Mitochondrial Anion Transport Research Articles

Mitochondrial Uncoupling Proteins (UCPs) as Key Modulators of ROS Homeostasis: A Crosstalk between Diabesity and Male Infertility?

Uncoupling proteins (UCPs) are transmembrane proteins members of the mitochondrial anion transporter family present in the mitochondrial inner membrane. Currently, six homologs have been identified (UCP1-6) in mammals, with ubiquitous tissue distribution and multiple physiological functions. UCPs are regulators of key events for cellular bioenergetic metabolism, such as membrane potential, metabolic efficiency, and energy dissipation also functioning as pivotal modulators of ROS production and general cellular redox state. UCPs can act as proton channels, leading to proton re-entry the mitochondrial matrix from the intermembrane space and thus collapsing the proton gradient and decreasing the membrane potential. Each homolog exhibits its specific functions, from thermogenesis to regulation of ROS production. The expression and function of UCPs are intimately linked to diabesity, with their dysregulation/dysfunction not only associated to diabesity onset, but also by exacerbating oxidative stress-related damage. Male infertility is one of the most overlooked diabesity-related comorbidities, where high oxidative stress takes a major role. In this review, we discuss in detail the expression and function of the different UCP homologs. In addition, the role of UCPs as key regulators of ROS production and redox homeostasis, as well as their influence on the pathophysiology of diabesity and potential role on diabesity-induced male infertility is debated.

Two-photon fluorescence imaging of mitochondrial superoxide anion transport mediating liver ischemia-reperfusion injury in mice.

We constructed a two-photon fluorescence ratio probe (CST) for in situ quantitative real-time detection of mitochondrial O2˙-. Fluorescence imaging showed that O2˙- was over-generated from mitochondria and conveyed to the cytoplasm via voltage-dependent anion channels in hepatic ischemia-reperfusion mice, damaging the important functional protein aconitase in the cytoplasm.

91 - Unveil mitochondrial superoxide anion transport pathway in ischemia/reperfusion injury of the mouse liver via two-photon fluorescence imaging

Monitor dynamic changes in mitochondrial and cytoplasmic superoxide anion (O2•−) levels can unveil O2•− signalling pathway of hepatic ischemia/reperfusion (IR) injury and find relative therapeutic target. However, reversible and ratio two-photon fluorescence probe for mitochondrial O2•− hasn’t been presented. Therefore, we developed a reversible and ratio two-photon fluorescence probe for mitochondrial O2•−. With the aid of a cytoplasm O2•− probe and two-photon fluorescent microscopy, the crosstalk between mitochondrial O2•− and cytoplasmic O2•− has been explored. We found that mitochondrial O2•− transported to cytoplasm via VDAC channel in hepatic ischemia/reperfused mice. Furthermore, blocking VDAC channel and increasing mitochondrial Mn-SOD may reduce the risk of IR injury death. Our work uncovers mitochondria O2•− possible transport pathway and molecular mechanism of IR injury, also provides a new therapeutic strategy for IR injury.

A differential expression of uncoupling protein-2 associates with renal damage in stroke-resistant spontaneously hypertensive rat/stroke-prone spontaneously hypertensive rat-derived stroke congenic lines.

Uncoupling protein-2 (UCP2), a mitochondrial anion transporter involved in mitochondrial uncoupling, limiting reactive oxygen species formation, is significantly downregulated in kidneys of high-salt-fed stroke-prone spontaneously hypertensive rat (SHRSP), where it associates with increased renal damage occurrence. We aimed at establishing whether UCP2 differential expression associates with renal damage in two stroke-resistant spontaneously hypertensive rat (SHRSR)/SHRSP-derived stroke congenic lines. For this purpose, SHRSR, SHRSP, and two reciprocal stroke congenic lines carrying the (D1Rat134-Mt1pa) segment of chromosome 1 were fed with Japanese style diet for 8 weeks. At 4, 6, and 8 weeks of Japanese diet, kidneys were removed and analyzed for UCP2 gene and protein expression [UCP2 maps within (D1Rat134-Mt1pa)]; nuclear factor kappa-light-chain-enhancer of activated B cells protein expression; oxidized total protein levels; mitochondrial function; gene expression of cubulin, megalin, and nephrin. At 6 and 8 weeks of Japanese diet, histological damage and percentage of high molecular weight urinary proteins excretion were assessed. Introgression of UCP2 in the SHRSP configuration within the SHRSR genome led to UCP2 downregulation upon Japanese diet, as compared with the SHRSR, with significantly reduced ATP levels, increased rate of inflammation, oxidative stress, renal damage, and excretion of high molecular weight proteins. The opposite phenomena were observed in the reciprocal congenic line, compared with the SHRSP. In vitro, high-NaCl medium led to UCP2 downregulation, increased apoptosis/necrosis, and reduced viability in primary renal proximal tubular epithelial cells isolated from SHRSP. Exposure of the SHRSP/proximal tubular epithelial cells to recombinant UCP2 rescued the high-salt-dependent deleterious effects. A differential UCP2 expression associates with different degree of renal damage upon Japanese diet in two SHRSR/SHRSP-derived stroke congenic lines through modulation of mitochondrial function, inflammation, and oxidative stress.

Glia Maturation Factor and Mitochondrial Uncoupling Proteins 2 and 4 Expression in the Temporal Cortex of Alzheimer's Disease Brain.

Alzheimer’s disease (AD) is characterized by the presence of neuropathological lesions containing amyloid plaques (APs) and neurofibrillary tangles (NFTs). AD is associated with mitochondrial dysfunctions, neuroinflammation and neurodegeneration in the brain. We have previously demonstrated enhanced expression of the proinflammatory protein glia maturation factor (GMF) in glial cells near APs and NFTs in the AD brains. Parahippocampal gyrus consisting of entorhinal and perirhinal subdivisions of temporal cortex is the first brain region affected during AD pathogenesis. Current paradigm implicates oxidative stress-mediated neuronal damage contributing to the early pathology in AD with mitochondrial membrane potential regulating reactive oxygen species (ROS) production. The inner mitochondrial membrane anion transporters called the uncoupling proteins (UCPs), function as regulators of cellular homeostasis by mitigating oxidative stress. In the present study, we have analyzed the expression of GMF and mitochondrial UCP2 and UCP4 in the parahippocampal gyrus of AD and non-AD brains by immunostaining techniques. APs were detected by thioflavin-S fluorescence staining or immunohistochemistry (IHC) with 6E10 antibody. Our current results suggest that upregulation of GMF expression is associated with down-regulation of UCP2 as well as UCP4 in the parahippocampal gyrus of AD brains as compared to non-AD brains. Further, GMF expression is associated with up-regulation of inducible nitric oxide synthase (iNOS), the enzyme that induces the production of nitric oxide (NO), as well as nuclear factor kB p65 (NF-κB p65) expression. Also, GMF appeared to localize to the mitochondria in AD brains. Based on our current observations, we propose that enhanced expression of GMF down-regulates mitochondrial UCP2 and UCP4 thereby exacerbating AD pathophysiology and this effect is potentially mediated by iNOS and NF-κB. Thus, GMF functions as an activator protein that interferes with the cytoprotective mechanisms in AD brains.

Cysteine Residues Impact the Stability and Micelle Interaction Dynamics of the Human Mitochondrial β-Barrel Anion Channel hVDAC-2

The anti-apoptotic 19-stranded transmembrane human voltage dependent anion channel isoform 2 (hVDAC-2) β-barrel stability is crucial for anion transport in mitochondria. The role of the unusually high number of cysteine residues in this isoform is poorly understood. Using a Cys-less construct of hVDAC-2, we haveinvestigated the contribution of cysteines to channel function, barrel stability and its influence on the strength of protein-micelle interactions. We observe that despite the overall preservation in barrel structure upon cysteine mutation, subtle local variations in the mode of interaction of the barrel with its refolded micellar environment arise, which may manifest itself in the channel activity of both the proteins.Fluorescence measurements of the Trp residues in hVDAC-2 point to possible differences in the association of the barrel with lauryldimethylamine oxide (LDAO) micelles. Upon replacement of cysteines in hVDAC-2, our data suggests greater barrel rigidity by way of intra-protein interactions. This, in turn, lowers the equilibrium barrel thermodynamic parameters in LDAOby perturbingthe stability of the protein-micelle complex. In addition to this, we also find a difference in the cooperativity of unfolding upon increasing the LDAO concentration, implying the importance of micelle concentration and micelle-protein ratios on the stability of this barrel. Our results indicate that the nine cysteine residues of hVDAC-2 are the key in establishing strong(er) barrel interactions with its environment and also impart additional malleability to the barrel scaffold.

Modulation of mitochondrial glutathione status and cellular energetics in primary cultures of proximal tubular cells from remnant kidney of uninephrectomized rats

Compensatory renal hypertrophy following reduction in renal mass leads to a hypermetabolic state and increases in basal mitochondrial oxidative stress and susceptibility to several nephrotoxicants. Previous studies provide conflicting data on whether renal mitochondria after reduction in renal mass undergo proliferation or hypertrophy or both. In the present study, our goal was to determine whether mitochondria of hypertrophied kidney undergo hypertrophy or proliferation after uninephrectomy using the uninephrectomized (NPX) rat model. Renal proximal tubular (PT) cells from NPX rats exhibited increased mitochondrial density, membrane potential and protein but no significant difference in mitochondrial DNA, as compared to PT cells from control rats. Our previous studies showed that overexpression of two mitochondrial anion transporters, the dicarboxylate (DIC, Slc25a10) and oxoglutarate (OGC, Slc25a11) carriers, in NRK-52E cells resulted in increased mitochondrial uptake of glutathione (GSH) and protection from chemically induced apoptosis. In the present study, we overexpressed DIC- and OGC-cDNA plasmids to assess their function in renal PT cells after compensatory renal hypertrophy. PT cells from NPX rats that were first preincubated with GSH were protected from cytotoxicity due to the mitochondrial inhibitor antimycin A by overexpression of either of the two mitochondrial GSH transporters. Our present results provide further evidence that compensatory renal hypertrophy is associated primarily with mitochondrial hypertrophy and hyperpolarization and that manipulation of mitochondrial GSH transporters in PT cells of hypertrophied kidney can alter susceptibility to chemically induced injury under appropriate conditions and may be a suitable therapeutic approach.

Evidence for Altered Communication Between the L-Type Ca2+ Channel and Mitochondria in a Model of Cardiomyopathy

Progression of cardiac hypertrophy to failure and development of many cardiomyopathies involves myocyte remodeling, disorganisation of cytoskeletal proteins and reduced energy metabolism. The mechanisms by which cytoskeletal disruption leads to mitochondrial dysfunction are poorly understood.Calcium influx through the L-type Ca2+ channel (LTCC) is a requirement for contraction in the heart. The LTCC can influence mitochondrial superoxide production, NADH production and metabolic activity in a calcium-dependent manner. Activation of the channel can also increase mitochondrial membrane potential (Ψm) in a calcium-independent manner. This response is dependent upon the cytoskeleton. We hypothesized that disruption of normal cytoskeletal architecture will result in altered communication between the LTCC and mitochondria. We investigated this hypothesis in the murine model of Duchenne Muscular Dystrophy(mdx). Myocytes from 8 week old mdx mice that exhibit disorganised cytoskeletal protein networks but not yet overt cardiomyopathy, demonstrated significantly slower LTCC inactivation rate (26.2±1.8ms, n=13 vs 21.1±1.3ms, n=16; p<0.05) and significantly greater calcium influx (681±40nM, n=7 vs 432±51nM, n=5). However activation of the LTCC did not increase Ψm (n=6) or metabolic activity (measured as formation of formazan from tetrazolium salt) in mdx myocytes (n=8). Application of 4,4′diisothiocyano-2,2′-stilbenedisulfonic acid, that blocks anion transport mimicked the response of BayK(-) in control myocytes (n=4) and “restored” the increase in Ψm in mdx myocytes (n=4).The activities of the mitochondrial respiratory complexes were normal in mitochondria isolated from 8 week old mdx hearts and from 40 week old mdx hearts that had developed cardiomyopathy. We conclude that the communication between the L-type Ca2+ channel and mitochondria is altered in the dystrophin-deficient cardiomyocyte. This appears to involve an alteration in the association between the channel protein, actin filaments and mitochondrial anion transport and precedes the development of cardiomyopathy.

Role of mitochondrial uncoupling protein 4 in rat inner ear

The uncoupling protein 4 (UCP4) belongs to the mitochondrial anion transporter family. Protein tissue distribution and functions are still a matter of debate. Using an antibody we have previously shown that UCP4 appears in neurons and to a lesser extent in astrocytes of murine neuronal tissue as early as days 12–14 of embryonic development ( Smorodchenko et al., 2009). Here we demonstrated for the first time that neurosensory cells such as hair cells of the inner ear and mechanosensitive Merkel cells in skin also express a significant amount of UCP4. We tested the hypothesis about whether UCP4 contributes to the regulation of oxidative stress using the model of oxygen deprivation. For this we compared the protein expression level in freshly isolated explants of organ of Corti, modiolus and stria vascularis from neonatal rats with explants cultured under hypoxia. Western blot analysis revealed that the UCP4 level was not increased under hypoxic conditions, when compared to the mitochondrial outer membrane protein VDAC or to the anti-oxidative enzyme SOD2. We moreover demonstrated that UCP4 expression is differently regulated during postnatal stages and is region-specific. We hypothesized that UCP4 may play an important role in functional maturation of the rat inner ear.

Transcriptional Upregulation of Mitochondrial Uncoupling Protein 2 Protects Against Oxidative Stress-Associated Neurogenic Hypertension

Mitochondrial uncoupling proteins (UCPs) belong to a superfamily of mitochondrial anion transporters that uncouple ATP synthesis from oxidative phosphorylation and mitigates mitochondrial reactive oxygen species production. We assessed the hypothesis that UCP2 participates in central cardiovascular regulation by maintaining reactive oxygen species homeostasis in the rostral ventrolateral medulla (RVLM), where sympathetic premotor neurons that maintain vasomotor tone located. We also elucidated the molecular mechanisms that underlie transcriptional upregulation of UCP2 in response to oxidative stress in RVLM. In Sprague-Dawley rats, transcriptional upregulation of UCP2 in RVLM by rosiglitazone, an activator of its transcription factor peroxisome proliferator-activated receptor (PPAR)gamma, reduced mitochondrial hydrogen peroxide level in RVLM and systemic arterial pressure. Oxidative stress induced by microinjection of angiotensin II into RVLM augmented UCP2 mRNA or protein expression in RVLM, which was antagonized by comicroinjection of NADPH oxidase inhibitor (diphenyleneiodonium chloride), superoxide dismutase mimetic (tempol), or p38 mitogen-activated protein kinase inhibitor (SB203580) but not by extracellular signal-regulated kinase 1/2 inhibitor (U0126). Angiotensin II also induced phosphorylation of the PPARgamma coactivator, PPARgamma coactivator (PGC)-1alpha, and an increase in formation of PGC-1alpha/PPARgamma complexes in a p38 mitogen-activated protein kinase-dependent manner. Intracerebroventricular infusion of angiotensin II promoted an increase in mitochondrial hydrogen peroxide production in RVLM and chronic pressor response, which was potentiated by gene knockdown of UCP2 but blunted by rosiglitazone. These results suggest that transcriptional upregulation of mitochondrial UCP2 in response to an elevation in superoxide plays an active role in feedback regulation of reactive oxygen species production in RVLM and neurogenic hypertension associated with chronic oxidative stress.

Mitochondrial glutathione uptake: characterization in isolated brain mitochondria and astrocytes in culture

Glutathione in the mitochondria is an important determinant of cellular responses to oxidative stress. Mitochondrial glutathione is maintained by uptake from the cytosol, a process that has been little studied in brain cells. In the present study, measurements using isolated rat brain mitochondria showed a rapid uptake of [3H]-glutathione that was strongly influenced by the mitochondrial glutathione content. [3H]-glutathione incorporated into the mitochondria was not rapidly released. Uptake was inhibited by substrates and inhibitors for several known mitochondrial anion transporters. Citrate, isocitrate and benzene-1,2,3-tricarboxylate were particularly effective inhibitors, suggesting a possible role for a tricarboxylate carrier in the glutathione transport. The properties of uptake differed greatly from those reported previously for mitochondria from kidney and liver. In astrocytes in primary culture, diethylmaleate or hydrogen peroxide treatment resulted in depletion of cytosolic and mitochondrial glutathione. The pattern of restoration of glutathione content in the presence of glutathione precursors following treatment with diethylmaleate was consistent with uptake into mitochondria being controlled primarily by the glutathione gradient between the cytosol and mitochondria. However, following hydrogen peroxide treatment, recovery of glutathione in the mitochondria initially preceded comparable proportional restoration in the cytosol, suggesting the possibility of additional controls on glutathione uptake in some conditions.

Polyunsaturated fatty acids activate human uncoupling proteins 1 and 2 in planar lipid bilayers

Uncoupling proteins 1 (UCP1) and 2 (UCP2) belong to the family of mitochondrial anion transporters and share 59% sequence identity with each other. Whereas UCP1 was shown to be responsible for the rapid production of heat in brown adipose tissue, the primary function and transport properties of ubiquitously expressed UCP2 are controversially discussed. Here, for the first time, the activation pattern of the recombinant human UCP2 in comparison to the recombinant human UCP1 are studied using a well-defined system of planar lipid bilayers. It is shown that despite apparently different physiological functions, hUCP2 exhibited its protonophoric function similar to hUCP1--exclusively in the presence of long-chain fatty acids (FA). The calculated hUCP2 transport rate of 4.5 s(-1) is the same order of magnitude, as shown previously for UCP1. It leads to the conclusion that the differences in the activity of both proteins in living mitochondria are based exclusively on their different expression level. Both proteins are activated much more effectively by polyunsaturated than by saturated FA. The proton and total membrane conductances increased in the range palmitic < oleic < eicosatrienoic < linoleic < retinoic < arachidonic acids. The higher uncoupling protein (UCP)-dependent conductance in the presence of polyunsaturated FA is explained on the basis of the FA cycling hypothesis.

Conjugated linoleic acid and hepatic lipogenesis in mouse: role of the mitochondrial citrate carrier

Conjugated linoleic acid (CLA) is able to reduce adiposity by affecting lipid metabolism. In particular, CLA administration to mice reduces body fat mass with a concomitant lipid accumulation in the liver. We investigated the effects of CLA on the activity of the mitochondrial citrate carrier (CIC), which is implicated in hepatic lipogenesis. The transport activity of the CIC, measured both in intact mitochondria and in the proteoliposomes, progressively increased with the duration of CLA feeding. An increase in the CIC activity of approximately 1.7-fold was found in 16 week CLA-treated mice with respect to control animals. A kinetic analysis showed a 1.6-fold increase in the V(max) of citrate transport but no change in the K(m) value. Western blot experiments revealed an increase of approximately 1.7-fold in the expression of CIC after CLA treatment. A strict correlation between the increase in CIC activity and the stimulation of the cytosolic lipogenic enzymes was also found. These data indicate that the CIC may play a role in the onset of hepatic steatosis in CLA-fed mice by supplying the carbon source for de novo fatty acid synthesis.

Happily at Work

Happily at Work

Structure and function of mitochondrial anion transport proteins.

Structure and function of mitochondrial anion transport proteins.

Models of the Transmembrane Domains of the Yeast Mitochondrial CitrateTransport Protein

We have used cysteine scanning, hydropathy analysis and molecular modeling to construct four possible models of the transmembrane helical domains of the yeast mitochondrial citrate transport protein. Models 1 and 2 invoke the formation of a translocation pathway by the six membrane-spanning alpha-helical domains that comprise each citrate transport protein monomer. Thus the homodimeric CTP (the functional form of the CTP) would contain two separate translocation pathways. Models 3 and 4 explore a novel way in which dimerization might take place, in which transmembrane domain 3 would form part of the dimer interface. This would lead to the formation of two seven-helix translocation pathways within the transporter dimer. Importantly, these studies have led to the construction of the first detailed structural models for any of the mitochondrial anion transport proteins, a family of proteins which is essential to cellular bioenergetics. Furthermore, these models suggest numerous experiments which can be carried out to further elucidate the structure of the translocation pathway through the membrane.

Mitochondrial uncoupling: role of uncoupling protein anion carriers and relationship to thermogenesis and weight control "the benefits of losing control".

Uncoupling proteins, a subgroup of the mitochondrial anion transporter superfamily, have been identified in prokaryotes, plants, and mammalian cells. Evolutionary conservation of these molecules reflects their importance as regulators of two critical mitochondrial functions, i.e., ATP synthesis and the production of reactive oxygen species (ROS). Although the amino acid sequences of the three mammalian uncoupling proteins, UCP1, UCP2 and UCP3, are very similar, each homolog is the product of a unique gene and important differences have been demonstrated in their tissue-specific expression and regulation. UCP1 and UCP3 appear to be key regulators of energy expenditure, and hence, nonshivering thermogenesis, either in brown adipose tissue (UCP1) or skeletal muscle (UCP3). UCP2 is expressed more ubiquitously, although generally at low levels, in many tissues. There is conflicting evidence about its importance as a regulator of resting metabolic rate. However, evidence suggests that this homolog might modulate the mitochondrial generation of ROS in some cell types, including macrophages and hepatocytes. While the induction of various uncoupling protein homologs provides adaptive advantages, both to the organism (e.g., thermogenesis) and to individual cells (e.g., reduced ROS), increased uncoupling protein activity also increases cellular vulnerability to necrosis by compromising the mitochondrial membrane potential. This narrow "risk-benefit" margin necessitates tight control of uncoupling protein activity in order to preserve cellular viability and much remains to be learned about the regulatory mechanisms involved.

Inhibition by Butylmalonate of Proton Influx in Nonphosphorylating Mitochondria

The impermeability of the inner membrane to protons is one of the four postulates of the chemiosmotic theory on the coupling mechanism between respiration and phosphorylation in mitochondria. However, oxygen uptake in isolated nonphosphorylating mitochondria requires that protons translocated from inside to outside must be, at least in part, retaken up. The nonohmic relationship between the respiration rate and the protonmotive force has been mainly ascribed to an increase in the proton conductance of the inner membrane (proton leak). In liver mitochondria oxygen pulse experiments the rate of both the efflux and the reentry of protons, linked to the oxygen consumption supported by succinate oxidation, is greatly stimulated by low concentrations of butylmalonate. The steady-state level of protons exported outside in the acidification–alkalinization cycle of the medium, generated by an oxygen pulse, is also increased but the rate of oxygen uptake is unaffected. However, in valinomycin-stimulated respiration butylmalonate inhibits the ratio of proton influx/oxygen consumption by 50% and also stimulates the ratio of proton efflux/oxygen consumption by 50%. Titration of the butylmalonate effect gives a saturation curve with a half-maximal effect at 5 μM. Identical results are obtained inthe presence of oligomycin which excludes the involvement of the ATP-synthase complex. The data obtained are not in contrast with the existence in the inner membrane of a channel-like system inhibited by butylmalonate and involved, together with other systems, in promoting the backflow of protons in nonphosphorylating state 4 respiration. Such a system, similar to thermogenin, could be involved in tissues, other than adipose, in a more general thermogenesis program by promoting the dissipation as heat of the energy given by the electrochemical proton gradient. The possibility that butylmalonate might inhibit the proton movement associated with cation and anion transport in mitochondria has also been considered.

Identification of a Novel Gene Encoding the Yeast Mitochondrial Dicarboxylate Transport Protein via Overexpression, Purification, and Characterization of Its Protein Product

A gene encoding the mitochondrial dicarboxylate transport protein (DTP) has been identified for the first time from any organism. Our strategy involved overexpression of putative mitochondrial transporter genes, selected based on analysis of the yeast genome, followed by purification and functional reconstitution of the resulting protein products. The DTP gene from the yeast Saccharomyces cerevisiae encodes a 298-residue basic protein which, in common with other mitochondrial anion transporters of known sequence and function, displays the mitochondrial transporter signature motif, three homologous 100-amino acid sequence domains, and six predicted membrane-spanning regions. The product of this gene has been abundantly expressed in Escherichia coli where it accumulates in inclusion bodies. Upon solubilization of the overexpressed DTP from isolated inclusion bodies with Sarkosyl, 28 mg of DTP was obtained per liter of E. coli culture at a purity of 75%. The purified, overexpressed DTP was then reconstituted in phospholipid vesicles where both its kinetic properties (i.e. Km = 1. 55 mM and Vmax = 3.0 micro;mol/min/mg protein) and its substrate specificity were determined. The intraliposomal substrates malonate, malate, succinate, and phosphate effectively supported [14C]malonate uptake, whereas other anions tested did not. External substrate competition studies revealed a similar specificity profile. Inhibitor studies indicated that the reconstituted transporter was sensitive to inhibition by n-butylmalonate, p-chloromercuribenzoate, mersalyl, and to a lesser extent pyridoxal 5'-phosphate but was insensitive to N-ethylmaleimide and selective inhibitors of other mitochondrial anion transporters. In combination, the above findings indicate that the identified gene encodes a mitochondrial transport protein which upon overexpression and reconstitution displays functional properties that are virtually identical to those of the native mitochondrial dicarboxylate transport system. In conclusion, the present investigation has resulted in identification of a gene encoding the mitochondrial DTP and thus eliminates a major impediment to molecular studies with this metabolically important transporter. Based on both structural and functional considerations, the yeast DTP is assignable to the mitochondrial carrier family. Additionally, the development of a procedure that enables the expression and isolation of large quantities of functional DTP provides the foundation for comprehensive investigations into the structure/function relationships within this transporter via site-directed mutagenesis, as well as for the initiation of crystallization trials.

Structure, function and regulation of the tricarboxylate transport protein from rat liver mitochondria

Recent progress is summarized on the structure, function, and regulation of the tricarboxylate (i.e., citrate) transport protein (CTP) from the rat liver mitochondrial inner membrane. The transporter has been purified and its reconstituted function characterized. A cDNA clone encoding the CTP has been isolated and sequenced, thus enabling a deduction of the complete amino acid sequence of this 32.6 kDa transport protein. Dot matrix analysis and sequence alignment indicate that based on structural considerations the CTP can be assigned to the mitochondrial carrier family. Hydropathy analysis of the transporter sequence indicates six putative membrane-spanning alpha-helices and has permitted the development of an initial model for the topography of the CTP within the inner membrane. The questions as to whether more than one gene encodes the CTP and whether more than one isoform is expressed remain unanswered at this time. Studies documenting a diabetes-induced alteration in the function of several mitochondrial anion transporters, which can be reversed by treatment with insulin, provide a physiologically/pathologically relevant experimental system for studying the molecular mechanism(s) by which mitochondrial transporters are regulated. Potential future research directions are discussed.