Plasma unbound free fatty acid profiles in premature infants before and after intralipid infusion.

Background: Unbound free fatty acids (FFAu) are the bioactive fraction of plasma free fatty acids (FFA). Most plasma FFA are bound to albumin. Only when FFA dissociate from albumin, do they become biologically active.Objective: To measure the first FFAu profiles in human infants and to measure these profiles before and during intravenous administration of the soybean lipid, intralipid (IL).Study design: The study population was 16 premature infants, from a parent study of 130 infants with birth weights 500-2000 g and gestational age 23-34 weeks. The infants chosen had plasma samples of ≥120 µL (volume needed for each FFAu profile measurement) in the first day of life. Infants received IL infusions starting in the second day of life at 1 g/kg/day, increasing by 1-g/kg/day daily up to 3 g/kg/day. FFAu profiles were determined during IL infusion when plasma was available. Profiles are the concentrations of the nine most abundant long-chain FFAu and were determined using novel fluorescent probes.Results: Before intralipid infusion unbound myristic acid was the dominant FFAu, as high as 78% of the total FFAu (sum of the 9 FFAu). In contrast, unbound linoleic acid was 0% in all infants. With increasing infusion of IL to 3 g/kg/day, unbound linoleic increased to 26% of the total FFAu, with unbound oleic, myristic, and linolenic acid the second, third and fourth most abundant. The average total FFAu concentration also increased from 4 nM before intralipid to 53 nM at 3 g/kg/day. During IL infusion the FFAu profiles approached the fatty acid composition of intralipid at 3 g/kg/day.Conclusions: This first study of FFAu profiles in neonates revealed that before IL infusion unbound linoleic acid was zero in all 16 infants and levels of myristic acid were exceptionally large, as much as 78% of the total FFAu profile. These results suggest important and previously unrecognized roles of lipid metabolism in early development. Zero unbound linoleic acid before IL infusion may help promote closure of the ductus arteriosus but after IL infusion, synthesis of arachidonic from linoleic acid may tend to promote patency. The high levels of unbound myristate may be needed for immediate neonatal energy needs.

Unbound free fatty acid profiles in human plasma and the unexpected absence of unbound palmitoleate.

We determined for the first time the profiles of the nine most abundant unbound FFAs (FFAus) in human plasma. Profiles were determined for a standard reference plasma of pooled healthy adults for which the Lipid MAPSMAPS Consortium had determined the total FFA profiles. Measurements were performed by using 20 different acrylodan-labeled fatty acid binding protein mutants (probes), which have complementary specificities for the nine FFAs that comprise more than 96% of long-chain plasma FFA. The acrylodan fluorescence emission for each probe changes upon binding a FFAu. The plasma concentrations of each of the nine FFAus were determined by combining the measured fluorescence ratios of the 20 probes. The total molar FFAu concentration accounted for <10-5 of the total FFA concentration, and the mole fractions of the FFAu profiles were substantially different than the total FFA profiles. Myristic acid, for example, comprises 22% of the unbound versus 2.8% of the total. The most surprising difference is our finding of zero unbound cis-9-palmitoleic acid (POA), whereas the total POA was 7.2%. An unidentified plasma component appears to specifically prevent the release of POA. FFAus are the physiologically active FFAs, and plasma FFAu profiles may provide novel information about human health.

Usefulness of serum unbound free fatty acid levels to predict death early in patients with ST-segment elevation myocardial infarction (from the Thrombolysis In Myocardial Infarction [TIMI] II trial).

Circulating total free fatty acid (FFA) levels are elevated early in myocardial infarction (MI) and have been associated with an increase in mortality. We investigated the association of serum unbound FFA (FFAu) levels with mortality in patients presenting with ST-segment elevation MI in the Thrombolysis In Myocardial Infarction II trial. The Thrombolysis In Myocardial Infarction II trial enrolled patients within 4 hours of chest pain onset. The patients were treated with a recombinant tissue plasminogen activator within 1 hour of enrollment. The FFAu concentration was evaluated in serum samples from 1,834 patients obtained at baseline, before therapy. The FFAu level was an independent risk factor for death as early as at 1 day of hospitalization and continued to be an independent risk factor for the >3.8 years of follow-up. When adjusted for other cardiovascular risk factors, the FFAu levels in the fourth versus the first quartile remained an independent risk factor for death from MI (hazard ratio 5.0, 95% confidence interval 1.9 to 13.0), all cardiac death (hazard ratio 2.4, 95% confidence interval 1.3 to 4.4), and all-cause death (hazard ratio 1.9, 95% confidence interval 1.2 to 3.1). Women were twice as likely to be in the upper 2 FFAu quartiles and had approximately twice the rate of death as men. In conclusion, FFAu elevation is 1 of the earliest molecular biomarkers of mortality in patients with ST-segment elevation MI and was independent of other risk factors known to affect the outcomes after ST-segment elevation MI.

Effects of bilirubin on neutrophil responses in newborn infants.

BACKGROUND: Newborns are susceptible to inflammatory diseases due to defects in clearing activated immune cells from tissues. Therefore, mechanisms have likely evolved to protect neonates from leukocyte-mediated cytotoxicity. Bilirubin has antioxidant activity, and it is possible that it also exerts effects on cellular immune responses in jaundiced infants. OBJECTIVES: We hypothesize that bilirubin increases expression of antioxidant genes and decreases production of inflammatory proteins in neonatal neutrophils. METHODS: Neutrophils were isolated from umbilical cord blood, and from adults for comparison, and treated with bilirubin (10-300 µmol/l, equivalent to unbound bilirubin 3-40 nmol/l), in the presence or absence of lipopolysaccharide (LPS). Expression of genes for antioxidant enzymes [superoxide dismutase (SOD), heme-oxygenase-1 (HO-1)] and heme-dependent enzymes involved in inflammation [NADPH oxidase-1 (NOX-1), cyclooxygenase-2 (COX-2)] was measured by PCR. Inflammatory cytokines were measured by bead array analysis using flow cytometry. RESULTS: We found that LPS induced production of interleukin (IL)-8, IL-1ß, and macrophage inhibitory protein-1ß (MIP-1ß). Bilirubin increased basal production of IL-8 and IL-1ß, but downregulated LPS-induced generation of IL-8 and MIP-1ß. It also upregulated SOD and HO-1 gene expression. We observed an unexpected bilirubin-induced increase in gene expression of NOX-1 in LPS-activated cells, and of COX-2 in both resting and activated cells. CONCLUSIONS: These findings suggest that bilirubin suppresses inflammation and increases antioxidant enzyme generation in activated neonatal neutrophils. The unexpected increases in NOX-1 and COX-2 expression may represent an early response, with physiologic effects mitigated by increased antioxidant activity. Further studies will be needed to define levels of bilirubin that optimize its protective effects, while minimizing potential inflammatory toxicity.

Fluorescence sensor for the quantification of unbound bilirubin concentrations.

BACKGROUND: Hyperbilirubinemia in jaundiced neonates is routinely assessed by use of total serum bilirubin. However, the unbound or free form (B(f)), not total bilirubin, crosses the blood-brain barrier and can be neurotoxic. Although the peroxidase-mediated oxidation of bilirubin can be used to measure plasma concentrations of B(f), this measurement is relatively complex and the assay is not routinely used. We describe a fluorescence sensor for quantifying B(f) in plasma. METHODS: Our method uses a mutated fatty acid binding protein labeled with the fluorescent molecule acrylodan (BL22P1B11), whose fluorescence is quenched upon binding bilirubin. Another configuration (BL22P1B11-Rh) was developed that uses BL22P1B11 together with the fluorophore rhodamine B, which responds by a change in the ratio of its fluorescence. RESULTS: The "B(f) probes" were calibrated with aqueous solutions of bilirubin and yielded similar bilirubin dissociation constants [K(d) = 16 (1.5) nmol/L]. We used the probes to determine B(f) concentrations in equilibrium with human serum albumin (HSA) and in human plasma samples supplemented with bilirubin. We obtained equivalent B(f) values in both systems, and the B(f) probe results were in agreement with the peroxidase assay. B(f) measurements revealed that bilirubin-HSA binding was well described by 2 sites with K(d) values of 15.4 (1) nmol/L and 748 (14) nmol/L. We measured B(f) concentrations in the range expected in jaundiced neonates with a mean CV of approximately 3%. CONCLUSIONS: The BL22P1B11-Rh probe provides accurate plasma sample B(f) concentrations with a single measurement, in 1 min with either a handheld B(f) meter or a laboratory fluorometer.

Fatty acid (FFA) transport in cardiomyocytes revealed by imaging unbound FFA is mediated by an FFA pump modulated by the CD36 protein.

Free fatty acid (FFA) transport across the cardiomyocyte plasma membrane is essential to proper cardiac function, but the role of membrane proteins and FFA metabolism in FFA transport remains unclear. Metabolism is thought to maintain intracellular FFA at low levels, providing the driving force for FFA transport, but intracellular FFA levels have not been measured directly. We report the first measurements of the intracellular unbound FFA concentrations (FFA(i)) in cardiomyocytes. The fluorescent indicator of FFA, ADIFAB (acrylodan-labeled rat intestinal fatty acid-binding protein), was microinjected into isolated cardiomyocytes from wild type (WT) and FAT/CD36 null C57B1/6 mice. Quantitative imaging of ADIFAB fluorescence revealed the time courses of FFA influx and efflux. For WT mice, rate constants for efflux (∼0.02 s(-1)) were twice influx, and steady state FFA(i) were more than 3-fold larger than extracellular unbound FFA (FFA(o)). The concentration gradient and the initial rate of FFA influx saturated with increasing FFA(o). Similar characteristics were observed for oleate, palmitate, and arachidonate. FAT/CD36 null cells revealed similar characteristics, except that efflux was 2-3-fold slower than WT cells. Rate constants determined with intracellular ADIFAB were confirmed by measurements of intracellular pH. FFA uptake by suspensions of cardiomyocytes determined by monitoring FFA(o) using extracellular ADIFAB confirmed the influx rate constants determined from FFA(i) measurements and demonstrated that rates of FFA transport and etomoxir-sensitive metabolism are regulated independently. We conclude that FFA influx in cardiac myocytes is mediated by a membrane pump whose transport rate constants may be modulated by FAT/CD36.

Flip-flop is the rate-limiting step for transport of free fatty acids across lipid vesicle membranes.

The mechanism of transport of free fatty acids (FFA) across lipid bilayer membranes remains a subject of debate. The debate is whether the rate-limiting step for transport is flip-flop across the membrane or dissociation into the aqueous phase. Recently, a new method for assessing dissociation was described in which fluorescein phosphatidylethanolamine (FPE) introduced into the outer leaflet of lipid vesicles was used to monitor FFA dissociation. Transport of FFA into vesicles containing both FPE in the outer leaflet and pyranine trapped in the inside aqueous phase revealed identical rate constants for quenching of FPE and pyranine fluorescence. Because no difference was observed in the time for FFA binding to the outer surface and flip-flop across the bilayer, it was concluded that dissociation was slower than flip-flop. Here, we used FPE and BSA to assess dissociation of oleate from lipid vesicles. In separate pyranine- or ADIFAB-containing vesicles, we assessed flip-flop. We found that the FPE and BSA transfer methods yielded equivalent rate constants for dissociation, which were 3-10-fold faster than that of flip-flop. We found that in vesicles containing both FPE and pyranine, pyranine fluorescence cannot be separated from FPE fluorescence. The identical rate constants for FPE and pyranine observed with vesicles containing both fluorophores reflected the dominance (20-fold) of FPE fluorescence at pyranine excitation and emission wavelengths. Because the dissociation rate constants are 3-10 times faster than the rate constants for flip-flop, flip-flop must be the rate-limiting step for the transport of FFA across lipid vesicles.

B-type natriuretic peptide and serum unbound free fatty acid levels after contemporary percutaneous coronary intervention.

OBJECTIVES: To determine the frequency and timing of B-type natriuretic peptide (BNP) and unbound free fatty acid (FFAu) elevation after percutaneous coronary intervention (PCI). DESIGN AND METHODS: Blood samples were collected from 55 patients undergoing PCI within 1 hour prior to PCI, immediately after PCI, 6 hours and 18-24 hours after PCI, and were analyzed for BNP and FFAu. RESULTS: There was a trend toward a rise in BNP levels at 18-24 hours post-PCI (65 vs. 45 pg/ml; p = 0.056). FFAu levels rose immediately after PCI and returned to baseline by 6 hours postprocedure (2.0 nM pre-PCI, 6.4 nM immediately post-PCI, 1.9 nM 6 hours post-PCI, and 2.2 nM 18-24 hours post-PCI; p < 0.0001). BNP and FFAu levels were elevated post-PCI in 17% and 82% of cases. CONCLUSIONS: PCI using short inflation times and coronary stenting are associated with a trend toward increased BNP levels at 18-24 hours post-PCI and a transient significant rise in FFAu levels.

Free fatty acid transport across adipocytes is mediated by an unknown membrane protein pump.

The role of cell membranes in regulating the flux of long chain free fatty acids (FFA) into and out of adipocytes is intensely debated. Four different membrane proteins including, FABPpm, CD36/FAT, caveolin-1, and FATP have been identified as facilitating FFA transport. Moreover, CD36 and caveolin-1 are also reported to mediate transport in conjunction with lipid rafts. The principal evidence for these findings is a correlation of the level of FFA uptake with the expression level of these proteins and with the integrity of lipid rafts. The 3T3-L1 and 3T3-F442A cell lines in their preadipocyte states reveal little or no expression of these proteins and correspondingly low levels of uptake. Here we have microinjected the adipocyte and preadipocyte cell lines with ADIFAB, the fluorescent indicator of FFA. The ADIFAB fluorescence allowed us to monitor the intracellular unbound FFA concentration during FFA influx and efflux. We show that these measurements of transport, in contrast to FFA uptake measurements, correlate neither with expression of these proteins nor with lipid raft integrity in preadipocytes and adipocytes. Transport characteristics, including the generation of an ATP-dependent FFA concentration gradient, are virtually identical in adipocytes and preadipocytes. We suggest that the origin of the discrepancy between uptake and our measurements is that most of the FFA transported into the cells is lost during the uptake but not in the transport protocols. We conclude that long chain fatty acid transport in adipocytes is very likely mediated by an as-yet-unidentified membrane protein pump.

Fatty acid-specific fluorescent probes and their use in resolving mixtures of unbound free fatty acids in equilibrium with albumin.

We report the first measurements for profiling mixtures of unbound free fatty acids. Measurements utilized fluorescent probes with distinctly different response profiles for different free fatty acids (FFA). These probes were constructed by labeling site-specific mutants of the rat intestinal fatty acid binding protein (rI-FABP) with acrylodan. The probes were produced and screened by high-throughput methods, and from more than 30 000 such probes we selected six that together have sufficient specificity and sensitivity for resolving the profile of unbound FFA (FFAu) in mixtures of different FFAu. We developed analytical methods to determine the FFAu profile from the fluorescence (ratio) response of the different probes and used these methods to determine FFAu profiles for mixtures of arachidonate, linoleate, oleate, palmitate, and stearate in equilibrium with bovine serum albumin (BSA). Measurements were performed using mixtures with a range of total FFAu concentrations, including 0.9 nM, which is similar to normal plasma levels. We also measured single FFA binding isotherms for BSA and found that binding was described well by six to seven sites with the same binding constants (Kd). The Kd values for the FFA (4-38 nM) were inversely related to the aqueous solubility of the FFA. We constructed a model with these parameters to predict the FFAu profile in equilibrium with BSA and found excellent agreement between the profiles measured using the FFA probes and those calculated with this model. These results should lead to a better understanding of albumin's role in buffering FFAu and to profiling FFAu in intra- and extracellular biological fluids.

High-resolution quantitative imaging of mammalian and bacterial cells using stable isotope mass spectrometry.

BACKGROUND: Secondary-ion mass spectrometry (SIMS) is an important tool for investigating isotopic composition in the chemical and materials sciences, but its use in biology has been limited by technical considerations. Multi-isotope imaging mass spectrometry (MIMS), which combines a new generation of SIMS instrument with sophisticated ion optics, labeling with stable isotopes, and quantitative image-analysis software, was developed to study biological materials. RESULTS: The new instrument allows the production of mass images of high lateral resolution (down to 33 nm), as well as the counting or imaging of several isotopes simultaneously. As MIMS can distinguish between ions of very similar mass, such as 12C15N- and 13C14N-, it enables the precise and reproducible measurement of isotope ratios, and thus of the levels of enrichment in specific isotopic labels, within volumes of less than a cubic micrometer. The sensitivity of MIMS is at least 1,000 times that of 14C autoradiography. The depth resolution can be smaller than 1 nm because only a few atomic layers are needed to create an atomic mass image. We illustrate the use of MIMS to image unlabeled mammalian cultured cells and tissue sections; to analyze fatty-acid transport in adipocyte lipid droplets using 13C-oleic acid; to examine nitrogen fixation in bacteria using 15N gaseous nitrogen; to measure levels of protein renewal in the cochlea and in post-ischemic kidney cells using 15N-leucine; to study DNA and RNA co-distribution and uridine incorporation in the nucleolus using 15N-uridine and 81Br of bromodeoxyuridine or 14C-thymidine; to reveal domains in cultured endothelial cells using the native isotopes 12C, 16O, 14N and 31P; and to track a few 15N-labeled donor spleen cells in the lymph nodes of the host mouse. CONCLUSION: MIMS makes it possible for the first time to both image and quantify molecules labeled with stable or radioactive isotopes within subcellular compartments.

Different mechanisms of free fatty acid flip-flop and dissociation revealed by temperature and molecular species dependence of transport across lipid vesicles.

The mechanism of free fatty acid (FFA) transport across membranes is a subject of intense investigation. We have demonstrated recently that flip-flop is the rate-limiting step for transport of oleic acid across phospholipid vesicles (Cupp, D., Kampf, J. P., and Kleinfeld, A. M. (2004) Biochemistry 43, 4473-4481). To better understand the nature of the flip-flop barrier, we measured the temperature dependence of a series of saturated and monounsaturated FFA. We determined the rate constants for flip-flop and dissociation for small (SUV), large (LUV), and giant (GUV) unilamellar vesicles composed of egg phosphatidylcholine. For all FFA and vesicle types, dissociation was faster than flip-flop, and for all FFA, flip-flop and dissociation were faster in SUV than in LUV or GUV. Rate constants for both flip-flop and dissociation decreased exponentially with increasing FFA size. However, only the flip-flop rate constants increased significantly with temperature; the barrier to flip-flop was virtually entirely due to an enthalpic activation free energy. The barrier to dissociation was primarily entropic. Analysis in terms of a simple free volume (V(f)) model revealed V(f) values for flip-flop that ranged between approximately 12 and 15 Angstroms(3), with larger values for SUV than for LUV or GUV. V(f) values increased with temperature, and this temperature dependence generated the enthalpic barrier to flip-flop. The barrier for dissociation and its size dependence primarily reflect the aqueous solubility of FFA. These are the first results to distinguish the energetics of flipflop and dissociation. This should lead to a better understanding of the mechanisms governing FFA transport across biological membranes.

Free fatty acid release from human breast cancer tissue inhibits cytotoxic T-lymphocyte-mediated killing.

Immune-mediated antitumor activities confront a variety of tumor-mediated defense mechanisms. Here, we describe a new mechanism involving FFA that may allow breast cancer to evade immune clearance. We determined the IC50 at which unbound free fatty acids (FFA(u)) inhibit murine cytotoxic T-lymphocyte (CTL)-mediated killing to assess the physiologic relevance of this phenomenon. We found that the IC50 for unbound oleate is 125 +/- 30 nM, approximately 200-fold greater than normal plasma levels. FFA inhibition, however, may play an important role in breast cancer because we found that large quantities of FFAs are released constitutively into the media surrounding samples of human breast cancer but not normal or benign tissue. FFA(u) concentration ([FFA(u)]) increased to at least 25 nM in 20 of 22 cancer tissue samples and exceeded 100 nM in 11 patients. Media from these samples inhibited CTL-mediated killing. Extrapolation from our in vitro conditions suggests that for tumor interstitial fluid, in vivo [FFA(u)] may be 300-fold greater than we observed in vitro. Although breast cancer release of FFA may suppress effector cell antitumor activity, strategies that reduce interstitial [FFA(u)] may significantly improve antitumor immune therapies.

Transport of 13C-oleate in adipocytes measured using multi imaging mass spectrometry.

The mechanism of long chain free fatty acid (FFA) transport across cell membranes is under active investigation. Here we describe the use of multi imaging mass spectrometry (MIMS) to monitor intracellular concentrations of FFA and provide new insight into FFA transport in cultured adipocytes. Cells were incubated with 13C-oleate:BSA and either dried directly or dried after washing with a medium deprived of 13C-oleate:BSA. Cells were analyzed with MIMS using a scanning primary Cs+ ion beam and 12C-, 13C-, 12C14N-, 13C14N-) (or 12C 15N-) were imaged simultaneously. From these quantitative images the values of the 13C/ 12C ratios were determined in the intracellular lipid droplets, in the cytoplasm and outside the 3T3F442A adipocytes. The results indicate that after incubation with 13C-oleate:BSA the droplet 13C/ 12C ratio was 15 +/- 6%. This value is about 14-fold higher than the 13C/ 12C terrestrial ratio (1.12%). After washing the 13C-oleate:BSA, the droplet 13C/ 12C ratios decreased to 1.6 +/- 0.1%, about 40% greater than the natural abundance. Results for washed cells indicate that relatively little FFA was esterified. The unwashed cell results, together with the value of the lipid water partition coefficient, reveal that intracellular unbound FFA (FFAu) concentrations were on average about 4.5-fold greater than the extracellular FFAu concentrations. These results are consistent with the possibility that FFA may be pumped into adipocytes against their electro-chemical potential. This work demonstrates that MIMS can be used to image and quantitate stable isotope labeled fatty acid in intracellular lipid droplets.

Fatty acid transport in adipocytes monitored by imaging intracellular free fatty acid levels.

Transport of free fatty acids (FFA) across the adipocyte plasma membrane is critical for maintaining homeostasis. To determine the membrane's role in regulating transport we describe here the first measurements of the intracellular (unbound) FFA concentration ([FFA(i)]) and their use in monitoring transport of FFA across 3T3F442A adipocytes. [FFA(i)] was measured by microinjecting cells with ADIFAB, a fluorescently labeled fatty acid-binding protein that is used to measure unbound FFA levels. We used ratio fluorescence microscopy of intracellular ADIFAB to image unbound FFA levels and determined the time course of [FFA(i)] in response to changing the extracellular unbound FFA concentration ([FFA(o)]). [FFA(o)] was clamped at defined levels using complexes of FFA and bovine serum albumin. We show that FFA influx is slow, requiring about 300 s to reach steady state (rate constant approximately 0.02 s(-1)) and saturable (K(o) approximately 200 nm). Efflux is twice as fast as influx, for zero [FFA(o)], but decreases with increasing [FFA(o)]. Surprisingly, at steady state [FFA(i)] is 2-5-fold (average 2-fold) greater than [FFA(o)] and this [FFA(i)]/[FFA(o)] gradient is abolished by depleting cellular ATP. Our results indicate that FFA transport across adipocyte membranes is highly regulated, involving an ATP-driven pump and a mechanism for gating efflux that is sensitive to [FFA(o)]. These characteristics are well described by a membrane carrier model but are not consistent with FFA transport across the membrane's lipid phase. We suggest that these characteristics are important in regulating circulating FFA levels by the adipocyte.

Fatty acid-albumin complexes and the determination of the transport of long chain free fatty acids across membranes.

Understanding the mechanism that governs the transport of long chain free fatty acids (FFA) across lipid bilayers is critical for understanding transport across cell membranes. Conflicting results have been reported for lipid vesicles; most investigators report that flip-flop occurs within the resolution time of the method (<5 ms) and that dissociation from the membrane is rate limiting, while other studies find that flip-flop is rate limiting and on the order of seconds. We have reinvestigated this problem and find that the methods used in studies reporting rapid flip-flop have not been interpreted correctly. We find that accurate information about transport of FFA across lipid vesicles requires that FFA be delivered to the vesicles as complexes with albumin (BSA). For example, we find that stopped-flow mixing of uncomplexed FFA with small unilamellar vesicles (SUV) containing pyranine yields the very fast influx rates reported previously (>100 s(-1)). However, these influx rates increase linearly with lipid vesicle concentration and can therefore not, as previously interpreted, represent flip-flop. In contrast, measurements of influx rates in SUV and giant unilamellar vesicles performed with oleate-BSA complexes reveal no dependence on vesicle concentration and yield influx rate constants of approximately 4 and approximately 0.5 s(-1), respectively. Rate constants for efflux and dissociation were determined from the transfer of oleate from vesicles to BSA and reveal similar influx and efflux but dissociation rate constants that are approximately 5-10-fold greater. We conclude that flip-flop is rate limiting for transport of FFA across lipid vesicles and slows with an increasing radius of curvature. These results, in contrast to those reporting that flip-flop is extremely fast, indicate that the lipid bilayer portion of biological membranes may present a significant barrier to transport of FFA across cell membranes.

Stopped-flow kinetic analysis of long-chain fatty acid dissociation from bovine serum albumin.

The kinetics of the interaction of long-chain fatty acids (referred to as fatty acids) with albumin is critical to understanding the role of albumin in fatty acid transport. In this study we have determined the kinetics of fatty acid dissociation from BSA and the BSA-related fatty acid probe BSA-HCA (BSA labelled with 7-hydroxycoumarin-4-acetic acid) by stopped-flow methods. Fatty acid-albumin complexes of a range of natural fatty acid types and albumin molecules (donors) were mixed with three fatty acid-binding acceptor proteins. Dissociation of fatty acids from the donor was monitored by either the time course of donor fluorescence/absorbance or the time course of acceptor fluorescence. The results of these measurements indicate that fatty acid dissociation from BSA as well as BSA-HCA is well described by a single exponential function over the entire range of fatty acid/albumin molar ratios used in these measurements, from 0.5:1 to 6:1. The observed rate constants (k(obs)) for the dissociation of each fatty acid type reveal little or no dependence on the initial fatty acid/albumin ratio. However, dissociation rates were dependent upon the type of fatty acid. In the case of native BSA with an initial fatty acid/BSA molar ratio of 3:1, the order of k(obs) values was stearic acid (1.5 s(-1)) < oleic acid < palmitic acid congruent with linoleic acid