Selective binding of cholesterol by recombinant fatty acid binding proteins

The sterol binding specificity of rat recombinant liver fatty acid binding protein (L-FABP) and intestinal fatty acid binding protein (I-FABP) was characterized with [3H]cholesterol and a fluorescent sterol analog dehydroergosterol. Ligand binding analysis, fluorescence spectroscopy, and activation of microsomal acyl-CoA:cholesterol acyltransferase activity showed that L-FABP-bound sterols. 1) Lipidex-1000 assay showed a dissociation constant Kd = 0.78 +/- 0.18 microM and stoichiometry of 0.47 +/- 0.16 mol/mol for [3H]cholesterol binding to L-PABP. 2) With [3H]cholesterol/phosphatidylcholine liposomes, the cholesterol binding parameters for L-FABP were Kd = 1.53 +/- 0.28 microM and stoichiometry 0.83 +/- 0.07 mol/mol. 3) L-FABP interaction with dehydroergosterol altered the fluorescence intensity and polarization of dehydroergosterol. Dehydroergosterol bound to L-FABP with Kd = 0.37 microM and a stoichiometry of 0.83 mol/mol. 4) Cholesterol and dehydroergosterol decreased L-FABP tyrosine lifetime. Dehydroergosterol binding produced sensitized emission of bound dehydroergosterol with longer lifetime.5) L-FABP bound two cis-parinaric acid molecules/molecule of protein. Cholesterol displaced one of these bound cis-parinaric acids. 6) L-FABP enhanced acyl-CoA:cholesterol acyltransferase in a concentration-dependent manner. In contrast, these assays indicated that I-FABP did not bind sterols. Thus, L-FABP appears able to bind 1 mol of cholesterol/mol of L-FABP, the L-FABP sterol binding site is equivalent to one of the two fatty acid binding sites, and L-FABP stimulates acyl-CoA:cholesterol acyltransferase by transfer of cholesterol.     

Interaction of fatty acids with recombinant rat intestinal and liver fatty acid-binding proteins

Intestinal enterocytes contain two homologous fatty acid-binding proteins, intestinal fatty acid-binding protein (I-FABP)2 and liver fatty acid-binding protein (L-FABP). Since the functional basis for this multiplicity is not known, the fatty acid-binding specificity of recombinant forms of both rat I-FABP and rat L-FABP was examined. A systematic comparative analysis of the 18 carbon chain length fatty acid binding parameters, using both radiolabeled (stearic, oleic, and linoleic) and fluorescent (trans-parinaric and cis-parinaric) fatty acids, was undertaken. Results obtained with a classical Lipidex-1000 binding assay, which requires separation of bound from free fatty acid, were confirmed with a fluorescent fatty acid-binding assay not requiring separation of bound and unbound ligand. Depending on the nature of the fatty acid ligand, I-FABP bound fatty acid had dissociation constants between 0.2 and 3.1 microM and a consistent 1:1 molar ratio. The dissociation constants for L-FABP bound fatty acids ranged between 0.9 and 2.6 microM and the protein bound up to 2 mol fatty acid per mole of protein. Both fatty acid-binding proteins exhibited relatively higher affinity for unsaturated fatty acids as compared to saturated fatty acids of the same chain length. cis-Parinaric acid or trans-parinaric acid (each containing four double bonds) bound to L-FABP and I-FABP were displaced in a competitive manner by non-fluorescent fatty acid. Hill plots of the binding of cis- and trans- parinaric acid to L-FABP showed that the binding affinities of the two sites were very similar and did not exhibit cooperativity. The lack of fluorescence self-quenching upon binding 2 mol of either trans- or cis-parinaric acid/mol L-FABP is consistent with the presence of two binding sites with dissimilar orientation in the L-FABP. Thus, the difference in binding capacity between I-FABP and L-FABP predicts a structurally different binding site or sites.     

Involvement of arginine in the binding of heme and fatty acids to fatty acid-binding protein from bovine liver

Fatty acid-binding protein from bovine liver but not from bovine heart binds hematin in a saturable manner with high affinity. This property is not confined to a particular isoform as both, pI 6.0- and pI 7.0 L-FABP, bind hematin similarly. In competition experiments hematin and oleic acid could replace each other demonstrating that they share at least parts of the same binding site. Common structural features, i.e. the presence of carboxylic groups and of hydrophobic carbon chains led to the hypothesis that both ligands interact similarly with L-FABP. This was supported by the decrease of binding affinity for either ligand upon modification with phenylglyoxal. Modification in the presence of fatty acid revealed the protection of one of the two arginines of L-FABP. By peptide mapping and Edman degradation Arg¹²² was identified as the counterpart of the fatty acids carboxylic group.     

Polyene fatty acid interactions with recombinant intestinal and liver fatty acid-binding proteins. Spectroscopic studies

Binding and proximity relationships of fatty acids with recombinant rat liver fatty acid-binding protein (L-FABP) and intestinal fatty acid-binding protein (I-FABP) were studied with absorption and fluorescence spectroscopy. Protein aromatic amino acids were examined in the absence and presence of bound fatty acid. Second derivative absorbance spectroscopy of the apo- and holoproteins suggested that fatty acid binding altered the conformation of L-FABP, but not of I-FABP. Fatty acid binding also blocked the accessibility of L-FABP tyrosine and I-FABP tryptophan to Stern-Volmer quenching by acrylamide, indicating that these amino acids were present in the fatty acid-binding pocket. Forster energy transfer from I-FABP tryptophan to bound cis-parinaric acid resulted in quenching of tryptophan lifetime and appearance of sensitized lifetime of bound cis-parinaric acid. The calculated donor-acceptor distances were 16.9 +/- 0.6 and 19.2 +/- 0.3 A for I-FABP and L-FABP, respectively. Absorbance spectral shifts and ratios of fluorescence excitation maxima indicated that the parinaric acid microenvironment in the fatty acid-binding site of I-FABP was much less polar than that of L-FABP. Parinaric acids displayed similar rotational correlation time and limiting anisotropy when bound to I-FABP and to L-FABP. These results are consistent with a close proximity of bound fatty acids to the tyrosine and tryptophan residues and with immobilization of the polyene fatty acids in the fatty acid-binding site(s) of L-FABP and I-FABP. The two proteins differ in that only L-FABP has two fatty acid-binding sites and appears to undergo significant conformational change upon fatty acid binding.     

Decreased liver fatty acid binding capacity and altered liver lipid distribution in mice lacking the liver fatty acid-binding protein gene

Although liver fatty acid-binding protein (L-FABP) is an important binding site for various hydrophobic ligands in hepatocytes, its in vivo significance is not understood. We have therefore created L-FABP null mice and report here their initial analysis, focusing on the impact of this mutation on hepatic fatty acid binding capacity, lipid composition, and expression of other lipid-binding proteins. Gel-filtered cytosol from L-FABP null liver lacked the main fatty acid binding peak in the fraction that normally comprises both L-FABP and sterol carrier protein-2 (SCP-2). The binding capacity for cis-parinaric acid was decreased >80% in this region. Molar ratios of cholesterol/cholesterol ester, cholesteryl ester/triglyceride, and cholesterol/phospholipid were 2- to 3-fold greater, reflecting up to 3-fold absolute increases in specific lipid classes in the order cholesterol > cholesterol esters > phospholipids. In contrast, the liver pool sizes of nonesterified fatty acids and triglycerides were not altered. However, hepatic deposition of a bolus of intravenously injected [14C]oleate was markedly reduced, showing altered lipid pool turnover. An increase of approximately 75% of soluble SCP-2 but little or no change of other soluble (glutathione S-transferase, albumin) and membrane (fatty acid transport protein, CD36, aspartate aminotransferase, caveolin) fatty acid transporters was measured. These results (i) provide for the first time a quantitative assessment of the contribution of L-FABP to cytosolic fatty acid binding capacity, (ii) establish L-FABP as an important determinant of hepatic lipid composition and turnover, and (iii) suggest that SCP-2 contributes to the accumulation of cholesterol in L-FABP null liver.     

Identification of two lipid binding proteins from liver of Gallus domesticus

1. Two low molecular weight (approximately 14,000 Da) proteins exhibiting lipid binding activity were purified from liver cytosol and identified as non-specific lipid binding protein (ns-LTP) and fatty acid binding protein (L-FABP). 2. Ligand binding assays indicated that ns-LTP exhibited greater binding activity for cholesterol and little binding of fatty acids. Conversely, L-FABP had higher relative binding activity for fatty acids but did not bind cholesterol. 3. Amino acid composition and pI data supported the identification of the chicken liver lipid binding proteins as L-FABP and ns-LTP. 4. Polyclonal antisera was prepared against each of the liver lipid binding proteins and monospecificity verified using Western blot analysis.     

Expression of rat intestinal fatty acid-binding protein in Escherichia coli. Purification and comparison of ligand binding characteristics with that of Escherichia coli-derived rat liver fatty acid-binding protein

Rat intestinal fatty acid-binding protein (I-FABP) is an abundant, 15,124-Da polypeptide found in the cytosol of small intestinal epithelial cells (enterocytes). It is homologous to rat liver fatty acid-binding protein (L-FABP), a 14,273-Da cytosolic protein which is found in enterocytes as well as hepatocytes. It is unclear why the small intestinal epithelium contains two abundant fatty acid-binding proteins. A systematic comparative analysis of the ligand binding characteristics of the two FABPs has not been reported. To undertake such a study we expressed the coding region of a full length I-FABP cDNA in Escherichia coli and purified large quantities of the protein. We also purified rat L-FABP from a similar, previously described expression system (Lowe, J. B., Strauss, A. W., and Gordon, J. I. (1984) J. Biol. Chem. 259, 12696-12704). Analysis of fatty acids associated with each of the homogeneous E. coli-derived FABPs suggested that the two proteins differed in their ligand binding specificity and capacity. All of the fatty acids associated with I-FABP were saturated while 30% of the E. coli fatty acids bound to L-FABP were unsaturated (16:1, 18:1, 18:2). We directly analyzed the ability of I- and L-FABP to bind fatty acids of different chain length and degree of saturation using a hydroxyalkoxypropyl dextran-based assay. Scatchard analysis revealed that each mole of L-FABP can bind up to 2 mol of long chain fatty acid while each mole of I-FABP can bind only 1 mole of fatty acid. L-FABP exhibited a relatively higher affinity for unsaturated fatty acids (oleate, arachidonate) than for saturated fatty acid (palmitate). By contrast, we were not able to detect a significant difference in the affinity of I-FABP for palmitate, oleate, and arachidonate. Neither protein exhibited any appreciable affinity for fatty acids whose chain length was less than C16. The observed differences in ligand affinities and capacities suggest that these proteins may have distinct roles in metabolism and/or compartmentalization of fatty acids within enterocytes.     

Specific high affinity binding of lipoxygenase metabolites of arachidonic acid by liver fatty acid binding protein

Liver fatty acid binding protein (L-FABP) binds avidly the arachidonic acid metabolites, hydroperoxyeicosatetraenoic acids (HPETEs) and hydroxyeicosatetraenoic acids (HETEs). Binding of 15-[3H]HPETE was specific, saturable, reversible, and rapid. Protein specificity was indicated by the following order: L-FABP greater than bovine serum albumin greater than ovalbumin = beta-lactoglobulin greater than ribonuclease. Ligand specificity was evidenced by the following order of apparent competition: 15-HPETE greater than or equal to 5-HETE greater than or equal to 5-HPETE = oleic acid greater than 12-HETE greater than 12-HPETE greater than or equal to 15-HETE greater than prostaglandin E1 much greater than leukotriene C4 greater than prostaglandin E2 much greater than thromboxane B2 = leukotriene B4. Once bound, 15-HPETE was reversibly displaced. Ligand was recovered from the protein complex and confirmed to be 15-[3H]HPETE by TLC. L-FABP bound HPETE with a dissociation constant of 76 nM,5-HETE at 175 nM, and 15-HETE at 1.8 microM, and the reference fatty acids oleic acid at 1.2 microM and arachidonic acid at 1.7 microM. Thus, the affinity was approximately 16-fold greater for 15-HPETE, and 7-fold higher for 5-HETE, than for oleic acid. The need exists for studies of complexes of L-FABP with the HPETEs and HETEs in hepatocytes, especially since L-FABP has previously been associated with mitosis in normal hepatocytes, and shown to be the target protein of two liver carcinogens, and these arachidonic acid metabolites have been found to be able to modulate activities related to cell growth.     

An improved method for the purification of rat liver-type fatty acid binding protein from Escherichia coli

Rat liver fatty acid binding protein (L-FABP) was efficiently expressed in Escherichia coli and purified to homogeneity. The cDNA encoding L-FABP was ligated into the pTrc99A expression vector and expressed by induction with isopropyl-beta-d-thiogalactopyranoside under the control of the P(trc) promoter. Following an 18 h induction period, L-FABP constituted approximately 3% of the cytosolic protein. The protein could be purified to electrophoretic homogeneity (silver-stained polyacrylamide gel detection) by ammonium sulfate fractionation (65% saturation) of the soluble bacterial lysate followed by the chromatographic sequence of anion-exchange-->hydrophobic interaction-->anion-exchange chromatography. The recombinant protein displayed an isoelectric point of 7.0 and cross-reactivity with rabbit anti-(human L-FABP) polyclonal antibody. The ligand binding properties of the delipidated L-FABP were examined by titration with the fluorescent probe 1-anilino-8-naphthalene sulfonic acid and isothermal titration calorimetric analysis of oleic acid binding. The purified rat L-FABP displayed a binding stoichiometry of 2:1 (ANS:L-FABP) with dissociation constants (K(d)) of 1.7 and 15.5 microM for the high and low affinity binding sites, respectively. The K(d) values determined by ITC for oleic acid binding were 0.155 and 4.04 microM with a binding stoichiometry of approximately 2 mol of fatty acid/mol of protein. These physicochemical and binding properties are in agreement with those of L-FABP isolated from rat liver tissue.     

The binding affinity of fatty acid-binding proteins from human, pig and rat liver for different fluorescent fatty acids and other ligands

1. Two forms of fatty acid-binding proteins (FABPs) were isolated from human, pig and rat liver cytosols by gelfiltration and anion-exchange chromatography. 2. Both forms did not show physicochemical or chemical differences. They had an Mr of about 14.5 kDa for all species. pI Values were 5.8 for both forms of human and pig liver FABP and 6.4 for both forms of rat liver FABP. In contrast to heart FABPs no tryptophan was present in liver FABPs. 3. Liver FABPs show a much higher enhancement of fluorescence at binding of 11-dansylaminoundecanoic acid, 16-anthroyloxy-palmitic acid and 1-pyrene-dodecanoic acid than heart FABPs and additionally a blue shift in excitation and emission wavelengths with the first fatty acid. 4. The bulky side-chain did not affect fatty acid binding since binding constants of liver FABPs were comparable for these fluorescent fatty acids and oleic acid (0.3-0.7 microM). 5. A 1:1 binding stoichiometry was obtained for oleic acid binding with heart and liver FABPs. 6. Liver FABPs have a high binding affinity for C16-C22 saturated and unsaturated fatty acids, palmitoyl-CoA, bromo-substituted fatty acids, POCA, tetradecylglycidic acid and flavaspidic acid. 7. Fatty acid binding could be reduced to less than 50% by arginine modification with 2,3-butadione or by enzymatic degradation of FABPs with trypsin or pronase.     

Comparisons of the effects of temperature on the liver fatty acid binding proteins from hibernator and nonhibernator mammals.

Hibernating mammals rely heavily on lipid metabolism to supply energy during hibernation. We wondered if the fatty acid binding protein from a hibernator responded to temperature differently than that from a nonhibernator. We found that the Kd for oleate of the liver fatty acid binding protein (1.5 microM) isolated from ground squirrel (Spermophilus richardsonii) was temperature insensitive over 5-37 degrees C, while the rat liver fatty acid binding protein was affected with the Kd at 37 degrees C being about half (0.8 microM) that found at lower temperatures. This same trend was observed when comparing the specificity of various fatty acids of differing chain length and degree of unsaturation for the two proteins at 5 and 37 degrees C. At the lower temperature, ground squirrel protein bound long-chain unsaturated fatty acids, particularly linoleate and linolenate, at least as well as at the higher temperature and matched requirements for these fatty acids in the diet. The most common long-chain fatty acid, palmitate, was a more effective ligand for ground squirrel liver fatty acid binding protein at 5 degrees C than at 37 degrees C, with the opposite occurring in the eutherm. Rat protein was clearly not adapted to function optimally at temperatures lower than the animal's body temperature.     

Induction of hepatic cytosolic fatty acid binding protein with clofibrate accelerates both membrane and cytoplasmic transport of palmitate

The role of liver cytosolic fatty acid binding protein (L-FABP) in fatty acid transport and metabolism is unclear. Female liver contains substantially more L-FABP than male liver. Female liver also has a different fatty acid transport phenotype, including more rapid uptake, efflux and cytoplasmic transport. However, it is not known if the greater levels of L-FABP are responsible for these differences. We therefore determined whether increasing L-FABP using clofibrate causes male liver to acquire a female transport phenotype. The multiple indicator dilution (MID) method was used to estimate the rate constants for influx, efflux and cytoplasmic diffusion of palmitate in isolated perfused rat livers. Clofibrate treatment increased cytosolic concentrations of L-FABP 4.2+/-0.8-fold, the rate of cytoplasmic diffusion of palmitate 4.3+/-1.7-fold, and the steady-state palmitate extraction 1.5+/-0.3-fold (mean+/-S.E.). Influx and efflux constants were both increased (by 44% and 79%, respectively) to levels typical of female livers. These data suggest that clofibrate-induced elevation of cytosolic L-FABP not only stimulates intracellular diffusion but also influx and efflux of fatty acids. Possible mechanisms include reducing fatty acid binding to cytoplasmic membranes, induction of membrane fatty acid carriers, and catalyzing fatty acid exchange between aqueous cytoplasm and the plasma membrane.     

Ablation of the liver fatty acid binding protein gene decreases fatty acyl CoA binding capacity and alters fatty acyl CoA pool distribution in mouse liver

Although liver fatty acid binding protein (L-FABP) is known to bind not only long chain fatty acid (LCFA) but also long chain fatty acyl CoA (LCFA-CoA), the physiological significance of LCFA-CoA binding has been questioned and remains to be resolved. To address this issue, the effect of L-FABP gene ablation on liver cytosolic LCFA-CoA binding, LCFA-CoA pool size, LCFA-CoA esterification, and potential compensation by other intracellular LCFA-CoA binding proteins was examined. L-FABP gene ablation resulted not only in loss of L-FABP but also in concomitant upregulation of two other intracellular LCFA-CoA binding proteins, acyl CoA binding protein (ACBP) and sterol carrier protein-2 (SCP-2), by 45 and 80%, respectively. Nevertheless, the soluble fraction from livers of L-FABP (-/-) mice bound 95% less radioactive oleoyl-CoA than wild-type L-FABP (+/+) mice. The intracellular LCFA-CoA binding protein fraction (Fraction III) from wild-type L-FABP (+/+) mice, isolated by gel permeation chromatography of liver soluble proteins, exhibited one high-affinity binding and several low-affinity binding sites for cis-parinaroyl-CoA, a naturally occurring fluorescent LCFA-CoA. In contrast, high-affinity LCFA-CoA binding was absent from Fraction III of L-FABP (-/-) mice. While L-FABP gene ablation did not alter liver LCFA-CoA pool size, LCFA-CoA acyl chains of L-FABP (-/-) mouse livers were enriched 2.1-fold in C16:1 and decreased 1.9-fold in C20:0 fatty acids. Finally, L-FABP gene ablation selectively increased the amount of LCFAs esterified into liver phospholipid > cholesteryl ester, while concomitantly decreasing the amount of fatty acids esterified into triglycerides by 40%. In summary, these data with L-FABP (-/-) mice demonstrated for the first time that L-FABP is a physiologically significant contributor to determining liver cytosolic LCFA-CoA binding capacity, LCFA-CoA acyl chain distribution, and esterified fatty acid distribution.     

Enhanced expression of cytosolic fatty acid binding protein and fatty acid uptake during liver regeneration in rats

BACKGROUND/AIMS: Cytoplasmic liver fatty acid binding protein (L-FABP) has been suggested to be associated with cellular mitotic activity but the changes in L-FABP mRNA and protein levels during liver regeneration following partial hepatectomy (PHx) are not clear. METHODS: In the present study, we determined the time course of L-FABP mRNA expression and L-FABP levels following 70% PHx using Northern and Western blot, respectively. To elucidate one of the roles for L-FABP in PHx, [3H]-palmitic acid clearance in hepatocytes isolated from 24 h post-PHx and control animals was assessed. RESULTS: L-FABP mRNA increased at 30 min, peaked at approximately 1 h (163 +/- 17%; mean +/- SE, n = 5), and returned to control levels 6 h post-PHx. L-FABP level also increased at 1 h but peaked at 24-h (219 +/- 41%; mean +/- SE, n = 5). Hepatocyte [3H]-palmitic acid clearance increased by 29% at 24-h post-PHx, suggesting an increased intracellular transport (or binding) function by L-FABP. Pre-treatment with dexamethasone statistically reduced L-FABP levels (29%) and suppressed the regenerative process (mitotic activity). CONCLUSIONS: L-FABP mRNA increased sharply in response to PHx but the increase was short lived, while L-FABP level increased at a later stage. Both L-FABP content and fatty acid uptake increased significantly during liver regeneration induced by PHx in rats. It is likely that L-FABP is one of the factors responsible for hepatic regeneration.     

Very long chain n-3 and n-6 polyunsaturated fatty acids bind strongly to liver fatty acid-binding protein

Synthesis of n-3 and n-6 very long chain-PUFAs (VLC-PUFAs) from 18-carbon essential fatty acids is differentially regulated. The predominant product arising from n-3 fatty acids is docosahexaenoic acid (22:6n-3), with the liver serving as the main site of production. The synthetic pathway requires movement of a 24-carbon intermediate from the endoplasmic reticulum to peroxisomes for retroconversion to 22:6n-3. The mechanism of this intra-organelle flux is unknown, but could be binding-protein facilitated. We thus investigated binding of a series of previously untested VLC-PUFAs to liver fatty acid-binding protein (L-FABP). Three fluorometric assays were employed, all of which showed strong binding (K(d)' approximately 10(-8) to 10(-7) M) of 20-, 22-, and 24-carbon n-3 PUFAs to L-FABP. In contrast, synthesis of the predominant n-6 PUFA product, arachidonic acid, does not require intra-organelle transport. However, we found that n-6 VLC-PUFAs bound to L-FABP with affinities (K(d)' approximately 10(-8) to 10(-7) M) comparable to their n-3 counterparts.Although these results raise the possibility that L-FABP may participate in the cytoplasmic processing of n-3 and n-6 VLC-PUFAs, there is no evidence on the basis of binding affinities that L-FABP accounts for differences in the predominant products formed by the n-3 and n-6 PUFA metabolic pathways.     

Binding of bile acids by glutathione S-transferases from rat liver

Binding of bile acids and their sulfates and glucuronides by purified GSH S-transferases from rat liver was studied by 1-anilino-8-naphthalenesulfonate fluorescence inhibition, flow dialysis, and equilibrium dialysis. In addition, corticosterone and sulfobromophthalein (BSP) binding were studied by equilibrium and flow dialysis. Transferases YaYa and YaYc had comparable affinity for lithocholic (Kd approximately 0.2 microM), glycochenodeoxycholic (Kd approximately to 60 microM), and cholic acid (Kd approximately equal 60 microM), and BSP (Kd approximately 0.09 microM). YaYc had one and YaYa had two high affinity binding sites for these ligands. Transferases containing the Yb subunit had two binding sites for these bile acids, although binding affinity for lithocholic acid (Kd approximately 4 microM) was lower than that of transferases with Ya subunit, and binding affinities for the other bile acids were comparable to the Ya family. Sulfated bile acids were bound with higher affinity and glucuronidated bile acids with lower affinity by YaYa and YaYc than the respective parent bile acids. In the presence of GSH, binding of lithocholate by YaYc was unchanged and binding by YbYb' was inhibited. Conversely, GSH inhibited the binding of cholic acid by YaYc but had less effect on binding by YbYb'. Cholic acid did not inhibit the binding of lithocholic acid by YaYa.     

Microsomal fatty acyl-CoA transacylation and hydrolysis: fatty acyl-CoA species dependent modulation by liver fatty acyl-CoA binding proteins1

Liver and intestinal cytosol contain abundant levels of long chain fatty acyl-CoA binding proteins such as liver fatty acid binding protein (L-FABP) and acyl-CoA binding protein (ACBP). However, the relative function and specificity of these proteins in microsomal utilization of long chain fatty acyl-CoAs (LCFA-CoAs) for sequential transacylation of glycerol-3-phosphate to form phosphatidic acid is not known. The results showed for the first time that L-FABP and ACBP both stimulated microsomal incorporation of the monounsaturated oleoyl-CoA and polyunsaturated arachidonoyl-CoA 8–10-fold and 2–3-fold, respectively. In contrast, these proteins inhibited microsomal utilization of the saturated palmitoyl-CoA by 69% and 62%, respectively. These similar effects of L-FABP and ACBP on microsomal phosphatidic acid biosynthesis were mediated primarily through the activity of glycerol-3-phosphate acyltransferase (GPAT), the rate limiting step, rather than by protecting the long chain acyl-CoAs from microsomal hydrolase activity. In fact, ACBP but not L-FABP protected long chain fatty acyl-CoAs from microsomal acyl-CoA hydrolase activity in the order: palmitoyl-CoA>oleoyl-CoA>arachidonoyl-CoA. In summary, the data established for the first time a role for both L-FABP and ACBP in microsomal phosphatidic acid biosynthesis. By preferentially stimulating microsomal transacylation of unsaturated long chain fatty acyl-CoAs while concomitantly exerting their differential protection from microsomal acyl-CoA hydrolase, L-FABP and ACBP can uniquely function in modulating the pattern of fatty acids esterified to phosphatidic acid, the de novo precursor of phospholipids and triacylglycerols. This may explain in part the simultaneous presence of these proteins in cell types involved in fatty acid absorption and lipoprotein secretion.     

Liver fatty acid binding protein expression enhances branched-chain fatty acid metabolism

Although liver fatty acid binding protein (L-FABP) is known to enhance uptake and esterification of straight-chain fatty acids such as palmitic acid and oleic acid, its effects on oxidation and further metabolism of branched-chain fatty acids such as phytanic acid are not completely understood. The present data demonstrate for the first time that expression of L-FABP enhanced initial rate and average maximal oxidation of [2,3-3H] phytanic acid 3.5- and 1.5-fold, respectively. This enhancement was not due to increased [2,3-3H] phytanic acid uptake, which was only slightly stimulated (20%) in L-FABP expressing cells after 30 min. Similarly, L-FABP also enhanced the average maximal oxidation of [9,10-3H] palmitic acid 2.2-fold after incubation for 30 min. However, the stimulation of L-FABP on palmitic acid oxidation nearly paralleled its 3.3-fold enhancement of uptake. To determine effects of metabolism on fatty acid uptake, a non-metabolizable fluorescent saturated fatty acid, BODIPY-C16, was examined by laser scanning confocal microscopy (LSCM). L-FABP expression enhanced uptake of BODIPY-C16 1.7-fold demonstrating that L-FABP enhanced saturated fatty acid uptake independent of metabolism. Finally, L-FABP expression did not significantly alter [2,3-3H] phytanic acid esterification, but increased [9,10-3H] palmitic acid esterification 4.5-fold, primarily into phospholipids (3.7-fold) and neutral lipids (9-fold). In summary, L-FABP expression enhanced branched-chain phytanic acid oxidation much more than either its uptake or esterification. These data demonstrate a potential role for L-FABP in the peroxisomal oxidation of branched-chain fatty acids in intact cells.     

Ligand specificity and conformational stability of human fatty acid-binding proteins.

Fatty acid binding proteins (FABPs) are small cytosolic proteins with virtually identical backbone structures that facilitate the solubility and intracellular transport of fatty acids. At least eight different types of FABP occur, each with a specific tissue distribution and possibly with a distinct function. To define the functional characteristics of all eight human FABPs, viz. heart (H), brain (B), myelin (M), adipocyte (A), epidermal (E), intestinal (I), liver (L) and ileal lipid-binding protein (I-LBP), we studied their ligand specificity, their conformational stability and their immunological crossreactivity. Additionally, binding of bile acids to I-LBP was studied. The FABP types showed differences in fatty acid binding affinity. Generally, the affinity for palmitic acid was lower than for oleic and arachidonic acid. All FABP types, except E-FABP, I-FABP and I-LBP interacted with 1-anilinonaphtalene-8-sulphonic acid (ANS). Only L-FABP, I-FABP and M-FABP showed binding of 11-((5-dimethylaminonaphtalene-1-sulfonyl)amino)undecanoic acid (DAUDA). I-LBP showed increasing binding of bile acids in the order taurine-conjugated>glycine-conjugated>unconjugated bile acids. A hydroxylgroup of bile acids at position 7 decreased and at position 12 increased the binding affinity to I-LBP. The fatty acid-binding affinity and the conformation of FABP types were differentially affected in the presence of urea. Our results demonstrate significant differences in ligand binding, conformational stability and surface properties between different FABP types which may point to a specific function in certain cells and tissues. The preference of I-LBP (but not L-FABP) for conjugated bile acids is in accordance with a specific role in bile acid reabsorption in the ileum.     

Unsaturated fatty acids inhibit glucocorticoid receptor binding of trout hepatic cytosol.

1. The effect of free fatty acids [FFAs (saturated (S) and unsaturated (U))] on dexamethasone binding in vitro using liver cytosol from rainbow trout was examined. 2. All UFFAs but none of the SFFAs tested suppressed binding. This suppression is dose-dependent and correlated roughly with the degree of unsaturation of the FFAs. 3. Scatchard analysis indicated that the addition of linoleic C18:2 (150 microM) increased the dissociation constant (Kd = 5.1 +/- 0.4 x 10(-8) M vs control of 1.7 +/- 0.3 x 10(-8) M) but minimally affected the binding capacity (Bmax = 68 +/- 6.2 vs control of 88 +/- 15.2 fmol/mg protein) suggesting C18:2 caused a conformational change of the receptor. 4. Lineweaver-Burk plot revealed a mixed non-competitive type of inhibition by C18:2. 5. Free acid appeared to be required for inhibition as esterification or derivatization of the acid greatly diminished its potency. 6.C18:2 also promotes the dissociation of bound [3H]-dexamethasone from the steroid-receptor complex but slower in rate and lesser in magnitude compared to that caused by dexamethasone or the glucocorticoid antagonist RU 38486. 7. UFFAs and some of their derivatives can thus modulate glucocorticoid receptor function in vitro and might play essential roles in regulating glucocorticoid action in fish as well. 8. These fatty acids presumably acts at a site different from that of the glucocorticoid binding site.