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 trafficking in the adipocyte.

The insolubility of fatty acids in cellular environments requires that specific trafficking mechanisms be developed to vectorally orient and deliver lipids for cellular needs. The roles of putative membrane bound fatty acid transporters and soluble carrier proteins are discussed in terms of mechanisms of fatty acid trafficking. The numerous roles for fatty acids as an energy source, as structural elements for membrane synthesis, as bioregulators and as prohormones with the potential to regulate gene expression, are discussed in terms of the necessity to regulate their intracellular location and concentration.

Targeted disruption of the adipocyte lipid-binding protein (aP2 protein) gene impairs fat cell lipolysis and increases cellular fatty acid levels.

The availability of mice containing an adipocyte lipid-binding protein (ALBP/aP2) gene disruption allowed for a direct examination of the presumed role of lipid-binding proteins in the mobilization and trafficking of intracellular fatty acids. Total body and epididymal fat pad weights, as well as adipose cell morphology, were unaltered in male ALBP/aP2 disrupted mice when compared to their wild-type littermates. Analysis of adipocytes isolated from wild-type and ALBP/aP2 null mice revealed that a selective 40- and 13-fold increase in the level of the keratinocyte lipid-binding protein (KLBP) mRNA and protein, respectively, accompanied the ALBP/aP2 gene disruption. Although KLBP protein was significantly up-regulated, the total lipid-binding protein level decreased 8 -fold as a consequence of the disruption. There was no appreciable difference in the rate of fatty acid influx or esterification in adipocytes of wild-type and ALBP/aP2 null animals. To the contrary, basal lipolysis decreased approximately 40% in ALBP/aP2 nulls as compared to wild-type littermates. The glycerol release from isproterenol-stimulated ALBP/aP2 null fat cells was similarly reduced by approximately 35%. Consistent with a decrease in basal efflux, the non-esterified fatty acid (NEFA) level was nearly 3-fold greater in adipocytes from ALBP/aP2 nulls as compared to wild-type animals. The significant decrease in both basal and isoproterenol-stimulated lipolysis in adipose tissue of ALBP/aP2 null mice supports the model whereby intracellular lipid-binding proteins function as lipid chaperones, facilitating the movement of fatty acids out of the fat cell.

Regulation of gene expression in adipose cells by polyunsaturated fatty acids.

In fat cells polyunsaturated fatty acids are both substrates for, and products of, triacylglycerol metabolism. Dietary fatty acids are efficiently incorporated into the triacylglycerol droplet under lipogenic conditions while rapidly mobilizing them during lipolytic stimulation. Hence, the flux and magnitude of the fatty acid pool in adipocytes is constantly changing in response to hormonal, metabolic and genetic determinants. Due to the rapidly changing flux of fatty acids, the majority of genes encoding enzymes and proteins of lipid metabolism are largely refractory to long-term regulatory control by fatty acids. Only at extremes of high or low lipid levels, or under pathophysiological conditions, do adipose genes respond by up- or down-regulating gene expression. Despite the lack of responsiveness to lipids in adipose tissue, a surprisingly large number of genes have been characterized recently as lipid responsive when assayed in heterologous systems. These observations suggest an endogenous negative element exists in the lipid signaling pathway in adipocytes. The major intracellular lipid binding protein in adipose cells is the adipocyte lipid binding protein (ALBP), the product of the aP2 gene. This protein is 15 kDa, abundant and found exclusively in the cytoplasm of adipocytes. The protein binds fatty acids and related lipids in a 1:1 stoichiometry within a large water filled interior cavity. The lipid binding protein forms high affinity associations with polyunsaturated fatty acids such as arachidonic acid (Kd approximately 250 nM) but not with prostaglandins of the E, D or J series (Kd > 4 microM). The upstream region of the aP2 gene contains a peroxisome-proliferator activated receptor response element which associates with PPARs to regulate its expression. A positive autoregulatory circuit exists to upregulate lipid binding protein expression when polyunsaturated fatty acid levels are increased. Analysis of adipose tissue from aP2 null animals generated by a targeted disruption revealed that the partial loss of ALBP expression in heterozygotes and complete lack of ALBP in the nulls was accompanied by a compensatory up-regulation of the keratinocyte lipid binding protein. However, the total amount of lipid binding protein in the nulls was less than 15% that in the wild type littermates. No evidence was found for upregulation of other lipid binding proteins such as the heart FABP or liver FABP. In aP2 nulls, the fatty acid composition was unaltered but the mass of fatty acid per gram tissue more than doubled relative to wild type. In heterozygotes, the level of fatty acid was intermediate to that of wild-type and nulls, consistent with an intermediate level of lipid binding protein. These results indicate that the fatty acid pool level in adipocytes is inversely correlated with the amount of lipid binding protein. Since prostaglandin biosynthesis is dependent upon polyunsaturated fatty acid substrates, the intracellular lipid binding proteins control accessibility of substrates of the prostanoid pathway. Intracellular lipid binding proteins therefore are negative elements in polyunsaturated fatty acid control of gene expression.

Expression, purification, and ligand-binding analysis of recombinant keratinocyte lipid-binding protein (MAL-1), an intracellular lipid-binding found overexpressed in neoplastic skin cells.

The keratinocyte lipid-binding protein (KLBP) has been identified on the basis of nucleotide sequence analysis of its cloned cDNA as a new member of the intracellular lipid-binding protein (iLBP) multigene family. To characterize KLBP and determine its ligand-binding properties, its cDNA was subcloned into Escherichia coli, and the protein was overexpressed and purified to homogeneity by a combination of acid extraction, gel permeation, and ion-exchange chromatographies. Purified KLBP exhibited high-affinity binding of the fluorescent hydrophobic probe 1-anilinonaphthalene-8-sulfonate (1,8-ANS), displaying an apparent dissociation constant of 390 +/- 90 nM (n = 0.74 +/- 0.2). Using an assay based upon displacement of the bound fluorophore, KLBP was found to bind long chain fatty acids most avidly; oleic acid (18:1) bound with an apparent Kd of 248 +/- 12 nM, and arachidonic acid (20:4) exhibited a dissociation constant of 318 +/- 14 nM. As the length of the fatty acid decreased, the binding affinity was reduced; myristic acid (14:0) bound with a K(d) of 1409 +/- 423 nM, but medium-chain (decanoic acid, 10:0) and short-chain (octanoic acid, 8:0) lipids were not bound at all. The protein did not bind prostaglandin E2 with any measurable affinity but did associate with eicosanoids such as 5-hydroperoxyeicosatetraenoic acid (5-HPETE; K(d) of 848 +/- 211 nM) and 15-HPETE (Kd of 463 +/- 243 nM) and to a lesser extent their hydroxy derivatives, 5-HETE and 15-HETE (Kd of 1560 +/- 115 nM and greater than 4 microM, respectively). all-trans-Retinoic acid was a weak ligand for KLBP, binding with a Kd of 3600 nM, and all-trans-retinol did not displace 1,8-ANS. Molecular modeling of the KLBP sequence upon the X-ray crystal structures of several iLBP's suggested that the side chains of one or more cysteine residues may reside within the putative ligand-binding cavity. Consistent with this, sulfhydryl titration of purified KLBP with 5,5'-dithiobis(2-nitrobenzoic acid) at pH 8.0 in the presence and absence of oleic acid revealed that at least one residue was protected from modification by the fatty acid. These results describe the first purification and characterization of the ligand-binding properties of KLBP and indicate that the protein is a fatty acid binding protein with a tertiary structure likely to be similar to other members of the iLBP multigene family.