Purification and characterization of fatty acid-binding protein from rat kidney

We detected the presence of a fatty acid-binding protein (FABP) in rat kidney cytosols. This protein was eluted and purified 9.3-fold by sequential gel filtration and anion-exchange chromatography. Homogeneity was shown by a single band on polyacrylamide gel with a molecular weight of about 15,500. It had an optimum binding pH of 7.4. The binding of palmitate to the protein was saturable. Examination of fatty acid binding revealed the presence of a single class of fatty acid-binding sites. The apparent dissociation constant was 1.0 microM and the maximal binding capacity was 48 nmol/mg of protein. This protein showed similar binding characteristics for palmitate, oleate, and arachidonate. Rabbit antibody to this cytosolic FABP gave a single precipitin line with the antigen and selectively inhibited [14C]palmitate binding to the protein.     

Characterization of a fatty acid-binding protein from rat heart

A fatty acid-binding protein has been isolated from rat heart and purified by gel filtration chromatography on Sephadex G-75 and anion-exchange chromatography on DE52. The circular dichroic spectrum of this protein was not affected by protein concentration, suggesting that it does not aggregate into multimers. Computer analyses of the circular dichroic spectrum predicted that rat heart fatty acid-binding protein contains approximately 22% alpha-helix, 45% beta-form and 33% unordered structure. Immunological studies showed that the fatty acid-binding proteins from rat heart and rat liver are immunochemically unrelated. The amino acid composition and partial amino acid sequence of the heart protein indicated that it is structurally related to, but distinct from, other fatty acid-binding proteins from liver, intestine, and 3T3 adipocytes. Using a binding assay which measures the transfer of fatty acids between donor liposomes and protein (Brecher, P., Saouaf, R., Sugarman, J. M., Eisenberg, D., and LaRosa, K. (1984) J. Biol. Chem. 259, 13395-13401), it was shown that both rat heart and liver fatty acid-binding proteins bind 2 mol of oleic acid or palmitic acid/mol of protein. The structural and functional relationship of rat heart fatty acid-binding protein to fatty acid-binding proteins from other tissues is discussed.     

Characterization and binding properties of fatty acid-binding proteins from human, pig, and rat heart

Fatty acid-binding proteins (FABPs) were isolated from the cytosols of hearts of man, pig, and rat by gel filtration and anion-exchange chromatography. The heart FABPs had a Mr of about 15,000 (pig, rat) and 15,500 (man); pI values were 5.2, 4.9, and 5.0 for human, pig, and rat heart, respectively. In contrast to liver FABPs, tryptophan was present in the heart FABPs. Binding characteristics for long-chain fatty acids determined with the radiochemical Lipidex assay were comparable for all three proteins. Heart FABPs also bind palmitoyl-CoA and -carnitine with an affinity comparable to that for palmitic acid. Other ligands investigated, heme, bilirubin, cholesterol, retinoids, and prostaglandins, could not compete with oleic acid for binding by human heart FABP. Binding parameters of FABP for oleic acid from multilamellar liposomes were comparable to those from the Lipidex binding assay. Immunological interspecies cross-reactivity with antisera against the heart FABPs was much higher between man and pig than between rat and man or pig. None of the antisera reacted with liver FABPs. The IgG fraction of anti-human heart FABP serum inhibited fatty acid binding to human heart FABP.     

Diurnal variation of cytosolic fatty acid-binding protein content and of palmitate oxidation in rat liver and heart

Delipidated proteins from albumin-free liver and heart cytosol obtained from rats sacrificed at the mid-dark or the mid-light phase of the light cycle were assayed for their palmitate-binding capacity. In both tissues a marked variation of this binding capacity was observed from about 3-4 nmol/mg of protein in the mid-light phase of the cycle to about 7-8 nmol/mg of protein in the mid-dark phase. Sephadex G-75 chromatography of the cytosolic proteins revealed that the palmitate binding could in all cases almost entirely be attributed to proteins of Mr = 12,000-14,000, suggesting that the observed diurnal variations are related to differences in the content of fatty acid-binding protein (FABP). In both rat liver and heart FABP represents about 4 (mid-light) to 8% (mid-dark) of the total soluble proteins. Cholestyramine feeding increased the FABP content of liver cytosol from rats sacrificed at the mid-light phase, but not in those sacrificed at the mid-dark phase, in such a way that the diurnal variation of the FABP content virtually disappeared. The palmitate oxidation capacity and citrate synthase activity also exhibited a concomitant diurnal periodicity in rat liver and, to a lesser extent, in rat heart. The results provide additional evidence for an important role of FABP in cellular fatty acid metabolism in both liver and heart and for the similarity of FABP with sterol carrier protein.     

Isolation and characterization of fatty acid-binding protein from rat brain

A fatty acid-binding protein has been identified and isolated from the cytosol fraction of rat brain. The fatty acid-binding protein was purified to homogeneity by gel filtration and preparative isoelectric focusing. The binding protein was different from Z protein from rat liver in its isoelectric point and immunological reactivity, in spite of its similar molecular weight of 12,000. Rabbit antibodies against rat liver Z protein were used to demonstrate that the fatty acid-binding proteins from rat liver and brain are immunologically unrelated, and that no Z protein is present in rat brain cytosol.     

Fatty acid-binding capacity of cytosolic proteins of various rat tissues: effect of postnatal development, starvation, sex, clofibrate feeding and light cycle

Fatty acid-binding capacity of dealbuminized, delipidated cytosolic proteins from rat tissues was studied with a radiochemical binding assay. Oleate-binding capacity ranges from 1.6 to 4.4 pmol/micrograms cytosolic protein in liver, heart, kidney, adrenal, brain, skeletal muscle and diaphragm. Differences in binding affinity indicate the presence of different fatty acid-binding proteins in these tissues. No change in fatty acid-binding protein content of heart and liver cytosol was observed during postnatal development up to 70 days. Starvation did not affect the fatty acid-binding capacity of heart cytosol, but increased the oleate-binding capacity in liver cytosol. Sex-related differences of binding by heart and liver cytosolic proteins were found with oleate, but not with palmitate. Fatty acid-binding capacity of liver and heart cytosol did not show marked diurnal variation. Clofibrate treatment had different effects on the oleate-binding capacity of cytosolic proteins: an increase in liver and kidney, no change in skeletal muscle and a decrease in heart. The results are discussed in relation to data concerning fatty acid oxidation.     

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.     

Presence of intestinal, liver and heart/adipocyte fatty-acid-binding protein types in the liver of a chimaera fish

Five fatty-acid-binding proteins from the liver of the elephant fish (Callorhynchus callorhynchus), a chimaera fish that belongs—together with the elasmobranchs—to the ancient chondrichthyes class were isolated and characterized. The purification procedures for these proteins involved gel filtration, anion-exchange chromatography, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis as a last step. They were submitted to “in gel” tryptic or cyanogen bromide digestion and the resulting peptides were separated by high performance liquid chromatography and then sequenced by Edman degradation. According to their partial amino acid sequences, one of them presents the highest identity with fatty-acid-binding proteins from human and catfish liver, another three with those from mammalian heart or adipose tissue and the fifth with the mammalian intestinal fatty-acid-binding protein. The presence of various members of this protein family, as now found in elephant fish and previously in catfish (Rhamdia sapo) liver, does not occur in mammalian liver which expresses only one a characteristic fatty-acid-binding protein.     

The interaction of albumin and fatty-acid-binding protein with membranes: oleic acid dissociation

Bovine serum albumin or fatty-acid-binding protein rapidly lose oleic acid when incubated in the presence of dimyristoyl lecithin liposomes. The phenomenon is dependent on vesicle concentration and no measurable quantities of protein are found associated with liposomes. Upon gel filtration on Sepharose CL-2B of incubated mixtures of microsomes containing [1-14C] oleic acid and albumin or fatty-acid-binding protein, association of fatty acid with the soluble proteins could be demonstrated. Both albumin and fatty-acid-binding protein stimulated the transfer of oleic acid from rat liver microsomes to egg lecithin liposomes. These results indicate that albumin is more effective in the binding of oleic acid than fatty-acid-binding protein, which allows a selective oleic acid dissociation during its interaction with membranes.     

The fatty acid-binding protein from human skeletal muscle

Fatty acid-binding protein (FABP) was isolated from human skeletal muscle by gel filtration and anion- and cation-exchange chromatography. The isolation procedure, however, with rat and pig skeletal muscle gave mostly inactive preparations. Rat muscle FABP preparations contained parvalbumin as a contaminant. FABP from human muscle had a Mr of about 15 kDa, a pI value of 5.2, and a Kd value with oleic acid of 0.50 microM. Skeletal muscle and heart FABPs and their antisera showed a strong cross-reactivity on Western blots and in enzyme-linked immunosorbent assays (ELISA). No cross-reactivity was observed with liver FABP and its antiserum. On the basis of amino acid composition, electrophoretic behavior, fatty acid binding, and immunochemical properties, human skeletal muscle FABP must be similar or closely related to human heart FABP. The FABP content determined by ELISA was comparable in various human muscles and cultured muscle cells, but lower than that in rat muscles.     

Isoelectric analysis of 3H-pargyline-labelled monoamine oxidase in rat and carp

1. After selective binding of [3H]pargyline to either monoamine oxidase (MAO) A or MAO B in the rat liver, MAO B alone in the rat brain and MAO in carp brain and liver, molecular weight and isoelectric points (pI) of these MAO were determined by sodium dodecyl sulphate (SDS)-polyacrylamide gel electrophoresis and isoelectric focusing and results obtained were compared. 2. For all tissues tested, SDS-polyacrylamide gel electrophoresis of [3H]pargyline-bound samples revealed a labelled protein band of an apparent mol. wt of 60,000 da. 3. Estimation of radioactivity of [3H]pargyline bound after isoelectric focusing revealed a single protein band with acidic pI values of about 5.5 for rat brain and liver MAO B. 4. Moreover, the pI values of about 7.5 were obtained for carp brain and liver MAO. This basic value was also found for MAO A in the rat liver MAO A.     

Retinoic acid-binding protein in rat tissue. Partial purification and comparison to rat tissue retinol-binding protein.

When the 100,000 X g supernatant fractions of several rat organs are incubated with all-trans-[3H]retinoic acid, a binding component for retinoic acid with a sedimentation coefficient of 2 S can be detected by sucrose gradient centrifugation. This tissue binding protein for retinoic acid is distinct from the tissue binding protein for retinol which has been previously described. The tissue retinoic acid-binding protein has been partially purified from rat testis and this partially purified protein would appear to have a molecular weight of 14,500 as determined by gel filtration and high binding specificity for all-trans-retinoic acid. Binding of [3H]retinoic acid is not diminished by a 200-fold molar excess of retinal, retinol, or oleic acid but is reduced by a 200-fold excess of unlabeled retinoic acid. Tissue retinoic acid-binding protein can be detected in extracts of brain, eye, ovary, testis, and uterus but is apparently absent in heart muscle, small intestine, kidney, liver, lung, gastrocnemious muscle, serum, and spleen. This distribution is different than that observed for the tissue retinol-binding protein. Tissue retinol-binding protein was also purified extensively from rat testis. The partially purified protein has an apparent molecular weight of 14,000 and high binding specificity for all-trans-[3H]retinol as only unlabeled all-trans-retinol but not retinal, retinoic acid, retinyl acetate, retinyl palmitate, or oleic acid could diminish binding of the 3H ligand under the conditions employed. The partially purified protein has a fluorescence excitation spectrum with lambda max at 350 nm. In contrast, the retinol-binding protein isolated from rat serum and described by others has a fluorescence excitation spectrum with lambda max at 334 nm and an apparent molecular weight of 19,000. When partially purified tissue retinol-binding protein is extracted with heptane, the heptane extract has a fluorescence excitation spectrum similar to that of all-trans-retinol.     

Comparison between muscle and liver enolases and their behavior during differentiation and growth.

1. Rabbit liver enolase (EC 4.2.1.11) was purified about 200-fold and the enzyme was distinguished from crystalline muscle enolase by column isoelectrofocusing. It was found that the pI of muscle enolase was at about pH 8.8 and the pI of liver enolase was at about pH 6.7. Liver enolase was more liable to heat than muscle enolase. Anti-muscle enolase antibody did not react with liver enolase in double diffusion and immunoprecipitation tests. No substantial difference seemed to exist between muscle and liver enolases in pH optima, kinetic constants, and gel filtration. 2. It was observed by electrofocusing that the pI of rat muscle enolase was pH 7.2 to 7.9 and that of liver enolase was about pH 5.9. The main component of muscle enolase was designated as type A enolase, and liver enolase as type B enolase. Type A enolase was present in skeletal muscle and heart muscle. Type B enolase was widely distributed and present in liver, kidney, spleen, brain, lung, small intestine, and heart muscle. More acidic isozyme than type B enolase coexisted in the brain, and more basic isozyme than type A enolase, coexisted in the small intestine. A prototype of enolase in the early stage of differentiation was found to be type B enolase and, as differentiation progressed, type B decreased in muscle, while type A increased. On the other hand, liver enolase was retained as type B during differentiation. The enolase in regenerating liver was the same as in normal liver.     

Displacement of sulphobromophthalein from albumin and fatty-acid-binding protein by oleic acid

The absorption of sulphobromophthalein changes upon addition of bovine serum albumin or fatty-acid-binding protein at pH 8.4. The sulphobromophthalein spectrum is changed most drastically after the addition of albumin than in the presence of fatty-acid-binding protein isolated from rat liver, suggesting as a first approximation that binding capacity of albumin is much higher than that of fatty-acid-binding protein. When both soluble proteins are saturated with oleic acid it is observed a decrease in the binding of sulphobromophthalein which suggests that the presence of fatty acids in those soluble proteins may affect the binding of other ligands.     

A novel role of fatty acid-binding protein as a vehicle of retinoids

Intracellular transport and storage of retinoids were shown to be conducted by fatty acid-binding protein (FABP). When rat liver cytosol was gel filtrated, retinyl palmitate-binding activity was mainly eluted in the fraction with a Mr. of around 14,000, in which both FABP and cellular retinol-binding protein (CRBP) co-existed. From the binding analysis of purified FABP and CRBP to retinyl palmitate, FABP was found to have a relatively high affinity (Kd = 1.4 X 10(-6) M) to retinyl palmitate, while binding of retinyl palmitate to CRBP was scarcely detectable. By using anti-FABP serum, it was shown that FABP was distributed in organs relating to absorption and storage of retinoids, such as jejunum, ileum, and liver. In liver, the protein was localized in the parenchymal cells and with particularly high concentration in the perisinusoidal cells, probably fat-storing cells.     

Purification and characterization of a binding protein related to the Z class of cytosolic proteins in guinea-pig liver cytosol (guinea-pig Z protein).

The purification and characterization of a low-molecular-mass binding protein from female guinea-pig liver cytosol is reported. Its molecular mass (14.4 kDa), amino acid composition, abundance and biological properties identify it as belonging to the Z class of liver cytosolic proteins [Levi, A.J., Gatmaitan, Z. & Arias, I.M. (1969) J. Clin. Invest. 48, 2956-2167]. Among the most important members of this class of proteins are the fatty-acid-binding proteins (FABPs) and the sterol carrier protein2 (SCP2). The guinea-pig Z protein (G-ZP) has some similarities in its amino acid composition and NH2-terminal sequence with those of the rat liver FABP, but its isoelectric point is basic (pI 8.85), like that of SCP2. We also examined its binding affinities for a number of ligands bound by these two proteins. The results show that the purified G-ZP binds dehydroepiandrosterone sulfate, estrone sulfate, oleic acid and cholesterol, but shows no affinity for free steroids such as estrone and DHEA. Thus it can be said that G-ZP has some characteristics of FABPs and some of SCP2 but seems, however, to be different from both these proteins. The purified G-ZP inhibits microsomal DHEA sulfate sulfatase activity in a mixed noncompetitive way. This protein could be involved in the transport and/or metabolism of sulfated steroids.     

Cellular retinoic acid-binding protein from rat testis. Purification and characterization

Cellular retinoic acid-binding protein has been purified to homogeneity from rat testes. The procedures utilized in the purification included acid precipitation, gel filtration, and chromatography on DEAE-cellulose. The binding protein was purified approximately 12,000-fold, based on total soluble testicular protein. The protein is a single polypeptide chain with a molecular weight of 14,600, determined by information from gel filtration and sodium dodecyl sulfate-polyacrylamide electrophoresis. The protein binds retinoic acid with high affinity; the apparent dissociation constant was determined by fluorometric titration to be 4.2 X 10(-9) M.     

Cardiac fatty acid-binding proteins. Isolation and characterization of the mitochondrial fatty acid-binding protein and its structural relationship with the cytosolic isoforms

In the course of our studies on the structural diversity of the isoforms of cardiac fatty acid-binding proteins (cFABPs), a cardiac-type FABP from the matrix of bovine heart mitochondria was purified to homogeneity and obtained as a single 15-kDa protein with an isoelectric point of 4.9. The primary structures of this protein and of the two isoforms isolated from the cytosol (pI4.9-cFABP and pI 5.1-cFABP) were investigated by means of plasma desorption mass spectrometry and sequencing of peptides. All three proteins are amino-terminally blocked with an acetyl group and shown to be colinear with the sequence deduced from a cDNA clone for bovine heart fatty acid-binding protein (Billich, S., Wissel, T., Kratzin, H., Hahn, U., Hagenhoff, B., Lezius, A. G., and Spener, F. (1988) Eur. J. Biochem. 175, 549-556) except for the residue at position 98. This residue is demonstrated to be the molecular origin of bovine cFABP isoforms since pI 5.1-cFABP contains Asn98 in accordance with the sequence derived from the cDNA, whereas in pI 4.9-cFABP, this position is occupied by Asp98. Moreover, mitochondrial FABP is identical to pI 4.9-cFABP. Molecular masses of pI 4.9-cFABP (14,679 +/- 10 Da) and pI 5.1-cFABP (14,678 +/- 20 Da) determined by plasma desorption mass spectrometry coincide with that calculated from the cDNA (14,673 Da). Hence, residues linked to these proteins by posttranslational modification are not present, and the Asn-Asp exchange is the sole origin of heterogeneity of mitochondrial and cytosolic fatty acid-binding proteins from bovine heart.     

Fatty acid-binding protein from human heart localized in native and denaturing two-dimensional gels

Summary A group of low molecular weight fatty acid-binding cytosolic proteins, FABP_c with high abundance in heart, liver, skeletal muscle, intestine and adipose tissue, are anticipated to play a role in long-chain fatty acid metabolism in these tissues. Recently, a FABP_c with M_T 15 kDa has been purified from human heart muscle and found to be present in levels 2–4% of cytosolic proteins of human heart myocytes. In the present study two-dimensional gel electrophoresis under native and denaturing conditions has been used to characterize FABP_c from human heart and this protein is found to be a major protein of human heart myocytes. The pI of FABP_c from human heart was found to be about 5.3 under native conditions and about 6.5 in the presence of 9 M urea.     

Primary structure of a 15-kDa protein from rat intestinal epithelium. Sequence similarity to fatty-acid-binding proteins

An abundant and novel cytosolic protein was purified from the rat intestinal epithelium by gel filtration, ion-exchange and hydroxylapatite chromatography. The protein was eluted into two different positions (fractions 1 and 2) on DEAE-cellulose chromatography. We have completed the primary structure of the protein of fraction 1 by Edman degradation. The protein (144565 Da) contains 127 amino acid residues and has an acetylated alanine at its NH2-terminus. Comparison of the primary structure of the protein with porcine gastrotropin [Walz, A. D., Wider, M. D., Snow, J. W., Dass, C. & Desiderio, D. M. (1988) J. Biol. Chem. 263, 14189-14195] and rat hepatic fatty-acid-binding protein revealed that identical residues within these proteins are found in 90 and 54 out of a total of 127 positions, respectively. Bioactivity studies demonstrated that neither the protein nor liver and intestinal fatty-acid-binding proteins influence gastric acid secretory activity in rats with gastric fistulas compared to pentagastrin. The protein showed very low affinity for palmitic-acid-binding in vitro assay system and only trace amounts of endogenous fatty acids were detected from the protein. The protein, rat intestinal 15-kDa protein is considered to be a new member of the fatty-acid-binding protein family based on its structural features.