Karim S. Echtay

A signalling role for 4-hydroxy-2-nonenal in regulation of mitochondrial uncoupling

Oxidative stress and mitochondrial dysfunction are associated with disease and aging. Oxidative stress results from overproduction of reactive oxygen species (ROS), often leading to peroxidation of membrane phospholipids and production of reactive aldehydes, particularly 4‐hydroxy‐2‐nonenal. Mild uncoupling of oxidative phosphorylation protects by decreasing mitochondrial ROS production. We find that hydroxynonenal and structurally related compounds (such as trans‐retinoic acid, trans‐retinal and other 2‐alkenals) specifically induce uncoupling of mitochondria through the uncoupling proteins UCP1, UCP2 and UCP3 and the adenine nucleotide translocase (ANT). Hydroxynonenal‐induced uncoupling was inhibited by potent inhibitors of ANT (carboxyatractylate and bongkrekate) and UCP (GDP). The GDP‐sensitive proton conductance induced by hydroxynonenal correlated with tissue expression of UCPs, appeared in yeast mitochondria expressing UCP1 and was absent in skeletal muscle mitochondria from UCP3 knockout mice. The carboxyatractylate‐sensitive hydroxynonenal stimulation correlated with ANT content in mitochondria from Drosophila melanogaster expressing different amounts of ANT. Our findings indicate that hydroxynonenal is not merely toxic, but may be a biological signal to induce uncoupling through UCPs and ANT and thus decrease mitochondrial ROS production.

Coenzyme Q is an obligatory cofactor for uncoupling protein function

Uncoupling proteins (UCPs) are thought to be intricately controlled uncouplers that are responsible for the futile dissipation of mitochondrial chemiosmotic gradients, producing heat rather than ATP. They occur in many animal and plant cells and form a subfamily of the mitochondrial carrier family. Physiological uncoupling of oxidative phosphorylation must be strongly regulated to avoid deterioration of the energy supply and cell death, which is caused by toxic uncouplers. However, an H+ transporting uncoupling function is well established only for UCP1 from brown adipose tissue, and the regulation of UCP1 by fatty acids, nucleotides and pH remains controversial. The failure of UCP1 expressed in Escherichia coli inclusion bodies to carry out fatty-acid-dependent H+ transport activity inclusion bodies made us seek a native UCP cofactor. Here we report the identification of coenzyme Q (ubiquinone) as such a cofactor. On addition of CoQ10 to reconstituted UCP1 from inclusion bodies, fatty-acid-dependent H+ transport reached the same rate as with native UCP1. The H+ transport was highly sensitive to purine nucleotides, and activated only by oxidized but not reduced CoQ. H+ transport of native UCP1 correlated with the endogenous CoQ content.

Uncoupling proteins: the issues from a biochemist point of view

The functional characteristics of uncoupling proteins (UCP) are reviewed, with the main focus on the results with isolated and reconstituted proteins. UCP1 from brown adipose tissue, the paradigm of the UCP subfamily, is treated in more detail. The issues addressed are the role and mechanism of fatty acids, the nucleotide binding, the regulation by pH and the identification by mutagenesis of residues involved in these functions. The transport and regulatory functions of UCP2 and 3 are reviewed in comparison to UCP1. The inconsistencies of a proposed nucleotide insensitive H(+) transport by these UCPs as concluded from the expression in yeast and Escherichia coli are elucidated. In both expression system UCP 2 and 3 are not in or cannot be converted to a functionally native state and thus also for these UCPs a nucleotide regulated H (+) transport is postulated.

Regulation of UCP3 by nucleotides is different from regulation of UCP1

UCP3 is an isoform of UCP1, expressed primarily in skeletal muscle. Functional properties of UCP3 are still largely unknown. Here, we report about the expression of UCP3 and of UCP1 in inclusion bodies of Escherichia coli. On solubilization and reconstitution into proteoliposomes, both UCP3 and UCP1 transport Cl− at rates equal to the reconstituted native UCP1. Cl− transport is inhibited by low concentrations of ATP, ADP, GTP and GDP. However, no H+ transport activity is found possibly due to the lack of a cofactor presents in UCP from mitochondria. The specificity of inhibition by nucleoside tri‐ and diphosphate is different between UCP1 and UCP3. UCP1 is more sensitive to tri‐ than diphosphate whereas in UCP3, the gradient is reverse. These results show a new paradigm for the regulation of thermogenesis at various tissues by the ATP/ADP ratio. In brown adipose tissue, the thermogenesis is correlated with a low ATP/ADP whereas in skeletal muscle, non‐shivering thermogenesis is active at a high ATP/ADP ratio, i.e. in the resting state.

Ubiquinone is not required for proton conductance by uncoupling protein 1 in yeast mitochondria.

Q (coenzyme Q or ubiquinone) is reported to be a cofactor obligatory for proton transport by UCPs (uncoupling proteins) in liposomes [Echtay, Winkler and Klingenberg (2000) Nature (London) 408, 609-613] and for increasing the binding of the activator retinoic acid to UCP1 [Tomás, Ledesma and Rial (2002) FEBS Lett. 526, 63-65]. In the present study, yeast ( Saccharomyces cerevisiae ) mutant strains lacking Q and expressing UCP1 were used to determine whether Q was required for UCP function in mitochondria. Wild-type yeast strain and two mutant strains (CENDeltaCOQ3 and CENDeltaCOQ2), both not capable of synthesizing Q, were transformed with the mouse UCP1 gene. UCP1 activity was measured as fatty acid-dependent, GDP-sensitive proton conductance in mitochondria isolated from the cells. The activity of UCP1 was similar in both Q-containing and -deficient yeast mitochondria. We conclude that Q is neither an obligatory cofactor nor an activator of proton transport by UCP1 when it is expressed in yeast mitochondria.

In the Uncoupling Protein (UCP-1) His-214 Is Involved in the Regulation of Purine Nucleoside Triphosphate but Not Diphosphate Binding

The nucleotide binding to uncoupling protein (UCP-1) of brown adipose tissue is regulated by pH. The binding pocket of the nucleotide phosphate moiety has been proposed to be controlled by the protonization of a carboxyl group (pK ≈4.5) for both nucleoside diphosphates (NDP) and nucleoside triphosphates (NTP) (identified as Glu-190) and of a histidine (pK ≈7.2) for NTP only. Here we identify His-214 as a pH sensor specific for NTP binding only. In reconstituted UCP-1 from hamster, DEPC diminishes binding of NTP but not of NDP. It also prevents inhibition of H+ transport by NTP but not by NDP. Hamster UCP-1 expressed in Saccharomyces cerevisiae was mutated to H214N resulting in only moderate change of the binding affinity for NTP (GTP) but a 10-fold affinity decrease with the bulkier substituent in H214W, whereas the affinity for NDP (ADP) was largely unchanged. The steep decrease with pH of the binding affinity for NTP in wild type (from pH 6.0 to 7.5) was much flatter in the mutants. Also, the pH dependence of binding and dissociation rates was diminished in these mutants. The transport of H+ and Cl− was not affected. Thus, His-214 is only involved in nucleotide binding, whereas, as previously shown, His-145 and His-147 are involved only in H+ transport. The results validate the earlier proposal of a histidine regulating the NTP binding in addition to a carboxyl group controlling both NTP and NDP binding. It is proposed that His-214 protrudes into the binding pocket for the γ-phosphate thus inhibiting NTP binding and that His214H+ is retracted by a background –CO2 − group to give way for the γ-phosphate.

Nucleotide binding to human uncoupling protein-2 refolded from bacterial inclusion bodies

Experiments were performed to test the hypothesis that recombinant human uncoupling protein-2 (UCP2) ectopically expressed in bacterial inclusion bodies binds nucleotides in a manner identical with the nucleotide-inhibited uncoupling that is observed in kidney mitochondria. For this, sarkosyl-solubilized UCP2 inclusion bodies were treated with the polyoxyethylene ether detergent C12E9 and hydroxyapatite. Protein recovered from hydroxyapatite chromatography was approx. 90% pure UCP2, as judged by Coomassie Blue and silver staining of polyacrylamide gels. Using fluorescence resonance energy transfer, N-methylanthraniloyl-tagged purine nucleoside di- and tri-phosphates exhibited enhanced fluorescence with purified UCP2. Dissociation constants determined by least-squares non-linear regression indicated that the affinity of UCP2 for these fluorescently tagged nucleotides was 3-5 microM or perhaps an order of magnitude stronger, depending on the model used. Competition experiments with [8-14C]ATP demonstrated that UCP2 binds unmodified purine and pyrimidine nucleoside triphosphates with 2-5 microM affinity. Affinities for ADP and GDP were approx. 10-fold lower. These data indicate that: UCP2 (a) is at least partially refolded from sarkosyl-solubilized bacterial inclusion bodies by a two-step treatment with C12E9 detergent and hydroxyapatite; (b) binds purine and pyrimidine nucleoside triphosphates with low micromolar affinity; (c) binds GDP with the same affinity as GDP inhibits superoxide-stimulated uncoupling by kidney mitochondria; and (d) exhibits a different nucleotide preference than kidney mitochondria.

Molecular properties of purified human uncoupling protein 2 refolded from bacterial inclusion bodies.

One way to study low-abundance mammalian mitochondrial carriers is by ectopically expressing them as bacterial inclusion bodies. Problems encountered with this approach include protein refolding, homogeneity, and stability. In this study, we investigated protein refolding and homogeneity properties of inclusion body human uncoupling protein 2 (UCP2). N-methylanthraniloyl-tagged ATP (Mant-ATP) experiments indicated two independent inclusion body UCP2 binding sites with dissociation constants (Kd) of 0.3–0.5 and 23–92 μM. Dimethylanthranilate, the fluorescent tag without nucleotide, bound with a Kd of greater than 100 μM, suggesting that the low affinity site reflected binding of the tag. By direct titration, UCP2 bound [8-14C] ATP and [8-14C] ADP with Kds of 4–5 and 16–18 μM, respectively. Mg2+ (2 mM) reduced the apparent ATP affinity to 53 μM, an effect entirely explained by chelation of ATP; with Mg2+, Kd using calculated free ATP was 3 μM. A combination of gel filtration, Cu2+-phenanthroline cross-linking, and ultracentrifugation indicated that 75–80% of UCP2 was in a monodisperse, 197 kDa form while the remainder was aggregated. We conclude that (a) Mant-tagged nucleotides are useful fluorescent probes with isolated UCP2 when used with dimethylanthranilate controls; (b) UCP2 binds Mg2+-free nucleotides: the Kd for ATP is about 3–5 μM and for Mant-ATP it is about 10 times lower; and (c) in C12E9 detergent, the monodisperse protein may be in dimeric form.

Uncoupling proteins: Martin Klingenberg's contributions for 40 years

The uncoupling protein (UCP1) is a proton (H+) transporter in the mitochondrial inner membrane. By dissipating the electrochemical H+ gradient, UCP1 uncouples respiration from ATP synthesis, which drives an increase in substrate oxidation via the TCA cycle flux that generates more heat. The mitochondrial uncoupling-mediated non-shivering thermogenesis in brown adipose tissue is vital primarily to mammals, such as rodents and new-born humans, but more recently additional functions in adult humans have been described. UCP1 is regulated by β-adrenergic receptors through the sympathetic nervous system and at the molecular activity level by nucleotides and fatty acid to meet thermogenesis needs. The discovery of novel UCP homologs has greatly contributed to the understanding of human diseases, such as obesity and diabetes. In this article, we review the progress made towards the molecular mechanism and function of the UCPs, in particular focusing on the influential contributions from Martin Klingenbergs laboratory. Because all members of the UCP family are potentially promising drug targets, we also present and discuss possible approaches and methods for UCP-related drug discovery.