Fatty acid-binding protein and its relation to fatty acid oxidation

A relation between fatty acid oxidation capacity and cytosolic FABP content was found in heart and various muscles of the rat. Other tissues do not show such a relation, since they are involved in more or other pathways of fatty acid metabolism. At postnatal development FABP content and fatty acid oxidation capacity rise concomitantly in heart and quadriceps muscle in contrast to in liver and kidney. A dietary fat content of 40 en. % increased only the FABP content of liver and adipose tissue. Peroxisomal proliferators increased fatty acid oxidation in both liver and kidney, but only the FABP content of liver, and had no effect on heart and skeletal muscle. The FABP content of muscle did not show adaptation to various conditions. Only it increased in fast-twitch muscles upon chronic electrostimulation and endurance training.     

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.     

Fatty acid binding proteins in the three types of rat skeletal muscle

By means of Sephadex G-50 column chromatography, a Mr 12,000 fatty acid binding protein (FABP) was found to be present in all three types of skeletal muscle. FABP concentrations in muscle cytosols (105,000g supernatant) were fiber type specific with binding levels (expressed as pmole [14C]oleate bound/mg protein) of 70 +/- 7 in fast-twitch white (FTW) (heart FABP = 469 +/- 33). Cytosols from all three fiber types cross-reacted with antibody to pure heart FABP on Ouchterlony immunodiffusion analysis. FABP content, determined by radial immunodiffusion, followed the same pattern in the muscle types as that in the binding assay. The values (in micrograms/mg protein) were 3.3 +/- 0.1 in FTW, 17.0 +/- 0.4 in FTR, and 31.7 +/- 1.4 in STR fibers (heart = 55). Disc gel electrophoresis revealed a protein band in each fiber type that had migration identical to that of pure heart FABP and was proportional to the amounts determined by Sephadex G-50 chromatography and immunoassay. In addition, Western blots of tissue cytosols, using antibody to heart FABP, detected single protein bands identical in size to pure heart FABP in all three types of skeletal muscle. These results show the presence of a FABP in all skeletal muscle types with an immunologic and electrophoretic characterization identical to that of heart FABP.     

The effect of starvation on branched-chain 2-oxo acid oxidation in rat muscle.

Oxidative-decarboxylation rates of branched-chain amino acids in rat hemidiaphragm and of branched-chain 2-oxo acids in hemidiaphragm, soleus muscle and heart slices of 110-120 g rats were increased considerably by 3-4 days of starvation, when they were calculated from the specific radioactivity in the medium. When the supply from endogenous protein degradation to the oxidation-precursor pool was severely limited by transaminase inhibitors, oxidative-decarboxylation rates of branched-chain 2-oxo acids rose significantly. Since this apparent increase was relatively larger in preparations from fed rats than from 3-days-starved rats, the differences in oxidation rates with nutritional state became less or even not significant. With rat heart the smaller dilution of the oxidation precursor pool after starvation is in accordance with the reported decrease in protein breakdown. Since protein degradation increases with starvation in skeletal muscles, we suggest that the amino acid pool arising from protein degradation is more segregated from the oxidation precursor pool in muscles from starved than from fed rats. We conclude that starvation increases branched-chain amino acid and 2-oxo acid oxidation in skeletal and cardiac muscle considerably less than has been suggested by previous studies.     

Immunochemical quantitation of fatty-acid-binding proteins. I. Tissue and intracellular distribution, postnatal development and influence of physiological conditions on rat heart and liver FABP

Antisera against rat heart and liver fatty acid-binding protein (FABP) were applied in Western blotting analysis and ELISA to assess their tissue and intracellular distribution, and the influence of development, physiological conditions and several agents on the FABP content of tissue cytosols. The data obtained are compared with the oleic acid-binding capacity. Heart FABP is found in high concentrations in heart, skeletal muscles, diaphragm and lung, and in lower concentrations in kidney, brain and spleen, whereas liver FABP is limited to liver and intestine. In heart and liver, FABP is only present in the cytosol. The FABP content of both heart and liver shows a progressive increase during the first weeks of postnatal development, in contrast to their constant oleic acid-binding capacity. The reciprocally declining alpha-fetoprotein content of both tissues may partially account for the complementary fraction of the fatty acid-binding capacity. The FABP content and the fatty acid-binding capacity of adult heart and liver were in good accordance under various physiological conditions. Addition of clofibrate to the diet induces an increase of liver FABP content, whereas feeding of cholesterol, cholestyramine, mevinolin or cholate caused a marked decrease. The significance of the combined determination of fatty acid-binding capacity and FABP content (by immunochemical quantitation and blotting analysis) is indicated.     

Expression and activity of cyclooxygenase isoforms in skeletal muscles and myocardium of humans and rodents.

Conflicting data have been reported on cyclooxygenase (COX)-1 and COX-2 expression and activity in striated muscles, including skeletal muscles and myocardium, in particular it is still unclear whether muscle cells are able to produce prostaglandins (PGs). We characterized the expression and enzymatic activity of COX-1 and COX-2 in the skeletal muscles and in the myocardium of mice, rats and humans. By RT-PCR, COX-1 and COX-2 mRNAs were observed in homogenates of mouse and rat hearts, and in different types of skeletal muscles from all different species. By Western blotting, COX-1 and -2 proteins were detected in skeletal muscles and hearts from rodents, as well as in skeletal muscles from humans. Immunoperoxidase stains showed that COX-1 and -2 were diffusely expressed in the myocytes of different muscles and in the myocardiocytes from all different species. In the presence of arachidonic acid, which is the COX enzymatic substrate, isolated skeletal muscle and heart samples from rodents released predominantly PGE(2). The biosynthesis of PGE(2) was reduced between 50 and 80% (P < 0.05 vs. vehicle) in the presence of either COX-1- or COX-2-selective blockers, demonstrating that both isoforms are enzymatically active. Exogenous PGE(2) added to isolated skeletal muscle preparations from rodents did not affect contraction, whereas it significantly fastened relaxation of a slow type muscle, such as soleus. In conclusion, COX-1 and COX-2 are expressed and enzymatically active in myocytes of skeletal muscles and hearts of rodents and humans. PGE(2) appears to be the main product of COX activity in striated muscles.     

Detection,tissue distribution and (sub)cellular localization of fatty acid-binding protein types

Summary This overview of recent work on FABP types is focussed on their detection and expression in various tissues, their cellular and subcellular distribution and their binding properties. Besides the 3 well-known liver, heart and intestinal types, new types as the adipose tissue, myelin and (rat) renal FABPs have been described. Recent observations suggest the occurrence of more tissue-specific types, e.g. in placenta and adrenals. Heart FABP is widely distributed and present in skeletal muscles, kidney, lung, brain and endothelial cells. The cellular distribution of FABP types appears to be related to the function of the cells in liver, muscle and kidney. The presence of FABP in cellular organelles requires more evidence. The functional significance of the occurrence of more FABP types is unclear, in spite of the observed differences in their ligand-protein interaction.Abbreviations FABP(s) Fatty Acid-Binding Protein(s)     

Fatty acid binding proteins from heart

Heart contains a fatty acid binding protein (FABP) concentration comparable to liver, when it is determined with a fatty acid-binding assay. The low concentration detected with anti-liver FABP antibodies is related to the different chemical forms and physiochemical properties of liver and heart FABP. The ratio of fatty acid bound per purified protein molecule is one or lower. Rat heart mitochondria oxidize FABP-bound fatty acids. The FABP content of rat heart is dependent on sex and diurnal cycle, but is not influenced by starvation or clofibrate feeding. It is also not different in the newborn rat. FABP was obtained from human heart in a yield of 11%. It shows similar binding characteristics to palmitic, oleic and arachidonic acid. The functional significance of the specific heart FABP is discussed in relation to myocardial fatty acid metabolism in normal and pathological conditions.     

Non-enzymatic glycosylation of myosin: effects of diabetes and ageing.

The influence of diabetes mellitus, streptozotocin-induced diabetes and ageing on the non-enzymatic glycosylation of myosin from cardiac and skeletal muscles was investigated. In cardiac muscle, and to a lesser extent also in skeletal muscles of the rat, non-enzymatic glycosylation of myosin increases with the age, as measured in 6-, 12- and 29-month-old animals. Skeletal muscle myosin from diabetic humans and also that from diabetic rat cardiac muscle are more glycosylated when compared with control myosin preparations. Ca(2+)-ATPase activity of myosin is lower in muscles of diabetic individuals as compared with control muscles.     

Training-induced elevation in FABP(PM) is associated with increased palmitate use in contracting muscle.

To evaluate the effects of endurance training in rats on fatty acid metabolism, we measured the uptake and oxidation of palmitate in isolated rat hindquarters as well as the content of fatty acid-binding proteins in the plasma membranes (FABP(PM)) of red and white muscles from 16 trained (T) and 18 untrained (UT) rats. Hindquarters were perfused with 6 mM glucose, 1,800 microM palmitate, and [1-(14)C]palmitate at rest and during electrical stimulation (ES) for 25 min. FABP(PM) content was 43-226% higher in red than in white muscles and was increased by 55% in red muscles after training. A positive correlation was found to exist between succinate dehydrogenase activity and FABP(PM) content in muscle. Palmitate uptake increased by 64-73% from rest to ES in both T and UT and was 48-57% higher in T than UT both at rest (39.8 +/- 3.5 vs. 26.9 +/- 4. 4 nmol. min(-1). g(-1), T and UT, respectively) and during ES (69.0 +/- 6.1 vs. 43.9 +/- 4.4 nmol. min(-1). g(-1), T and UT, respectively). While the rats were resting, palmitate oxidation was not affected by training; palmitate oxidation during ES was higher in T than UT rats (14.8 +/- 1.3 vs. 9.3 +/- 1.9 nmol. min(-1). g(-1), T and UT, respectively). In conclusion, endurance training increases 1) plasma free fatty acid (FFA) uptake in resting and contracting perfused muscle, 2) plasma FFA oxidation in contracting perfused muscle, and 3) FABP(PM) content in red muscles. These results suggest that an increased number of these putative plasma membrane fatty acid transporters may be available in the trained muscle and may be implicated in the regulation of plasma FFA metabolism in skeletal muscle.     

Purification and characterization of a fatty-acid-binding protein from the gastric mucosa of rats. Possible identity with heart fatty-acid-binding protein and its parietal cell localization

Fatty acid-binding protein (FABP) was purified from rat gastric mucosa by successive Sephadex G-75 chromatography, DEAE-cellulose chromatography and HPLC on an RP-2 (Merck) reversed-phase column. The purified stomach FABP migrated as a single band corresponding to an apparent molecular mass of 15 kDa on SDS/PAGE. Stomach FABP appeared to be identical with rat heart FABP, as judged from its electrophoretic mobility, amino acid composition and tryptic peptide map. In addition, the amino acid sequences of two selected tryptic peptides coincided completely with the rat heart FABP sequence deduced from that of cDNA. Stomach FABP showed immunochemical identity with rat heart FABP when tested with an antiserum against rat heart FABP. Immunohistochemically, stomach FABP was specifically stained with anti-(rat heart FABP) serum in parietal cells of the gastric mucosa. The results suggested that the primary structure of stomach FABP is identical with that of rat heart FABP, and showed that stomach FABP is localized in parietal cells of the gastric mucosa.     

The significance of lipoprotein lipase in rat skeletal muscles.

Lipoprotein lipase was assayed in extracts of acetone-ether powders of rat skeletal muscles. Enzyme activity in soleus had typical characteristics of lipoprotein lipase in other tissues: inhibition by molar NaCl and protamine sulfate and activation by the human apolipoprotein, R-glutamic acid. Activity in muscles with predominantly red fibers (soleus, diaphragm, lateral head of gastrocnemius and anterior band of semitendinosus) was higher than in those with predominantly white fibers (body of gastrocnemius and posterior band of semitendinosus). No effect of a 24 hour fast upon enzyme activity was observed in ten skeletal muscles, but activity decreased substantially in four adipose tissue depots and increased slightly in heart muscle with fasting. Four minutes after intravenous injection of labeled lymph chylomicrons, skeletal muscles with predominantly red fibers incorporated several times more chylomicron triglyceride fatty acids than thos with predominantly white fibers. Estimated lipoprotein lipase activity in total skeletal muscle was about two-thirds that in total adipose tissue of rats fed ad libitum. After a 24 hour fast, total activity in skeletal muscle was about twice that in adipose tissue. These data suggest that a substantial fraction of lipoprotein lipase is in skeletal muscle of rats and that this tissue, especially its red fibers, is an important site of removal of triglycerides from the blood.     

Rat muscle acylphosphatase: Purification, amino sequence, and immunological characterization

Acylphosphatase was purified from rat skeletal muscle essentially by gel filtration and high-performance ion-exchange chromatography. The complete amino acid sequence was reconstructed by using the sequence data obtained from tryptic, peptic, andS. aureus V8 protease peptides. The protein consists of 96 amino acid residues and is acetylated at the NH₂-terminus. The immunological cross-reactivity of acylphosphatase from rat and horse skeletal muscle was examined by ELISA. The reaction with rabbit antiserum revealed the presence of at least five antigenic sites on rat enzyme, two of which are common to horse muscle enzyme. Anti-rat antibodies also recognize the peptide that corresponds to the initial part of the molecule, which varies greatly from equine enzyme. Two completely new antigenic sites are herein described: the first can be considered the main antigenic site and is located within positions 21–36, the second is in the COOH-terminal part of the molecule. A mixture of immunoreactive peptides gives strong antibody-antigen reaction inhibition (94%).     

Immunochemical analysis of the peroxisomal beta-oxidation enzymes in rat and human heart and skeletal muscle and in skeletal muscle of Zellweger patients

Immunoblot analyses with antibodies against the peroxisomal beta-oxidation enzymes from rat liver showed the presence of these enzymes in rat and human liver and kidney and rat adrenal gland. The bifunctional protein could not be detected in muscle tissues or cultured muscle cells. Acyl-CoA oxidase was detected in rat heart and cultured human muscle cells. 3-Ketoacyl-CoA thiolase was also detected in human and rat heart and skeletal muscle; however, this enzyme was not detectable in skeletal muscle of Zellweger patients, in agreement with the absence of peroxisomal fatty acid oxidation.     

Different metabolic adaptation of heart and skeletal muscles to moderate-intensity treadmill training in the rat

The effect was investigated of treadmill training of moderate intensity on the fatty acid-binding protein (FABP) content in relation to parameters of oxidative and glycolytic metabolism. To this end, the cytoplasmic FABP content and the activity of beta-hydroxyacyl-coenzyme A dehydrogenase (HAD), citrate synthase (CS), and 6-phosphofructokinase (PFK) were measured in heart, fast-twitch extensor digitorum longus (EDL) and slow-twitch soleus muscles (SOL) of male Wistar rats. To investigate the influence of the amount of training (defined as the product of exercise duration, intensity and frequency), two training groups were created that differed in training frequency (HF, high frequency 5 days x week(-1), n = 9; LF, low frequency 2 days x week(-1), n = 9; the exercise being 20 m x min(-1) for 2 h with no gradient, over 6 weeks) and compared with SC, sedentary controls (n = 7). In heart muscle, the cytoplasmic FABP content was 34% higher in HF than in SC but was the same as in LF. The CS and HAD activities were no different in the three groups, suggesting that the capacity to oxidize fatty acids (FA) was not affected by training. The PFK activity was higher (43%) in HF, suggesting a shift towards carbohydrate utilization. The FABP content and HAD activity did not change in SOL and EDL after training whereas the CS activity increased (27%) in SOL and decreased (21%) in EDL in both training groups. In addition, PFK activity in EDL was much higher (113%) in the HF than in SC group. The HF training was associated with a fine-tuning of FA availability and use in heart muscle, and with a more efficient energy production. It is suggested therefore that cytoplasmic FABP could be an early marker of muscle adaptation to training in heart but not in skeletal muscle. The training reinforced the metabolic profile of the skeletal muscles, in particular that of the fast-twitch glycolytic muscle. We concluded that a large amount of training is needed when the effect on both oxidative and glycolytic parameters is to be studied.     

Intracellular transport of lipids

Summary Translocation of lipids inside mammalian cells is considered to be facilitated by a number of low-molecular weight lipid binding proteins. An overview of these proteins is given, with particular reference to the heart. Three distinct phospholipid transfer proteins specifically stimulate the net transfer of individual phospholipid classes between membrane structures. In rat cardiac muscle their content is 15–140 pmol/g ww. Fatty acid-binding proteins (FABP) are abundantly present in tissues actively involved in the uptake or utilization of long-chain fatty acids, such as intestine, liver and heart. The four distinct FABP types now identified show a complex tissue distribution with some tissues containing more than one type. Heart (H-) FABP comprises about 5% of the cytosolic protein mass; its content in rat heart is 100 nmol/g ww. Immunochemical evidence has been obtained for the presence of H-FABP in several other tissues, including red skeletal muscle, mammary gland and kidney. Beside long-chain fatty acids FABP binds with similar affinity also fatty acyl-CoA and acyl-L-carnitines. In heart the latter compound may be the primary ligand, since normoxic acyl-L-carnitine levels are several fold higher than those of fatty acids. In addition, H-FABP was found to modulate cardiac energy production by controlling the transfer of acyl-L-carnitine to the mitochondrial -oxidative system. H-FABP may also protect the heart against the toxic effects of high intracellular levels of fatty acid intermediates that arise during ischemia.     

Primary structure of locust flight muscle fatty acid binding protein.

The amino acid sequence of the fatty acid binding protein (FABP) from flight muscle of the locust, Schistocerca gregaria, has been determined. The sequence of the N-terminal 39 amino acid residues, determined by automated Edman degradation, was used to prepare a degenerate oligonucleotide that corresponded to amino acid residues 16-23. cDNA coding for FABP was constructed from flight muscle mRNA and amplified by the polymerase chain reaction using the degenerate oligonucleotide and an oligo dT-NotI primer adapter as primers. The amplification product was cloned and sequenced. Additionally, a cDNA library of flight muscle mRNA was prepared and screened with a 414-bp probe prepared from the clone. The primary structure of locust FABP was compared with the proteins in the Swiss protein databank and found to have significant homology with mammalian FABPs over the entire 133-residue sequence. The best match was versus human heart FABP (41% identity), attesting to the highly conserved nature of this protein. The results suggest that locust muscle FABP is a member of the lipid binding protein superfamily and may provide valuable insight into the evolution of this abundant protein class.     

Monoclonal antibodies to the muscle isoform of alpha-actinin--a marker for the study of the differentiation of skeletal and cardiac muscles

A battery of monoclonals to the rabbit skeletal muscle alpha-actinin has been produced. The majority of monoclonals proved to be species-specific by indirect immunofluorescence on the isolated rabbit skeletal myofibrils and on the differentiating cultures of chicken and rat skeletal muscles. One monoclonal, EA-53, reacts with the skeletal muscle alpha-actinin of various species (rat, rabbit, chicken) in immunofluorescence and immunoblotting. The monoclonal EA-53 recognizes also heart muscle alpha-actinin in cultured cardiomyocytes of human, rat and mouse origin. EA-53 does not stain alpha-actinin in myoblasts, fibroblasts, and endothelial cells. The monoclonal antibody EA-53 discriminating muscle and nonmuscle alpha-actinin isoforms could be used as a tool to study the mechanisms of skeletal and cardiac myogenesis.