Light microscopic immunocytochemical localization of hepatic and intestinal types of fatty acid-binding proteins in rat small intestine

Monospecific antisera to purified hepatic fatty acid-binding protein (hFABP) and gut fatty acid-binding protein (gFABP) have been used to localize these two proteins in the small intestine of fed rats at the light microscopic level. Pieces of duodenum, jejunum, and ileum were removed from 4-, 10-, 20-, 22-, and 60-day-old Sprague-Dawley rats. Both cryostat and paraffin sections were studied for the presence of hFABP or gFABP by the avidin-biotin immunoperoxidase method. Slides were graded blind for the intensity of staining. Despite the structural and immunological differences between these two proteins, we showed no major differences between their staining patterns or their staining intensity throughout the intestine during postnatal development. The staining for both fatty acid-binding proteins was cytoplasmic. No brush border staining was found. Staining was more intense in the proximal rather than distal intestine, in the villus rather than crypt cells, and in the apex rather than the base of intestinal cells. Shifts in staining patterns, and staining intensity occurring during development may be related to variations in dietary fat intake, rates of cell proliferation, intestinal anatomy, and mechanisms for fat absorption.     

Studies on fatty acid-binding proteins. The binding properties of rat liver fatty acid-binding protein.

The inactive 2Fe species of the Fe protein of the nitrogenase of Klebsiella pneumoniae was generated by treating oxidized Fe protein (Kp2) with MgATP and chelator. Incubation of the 2Fe species of Kp2 with the sulphurtransferase rhodanese in the presence of thiosulphate, ferric citrate and reduced lipoate reproducibly restored activity. The extent of restoration of activity depended on the molar ratio of 2Fe Kp2 to rhodanese and was time-dependent. Re-activation did not occur in the reaction mixture lacking rhodanese.     

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.     

Nomenclature of fatty acid-binding proteins

Summary A variety of designations is currently being used to refer to cellular fatty acid-binding proteins (FABPs). Besides from the use of other general names (e.g. Z protein), confusion mostly arises from the application of various abbreviations and symbols to denote the tissue(s) of origin and cellular localization (cytoplasm, plasma membrane) of a specific FABP. In order to minimize confusion a more unified and rational nomenclature is proposed, which is based on application of the formula X-FABPy. The prefix X is a capital letter indicating the tissue of greatest abundance, the suffix Y similarly denotes the (sub)cellular localization of the protein. The general and functional name fatty acid-binding protein (FABP) is preferred for the cellular proteins with the property to bind fatty acids, unless future research reveals that the binding of fatty acids is not the primary biological property or physiological role of (some of) these proteins.     

Studies on fatty acid-binding proteins. The diurnal variation shown by rat liver fatty acid-binding protein.

The concentration of fatty acid-binding protein in rat liver was examined by SDS/polyacrylamide-gel electrophoresis, by Western blotting and by quantifying the fluorescence enhancement achieved on the binding of the fluorescent probe 11-(dansylamino)undecanoic acid. A 2-3-fold increase in the concentration of this protein produced by treatment of rats with the peroxisome proliferator tiadenol was readily detected; however, only a small variation in the concentration of the protein due to a diurnal rhythm was observed. This result contradicts the 7-10-fold variation previously reported for this protein [Hargis, Olson, Clarke & Dempsey (1986) J. Biol. Chem. 261, 1988-1991].     

Cloning and tissue expression of chicken heart fatty acid-binding protein and intestine fatty acid-binding protein genes

Fatty acid-binding proteins (FABPs) are members of a superfamily of lipid-binding proteins, occurring intracellularly in invertebrates and vertebrates. This study was designed to clone and characterize the genes of heart fatty acid-binding protein and intestine fatty acid-binding protein in the chicken. PCR primers were designed according to the chicken EST sequences to amplify cDNA of H-FABP and I-FABP genes from chicken heart and intestinal tissues. Analysis of sequence showed that the cDNA of the chicken H-FABP gene is 75 to 77% homologues to human, mouse, and pig H-FABP genes, and the chicken I-FABP gene is 71 to 72% homologues to human, mouse, and pig I-FABP genes. In addition, Northern blot analysis indicated that of the two genes, similar to the copartner of the mammal, H-FABP gene was expressed in a wide variety of tissues, and I-FABP gene was expressed only in intestinal tissues. The expression levels of the chicken H-FABP mRNA in heart and I-FABP mRNA in intestine had significant differences between the broilers from fat line and Bai'er layers at six weeks of age. The results of this study provided basic molecular information for studying the role of two FABPs in the regulation of fatty acid metabolism in avian species.     

Regulation of the biosynthesis of two distinct fatty acid-binding proteins in rat liver and intestine. Influences of sex difference and of clofibrate

Two distinct fatty acid-binding proteins (FABPs) have been identified in rat intestine, gFABP (15,063 Da) which is confined to intestinal epithelium and hFABP (14,184 Da) which is found in both liver and intestine. We have examined the influence of sex difference and the effect of clofibrate, both of which affect cellular fatty acid metabolism and hFABP levels, on the concentration, and mRNA levels of both hepatic and intestinal FABPs. In the liver, hFABP concentration was approximately 2-fold greater in females and in clofibrate-treated males than in untreated male rats. These differences were not accompanied by changes in the fractional turnover of the polypeptide but rather by parallel increases in hFABP mRNA. In the intestine, the two FABPs exhibited different regulatory responses. Intestinal hFABP turnover was 33% greater in females than in males, whereas mRNA concentration was 50% greater. Thus, unlike hFABP in liver, there was no sex-related difference in the steady-state level of hFABP in intestine. However, clofibrate treatment, similar to its effects in the liver, doubled intestinal hFABP protein and mRNA concentration. In contrast to hFABP, neither gFABP protein nor mRNA concentration were sex dependent, whereas clofibrate produced only a modest increase in gFABP concentration without significantly changing gFABP mRNA levels. The results indicate that the influence of sex difference and the effect of clofibrate on hepatic fatty acid metabolism are both associated with changes in hFABP synthesis mediated pretranslationally. The differential response of hFABP and gFABP in intestine suggests that these proteins play distinct roles in the cellular metabolism of fatty acids.     

Research of anin vitro model to study the expression of fatty acid-binding proteins in the small intestine

In order to find anin vitro model for studying the regulation of the biosynthesis of the cytoplasmic Fatty Acid-Binding Proteins (FABPc) expressed in the small intestine, Intestinal- and Liver-(I- and L-) FABPc expressions were tested by Northern blotting in 8 normal or cancerous intestinal cell lines from man, mouse and rat and in organ culture of mouse jejunal explants. Neither I- nor L-FABPc mRNA was detected in any cell strains tested except in the highly differentiated human enterocyte-like intestinal cell line Caco-2. In this line, Northern blot analysis revealed a single messenger of about 0.7 kb corresponding to the L-FABPc. A two-fold increase in mRNA L-FABPc occurred in differentiated Caco-2 cells treated for 7 days with 0.05 mM bezafibrate, a peroxisome-proliferating hypolipidemic drug. The lack of I-FABPc messengers in this strain led us to seek anotherin vitro model. I- and L-FABPc messengers were found using an organ culture of mouse jejunal explants. A clear rise in I- and, especially, L-FABPc mRNA levels occurred 6 and 24 hr after the addition of 0.05 mM bezafibrate in the culture medium. Our results demonstrate, to our knowledge for the first time, that: 1) organ culture of intestinal explants provides a useful model for studyingin vitro the simultaneous regulation of I- and L-FABPc expressions, 2) biosynthesis of L-FABPc may be exploredin vitro using the Caco-2 cell line, 3) fibrate peroxisome-proliferators exert a direct effect on I- and L-FABPc expression in the small intestine, 4) L-FABPc expression seems to be more sensitive to fibrate action than is I-FABPc expression.Abbreviations I-FABPc cytosolic Intestinal Fatty Acid-Binding Protein - L-FABPc cytosolic Liver Fatty Acid-Binding Protein - bp base pair - EDTA Ethylenediamine Tetraacetic Acid - DMSO Dimethyl Sulfoxide - BSA Bovine Serum Albumin - DMEM Dulbecco's Modified Eagle's Medium - HBSS Hanks Balanced Salt Solution     

Studies of the fatty acid-binding site of rat liver fatty acid-binding protein using fluorescent fatty acids

Rat liver fatty acid-binding protein (FABP) is a 14.3-kDa cytosolic protein which binds long chain free fatty acids (ffa) and is believed to participate in intracellular movement and/or distribution of ffa. In the studies described here fluorescently labeled ffa were used to examine the physical nature of the ffa-binding site on FABP. The fluorescent analogues were 16- and 18-carbon ffa with an anthracene moiety covalently attached at eight different points along the length of the hydrocarbon chain (AOffa). Emission maxima of all FABP-bound AOffa were found to be considerably blue-shifted with respect to emission of phospholipid membrane-bound AOffa, suggesting a high degree of motional constraint for protein-bound ffa. Large fluorescence quantum yields and long excited state life-times indicate that the FABP-binding site for ffa is highly hydrophobic. Analysis of rotational correlation times for the FABP-bound AOffa suggest that the ffa are tightly bound to the protein. Variation of the quantum yield with attachment site suggests that the carboxylic acid group of the fatty acyl chain is located near the aqueous surface of the FABP. The rest of the ffa hydrocarbon chain is buried within the protein in a hydrophobic pocket and is particularly constrained at the midportion of the acyl chain.     

Unravelling the significance of cellular fatty acid-binding proteins

Cellular long-chain fatty acid (FA) transport and metabolism are believed to be regulated by membrane-associated and soluble proteins that bind and transport FAs. Several different classes of membrane proteins have been proposed as FA acceptors or transmembrane FA transporters. New evidence from in-vitro and whole-animal studies supports the existence of protein-mediated transmembrane transport of FAs, which is likely to coexist with passive diffusional uptake. The trafficking of FAs by intracellular fatty acid-binding proteins may involve their interaction with specific membrane or protein targets. Evidence is also emerging for concerted actions between the membrane and cytoplasmic fatty acid-binding proteins that allow for efficient regulation of FA transport and metabolism.     

Evolutionary diversification of the avian fatty acid-binding proteins

Phylogenetic analysis of avian and other vertebrate fatty acid binding proteins (FABPs) supported the hypothesis that several gene duplications within this family occurred prior to the most recent common ancestor (MRCA) of tetrapods and bony fishes. The chicken genome encodes two liver-expressed FABPs: (1) L-FABP or FABP1; and (2) Lb-FABP. We propose that the latter be designated FABP10, because in our phylogenetic analysis it clustered with zebrafish FABP10. Bioinformatic analysis of across-tissue gene expression patterns in the chicken showed some congruence with phylogenetic relationships. On the basis of expression, chicken FABP genes seemed to form two major groups: (1) a cluster of genes many of which showed predominant expression in the digestive system (FABP1, FABP2, FABP6, FABP10, RBP1, and CRABP1); and (2) a cluster of genes most of which had predominant expression in tissues other than those of the digestive system, including muscle and the central nervous system (FABP3, FABP4, FABP5, FABP7, and PMP2). Since these clusters corresponded to major clusters in the phylogenetic tree as well, it seems a plausible hypothesis that the earliest duplication in the vertebrate FABP family led to the divergence of a gut-specialized gene from a gene expressed mainly in nervous and muscular systems. Data on gene expression in livers of two lines of chickens selected for high growth and low growth showed differences between FABP1 and FABP10 expressions in the liver, supporting the hypothesis of functional divergence between the two chicken liver-expressed FABPs related to food intake.     

The fatty acid transport function of fatty acid-binding proteins

The intracellular fatty acid-binding proteins (FABPs) comprise a family of 14-15 kDa proteins which bind long-chain fatty acids. A role for FABPs in fatty acid transport has been hypothesized for several decades, and the accumulated indirect and correlative evidence is largely supportive of this proposed function. In recent years, a number of experimental approaches which more directly examine the transport function of FABPs have been taken. These include molecular level in vitro modeling of fatty acid transfer mechanisms, whole cell studies of fatty acid uptake and intracellular transfer following genetic manipulation of FABP type and amount, and an examination of cells and tissues from animals engineered to lack expression of specific FABPs. Collectively, data from these studies have provided strong support for defining the FABPs as fatty acid transport proteins. Further studies are necessary to elucidate the fundamental mechanisms by which cellular fatty acid trafficking is modulated by the FABPs.     

Primary structure and cellular distribution of two fatty acid-binding proteins in adult rat kidneys

Fatty acid-binding proteins (FABPs) were purified from the kidneys of female and male rats and characterized by primary structure and histological distribution in the kidney. Two FABPs (14 and 15.5 kDa) were found in male rat kidney cytosol whereas only 14-kDa FABP could be recognized in female rat kidneys throughout the purification steps. The amino acid sequence of the 14-kDa FABP was identical to that of rat heart FABP deduced from the cDNA sequence (Heuckeroth, R. O., Birkenmeier, E. H., Levin, M. S., and Gordon, J. I. (1987) J. Biol. Chem. 262, 9709-9717). Structural analysis of the male-specific 15.5-kDa FABP identified this second FABP as a proteolytically modified form of alpha 2u-globulin, an 18.7-kDa major urinary protein of adult male rats (Unterman, R. D., Lynch, K. R., Nakhasi, H. L., dolan, K. P., Hamilton, J. W., Cohn, D. V., and Feigelson, P. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 3478-3482) which shares a common ancestry with a number of hydrophobic ligand-binding proteins such as serum retinol-binding proteins. Immunohistochemical investigation disclosed that heart-type FABP (14-kDa FABP) is localized in the cytoplasm of the epithelia of the distal tubules in both male and female rat kidneys whereas 15.5-kDa FABP immunostaining was observed predominantly in the endosomes or lysosomes of proximal tubules in male rat kidneys. These results suggest strongly the functional divergence of two FABPs in the rat kidney.     

Bifunctional lipid-transfer: fatty acid-binding proteins in plants

Summary A cytosolic protein, able to facilitate intermembrane movements of phospholipids in vitro, has been purified to homogeneity from sunflower seedlings. This protein, which has the properties of a lipid-transfer protein (UP), is also able to bind oleoyl-CoA, as shown by FPLC chromatography. This finding, in addition to previous observations suggesting that a lipid-transfer protein from spinach leaves can bind oleic acid and that oat seedlings contain a fatty acid-binding protein with similar features than lipid transfer proteins, provides a clear demonstration that plant cells contain bifunctional fatty acid/lipid transfer proteins. These proteins can play an active role in fatty acid metabolism which involves movements of oleyl-CoA between intracellular membranes.Abbreviations FABP Fatty Acid-Binding Proteins - UP Lipid-Transfer Protein - PC Phosphatidylcholine - PI Phosphatidylinositol - PE Phosphatidylethanolamine - pI Isoelectric point     

Fatty acid-induced angiogenesis in first trimester placental trophoblast cells: Possible roles of cellular fatty acid-binding proteins

Angiogenesis is involved in the growth of new blood vessels from the existing one. Consequently, angiogenesis plays an indispensable role in tissue growth and repair including early placentation processes. Besides angiogenic growth factors (vascular endothelial growth factor (VEGF), angiopoietin-like 4 (ANGPTL4), placental growth factor (PlGF), platelet derived growth factor (PDGF), fibroblast growth factors (FGF)), dietary fatty acids (c>16) also directly or indirectly modulate angiogenic processes in tumors and other cell systems. Usually n − 3 fatty acids inhibit whereas n − 6 fatty acids stimulate angiogenesis in tumors and other cells. Contrary to this, docosahexaenoic acid, 22:6n − 3 (DHA) and other fatty acids including conjugated linoleic acid stimulate angiogenesis in placental first trimester cells. In addition to the stimulation of expression of major angiogenic factors such as VEGF and ANGPTL4, fatty acids also stimulate expression of intracellular fatty acid-binding proteins (FABPs) FABP-4 and FABP-3 those are known to directly modulate angiogenesis. Emerging data indicate that FABPs may be involved in the angiogenesis process. This paper reviews the fatty acid mediated angiogenesis process and the involvement of their binding proteins in these processes.     

Historic overview of studies on fatty acid-binding proteins

Summary Fatty acid-binding proteins (FABPs) were first identified in the cytosol of rat intestinal mucosa during studies on the regulation of intestinal fatty acid uptake. The subsequent finding of FABP activity in the cytosol of many other tissues initially was believed to reflect a single protein. However, the FABPs are now recognized as products of an ancient gene family comprised of at least 9 structurally related, soluble intracellular members, a number of which exhibit high-affinity binding of long-chain fatty acids. Despite recent insights into regulation and tissue-specific expression suggesting FABPs to subserve diverse roles, their precise biological functions remain to be elucidated.     

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.