Consequences of NaCT/SLC13A5/mINDY deficiency: good versus evil, separated only by the blood-brain barrier.

NaCT/SLC13A5 is a Na+-coupled transporter for citrate in hepatocytes, neurons, and testes. It is also called mINDY (mammalian ortholog of 'I'm Not Dead Yet' in Drosophila). Deletion of Slc13a5 in mice leads to an advantageous phenotype, protecting against diet-induced obesity, and diabetes. In contrast, loss-of-function mutations in SLC13A5 in humans cause a severe disease, EIEE25/DEE25 (early infantile epileptic encephalopathy-25/developmental epileptic encephalopathy-25). The difference between mice and humans in the consequences of the transporter deficiency is intriguing but probably explainable by the species-specific differences in the functional features of the transporter. Mouse Slc13a5 is a low-capacity transporter, whereas human SLC13A5 is a high-capacity transporter, thus leading to quantitative differences in citrate entry into cells via the transporter. These findings raise doubts as to the utility of mouse models to evaluate NaCT biology in humans. NaCT-mediated citrate entry in the liver impacts fatty acid and cholesterol synthesis, fatty acid oxidation, glycolysis, and gluconeogenesis; in neurons, this process is essential for the synthesis of the neurotransmitters glutamate, GABA, and acetylcholine. Thus, SLC13A5 deficiency protects against obesity and diabetes based on what the transporter does in hepatocytes, but leads to severe brain deficits based on what the transporter does in neurons. These beneficial versus detrimental effects of SLC13A5 deficiency are separable only by the blood-brain barrier. Can we harness the beneficial effects of SLC13A5 deficiency without the detrimental effects? In theory, this should be feasible with selective inhibitors of NaCT, which work only in the liver and do not get across the blood-brain barrier.

The 2-oxoglutarate carrier promotes liver cancer by sustaining mitochondrial GSH despite cholesterol loading.

Cancer cells exhibit mitochondrial cholesterol (mt-cholesterol) accumulation, which contributes to cell death resistance by antagonizing mitochondrial outer membrane (MOM) permeabilization. Hepatocellular mt-cholesterol loading, however, promotes steatohepatitis, an advanced stage of chronic liver disease that precedes hepatocellular carcinoma (HCC), by depleting mitochondrial GSH (mGSH) due to a cholesterol-mediated impairment in mGSH transport. Whether and how HCC cells overcome the restriction of mGSH transport imposed by mt-cholesterol loading to support mGSH uptake remains unknown. Although the transport of mGSH is not fully understood, SLC25A10 (dicarboxylate carrier, DIC) and SLC25A11 (2-oxoglutarate carrier, OGC) have been involved in mGSH transport, and therefore we examined their expression and role in HCC. Unexpectedly, HCC cells and liver explants from patients with HCC exhibit divergent expression of these mitochondrial carriers, with selective OGC upregulation, which contributes to mGSH maintenance. OGC but not DIC downregulation by siRNA depleted mGSH levels and sensitized HCC cells to hypoxia-induced ROS generation and cell death as well as impaired cell growth in three-dimensional multicellular HCC spheroids, effects that were reversible upon mGSH replenishment by GSH ethyl ester, a membrane permeable GSH precursor. We also show that OGC regulates mitochondrial respiration and glycolysis. Moreover, OGC silencing promoted hypoxia-induced cardiolipin peroxidation, which reversed the inhibition of cholesterol on the permeabilization of MOM-like liposomes induced by Bax or Bak. Genetic OGC knockdown reduced the ability of tumor-initiating stem-like cells to induce liver cancer. These findings underscore the selective overexpression of OGC as an adaptive mechanism of HCC to provide adequate mGSH levels in the face of mt-cholesterol loading and suggest that OGC may be a novel therapeutic target for HCC treatment.

Integrative toxicoproteomics implicates impaired mitochondrial glutathione import as an off-target effect of troglitazone.

Troglitazone, a first-generation thiazolidinedione of antihyperglycaemic properties, was withdrawn from the market due to unacceptable idiosyncratic hepatotoxicity. Despite intensive research, the underlying mechanism of troglitazone-induced liver toxicity remains unknown. Here we report the use of the Sod2(+/-) mouse model of silent mitochondrial oxidative-stress-based and quantitative mass spectrometry-based proteomics to track the mitochondrial proteome changes induced by physiologically relevant troglitazone doses. By quantitative untargeted proteomics, we first globally profiled the Sod2(+/-) hepatic mitochondria proteome and found perturbations including GSH metabolism that enhanced the toxicity of the normally nontoxic troglitazone. Short- and long-term troglitazone administration in Sod2(+/-) mouse led to a mitochondrial proteome shift from an early compensatory response to an eventual phase of intolerable oxidative stress, due to decreased mitochondrial glutathione (mGSH) import protein, decreased dicarboxylate ion carrier (DIC), and the specific activation of ASK1-JNK and FOXO3a with prolonged troglitazone exposure. Furthermore, mapping of the detected proteins onto mouse specific protein-centered networks revealed lipid-associated proteins as contributors to overt mitochondrial and liver injury when under prolonged exposure to the lipid-normalizing troglitazone. By integrative toxicoproteomics, we demonstrated a powerful systems approach in identifying the collapse of specific fragile nodes and activation of crucial proteome reconfiguration regulators when targeted by an exogenous toxicant.

Nonsteroidal anti-inflammatory drugs and other anthranilic acids inhibit the Na(+)/dicarboxylate symporter from Staphylococcus aureus.

The Na(+)/dicarboxylate symporter from Staphylococcus aureus, named SdcS, is a member of the divalent anion sodium symporter (DASS) family that also includes the mammalian SLC13 Na(+)/dicarboxylate cotransporters, NaDC1 and NaCT. The mammalian members of the family are sensitive to inhibition by anthranilic acid derivatives such as N-(p-amylcinnamoyl)anthranilic acid (ACA), which act as slow inhibitors. This study shows that SdcS is inhibited by ACA as well as the fenamate nonsteroidal anti-inflammatory drugs, flufenamate and niflumate. The inhibition was rapid and reversible. The IC(50) for ACA was approximately 55 µM. Succinate kinetics by SdcS were sigmoidal, with a K(0.5) of 9 µM and a Hill coefficient of 1.5. Addition of ACA decreased the V(max) and increased the Hill coefficient without affecting the K(0.5), consistent with its activity as a negative modulator of SdcS activity. ACA inhibition was not correlated with the K(0.5) for succinate in SdcS mutants, and ACA did not affect the reactivity of the N108C mutant to the cysteine reagent, MTSET. We conclude that ACA and other anthranilic acid derivatives are effective allosteric inhibitors of SdcS. Furthermore, the mechanism of inhibition appears to be distinct from the mechanism observed in human NaDC1.

Differential expression of select members of the SLC family of genes and regulation of expression by microRNAs in the chicken oviduct.

The yolk and white of eggs from chickens contain proteins and other molecules either secreted or transported by cells of the reproductive tract, or secreted by the liver and transported to the ovarian follicles of laying hens. Nutrients transported by solute carriers (SLCs) include glucose, electrolytes, and amino acids. Although SLC genes have been investigated in mammals, there are few studies of expression of SLC genes in the chicken oviduct. Therefore, we investigated temporal and cell-specific expression of selected SLC genes at 3 h and 20 h postovulation and regulation of their expression by microRNAs (miRs). Expression of SLC1A4 (glutamate and neutral amino acid transporter), SLC13A2 (dicarboxylate transporter), and SLC35B4 (UDP-xylose: UDP-N-acetylglucosamine transporter) mRNAs was limited to glandular epithelium (GE), while SLC4A5 (sodium bicarbonate cotransporter) and SLC7A3 (cationic amino acid transporter) mRNAs were expressed predominantly in the luminal epithelium of the magnum. Interestingly, SLC1A4, SLC4A5, SLC13A2 and SLC35B4 mRNAs were abundant only in GE of the shell gland, whereas SLC7A3 was not detected in the shell gland. In the magnum, SLC7A3 and SLC4A5 were expressed, but SLC1A4, SLC35B4, and SLC13A2 were not expressed at 20 h postovulation. In the shell gland, all SLC mRNAs were expressed at both time points, except for SLC7A3. The miRNA target validation assay revealed that miR-1764 and miR-1700 bind directly to SLC13A2 and SLC35B4 transcripts, respectively, to regulate expression. Results of this study demonstrate cell-specific and temporal changes in expression of selected SLC genes and regulation of SLC13A2 and SLC35B4 expression by miRs in the oviduct of laying hens.

Methylmalonate inhibits succinate-supported oxygen consumption by interfering with mitochondrial succinate uptake.

The effect of methylmalonate (MMA) on mitochondrial succinate oxidation has received great attention since it could present an important role in energy metabolism impairment in methylmalonic acidaemia. In the present work, we show that while millimolar concentrations of MMA inhibit succinate-supported oxygen consumption by isolated rat brain or muscle mitochondria, there is no effect when either a pool of NADH-linked substrates or N,N,N',N'-tetramethyl-p-phenylendiamine (TMPD)/ascorbate were used as electron donors. Interestingly, the inhibitory effect of MMA, but not of malonate, on succinate-supported brain mitochondrial oxygen consumption was minimized when nonselective permeabilization of mitochondrial membranes was induced by alamethicin. In addition, only a slight inhibitory effect of MMA was observed on succinate-supported oxygen consumption by inside-out submitochondrial particles. In agreement with these observations, brain mitochondrial swelling experiments indicate that MMA is an important inhibitor of succinate transport by the dicarboxylate carrier. Under our experimental conditions, there was no evidence of malonate production in MMA-treated mitochondria. We conclude that MMA inhibits succinate-supported mitochondrial oxygen consumption by interfering with the uptake of this substrate. Although succinate generated outside the mitochondria is probably not a sig-nificant contributor to mitochondrial energy generation, the physiopathological implications of MMA-induced inhibition of substrate transport by the mitochondrial dicarboxylate carrier are discussed.

Inhibition of the Na+/dicarboxylate cotransporter by anthranilic acid derivatives.

The Na(+)/dicarboxylate cotransporter NaDC1 absorbs citric acid cycle intermediates from the lumen of the small intestine and kidney proximal tubule. No effective inhibitor has been identified yet, although previous studies showed that the nonsteroidal anti-inflammatory drug, flufenamate, inhibits the human (h) NaDC1 with an IC(50) value of 2 mM. In the present study, we have tested compounds related in structure to flufenamate, all anthranilic acid derivatives, as potential inhibitors of hNaDC1. We found that N-(p-amylcinnamoyl) anthranilic acid (ACA) and 2-(p-amylcinnamoyl) amino-4-chloro benzoic acid (ONO-RS-082) are the most potent inhibitors with IC(50) values lower than 15 microM, followed by N-(9-fluorenylmethoxycarbonyl)-anthranilic acid (Fmoc-anthranilic acid) with an IC(50) value of approximately 80 microM. The effects of ACA on NaDC1 are not mediated through a change in transporter protein abundance on the plasma membrane and seem to be independent of its effect on phospholipase A(2) activity. ACA acts as a slow inhibitor of NaDC1, with slow onset and slow reversibility. Both uptake activity and efflux are inhibited by ACA. Other Na(+)/dicarboxylate transporters from the SLC13 family, including hNaDC3 and rbNaDC1, were also inhibited by ACA, ONO-RS-082, and Fmoc-anthranilic acid, whereas the Na(+)/citrate transporter (hNaCT) is much less sensitive to these compounds. The endogenous sodium-dependent succinate transport in Caco-2 cells is also inhibited by ACA. In conclusion, ACA and ONO-RS-082 represent promising lead compounds for the development of specific inhibitors of the Na(+)/dicarboxylate cotransporters.

Mechanism of inhibition of the dicarboxylate carrier of mitochondria by thiol reagents.

The nature of the inhibition of the dicarboxylate carrier by compounds reacting with SH groups has been investigated. (1) Mersalyl and p-hydroxymercuribenzoate increase the Km without changing the V of malonate/Pi exchange, when they are added simultaneously with the dicarboxylate. If, on the other hand, the mitochondria are preincubated with SH reagents prior to the addition of malonate, the mersalyl inhibition of malonate/Pi exchange becomes predominantly non-competitive with respect to malonate. (2) In the case of Pi/Pi exchange, catalyzed by the dicarboxylate carrier, the mersalyl inhibition is competitive with respect to Pi (as indicated by Lineweaver-Burk plots), even when mersalyl is added before the substrate. Dixon plots of the rate of Pi uptake against mersalyl concentration are, however, non-linear, suggesting that the inhibition is partially competitive. (3) Dicarboxylates and dicarboxylate analogous protect against SH reagent inhibition of both dicarboxylate and Pi uptake via the dicarboxylate carrier. The protectors are effective when added before, or together with the SH reagents, but do not reverse the inhibition once it has been established. Protection by substrate analogues progressively decreases, as the time of incubation with the SH reagent increases. (4) The presence of Pi does not protect against the SH reagent inhibition of the Pi uptake. (5) The rate of SH reagent inhibition of the dicarboxylate carrier is competively inhibited by dicarboxylates. (6) It is concluded that SH reagents bind at or near the dicarboxylate specific binding site and distant from the Pi binding site. As a result of this reaction these inhibitors prevent dicarboxylate binding directly and decrease the affinity for Pi by an indirect conformational change.