Judith Storch

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.

3-[p-(6-Phenyl)-1,3,5-hexatrienyl]phenylpropionic acid (PA-DPH): characterization as a fluorescent membrane probe and binding to fatty acid binding proteins

The negatively charged fluorophore 3-[p-(6-phenyl)-1,3,5-hexatrienyl]phenylpropionic acid (PA-DPH) was characterized by comparison with its parent compound DPH, and with cationic trimethylammonium-DPH (TMA-DPH). The molar absorption coefficient of PA-DPH (60,000 cm-1.mol-1) as well as its quantum yield (0.7) and fluorescence lifetime (5 ns) in fluid phase membranes are intermediate between DPH and TMA-DPH. Steady-state fluorescence polarization studies show that PA-DPH detects the phase transition of both neutral and anionic bilayers. In fluid phase membranes the absolute values of PA-DPH polarization are considerably higher than DPH and somewhat lower than TMA-DPH. The results suggest that like TMA-DPH, PA-DPH is anchored to the surface of the membrane by its charge, but that it is probing a region somewhat deeper along the bilayer normal. PA-DPH binds to rat hepatic fatty acid binding protein (hFABP) and bovine serum albumin at PA-DPH/protein molar ratios of 1.5:1 and at least 6:1, respectively. Native oleic acid competes with PA-DPH for binding to both proteins, suggesting that the two ligands compete for similar binding sites. The affinity of PA-DPH for hFABP is similar to that of oleic acid. Thus, PA-DPH should be useful both as an anionic fluorescent membrane probe and a long-chain free fatty acid analogue.

Role of macrophage-expressed adipocyte fatty acid binding protein in the development of accelerated atherosclerosis in hypercholesterolemic mice

Atherosclerosis is an inflammatory disease process associated with elevated levels of plasma cholesterol, especially low‐density lipoproteins. The latter become trapped within the arterial wall and are oxidized and taken up by macrophages to form foam cells. This process is an initiating event for atherosclerosis. Fatty acid binding proteins (FABP) are involved in fatty acid metabolism and cellular lipid transport, and adipocyte FABP (aP2) is also expressed in macrophages. We recently generated mice lacking both apolipoprotein (Apo)E and aP2 (ApoE−/−aP2−/−) and found that these mice, compared with ApoE−/− mice, developed markedly smaller atherosclerotic lesions that contained fewer macrophages. Here we investigated the mechanism(s) responsible for this prevention of atherosclerotic lesion formation. Bone marrow transplantations were performed in ApoE−/− mice, receiving cells from either ApoE−/− or ApoE−/−aP2−/− mice. The lack of aP2 in donor marrow cells led to the development of smaller (5.5‐fold) atherosclerotic lesions in the recipient mice. No differences were found in plasma cholesterol, glucose, or insulin levels between recipients of bone marrow cells from ApoE−/− or ApoE−/−aP2−/−mice. However, the expression of chemoattractant and inflammatory cytokines was decreased in macrophages from ApoE−/−aP2−/− mice compared with ApoE−/− mice, which may contribute to the decrease in atherosclerotic lesion formation. Taken together, we demonstrate the importance of macrophage aP2 in the development of atherosclerotic lesions.

The lipid structure of biological membranes

Abstract Recent studies of the structure of lipids in biological membranes have revealed surprising findings about their manner of orientation and modes of interaction, as well as the effects of their structure on anti-lipid antibody specificities. Many intriguing questions are currently being investigated, including whether lateral lipid domains are typical features of biological membranes, and how, when and where the asymmetric composition of membrane lipids arises and is maintained.

Diversity of fatty acid-binding protein structure and function: studies with fluorescent ligands

The mammalian fatty acid-binding proteins (FABP) are localized in many distinct cell types. They bind long chain fatty acidsin vitro, however, their functions and mechanisms of actionin vivo remain unknown. The present studies have sought to understand the relationships among these proteins, and to address the possible role of FABP in cellular fatty acid traffic. A series of anthroyloxy-labeled fluorescent fatty acids have been used to examine the physicochemical properties of the fatty acid-binding sites of different members of the FABP family. The fatty acid probes have also been used to study the rate and mechanism of fatty acid transfer from different FABP types to phospholipid membranes. The results of these studies show a number of interesting and potentially important differences between FABP family members. An examination of adipocyte and heart FABP (A- and H-FABP) shows that their fatty acid-binding sites are less hydrophobic than the liver FABP (L-FABP) site, and that the bound ligand experiences less motional constraint within the A- and H-FABP binding sites than within the L-FABP binding site. In keeping with these differences in structural properties, it was found that anthroyloxy-fatty acid transfer from A- and H-FABP to membranes is markedly faster than from L-FABP. Moreover, the mechanism of fatty acid transfer was found to be similar for the highly homologous logous A- and H-FABP, whereby transfer to phospholipid membranes appears to occur via transient collisional interactions between the FABP and membranes. Transfer of fatty acids from L-FABP, in contrast, occurs via an aqueous phase diffusion mechanism. Other studies utilized fluorescent fatty acid and monoacylglycerol derivatives to compare how the two FABP which are present in high abundance in the proximal small intestine interact with the two major products of dietary triacylglycerol hydrolysis. The results showed that whereas L-FABP binds both fatty acid and monoacylglycerol derivatives, intestinal FABP (I-FABP) appears to bind fatty acid but not monoacylglycerol. In summary, studies with fluorescent ligands have demonstrated unique properties for different FABP family members. A number of these differences appear to correlate with the degree of primary sequence homology between the proteins, and suggest functional diversity within the FABP family.

The Adipocyte Fatty Acid-binding Protein Binds to Membranes by Electrostatic Interactions

The adipocyte fatty acid-binding protein (AFABP) is believed to transfer unesterified fatty acids (FA) to phospholipid membranes via a collisional mechanism that involves ionic interactions between lysine residues on the protein surface and phospholipid headgroups. This hypothesis is derived largely from kinetic analysis of FA transfer from AFABP to membranes. In this study, we examined directly the binding of AFABP to large unilamellar vesicles (LUV) of differing phospholipid compositions. AFABP bound LUV containing either cardiolipin or phosphatidic acid, and the amount of protein bound depended upon the mol % anionic phospholipid. TheK a for CL or PA in LUV containing 25 mol % of these anionic phospholipids was approximately 2 × 103 m −1. No detectable binding occurred when AFABP was mixed with zwitterionic membranes, nor when acetylated AFABP in which surface lysines had been chemically neutralized was mixed with anionic membranes. The binding of AFABP to acidic membranes depended upon the ionic strength of the incubation buffer: ≥200 mmNaCl reduced protein-lipid complex formation in parallel with a decrease in the rate of FA transfer from AFABP to negatively charged membranes. It was further found that AFABP, but not acetylated AFABP, prevented cytochrome c, a well characterized peripheral membrane protein, from binding to membranes. These results directly demonstrate that AFABP binds to anionic phospholipid membranes and suggest that, although generally described as a cytosolic protein, AFABP may behave as a peripheral membrane protein to help target fatty acids to and/or from intracellular sites of utilization.

Structurally distinct plasma membrane regions give rise to extracellular membrane vesicles in normal and transformed lymphocytes

Shedding of extracellular membranes from the cell surface may be one of the means through which cells communicate with one another. In an attempt to elucidate whether cell surface exfoliation is a directed or random process, we investigated the membrane lipid and protein composition and membrane lipid order of shed extracellular membranes and of plasma membranes from which they arose in normal circulating lymphocytes and in the B-lymphoblastoid cell lines Raji, WI HF2 729 and the T-lymphoblastoid cell line Jurkat. Extracellular membranes derived from transformed cell lines were more rigid as assessed by steady state polarization of 1,6-diphenylhexatriene (DPH) and were highly enriched in cholesterol when compared with the corresponding plasma membrane. The extracellular membranes from normal lymphocytes, on the other hand, were more fluid and contained more polyunsaturated acyl chains than did the plasma membranes from these cells. Our results suggest that extracellular membranes are shed from specialized regions of the lymphocyte plasma membrane and that membrane exfoliation is likely to be a directed event.

A comparison of heart and liver fatty acid-binding proteins: interactions with fatty acids and possible functional differences studied with fluorescent fatty acid analogues

SummaryFatty acid-binding proteins (FABP) are distinct but related gene products which are found in many mammalian cell types. They are generally present in high abundance, and are found in those tissues where free fatty acid (ffa) flux is high. The function(s) of FABP is unknown. Also not known is whether all FABP function similarly in their respective cell types, or whether different FABP have unique functions. The purpose of these studies was to assess whether different members of the FABP family exhibit different structural and functional properties. Two fluorescent analogues of ffa were used to compare the liver (L-FABP) and heart (H-FABP) binding proteins. The propionic acid derivative of diphenylhexatriene (PADPH) was used to examine the physical properties of the ffa binding site on L- and H-FABP, as well as the relative distribution of ffa between FABP and membranes. An anthroyloxy-derivative of palmitic acid, 2AP, was used to monitor the transfer kinetics of ffa from liver or heart FABP to acceptor membranes, using a resonance energy transfer assay. The results demonstrate that the ffa binding sites of both FABP are hydrophobic in nature, although the L-FABP site is more nonpolar than the H-FABP site. Equilibration of PADPH between L-FABP and phosphatidylcholine (PC) bilayers resulted in a molar partition preference of > 20: 1, L-FABP : PC. Similar studies with H-FABP resulted in a PADPH partition preference of only 3:1, H-FABP : PC. Finally, the transfer of 2AP from H-FABP to acceptor membranes was found to be 50-fold faster than transfer from L-FABP. These studies demonstrate that important structural and functional differences exist between different members of the FABP family, and therefore imply that the roles of different FABP may be unique.

Resistance to the pore forming protein of cytotoxic T cells: comparison of target cell membrane rigidity

Cytotoxic T lymphocytes (CTL) release from their granules a 70 kDa protein, called PFP, perforin or cytolysin, which inserts into the target cell plasma membrane in its monomeric form. Here it polymerizes into a macromolecular complex forming pores as large as 20 nm. Although purified PFP/perforin can effectively lyze all target cells tested. CTL are refractory to lysis. The mechanism underlying the resistance of CTL is currently unknown. This study represents a search for membrane structural properties that could confer resistance to CTL against PFP/perforin-mediated lysis. The fluorescent dye merocyanine 540 was used to measure the lipid head group packing of CTL and several target cells, and 1-[4-(trimethylamine)phenyl]-6-phenylhexa-1,3,5-triene was used to estimate the fluidity of the membrane hydrocarbon region. The resistance against PFP/perforin-mediated lysis was determined by the 51Cr release assay. A comparison of the membrane rigidity with cell resistance led to the conclusion that the membrane lipid structure cannot account for the unusually high resistance of CTL. In particular, the resistant CTL line CTLL-2 has a lipid head group packing that is looser than that of Yac-1, and the sensitive target cells Jy-25 and EL-4 have membrane acyl chains that are less fluid than those of the effector CTLL-R8.

Effect of phospholipid headgroup composition on the transfer of fluorescent long-chain free fatty acids between membranes

The transfer of long-chain anthroyloxy-labeled-free fatty acids (AOffa) between small unilamellar vesicles (SUV) was studied using a fluorescence energy transfer assay. Donor SUV were labeled with AOffa, and acceptor SUV contained the nonexchangeable quencher NBD-phosphatidylethanolamine. Donor and acceptor membranes were mixed using a stopped-flow apparatus, and intermembrane transfer was monitored by the decrease in AO fluorescence with time. The effect of donor membrane phospholipid headgroup composition on AOffa transfer was examined by incorporating phosphatidylethanolamine (PE), phosphatidic acid (PA), or phosphatidylglycerol (PG) into donor SUV otherwise composed of phosphatidylcholine (PC). Addition of 25 mol% of either of the negatively charged phospholipids (PA or PG) resulted in an increase in the rate of AOffa transfer, whereas addition of zwitterionic PE had no effect on transfer rate. The transfer kinetics were in all cases best described by a biexponential process, and it was found that the addition of PA caused an increase in the fraction of AOffa which transfer at the fast rate. This was likely due in large part to the asymmetric distribution of AOffa in these vesicles, with more fatty acid in the outer hemileaflet. This in turn may be due to the asymmetric distribution of PA between the inner and outer hemileaflets. Thus the increased AOffa transfer rate from negatively charged vesicles may be caused by charge repulsion between ffa and negatively charged headgroups. This increase in transfer rate was maximized at pH 9 as compared to pH 7, further suggesting that the increased rate of intermembrane transfer may arise because of charge repulsion. Finally, it was shown that decreasing the membrane surface potential by increasing the ionic strength caused the rate of AOffa transfer from PA-containing vesicles and PC vesicles to become identical. The results demonstrate that the ionic character of the donor membrane bilayer is an important determinant of the transfer rate of long-chain fatty acids between membranes.