Fatty acid binding sites of rodent adipocyte and heart fatty acid binding proteins: characterization using fluorescent fatty acids

Murine adipocyte and rat heart fatty acid binding proteins (FABP) are closely related members of a family of cytosolic proteins which bind long-chain free fatty acids (ffa). The physical and chemical characteristics of the fatty acid binding sites of these proteins were studied using a series of fluorescent analogues of stearic acid (18:0) with an anthracene moiety covalently attached at seven different positions along the length of the hydrocarbon chain (AOffa). Previously, we used these probes to investigate the binding site of rat liver FABP (L-FABP) [Storch et al. (1989) J. Biol. Chem. 264, 8708-8713]. Here we extend those studies to adipocyte and heart FABP, two members of the FABP family which share a high degree of sequence homology with each other (62% identity) but which are less homologous with L-FABP (approximately 30%). The results show that the fluorescence emission spectra of AOffa bound to adipocyte FABP (A-FABP) are blue-shifted relative to heart FABP (H-FABP), indicating that AOffa bound to A-FABP are held in a more constrained configuration. For both proteins, constraint on the bound ffa probe is highest at the midportion of the acyl chain. Ffa are bound in a hydrophobic environment in both proteins. Excited-state lifetimes and fluorescence quantum yields suggest that the binding site of H-FABP is more hydrophobic than that of A-FABP. Nevertheless, acrylamide quenching experiments indicate that ffa bound to H-FABP are more accessible to the aqueous environment than are A-FABP-bound ffa.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanism of free fatty acid transfer from rat heart fatty acid-binding protein to phospholipid membranes. Evidence for a collisional process.

Fatty acid binding proteins (FABP) are a family of low molecular weight proteins found in many tissues that actively utilize free fatty acids (ffa). FABP would be expected to have a particularly important role in the heart, where over 80% of energy requirements are derived from oxidation of long chain fatty acids. The precise physiological function of heart FABP (H-FABP) has not been definitively identified, although it is thought to play a role in intracellular ffa transport. To examine the possible role of H-FABP in cardiac myocyte transfer of ffa, we examined the transfer of fluorescent anthroyloxy ffa (AOffa) from H-FABP to model phospholipid membranes, using a resonance energy transfer assay. In contrast to previous observations of ffa transfer from liver FABP and from membranes, transfer from H-FABP to membranes appears to occur by a different mechanism. AO-palmitate (16:0) transfer was 1.5-fold slower than AO-stearate (18:0) transfer, and mono-unsaturation did not affect the transfer rate. The AOffa transfer rate from H-FABP increased with increasing ionic strength and decreased slightly between pH 7 and 9. These results suggest that the rate of ffa transfer from H-FABP to membranes is independent of the ffa aqueous solubility. Thermodynamic analysis showed that the free energy of activation for the ffa transfer process arises primarily from an enthalpic component, with only a small entropic contribution, again suggesting the lack of an aqueous phase route of ffa delivery. Finally, the ffa transfer rate was found to be directly dependent on the concentration of acceptor membranes. These data therefore suggest that transfer of AOffa from H-FABP to membranes may occur via collisional interactions between the protein and membranes.     

Free fatty acid transfer from rat liver fatty acid-binding protein to phospholipid vesicles. Effect of ligand and solution properties.

Fatty acid binding proteins (FABP) are a family of 14-15-kDa proteins found in many mammalian cell types in high abundance. Although their precise physiological role remains hypothetical, the transfer of free fatty acids (ffa) to intracellular membrane sites is believed to be an important function of FABP. To better understand the role of FABP in this process, we have examined how the rate of ffa transfer from liver FABP (L-FABP) to model membranes is influenced by variations in ffa structure and properties of the aqueous phase. The rate of transfer of fluorescent anthroyloxy ffa to model acceptor membranes was monitored using a resonance energy transfer assay. The results show that a monounsaturated ffa transfers 2-fold more rapidly than a saturated ffa of equivalent chain length, and a two-carbon increase in acyl chain length results in a 3-fold decrease in transfer rate. The transfer rate decreases logarithmically with increasing ionic strength, suggesting that the aqueous solubility of the ffa is an important determinant of its dissociation rate from L-FABP. Fatty acid binding and the relative partition of n-(9-anthroloxy) ffa to L-FABP as compared with phospholipid membranes both decrease as pH decreases, indicating that ionized but not protonated ffa bind to L-FABP. The rate of ffa transfer from L-FABP to membranes increases approximately 4-fold with increasing pH, suggesting that ionization of the ffa carboxyl group is also an important determinant of the transfer process. Analysis of the dependence of the transfer rate on temperature demonstrates that the delta G++ of the activated state for ffa transfer arises from both enthalpic and entropic processes. These studies demonstrate that the rate of transfer of long chain ffa from L-FABP to membranes is substantially affected by aqueous phase variables as well as properties of the ffa ligand itself.     

Diversity of fatty acid-binding protein structure and function: studies with fluorescent ligands

The mammalian fatty acid-binding proteins (FABP) are localized in many distinct cell types. They bind long chain fatty acidsin vitro, however, their functions and mechanisms of actionin vivo remain unknown. The present studies have sought to understand the relationships among these proteins, and to address the possible role of FABP in cellular fatty acid traffic. A series of anthroyloxy-labeled fluorescent fatty acids have been used to examine the physicochemical properties of the fatty acid-binding sites of different members of the FABP family. The fatty acid probes have also been used to study the rate and mechanism of fatty acid transfer from different FABP types to phospholipid membranes. The results of these studies show a number of interesting and potentially important differences between FABP family members. An examination of adipocyte and heart FABP (A- and H-FABP) shows that their fatty acid-binding sites are less hydrophobic than the liver FABP (L-FABP) site, and that the bound ligand experiences less motional constraint within the A- and H-FABP binding sites than within the L-FABP binding site. In keeping with these differences in structural properties, it was found that anthroyloxy-fatty acid transfer from A- and H-FABP to membranes is markedly faster than from L-FABP. Moreover, the mechanism of fatty acid transfer was found to be similar for the highly homologous logous A- and H-FABP, whereby transfer to phospholipid membranes appears to occur via transient collisional interactions between the FABP and membranes. Transfer of fatty acids from L-FABP, in contrast, occurs via an aqueous phase diffusion mechanism. Other studies utilized fluorescent fatty acid and monoacylglycerol derivatives to compare how the two FABP which are present in high abundance in the proximal small intestine interact with the two major products of dietary triacylglycerol hydrolysis. The results showed that whereas L-FABP binds both fatty acid and monoacylglycerol derivatives, intestinal FABP (I-FABP) appears to bind fatty acid but not monoacylglycerol. In summary, studies with fluorescent ligands have demonstrated unique properties for different FABP family members. A number of these differences appear to correlate with the degree of primary sequence homology between the proteins, and suggest functional diversity within the FABP family.Abbreviations FABP Fatty Acid-Binding Protein - L-FABP Liver FABP - H-FABP Heart FABP - A-FABP Adipocyte FABP - I-FABP Intestinal FABP - AOffa n-(9-anthroyloxy)fatty acid - MG Monoacylglycerol - NBD-PE N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine     

Transfer of fluorescent fatty acids from liver and heart fatty acid-binding proteins to model membranes

Fatty acid binding proteins (FABP) are a family of 14-15 kDa proteins found in high abundance in many mammalian cell types. The physiological functions of the FABP remain unknown. It is also not known whether each FABP has a unique function, or whether all FABP function in a similar manner in their respective tissues. In this report the rate of transfer of anthroyloxy-labeled free fatty acid (ffa) from FABP to phospholipid bilayers is monitored using a fluorescence resonance energy transfer assay. A comparison is made between heart muscle FABP and liver FABP, and the results show that the rate of ffa transfer from the heart protein is an order of magnitude greater than the rate of transfer from the liver protein. Ffa transfer rates from both liver and heart FABP are independent of acceptor concentration and composition, suggesting that, at least in the case of model membrane acceptor vesicles, the mechanism of transfer is via aqueous diffusion rather than via collision of FABP with membranes. Since the rate of ffa transfer is likely to be important to cellular ffa traffic, these studies suggest that heart FABP may function differently within the myocyte than does liver FABP within the hepatocyte.     

A comparison of heart and liver fatty acid-binding proteins: interactions with fatty acids and possible functional differences studied with fluorescent fatty acid analogues

Summary Fatty acid-binding proteins (FABP) are distinct but related gene products which are found in many mammalian cell types. They are generally present in high abundance, and are found in those tissues where free fatty acid (ffa) flux is high. The function(s) of FABP is unknown. Also not known is whether all FABP function similarly in their respective cell types, or whether different FABP have unique functions. The purpose of these studies was to assess whether different members of the FABP family exhibit different structural and functional properties. Two fluorescent analogues of ffa were used to compare the liver (L-FABP) and heart (H-FABP) binding proteins. The propionic acid derivative of diphenylhexatriene (PADPH) was used to examine the physical properties of the ffa binding site on L- and H-FABP, as well as the relative distribution of ffa between FABP and membranes. An anthroyloxy-derivative of palmitic acid, 2AP, was used to monitor the transfer kinetics of ffa from liver or heart FABP to acceptor membranes, using a resonance energy transfer assay. The results demonstrate that the ffa binding sites of both FABP are hydrophobic in nature, although the L-FABP site is more nonpolar than the H-FABP site. Equilibration of PADPH between L-FABP and phosphatidylcholine (PC) bilayers resulted in a molar partition preference of > 20: 1, L-FABP : PC. Similar studies with H-FABP resulted in a PADPH partition preference of only 3:1, H-FABP : PC. Finally, the transfer of 2AP from H-FABP to acceptor membranes was found to be 50-fold faster than transfer from L-FABP. These studies demonstrate that important structural and functional differences exist between different members of the FABP family, and therefore imply that the roles of different FABP may be unique.Abbreviations FABP Fatty Acid-Binding Protein - L-FABP Liver FABP - H-FABP Heart FABP - SUV Small Unilamellar Vesicle - PADPH 3-[p-(6-Phenyl)-1,3,5-Hexatrienyl]-phenylpropionic acid - 2AP 2-(9-Anthroyloxy)Palmitic acid - Q Quantum yield - _F Fluorescence lifetime     

Relation of lung fatty acid binding protein to the biosynthesis of pulmonary phosphatidic acid and phosphatidylcholine

The activities of glycerophosphate and lysophosphatidylcholine (LPC) acyltransferases were determined using lung microsomes in the presence of lung fatty acid binding protein (FABP). The synthesis of phosphatidic acid (PA) was increased two- to fourfold in the presence of FABP as compared to albumin. Lung FABP did not increase the incorporation of palmitoyl CoA into phosphatidylcholine. The results indicate that FABP-bound fatty acyl CoA may be a preferred substrate for glycerophosphate acyltransferase.     

Effect of fatty acid-binding proteins on intermembrane fatty acid transport studies on different types and mutant proteins.

Liposomes of different charge fixed to nitrocellulose filters were used to study the transfer of fatty acids to rat heart or liver mitochondria in the presence of fatty acid-binding protein (FABP) or albumin. [14C]Palmitate oxidation was used as a parameter. Different FABP types and heart FABP mutants were tested. The charge of the liposomes did not influence the solubilization and mitochondrial oxidation of palmitate without FABP and the amount of solubilized palmitate in the presence of FABP. Mitochondria did not show a preference for oxidation of FABP-bound palmitate over their tissue-specific FABP type. All FABP types increased palmitate oxidation by heart and liver mitochondria with neutral, positive and negative liposomes by 2.5-fold, 3.2-fold and twofold, respectively. Ileal lipid-binding protein and H-FABP mutants that do not bind fatty acid had no effect. Other H-FABP mutants had different effects, dependent on the site of mutation. The effect of albumin was similar to, but not dependent on, liposome charge. The ionic strength had only a slight effect. In conclusion, the transfer of palmitate from liposomal membranes to mitochondria was increased by all FABP types to a similar extent. The membrane charge had a large effect in contrast to the origin of the mitochondria.     

Significance of cytoplasmic fatty acid-binding protein for the ischemic heart

Ischemia of the heart is accompanied by the tissue accumulation of long-chain fatty acids and their metabolic derivatives such as -hydroxy fatty acids and fatty acyl-CoA and acyl-L-carnitine esters. These substances might be detrimental for proper myocardial function. Previously, it has been suggested that intracellular lipid binding proteins like cytoplasmic fatty acid-binding protein (FABP) and acyl-CoA binding protein (ACBP) may bind these accumulating fatty acyl moieties to prevent their elevated levels from potentially harmful actions. In addition, the suggestion has been made that the abundantly present FABP may scavenge free radicals which are generated during reperfusion of the ischemic heart. However, these protective actions are challenged by the continuous physico-chemical partition of fatty acyl moieties between FABP and membrane structures and by the rapid release of FABP from ischemic and reperfused cardiac muscle. Careful evaluation of the available literature data reveals that at present no definite conclusion can be drawn about the potential protective effect of FABP on the ischemic and reperfused heart. Biochem123: 167–173, 1993)Abbreviations FABP Fatty Acid-Binding Protein - ACBP Acyl-CoA Binding Protein - MDGI Mammary-Derived Growth Inhibitor - CK Creatine Kinase - LDH Lactate Dehydrogenase     

Role of fatty acid-binding protein in cardiac fatty acid oxidation

Summary Although abundant in most biological tissues and chemically well characterized, the fatty acid-binding protein (FABP) was until recently in search of a function. Because of its strong affinity for long chain fatty acids and its cytoplasmic origin, this protein was repeatedly claimed in the literature to be the transcytoplasmic fatty acid carrier. However, techniques to visualize and quantify the movements of molecules in the cytoplasm are still in their infancy. Consequently the carrier function of FABP remains somewhat speculative. However, FABP binds not only fatty acids but also their CoA and carnitine derivatives, two typical molecules of mitochondrial origin. Moreover, it has been demonstrated and confirmed that FABP is not exclusively cytoplasmic, but also mitochondrial. A function for FABP in the mitochondrial metabolism of fatty acids plus CoA and carnitine derivatives would therefore be anticpated. Using spin-labelling techniques, we present here evidence that FABP is a powerful regulator of acylcarnitine flux entering the mitochondrial -oxidative system. In this perspective FABP appears to be an active link between the cytoplasm and the mitochondria, regulating the energy made available to the cell. This active participation of FABP is shown to be the consequence of its gradient-like distribution in the cardiac cell, and also of the coexistence of multispecies of this protein produced by self-aggregation.     

Interactions of oleic acid with liver fatty acid binding protein: a carbon-13 NMR study

13C NMR spectroscopy was used to probe the structural interactions between carboxyl-13C-enriched oleic acid (18:1) and rat liver fatty acid binding protein (FABP) and the partitioning of 18:1 between FABP and unilamellar phosphatidylcholine (PC) vesicles. Spectra of systems containing 2-8 mol of 18:1/mol of FABP (but no PC) exhibited one carboxyl resonance (182.2 ppm) corresponding to FABP-bound 18:1. At pH values less than 8.0, an additional carboxyl resonance, corresponding to unbound 18:1 in a lamellar phase, was observed. Both resonances exhibited ionization shifts with estimated apparent pKa values of less than 5 (bound 18:1) and greater than 7 (unbound 18:1). The intensity of the resonance corresponding to FABP-bound 18:1 increased with increasing 18:1/FABP mole ratio and at 8/1 mole ratio indicated that at least 2 and 6 mol of 18:1/mol of FABP were FABP-bound at pH 7.4 and 8.6, respectively. NMR spectra of systems containing equal concentrations (w/v) of FABP and PC and from 1 to 4 mol of total fatty acid (FA)/mol of FABP exhibited two 18:1 carboxyl resonances (182.2 and 178.5 ppm, pH 7.4). The downfield resonance corresponded to FABP-bound 18:1 and the upfield resonance to PC vesicle bound 18:1. At 1/1 mole ratio (FA/FABP), the intensities of both resonances were approximately equal, but at 4/1 mole ratio the resonance for PC vesicle bound 18:1 was 3-fold more intense than that for FABP-bound 18:1. The following conclusions are reached: (i) The carboxyl groups of 18:1 bound to liver FABP experience only one type of binding environment (the aqueous milieu adjacent to the protein surface).(ABSTRACT TRUNCATED AT 250 WORDS)     

Spectroscopic investigations on the binding site of bovine hepatic fatty acid binding protein. Evidence for the existence of a single binding site for two fatty acid molecules

The hydrophobic region of the binding site of a bovine fatty acid binding protein (pI 7.0-FABP) has been characterized using fluorescence and circular dichroism (CD) spectroscopy. Blue-shifts of fluorescence emission maxima and increased lifetimes of naphthylamine dyes, anthroyloxy-fatty acids, pyrene nonanoic acid and trans-parinaric acid indicated a hydrophobic interaction with FABP. The fluorescence quenching of various anthroyloxy-fatty acids by iodide and acrylamide showed lower accessibility to the fluorophore linked to the carbon adjacent to the carbonyl group and towards the methyl end of the fatty acid. Binding stoichiometries were different for fatty acids and their bulky fluorescent analogues. trans-Parinaric acid when bound to FABP showed a complex induced CD-spectrum, which is explained by a close proximity of two ligands in the same binding site. Fluorescent derivatives of phosphatidylcholine with trans-parinaric acid and cholesteryl trans-parinarate did not bind to FABP. Thus, the binding site appears to be constructed for high affinity binding of long chain fatty acids.     

The structure of crystalline Escherichia coli-derived rat intestinal fatty acid-binding protein at 2.5-A resolution

Rat intestinal fatty acid-binding protein (I-FABP) is an abundant cytoplasmic protein which is synthesized in the small intestinal lining cell where it is thought to participate in the absorption and intracellular metabolism of fatty acids. Each mole of this 132-residue polypeptide binds 1 mol of long chain fatty acid in a noncovalent fashion. Because of its small size and single ligand-binding site, I-FABP represents an attractive model for defining the molecular details of long chain fatty acid-protein interactions. The structure of Escherichia coli-derived rat I-FABP has now been solved to 2.5 A resolution using three isomorphous heavy atom derivatives. The protein consists of 10 anti-parallel beta-strands present as two orthogonal beta-sheets. Together a "clam shell-like" structure is formed with an opening located between two beta-strands and an interior that is lined with the side chains of nonpolar amino acids. The bound fatty acid ligand is located in the interior of the protein and has a bent conformation, possibly reflecting the presence of several gauche bonds in the hydrocarbon tail. Our present interpretation of the electron density map suggests that the fatty acid is oriented with its carboxylate group facing the guanidinium group of Arg127, whereas the end of its hydrocarbon tail is in close proximity to Val106. The indole side chain of Trp83 forms the molecular framework around which the principal bend of the hydrocarbon chain occurs.     

Interaction of fatty acids,acyl-CoA derivatives and retinoids with microsomal membranes: effect of cytosolic proteins

This paper reviews characteristics of microsomal membrane structure; long chain fatty acids, acyl CoA derivatives, retinoids and the microsomal formation of acyl CoA derivatives and retinyl esters. It is analyzed how the movement of these molecules at the intracellular level is affected by their respective binding proteins (Fatty acid binding protein, acyl CoA binding protein and cellular retinol binding protein). Studies with model systems using these hydrophobic ligands and the lipid-binding or transfer proteins are also described. This topic is of interest especially because in the esterification of retinol the three substrates and the three binding proteins may interact. (Mol Cell Biochem20: 89–94, 1993)Abbreviations FABP(s) Fatty Acid Binding Protein(s) - CRBP Cellular Retinol Binding Protein - ACBP Acyl-CoA-Binding Protein     

Tryptophan insertion mutagenesis of liver fatty acid-binding protein: L28W mutant provides important insights into ligand binding and physiological function

Liver fatty acid-binding protein (FABP) binds a variety of non-polar anionic ligands including fatty acids, fatty acyl CoAs, and bile acids. Previously we prepared charge reversal mutants and demonstrated the importance of lysine residues within the portal region in ligand and membrane binding. We have now prepared several tryptophan-containing mutants within the portal region, and one tryptophan at position 28 (L28W) has proved remarkably effective as an intrinsic probe to further study ligand binding. The fluorescence of the L28W mutant was very sensitive to fatty acid and bile acid binding where a large (up to 4-fold) fluorescence enhancement was obtained. In contrast, the binding of oleoyl CoA reduced tryptophan fluorescence. Positive cooperativity for fatty acid binding was observed while detailed information on the orientation of binding of bile acid derivatives was obtained. The ability of bound oleoyl CoA to reduce the fluorescence of L28W provided an opportunity to demonstrate that fatty acyl CoAs can compete with fatty acids for binding to liver FABP under physiological conditions, further highlighting the role of fatty acyl CoAs in modulating FABP function in the cell.     

Rat heart fatty acid-binding protein is highly homologous to the murine adipocyte 422 protein and the P2 protein of peripheral nerve myelin

The rat heart contains an abundant cytosolic protein which binds long chain fatty acids. We have determined its primary structure by Edman degradation of peptides generated from chymotryptic, tryptic, and elastase digestions. This polypeptide (Mr = 14,992) contains 134 amino acids and has a blocked (acetylated) NH2 terminus. The sequence of rat heart fatty acid-binding protein (FABP) is remarkably similar to the murine adipocyte 422 protein and the P2 protein of peripheral nerve myelin. Computer-assisted alignment of heart FABP and 422 revealed that 82 of 132 comparable residues are identical (62%). There are 77 identities out of 131 possible matches between this protein and the human myelin P2 protein (59%). Similar comparisons demonstrate that heart FABP has significant homology to several other proteins which bind hydrophobic ligands. The rank of order of similarity to heart FABP is: 422 greater than myelin P2 greater than cellular retinoic acid-binding protein greater than cellular retinol-binding protein II greater than cellular retinol-binding protein greater than intestinal FABP greater than liver FABP. These eight sequences form a family of paralogous homologues. Heart FABP has a region of internal homology involving tandemly arrayed oligopeptides spanning residues 71-100 and 101-131. This feature is not found in the 422 and P2 sequences. The endogenous ligands bound by the 422, P2, and heart FABP sequences have not been defined. Interpretation of the biological significance of their structural similarities and differences will require information about their ligand specificities and affinities.     

Transfer of long-chain fluorescent free fatty acids between unilamellar vesicles

Movement of free fatty acids (ffa) between small unilamellar vesicles (SUV) was studied by measuring the transfer of fluorescent n-(9-anthroyloxy)-labeled analogues (AOffa) between donor and acceptor vesicles. Donors were composed of egg phosphatidylcholine (PC) loaded with 1-2 mol % AOffa, and acceptors were egg PC containing 10-12 mol % N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine (NBD-PE). The fluorescence of AO added directly to acceptor SUV was greater than 98% quenched by energy transfer to NBD. Thus, AOffa movement from donor to acceptor was monitored by the time-dependent decrease in AO fluorescence. The transfer of the short-chain AOffa, although too fast to be resolved by the methods used here, is consistent with studies that find transfer rates on the order of milliseconds and kinetics which are first order. In contrast, transfer rates for the long-chain AOffa are more than 2 orders of magnitude slower, and the kinetics of the transfer process are best described by the sum of two exponentials plus a constant. The ffa ionization state was also found to be an important determinant of transfer rate. The charged species transferred an average of 10-fold faster than the protonated ffa. The ffa pKa in the membrane is 9, as calculated from the pH dependence of transfer. Similar to results found for other lipids, long-chain AOffa are transferred via water rather than a collision-mediated process. The aqueous phase route of AOffa intermembrane transfer is indicated by the lack of effect on transfer of large alterations in the product of donor and acceptor phospholipid concentrations. Moreover, the transfer rate is decreased as [NaCl] is increased from 0.1 to 4 M. This effect of ionic strength is probably due not only to a decrease in the aqueous phase partition of the AOffa but also to an alteration in bilayer structure, as measured by fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene. The observed kinetics are consistent with a model in which the transfer involves two steps: transbilayer movement between the inner and outer bilayer leaflets, followed by transfer from the outer leaflet to the aqueous phase (off rate). Within the framework of this model, the observed slow rate is primarily determined by the rate of transbilayer movement, and the observed fast rate is approximately equal to the off rate. The off rate is about 10-fold faster than the rate of transbilayer movement.     

Liver fatty acid-binding protein and obesity

While low levels of unesterified long chain fatty acids (LCFAs) are normal metabolic intermediates of dietary and endogenous fat, LCFAs are also potent regulators of key receptors/enzymes and at high levels become toxic detergents within the cell. Elevated levels of LCFAs are associated with diabetes, obesity and metabolic syndrome. Consequently, mammals evolved fatty acid-binding proteins (FABPs) that bind/sequester these potentially toxic free fatty acids in the cytosol and present them for rapid removal in oxidative (mitochondria, peroxisomes) or storage (endoplasmic reticulum, lipid droplets) organelles. Mammals have a large (15-member) family of FABPs with multiple members occurring within a single cell type. The first described FABP, liver-FABP (L-FABP or FABP1), is expressed in very high levels (2–5% of cytosolic protein) in liver as well as in intestine and kidney. Since L-FABP facilitates uptake and metabolism of LCFAs in vitro and in cultured cells, it was expected that abnormal function or loss of L-FABP would reduce hepatic LCFA uptake/oxidation and thereby increase LCFAs available for oxidation in muscle and/or storage in adipose. This prediction was confirmed in vitro with isolated liver slices and cultured primary hepatocytes from L-FABP gene-ablated mice. Despite unaltered food consumption when fed a control diet ad libitum, the L-FABP null mice exhibited age- and sex-dependent weight gain and increased fat tissue mass. The obese phenotype was exacerbated in L-FABP null mice pair fed a high-fat diet. Taken together with other findings, these data suggest that L-FABP could have an important role in preventing age- or diet-induced obesity.     

Heart fatty acid uptake is decreased in heart fatty acid-binding protein gene-ablated mice

Cell culture systems have demonstrated a role for cytoplasmic fatty acid-binding proteins (FABP) in lipid metabolism, although a similar function in intact animals is unknown. We addressed this issue using heart fatty acid-binding protein (H-FABP) gene-ablated mice. H-FABP gene ablation reduced total heart fatty acid uptake 40 and 52% for [1-(14)C]16:0 and [1-(14)C]20:4n-6 compared with controls, respectively. Similarly, the amount of fatty acid found in the aqueous fraction was reduced 40 and 52% for [1-(14)C]16:0 and [1-(14)C]20:4n-6, respectively. Less [1-(14)C]16:0 entered the triacylglycerol pool, with significant redistribution of fatty acid between the triacylglycerol pool and the total phospholipid pool. Less [1-(14)C]20:4n-6 entered each lipid pool measured, but these changes did not alter the distribution of tracer among these pools. In gene-ablated mice, significantly more [1-(14)C]16:0 was targeted to choline and ethanolamine glycerophospholipids, whereas more [1-(14)C]20:4n-6 was targeted to the phosphatidylinositol (PtdIns) pool. H-FABP gene ablation significantly increased PtdIns mass 1.4-fold but reduced PtdIns 20:4n-6 mass 30%. Consistent with a reported effect of FABP on plasmalogen mass, ethanolamine plasmalogen mass was reduced 30% in gene-ablated mice. Further, 20:4n-6 mass was reduced in each of the three other major phospholipid classes, suggesting H-FABP has a role in maintaining steady-state 20:4n-6 mass in heart. In summary, H-FABP was important for heart fatty acid uptake and targeting of fatty acids to specific heart lipid pools as well as for maintenance of phospholipid pool mass and acyl chain composition.