The conserved regulation of mitochondrial uncoupling proteins: From unicellular eukaryotes to mammals

Uncoupling proteins (UCPs) belong to the mitochondrial anion carrier protein family and mediate regulated proton leak across the inner mitochondrial membrane. Free fatty acids, aldehydes such as hydroxynonenal, and retinoids activate UCPs. However, there are some controversies about the effective action of retinoids and aldehydes alone; thus, only free fatty acids are commonly accepted positive effectors of UCPs. Purine nucleotides such as GTP inhibit UCP-mediated mitochondrial proton leak. In turn, membranous coenzyme Q may play a role as a redox state-dependent metabolic sensor that modulates the complete activation/inhibition of UCPs. Such regulation has been observed for UCPs in microorganisms, plant and animal UCP1 homologues, and UCP1 in mammalian brown adipose tissue. The origin of UCPs is still under debate, but UCP homologues have been identified in all systematic groups of eukaryotes. Despite the differing levels of amino acid/DNA sequence similarities, functional studies in unicellular and multicellular organisms, from amoebae to mammals, suggest that the mechanistic regulation of UCP activity is evolutionarily well conserved. This review focuses on the regulatory feedback loops of UCPs involving free fatty acids, aldehydes, retinoids, purine nucleotides, and coenzyme Q (particularly its reduction level), which may derive from the early stages of evolution as UCP first emerged.     

Mitochondrial UCPs: new insights into regulation and impact

Uncoupling proteins (UCPs) are mitochondrial inner membrane proteins sustaining an inducible proton conductance. They weaken the proton electrochemical gradient built up by the mitochondrial respiratory chain. Brown fat UCP1 sustains a free fatty acid (FA)-induced purine nucleotide (PN)-inhibited proton conductance. Inhibition of the proton conductance by PN has been considered as a diagnostic of UCP activity. However, conflicting results have been obtained in isolated mitochondria for UCP homologues (i.e., UCP2, UCP3, plant UCP, and protist UCP) where the FFA-activated proton conductance is poorly sensitive to PN under resting respiration conditions. Our recent work clearly indicates that the membranous coenzyme Q, through its redox state, represents a regulator of the inhibition by PN of FFA-activated UCP1 homologues under phosphorylating respiration conditions. Several physiological roles of UCPs have been suggested, including a control of the cellular energy balance as well as the preventive action against oxidative stress. In this paper, we discuss new information emerging from comparative proteomics about the impact of UCPs on mitochondrial physiology, when recombinant UCP1 is expressed in yeast and when UCP2 is over-expressed in hepatic mitochondria during steatosis.     

冷暴露对中缅树鼩褐色脂肪组织中解偶联蛋白1含量的影响

自备抗血清采用酶联免疫法测定了中缅树鼩(Tupaia belangeri)在(5±1)℃冷暴露0 d、7 d、14 d、21d、28 d时,褐色脂肪组织(BAT)中解偶联蛋白1(UCP1)的含量.结果表明,随着冷暴露时间的延长,中缅树鼩的体重、褐色脂肪组织重量均表现出了增加的趋势,BAT线粒体总蛋白和UCP1的含量也呈增加的趋势,其中UCP1的含量在28 d时达到极显著水平,比对照组增加了55.9%.说明冷暴露能够诱导中缅树鼩UCP1表达增加,从而使其适应性产热增加.     

Mitochondrial uncoupling proteins: regulation and physiological role

Uncoupling proteins (UCPs), members of mitochondrial carrier family, are present in mitochondrial inner membrane and mediate free fatty acid-activated, purine-nucleotide-inhibited H+ re-uptake. UCPs can modulate the tightness of coupling between mitochondrial respiration and ATP synthesis. A physiological function of the first described UCP, UCP1 or termogenin, present in mitochondria of mammalian brown adipose tissues is well established. UCP1 plays a role in nonshivering thermogenesis in mammals. The widespread presence of UCPs in eukaryotes, in non-thermogenic tissues of animals, plants and in unicellular organisms implies that these proteins may elicit other functions than thermogenesis. However, the physiological functions of UCP1 homologues are still under debate. They can regulate energy metabolism through modulation of the electrochemical proton gradient and production of ROS. Functional activation of UCPs is proposed to decrease ROS production. Moreover, products of lipid peroxidation can activate UCPs and promote feedback down-regulation of mitochondrial ROS production.     

Mitochondrial uncoupling proteins in unicellular eukaryotes

Uncoupling proteins (UCPs) are members of the mitochondrial anion carrier protein family that are present in the mitochondrial inner membrane and mediate free fatty acid (FFA)-activated, purine nucleotide (PN)-inhibited proton conductance. Since 1999, the presence of UCPs has been demonstrated in some non-photosynthesising unicellular eukaryotes, including amoeboid and parasite protists, as well as in non-fermentative yeast and filamentous fungi. In the mitochondria of these organisms, UCP activity is revealed upon FFA-induced, PN-inhibited stimulation of resting respiration and a decrease in membrane potential, which are accompanied by a decrease in membranous ubiquinone (Q) reduction level. UCPs in unicellular eukaryotes are able to divert energy from oxidative phosphorylation and thus compete for a proton electrochemical gradient with ATP synthase. Our recent work indicates that membranous Q is a metabolic sensor that might utilise its redox state to release the PN inhibition of UCP-mediated mitochondrial uncoupling under conditions of phosphorylation and resting respiration. The action of reduced Q (QH₂) could allow higher or complete activation of UCP. As this regulatory feature was demonstrated for microorganism UCPs (A. castellanii UCP), plant and mammalian UCP1 analogues, and UCP1 in brown adipose tissue, the process could involve all UCPs. Here, we discuss the functional connection and physiological role of UCP and alternative oxidase, two main energy-dissipating systems in the plant-type mitochondrial respiratory chain of unicellular eukaryotes, including the control of cellular energy balance as well as preventive action against the production of reactive oxygen species.     

<Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> Uncoupling Proteins (AtUCPs): insights into gene expression during development and stress response and epigenetic regulation

Mitochondrial inner membrane uncoupling proteins (UCP) catalyze a proton conductance that dissipates the proton electrochemical gradient established by the respiratory chain, thus affecting the yield of ATP synthesis. UCPs are involved in mitochondrial energy flow regulation and have been implicated in oxidative stress tolerance. Based on the global gene expression profiling datasets available for Arabidopsis thaliana, in this review we discuss the regulation of UCP gene expression during development and in response to stress, and provide interesting insights on the possible existence of epigenetic regulation of UCP expression.     

棕榈酸对模拟高原低氧大鼠离体脑线粒体解耦联蛋白活性及质子漏的影响

本文旨在通过观察棕榈酸对模拟高原低氧大鼠离体脑线粒体解耦联蛋白(uncoupling proteins,UCPs)活性的影响及脑线粒体质子漏与膜电位的改变,探讨UCPs在介导游离脂肪酸对低氧时线粒体氧化磷酸化功能改变中的作用.将SpragueDawley大鼠随机分为对照组、急性低氧组和慢性低氧组.低氧大鼠于低压舱内模拟海拔5 000 m高原23 h/d作低氧暴露,分别连续低氧3 d和30 d.用差速密度梯度离心法提取脑线粒体,[3H-GTP法测定UCPs含量与活性,TPMP 电极与Clark氧电极结合法测量线粒体质子漏,罗丹明123荧光法测定线粒体膜电位.结果显示,低氧使脑线粒体内UCPs含量与活性升高、质子漏增加、线粒体膜电位降低;同时,低氧暴露降低脑线粒体对棕榈酸的反应性,UCPs活性的改变率低于对照组,且线粒体UCPs含量、质子漏、膜电位变化率亦出现相同趋势.线粒体质子漏与反映UCPs活性的Kd值呈线性负相关(P<0.01 r=-0.906),与反映UCPs含量的Bmax呈线性正相关(P<0.01,r=0.856),与膜电位呈线性负相关(P<0.01,r=-0.880).以上结果提示,低氧导致的脑线粒体质子漏增加及膜电位降低与线粒体内UCPs活性升高有关,同时低氧暴露能降低脑线粒体对棕榈酸的反应性,提示在高原低氧环境下,游离脂肪酸升高在维持线粒体能量代谢中起着自身保护和调节机制.     

UCP2, UCP3, avUCP, what do they do when proton transport is not stimulated? Possible relevance to pyruvate and glutamine metabolism

Uncoupling proteins (UCPs) are specialized members of the mitochondrial transporter family. They allow passive proton transport through the mitochondrial inner membrane. This activity leads to uncoupling of mitochondrial respiration and to energy waste, which is well documented with UCP1 in brown adipose tissue. The uncoupling activity of the new UCPs (discovered after 1997), such as UCP2 and UCP3 in mammals or avUCP in birds, is more difficult to characterize. However, extensive data support the idea that the new UCPs are involved in the control of reactive oxygen species (ROS) generation. This fits with the hypothesis that mild uncoupling caused by the UCPs prevents ROS production. Activators and inhibitors regulate the proton transport activity of the UCPs. In the absence of activators of proton transport, the UCP allows the permeation of other ions. We suggest that this activity has physiological significance and, for example, UCP3 expressed in glycolytic muscle fibres may be a passive pyruvate transporter ensuring equilibrium between glycolysis and oxidative phosphorylation. Induction of UCP2 expression by glutamine strengthens the proposal that new UCPs could act to determine the choice of mitochondrial substrate. This would obviously have an impact on mitochondrial bioenergetics and ROS production.     

Respiration under control of uncoupling proteins: Clinical perspective

The term 'uncoupling protein' was originally used for the mitochondrial membrane protein UCP1, which is uniquely present in mitochondria of brown adipocytes, thermogenic cells that regulate body temperature in small rodents, hibernators and mammalian newborns. In these cells, UCP1 acts as a proton carrier activated by free fatty acids and creates a shunt between complexes of the respiratory chain and ATP-synthase resulting in a futile proton cycling and dissipation of oxidation energy as heat. Recent identification of new homologues to UCP1 expressed in brown and white adipose tissue, muscle, brain and other tissues together with the hypothesis that these novel uncoupling proteins (UCPs) may regulate thermogenesis and/or fatty acid metabolism and furthermore may protect against free radical oxygen species production have generated considerable optimism for rapid advances in the identification of new targets for pharmacological management of complex pathological syndromes such as obesity, type 2 diabetes or chronic inflammatory diseases. However, since the physiological and biochemical roles of the novel UCPs are not yet clear, the main challenge today consists first of all in providing mechanistic explanation for their functions in cellular physiology. This lively awaited information may be the basis for potential pharmacological targeting of the UCPs in future.     

Canine mitochondrial uncoupling proteins: structure and mRNA expression of three isoforms in adult beagles

Uncoupling proteins (UCPs) are members of the mitochondrial transporter family that dissipate the proton gradient as heat more than via ATP synthesis. In the present study, nucleotide and amino acid sequences of UCPs 1, 2 and 3 of a dog were determined, and their mRNA expression in various peripheral tissues was examined. The sequences were highly (76-97%) homologous to those of other species. Although lower homologies (60-74%) were found when compared among the three canine UCPs, their deduced amino acid sequences had some common domains, such as three mitochondrial carrier protein motifs, six transmembrane alpha-helix domains, and putative purine nucleotide binding domains. By Northern blot analyses, UCP1 mRNA was not detected in any tissues examined. UCP2 mRNA was expressed in most tissues, particularly abundantly in adipose tissue, spleen and lung. Two sizes of UCP3 mRNA were found exclusively in heart and skeletal muscle. These results suggest that canine UCPs have uncoupling activity, and are involved in the regulation of metabolic heat production and/or energy expenditure, as do those of other species.     

Evidence for Involvement of Uncoupling Proteins in Cerebral Mitochondrial Oxidative Phosphorylation Deficiency of Rats Exposed to 5,000 m High Altitude

The present study aimed to investigate the change of proton leak and discuss the role of cerebral uncoupling proteins (UCPs) and its regulatory molecules non-esterified fatty acid (NEFA) in high altitude mitochondrial oxidative phosphorylation deficiency. The model group animals were exposed to acute high altitude hypoxia, and the mitochondrial respiration, protein leak, UCPs abundance/activity and cerebral NEFA concentration were measured. We found that in the model group, cerebral mitochondrial oxidative phosphorylation was severely impaired with decreased ST3 respiration rate and ATP pool. Proton leak kinetics curves demonstrated an increase in proton leak; GTP binding assay pointed out that total cerebral UCPs activity significantly increased; Q-PCR and western blot showed upregulated expression of UCP4 and UCP5. Moreover, cerebral NEFA concentration increased. In conclusion, UCPs mediated proton leak is closely related to cerebral mitochondria oxidative phosphorylation deficiency during acute high altitude hypoxia and NEFA is involved in this signaling pathway.     

Functional characterization of the mitochondrial uncoupling proteins from the white shrimp Litopenaeus vannamei

Mitochondrial uncoupling proteins (UCPs) play an essential role in dissipating the proton gradient and controlling the mitochondrial inner membrane potential. When active, UCPs promote proton leak across the inner membrane, oxidative phosphorylation uncoupling, oxygen uptake increase and decrease the ATP synthesis. Invertebrates possess only isoforms UCP4 and UCP5, however, the role of these proteins is not clear in most species since it may depend on the physiological needs of each animal. This study presents the first functional characterization of crustacean uncoupling proteins from the white shrimp Litopenaeus vannamei LvUCP4 and LvUCP5. Free radicals production in various shrimp organs/tissues was first evaluated, and mitochondria were isolated from shrimp pleopods. The oxygen consumption rate, membrane potential and proton transport of the isolated non-phosphorylating mitochondria were used to determine LvUCPs activation/inhibition. Results indicate that UCPs activity is stimulated in the presence of 4-hydroxyl-2-nonenal (HNE) and myristic acid, and inhibited by the purine nucleotide GDP. A hypoxia/re-oxygenation assay was conducted to determine whether UCPs participate in shrimp mitochondria response to oxidative stress. Isolated mitochondria from shrimp at re-oxygenation produced large quantities of hydrogen peroxide and higher levels of both LvUCPs were immunodetected. Results suggest that, besides the active response of the shrimp antioxidant system, UCP-like activity is activated after hypoxia exposure and during re-oxygenation. LvUCPs may represent a mild uncoupling mechanism, which may be activated before the antioxidant system of cells, to early control reactive oxygen species production and oxidative damage in shrimp.     

Tissue-specific distribution of uncoupling proteins in normal rats and rats with high-fat-diet-induced obesity

Uncoupling proteins (UCPs) are a proton transporter family located in the mitochondrial inner membrane. Thus far, five molecules (UCP1–UCP5) have been identified as members of the UCP family. Recently, UCPs have attracted considerable interest in research on energy metabolism and obesity. However, to date, no study has focused on a comprehensive and systematic evaluation of the tissue-specific distribution of UCPs in obese individuals. Our study presents evidence of differential tissue expression profiles of five isoforms of UCPs in normal and diet-induced obese (DIO) rats using real-time polymerase chain reaction (PCR) analysis. The results clearly show that the tissue-specific expression patterns of individual isoforms between DIO and normal rats are quite distinct, which suggests a close relationship between the alterations in UCP expression and dietary obesity.     

Mitochondrial uncoupling proteins--facts and fantasies

Instead of a comprehensive review, we describe the basic undisputed facts and a modest contribution of our group to the fascinating area of the research on mitochondrial uncoupling proteins. After defining the terms uncoupling, leak, protein-mediated uncoupling, we discuss the assumption that due to their low abundance the novel mitochondrial uncoupling proteins (UCP2 to UCP5) can provide only a mild uncoupling, i.e. can decrease the proton motive force by several mV only. Contrary to this, the highly thermogenic role of UCP1 in brown adipose tissue is not given only by its high content (approximately 5 % of mitochondrial proteins) but also by the low ATP synthase content and high capacity respiratory chain. Fatty acid cycling mechanism as a plausible explanation for the protonophoretic function of all UCPs and some other mitochondrial carriers is described together with the experiments supporting it. The phylogenesis of all UCPs, estimated UCP2 content in several tissues, and details of UCP2 activation are described on the basis of our experiments. Functional activation of UCP2 is proposed to decrease reactive oxygen species (ROS) production. Moreover, reaction products of lipoperoxidation such as cleaved hydroperoxy-fatty acids and hydroxy-fatty acid can activate UCP2 and promote feedback down-regulation of mitochondrial ROS production.     

4-hydroxy-2-nonenal and uncoupling proteins: an approach for regulation of mitochondrial ROS production

One factor that has the potential to regulate reactive oxygen species (ROS) generation is the mild uncoupling of oxidative phosphorylation, i.e. proton (H(+)) leak across the mitochondrial inner membrane. Proton leak has been shown to attenuate ROS generation, whereas ROS and their derivatives (such as superoxide and hydroxynonenal) have been shown to induce H(+) leak through uncoupling proteins (UCPs). This suggests the existence of a feedback loop between ROS and H(+) leak mediated through UCPs. Although the physiological functions of the new UCPs, such as UCP2 and UCP3, are still not established, extensive data support the idea that these mitochondrial carrier proteins are involved in the control of ROS generation. The molecular basis of both ROS generation and hydroxynonenal-induced uncoupling through UCPs is reviewed and the consequences of their interaction for protection against excessive ROS production at the expense of energy production is discussed.     

Alteration of plant mitochondrial proton conductance by free fatty acids. Uncoupling protein involvement

We characterized the uncoupling activity of the plant uncoupling protein from Solanum tuberosum (StUCP) using mitochondria from intact potato tubers or from yeast (Saccharomyces cerevisiae) expressing the StUCP gene. Compared with mitochondria from transfected yeast, StUCP is present at very low levels in intact potato mitochondrial membranes (at least thirty times lower) as shown by immunodetection with anti-UCP1 antibodies. Under conditions that ruled out undesirable effects of nucleotides and free fatty acids on uncoupling activity measurement in plant mitochondria, the linoleic acid-induced depolarization in potato mitochondria was insensitive to the nucleotides ATP, GTP, or GDP. In addition, sensitivity to linoleic acid was similar in potato and in control yeast mitochondria, suggesting that uncoupling occurring in potato mitochondria was because of a UCP-independent proton diffusion process. By contrast, yeast mitochondria expressing StUCP exhibited a higher sensitivity to free fatty acids than those from the control yeast and especially a marked proton conductance in the presence of low amounts of linoleic acid. However, this fatty acid-induced uncoupling was also insensitive to nucleotides. Altogether, these results suggest that uncoupling of oxidative phosphorylation and heat production cannot be the dominant feature of StUCP expressed in native potato tissues. However, it could play a role in preventing reactive oxygen species production as proposed for mammalian UCP2 and UCP3.     

Uncoupling proteins in modulation of mitochondrial functions--therapeutic prospects

Enormous interest in mitochondrial uncoupling proteins (UCPs) is caused by relevant impact of these energy-dissipating systems on cellular energy transduction. A key role of UCPs in regulation of mitochondrial metabolism is supported by existence of their different isoforms in various mammalian tissues. Recent studies have shown that UCPs have an important part in pathogenesis of various disorders, such as obesity, type-2 diabetes, cachexia, aging or tumor. The obscure roles of UCPs in normal physiology and their emerging role in pathophysiology, provide exciting potential for further investigation. However, neither the exact physiological nor biochemical roles of UCP homologues are well understood. Therefore, providing mechanistic explanation of their functions in cellular physiology may be the basis for potential farmacological targeting of UCPs in future on clinical scale.     

Toward understanding the mechanism of ion transport activity of neuronal uncoupling proteins UCP2, UCP4, and UCP5

Neuronal uncoupling proteins (UCP2, UCP4, and UCP5) have crucial roles in the function and protection of the central nervous system (CNS). Extensive biochemical studies of UCP2 have provided ample evidence of its participation in proton and anion transport. To date, functional studies of UCP4 and UCP5 are scarce. In this study, we show for the first time that, despite a low level of amino acid sequence identity with the previously characterized UCPs (UCP1-UCP3), UCP4 and UCP5 share their functional properties. Recombinantly expressed in Escherichia coli, UCP2, UCP4, and UCP5 were isolated and reconstituted into liposome systems, where their conformations and ion (proton and chloride) transport properties were examined. All three neuronal UCPs are able to transport protons across lipid membranes with characteristics similar to those of the archetypal protein UCP1, which is activated by fatty acids and inhibited by purine nucleotides. Neuronal UCPs also exhibit transmembrane chloride transport activity. Circular dichroism spectroscopy shows that these three transporters exist in different conformations. In addition, their structures and functions are differentially modulated by the mitochondrial lipid cardiolipin. In total, this study supports the existence of general conformational and ion transport features in neuronal UCPs. On the other hand, it also emphasizes the subtle structural and functional differences between UCPs that could distinguish their physiological roles. Differentiation between structure-function relationships of neuronal UCPs is essential for understanding their physiological functions in the CNS.