UCP3 overexpression neutralizes oxidative stress rather than nitrosative stress in mouse myotubes

The deleterious effects of oxidants on proteins may be modified by overexpression of uncoupling protein 3 (UCP3) in skeletal muscle cells exposed to hyperoxia or H₂O₂. UCP3 overexpression significantly attenuated the increase in protein carbonylation in response to hyperoxia and H₂O₂ exposures. However, antioxidant enzyme content and activity (superoxide dismutases, peroxiredoxins, glutathione peroxidase-I, and catalase) were reduced or not modified in UCP3-overexpressing myotubes exposed to oxidants. Protein nitration increased in UCP3-overexpressing cells exposed to hyperoxia, but not to H₂O₂. We conclude that protein oxidation rather than nitration is neutralized by UPC3 overexpression in mouse myotubes exposed to abundant reactive oxygen species.     

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.     

Mitochondrial UCP4 attenuates MPP+- and dopamine-induced oxidative stress,mitochondrial depolarization,and ATP deficiency in neurons and is interlinked with UCP2 expression

Mitochondrial uncoupling proteins (UCPs) uncouple oxidative phosphorylation from ATP synthesis. We explored the neuroprotective role of UCP4 with its stable overexpression in SH-SY5Y cells, after exposure to either MPP⁺ or dopamine to induce ATP deficiency and oxidative stress. Cells overexpressing UCP4 proliferated faster in normal cultures and after exposure to MPP⁺ and dopamine. Differentiated UCP4-overexpressing cells survived better when exposed to MPP⁺ with decreased LDH release. Contrary to the mild uncoupling hypothesis, UCP4 overexpression resulted in increased absolute ATP levels (with ADP/ATP ratios similar to those of controls under normal conditions and ADP supplementation) associated with increased respiration rate. Under MPP⁺ toxicity, UCP4 overexpression preserved ATP levels and mitochondrial membrane potential (MMP) and reduced oxidative stress; the preserved ATP level was not due to increased glycolysis. Under MPP⁺ toxicity, the induction of UCP2 expression in vector controls was absent in UCP4-overexpressing cells, suggesting that UCP4 may compensate for UCP2 expression. UCP4 function does not seem to adhere to the mild uncoupling hypothesis in its neuroprotective mechanisms under oxidative stress and ATP deficiency. UCP4 overexpression increases cell survival by inducing oxidative phosphorylation, preserving ATP synthesis and MMP, and reducing oxidative stress.     

The human uncoupling proteins 5 and 6 (UCP5/SLC25A14 and UCP6/SLC25A30) transport sulfur oxyanions,phosphate and dicarboxylates

The human genome encodes 53 members of the solute carrier family 25 (SLC25), also called the mitochondrial carrier family. In this work, two members of this family, UCP5 (BMCP1, brain mitochondrial carrier protein 1 encoded by SLC25A14) and UCP6 (KMCP1, kidney mitochondrial carrier protein 1 encoded by SLC25A30) have been thoroughly characterized biochemically. They were overexpressed in bacteria, purified and reconstituted in phospholipid vesicles. Their transport properties and kinetic parameters demonstrate that UCP5 and UCP6 transport inorganic anions (sulfate, sulfite, thiosulfate and phosphate) and, to a lesser extent, a variety of dicarboxylates (e.g. malonate, malate and citramalate) and, even more so, aspartate and (only UCP5) glutamate and tricarboxylates. Both carriers catalyzed a fast counter-exchange transport and a very low uniport of substrates. Transport was saturable and inhibited by mercurials and other mitochondrial carrier inhibitors at various degrees. The transport affinities of UCP5 and UCP6 were higher for sulfate and thiosulfate than for any other substrate, whereas the specific activity of UCP5 was much higher than that of UCP6. It is proposed that a main physiological role of UCP5 and UCP6 is to catalyze the export of sulfite and thiosulfate (the H₂S degradation products) from the mitochondria, thereby modulating the level of the important signal molecule H₂S.     

Stromal pH and Photosynthesis Are Affected by Electroneutral K and H Exchange through Chloroplast Envelope Ion Channels

Potassium movement across the limiting membrane of the chloroplast inner envelope is known to be linked to counterex-change of protons. For this reason, K⁺ efflux is known to facilitate stromal acidification and the resultant photosynthetic inhibition. However, the specific nature of the chloroplast envelope proteins that facilitate K⁺ fluxes, and the biophysical mechanism which links these cation currents to H⁺ counterflux, is not characterized. It was the objective of this work to elucidate the nature of the system regulating K⁺ flux linked to H⁺ counterflux across the chloroplast envelope. In the absence of external K⁺, exposure of spinach (Spinacia oleracea) chloroplasts to the K⁺ ionophore valinomycin was found to increase the rate of K⁺ efflux and H⁺ influx. These data were interpreted as suggesting that H⁺ counterexchange must be indirectly linked to movement of K⁺ across the envelope. Studies using the K⁺ channel blocker tetraethylammonium indicated that K⁺ likely moves, in a uniport fashion, into or out of the stroma through a monovalent cation channel in the envelope. Blockage of K⁺ efflux from the stroma by exposure to tetraethylammonium was found to restrict H⁺ influx, further substantiating an indirect linkage of these cation currents. Further studies comparing the effect of exogenous H⁺ ionophores and K⁺/H⁺ exchangers suggested that K⁺ uniport through this ion channel likely is the main endogenous pathway for K⁺ currents across the envelope. These experiments were also consistent with the presence of a proton channel in the envelope. Movement of H⁺ through this channel was speculated to be regulated and rate limited by an electroneutral requirement for K⁺ countercurrents through the separate K⁺ uniport pathway. K⁺ and H⁺ fluxes across the chloroplast envelope were envisioned to be interrelated via this mechanism. The significant effect of cation currents across the envelope, as mediated by these channels, on photosynthetic capacity of the isolated chloroplast was also demonstrated.     

Respiration-dependent contraction of swollen heart mitochondria: Participation of the K+/H+ antiporter

Respiration-dependent contraction of heart mitochondria swollen passively in K⁺ nitrate is activated by the ionophore A23187 and inhibited by Mg²⁺. Ion extrusion and osmotic contraction under these conditions are strongly inhibited by quinine, a known inhibitor of the mitochondrial K⁺/H⁺ antiporter, as measured in other systems. The inhibition by quinine is relieved by the exogenous antiporter nigericin. Respiration-dependent contraction is also inhibited by dicyclohexylcarbodiimide (DCCD) when reacted under conditions known to inhibit K⁺/H⁺ antiport (Martinet al., J. Biol. Chem. 259, 2062–2065, 1984). These studies strongly support the concept that K⁺ is extruded from the matrix by the endogenous K⁺/H⁺ antiporter and that inhibition of this component by quinine or DCCD inhibits respiration-dependent contraction. The extrusion of K⁺ nitrate is accompanied by a respiration-dependent efflux of a considerable portion of the endogenous Mg²⁺. This Mg²⁺ efflux does not occur in the presence of nigericin or when the mitochondrial Na⁺/H⁺ antiporter is active. Mg²⁺ efflux may take place on the K⁺/H⁺ antiporter. DCCD, reacted under conditions that do not result in inhibition of the K⁺/H⁺ antiporter, blocks a monovalent cation uniport pathway. This uniport contributes to futile cation cycling at elevated pH, and its inhibition by DCCD stimulates respiration-dependent contraction.     

Nature of the light-induced h efflux and na uptake in cyanobacteria

We investigated the nature of the light-induced, sodium-dependent acidification of the medium and the uptake of sodium by Synechococcus. The rate of acidification (net H⁺ efflux) was strongly and specifically stimulated by sodium. The rates of acidification and sodium uptake were strongly affected by the pH of the medium; the optimal pH for both processes being in the alkaline pH range. Net proton efflux was severely inhibited by inhibitors of adenosine triphosphatase activity, energy transfer, and photosynthetic electron transport, but was not affected by the presence of inorganic carbon (C_i). Light and C_i stimulated the uptake of sodium, but the stimulation by C_i was observed only when C_i was present at the time sodium was provided. Amiloride, a potent inhibitor of Na⁺/H⁺ antiport and Na⁺ channels, stimulated the rate of acidification but inhibited the rate of sodium uptake. It is suggested that acidification might stem from the activity of a light dependent proton excreting adenosine triphosphatase, while sodium transport seems to be mediated by both Na⁺/H⁺ antiport and Na⁺ uniport.     

An investigation into the roles of photosynthesis and respiration in h efflux from aerated suspensions of asparagus mesophyll cells

Aerated and stirred suspensions of mechanically isolated Asparagus sprengeri Regel mesophyll cells were used to investigate the roles of respiration and photosynthesis in net H⁺ efflux. Rates varied between 0.12 and 1.99 nanomoles H⁺ per 10⁶ cells per minute or 3 and 40 nanomoles H⁺ per milligram chlorophyll per minute. The mean rate of H⁺ efflux was 10% greater in the dark. 3-(3,4-Dichlorophenyl)-l,l-dimethylurea, an inhibitor of noncyclic photophosphorylation, did not inhibit H⁺ efflux from illuminated cells. Bubbling with N₂ or addition of oligomycin, an inhibitor of mitochondrial ATP production, resulted in rapid and virtually complete inhibition of H⁺ efflux in light or dark. In the absence of aeration, H⁺ efflux came to a halt but resumed with aeration or illumination. When aeration was switched to CO₂-free air, rates of H⁺ efflux were reduced 43% in the dark and 57% in the light. Oligomycin eliminated dark CO₂ fixation but not photosynthetic CO₂ fixation. It is suggested that H⁺ efflux is dependent on respiration and dark CO₂ fixation, but independent of photosynthesis.     

Different ionic conditions prompt NHE2 and NHE3 translocation to the plasma membrane

We tested whether NHE3 and NHE2 Na⁺/H⁺ exchanger isoforms were recruited to the plasma membrane (PM) in response to changes in ion homeostasis. NHE2-CFP or NHE3-CFP fusion proteins were functional Na⁺/H⁺ exchangers when transiently expressed in NHE-deficient PS120 fibroblasts. Confocal morphometry of cells whose PM was labeled with FM4-64 measured the fractional amount of fusion protein at the cell surface. In resting cells, 10-20% of CFP fluorescence was at PM and stable over time. A protocol commonly used to activate the Na⁺/H⁺ exchange function (NH₄-prepulse acid load sustained in Na⁺-free medium), increased PM percentages of PM NHE3-CFP and NHE2-CFP. Separation of cellular acidification from Na⁺ removal revealed that only NHE3-CFP translocated when medium Na⁺ was removed, and only NHE2-CFP translocated when the cell was acidified. NHE2/NHE3 chimeric proteins demonstrate that the Na⁺-removal response element resides predominantly in the NHE3 cytoplasmic tail and is distinct from the acidification response sequence of NHE2.     

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.     

The ascidian sperm reaction: evidence for Cl- and HCO3- involvement in acid release

Ascidia callosa sperm are triggered to undergo initiation of the sperm reaction (mitochondrial swelling) by increasing the pH or lowering the Na⁺ concentration of the medium. The optimal [Na⁺] for acid release is 20 mM with excellent correlation between acid release and initiation of morphological changes. Increasing the [K⁺] to around 20 mM inhibits acid release when applied up to 1 min after triggering the sperm but with less inhibition at 2 and 4 min, suggesting that K⁺ inhibits initiation of acid release rather than acid release itself. Acid release and the sperm reaction can also be triggered by Cl^?-free (NO^?₃ or glutamate substituted) seawater (SW). Cl^? efflux accompanies H⁺ efflux with twice as many Cl^? being released as H⁺. Both H⁺ and Cl^? release in Cl^?-free SW are dependent upon CO₂ being present in HCO^?₃-free medium, suggesting that H⁺ efflux is in part Cl^? and HCO^?₃-mediated. However, the chloride channel blocking agent SITS has no effect on H⁺ release and augments Cl^? release. Acid release results in a substantial increase in internal pH as determined by partitioning of 9-amino acridine. We envision acid release from ascidian sperm as involving two systems, the Na⁺-dependent acidification system of unreacted sperm and the Cl^?- and HCO^?₃-mediated H⁺ release at activation. The mechanism controlling acid release would then involve inactivation of the internal acidification process and activation of the chloride-bicarbonate-mediated alkalinization process.     

Effects of Extracellular pH on UV-Induced K Efflux from Cultured Rose Cells

Ultraviolet (UV) light causes a specific leakage of K⁺ from cultured rose cells (Rosa damascena). During K⁺ efflux, there is also an increase in extracellular HCO₃⁻ and acidification of the cell interior. We hypothesized that the HCO₃⁻ originated from intracellular hydration of respiratory CO₂ and served as a charge balancing mechanism during K⁺ efflux, the K⁺ and HCO₃⁻ being cotransported out of the cell through specific channels. An alternative hypothesis which would yield similar results would be the countertransport of K⁺ and H⁺. To test these hypotheses, we studied the effect of a range of external pH values (pH 5-9), regulated by various methods (pH-stat, 100 millimolar Tris-Mes buffer, or CO₂ partial pressure), on the UV-induced K⁺ efflux. Both UV-C (<290 nanometers) and UV-B (290-310 nanometers) induced K⁺ efflux with a minimum at about pH 6 to 7, and greater efflux at pH values of 5, 8, and 9. Since pH values of 8 and 9 increased instead of reduced the efflux of K⁺, these data are not consistent with the notion that the efflux of K⁺ is dependent on an influx of H⁺, a process that would be sensitive to external H⁺ concentration. We suggest that the effect of pH on K⁺ efflux may be mediated through the titration of specific K⁺-transporting proteins or channels in the plasma membrane. Since we could not detect the presence of carbonic anhydrase activity in cell extracts, we could not use the location of this enzyme to aid in our interpretation regarding the site of hydration of CO₂.     

Hydroperoxy fatty acid cycling mediated by mitochondrial uncoupling protein UCP2

Functional activation of mitochondrial uncoupling protein-2 (UCP2) is proposed to decrease reactive oxygen species production. Skulachev and Goglia (Skulachev, V. P., and Goglia, F. (2003) FASEB J. 17, 1585-1591) hypothesized that hydroperoxy fatty acid anions are translocated by UCPs but cannot flip-flop across the membrane. We found that the second aspect is otherwise; the addition of synthesized linoleic acid hydroperoxides (LAOOH, a mix of four isomers) caused a fast flip-flop-dependent acidification of liposomes, comparable with the linoleic acid (LA)-dependent acidification. Using Escherichia coli-expressed UCP2 reconstituted into liposomes we found that LAOOH induced purine nucleotide-sensitive H(+) uniport in UCP2-proteoliposomes with higher affinity than LA (K(m) values 97 microM for LAOOH and 275 microM for LA). In UCP2-proteoliposomes LAOOH also induced purine nucleotide-sensitive K(+) influx balanced by anionic charge transfer, indicating that LAOOH was also transported as an anion with higher affinity than linoleate anion, the K(m) values being 90 and 350 microM, respectively. These data suggest that hydroperoxy fatty acids are transported via UCP2 by a fatty acid cycling mechanism. This may alternatively explain the observed activation of UCP2 by the externally generated superoxide. The ability of LAOOH to induce UCP2-mediated H(+) uniport points to the essential role of superoxide reaction products, such as hydroperoxyl radical, hydroxyl radical, or peroxynitrite, initiating lipoperoxidation, the released products of which support the UCP2-mediated uncoupling and promote the feedback down-regulation of mitochondrial reactive oxygen species production.     

Rapid calcium exchange for protons and potassium in cell walls of Chara

Net fluxes of Ca²⁺, H⁺ and K⁺ were measured from intact Chara australis cells and from isolated cell walls, using ion-selective microelectrodes. In both systems, a stimulation in Ca²⁺ efflux (up to 100 nmol m^?2 s^?1, from an influx of ～40 nmol m^?2 s^?1) was detected as the H⁺ or K⁺ concentration was progressively increased in the bathing solution (pH 7.0 to 4.6 or K⁺ 0.2 to 10mol m^?3, respectively). A Ca²⁺ influx of similar size occurred following the reverse changes. These fluxes decayed exponentially with a time constant of about 10 min. The threshold pH for Ca²⁺ efflux (pH 5.2) is similar to a reported pH threshold for acid-induced wall extensibility in a closely related characean species. Application of NH₄⁺ to intact cells caused prolonged H⁺ efflux and also transient Ca²⁺ efflux. We attribute all these net Ca²⁺ fluxes to exchange in the wall with H⁺ or K⁺. A theoretical treatment of the cell wall ion exchanges, using the ‘weak acid Donnan Manning’ (WADM) model, is given and it agrees well with the data. The role of Ca²⁺ in the cell wall and the effect of Ca²⁺ exchanges on the measured fluxes of other ions, including bathing medium acidification by H⁺ efflux, are discussed.     

UCP3 Regulates Single-Channel Activity of the Cardiac mCa1

Mitochondrial Ca²⁺ uptake (mCa²⁺ uptake) is thought to be mediated by the mitochondrial Ca²⁺ uniporter (MCU). UCP2 and UCP3 belong to a superfamily of mitochondrial ion transporters. Both proteins are expressed in the inner mitochondrial membrane of the heart. Recently, UCP2 was reported to modulate the function of the cardiac MCU related channel mCa1. However, the possible role of UCP3 in modulating cardiac mCa²⁺ uptake via the MCU remains inconclusive. To understand the role of UCP3, we analyzed cardiac mCa1 single-channel activity in mitoplast-attached single-channel recordings from isolated murine cardiac mitoplasts, from adult wild-type controls (WT), and from UCP3 knockout mice (UCP3^–/–). Single-channel registrations in UCP3^?/? confirmed a murine voltage-gated Ca²⁺ channel, i.e., mCa1, which was inhibited by Ru360. Compared to WT, mCa1 in UCP3^?/? revealed similar single-channel characteristics. However, in UCP3^?/? the channel exhibited decreased single-channel activity, which was insensitive to adenosine triphosphate (ATP) inhibition. Our results suggest that beyond UCP2, UCP3 also exhibits regulatory effects on cardiac mCa1/MCU function. Furthermore, we speculate that UCP3 might modulate previously described inhibitory effects of ATP on mCa1/MCU activity as well.     

Involvement of 14-3-3 proteins in the osmotic regulation of H+-ATPase in plant plasma membranes

 Taking the binding of fusicoccin to plasma membranes as an indicator of complex formation between the 14-3-3 dimer and H⁺-ATPase, we assessed the effect of osmotic stress on the interaction of these proteins in suspension-cultured cells of sugar beet (Beta vulgaris L.). An increase in osmolarity of the cell incubation medium, accompanied by a decrease in turgor, was found to activate the H⁺ efflux 5-fold. The same increment was observed in the number of high-affinity fusicoccin-binding sites in isolated plasma membranes; the 14-3-3 content in the membranes increased 2- to 3-fold, while the H⁺-ATPase activity changed only slightly. The data obtained indicate that osmotic regulation of H⁺-ATPase in the plant plasma membrane is achieved via modulation of the coupling between H⁺ transport and ATP hydrolysis, and that such regulation involves 14-3-3 proteins. Received: 10 February 2000 / Accepted: 31 March 2000     

Solute transport at the plasmalemma and the early evolution of cells

The evolution of the plasmalemma and its porter systems is considered in relation to selective pressures on primitive cells. Initially the polar lipid bilayer acted to separate the genetic apparatus of the protocell from the rest of the world. The requirement for the supply of nutrients and removal of waste products resulted in the evolution of passive uniporters for a number of organic and inorganic solutes. There was also a requirement for primary active transport, whereby one or more solutes is transported across the membrane contrary to the direction predicted from passive driving forces, with an energy input from light, redox reactions, “high-energy phosphate” or some other metabolic process. Active transport is discussed in terms of cytoplasmic pH regulation, cytoplasmic volume regulation, Ca²⁺ exclusion/phosphate accumulation, and the accumulation of organic (heterotrophic) substrates.It is suggested that volume regulation in wall-less cells was initially achieved by Na⁺ exclusion with active Na⁺ extrusion as a later refinement; the same applies to the maintenance of the characteristically low free Ca²⁺ level in the cytoplasm. A requirement for active phosphate influx is also likely in view of the high concentrations of orthophosphate required for phosphorylation reactions relative to the likely external concentration of phosphate and the inside-negative potential difference. This p.d., which results inter alia from Na⁺ extrusion, makes the maintenance of intracellular pH via passive H⁺ fluxes very difficult in the face of continued intracellular production of H⁺ during fermentation. Hence an early role for primary active extrusion (uniport) of H⁺ is very likely. Such uniport is of universal occurrence in present-day cells. Besides its role in pH regulation and in energy-coupling, H⁺ transport energises secondary (H⁺-linked) transport of many other solutes. We suggest that transport of HCO₃^? might also have a pH-regulating role, but apparently HCO₃^? cannot substitute for H⁺ with respect to energy-coupling and secondary active transport.     

Energy-dependence exchange of K+ in heart mitochondria. K+ efflux.

The efflux ⁴²K⁺ from isolated beef heart mitochondria under conditions of near steadystate K⁺ is increased by repiration and is sensitive to uncouplers and to exogenous Mg² The respiration-dependent efflux is strongly activated by inorganic phosphate in the presence of external K⁺, but not Na⁺, and is inhibited by oxidative phosphorylation. Low concentrations of mersalyl also activate respiration-dependent efflux of ⁴²K⁺ in the absence of net alteration in matrix K⁺. Acetate in the presence of mersalyl brings about net accumulation of K⁺ with retention of internal ⁴²K⁺. The results are consistent with a model in which nearly constant matrix K⁺ is maintained by the regulated interplay between a K⁺ uniport (which is responsive to membrane potential and which is the pathway for K⁺ influx) and a $\text{K}{}^{\mathrm{+}}\text{H}{}^{\mathrm{+}}$ exchanger (which responds to the transmembrane pH differential and which is the pathway for net K⁺ efflux).     

Workshop 7: 2

Glutamine, the preferred precursor for neurotransmitter glutamate, is likely to be the principal substrate for the neuronal System A transporter SAT1 in vivo. By measuring currents associated with SAT1 expression in Xenopus oocytes, we found that SAT1 mediates transport of small, neutral, aliphatic amino acids including glutamine, alanine and the System A‐specific analogue 2‐(methylamino) isobutyrate, each with K_0.5 of 0.3–0.5 mm . Amino acid transport is driven by the Na⁺ electrochemical gradient. Kinetic data indicates that Na⁺/cotransport comprises the ordered binding first of Na⁺ (a voltage‐dependent step), then alanine, then simultaneous translocation. Li⁺ (but not H⁺) can substitute for Na⁺ but results in reduced V_max. In the absence of amino acid, SAT1 mediates a cation leak with selectivity Na⁺, Li⁺, H⁺, K⁺. The temperature‐dependence of the leak current (E_a = 17 ± 3 kcal/mol) is consistent with carrier‐mediated Na⁺ uniport activity (cf 13 ± 2 kcal/mol for Na⁺/alanine cotransport) but the leak does not saturate at physiological [Na⁺], suggesting channel activity. Despite a Na⁺ Hill coefficient of 1, we obtained Na⁺/amino acid coupling coefficients greater than 1 from simultaneous measurement of charge and [³H]alanine or [³H]glutamine uptake. Interpretation of these data is model‐dependent and consistent with either (1) an all‐carrier model in which Na⁺/amino acid cotransport is thermodynamically coupled 2 : 1, cotransport is preferred over Na⁺ uniport, and in which there is little cooperativity between Na⁺ binding events, or (2) 1 : 1 coupling in parallel with an always‐on Na⁺ channel activity. In either scenario, the presence of SAT1 at the plasma membrane and resultant Na⁺ fluxes will place a significant energy burden on the cell.     

Glutathionylation acts as a control switch for uncoupling proteins UCP2 and UCP3

The mitochondrial uncoupling proteins 2 and 3 (UCP2 and -3) are known to curtail oxidative stress and participate in a wide array of cellular functions, including insulin secretion and the regulation of satiety. However, the molecular control mechanism(s) governing these proteins remains elusive. Here we reveal that UCP2 and UCP3 contain reactive cysteine residues that can be conjugated to glutathione. We further demonstrate that this modification controls UCP2 and UCP3 function. Both reactive oxygen species and glutathionylation were found to activate and deactivate UCP3-dependent increases in non-phosphorylating respiration. We identified both Cys(25) and Cys(259) as the major glutathionylation sites on UCP3. Additional experiments in thymocytes from wild-type and UCP2 null mice demonstrated that glutathionylation similarly diminishes non-phosphorylating respiration. Our results illustrate that UCP2- and UCP3-mediated state 4 respiration is controlled by reversible glutathionylation. Altogether, these findings advance our understanding of the roles UCP2 and UCP3 play in modulating metabolic efficiency, cell signaling, and oxidative stress processes.