Purification and properties of the very high density lipoprotein from the hemolymph of adult Triatoma infestans

The very high density lipoprotein (VHDL) of Triatoma infestans hemolymph from adult males has been isolated and purified by two-step density gradient ultracentrifugation. It appears to be homogeneous as judged by native polyacrylamide gel electrophoresis. The content of VHDL in hemolymph was estimated to be 8 mg protein/ml. The purified protein has a molecular weight (Mr) of 450,000, is composed of six subunits of Mr approximately equal to 77,000, and possesses a high content of aromatic amino acids. This protein is glycosylated and contains 3% of lipids by weight with a remarkable amount of free fatty acids (25% of total lipids). The T. infestans VHDL has a different lipid and amino acid composition from lipophorin. The lipid composition and the spectroscopic studies using cis-parinaric acid indicated a high fatty acid binding affinity. It has nine binding sites per mol of VHDL. Competence studies revealed that VHDL has its highest affinity for the binding of palmitic acid followed by stearic and arachidonic acids.     

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.     

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.     

Binding of bile acids, organic anions, and fatty acids by bovine intestinal Z protein.

Z protein from bovine small intestinal mucosa was purified and its binding affinities for bile acids, organic anions, and fatty acids were compared with those of bovine hepatic Z protein. Purification of Z protein from intestinal and hepatic cytosol was performed by gel filtration, chromatofocusing, and hydroxyapatite chromatography. Both purified proteins had the same molecular weight (Mr 14,000) and eluted from a chromatofocused gel at about pH 10. Binding studies were performed by the competitive displacement of 8-anilinonaphthalene-1-sulfonic acid and by equilibrium dialysis. Binding affinities for bile acids, organic anions, and fatty acids were very similar between intestinal and hepatic Z proteins. Although the real physiologic role of Z protein remains to be further elucidated, these data indicate that intestinal Z protein participates in the mechanism of intracellular bile acid transfer in enterocytes.     

Purification and initial characterization of the 71-kilodalton rat heat-shock protein and its cognate as fatty acid binding proteins

The major rat heat-shock (stress) protein and its cognate were purified to electrophoretic homogeneity from livers of heat-shocked rats. Both proteins exhibited similar behavior on a variety of column chromatography matrices but were separable by preparative isoelectric focusing under nondenaturing conditions by virtue of a 0.2 pH unit difference in isoelectric point. Both purified proteins had similar physical properties, suggesting the possibility that they may have similar biological functions as well. Both proteins were homodimers under nondissociative conditions (Mr 150 000) with isoelectric points of 5.0 (cognate) and 5.2 (major stress protein). After denaturation, both proteins had an increase in isoelectric point of 0.6 pH unit, and the resulting polypeptide chains had apparent molecular weights of 73 000 (cognate) and 71 000 (major stress protein). Similarities in the electrophoretic properties of these two proteins and serum albumin, which also undergoes a large basic shift in isoelectric point due to loss of fatty acids and conformational changes accompanying denaturation, prompted us to search for lipids associated with the purified 71-kilodalton stress protein and its cognate. Thin-layer chromatography of chloroform/methanol extracts of these two proteins revealed nonesterified fatty acids bound to both proteins. Palmitic acid, stearic acid, and a small amount of myristic acid were identified by gas chromatography/mass spectroscopy. Both proteins contained approximately four molecules of fatty acid per dimer with palmitate and stearate present in a one to one molar ratio. Possible roles of the major stress protein and its cognate as fatty acid associated proteins in cellular responses to stress are discussed.     

Partial purification of molecular weight 12 000 fatty acid binding proteins from rat brain and their effect on synaptosomal Na+-dependent amino acid uptake

High-affinity, Na+-dependent synaptosomal amino acid uptake systems are strongly stimulated by proteins which are known to bind fatty acids, including the Mr 12 000 fatty acid binding protein (FABP) from liver. To explore the possibility that such a function might be served by fatty acid binding proteins intrinsic to brain, we examined the 105000g supernatant of brain for fatty acid binding. Observed binding was accounted for mainly by components excluded by Sephadex G-50, and to a small degree by the Mr 12 000 protein fraction (brain FABP fraction). The partially purified brain FABP fraction contained a protein immunologically identical with liver FABP as well as a FABP electrophoretically distinct from liver FABP. Brain FABP fraction markedly stimulated synaptosomal Na+-dependent, but not Na+-independent, amino acid uptake, and also completely reversed the inhibition of synaptosomal Na+-dependent amino acid uptake induced by oleic acid. Palmitic, stearic, and oleic acids were endogenously associated with the brain FABP fraction. These data are consistent with the hypothesis that Mr 12 000 soluble FABPs intrinsic to brain may act as regulators of synaptosomal Na+-dependent amino acid uptake by sequestering free fatty acids which inhibit this process.     

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.     

Purification, properties, and immunological characterization of folate-binding proteins from human leukemia cells

A new matrix for affinity chromatography using pteroylglutamic acid coupled to an epoxy-activated matrix via hexanediamine resulted in negligible ligand leakage and permitted the purification of soluble and membrane-associated folate-binding proteins from human leukemia cells contained in a human spleen. Two species of membrane-associated folate-binding proteins were purified from the solubilized membrane fraction of the tissue using 2 M guanidine-HCl to elute the proteins from the affinity matrix. The higher molecular weight binding protein had an Mr of approximately 310,000 and the smaller species had an Mr of approximately 28,000 by gel filtration. By SDS-polyacrylamide gel electrophoresis the smaller species of membrane-associated protein had a molecular weight of 35,500, but the molecular weight of the larger membrane-associated species could not be determined by this method because of the high concentration of residual Triton X-100 in the sample which interfered with the silver staining of the gel. Two folate-binding proteins, which by SDS-polyacrylamide gel electrophoresis had molecular weights of 34,500 and 32,000, were purified from the 44,000 X g supernatant fraction of the tissue homogenate by acid elution from the affinity matrix. Despite the different cell components from which the soluble and membrane-associated folate-binding proteins were purified, the amino acid compositions were similar, especially with respect to the apolar amino acids. All these forms of folate-binding proteins had higher affinity for oxidized than for reduced folates, and very low affinity for 5-formyltetrahydrofolate and methotrexate. Although these proteins cross-react with one antiserum raised previously to a folate-binding protein from other human leukemia cells, they do not cross-react with the folate-binding proteins purified from two other sources of human leukemia cells, from human placenta, or from the human KB cell line.     

Newly identified bile acid binders in rat liver cytosol. Purification and comparison with glutathione S-transferases

Gel filtration of male rat liver cytosol preincubated with radiolabeled lithocholic, chenodeoxycholic, and glycochenodeoxycholic acids, and taurocholic acid revealed two major peaks of radioactivity, one co-eluting with the glutathione S-transferases and the other with a separate fraction, respectively. Chromatofocusing of the pooled fractions containing the new bile acid binding activity resulted in a separation of bile acid binding from the previously described organic anion binding activity in this fraction. Two binding peaks for lithocholic acid (pI 5.6, Binder I, and pI 5.5, Binder II) were identified on chromatofocusing and were further purified to apparent homogeneity by hydroxyapatite chromatography. The two Binders were monomers having identical molecular weight (33,000) and similar amino acid compositions. Bile acid binding to purified Binders I and II and glutathione S-transferases A, B, and C was studied by inhibition of the fluorescence of bound 1-anilino-8-naphthalenesulfonate (ANS). Confirmatory experiments using equilibrium dialysis produced comparable results. Glutathione S-transferase B had greater affinity for bile acids than transferases A or C. Binder II, which had greater affinity than Binder I for most bile acids, had greater affinity for chenodeoxycholic acid than transferase B but comparable or lower affinities for the other bile acids. All bile acids studied diminished ANS fluorescence with Binder II. Taurocholic and cholic acids increased ANS fluorescence with Binder I without affecting KANS, whereas lithocholic and chenodeoxycholic acids diminished ANS fluorescence with Binder I. In summary, we have identified and isolated two proteins (Binders I and II) which, along with glutathione S-transferase B, are the major hepatic cytosol bile acid binding proteins; these proteins have overlapping but distinct specificities for various bile acids.     

The membrane fatty acid-binding protein is not identical to mitochondrial glutamic oxaloacetic transaminase (mGOT)

Summary For evaluation whether the membrane fatty acid-binding protein is related to mGOT, studies on the structure and function of both purified proteins were performed. Physicochemical characterization revealed that both proteins are different: the membrane fatty acid-binding protein has a molecular weight of 40 kD and a pI of 8.5–9.0, whereas rat mGOT has a molecular weight of 44 kD and a pI of 9.5–10.0. According to this distinct differences, they migrated separately on 2-dimensional electrophoresis. Furthermore, monospecific antibodies against the membrane fatty acid binding protein did not react with rat mGOT. In co-chromatography studies only the membrane fatty acid-binding protein showed affinity for long chain fatty acids, but not mGOT. Moreover, membrane binding studies were performed with the monospecific antibody to the membrane fatty acid binding protein. The inhibitory effect of this antibody on plasma membrane binding of oleate was reversed after preabsorption of the antibody with the membrane fatty acid binding protein, but was not affected after preabsorption with mGOT. These results indicate that the membrane fatty acid binding protein and mGOT are structurally and functionally not related. The data also support the significance of this membrane protein in the plasma membrane binding process of long chain fatty acids.     

Isolation and characterization of the three fractions (DE-I, DE-II and DE-III) of rat-liver Z-protein and the complete primary structure of DE-II

Three fractions (DE-I, DE-II and DE-III) of Z-protein (fatty acid binding protein) have been isolated from rat liver cytosol by DEAE-cellulose chromatography and characterized. They had the same molecular weight of 14000 and essentially identical amino acid composition. However, compositions of endogenous fatty acids were found to differ strikingly from one another. Long-chain fatty acids detected in DE-II were palmitic, stearic, oleic, linoleic and arachidonic acids. In contrast to DE-II, DE-III contained mainly arachidonic acid. Molar ratios of endogenous long-chain fatty acids to both DE-II and DE-III were estimated to be around 1.0. Unlike the latter two fractions, DE-I was virtually lipid-free. Analyses of the three fractions by polyacrylamide gel electrophoresis, electrofocusing and DEAE-cellulose chromatography before and after delipidation suggested that the difference between DE-I and DE-II was in part due to fatty acids bound to DE-II. In contrast, DE-III appeared to be somewhat different from these forms in its protein structure, though tryptic peptide mappings of the three fractions did not reveal clear differences among them. Analysis of the primary structure was made on the most abundant fraction, DE-II, to investigate the relationship among the three fractions and to other proteins. The protein was a single chain consisting of 127 amino acid residues and had a mostly acetylated NH2 terminus and a free sulfhydryl group. The complete sequence of Z-protein showed striking homology to cellular retinoid binding proteins and peripheral nerve myelin P2 protein, which indicated the presence of a new family of cellular lipid-binding proteins diverged from a common ancestor. A possible intragenic duplication of Z-protein was also suggested.     

Bovine serum albumin. Study of the fatty acid and steroid binding sites using spin-labeled lipids.

Three spin-labeled derivatives of stearic acid and two derivatives of palmitic acid have been used to study the structure of the strong fatty acid binding site of bovine serum albumin. The steroid and indole binding sites have been studied using spin-labeled derivatives of androstol and indole, respectively. Paramagnetic resonance and fluorescence quenching data suggest that the fatty acid, steroid, and indole binding sites may be identical. The mobility of the nitroxyl group at C-8 of palmitic acid bound to albumin at a 1:1 molar ratio is unaffected when the carboxyl group is esterified. When the nitroxyl group is located at C-5 on this acid its motion is detectably increased by esterification of the carboxyl group but the magnitude of this change is small. This result suggests that the carboxyl group may play a minor role in the binding of fatty acids to the strongest fatty acid binding site of albumin. When stearic acid derivatives bearing the nitroxide at C-5, C-12, and C-16 are bound to albumin at a ligand to albumin ratio of 1, the order of mobility at 0-30 degrees is C-16 greater than C-12 congruent to C-5. Although motion at the methyl terminus is always greater than at the COOH terminus in the range 0-60 degrees, a simple monotonic increase in chain motion between the two termini is not observed. Arrhenius plots of the motion parameters for these bound fatty acids show two abrupt changes in slope. The temperature ranges for these changes are 15-23 degrees and 38-45 degrees. These results suggest that when one mole of spin-labeled fatty acid is bound to albumin, the protein undergoes a conformational change in each of these temperature ranges.     

Amino acid sequence and some ligand binding properties of fatty acid-binding protein from bovine brain

Summary A fatty acid-binding protein (FABP) from the cytosol of bovine brain was purified by Sephadex G-75 filtration and electrofocusing. The purified protein migrated as a single protein band in 15% polyacrylamide gel electrophoresis with an apparent molecular mass of 14.7 kDa. To ascertain that the purified protein was a FABP, it was submitted to fatty acid-binding tests. Oleic and palmitic acids bound to brain FABP but this was not the case for palmitoyl CoA. By Scatchard analysis the ligand binding values were: Kd = 0.28 µM, Bmax (mol/mol) = 0.6 for oleic acid and Kd = 0.8 µM, Bmax (mol/mol) = 2.1 for palmitic acid. The complete amino acid sequence of the brain FABP was determined and a microheterogeneity was observed. Sequence comparison with other FABPs of known sequence and the observed microheterogeneity demonstrated the presence in brain of several homologous FABPs closely related to heart FABP.This paper corresponds to a communication at the first international workshop on fatty acid binding proteins (Maastricht, the Netherlands, September 4–5, 1989).     

Characterization and binding properties of human fetal lung fatty acid-binding proteins

When delipidated Mr>10,000 cut-off human fetal lung cytosol was separated on gel filtration and ion-exchange chromatography on Auto-FPLC system, two fatty acid-binding proteins (FABPs) of pI 6.9 and pI 5.4 were purified to homogeneity. On Western blotting analysis with the anti-human fetal lung pI 6.9 FABP, these two proteins showed immunochemical cross reactivity with each other and with purified hepatic FABPs but not with cardiac or gut FABP. These two FABPs have identical molecular mass of 15.2 kDa, which is slightly higher than that of the hepatic proteins (14.2 kDa). Carbohydrate covalently linked to FABPs, that may substantially add to the molecular mass, was not detected in the purified protein preparations. Amino acid analysis revealed that both the proteins have same amino acid composition each containing one Trp residue that is lacking in hepatic FABP. Different isoforms of lung FABP exhibited different binding ability for their natural ligands. These proteins bind palmitoyl CoA with higher affinity than oleic acid. pI 6.9 FABP can more rapidly and efficiently transfer fatty acid than can pI 5.4 FABP from unilammelar liposomes. Thus these FABPs may play a critical role in fatty acid transport during human fetal lung development.Abbreviations AO anthroyloxy - 12-AS 12-(9-anthroyloxy)stearic acid - FABP fatty acid-binding protein - NBD-PE [N-(4-nitrobenzo-2-oxa-1,3-diazole)phosphatidylethanolamine - Pal-CoA palmitoyl coenzyme A - PITC phenylisothiocyanate - PBS phosphate-buffered saline - PtdCho phosphatidylcholine - SUV small unilamellar vesicle - Tris tris(hydroxymethyl) amino methane     

Natural ligand binding and transfer from liver fatty acid binding protein (LFABP) to membranes

Liver fatty acid-binding protein (LFABP) is distinctive among fatty acid-binding proteins because it binds more than one molecule of long-chain fatty acid and a variety of diverse ligands. Also, the transfer of fluorescent fatty acid analogues to model membranes under physiological ionic strength follows a different mechanism compared to most of the members of this family of intracellular lipid binding proteins. Tryptophan insertion mutants sensitive to ligand binding have allowed us to directly measure the binding affinity, ligand partitioning and transfer to model membranes of natural ligands. Binding of fatty acids shows a cooperative mechanism, while acyl-CoAs binding presents a hyperbolic behavior. Saturated fatty acids seem to have a stronger partition to protein vs. membranes, compared to unsaturated fatty acids. Natural ligand transfer rates are more than 200-fold higher compared to fluorescently-labeled analogues. Interestingly, oleoyl-CoA presents a markedly different transfer behavior compared to the rest of the ligands tested, probably indicating the possibility of specific targeting of ligands to different metabolic fates.     

Molecular simulations of β‐lactoglobulin complexed with fatty acids reveal the structural basis of ligand affinity to internal and possible external binding sites

The interaction of saturated fatty acids of different length (C8:0 to C18:0) with β‐lactoglobulin (βLG) was investigated by molecular dynamics simulation and docking approaches. The results show that the presence of such ligands in the hydrophobic central cavity of βLG, known as the protein calyx, determines an enhancement of atomic fluctuations compared with the unliganded form, especially for loops at the entrance of the binding site. Concerted motions are evidenced for protein regions that could favor the binding of ligands. The mechanism of anchoring of fatty acids of different length is similar for the carboxylate head‐group, through electrostatic interactions with the side chains of Lys60/Lys69. The key protein residues to secure the hydrocarbon chain are Phe105/Met107, which adapt their conformation upon ligand binding. In particular, Phe105 provides an additional hydrophobic clamp only for the tail of the two fatty acids with the longest chains, palmitic, and stearic acid, which are known to bind βLG with a high affinity. The search of additional external binding sites for fatty acids, distinct from the calyx, was also carried out for palmitic acid. Two external sites with a lower affinity were identified as secondary sites, one consisting in a hydrophobic cavity allowing two distinct binding modes for the fatty acid, and the other corresponding to a surface crevice close to the protein α‐helix. The overall results provide a comprehensive picture of the dynamical behavior of βLG in complex with fatty acids, and elucidate the structural basis of the binding of these physiological ligands. Proteins 2014; 82:2609–2619. © 2014 Wiley Periodicals, Inc.     

Structure-based ligand binding sites of protein p14.5, a member of protein family YER057c/YIL051c/YjgF

Seventeen mutants with one, two or three amino acids substitutions of human protein p14.5, homologue to well-known tumor antigen from goat liver UK114 and a member of proteins YER057c/YIL051c/YjgF family, have been used for structure-functional relation studies and ligand binding analysis using cross-linking by triacryloyl-hexahydro-s-triazine (TAT), size exclusion chromatography, free fatty acid and 8-anilino-1-naphthalenesulfonic acid (ANS) binding assays. Amino acids having the most significant impact on the ligand binding activity have been determined: R107, N93, Y21 and F89. Arginine 107 has been identified as the most accessible amino acid in the cleft. Trimeric structure of protein p14.5 has been confirmed as being essential for stoichiometric small ligand binding activity and oligomeric structure of p14. Ligand binding activity may be related with the biological functions of these proteins, which still are not understood well.     

Interaction of rat liver microsomes containing saturated or unsaturated fatty acids with fatty acid binding protein: Peroxidation effect

In the studies described here rat liver microsomes containing labeled palmitic, stearic, oleic or linoleic acids were incubated with fatty acid binding protein (FABP) and the rate of removal of¹⁴C-labeled fatty acids from the membrane by the soluble protein was measured using a model system. More unsaturated than saturated fatty acids were removed from native liver microsomes incubated with similar amounts of FABP. Thein vitro peroxidation of microsomal membranes mediated by ascorbate-Fe⁺⁺, modified its fatty acid composition with a considerable decrease of the peroxidizability index. These changes in the microsomes facilitated the removal of oleic and linoeic acids by FABP, but the removal of palmitic and stearic acids was not modified. This effect is proposed to result from a perturbation of membrane structure following peroxidation with release of free fatty acids from susceptible domains.Abbreviations BSA bovine serum albumin - FABP fatty acid binding protein     

Identification of fatty acid molecules in a Fasciola hepatica immunoprophylactic fatty acid-binding protein

Fasciola hepatica adult flukes have a native protein complex denoted nFh12 and consisting of fatty acid binding proteins that comprise at least 8 isoforms. It is a potent immunogen because in several animal hosts it induces an early antibody response to F. hepatica infection. It is also a potent cross-protective immunogen because it induces a protective immune response in mice to challenge infection with Schistosoma mansoni cercariae. The gene encoding this protein has been cloned and sequenced. It produces a polypeptide of 132 amino acids with a predicted molecular mass of 14.7 kDa and is denoted rFh15. It also has a significant homology to a 14-kDa S. mansoni fatty acid binding protein (Sm14). In the present study, nFh12 was delipidated with charcoal treatment and then studied by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Additionally, a lipid analysis of nFh12 was undertaken using gas chromatography-mass spectrometry to demonstrate that the nFh12 protein complex is, in fact, a complex of fatty acid binding proteins. Five long-chain saturated and unsaturated fatty acids were detected. The most abundant were palmitic acid (38%), stearic acid (24%), and oleic acid (13%). These fatty acid molecules do not have covalent bonds attached to the protein molecule. Because both nFh12 and Sm14 protect mice against challenge infection with F. hepatica and S. mansoni, it is possible that they have common protective epitopes in which fatty acids could be involved. Further studies are in progress to determine the chemical nature of these potential common epitopes.     

Purification and characterization of a long chain, fatty-acid-binding protein supplying the mitochondrial beta-oxidative system in the heart.

A fatty-acid-binding protein with a molecular weight of approximately 12 000 was purified from rat heart and the binding investigated by electron spin resonance. The stearic acid bound to the protein was found to be transferred to the mitochondrial beta-oxidative system, suggesting a role as transcytoplasmic fatty acid carrier for this protein. For the first time a physiological cytoplasmic protein was used as a carrier supplying the mitochondrial beta-oxidative system. A new mechanism of action is proposed to explain the control exerted by this type of protein in some membrane-linked enzymatic processes.