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fifi 8.3.6 _ 0 6 S' PFOS Pharmacokinetic - / 000113 AN INVESTIGATION OF THE EFFECTS OF FLUOROCARBONS ON LIVER FATTY ACID-BINDING PROTEIN. DEANNA J. NABBEFELD Masters Thesis Key FC1: Perfluorooctane Sulfonic Acid (PFOS) FC2: Ammonium Perfluorooctonate (APFO) FC3: N-ethylperfluorooctane Sulfonamide Ethanol (N-EtFOSE) FC4: N-ethylperfluorooctane Sulfonamide (N-Et FOSE Amide; FX-12) 000114 AN INVESTIGATION OF THE EFFECTS OF FLUOROCARBONS ON LIVER FATTY ACID-BINDING PROTEIN. A THESIS SUBMITTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY O F MINNESOTA BY DEANNA J. NABBEFELD IN FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF M ASTER OF SCDENCE/ENVIRONMENTAL HEALTH A PRIL, 1998 000115 AN INVESTIGATION OF THE EFFECTS OF FLUOROCARBONS ON LIVER FATTY ACID-BINDING PROTEIN. ABSTRACT The objective o f this study was to investigate the hypothesis that certain Fluorocarbons (FCs) bind liver fatty acid-binding protein (L-FABP) and displace endogenous fatty acids (FAs) as an initial event leading to peroxisome proliferation. The goals o f the study were to assess the effect o f FCs on L-FABP function as evaluated by the ability o f the fluorescent FA analogue 11 - (5-dimethylaminonapthalenesulphonyl) - undecanoic acid (DAUDA) to bind to L-FABP isolated from rats and guinea pigs treated and not treated with FC1 in vivo; and to assess the potency o f FC1, FC2, FC3 and FC4 for binding to LFABP. Results show a decreased maximum binding capacity o f L-FABP from FC1 treated rats without an increase in Kd. The most potent L-FABP binder was FC1, followed by FC4 and (with equal IC50S) FC3 and FC2. Results for guinea pig L-FABP samples were inconclusive. This may be because guinea pig samples were only partially purified; thus resulting in a high degree o f interference from remaining cellular debris and a lower concentration o f L-FABP, as a proportion o f total protein, as compared to rat samples. INTRODUCTION Study Objectives This study was designed to investigate the hypothesis that certain fluorocarbons (FCs) bind to liver fatty acid-binding protein (L-FABP) and displace endogenous fatty acids (FAs) as an initial event leading to peroxisome proliferation. To examine this hypothesis, the kinetics o f FA and FC binding to L-FABP were investigated with an in vitro binding assay using the fluorescent FA analogue 11 - (5-dimethylaminonapthalenesulphonyl) - undecanoic acid (DAUDA). FC1 and FC2, known peroxisome proliferators, and FC3 and FC4, suspect peroxisome proliferators, were examined. Wyeth-14,643 (WY), a well known peroxisome proliferator, was used as the positive control and methanol as the negative control. Oleic acid, a FA known to bind to L-FABP with a very high affinity, was used to measure the maximum L-FABP binding. (Figure 1 - structures). L-FABP from 000116 male rats (considered to be strong responders to peroxisome proliferators) and male guinea pigs (considered to be weak or non-responders to peroxisome proliferators) (Svoboda, Grady and Azamoff, 1967; Orton etal., 1984; Lake and Gray, 1985; Elcombe and Mitchell, 1986), treated or not treated with FC1 in vivo, were examined. The goals o f the study were as follows: 1) to assess the effect o f FCs on L-FABP function, as evaluated by the ability o f DAUDA to bind to L-FABP isolated from rats and guinea pigs; and 2) to assess the potency o f the various FCs for binding to L-FABP. The first goal was accompilished as follows: a. L-FABP from rats and guinea pigs, treated and not treated with FC1, was isolated; b. the maximum binding capacity or receptor number (Bmax) o f each L-FABP sample and the dissociation constant or affinity (Kd) o f DAUDA for each L-FABP sample were calculated; and c. the concentration o f oleic acid which inhibited 50% o f specific DAUDA binding to isolated L-FABP samples, the oleic acid IC50for each sample, was measured. The second goal was achieved by calculating the IC50 o f each FC for the binding o f DAUDA to the isolated control rat L-FABP sample. 000117 3 000118 Ba c k g r o u n d Liver Fa ttyA cid-Binding Protein The exact role o f L-FABP, a member o f the intracellular lipid-binding protein (iLBP) family, is unclear (Bass, Kaikaus and Ockner, 1993). It is found predominately in the liver, although it is also present in the small intestinal and colonic enterocytes, gastric brush border, and enteroendocrine cells (Bass, 1985; Bass, 1988; Sweetser, Heuckeroth and Gordon, 1987; Vincent and Muller-Eberhard, 1985; Chan etal., 1985; Gordon etal., 1982; Sorof and Custer, 1987). Accepted functions o f L-FABP include binding and transporting FAs within the cell, regulating lipid metabolism, and protecting the cell by maintaining the concentration of free fatty acids (FFAs) below toxic levels (Bass et al., 1993). L-FABP is unique to the iLBP family in that it has a larger binding cavity (Thompson etal., 1997); broader ligand specificity (binds multiple hydrophobic compounds such as heme, certain eicosanoids, bilirubin, thyroxine, steroids, specific carcinogens and peroxisome proliferators as well as FAs) (Kaikaus, Bass and Ockner, 1990; Ockner etal., 1972; Rolf et al., 1995; Thumser, Voysey and Wilton, 1994; Khan and Sorof, 1990; Levi, Gatmaitan and Area, 1969); and the ability to bind tw o molecules per protein while other iLBPs bind only one (Thompson et al., 1997). The crystal structure o f rat L-FABP (Thompson et al, 1997) reveals two short antiparallel a-helices positioned over one end o f an 1 1-stranded antiparallel P-barrel. This differs from other iLBPs, which are 10-stranded, but does not significantly alter the conformation of the protein. A cavity is formed within the P-barrel that serves as an internalized ligand 000119 binding site with polar and nonpolar residues and bound water. In addition to a normal gap between the two (3-strands, L-FABP has a second gap formed by missing hydrogen bonds. The function o f this gap is unknown, but the missing hydrogen bonds increase the range o f motion in L-FABP compared to other iLBPs. This localized conformational flexibility may contribute to the broad ligand specificity exhibited by L-FABP. Two L-FABP binding sites exist, and interact allosterically. Crystal structures o f the protein prepared with oleic acid have characterized the primary binding site by an internalized carboxylate and a U-shaped hydrocarbon chain. Fatty acids bound in the primary binding site interact with Argizz, a conserved residue in all iLBPs; and are surrounded by protein atoms, structural water and nearby atoms o f the second bound FA. The oleic acid in the primary binding site is involved in hydrogen bond interactions at the carboxyl group with Ser39 Arg122 and Ser124. The secondary binding site is characterized by having the carboxylate o f the second oleic acid near the surface, and the hydrocarbon tail inserted toward the center o f the molecule and between the U-shaped hydrocarbon chain in the primary binding site. The carboxylate at this site is solvent-accessible, but still involved in a network o f hydrogen bonds with residues forming the entrance to the primary binding cavity. The two ligands are in physical contact and it is believed that they influence each others relative affinities. Structural data suggest the second site may not exist until the primary site is filled, or that the prior presence o f a FA in the primary site may be required for anything larger that a C UFA to bind the secondary site (Thompson et al., 1997). 5 000120 Fluorocarbons Fluorocarbons (FCs) are compounds structurally analogous to hydrocarbons with the hydrogens replaced with fluorines. The FCs under investigation resemble long chain FAs, having a hydrophobic tail and a polar head group. The tails o f FCs are more rigid in structure than the tails o f FAs, however, and thus the conformational flexibility o f FCs is more restricted than that o f FAs (Zisman, 1964). FCs have unique chemical and physical properties such as being very heat stable, inert and chemically and electrically nonreactive (Bryce, 1964; Bankes, 1970; George and Anderson, 1986; Gilliland, 1992; Clark et al., 1973). Such characteristics make them ideal for use in many consumer products and industrial procedures (Bryce, 1964). FCs are components o f products including household cleaners, leather treatments, insecticides and fire-extinguishing foams; used as surfactants in the aqueous polymerization o f fluorinated monomers; and used in industrial processes such as insulating, cooling, wetting, and corrosion inhibition (Bryce, 1964; Bankes, 1970; George and Anderson, 1986; Gilliland, 1992; Clark et al., 1973). Despite the usefulness of these chemicals, some are known to cause mitochondrial inhibition, cholestasis, peroxisome proliferation and tumor formation in rodents (Gilliland and Mandel, 1996; Langely, 1990; Ikeda et al., 1985; Pastoor et al., 1987; Harrision et al., 1988; Abdellatif et al., 1991). Permadi et al.( 1993) suggest chain length o f FCs influences the severity o f effect, finding the greatest significance exhibited by Cg compounds followed closely by Cio compounds, and increasingly less severe consequences exhibited with shorter chained molecules. The work o f Feller and Intrasuksri (1993) agreed with that o f Permadi et al.(1993), and added 6 000121 that a carboxylic function was important for the stimulation o f peroxisome prioliferation. Similar results were reported by Kennedy et al. (1998), who analyzed FCs ranging in length from 4-9 carbons for the effect o f structure on toxicity. They found Cg FCs to produce effects at a 10-fold lower dose than C6 FCs, and short chained FCs to be the least toxic. Although the effects seen in rodents have not been seen in humans, the potential for cumulative and long-term human toxicity resulting from continuous exposure to low concentrations o f FCs is o f concern (Gilliland and Mandel, 1996; Gilliland, 1992). Peroxisomes & Peroxisome Proliferation According to Small (1993), peroxisomes (also called microbodies or, in plants, glyoxysomes) are single membrane-limited cytoplasmic organelles present in most eukaryotic cells. The major function of peroxisomes is the P-oxidation o f FAs and FA derivatives (Mannaerts and Van Veldhoven, 1993). Peroxisomes contain no DNA; rather, their proteins are synthesized on free polyribosomes in the cell cytosol and imported into pre-existing peroxisomes post-translationally. It is believed that new peroxisomes form by fission from existing peroxisomes. Peroxisomes have been shown to proliferate following exposure to a diverse class o f chemicals referred to as peroxisome proliferators (Green, Issemann and Tugwood, 1993). The mechanism by which this occurs is unclear. Peroxisome proliferation is thought to be mediated by peroxisome proliferator activated receptors (PPARs), nuclear hormone receptors which, upon binding ligand, recognize specific DNA sequence motifs located upstream of the peroxisome proliferator target genes (peroxisome proliferator response 7 000122 elements (PPREs)), and activate specific gene transcription (Isseman and Green, 1990; Dryer et al., 1993). Due to the diversity o f peroxisome proliferators shown to activate PPAR (Green et al., 1993), speculation exists over a direct modulation o f PPAR by peroxisome proliferators, and an indirect mechanism is suggested. In addition to chemical and xenobiotic peroxisome proliferators, natural factors such as a high fat diet, starvation and diabetes (Flatmark et al., 1988; Ishii etal., 1980; Ishii, Horie and Suga, 1980; Horie, Fukumori and Suga, 1991; Gttlicher, Widmark and Gustafsson, 1992) have been shown to cause peroxisome proliferation. This correlation between peroxisome proliferation and FA metabolism suggests that PPAR serves an important role in lipid homeostasis (Vanden Heuval, 1996). It is probable, thus, that PPAR activation represents a physiological response to a biological stimulus, likely a factor involved in FA metabolism (Green et al., 1993). Possible stimuli/PPAR ligands include steroids, FAs and derivatives o f FA metabolism, and cholesterol metabolites (Green et al., 1993). Target genes include those for acyl-CoA oxidase (Tugwood et al, 1992; Feller and Intrasuksri, 1993), L-FABP (Isseman et al., 1992) and P450 ivai genes (Green et al., 1993). Significant interest surrounds the issue o f peroxisome proliferation because some peroxisome proliferators have been shown to cause hepatocellular carcinomas in laboratory rodents (Moody et al, 1991; Vanden Heuval, 1996). The mechanism by which peroxisome proliferators cause cancer in rodents is unknown. They are classified as a novel class o f epigenic chemical carcinogen (Vanden Heuvel, 1996), are nonmutagenic in the Ames assay and do not appear to bind DNA (Conway et al., 1989; Cohen and Grasso, 1981; Reddy and Lalwani, 1983, Stott, 1988; Reddy and Rao, 1989; Lake et al., 1990). 8 000123 Multiple mechanisms have been proposed to explain peroxisome proliferator-induced liver tumor formation, including oxidative stress (Reddy and Rao, 1989), enhanced cell replication (Marsman et ai., 1988) and promotion o f spontaneously formed lesions (Schulte-Hermann et al., 1989). Green et al. (1993) propose peroxisome proliferators are "complete carcinogens" which exhibit a combination o f initiation (oxidative radical production) and promotion (liver mitogenesis), possibly leading to sustained DNA replication depending on the compound and dose. Doubt about a causal relationship between peroxisome proliferation and carcinogenesis in rodents exists, however, and the relevance to human health is unclear (Tucker and Orton, 1993). Mammalian species differ in their response to peroxisome proliferators (Lake and Gray, 1985; Rodricks and Turnbull, 1987). Rats are considered strong responders, and guinea pigs and nonhuman primates low to non-responders (Svoboda et a i, 1967; Orton et al., 1984; Lake and Gray, 1985; Elcombe and Mitchell, 1986). Slight to no increase in peroxisomes were found in human patients treated with colfibrate (Hanefeld, Kemmer and Kadner, 1983) and fenofibrate (Blmcke et a i, 1983), drugs used in the treatment o f hypercholesterolemia and known peroxisome proliferators in rodents. Many hypothesize that if a causal relationship does exist between peroxisome proliferation and hepatocarcinogenesis, it is specific to rodents and not a risk to man (Tucker and Orton, 1993). Other well documented effects o f peroxisome proliferators in rodents include inhibition o f mitochondria ^-oxidation (Elcombe and Mitchell, 1986; Eacho and Foxworthy, 1988; 9 000124 Foxworthy and Eacho, 1988; Lock, Mitchell and Elcombe, 1989; Wallace, 1998), induction of peroxisomal -oxidation and co-oxidation in the ER (Reddy and Lalwani, 1983; Hawkins et a l, 1987), induction o f L-FABP expression (Bass, Manning and Ockner, 1985; Das, Gourisankar and Mukheijea, 1989; Fleischner et a i, 1975), cholestasis (Elcombe and Mitchell, 1986; Foxworthy and Eacho, 1988; Lock et al., 1989; Van Rafelghem et a l, 1988) and hepatomegaly (Moody et a l, 1991). Fa tty A cid Ca tabolism in the Hepatocyte Free fatty acids (FFAs), formed by the breakdown o f triacylglycerols stored in adipocytes, are carried in the blood by serum albumin and transported into hepatocytes by what is thought to be a plasma membrane bound fatty acid-binding protein (FABPpm) (Stremmel, Strohmeyer and Berk, 1986; Stremmel et a l, 1985). Once in the cell, FFAs are picked up by L-FABP and, under routine conditions, the majority are transported to the mitochondria for -oxidation, a process by which FAs are degraded to acetyl-CoA by the sequential removal o f two carbon segments (Moran and Scrimgeour, 1994). Mitochondrial -oxidation is coupled to the generation o f high energy phosphate bonds via oxidative phosphorylation, and results in the synthesis o f ATP and ketone bodies. In order to gain entry into the mitochondria, FA must first be converted to acyl-CoA esters by acyl-CoA synthetases, FA specific enzymes located in the mitochondrial outer membrane (Singh, Derwas and Poulos, 1987). The rate o f FA entry into the mitochondria is regulated by carnitine acyl-transferase I, a second enzyme located in the outer membrane o f the mitochondria, which converts acyl-GoA esters to acylcamitines (Murthy and Pande, 1987). Once inside the mitochondria, acylcarnhines are converted back to by acyl-CoA 10 000125 esters by carnitine acyltransferase II, and degraded by mitochondrial (3-oxidation to acetylCoA (McGarry and Foster, 1980; Bieber, 1988). Acetyl-CoA is shuttled into the cytosol by the citrate transport system for cholesterol and lipid synthesis (Stryer, 1994). The key factor regulating the rate o f mitochondrial (3-oxidation is the amount o f FA entering the mitochondria which, as stated above, is controlled by carnitine acyl-transferase I. The activity o f carnitine acyl-transferase I is controlled by the abundance o f malonyl-CoA, the first committed intermediate in FA synthesis (McGarry and Foster, 1980). According to Bass et ai. (1993), under conditions o f increased FA biosynthesis, malonyl-CoA production is increased. Malonyl-CoA is produced from acetyl-CoA in a reaction catalyzed by acetyl-CoA carboxylase, an enzyme controlled by reversible phosphorylation responding to hormone signals and the presence o f fatty acyl-CoA (Moran and Scrimgeour, 1994). When fatty acyl-CoA levels are low, acetyl-CoA carboxylase activity is high. This enhances the conversion o f acetyl-CoA to malonyl-CoA. When malonylCoA is plentiful, the activity of camitine-acyltransferase I is limited. This causes the rate of mitochondrial (3-oxidation to decrease; FFAs to accumulate; acyl-CoA production and hence cholesterol synthesis to slow; and the rates o f alternate routes o f FA catabolism, peroxisomal (3-oxidation and 0-oxidation in the endoplasmic reticulum (ER), to increase (L ocke/ a i, 1989). Peroxisomal 3-oxidation is normally responsible for catabolizing most, if not all, o f the very long chain fatty acids brought into the hepatocyte (Singh et al., 1981; Singh et al, 1984; Lazo et a i, 1990; Jakobs and Wanders, 1991). This system is also capable o f oxidizing medium and long chain FAs and previously activated CoA esters o f medium and 11 000126 long chain dicarboxylic acids. Under normal conditions, however, mitochondrial oxidation is the dominant route of catabolism for such substrates (Singh et a i , 1987). Peroxisomal -oxidation proceeds through similar steps as does mitochondrial oxidation, however, important differences exist. First, the enzymes used in each process are different proteins (Hashimoto, 1987). Secondly, peroxisomal -oxidation does not degrade FAs to their two carbon fragments as does mitochondrial -oxidation; rather, peroxisomal -oxidation stops after a few cycles, only shortening the carbon chain (Lazarow, 1978; Thomas etal., 1980). Thirdly, peroxisomal -oxidation is not coupled to an electron transport chain and oxidative phosphorylation as is mitochondrial oxidation (Lazarow and de Duve, 1976; Mannaerts et al., 1979). Thus, while mitochondrial -oxidation produces ATP and ketone bodies, peroxisomal -oxidation produces hydrogen peroxide and heat. The rate o f peroxisomal -oxidation is thought to be controlled by substrate supply, specifically the activity o f acyl-CoA oxidase, which reduces molecular oxygen to hydrogen peroxide in the first step o f peroxisomal oxidation (Mannaerts et a i, 1979; Miyazawa et a i, 1983). Like substrates for mitochondrial -oxidation, substrates for peroxisomal -oxidation must be esterified to their acyl-CoA derivatives; however, peroxisomal -oxidation is not dependent on carnitine acyl transferase I, as is mitochondrial -oxidation (Mannaerts and Van Veldhoven, 1993). co-Oxidation in the ER, a P450 ivai mediated process, is responsible for converting monocarboxylic acids to dicarboxylic acids. Dicarboxylic acids are activated in the ER by 12 000127 dicarboxylyl-CoA synthetase, an enzyme absent in mitochondria and peroxisomes. CoA esters o f dicarboxylic acids are almost entirely dependent on mitochondrial 3-oxidation for catabolism (Suzuki et al., 1989). The ER also oxidizes bile acid intermediates and is able to esterify very long chain fatty acids (Singh and Poulos, 1988; Lazo et al., 1990). A prerequisite o f esterification is activation o f FAs to their CoA derivatives (Mannaerts and Van Veldhoven, 1993). -Oxidation in the ER is enhanced in cases o f FA overload (eg uncontrolled diabetes) or inhibition o f mitochondrial P-oxidation (Mortensen and Gregersen, 1981; Golden and Kean, 1984; Mortensen, 1986; Vianey - Liaud etal., 1987); and like peroxisomal P-oxidation, G>-oxidation is not dependent on carnitine acyl transferase I (Mannaerts and Van Veldhoven, 1993). Hypothesis As stated above, exposure to FCs leads to mitochondrial inhibition, cholestasis, peroxisome proliferation, and tumor formation in rodents. Three o f these endpoints mitochondrial inhibition, cholestasis and peroxisome proliferation - are directly linked to FA metabolism. This study was designed to test the hypothesis that an initial step in FCinduced peroxisome proliferation is displacement o f FAs from L-FABP by FCs. This hypothesis is supported by the fact that L-FABP has been shown to bind nongenotoxic peroxisome proliferators, including certain FCs, in vitro (Vanden Heuvel, 1996; Issemann etal., 1992), with relative strengths o f binding that parallel their ability to elicit peroxisome proliferation (Brandes et al., 1990; Kanda et al., 1990; Cannon and Eacho, 1991). According to the theory under question, upon displacement o f FAs from L-FABP, the intracellular levels o f fatty acyl-CoA would decrease. This would increase the activity 13 000128 of acetyl-CoA carboxylase and enhance the conversion o f acetyl-CoA to malonyl-CoA. An increase in the level o f malonyl-CoA would repress the activity o f carnitine acyltransferase I, and inhibit mitochondrial P-oxidation. -Oxidation in the ER would be enhanced, increasing the production o f dicarboxylic acids. PPARs would be activated, by the binding o f FAs or metabolic intermediates such as dicarboxylic acids, and specific gene transcription o f acyl-CoA oxidase, L-FABP and P450 ivai would be induced. A positive relationship between the amount o f L-FABP and the rate o f peroxisomal P-oxidation has been found (Appelkvist and Dallner, 1980), and the level o f acyl-CoA oxidase is thought to determine the rate o f peroxisomal P-oxidation (Mannaerts et al., 1979; Miyazawa et a l, 1983). Thus, increased transcription o f acyl-CoA oxidase and L-FABP would increase rates o f peroxisomal P-oxidation and elicit peroxisome proliferation. Induction o f P450ivai genes would further increase the rate o f -oxidation in the ER. Cholesterol synthesis would eventually cease in response to mitochondrial inhibition and lack o f acetyl-CoA production, and decreased esterification by the ER due to decreased acyl-CoA. This would lead to cholestasis. The mechanisms by which carcinogenesis could be induced or promoted will not be discussed. 14 000129 MATERIALS AND METHODS Materials Wyeth-14,643 (WY) was obtained from ChemSyn Science Laboratories, Lexena, KS; FCs were provided by 3M Speciality Chemicals Division, St. Paul, MN; Optifluor LSCcocktail was obtained from the Packard Instrument Company, Meriden, CT; AMICON YM-5 membrane was purchased from Amicon Corporation, Lexington, MA, BCA Protein Assay was obtained from Pierce Chemical Company, Rockford, EL; and 11-(5Dimethylaminonapthalenesulphonyl)-undecanoic acid (DAUDA) was purchased from Molecular Probes, Eugene, OR. All other chemicals were obtained from VWR Scientific, West Chester, PA. A nim als and T reatm ent Male rats and guinea pigs, 6-8 weeks of age, weighing between 150 and 250 grams were purchased from Charles River Labs, Wilmington, M A . Following an adaptation period of one week after arrival at 3M, animals were weighed, ear-tagged and exposed. The treatment groups consisted o f the following: 1. Guinea Pig Vehicle Control - Tween 80, 2% (n = 4); 2. Rat Vehicle Control - Tween 80, 2% (n = 4); 3. Guinea Pig FC1 - FC1 in Tween 80, 2% (n = 4); and, 4. Rat FC1 - FC1 in Tween 80, 2% (n = 4). All treatments were administered by intraperitoneal (ip) injection. The vehicle control groups were dosed at 5ml / kg body weight 2% Tween 80. The FC1 groups were dosed at 15 000130 5 ml / kg body weight with a suspension o f 32 mM FC 1 in Tween-80, 2% (86 mg FC1 / kg body w eight). All animals were housed individually in controlled environments and observed for mortality and clinical signs o f toxicity during the first four hours after dosing, at 24 hours, and daily thereafter for the duration o f the study. Animals were sacrificed with CO2 12 days after dosing. Body weights and selected organ weights (liver, kidneys, testes) were recorded at necropsy. Organ tissues and body fluids were stored frozen at 70C for biochemical analysis or in 10% buffered formaldehyde for subsequent histological analysis. Selected livers were perfused with and stored in gluteraldehyde for future histological analysis by light microscopy. purification of l-fabp Protein purification was performed at the University o f San Francisco, CA (UCSF) Liver Research Center. Three frozen livers (rat FC1, guinea pig vehicle control, and guinea pig FC1) were shipped in dry ice from 3M to UCSF. These livers and one fresh liver, from a non-treated rat (control) sacrificed at UCSF, were purified. Frozen livers (approximately lOg each) were thawed and weighed. The fresh liver (approximately lOg) was isolated and perfused with isotonic saline. Each liver was homogenized 30% (w/v) in ice-cold lOmM potassium phosphate buffer, pH 7.4, using a Teflon-glass Potter-Elvehjem tissue homogenizer. The homogenates were centrifuged for 20 minutes at 10,000g in a Sorvall superspeed RC2-B centrifuge maintained at 4C. The supernatants were removed and subsequently centrifuged for one hour at 38-40,000 rpm (4C) in a Beckman L7 Ultracentrifuge. The resulting supernatant (cytosol) was labeled with 0.5pCi o f 1-14C oleate to trace the L-FABP during purification. 16 000131 Purification steps were performed in a cold room at 4C. The cytosol was loaded on a Sephadex G50 M column (5 x 60 cm) equilibrated with lOmM potassium phosphate buffer, pH 7.4. Protein was eluted from the column at a flow rate o f approximately 1.4 ml/minute. One hundred fractions were collected (approximately 14.5 ml/fraction). Optifluor LSC-cocktail (5 ml) was added to a 20pl aliquot o f each fraction and a Packard Tri-carb 4530 scintillation counter was used to assess L-FABP activity. Fractions with LFABP activity were pooled and concentrated to approximately 5ml using a vacuum filter apparatus fitted with an AMICON YM-5 membrane. Guinea pig samples (control and FC1 treated) were concentrated and frozen at this point. Rat samples (control and FC1 treated) were further purified as follows. The concentrated solution was loaded on a Sephadex G50 (fine) gel filtration column (2.5 x 45 cm) equilibrated with lOmM potassium phosphate buffer, pH 7.4. The flow rate was approximately 0.9 ml/minute. Sixty fractions were collected at a volume o f 3.48ml/fraction. The fractions containing L-FABP activity were pooled and concentrated to approximately 5ml. The concentrated cytosol was dialyzed overnight at 4C against 30mM Tris-HCl, pH 9, using a Spectrapore Membrane MWCO 3,500. The sample was then applied to a DEAE-cellulose column (Whatman DE-52, 1.25 x 15cm or 2.5 x 15cm) previously equilibrated with 30mM Tris-HCl, pH 9, (degassed). The column was eluted with 30mM Tris-HCl, pH 9, (degassed) followed by a linear gradient o f NaCl (0-0.2M) in 30mM Tris-HCl, pH 9. The flow rate was approximatly lml/minute. Twenty fractions, 7.8 ml each, were collected. 17 00013 Homogeneity o f the final rat control and rat F C 1 fractions was assessed using sodium dodecyl sulfate / polyacrylamide-gel electrophoresis (SDS PAGE) analysis, and confirmed by the appearance o f a dominant protein band at molecular weight (MW) 14,000 Daltons (Da.) (Figure 4). Protein concentration o f all samples was determined using the bicinchonic acid (BCA) protein assay by Pierce with BSA as the standard (Table 1). None o f the samples were delipidated. Figure 3 - SDS PAGE Analysis of fractions Following Purification of L-FABP from Rat Liver Cytosol. M arker M r values are shown. Rat Control L-FABP to- ac RATFC1 L-FABP 18 000133 Table 1 - Protein Concentration. Protein concentration was determined using the BCA protein assay with BSA as the standard. Values are a mean standard deviation o f 2 trials.____________________ FRACTIONS TOTAL PROTEIN ____ CONCENTRATION (ng/ml) PURIFIED Rat Control Rat FC1 123.1 13.7 308.8 1.4 PARTIALL Y PURIFIED Guinea Pig Vehicle Control Guinea Pig FC1 1755.7 10.1 1021.0 129.7 Fluorescence Measurements Fluorescence measurements were based on the work o f Wilkinson and Wilton (1986). All assays were carried out at room temperature using a slit with o f 5nm in a SPEX 1681 0.22m spectrometer, SPEX Industries, Incorporated. A stock solution o f DAUDA, 0. ImM, was prepared by slowly adding 50mM potassium phosphate (KH2PO4) buffer, pH 7.2, to ImM D A U D A in methanol. All further dilutions o f D A U D A were in 50mM KH2PO4, pH 7.4. All dilutions ofL-FABP samples were in 5O111MKH2PO4, pH 7.4. All FCs, WY and oleic acid were dissolved in methanol. All measurements were made after binding had reached equilibrium. Fluorescence Characterization Emission and Excitation Maxima and Average Maximum Fluorescence Intensity The maximum emission and excitation wavelengths (nm) and average maximum fluorescence intensity (FI) (cpm) were determined for lpM DAUDA binding to each L- 19 FABP sample. L-FABP, from original undiluted stock, was added to 2ml 1pM DAUDA in aliquots o f 1 .6 -1 14pl (depending on the concentration o f protein) until no further change in emission or excitation wavelength or FI was detected. The range o f protein concentrations analyzed for each L-FABP sample was 0.1 pM-3pM. Excitation scans, from 250-400nm using an emission wavelength o f 500nm, and emission scans, from 350600nm upon excitation at 350nm, were performed with each addition. FI (Em. 500nm, Ex., 350nm) was measured following each addition o f L-FABP. Curves o f FI versus concentration o f L-FABP, representing an average standard deviation o f 3 trials, were constructed for each L-FABP sample. The three highest FI values for each curve were averaged to determine the average maximum FI for DAUDA binding to each sample. Specific DAUDA Binding Total binding o f DAUDA (0-8 pM) to each L-FABP sample was determined by adding 220pl aliquots o f O.lmM DAUDA to 2ml lpM L-FABP. Increased FI (Em. 500nm, Ex., 350nm) due to the binding of DAUDA to protein was measured. Nonspecific binding was assessed by saturating L-FABP binding sites with oleic acid and performing the same titration. Aliquots, 2-20pl, o f 0. ImM DAUDA were added to a 2ml solution o f 1pM LFABP and lOOpl oleic acid. Specific binding o f DAUDA to each L-FABP sample was determined by subtracting nonspecific binding from total binding. Anal ysis of the Effect of FCs of L-FABP Calculation o f DAUDA Binding Constants (K j B ^ ) Kd and Bmax values were determined for each protein. Specific binding was transformed to units o f bound DAUDA (pM) by dividing the specific FI (cpm) by the maximum FI per 20 00013S IpM DAUDA (cpm) for each L-FABP sample. Computer assisted nonlinear regression (GraFit Version 3, Erithacus Software Limited) was used to construct curves of specific bound DAUDA versus free DAUDA representing an average of 3-6 trials. The following equation was used. Bound = ([L] x Bmax)/(Kd + [L]). Calculation of Oleic Acid K V s The concentration of oleic acid which inhibits 50% of specific DAUDA binding, the IC50, was calculated for each combination of oleic acid and L-FABP sample. Cuvettes contained 2ml IpM L-FABP and IpM DAUDA. Oleic acid, ImM in 10% methanol, was added in 0.4-20 pi aliquots. FI (cpm) (Em. 500nm, Ex. 350nm) due to the binding of DAUDA to protein following each addition was measured. Curves of percent inhibition of specific DAUDA binding versus oleic acid concentration, representing an average standard deviation of 3-6 trials corrected for the effect of methanol, were constructed. Analysis of the Potency of Various FCs for Binding to L-FABP Competitive Binding Experiments - Calculation of ICsals Cuvettes contained 2 ml IpM rat control L-FABP and IpM DAUDA. Ligands, ImM (FCs and WY in 100% methanol, and methanol in 50mM KEhPQj.pH 7.2), were added in 0.4-20 pi aliquots. FI (cpm) (Em. 500nm, Ex. 350nm) due the binding of DAUDA to protein following each addition was measured. Curves of percent inhibition of specific DAUDA binding versus competitor concentration, representing an average standard deviation of 3-6 trials corrected for the effect of methanol were constructed. The concentration of each competitor which inhibited 50% of specific DAUDA binding, the IC50, was calculated. 21 00013 RESULTS & DISCUSSION Fluorescence Measurements Fluorescence Characterization EfUISSlon Mid Excitation M^xunuin The emission and excitation spectra of each protein binding DAUDA was analyzed to determine the optimal conditions for the study. The maximum emission and excitation wavelengths for all proteins were approximately 500 and 350nm respectively (Table 2). Values for guinea pig L-FABP samples were slightly higher than those for rat samples. This difference is likely because guinea pig samples were only partially purified; thus, more cellular debris remained to potentially interfere with DAUDA binding, and less L-FABP as a proportion of total protein was present. A "blue shift" in both emission and excitation wavelength occurred upon the addition of each L-FABP sample to DAUDA. Excitation wavelength shifted from approximately 330 to 340nm (Figure 4), and emission wavelength shifted from approximately 550 to 500nm (Figure 5). This shifting of wavelength is characteristic of DAUDA binding to a nonpolar site on L-FABP (Wilkinson and Wilton, 1986). According to Thumser etal. (1994a), DAUDA only binds one of the two oleatebinding sites of L-FABP. Due to the stringent conformational requirements of primary site binding (internalized carboxylate/polar group and a U-shaped hydrocarbon/hydrophobic chain), DAUDA most likely binds the secondary site. Similar shifting of fluorescence wavelength and emission and excitation maxima were found by Wilkinson and Wilton (1986) and Thumser, Vosey and Wilton (1996). 22 000137 Table 2 - Em ission and Excitation Maxim a. Fluorescence emission maxima (nm) were measured upon excitation at 350nm. Excitation maxima (nm) were measured using an emission wavelength o f 500nm. L-FABP was added to IpM DAUDA until no further change in emission or excitation wavelength was detected. Each value is an average standard deviation o f 3 trials._____________________ SAMPLE EMISSION EXCITATION __________________________________ MAXIMUM (nm) MAXIMUM (nm) DAUDA only 551.33 1.53 331.00 1.00 Rat Control L-FABP 502.67 4.62 344.33 2.08 Rat FC1 L-FABP 502.33 4.04 339.67 6.66 Guinea Pig Vehicle Control L-FABP 511.00 7.81 340.67 5.13 Guinea Pig FC1 L-FABP 511.00 7.81 333.67 1.15 00013S 000139 Average Maximum Fluorescence Intensity The average maximum FI (cpm) o f 1pm DAUDA binding to L-FABP from FC1 treated and non-treated animals did not substantially differ. The average maximum FI was approximately 850,000 cpm for rat L-FABP samples, and 660,000 cpm for guinea pig LFABP samples (Table 3). Maximum FI was reached following the addition o f lp M rat control L-FABP, 2.5pM rat FC1 L-FABP, 2.5pM guinea pig vehicle control L-FABP and 2pM guinea pig FC1 L-FABP (Figure 6). The lower the affinity o f receptor for probe, the higher the concentration o f receptor needed for binding, and vice versa (Matthews, 1993). Thus, these data suggest that the rat FC1 L-FABP sample had a decreased affinity for DAUDA as compared to the rat control L-FABP sample, and that the guinea pig FC 1 sample had an increased affinity for DAUDA as compared to the guinea pig vehicle control L-FABP sample. The average maximum FI for guinea pig samples was 77.6% lower than that for rat samples. This may be due to the impurity o f the guinea pig samples resulting in a high degree of interference in DAUDA binding and a lower concentration o f L-FABP as a proportion o f total protein. Table 3 - Maximum FI of 1uM DAUDA. Cuvettes containing 2 ml 1pM DAUDA were titrated with rat and guinea pig L-FABP samples (0. ImM) to determine the maximum FI o f 1pm DAUDA binding to each sample. Three trials per protein were performed. Values are the average standard deviation of the 3 highest average FI values per protein. L-FABP SAMPLE MAXIMUM FI (com) Rat Control 848,093 13,639 Rat FC1 852,438 24,776 Guinea Pig Vehicle Control 655,348 63,812 Guinea Pig FC 1 669,632 33,619 25 000140 FIGURE6 - A v e r a g e Maximum FI o f IliM DAUDA. FI vs fL-FABPl. Cuvettes containing 2 ml lpM DAUDA were titrated with rat and guinea pig L-FABP samples (0.1 mM) to determine the maximum FI of 1pm DAUDA binding to each sample. FI, due to the binding of DAUDA to protein, was measured after each addition. Each curve is an average of 3 trials. -- Rat Control -- -- Rat PTOS --A - Guinea Rg V . Control -- -- Guinea Rg PFOS Specific DAUDA Binding Because of its well documented high affinity for L-FABP (Thumser et al., 1994 a,b; Thumser and Wilton, 1994; Thumser etal, 1996; Thumser and Wilton, 1995), oleic acid was chosen as the displacing ligand to determine nonspecific binding of DAUDA to LFABP. Excess oleic acid was added to occupy all L-FABP binding sites and prevent the specific binding of DAUDA to L-FABP. DAUDA was titrated into the assay and FI, due to nonspecific binding, was observed. Total binding was determined by performing the assay in the absence of oleic acid; specific binding was calculated by subtracting nonspecific binding from total binding. Absolute FI values are given in Table 4. The breakdown of total binding into percent specific and nonspecific binding is shown in Figure 7. 26 000141 Table 4 - luM DAUDA Binding to luM L-FABP. Total binding of DAUDA to each L-FABP sample was determined by adding aliquots of O.lmM DAUDA to 2ml lpM L-FABP. Increased FI due to the binding of DAUDA to protein was measured. Nonspecific binding was measured in the presence of lOOpM oleic acid. Specific binding of DAUDA to each L-FABP sample was determined by subtracting nonspecific binding from total binding. Values are an average standard deviation of 3-6 trials (cpm). L-FABP Sample Rat Control R atF C l Guinea Pig V. Control Guinea Pig FC1 TOTAL 818.000 124,000 302.000 81,000 219.000 138,000 162.000 15,000 NONSPECIFIC 78.000 26,000 96.000 21,000 92.000 23,000 94.000 65,000 SPECIFIC 740.000 124,000 206.000 81,000 127,000 138,000 68,000+ 15,000 27 000142 Figure1:-DAUDA Binding, Total binding of DAUDA to each L-FABP sample was determined by adding aliquots of 0. ImM DAUDA to 2ml lpM L-FABP. Increased FI due to the binding of DAUDA to protein was measured. Nonspecific binding was measured in the presence of 100pM oleic acid. Specific binding of DAUDA to each L-FABP sample was determined by subtracting nonspecific binding from total binding. Values are an average of 3-6 trials. RAT CONTROL L-FABP Nonspecific 10% Specific 90% RAT PC-7- L-FABP Nonspecific 32% Specific 68% GUINEA PIG VEHICLE CONTROL L-FABP Specific 58% Nonspecific 42% GUINEA PIG p e a L-FABP Specific 42% Nonspecific 58% 28 000143 Specific binding o f DAUDA to rat control L-FABP represented approximately 90% o f total binding, while specific binding o f DAUDA to rat FC1 L-FABP accounted for only 68% o f total binding. When a ligand has lower affinity for a receptor, a larger proportion o f total binding is nonspecific (Matthews, 1993); thus, these data suggest the rat FC1 LFABP sample had a three fold lower affinity for DAUDA than the rat control L-FABP sample. This is consistent with the results o f the average maximum FI analysis o f the rat L-FABP samples, which also suggests the affinity o f L-FABP for DAUDA was decreased in the FC 1 sample. Less o f a difference was seen between the two guinea pig L-FABP samples. Specific binding o f 1pM DAUDA to 1pM L-FABP represented 58% o f total binding in the guinea pig vehicle control L-FABP sample, and 42% of total binding in the guinea pig FC1 sample. The data suggest the guinea pig FC1 L-FABP sample had lower affinity for DAUDA than the guinea pig vehicle control L-FABP sample. This is not consistent with the results o f the average maximum FI analysis, which suggest the relative affinity o f the guinea pig FC1 L-FABP sample was higher than that for the guinea pig vehicle control L-FABP sample. This inconsistency may be due to the crudeness o f the guinea pig samples giving rise to a high degree o f interference in the binding o f DAUDA to L-FABP. The overall crudeness o f the guinea pig L-FABP samples, as compared to the rat L-FABP samples, is reflected in a lower absolute total DAUDA binding (cpm), a higher percent nonspecific binding and a lower percent specific binding. 29 000144 Anal ysis of the E ffect of FCs on L- FABP Calculation of DAUDA Binding Constants DAUDA binding constants were calculated for each L-FABP sample. The purpose of this analysis was to assess the effect of FC1 on the functionality of L-FABP; and to confirm the results shown thus far, which suggest the affinity of L-FABP for DAUDA was decreased in FC1 treated rat L-FABP samples, and that guinea pig L-FABP samples were too impure to accurately analyze. The maximum binding capacity or receptor number (Bmax) of each L-FABP sample and the dissociation constant or affinity (Kd) of each L-FABP sample for DAUDA were determined using computer assisted nonlinear regression (Table 5 and Figure 9). Specific binding of DAUDA to each L-FABP sample was converted to )iM by dividing the FI (cpm) due to specific DAUDA binding (Table 4) by the average maximum FI (cpm) per lpM DAUDA for each L-FABP sample (Table 3). The Bmax of rat control L-FABP was nearly l|iM . This agrees with the work o f Thumser et al. (1994 a,b), Thumser and Wilton (1994) and Thumser et al. (1996) who all found DAUDA to bind to one of the oleic acid binding sites on L-FABP. The Bmax for the rat FC1 L-FABP sample was approximately 0.35p.M, suggesting the capacity of rat FC1 LFABP to bind DAUDA was nearly one third that of rat control L-FABP. One possible explanation for this decreased capacity is that FC1 is bound to L-FABP in the FC1 sample, rendering fewer available binding sites and allowing less DAUDA to bind. The rigid tail of 30 000145 FC 1 (Zisman, 1964) and strict conformational requirements for primary site binding to LFABP (Thompson et al., 1997) suggest FC 1 binding would occur in the secondary binding site. Another possible explanation is that the vehicle (Tween 80,2% ) somehow affected the binding of DAUDA to L-FABP in the FC 1 treated sample. This is unlikely, however, since Tween 80 is a mild, non-ionic detergent, designed to allow solubilized proteins to retain their native structure (Sigma, 1998); and because a low concentration of Tween 80 used (see methods). This does point out, however, the importance of including a vehicle control in the experiment. The Kds for the rat control L-FABP and rat FC1 L-FABP samples were not notably different and were comparable to the Kd of 0.38 0.02|iM found by Thumser et al. (1996). Thus, although the data for average maximum FI and percent specific binding suggest a decreased affinity of rat FC1 L-FABP for DAUDA as compared to rat control L-FABP, the Kd and Bmax values suggest the maximum binding capacity/number of binding sites rather than the binding affinity was affected. The Bmax of the guinea pig vehicle control L-FABP sample was much lower than expected, 0.28 lp.M as compared to approximately l(iM for the rat control L-FABP sample. The Kd for the guinea pig vehicle control L-FABP sample was higher than expected, 0.48nM as compared to approximately 0.3)iM for the rat control L-FABP. One possible explanation for these differences in results is that rat L-FABP and guinea pig L-FABP are different Although the crystal structure of guinea pig L-FABP has not been deduced, sequence identity for FABPs of the same tissue type from different species is 31 000146 approximately 82-92% (Richieri, Ogata and Kleinfeld, 1994). One can, therefore, expect the binding constants of control guinea pig and rat L-FABP to be comparable. Other possible explanations for this difference are that the vehicle (Tween 80, 2%) had some effect on the L-FABP, or that the crudeness of the guinea pig sample caused a great deal of interference with the binding of DAUDA to L-FABP. As mentioned above, the affect of Tween 80 is presumably minimal; thus, the crudeness of the sample is likely to be to blame for the unexpected binding constants. As discussed previously, the results for specific binding of DAUDA to guinea pig L-FABP suggest the guinea pig FC1 L-FABP sample had lower affinity for DAUDA than the guinea pig vehicle control L-FABP sample. This suggestion was counter to the results for average maximum FI, which indicate the guinea pig FC1 sample had an increased affinity for DAUDA as compared to the guinea pig vehicle control L-FABP sample. These contradictory data, when combined to calculate a Kd and Bmax for each guinea pig LFABP sample, resulted in a Kd for the guinea pig FC1 L-FABP sample that was about 4.5 times that of the vehicle control sample, and a capacity of the guinea pig FC1 L-FABP sample that was about twice that of the guinea pig vehicle control L-FABP sample. These results are inconsistent and inconclusive, likely due to the impurity of the guinea pig samples, as discussed above. 32 000147 Tables - DAUDA Binding Constants. Values are an average standard deviation of 3 trials as calculated by computer assisted nonlinear regression. Bound = ([L] x Bmax)/(Kd + [L]). L-FABP SAMPLE BmaxfriM) Kd OiM) Rat Control 0.987 0.016 0.278 0.020 RatFCl 0.345 0.012 0.260 0.063 Guinea Pig Vehicle Control 0.281 0.043 0.480 0.391 Guinea Pig FC 1 0.413 0.060 2.240 0.852 Figure 8 - Specific Bound vs Free DAUDA. Computer assisted nonlinear regression was used to construct curves of specific bound DAUDA versus free DAUDA (Bound = ([L] x Bmax)/(Kd + [L])). Each curve is an average of 3-6 trials. The reduced chi square value for each regression was as follows: rat control L-FABP, 3.83e-16; rat FC1 L-FABP, 7.83e-16; guinea pig vehicle control LFABP, 6.12e-15; and guinea pig FC1 L-FABP, 1.67e-15. RAT CONTROL L-FABP RAT L-FABP Free (pM) 0.35 0.30 0.25 f o5 0.20 0.15 m 0.10 0.05 0.00 0.17 0.29 0.76 0.12 0.17 0.22 0.27 0.32 Frae (pM) GUINEA PIG CONTROL L-FABP Fra* (pM) GUINEA PIG FC.X L-FABP 0.35 0.30 5 0.25 ~ 0.20 1 0.15 m 0.10 0.05 0.00 0.09 0.47 1.35 2.26 3.22 4.25 5.68 7.68 FraaftiM) 33 000148 Calculation of Oleic Acid ICTM's An IC50 was calculated for each combination of oleic acid and L-FABP sample to assess the functionality of L-FABP from FCl-treated and non-treated rats and guinea pigs. Oleic acid, ImM in 10% methanol, was titrated into 2 ml lpM L-FABP and lpM DAUDA. FI (cpm), due the binding of DAUDA to protein, was measured following each addition. Curves of percent inhibition of specific DAUDA binding versus oleic acid concentration were constructed (Figure 9). Table 6 shows the percent inhibition of specific DAUDA binding by 2|iM oleic acid and the ICso values for each L-FABP sample. As discussed in the introduction, oleic acid is capable of binding both primary and secondary L-FABP binding sites; and once a ligand has bound the primary site, binding to the secondary site is facilitated (Thompson et al., 1997). This relatively unconstrained binding of oleic acid to L-FABP is reflected in a sharp decrease in FI (cpm) and an increase in DAUDA-specific binding inhibition upon the addition of micro-molar quantities of oleic acid to solutions of L-FABP and DAUDA. Ninety one percent of specific DAUDA binding to rat control L-FABP was inhibited by 2|iM oleic acid; and the ICjoof oleic acid for the rat control L-FABP sample was O.OlpM. This percent inhibition was higher than that found by Thumser et al. ( 1994b), Thumser et al. (1996) and Thumser and Wilton (1995), of 80.5%, 76% and 80% respectively, under similar conditions. The percent inhibition was much lower (52%) and IC50 much higher (0.5|iM) for the rat F C 1 L-FABP sample as compared to the rat control L-FABP sample. This suggests the ability of L-FABP from the FCl-treated rat to bind oleic acid was decreased. One explanation for this decrease in functionality, is that FC1 was bound to L- 34 000149 FABP in the FC1 treated sample, rendering fewer sites available to bind oleic acid and requiring more oleic acid to achieve 50% inhibition. This agrees with the results presented for the analysis of average maximum FI, specific DAUDA binding and DAUDA binding constants in rat L-FABP samples. The percent inhibition of specific DAUDA binding to the guinea pig vehicle control LFABP sample upon addition of 2pM oleic acid was 93%; that for the guinea pig FC1 sample was 63%. This is similar to the results for the rat samples; however, the curves of percent inhibition versus oleic acid concentration for rat and guinea pig samples were very different (Figure 9). The curves for rat samples were hyperbolic while the curves for guinea pig samples were more linear and scattered. The resulting IC50 values for both guinea pig L-FABP samples were the same, 0.2fiM oleic acid. The data are ambiguous, and are likely due to the crudeness of the guinea pig samples. Table 6 - Oleic Acid IC*>'s & Percent Inhibition of Specific DAUDA Binding. The ICsoof oleic acid for each L-FABP sample was calculated by adding oleic acid, IraM in 10% methanol, to a solution of lpM L-FABP and lpM DAUDA. Values are ICso's of oleic acid for each L-FABP sample and percent inhibition of specific DAUDA binding by 2pM oleic acid. L-FABP Sample Oleic Acid IC50 (|i-M) % Inhibition by 2pM oleic acid Rat Control 0.01 91 RatFCl 0.5 52 Guinea Pig Vehicle Control 0.2 93 Guinea Pig FC1 0.2 63 35 000150 Figure 9- % DAUDA Inhibition vs fOleic a c id I. Oleic acid, ImM in 10% methanol, was added to a solution of lpM L-FABP and IpM DAUDA. Curves represent an average of 3-6 trials corrected for the effect of methanol. RAT L-FABP 100% 80% c A 60% 1 40% 5 20% 0% 0.00 0.02 0.10 0.20 1 [olaic acid] (|M ) 2 GUINEA PIG L-FABP [oMc acid] (|iM) ANALYSIS OF THE POTENCY OF FCS FOR BINDING TO L-FABP Competitive Binding Experiments - Calculation of IC ^'s An ICso of each FC, WY and methanol was calculated for DAUDA binding to the rat control L-FABP sample. Each ligand (ImM, in 100% methanol or 50mM KH2PO4, pH 7.2) was titrated into 2ml lpM rat control L-FABP and lpM DAUDA. The addition of 36 000131 competitor to L-FABP and DAUDA induced a shift o f emission wavelength back towards the curve o f DAUDA with no L-FABP (Figure 10). This is indicative o f DAUDA being displaced from a nonpolar binding site on L-FABP, such as the secondary binding site. To varying degrees, similar shifting and decreases in FI occurred upon addition o f each competitor. FI (cpm), due the binding o f DAUDA to protein, was measured following each addition of competitor; and curves o f percent inhibition o f specific DAUDA binding versus ligand concentration constructed (Figure 11). Table 8 gives the percent inhibition o f specific DAUDA binding by 10pM competitor and the ICso values for each competitor. FC1 was the strongest inhibitor o f specific DAUDA binding, with 69% inhibition upon the addition o f lOpM and an IC50o f 4.9pM. FC4 was the next strongest, with 51% inhibition upon the addition o f lOpM and an IC50o f 9.7pM. Wyeth followed FC4, with 50% inhibition upon the addition o f 10pM, and an IC50o f lOpM. FC3 and FC2 both inhibited 43% o f specific DAUDA binding upon the addition o f lOpM and had ICS0's greater than lOpM. Thumser and Wilton (1996) suggest that ligands for L-FABP need to have both a hydrophobic and a hydrophilic domain. Each FC and WY fits this description to varying degrees. Due to the rigid tail o f the FCs and the bulky structure o f WY, it is likely that binding o f each o f these competitors to L-FABP occurs in the secondary binding site on L-FABP. It is conceivable that the FCs bind with their rigid hydrophobic CF tails, analogous to the flexible CH tail o f oleic acid, in the secondary binding site and that the polar head groups o f FCs are solvent exposed as is the carboxylate group on oleic acid. 37 00015 To reason by structure, the varying potencies o f each FC to binding L-FABP is difficult. Thompson et al. (1997) suggest that anything larger than a C u molecule may require prior binding in the primary site. As was mentioned in the introduction, Cg and Cio FCs are the most potent peroxisome proliferators. It may be the case that Cg and Cio molecules bind most readily to the secondary binding site on L-FABP, not requiring a molecule to be bound in the primary binding site. All o f the FCs examined in the present study were Cg molecules; thus, an analysis o f chain length cannot be undertaken at this time. The disparate potencies o f binding L-FABP between FCs do not appear to be due to differences in polarity and hydrogen bonding ability. For example, FC2, having a very polar carboxylate head group, and capable o f extensive hydrogen bonding, has a higher ICso than FC4, which has a less polar head group and less ability to hydrogen bond (see Figure 1). The binding o f WY to the secondary binding site on L-FABP is difficult to reason. In place o f the hydrophobic tail, present on FCs and oleic acid, WY has two aeromatic rings. The conformational flexibility o f L-FABP may accommodate this bulky structure internally, and position the carboxylate externally, in a solvent exposed manner able to participate in hydrogen bonding. Thompson et al. (1997) also speculate that a third binding site, located completely on the exterior o f L-FABP, may exist. Only the first few carbons o f a molecule binding to such a site would be bound in an organized fashion, the remaining portion o f the ligand would be disordered. This, although highly speculative, may be the site o f WY binding to L-FABP. 38 000153 Methanol was chosen as the negative control because a non-peroxisome proliferator, similar in structure to the FCs being researched, has not been identified. Upon the addition o f 1OpM methanol, 21% o f specific DAUDA binding was inhibited. The I C jo o f methanol was much greater than lOpM. It is reasonable to suggest methanol is capable of weakly binding the secondary L-FABP binding site, with the CH3 group internally located and the OH group exposed to the exterior o f the protein. The structure o f methanol renders it an unlikely candidate for looping into a U-shape and participating in primary site binding. 39 000154 Figure 10 - chromatogram. The addition o f competitor to L-FABP and DAUDA induced a shift o f emission wavelength back towards the curve o f DAUDA with no L-FABP. This is indicative o f DAUDA being displaced from a nonpolar binding site on L-FABP. To varying degrees, similar shifting and decreases in FI occurred upon addition o f each competitor. The example shown is for FC2 binding rat control L-FABP. KEY : a = luM DAUDA, liML-FABP; b = lpM DAUDA, 1L-FABP, IOjiM FC2; c * IuMDAUDA, ljiM L-FABP, 15fiMFC2; d = ljiM DAUDA, IpM L-FABP, 20nM FC2; e = l(iM DAUDA; f = 0 DAUDA, 0 L-FABP, 50mM KH2P04 40 000155 Table 8 - IO n's of FCs and WY & Percent Inhibition of Specific DAUDA binding. The IC50of each competitor for the rat L-FABP sample was calculated by adding competitor (Im M ) to lpM L-FABP and lpM DAUDA. Values are the ICso's of each competitor and % inhibition of specific DAUDA binding by 10pM of each competitor. COMPETITOR FC1 FC4 WY FC3 FC2 Methanol IC50 (pm) 4.9 9.7 10 >10 >10 >10 % INHIBITION 69 51 50 43 43 21 41 000156 CONCLUSIONS & FUTURE DIRECTIONS This study was designed to investigate the hypothesis that certain Fluorocarbons (FCs) bind to liver fatty acid-binding protein (L-FABP) and displace endogenous fatty acids (FAs) as an initial event in peroxisome proliferation. To examine this hypothesis, the kinetics of FA and FC binding to L-FABP were investigated using DAUDA, a fluorescently labeled octanoic acid analogue. L-FABP from male rats (considered to be strong responders to peroxisome proliferators) and male guinea pigs (considered to be weak or non-responders to peroxisome proliferators) (Svoboda etal., 1967; Orton etal., 1984; Lake and Gray, 1985; Elcombe and Mitchell, 1986) were examined. The first goal was to assess the effect of FCs on L-FABP function as evaluated by the ability of DAUDA to bind to L-FABP isolated from rats and guinea pigs treated and not treated with FC1 in vivo. Results show a decreased maximum binding capacity of LFABP from FCl-treated rats without an increase in Kd. This was demonstrated by a lower Bmax, higher oleic acid ICjoand unchanged Kd in L-FABP from rats treated with FC1 as compared to samples from control rats These results are likely due to FC1 binding to the secondary binding site on L-FABP; thus preventing the binding of DAUDA to L-FABP. Results for guinea pig L-FABP samples were inconclusive. This is presumably because guinea pig samples were only partially purified, resulting in a high degree of interference from remaining cellular debris and a lower concentration of L-FABP, as a proportion of total protein, as compared to the more highly purified rat samples. A second attempt will be made to analyze the difference in response to FCs seen in rodent and guinea pig LFABP. This analysis will be performed on fully purified L-FABP samples. 42 000157 The second goal of the study was to assess the potency of the various FCs for binding to L-FABP, as suggested by IC50 values. Results indicate the most potent L-FABP binder is FC1, followed by FC4, WY and (with equal IC50S) FC3 and FC2. Binding of FCs to LFABP likely occurs in the secondary binding site; and the variance in potency is likely due to structural differences. Future work will focus on correlating new data with the results of this study, and relating the effects seen in rodents and guinea pigs to the relevance they pose to human health. The possibility of completing a new set of kinetics assays using a probe capable of binding both L-FABP binding sites will be looked into. This would help characterize the interaction of DAUDA with L-FABP and create a new set of results for analysis. Human L-FABP will be examined, and the relevance to human health of FC induced peroxisome proliferation in rodents will be investigated. FCs of different chain length will be investigated, and the effect of chain length on ability to bind L-FABP analyzed. The ability of each FC to induce peroxisome proliferation in rodent L-FABP will be assessed using the method of Lazarow and de Duve (1976). An attempt will be made to correlate this capacity with the relative potency of each FC to bind L-FABP, as determined in the current study. Electro-Spray Mass Spectrometry analysis on the same L-FABP samples as analyzed in this study is currently underway. The objective is to quantify FC1 bound to L-FABP from FC1 treated animals, correlate this with the decrease in L-FABP capacity observed in this study and with the ability of FC1 to induce peroxisome proliferation in rodents. The long range goal is to refine the correlation between the amount of FC bound to L-FABP with peroxisome 43 000158 proliferation, and develop a biomarker for peroxisome proliferation based on bound FC levels. 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