx and efflux, and prior studies have focused on FATP1, FATP4, and CD36 (6). In this report, we evaluated the adipose-specific role(s) of ACSL1 using stable gene-silencing strategies in 3T3-L1 adipocytes using lentiviral delivery of shRNA. We report herein that, contrary to previous reports, in 3T3-L1 adipocytes, ACSL1 does not facilitate the basal or insulin-stimulated component of LCFA uptake. ACSL1 is, however, involved in the reesterification of hydrolyzed fatty acids released during basal and forskolin-stimulated lipolysis, thereby regulating their availability and efflux from the cell. Additionally, fatty acid reesterification by ACSL1 during lipolysis plays a major role in regulating the AMP-activated protein kinase (AMPK) as well as the PKCθ and JNK pathways leading to insulin resistance. Such findings bring to light a new interpretation of the role of ACSL1 and other acyl-CoA synthetases in the control of intermediary metabolism and lipid-mediated signal transduction.     

A novel role for fatty acid transport protein 1 in the regulation of tricarboxylic acid cycle and mitochondrial function in 3T3-L1 adipocytes

Fatty acid transport proteins (FATPs) are integral membrane acyl-CoA synthetases implicated in adipocyte fatty acid influx and esterification. Whereas some FATP1 translocates to the plasma membrane in response to insulin, the majority of FATP1 remains within intracellular structures and bioinformatic and immunofluorescence analysis of FATP1 suggests the protein primarily resides in the mitochondrion. To evaluate potential roles for FATP1 in mitochondrial metabolism, we used a proteomic approach following immunoprecipitation of endogenous FATP1 from 3T3-L1 adipocytes and identified mitochondrial 2-oxoglutarate dehydrogenase. To assess the functional consequence of the interaction, purified FATP1 was reconstituted into phospholipid-containing vesicles and its effect on 2-oxoglutarate dehydrogenase activity evaluated. FATP1 enhanced the activity of 2-oxoglutarate dehydrogenase independently of its acyl-CoA synthetase activity whereas silencing of FATP1 in 3T3-L1 adipocytes resulted in decreased activity of 2-oxoglutarate dehydrogenase. FATP1 silenced 3T3-L1 adipocytes exhibited decreased tricarboxylic acid cycle activity, increased cellular NAD⁺/NADH, increased fatty acid oxidation, and increased lactate production indicative of altered mitochondrial energy metabolism. These results reveal a novel role for FATP1 as a regulator of tricarboxylic acid cycle activity and mitochondrial function.     

TR4 activates FATP1 gene expression to promote lipid accumulation in 3T3-L1 adipocytes

We show that TR4 facilitates lipid accumulation in 3T3-L1 adipocytes via induction of the FATP1 gene. Further study showed that TR4 transactivated FATP1 5' promoter activity via direct binding to the TR4 responsive element located at the FATP1 5' promoter region. Constitutive overexpression of TR4 in 3T3-L1 adipocytes resulted in increased lipid accumulation, accompanied by an increase in fatty acid uptake. However, small interfering RNA knockdown of FATP1 abolished TR4-enhanced fatty acid uptake. Moreover, microRNA-mediated silencing of TR4 in 3T3-L1 adipocytes drastically reduced basal FATP1 5' promoter activity and FATP1 expression with reduced lipid accumulation.     

Fatty acid transport protein 1 and long-chain acyl coenzyme A synthetase 1 interact in adipocytes

The fatty acid transport proteins (FATP) and long-chain acyl coenzyme A synthetase (ACSL) proteins have been shown to play a role in facilitating long-chain fatty acid (LCFA) transport in mammalian cells under physiologic conditions. The involvement of both FATP and ACSL proteins is consistent with the model of vectorial acylation, in which fatty acid transport is coupled to esterification. This study was undertaken to determine whether the functions of these proteins are coordinated through a protein-protein interaction that might serve as a point of regulation for cellular fatty acid transport. We demonstrate for the first time that FATP1 and ACSL1 coimmunoprecipitate in 3T3-L1 adipocytes, indicating that these proteins form an oligomeric complex. The efficiency of FATP1 and ACSL1 coimmunoprecipitation is unaltered by acute insulin treatment, which stimulates fatty acid uptake, or by treatment with isoproterenol, which decreases fatty acid uptake and stimulates lipolysis. Moreover, inhibition of ACSL1 activity in adipocytes impairs fatty acid uptake, suggesting that esterification is essential for fatty acid transport. Together, our findings suggest that a constitutive interaction between FATP1 and ACSL1 contributes to the efficient cellular uptake of LCFAs in adipocytes through vectorial acylation.     

The fatty acid transport protein (FATP1) is a very long chain acyl-CoA synthetase

The primary sequence of the murine fatty acid transport protein (FATP1) is very similar to the multigene family of very long chain (C20-C26) acyl-CoA synthetases. To determine if FATP1 is a long chain acyl coenzyme A synthetase, FATP1-Myc/His fusion protein was expressed in COS1 cells, and its enzymatic activity was analyzed. In addition, mutations were generated in two domains conserved in acyl-CoA synthetases: a 6- amino acid substitution into the putative active site (amino acids 249-254) generating mutant M1 and a 59-amino acid deletion into a conserved C-terminal domain (amino acids 464-523) generating mutant M2. Immunolocalization revealed that the FATP1-Myc/His forms were distributed between the COS1 cell plasma membrane and intracellular membranes. COS1 cells expressing wild type FATP1-Myc/His exhibited a 3-fold increase in the ratio of lignoceroyl-CoA synthetase activity (C24:0) to palmitoyl-CoA synthetase activity (C16:0), characteristic of very long chain acyl-CoA synthetases, whereas both mutant M1 and M2 were catalytically inactive. Detergent-solubilized FATP1-Myc/His was partially purified using nickel-based affinity chromatography and demonstrated a 10-fold increase in very long chain acyl-CoA specific activity (C24:0/C16:0). These results indicate that FATP1 is a very long chain acyl-CoA synthetase and suggest that a potential mechanism for facilitating mammalian fatty acid uptake is via esterification coupled influx.     

Fatty acid metabolism in adipocytes: functional analysis of fatty acid transport proteins 1 and 4

The role of fatty acid transport protein 1 (FATP1) and FATP4 in facilitating adipocyte fatty acid metabolism was investigated using stable FATP1 or FATP4 knockdown (kd) 3T3-L1 cell lines derived from retrovirus-delivered short hairpin RNA (shRNA). Decreased expression of FATP1 or FATP4 did not affect preadipocyte differentiation or the expression of FATP1 (in FATP4 kd), FATP4 (in FATP1 kd), fatty acid translocase, acyl-coenzyme A synthetase 1, and adipocyte fatty acid binding protein but did lead to increased levels of peroxisome proliferator-activated receptor gamma and CCAAT/enhancer binding protein alpha. Both FATP1 and FATP4 kd adipocytes exhibited reduced triacylglycerol deposition and corresponding reductions in diacylglycerol and monoacylglycerol levels compared with control cells. FATP1 kd adipocytes displayed an approximately 25% reduction in basal (3)H-labeled fatty acid uptake and a complete loss of insulin-stimulated (3)H-labeled fatty acid uptake compared with control adipocytes. In contrast, FATP4 kd adipocytes as well as HEK-293 cells overexpressing FATP4 did not display any changes in fatty acid influx. FATP4 kd cells exhibited increased basal lipolysis, whereas FATP1 kd cells exhibited no change in lipolytic capacity. Consistent with reduced triacylglycerol accumulation, FATP1 and FATP4 kd adipocytes exhibited enhanced 2-deoxyglucose uptake compared with control adipocytes. These findings define unique and distinct roles for FATP1 and FATP4 in adipose fatty acid metabolism.     

FATP1 is an insulin-sensitive fatty acid transporter involved in diet-induced obesity

Fatty acid transport protein 1 (FATP1), a member of the FATP/Slc27 protein family, enhances the cellular uptake of long-chain fatty acids (LCFAs) and is expressed in several insulin-sensitive tissues. In adipocytes and skeletal muscle, FATP1 translocates from an intracellular compartment to the plasma membrane in response to insulin. Here we show that insulin-stimulated fatty acid uptake is completely abolished in FATP1-null adipocytes and greatly reduced in skeletal muscle of FATP1-knockout animals while basal LCFA uptake by both tissues was unaffected. Moreover, loss of FATP1 function altered regulation of postprandial serum LCFA, causing a redistribution of lipids from adipocyte tissue and muscle to the liver, and led to a complete protection from diet-induced obesity and insulin desensitization. This is the first in vivo evidence that insulin can regulate the uptake of LCFA by tissues via FATP1 activation and that FATPs determine the tissue distribution of dietary lipids. The strong protection against diet-induced obesity and insulin desensitization observed in FATP1-null animals suggests FATP1 as a novel antidiabetic target.     

Localization of adipocyte long-chain fatty acyl-CoA synthetase at the plasma membrane

Long-chain fatty acyl-CoA synthetase (FACS) catalyzes esterification of long-chain fatty acids (LCFAs) with coenzyme A (CoA), the first step in fatty acid metabolism. FACS has been shown to play a role in LCFA import into bacteria and implicated to function in mammalian cell LCFA import. In the present study, we demonstrate that FACS overexpression in fibroblasts increases LCFA uptake, and overexpression of both FACS and the fatty acid transport protein (FATP) have synergistic effects on LCFA uptake. To explore how FACS contributes to LCFA import, we examined the subcellular location of this enzyme in 3T3-L1 adipocytes which natively express this protein and which efficiently take up LCFAs. We demonstrate for the first time that FACS is an integral membrane protein. Subcellular fractionation of adipocytes by differential density centrifugation reveals immunoreactive and enzymatically active FACS in several membrane fractions, including the plasma membrane. Immunofluorescence studies on adipocyte plasma membrane lawns confirm that FACS resides at the plasma membrane of adipocytes, where it co-distributes with FATP. Taken together, our data support a model in which imported LCFAs are immediately esterified at the plasma membrane upon uptake, and in which FATP and FACS function coordinately to facilitate LCFA movement across the plasma membrane of mammalian cells.     

Differentially localized acyl-CoA synthetase 4 isoenzymes mediate the metabolic channeling of fatty acids towards phosphatidylinositol

The acyl-CoA synthetase 4 (ACSL4) has been implicated in carcinogenesis and neuronal development. Acyl-CoA synthetases are essential enzymes of lipid metabolism, and ACSL4 is distinguished by its preference for arachidonic acid. Two human ACSL4 isoforms arising from differential splicing were analyzed by ectopic expression in COS cells. We found that the ACSL4_v1 variant localized to the inner side of the plasma membrane including microvilli, and was also present in the cytosol. ACSL4_v2 contains an additional N-terminal hydrophobic region; this isoform was located at the endoplasmic reticulum and on lipid droplets. A third isoform was designed de novo by appending a mitochondrial targeting signal. All three ACSL4 variants showed the same specific enzyme activity. Overexpression of the isoenzymes increased cellular uptake of arachidonate to the same degree, indicating that the metabolic trapping of fatty acids is independent of the subcellular localization. Remarkably, phospholipid metabolism was changed by ACSL4 expression. Labeling with arachidonate showed that the amount of newly synthesized phosphatidylinositol was increased by all three ACSL4 isoenzymes but not by ACSL1. This was dependent on the expression level and the localization of the ACSL4 isoform. We conclude that in our model system exogenous fatty acids are channeled preferentially towards phosphatidylinositol by ACSL4 overexpression. The differential localization of the endogenous isoenzymes may provide compartment specific precursors of this anionic phospholipid important for many signaling processes.     

Mouse very long-chain Acyl-CoA synthetase 3/fatty acid transport protein 3 catalyzes fatty acid activation but not fatty acid transport in MA-10 cells

The family of proteins that includes very long-chain acyl-CoA synthetases (ACSVL) consists of six members. These enzymes have also been designated fatty acid transport proteins. We cloned full-length mouse Acsvl3 cDNA and characterized its protein product ACSVL3/fatty acid transport protein 3. The predicted amino acid sequence contains two highly conserved motifs characteristic of acyl-CoA synthetases. Northern blot analysis revealed that the mouse Acsvl3 mRNA is highly expressed in adrenal gland, testis, and ovary, with lower expression in the brain of adult mice. A developmental Northern blot revealed that Acsvl3 mRNA levels were significantly higher in embryonic mouse brain (embryonic days 12-14) than in newborn or adult mice, suggesting a possible role in nervous system development. Immunohistochemistry revealed high ACSVL3 expression in adrenal cortical cells, spermatocytes and interstitial cells of the testis, theca cells of the ovary, cerebral cortical neurons, and cerebellar Purkinje cells. Endogenous ACSVL3 was found primarily in mitochondria of MA-10 and Neuro2a cells by both Western blot analysis of subcellular fractions and immunofluorescence analysis. In MA-10 cells, loss-of-function studies using RNA interference confirmed that endogenous ACSVL3 is an acyl-CoA synthetase capable of activating both long-chain (C16:0) and very long-chain (C24:0) fatty acids. However, despite decreased acyl-CoA synthetase activity, initial rates of fatty acid uptake were unaffected by knockdown of Acsvl3 expression in MA-10 cells. These studies cast doubt on the designation of ACSVL3 as a fatty acid transport protein.     

FATP4 contributes as an enzyme to the basal and insulin-mediated fatty acid uptake of C₂C₁₂ muscle cells

The function of membrane proteins in long-chain fatty acid transport is controversial. The acyl-CoA synthetase fatty acid transport protein-4 (FATP4) has been suggested to facilitate fatty acid uptake indirectly by its enzymatic activity, or directly by transport across the plasma membrane. Here, we investigated the function of FATP4 in basal and insulin mediated fatty acid uptake in C(2)C(12) muscle cells, a model system relevant for fatty acid metabolism. Stable expression of exogenous FATP4 resulted in a twofold higher fatty acyl-CoA synthetase activity, and cellular uptake of oleate was enhanced similarly. Kinetic analysis demonstrated that FATP4 allowed the cells to reach apparent saturation of fatty acid uptake at a twofold higher level compared with control. Short-term treatment with insulin increased fatty acid uptake in line with previous reports. Surprisingly, insulin increased the acyl-CoA synthetase activity of C(2)C(12) cells within minutes. This effect was sensitive to inhibition of insulin signaling by wortmannin. Affinity purified FATP4 prepared from insulin-treated cells showed an enhanced enzyme activity, suggesting it constitutes a novel target of short-term metabolic regulation by insulin. This offers a new mechanistic explanation for the concomitantly observed enhanced fatty acid uptake. FATP4 was colocalized to the endoplasmic reticulum by double immunofluorescence and subcellular fractionation, clearly distinct from the plasma membrane. Importantly, neither differentiation into myotubes nor insulin treatment changed the localization of FATP4. We conclude that FATP4 functions by its intrinsic enzymatic activity. This is in line with the concept that intracellular metabolism plays a significant role in cellular fatty acid uptake.     

Oligomerization of the murine fatty acid transport protein 1

The 63-kDa murine fatty acid transport protein 1 (FATP1) was cloned on the basis of its ability to augment fatty acid import when overexpressed in mammalian cells. The membrane topology of this integral plasma membrane protein does not resemble that of polytopic membrane transporters for other substrates. Western blot analysis of 3T3-L1 adipocytes that natively express FATP1 demonstrate a prominent 130-kDa species as well as the expected 63-kDa FATP1, suggesting that this protein may participate in a cell surface transport protein complex. To test whether FATP1 is capable of oligomerization, we expressed functional FATP1 molecules with different amino- or carboxyl-terminal epitope tags in fibroblasts. These epitope-tagged proteins also form apparent higher molecular weight species. We show that, when expressed in the same cells, differentially tagged FATP1 proteins co-immunoprecipitate. The region between amino acid residues 191 and 475 is sufficient for association of differentially tagged truncated FATP1 constructs. When wild type FATP1 and the non-functional s250a FATP1 mutant are co-expressed in COS7 cells, mutant FATP1 has dominant inhibitory function in fatty acid uptake assays. Taken together, these results are consistent with a model in which FATP1 homodimeric complexes play an important role in cellular fatty acid import.     

Comparative biochemical studies of the murine fatty acid transport proteins (FATP) expressed in yeast

The fatty acid transport protein (FATP) family is a group of proteins that are predicted to be components of specific fatty acid trafficking pathways. In mammalian systems, six different isoforms have been identified, which function in the import of exogenous fatty acids or in the activation of very long-chain fatty acids. This has led to controversy as to whether these proteins function as membrane-bound fatty acid transporters or as acyl-CoA synthetases, which activate long-chain fatty acids concomitant with transport. The yeast FATP orthologue, Fat1p, is a dual functional protein and is required for both the import of long-chain fatty acids and the activation of very long-chain fatty acids; these activities intrinsic to Fat1p are separable functions. To more precisely define the roles of the different mammalian isoforms in fatty acid trafficking, the six murine proteins (mmFATP1-6) were expressed and characterized in a genetically defined yeast strain, which cannot transport long-chain fatty acids and has reduced long-chain acyl-CoA synthetase activity (fat1Delta faa1Delta). Each isoform was evaluated for fatty acid transport, fatty acid activation (using C18:1, C20:4, and C24:0 as substrates), and accumulation of very long-chain fatty acids. Murine FATP1, -2, and -4 complemented the defects in fatty acid transport and very long-chain fatty acid activation associated with a deletion of the yeast FAT1 gene; mmFATP3, -5, and -6 did not complement the transport function even though each was localized to the yeast plasma membrane. Both mmFATP3 and -6 activated C20:4 and C20:4, while the expression of mmFATP5 did not substantially increase acyl-CoA synthetases activities using the substrates tested. These data support the conclusion that the different mmFATP isoforms play unique roles in fatty acid trafficking, including the transport of exogenous long-chain fatty acids.     

Insulin and Chromium Picolinate Induce Translocation of CD36 to the Plasma Membrane Through Different Signaling Pathways in 3T3-L1 Adipocytes,and with a Differential Functionality of the CD36

Chromium picolinate (CrPic) has been indicated to activate glucose transporter 4 (GLUT4) trafficking to the plasma membrane (PM) to enhance glucose uptake in 3T3-L1 adipocytes. In skeletal and heart muscle cells, insulin directs the intracellular trafficking of the fatty acid translocase/CD36 to induce the uptake of cellular long-chain fatty acid (LCFA). The current study describes the effects of CrPic and insulin on the translocation of CD36 from intracellular storage pools to the PM in 3T3-L1 adipocytes in comparison with that of GLUT4. Immunofluorescence microscopy and immunoblotting revealed that both CD36 and GLUT4 were expressed and primarily located intracellularly in 3T3-L1 adipocytes. Upon insulin or CrPic stimulation, PM expression of CD36 increased in a similar manner as that for GLUT4; the CrPic-stimulated PM expression was less strong than that of insulin. The increase in PM localization for these two proteins by insulin paralleled LCFA ([1-¹⁴C]palmitate) or [³H]deoxyglucose uptake in 3T3-L1 adipocytes. The induction of the PM expression of GLUT4, but not CD36, or substrate uptake by insulin and CrPic appears to be additive in adipocytes. Furthermore, wortmannin completely inhibited the insulin-stimulated translocation of GLUT4 or CD36 and prevented the increased uptake of glucose or LCFA in these cells. Taken together, for the first time, these findings suggest that both insulin and CrPic induce CD36 translocation to the PM in 3T3-L1 adipocytes and that their translocation-inducing effects are not additive. The signaling pathway inducing the translocations is different, apparently resulting in a differential activity of CD36.     

Enzymatic properties of purified murine fatty acid transport protein 4 and analysis of acyl-CoA synthetase activities in tissues from FATP4 null mice

Fatty acid transport protein 4 (FATP4) is an integral membrane protein expressed in the plasma and internal membranes of the small intestine and adipocyte as well as in the brain, kidney, liver, skin, and heart. FATP4 has been hypothesized to be bifunctional, exhibiting both fatty acid transport and acyl-CoA synthetase activities that work in concert to mediate fatty acid influx across biological membranes. To determine whether FATP4 is an acyl-CoA synthetase, the murine protein was engineered to contain a C-terminal FLAG epitope tag, expressed in COS1 cells via adenovirus-mediated infection and purified to near homogeneity using alpha-FLAG affinity chromatography. Kinetic analysis of the enzyme was carried out for long chain (palmitic acid, C16:0) and very long chain (lignoceric acid, C24:0) fatty acids as well as for ATP and CoA. FATP4 exhibited substrate specificity for C16:0 and C24:0 fatty acids with a V(max)/K(m) (C16:0)/V(max)/K(m) (C24:0) of 1.5. Like purified FATP1, FATP4 was insensitive to inhibition by triacsin C but was sensitive to feedback inhibition by acyl-CoA. Although purified FATP4 exhibited high levels of palmitoyl-CoA and lignoceroyl-CoA synthetase activity, extracts from the skin and intestine of FATP4 null mice exhibited reduced esterification for C24:0, but not C16:0 or C18:1, suggesting that in vivo, defects in very long chain fatty acid uptake may underlie the skin disorder phenotype of null mice.     

Human Fatty Acid Transport Protein 2a/Very Long Chain Acyl-CoA Synthetase 1 (FATP2a/Acsvl1) Has a Preference in Mediating the Channeling of Exogenous n-3 Fatty Acids into Phosphatidylinositol

The trafficking of fatty acids across the membrane and into downstream metabolic pathways requires their activation to CoA thioesters. Members of the fatty acid transport protein/very long chain acyl-CoA synthetase (FATP/Acsvl) family are emerging as key players in the trafficking of exogenous fatty acids into the cell and in intracellular fatty acid homeostasis. We have expressed two naturally occurring splice variants of human FATP2 (Acsvl1) in yeast and 293T-REx cells and addressed their roles in fatty acid transport, activation, and intracellular trafficking. Although both forms (FATP2a (M_r 70,000) and FATP2b (M_r 65,000 and lacking exon3, which encodes part of the ATP binding site)) were functional in fatty acid import, only FATP2a had acyl-CoA synthetase activity, with an apparent preference toward very long chain fatty acids. To further address the roles of FATP2a or FATP2b in fatty acid uptake and activation, LC-MS/MS was used to separate and quantify different acyl-CoA species (C14–C24) and to monitor the trafficking of different classes of exogenous fatty acids into intracellular acyl-CoA pools in 293T-REx cells expressing either isoform. The use of stable isotopically labeled fatty acids demonstrated FATP2a is involved in the uptake and activation of exogenous fatty acids, with a preference toward n-3 fatty acids (C18:3 and C22:6). Using the same cells expressing FATP2a or FATP2b, electrospray ionization/MS was used to follow the trafficking of stable isotopically labeled n-3 fatty acids into phosphatidylcholine and phosphatidylinositol. The expression of FATP2a resulted in the trafficking of C18:3-CoA and C22:6-CoA into both phosphatidylcholine and phosphatidylinositol but with a distinct preference for phosphatidylinositol. Collectively these data demonstrate FATP2a functions in fatty acid transport and activation and provides specificity toward n-3 fatty acids in which the corresponding n-3 acyl-CoAs are preferentially trafficked into acyl-CoA pools destined for phosphatidylinositol incorporation.     

Characterization of the Acyl-CoA synthetase activity of purified murine fatty acid transport protein 1

Fatty acid transport protein 1 (FATP1) is an approximately 63-kDa plasma membrane protein that facilitates the influx of fatty acids into adipocytes as well as skeletal and cardiac myocytes. Previous studies with FATP1 expressed in COS1 cell extracts suggested that FATP1 exhibits very long chain acyl-CoA synthetase (ACS) activity and that such activity may be linked to fatty acid transport. To address the enzymatic activity of the isolated protein, murine FATP1 and ACS1 were engineered to contain a C-terminal Myc-His tag expressed in COS1 cells via adenoviral-mediated infection and purified to homogeneity using nickel affinity chromatography. Kinetic analysis of the purified enzymes was carried out for long chain palmitic acid (C16:0) and very long chain lignoceric acid (C24:0) as well as for ATP and CoA. FATP1 exhibited similar substrate specificity for fatty acids 16-24 carbons in length, whereas ACS1 was 10-fold more active on long chain fatty acids relative to very long chain fatty acids. The very long chain acyl-CoA synthetase activity of the two enzymes was comparable as were the Km values for both ATP and coenzyme A. Interestingly, FATP1 was insensitive to inhibition by triacsin C, whereas ACS1 was inhibited by micromolar concentrations of the compound. These data represent the first characterization of purified FATP1 and indicate that the enzyme is a broad substrate specificity acyl-CoA synthetase. These findings are consistent with the hypothesis that that fatty acid uptake into cells is linked to their esterification with coenzyme A.     

FAT/CD36-mediated long-chain fatty acid uptake in adipocytes requires plasma membrane rafts

We previously reported that lipid rafts are involved in long-chain fatty acid (LCFA) uptake in 3T3-L1 adipocytes. The present data show that LCFA uptake does not depend on caveolae endocytosis because expression of a dominant negative mutant of dynamin had no effect on uptake of [3H]oleic acid, whereas it effectively prevented endocytosis of cholera toxin. Isolation of detergent-resistant membranes (DRMs) from 3T3-L1 cell homogenates revealed that FAT/CD36 was expressed in both DRMs and detergent-soluble membranes (DSMs), whereas FATP1 and FATP4 were present only in DSMs but not DRMs. Disruption of lipid rafts by cyclodextrin and specific inhibition of FAT/CD36 by sulfo-N-succinimidyl oleate (SSO) significantly decreased uptake of [3H]oleic acid, but simultaneous treatment had no additional or synergistic effects, suggesting that both treatments target the same mechanism. Indeed, subcellular fractionation demonstrated that plasma membrane fatty acid translocase (FAT/CD36) is exclusively located in lipid rafts, whereas intracellular FAT/CD36 cofractionated with DSMs. Binding assays confirmed that [3H]SSO predominantly binds to FAT/CD36 within plasma membrane DRMs. In conclusion, our data strongly suggest that FAT/CD36 mediates raft-dependent LCFA uptake. Plasma membrane lipid rafts might control LCFA uptake by regulating surface availability of FAT/CD36.     

Insulin causes fatty acid transport protein translocation and enhanced fatty acid uptake in adipocytes

Fatty acid uptake into 3T3 L1 adipocytes is predominantly transporter mediated. Here we show that, during 3T3 L1 adipocyte differentiation, expression of fatty acid transport proteins (FATPs) 1 and 4 is induced. Using subcellular membrane fractionation and immunofluorescence microscopy, we demonstrate that, in adipocytes, insulin induces plasma membrane translocation of FATPs from an intracellular perinuclear compartment to the plasma membrane. This translocation was observed within minutes of insulin treatment and was paralleled by an increase in long chain fatty acid (LCFA) uptake. In contrast, treatment with TNF-alpha inhibited basal and insulin-induced LCFA uptake and reduced FATP1 and -4 levels. Thus, hormonal regulation of FATP activity may play an important role in energy homeostasis and metabolic disorders such as type 2 diabetes.