Free amino acids mimic the anabolic but not the proliferative effect of albumin in OK proximal tubular cells

When plasma proteins leak from circulation into the renal tubular lumen in the proteinuric renal diseases, nephrotoxicity of filtered albumin (and/or molecules bound to it) may be important in the subsequent development of tubulo-interstitial damage which contributes to the progression of the disease. When cultured opossum kidney (OK) proximal tubular cells were exposed to bovine serum albumin for 3 days in vitro, increased cell division ([3H]-thymidine incorporation) and cellular hypertrophy (increased protein/DNA ratio) were observed. Both effects were halved if defatted albumin was used. A trivial explanation for the growth responses is that free fatty acids carried on the albumin, and amino acids generated by intracellular degradation of the albumin, are exerting a non-specific growth effect as metabolic fuels which are oxidized to generate ATP. However, the water-soluble free fatty acid octanoate (1 mmol l(-1)) had no significant effect on protein/DNA ratio and a very variable stimulatory effect on [3H]-thymidine incorporation, whereas an essential amino acid mixture or 1 mmol/l(-1) l-Ala or l-Phe only increased the protein/DNA ratio. Furthermore no carnitine was added to the culture medium. This absence would have impaired mitochondrial transport (and hence oxidation) of long-chain free fatty acids derived from the albumin. l-Phe is also a poor substrate for mitochondrial oxidation in kidney. It is therefore concluded that the growth effects of albumin in OK proximal tubular cells are specific effects of the albumin protein and of the free fatty acids and amino acids derived from it, and not a non-specific effect on metabolic fuel supply.     

Determining molecular binding sites on human serum albumin by displacement of oleic acid

An NMR method was developed for determining binding sites of small molecules on human serum albumin (HSA) by competitive displacement of (13)C-labeled oleic acid. This method is based on the observation that in the crystal structure of HSA complexed with oleic acid, two principal drug-binding sites, Sudlow's sites I (warfarin) and II (ibuprofen), are also occupied by fatty acids. In two-dimensional [(1)H,(13)C]heteronuclear single quantum coherence NMR spectra, seven distinct resonances were observed for the (13)C-methyl-labeled oleic acid as a result of its binding to HSA. Resonances corresponding to the major drug-binding sites were identified through competitive displacement of molecules that bind specifically to each site. Thus, binding of molecules to these sites can be followed by their displacement of oleic acids. Furthermore, the amount of bound ligand at each site can be determined from changes in resonance intensities. For molecules containing fluorine, binding results were further validated by direct observations of the bound ligands using (19)F NMR. Identifying the binding sites for drug molecules on HSA can aid in determining the structure-activity relationship of albumin binding and assist in the design of molecules with altered albumin binding.     

Identification of alpha-1 acid glycoprotein as a lysophospholipid binding protein: a complementary role to albumin in the scavenging of lysophosphatidylcholine

Alpha-1 acid glycoprotein (AGP, orosomucoid), a major acute phase protein in plasma, displays potent cytoprotective and anti-inflammatory activities whose molecular mechanisms are largely unknown. Because AGP binds various exogenous drugs, we have searched for endogenous ligands for AGP. We found that AGP binds lysophospholipids in a manner discernible from albumin in several ways. First, mass spectrometric analyses showed that AGP isolated from plasma and serum contained lysophosphatidylcholine (LPC) enriched in mono and polysaturated acyl chains, whereas albumin contained mostly saturated LPC. Second, AGP bound LPC in a 1:1 molar ratio and with a higher affinity than free fatty acids, whereas albumin bound LPC in a 3:1 ratio but with a lower affinity than that of free fatty acids. Consequently, free fatty acids displaced LPC more avidly from albumin than from AGP. Competitive ligand displacement indicated the highest affinity for AGP to LPC20:4, 18:3, 18:1, and 16:0 (150-180 nM), lysophosphatidylserine (Kd 190 nM), and platelet activating factor (PAF) (Kd 235 nM). The high affinity of AGP to LPC in equilibrium was verified by stopped-flow kinetics, which implicated slow dissociation after fast initial binding, being consistent with an induced-fit mechanism. AGP also bound pyrene-labeled phospholipids directly from vesicles and more efficiently than albumin. AGP prevented LPC-induced priming and PAF-induced activation of human granulocytes, thus indicating scavenging of the cellular effects of the lipid ligands. The results suggest that AGP complements albumin as a lysophospholipid scavenging protein, particularly in inflammatory conditions when the capacity of albumin to sequester LPC becomes impaired.     

Fatty acids influence binding of cobalt to serum albumin in patients with fatty liver

Human serum albumin binds ligands such as fatty acids and metals in circulation. Oxidative stress can modify albumin and affect ligand binding. This study examines the role of oxidative stress and fatty acids in modulating cobalt binding to albumin in patients with fatty liver. Elevated levels of malondialdehyde and protein carbonyls, indicative of oxidative stress were evident in serum of patients with fatty liver. A significant decrease in albumin-cobalt binding was also observed. Albumin isolated from patient serum also showed an increase in bound fatty acids. In vitro experiments indicated that while oxidant exposure or removal of fatty acids independently decreased cobalt binding to albumin, removal of fatty acids from the protein prior to oxidant exposure did not influence the oxidant effect on albumin-cobalt binding. These results suggest that oxidative stress and fatty acids on albumin can influence albumin-cobalt binding in patients with fatty liver by independent mechanisms.     

Multiple fatty acid binding to albumin in human blood plasma

Binding equilibria of long-chain fatty acids to human serum albumin, in serum or plasma, were studied by a dialysis exchange rate technique. Palmitate was added to citrated plasma in vitro and it was observed that between six and ten palmitate molecules were bound to albumin with nearly equal affinity. Observations in vivo gave similar results in the following series: (a) in two volunteers with increased fatty acid concentrations after fasting, exercise, and a cold shower: (b) in three male volunteers in whom high concentrations of non-esterified fatty acids, up to 4.6 mM, were induced by intravenous administration of a preparation of lecithin/glycocholate mixed micelles, and (c) in 81 patients with diabetes mellitus, type I. The binding pattern of palmitate in serum or plasma is essentially different from that observed with palmitate added to buffered solutions of pure albumin when two molecules are tightly bound and about four additional molecules with lower affinity. The differences may partly be explained by the presence of chloride ions in blood plasma, reducing the affinity for binding of the first two fatty acid molecules, and partly by facilitated binding of several molecules of mixed fatty acids, as found in plasma.     

Ligand-binding properties of proalbumin Christchurch.

Proalbumin Christchurch, a circulating variant of human serum albumin, is secreted from the liver without cleavage of the hexapeptide situated at the N-terminal end of the peptide chain of proalbumin. We compared ligand-binding properties of proalbumin Christchurch and of normal albumin A from the same individual in order to test the effect of the presence of the hexapeptide. The two albumin forms exhibited similar affinities for palmitate, bilirubin, 8-anilinonaphthalene-1-sulphonate and Bromocresol Green. The patterns of endogenous fatty acids bound to the two forms of albumin were slightly different, although the differences were probably not of physiological significance. From these studies it would appear that the propeptide of proalbumin does not alter the protein conformation in such a way as to alter binding sites for organic anions.     

Influence of albumin and non-esterified fatty acids on serum prostacyclin binding in pregnancy

We investigated the etiology of the previously documented decrease in serum prostocyclin binding during pregnancy. Addition of albumin to the serum of pregnant women failed to raise binding to non-pregnant levels. Pregnancy serum bound significantly more prostacyclin following the removal of non-esterified fatty acids and the addition of fatty acid free albumin resulted in a rise in binding to non-pregnant levels. We conclude that serum protein prostacyclin binding is affected by both albumin concentration and non-esterified fatty acids.     

Multiple binding of bilirubin to human serum albumin and cobinding with laurate

Numerical analysis of multiple binding of two ligands to one carrier has been accomplished, using the principle of several sets of acceptable binding constants, with bilirubin-laurate-albumin as an example. Binding of bilirubin to defatted human serum albumin was investigated by a spectroscopic method, based upon a difference of light absorption spectrum for free and bound bilirubin. The observations were supplemented with previous data from an independent technique, measurement of oxidation rates of free bilirubin with hydrogen peroxide and peroxidase. A continuous isotherm was obtained, showing binding of at least 4 mol bilirubin per mole albumin with the following stoichiometric binding constants, 1.11 X 10(8), 1.7 X 10(7), 8 X 10(5), and 4 X 10(4) M-1 at pH 8.2, ionic strength 0.15 M, 25 degrees C. The binding is anticooperative at all steps. A saturation level was not reached. Cobinding of bilirubin and laurate was studied, with up to 2 mol of each ligand per mole albumin, using the peroxidase method for determination of free equilibrium concentrations of bilirubin, and a dialysis rate technique for free laurate. The findings could be described in terms of a stoichiometric model. Heterotropic cooperativity was present among the first bilirubin and the first and second laurate molecules. More than two molecules of either ligand can be bound at the same time.     

Bilirubin,model membranes and serum albumin interaction: The influence of fatty acids

Electronic circular dichroism (ECD), absorption and fluorescence spectroscopy were used to study the enantioselective interactions which involved bilirubin (BR), liposomes, human serum albumin of two different purities, pure (HSA) and non-purified of fatty acids (FA-HSA), and individual fatty acids.The application of the ECD technique to such a complex problem provided a new perspective on the BR binding to liposomes. Our results demonstrated that in the presence of pure HSA, BR preferred to bind to the protein over the liposomes. However, in the presence of FA-HSA, BR significantly bound to the liposomes composed either of DMPC or of sphingomyelin and bound only moderately to the primary and secondary binding sites of FA-HSA even at high BR concentrations. For the DMPC liposomes, even a change of BR conformation upon binding to the primary binding site was observed. The individual saturated fatty acids influenced the BR binding to HSA and liposomes in a similar way as fatty acids from FA-HSA. The unsaturated fatty acids interacted with BR alone and prevented it from interacting with either 99-HSA or the liposomes. In the presence of arachidonic acid, BR interacted enantioselectively with the liposomes and only moderately with 99-HSA.Hence, our results show a substantial impact of the liposomes on the BR binding to HSA. As a consequence of the existence of fatty acids in the blood plasma and in the natural structure of HSA, BR may possibly bind to the cell membranes even though it is normally bound to HSA.     

Utilization of free fatty acids complexed to human plasma lipoproteins by mammalian cell suspensions

The purpose of this study was to determine whether lipoprotein-bound free fatty acid could be utilized by isolated mammalian cells. Ehrlich ascites tumor cells were incubated in vitro with radioactive free fatty acids that were bound to human plasma lipoproteins. Under these conditions, lipoprotein-bound free fatty acids were readily taken up by the cells. After 2 min of incubation with free fatty acids bound to low density lipoproteins, most of the radioactivity that was associated with the cells was in the form of free fatty acids. As the incubation continued, increasing amounts of radioactivity were incorporated into CO(2) and cell lipids, particularly phospholipids. Most of the free fatty acid uptake was the result of fatty acid transfer from low density lipoproteins to the cell, not from irreversible incorporation of the intact free fatty acid-low density lipoprotein complex. Fatty acid uptake increased as the ratio of free fatty acid to low density lipoprotein was raised. When albumin was added to the medium, free fatty acid uptake decreased. A large percentage of the newly incorporated cellular radioactivity was released into the medium if the cells were exposed subsequently to a solution containing albumin. Most of the released radioactivity was in the form of free fatty acid. The results with this experimental model suggest that lipoprotein-bound free fatty acid, like albumin-bound free fatty acid, is readily available for uptake by isolated cells. The mechanism of free fatty acid utilization by the Ehrlich cell is similar when either low density lipoprotein or serum albumin serves as the fatty acid carrier.     

Recombinant Human Albumin in Cell Culture: Evaluation of Growth-Promoting Potential for NRK and SCC-9 Cells In Vitro

Serum-derived albumin has for a long time been used in cell culture media, but the exact role of albumin and/or impurities bound to albumin has not been precisely defined. In this study, recombinant human albumin was evaluated for its growth-promoting activity on two cell lines, NRK and SCC-9. For NRK cells, the recombinant human albumin was found to exert an inhibitory effect. The fact that fatty acid free HSA was also inhibitory while HSA fraction V was stimulatory suggested a role for fatty acids or some other bound moieties in growth stimulation by HSA fraction V. Addition of oleic acid, cholesterol, phosphatidylcholine, phosphatidylserine or a combination of these lipids, however, did not significantly improve the growth stimulating activity of either fatty acid free HSA or the recombinant human albumin. For SCC-9 cells, both recombinant human albumin and fatty acid free HSA showed slight stimulation (although they were not as active as HSA fraction V), suggesting that in some cell systems, the albumin molecule per se may promote cell growth and survival. This revised version was published online in July 2006 with corrections to the Cover Date.     

Microcalorimetric study of human serum

It was established that albumin of donor blood serum denatures in two temperature ranges. It is shown that the first stage of denaturation with Td = 61.5 degrees C is dominant and corresponds to melting of regions not bound to fatty acids. The second stage with Td = 80 degrees C corresponds to melting of regions bound to fatty acids. Serum denaturation heat is equal to 20.2 J/g dry protein. A change in denaturation heat capacity is 0.21 J/(g.K). Analysis of thermal parameters of deconvolution peaks showed that albumin of donor blood serum is in a fatless state and its multiple binding centers are essentially free as compared with freshly isolated albumin and may play an important role in binding of ligands in vivo. The thermal parameters of denaturation of some important human blood serum proteins including gamma-globulins, transferrin ceruloplasmin and protease inhibitors were also determined.     

Conformational changes in human serum albumin studied by fluorescence and absorption spectroscopy. Distance measurements as a function of pH and fatty acids.

pH- and fatty acid-induced conformational changes in human serum albumin were investigated by fluorescence-energy transfer, determining the distance between Trp-214 and bound bilirubin at 25 degrees C. This distance changes significantly with the pH, being 2.52 +/- 0.01 nm at pH 6, 2.31 +/- 0.04 nm at pH 9, 2.13 +/- 0.07 nm at pH 11.0 and 2.77 nm at pH 11.9. The influence of different fatty acids on the distance was also determined. At pH 7.4 medium-chain fatty acids seem to increase this distance, whereas long-chain fatty acids, at low concentrations, decrease the distance between the two chromophores. The contraction of the protein carrying long-chain saturated fatty acids is even more pronounced at pH 9.     

Electron spin-echo studies of spin-labelled lipid membranes and free fatty acids interacting with human serum albumin

Human serum albumin (HSA) is an abundant plasma protein that transports fatty acids and also binds a wide variety of hydrophobic pharmacores. Echo-detected (ED) EPR spectra and D(2)O-electron spin echo envelope modulation (ESEEM) Fourier-transform spectra of spin-labelled free fatty acids and phospholipids were used jointly to investigate the binding of stearic acid to HSA and the adsorption of the protein on dipalmitoyl phosphatidylcholine (DPPC) membranes. In membranes, torsional librations are detected in the ED-spectra, the intensity of which depends on chain position at low temperature. Water penetration into the membrane is seen in the D(2)O-ESEEM spectra, the intensity of which decreases greatly at the middle of the membrane. Both the chain librational motion and the water penetration are only little affected by adsorption of serum albumin at the DPPC membrane surface. In contrast, both the librational motion and the accessibility of the chains to water are very different in the hydrophobic fatty acid binding sites of HSA from those in membranes. Indeed, the librational motion of bound fatty acids is suppressed at low temperature, and is similar for the different chain positions, at all temperatures. Correspondingly, all segments of the bound chains are accessible to water, to rather similar extents.     

Fatty acids bound to vitamin D-binding protein (DBP) from human and bovine sera

Human and bovine vitamin D-binding protein (DBP) have been isolated from serum by a method that does not involve denaturing steps. This method includes Cibacron Blue-Sepharose chromatography, gel filtration, DEAE-Sephadex chromatography and albumin immunoadsorption. Analysis of fatty acids bound to the isolated human and bovine DBP showed molar ratios of fatty acid to protein of 0.4 and 1.3 respectively meanwhile human and bovine albumin have bound 1.8 and 1.5 moles per mol respectively. Most of fatty acids bound to human and bovine DBP are monounsaturated and saturated, mainly oleic and palmitic acids, which together account for 50% of the total of fatty acids in both species. By contrast, polyunsaturated fatty acids represented a minor component, less than 5%.     

Role of bovine serum albumin in the nutrition of Mycobacterium tuberculosis.

Bovine serum albumin promotes the growth of small inocula of Mycobacterium tuberculosis in media containing unesterified fatty acids. Albumin binds fatty acids present in concentrations toxic for the organisms. In the present study, additional roles of albumin were investigated. When present in a basal medium, fatty acid-free albumin could be utilized by M. tuberculosis as a sole source of carbon. Since albumin could not substitute for the amino acids in basal medium as a nitrogen source, it was concluded that the protein component in albumin was not utilized as a nutrient by the organisms. An ether extract of fatty acid-free albumin supported a small but significant amount of growth. Analysis of the lipids in fatty acid-free albumin by gas chromatography revealed the presence of 686 microgram of fatty acid per g of albumin. Although a small amount of growth occurred when a lipid extract of albumin was present in the medium, growth stimulation was dependent in major part on the presence of undenatured albumin in the medium. Lipids, when bound to albumin, can serve as a nontoxic source of carbon and energy.     

Electron spin-echo studies of spin-labelled lipid membranes and free fatty acids interacting with human serum albumin

Human serum albumin (HSA) is an abundant plasma protein that transports fatty acids and also binds a wide variety of hydrophobic pharmacores. Echo-detected (ED) EPR spectra and D₂O-electron spin echo envelope modulation (ESEEM) Fourier-transform spectra of spin-labelled free fatty acids and phospholipids were used jointly to investigate the binding of stearic acid to HSA and the adsorption of the protein on dipalmitoyl phosphatidylcholine (DPPC) membranes. In membranes, torsional librations are detected in the ED-spectra, the intensity of which depends on chain position at low temperature. Water penetration into the membrane is seen in the D₂O-ESEEM spectra, the intensity of which decreases greatly at the middle of the membrane. Both the chain librational motion and the water penetration are only little affected by adsorption of serum albumin at the DPPC membrane surface. In contrast, both the librational motion and the accessibility of the chains to water are very different in the hydrophobic fatty acid binding sites of HSA from those in membranes. Indeed, the librational motion of bound fatty acids is suppressed at low temperature, and is similar for the different chain positions, at all temperatures. Correspondingly, all segments of the bound chains are accessible to water, to rather similar extents.     

Role of bovine serum albumin in the nutrition of Mycobacterium tuberculosis.

Bovine serum albumin promotes the growth of small inocula of Mycobacterium tuberculosis in media containing unesterified fatty acids. Albumin binds fatty acids present in concentrations toxic for the organisms. In the present study, additional roles of albumin were investigated. When present in a basal medium, fatty acid-free albumin could be utilized by M. tuberculosis as a sole source of carbon. Since albumin could not substitute for the amino acids in basal medium as a nitrogen source, it was concluded that the protein component in albumin was not utilized as a nutrient by the organisms. An ether extract of fatty acid-free albumin supported a small but significant amount of growth. Analysis of the lipids in fatty acid-free albumin by gas chromatography revealed the presence of 686 microgram of fatty acid per g of albumin. Although a small amount of growth occurred when a lipid extract of albumin was present in the medium, growth stimulation was dependent in major part on the presence of undenatured albumin in the medium. Lipids, when bound to albumin, can serve as a nontoxic source of carbon and energy.     

Linoleic acid passage through the blood-brain barrier and a possible effect of age

It has already been established that the blood-brain barrier is readily crossed by unsaturated fatty acids, while saturated fatty acid transport appears to be protein mediated. When the passage of the fatty acids is tested in vivo by using perfusion buffers containing both linoleate and palmitate in different concentrations, linoleate is able to decrease the palmitate passage, while palmitate increases the linoleate passage. These results could be related to the effect of two fatty acids on the ratio between the fatty acids bound to the serum albumin and the free fatty acid pool, which is only available for transport through membranes. However, on the basis of some results obtained with aged rats, the possibility that a relationship may exist between palmitate and linoleate during their passage through the BBB is discussed. Moreover, it seems likely that in aged rats a moderate modification for fatty acids takes place in the BBB.     

How fatty acids bind to proteins: the inside story from protein structures

The interactions of fatty acids with proteins have been probed with a great variety of techniques and strategies. Many approaches have substituted covalently labeled fatty acids or structurally related molecules. Information from such studies ultimately requires validation by studies with natural fatty acids. However, even the best conventional approaches with natural fatty acids generally have revealed only limited aspects of fatty acid-protein interactions. In contrast, recent crystallographic and NMR studies of several proteins with bound fatty acids provide complete three-dimensional structures with molecular details of these interactions. This presentation reviews three examples of proteins that are indirectly or directly involved in cell signaling: a protein in the plasma compartment (human serum albumin); a protein family in the cytosolic compartment of mammalian cells (fatty-acid-binding proteins), and a nuclear protein (peroxisome proliferator-activated receptor): it also discusses the structures of these proteins and their binding pocket(s), compares their specific modes of interactions with fatty acids, and discusses established and potential roles of fatty acid-protein interactions in cell signaling.