High‐Fat Diet Feeding Elevates Skeletal Muscle Uncoupling Protein 3 Levels But Not Its Activity in Rats

Objective: The objective of this study is to test the impact of high‐fat diet (HFD) feeding on skeletal muscle (SM) uncoupling protein 3 (UCP3) expression and its association with mitochondrial ion permeability and whole‐body energy homeostasis. Research Methods and Procedures: Sprague–Dawley rats were fed ad libitum either a HFD (60% of energy from fat, n = 6) or a low‐fat diet (12% of energy from fat, n = 6) for 4 weeks. Twenty‐four‐hour energy expenditure was measured by indirect calorimetry in the last week of the dietary treatment. Blood samples were collected for plasma leptin and free fatty acid assays, and mitochondria were isolated from hindlimb SM for subsequent determinations of UCP3 levels and mitochondrial ion permeability. Results: Plasma leptin levels were higher in rats fed the HFD despite the same body weight in two groups. The same dietary treatment also rendered a 2‐fold increase in plasma free fatty acid and SM UCP3 protein levels (Western blot) compared with the group fed the low‐fat diet. However, the elevated UCP3 protein levels did not correlate with mitochondrial swelling rates, a measure of mitochondrial chloride, and proton permeability, or with 24‐hour energy expenditure. Discussion: The high correlation between the levels of plasma free fatty acid levels and SM UCP3 suggests that circulating free fatty acid may play an important role in UCP3 expression during the HFD feeding. However, the dissociation between the UCP3 protein levels and 24‐hour energy expenditure as well as mitochondrial ion permeability suggests that mitochondrial proton leak mediated by muscle UCP3 may not be a major contributor in energy balance in HFD feeding, and other regulatory mechanisms independent of gene regulation may be responsible for the control of UCP3‐mediated uncoupling activity.     

Fatty acid activation of the uncoupling proteins requires the presence of the central matrix loop from UCP1

Noradrenaline signals the initiation of brown fat thermogenesis and the fatty acids liberated by the hormone-stimulated lipolysis act as second messengers to activate the uncoupling protein UCP1. UCP1 is a mitochondrial transporter that catalyses the re-entry of protons to the mitochondrial matrix thus allowing a regulated discharge of the proton gradient. The high affinity of UCP1 for fatty acids is a distinct feature of this uncoupling protein. The uncoupling proteins belong to a protein superfamily formed by the mitochondrial metabolite carriers. Members of this family present a tripartite structure where a domain containing two transmembrane helices, linked by a long hydrophilic loop, is repeated three times. Using protein chimeras, where the repeats had been swapped between UCP1 and UCP3, it has been shown that the central third of UCP1 is necessary and sufficient for the response of the protein to fatty acids. We have extended those studies and in the present report we have generated protein chimeras where different regions of the second repeat of UCP1 have been sequentially replaced with their UCP2 counterparts. The resulting chimeras present a progressive degradation of the characteristic bioenergetic properties of UCP1. We demonstrate that the presence of the second matrix loop is necessary for the high affinity activation of UCP1 by fatty acids.     

Physiological regulation of the transport activity in the uncoupling proteins UCP1 and UCP2

Brown fat is a thermogenic organ that allows newborns and small mammals to maintain a stable body temperature when exposed to cold. The heat generation capacity is based on the uncoupling of respiration from ATP synthesis mediated by the uncoupling protein UCP1. The first studies on the properties of these mitochondria revealed that fatty acid removal was an absolute prerequisite for respiratory control. Thus fatty acids, that are substrate for oxidation, were proposed as regulators of respiration. However, their ability to uncouple all types of mitochondria and the demonstration that several mitochondrial carriers catalyze the translocation of the fatty acid anion have made them unlikely candidates for a specific role in brown fat. Nevertheless, data strongly argue for a physiological function. First, fatty acids mimic the noradrenaline effects on adipocytes. Second, there exists a precise correlation between fatty acid sensitivity and the levels of UCP1. Finally, fatty acids increase the conductance by facilitating proton translocation, a mechanism that is distinct from the fatty acid uncoupling mediated by other mitochondrial carriers. The regulation of UCP1 and UCP2 by retinoids and the lack of effects of fatty acids on UCP2 or UCP3 are starting to set differences among the new uncoupling proteins.     

Towards comprehension of the physiological role of UCP3.

Thyroid hormones have long been known to stimulate energy expenditure partly via loss of metabolic efficiency. The mechanism underlying the loss in metabolic efficiency observed, however, is not yet understood. An important candidate gene responsible for thyroid hormone induced thermogenesis was identified in 1997 with the discovery of skeletal muscle-uncoupling protein 3 (UCP3), a protein with approximately 60 % homology to the brown adipose tissue uncoupling protein 1 (UCP1). This short review summarizes our presentation held at the 'Thyroid and Sports' meeting; it does not aim to provide a concise overview of the available literature at this topic. Although induction of the UCP3 gene and increased protein expression during hyperthyroidism has been shown, there are no convincing data that increased UCP3 levels account for the increase in thermogenesis in the hyperthyroid state in humans. In contrast to cell and animal studies using ectopic overexpression of UCP3 as a model, induction of UCP3 in humans does not result in any apparent mitochondrial uncoupling. Hence, the primary physiological role of UCP3 may not be mitochondrial uncoupling, but uncoupling may occur as a side effect of a more pivotal role played by UCP3. Recently, UCP3 has been hypothesized to export fatty acid anions and/or lipid peroxides away from the mitochondrial matrix to prevent mitochondria from the harmful effects of peroxidized lipids. The present review aims to provide an overview of studies testing the feasibility of this unconventional function of UCP3.     

Functional characterisation of UCP1 in the common carp: uncoupling activity in liver mitochondria and cold-induced expression in the brain

Mammalian uncoupling protein 1 (UCP1) mediates nonshivering thermogenesis in brown adipose tissue. We previously reported on the presence of a UCP1 orthologue in ectothermic fish and observed downregulation of UCP1 gene expression in the liver of the common carp. Neither the function of UCP1, nor the mode of UCP1 activation is known in carp liver mitochondria. Here, we compared the proton conductance at 25°C of liver mitochondria isolated from carp either maintained at 20°C (warm-acclimated, WA) or exposed to 8°C (cold-acclimated, CA) water temperature for 7–10 days. Liver mitochondria from WA carp had higher state four rates of oxygen consumption and greater proton conductance at high membrane potential. Liver mitochondria from WA, but not from CA, carp showed a strong increase in proton conductance when palmitate (or 4-hydroxy-trans-2-nonenal, HNE) was added, and this inducible proton conductance was prevented by addition of GDP. This fatty acid sensitive proton leak is likely due to the expression of UCP1 in the liver of WA carp. The observed biochemical properties of proton leak strongly suggest that carp UCP1 is a functional uncoupling protein with broadly the same activatory and inhibitory characteristics as mammalian UCP1. Significant UCP1 expression was also detected in our previous study in whole brain of the carp. We here observed a twofold increase of UCP1 mRNA in carp brain following cold exposure, suggesting a role of UCP1 in the thermal adaptation of brain metabolism. In situ hybridization located the UCP1 gene expression to the optic tectum responsible for visual system control, the descending trigeminal tract and the solitary tract. Taken together, this study characterises uncoupling protein activity in an ectotherm for the first time. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Uncoupling Protein—A Useful Energy Dissepator

The structure/function relationship in the uncoupling proteins (UCP) is reviewed, stressingUCP from brown adipose tissue (UCP1) since, so far, nearly no biochemistry is known forthe UCP variants UCP2, UCP3, and UCP4. The transport for H⁺ and Cl^– and its dependenceon fatty acids in reconstituted vesicles is described. The inhibition and binding of nucleotidesto UCP1, in particular, the pH dependence and two-stage binding are analyzed. A model forthe role of fatty acid in H⁺ transport is shown. The role of specific residues in UCP1 isanalyzed by directed mutagenesis in a yeast expression system. The different regulation bythe cellular energy potential of UCP1 versus UCP3 is discussed.     

Human Uncoupling Protein‐3 and Obesity: An Update

The cloning of the uncoupling protein (UCP)1 homologs UCP2 and UCP3 has raised considerable interest in the mechanism. The expression of UCP3 mainly in skeletal muscle mitochondria and the potency of the skeletal muscle as a thermogenic organ made UCP3 an attractive target for studies toward manipulation of energy expenditure to fight disorders such as obesity and type 2 diabetes. Overexpressing UCP3 in mice resulted in lean, hyperphagic mice. However, the lack of an apparent phenotype in mice lacking UCP3 triggered the search for alternative functions of UCP3. The observation that fatty acid levels significantly affect UCP3 expression has given UCP3 a position in fatty acid handling and/or oxidation. Emerging data indicate that the primary physiological role of UCP3 may be the mitochondrial handling of fatty acids rather than the regulation of energy expenditure through thermogenesis. It has been proposed that UCP3 functions to export fatty acid anions away from the mitochondrial matrix. In doing so, fatty acids are exchanged with protons, explaining the uncoupling activity of UCP3. The exported fatty acid anions may originate from hydrolysis of fatty acid esters by a mitochondrial thioesterase, or they may have entered the mitochondria as nonesterified fatty acids by incorporating into and flip‐flopping across the mitochondrial inner membrane. Regardless of the origin of the fatty acid anions, this putative function of UCP3 might be of great importance in protecting mitochondria against fatty acid accumulation and may help to maintain muscular fat oxidative capacity.     

Uncoupled respiration, ROS production, acute lipotoxicity and oxidative damage in isolated skeletal muscle mitochondria from UCP3-ablated mice

The function of uncoupling protein 3 (UCP3) is still not established. Mitochondrial uncoupling, control of ROS production, protection against lipotoxicity and protection against oxidative stress are functions classically discussed. To establish a role for UCP3 in these functions, we have here used UCP3 (-/-) mice, backcrossed for 10 generations on a C57Bl/6 background. In isolated skeletal muscle mitochondria, we examined uncoupled respiration, both unstimulated and in the presence of fatty acids. We did not observe any difference between mitochondria from wildtype and UCP3 (-/-) mice. We measured H(2)O(2) production rate and respiration rate under reactive oxygen species-generating conditions (succinate without rotenone) but found no effect of UCP3. We tested two models of acute lipotoxicity-fatty acid-induced oxidative inhibition and fatty acid-induced swelling-but did not observe any protective effect of UCP3. We examined oxidative stress by quantifying 4-hydroxynonenal protein adducts and protein carbonyls in the mitochondria-but did not observe any protective effect of UCP3. We conclude that under the experimental conditions tested here, we find no evidence for the function of UCP3 being basal or induced uncoupling, regulation of ROS production, protection against acute lipotoxicity or protection against oxidative damage.     

Inhibition of mitochondrial UCP1 and UCP3 by purine nucleotides and phosphate

Mitochondrial membrane uncoupling protein 3 (UCP3) is not only expressed in skeletal muscle and heart, but also in brown adipose tissue (BAT) alongside UCP1, which facilitates a proton leak to support non-shivering thermogenesis. In contrast to UCP1, the transport function and molecular mechanism of UCP3 regulation are poorly investigated, although it is generally agreed upon that UCP3, analogous to UCP1, transports protons, is activated by free fatty acids (FFAs) and is inhibited by purine nucleotides (PNs). Because the presence of two similar uncoupling proteins in BAT is surprising, we hypothesized that UCP1 and UCP3 are differently regulated, which may lead to differences in their functions. By combining atomic force microscopy and electrophysiological measurements of recombinant proteins reconstituted in planar bilayer membranes, we compared the level of protein activity with the bond lifetimes between UCPs and PNs. Our data revealed that, in contrast to UCP1, UCP3 can be fully inhibited by all PNs and IC50 increases with a decrease in PN-phosphorylation. Experiments with mutant proteins demonstrated that the conserved arginines in the PN-binding pocket are involved in the inhibition of UCP1 and UCP3 to different extents. Fatty acids compete with all PNs bound to UCP1, but only with ATP bound to UCP3. We identified phosphate as a novel inhibitor of UCP3 and UCP1, which acts independently of PNs. The differences in molecular mechanisms of the inhibition between the highly homologous transporters UCP1 and UCP3 indicate that UCP3 has adapted to fulfill a different role and possibly another transport function in BAT.     

Fatty Acid Interaction with Mitochondrial Uncoupling Proteins

The phenomena of fatty acid interaction with mitochondrial integral membrane proteins, namelyuncoupling proteins (UCPs), are reviewed to emphasize the fatty acid cycling mechanism thathas been suggested to explain the UCP function. Fatty acid-induced uncoupling is suggestedto serve in bioenergetic systems, to set the optimum efficiency, and to tune the degree ofcoupling of oxidative phosphorylation. Fatty acid interaction with the classic uncouplingprotein (UCP1) from mitochondria of thermogenic brown adipose tissue (BAT) is well known.UCP1 is considered to mediate purine nucleotide-sensitive uniport of monovalent unipolaranions, including anionic fatty acids. The return of protonated fatty acid leads to H⁺ uniportand uncoupling. Experiments supporting this mechanism are also reviewed for plant uncouplingmitochondrial protein (PUMP) and ADP/ATP carrier. The fatty acid cycling mechanism ispredicted, as well for the recently discovered uncoupling proteins, UCP2 and UCP3.     

Molecular cloning of lamprey uncoupling protein and assessment of its uncoupling activity using a yeast heterologous expression system

We report the molecular cloning of a novel cDNA fragment from lamprey encoding a 313-amino acid protein that is highly homologous to human uncoupling proteins (UCP). We therefore named the protein lamprey UCP. This lamprey UCP, rat UCP1, human UCP2, and human mitochondrial oxoglutarate carrier were individually expressed in Saccharomyces cerevisiae and the recombinant yeast mitochondria were isolated and assayed for the state 4 respiration rate and proton leak. Only UCP1 showed a strong (3.6-fold increase of the ratio of mitochondrial state 4 respiration rate to FCCP-stimulated fully uncoupled respiration rate) and GDP-inhibitable uncoupling activity, while the uncoupling activities of both UCP2 and lamprey UCP were relatively weak (1.5-fold and 1.4-fold, respectively) and GDP-insensitive. The oxoglutarate carrier had no effect on the studied parameters. In conclusion, the lamprey UCP has a mild, unregulated uncoupling activity in the yeast system, which resembles UCP2, but not UCP1.     

Uncoupling mechanism and redox regulation of mitochondrial uncoupling protein 1 (UCP1)

Brown adipose tissue (BAT) and brown in white (brite) adipose tissue, termed also beige adipose tissue, are major sites of mammalian nonshivering thermogenesis. Mitochondrial uncoupling protein 1 (UCP1), specific for these tissues, is the key factor for heat production. Recent molecular aspects of UCP1 structure provide support for the fatty acid cycling model of coupling, i.e. when UCP1 expels fatty acid anions in a uniport mode from the matrix, while uncoupling. Protonophoretic function is ensured by return of the protonated fatty acid to the matrix independent of UCP1. This mechanism is advantageous for mitochondrial uncoupling and compatible with heat production in a pro-thermogenic environment, such as BAT. It must still be verified whether posttranslational modification of UCP1, such as sulfenylation of Cys253, linked to redox activity, promotes UCP1 activity. BAT biogenesis and UCP1 expression, has also been linked to the pro-oxidant state of mitochondria, further endorsing a redox signalling link promoting an establishment of pro-thermogenic state. We discuss circumstances under which promotion of superoxide formation exceeds its attenuation by uncoupling in mitochondria and throughout point out areas of future research into UCP1 function.     

Cold tolerance of UCP1-ablated mice: A skeletal muscle mitochondria switch toward lipid oxidation with marked UCP3 up-regulation not associated with increased basal,fatty acid- or ROS-induced uncoupling or enhanced GDP effects

Mice lacking the thermogenic mitochondrial membrane protein UCP1 (uncoupling protein 1) - and thus all heat production from brown adipose tissue - can still adapt to a cold environment (4 °C) if successively transferred to the cold. The mechanism behind this adaptation has not been clarified. To examine possible adaptive processes in the skeletal muscle, we isolated mitochondria from the hind limb muscles of cold-acclimated wild-type and UCP1(–/–) mice and examined their bioenergetic chracteristics. We observed a switch in metabolism, from carbohydrate towards lipid catabolism, and an increased total mitochondrial complement, with an increased total ATP production capacity. The UCP1(–/–) muscle mitochondria did not display a changed state-4 respiration rate (no uncoupling) and were less sensitive to the uncoupling effect of fatty acids than the wild-type mitochondria. The content of UCP3 was increased 3-4 fold, but despite this, endogenous superoxide could not invoke a higher proton leak, and the small inhibitory effect of GDP was unaltered, indicating that it was not mediated by UCP3. Double mutant mice (UCP1(–/–) plus superoxide dismutase 2-overexpression) were not more cold sensitive than UCP1(–/–), bringing into question an involvement of reactive oxygen species (ROS) in activation of any alternative thermogenic mechanism. We conclude that there is no evidence for an involvement of UCP3 in basal, fatty-acid- or superoxide-stimulated oxygen consumption or in GDP sensitivity. The adaptations observed did not imply any direct alternative process for nonshivering thermogenesis but the adaptations observed would be congruent with adaptation to chronically enhanced muscle activity caused by incessant shivering in these mice.     

Identification and characterization of uncoupling protein 4 in fat body and muscle mitochondria from the cockroach <Emphasis Type="Italic">Gromphadorhina cocquereliana</Emphasis>

We have identified and characterized an uncoupling protein in mitochondria isolated from leg muscle and from fat body, an insect analogue tissue of mammalian liver and adipose tissue, of the cockroach Gromphadorhina coquereliana (GcUCP). This is the first functional characterization of UCP activity in isolated insect mitochondria. Bioenergetic studies clearly indicate UCP function in both insect tissues. In resting (non-phosphorylating) mitochondria, cockroach GcUCP activity was stimulated by the addition of micromolar concentrations of palmitic acid and inhibited by the purine nucleotide GTP. Moreover, in phosphorylating mitochondria, GcUCP activity was able to divert energy from oxidative phosphorylation. Functional studies indicate a higher activity of GcUCP-mediated uncoupling in cockroach muscle mitochondria compared to fat body mitochondria. GcUCP activation by palmitic acid resulted in a decrease in superoxide anion production, suggesting that protection against mitochondrial oxidative stress may be a physiological role of UCPs in insects. GcUCP protein was immunodetected using antibodies raised against human UCP4 as a single band of around 36 kDa. GcUCP protein expression in cockroach muscle mitochondria was significantly higher compared to mitochondria isolated from fat body. LC-MS/MS analyses revealed 100% sequence identities for peptides obtained from GcUCP to UCP4 isoforms from D. melanogaster (the highest homology), human, rat or other insect mitochondria. Therefore, it can be proposed that cockroach GcUCP corresponds to the UCP4 isoforms of other animals.     

Human Uncoupling Proteins and Obesity

SCHRAUWEN, PATRICK, KEN WALDER, AND ERIC RAVUSSIN. Human coupling proteins and obesity. Obes. Res. 1999;7:97–105. Uncoupling protein (UCP) 2 and UCP3 are newly discovered proteins that can uncouple ATP production from mitochondrial respiration, thereby dissipating energy as heat and affecting energy metabolism efficiency. In contrast to UCP1, which is only present in brown adipose tissue, UCP2 has a wide tissue distribution, whereas UCP3 is expressed predominantly in skeletal muscle. Some evidence of a role for UCPs in modulating metabolic rate was provided by linkage and association studies. Furthermore, UCP3 gene expression was found to correlate negatively with body mass index and positively with sleeping metabolic rate in Pima Indians. Treatment with thyroid hormone increases expression of the UCP2 and UCP3 genes. Other regulators of UCP2 and UCP3 gene expression are β₃-adrenergic agonists and glucocorticoids. Surprisingly, fasting has a stimulatory effect on UCP2 and UCP3 mRNA levels, possibly explained by the effects of free fatty acid on UCP2 and UCP3 gene expression.     

Tissue-specific expression and cold-induced mRNA levels of uncoupling proteins in the Djungarian hamster

The uncoupling protein 1 (UCP1), a mitochondrial transmembrane protein, is responsible for adaptive thermogenesis in brown adipose tissue (BAT). Two UCP1 homologues, UCP2 and UCP3, were recently discovered, but it is controversial whether they also play a role in energy homeostasis. Djungarian hamster UCPs were found to exhibit high similarity with homologues known in other species. UCP1 mRNA was restricted to BAT, UCP2 mRNA was expressed in multiple tissues, and UCP3 mRNA was detected mainly in BAT and skeletal muscles. We examined the cold-induced regulation of hamster UCP mRNA levels and tested their correlation with serum free fatty acid (FFA) concentrations. In BAT UCP1, UCP2, and UCP3 expression was upregulated in the cold, but the increase and time course of increase differed. In skeletal muscle, UCP2 and UCP3 mRNA levels were not altered. Cold-induced changes of serum FFA levels correlated with the stimulation of UCP1 mRNA in BAT but not with UCP2 and UCP3.     

UCP2, not a physiologically relevant uncoupler but a glucose sparing switch impacting ROS production and glucose sensing

In mammals the two proteins UCP2 and UCP3 are highly similar to the mitochondrial uncoupling protein found in the brown adipose tissue (UCP1). Accordingly, it was proposed that UCP2 and UCP3 are also uncoupling proteins i.e. protonophores with impact on mitochondrial ROS production and glucose signaling. However, it appears now impossible to explain the physiological relevance of the new UCPs uniquely by their uncoupling activity as observed in vitro. Therefore, we propose a metabolic hypothesis in which UCP2 acts through a transport distinct of the proton transport. A consequence of this transport activity would be a decrease of the mitochondrial oxidation of the pyruvate originating from glucose. This would put UCP2 and UCP3 in a crucial position to influence cellular metabolism. The tight control exerted on UCP2 expression appears consistent with it. In this hypothesis, UCP2/3 would allow a cell to remain glycolytic within an aerobic organism. This tallies with the high expression level of UCP2 or UCP3 in glycolytic cells. The metabolic hypothesis would explain the spectacular modifications associated with UCP2 manipulation as well as the uncoupling activity usually called for and which in fact remains elusive in vivo.     

UCP1: The Original Uncoupling Protein—and Perhaps the Only One? New Perspectives on UCP1, UCP2, and UCP3 in the Light of the Bioenergetics of the UCP1-Ablated Mice

The availability of a UCP1-ablated mouse has enabled critical studies of the function of UCP1,UCP2, and UCP3. Concerning UCP1, its presence in brown-fat mitochondria is associatedwith innate uncoupling, high GDP-binding capacity, and GDP-inhibitable Cl^- permeabilityand uncoupling—but the high fatty acid sensitivity found in these mitochondria is observedeven in the absence of UCP1. The absence of UCP1 leads to low cold tolerance but not toobesity. UCP1 ablation also leads to an augmented expression of UCP2 and UCP3 in brownadipose tissue, making this tissue probably the one that boasts the highest expression ofthese UCPs. However, these very high expression levels are not associated with any inherentuncoupling, or with a specific GDP-binding capacity, or with a GDP-sensitive Cl^- permeability,or with any effect of GDP on mitochondrial membrane potential, or with an increased basalmetabolism of cells, or with the presence of norepinephrine- or fatty acid-induced thermogenesisin cells, and not with a cold-acclimation recruited, norepinephrine-induced thermogenicresponse in the intact animal. Therefore, it can be discussed whether any uncoupling effect isassociated with UCP2 or UCP3 when they are endogenously expressed and, consequently,whether (loss of) uncoupling (thermogenic) effects of UCP2 or UCP3 can be invoked toexplain metabolic phenomena, such as obesity.     

Putative function and physiological relevance of the mitochondrial uncoupling protein-3: involvement in fatty acid metabolism?

The discovery of the human homologue of the thermogenic protein UCP1, named uncoupling protein 3 (UCP3), boosted research on the role of this skeletal muscle protein in energy metabolism and body weight regulation. Nowadays, 9 years after its discovery emerging data indicate that the primary physiological role of UCP3 may be the mitochondrial handling of fatty acids rather than regulating energy expenditure via thermogenesis. UCP3 has been proposed to export fatty acid anions or fatty acid peroxides away from the matrix-side of the mitochondrial inner membrane to prevent their deleterious accumulation. In this way, UCP3 could protect mitochondria against lipid-induced oxidative mitochondrial damage, a function especially important under conditions of high fatty acid supply to skeletal muscle mitochondria. Such function may be clinically relevant in the development of type 2 diabetes mellitus, a condition characterized by muscular fat accumulation, mitochondrial damage and low levels of UCP3.     

Reconstitution of novel mitochondrial uncoupling proteins UCP2 and UCP3

Reconstitution of novel mitochondrial uncoupling proteins, human UCP2 and UCP3, expressed in yeast, was performed to characterize fatty acid (FA)-induced H⁺ efflux in the resulted proteoliposomes. We now demonstrate for the first time that representatives of physiologically abundant long chain FAs, saturated or unsaturated, activate H⁺ translocation in UCP2- and UCP3-proteoliposomes. Efficiency of lauric, palmitic or linoleic acid was roughly the same, but oleic acid induced faster H⁺ uniport. We have confirmed that ATP and GTP inhibit such FA-induced H⁺ uniport mediated by UCP2 and UCP3. Coenzyme Q₁₀ did not further significantly activate the observed H⁺ efflux. In conclusion, careful instant reconstitution yields intact functional recombinant proteins, UCP2 and UCP3, the activity of which is comparable with UCP1.