Electrophysiological Characterization of Human and Mouse Sodium-Dependent Citrate Transporters (NaCT/SLC13A5) Reveal Species Differences with Respect to Substrate Sensitivity and Cation Dependence

Zwart, Ruud; Peeva, Polina M; Rong, James X.; Sher, Emanuele

doi:10.1124/jpet.115.226902

Cited by 10 publications

(14 citation statements)

References 33 publications

(36 reference statements)

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“…In the mouse liver, knockout of the slc13 transporter, NaCT, inhibits lipogenesis by lowering the cytoplasmic concentrations of the fatty acid biogenesis intermediatecitrate (11,21). However, functional human NaCT measurements in Xenopus occytes show significantly lower affinity to citrate compared to the reported mouse isoform, as we report here and previously reported by Zwart et al (22). When monitored in mammalian cells, human NaCT Km was ~600 µM (23).…”

Section: Discussionsupporting

confidence: 62%

A dynamic anchor domain in slc13 transporters controls metabolite transport

Khamaysi

Aharon

Eini-Rider

et al. 2020

Journal of Biological Chemistry

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Metabolite transport across cellular membranes is required for bioenergetic processes and metabolic signaling. The solute carrier family 13 (slc13) transporters mediate transport of the metabolites succinate and citrate and hence are of paramount physiological importance. Nevertheless, the mechanisms of slc13 transport and regulation are poorly understood. Here, a dynamic structural slc13 model suggested that an interfacial helix, H4c, which is common to all slc13s, stabilizes the stationary scaffold domain by anchoring it to the membrane, thereby facilitating movement of the SLC13 catalytic domain. Moreover, we found that intracellular determinants interact with the H4c anchor domain to modulate transport. This dual function is achieved by basic residues that alternately face either the membrane phospholipids or the intracellular milieu. This mechanism was supported by several experimental findings obtained using biochemical methods, electrophysiological measurements in Xenopus oocytes, and fluorescent microscopy of mammalian cells. First, a positively charged and highly conserved H4c residue, Arg108, was indispensable and crucial for metabolite transport. Furthermore, neutralization of other H4c basic residues inhibited slc13 transport function, thus mimicking the inhibitory effect of the slc13 inhibitor, slc26a6. Our findings suggest that the positive charge distribution across H4c domain controls slc13 transporter function and is utilized by slc13-interacting proteins in the regulation of metabolite transport.

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Section: Discussionsupporting

confidence: 62%

A dynamic anchor domain in slc13 transporters controls metabolite transport

Khamaysi

Aharon

Eini-Rider

et al. 2020

Journal of Biological Chemistry

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“…Finally, a recent publication raised questions about the translatability of mINDY as a target for the treatment of metabolic disease from the mouse to the human situation due to differences in uptake properties between species. (33) Therefore, we directly measured 14 C-citrate uptake into mouse, rat, and human primary hepatocytes incubated with low physiological concentrations of citrate. In this setting, citrate uptake was highest in human primary hepatocytes, followed by mouse and rats (Fig.…”

Section: Significance Of Human Mindy Compared To Mouse and Rat Mindymentioning

confidence: 99%

The human longevity gene homolog INDY and interleukin‐6 interact in hepatic lipid metabolism

et al. 2017

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Reduced expression of the Indy (‘I am Not Dead, Yet’) gene in lower organisms promotes longevity in a manner akin to caloric restriction. Deletion of the mammalian homolog of Indy (mIndy, Slc13a5) encoding for a plasma membrane associated citrate transporter expressed highly in the liver, protects mice from high-fat diet and aging-induced obesity and hepatic fat accumulation through a mechanism resembling caloric restriction. We aimed to study a possible role of mIndy in human hepatic fat metabolism. In obese, insulin resistant patients with NAFLD, hepatic mIndy expression was increased and mIndy expression was also independently associated with hepatic steatosis. In non-human primates, a two year high fat, high sucrose diet increased hepatic mIndy expression. Liver microarray analysis showed that high mIndy expression was associated with pathways involved in hepatic lipid metabolism and immunological processes. Interleukin-6 (IL-6) was identified as a regulator of mIndy by binding to its cognate receptor. Studies in human primary hepatocytes confirmed that IL-6 markedly induced mIndy transcription via the IL-6-receptor (IL-6R) and activation of the transcription factor Stat3 and a putative start site of the human mIndy promoter was determined. Activation of the IL-6-Stat3 pathway stimulated mIndy expression, enhanced cytoplasmic citrate influx and augmented hepatic lipogenesis in vivo. In contrast, deletion of mIndy completely prevented the stimulating effect of IL-6 on citrate uptake and reduced hepatic lipogenesis. These data show that mIndy is increased in liver of obese humans and non-human primates with NALFD. Moreover, our data identify mIndy as a target gene of IL-6 and determine novel functions of IL-6 via mINDY. Targeting human mINDY may have therapeutic potential in obese patients with NAFLD.

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“…1 Whether the effects of NaCT knockout in mice can be translated into humans is unclear, because of speciesspecific differences with respect to substrate-sensitivity 8,9 and cation-dependency. 10 Cross-species translation is fur-ther complicated by the fact that there are at least two other transporters that play a role in citrate homeostasis: low-affinity sodium-dependent dicarboxylate cotransporter (NaDC1) encoded by SLC13A2, and high-affinity sodiumdependent dicarboxylate cotransporter (NaDC3) encoded by SLC13A3. Although NaCT is located primarily in the liver of both humans and mice, its relative importance to hepatic citrate uptake appears to be different across these species.…”

Section: Study Highlightsmentioning

confidence: 99%

“…Based on the hepatic clearance and plasma concentration of citrate, the hepatic influx of plasma citrate was calculated maximally to be 17 g/day with a 95% CI of [9][10][11][12][13][14][15][16][17][18][19][20] (Eq. 5).…”

Section: Clearance and Turnover Of Plasma Citrate In Healthy Humansmentioning

confidence: 99%

Model‐Based Assessment of Plasma Citrate Flux Into the Liver: Implications for NaCT as a Therapeutic Target

Erion²,

Maurer

2016

CPT Pharmacom & Syst Pharma

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Cytoplasmic citrate serves as an important regulator of gluconeogenesis and carbon source for de novo lipogenesis in the liver. For this reason, the sodium‐coupled citrate transporter (NaCT), a plasma membrane transporter that governs hepatic influx of plasma citrate in human, is being explored as a potential therapeutic target for metabolic disorders. As cytoplasmic citrate also originates from intracellular mitochondria, the relative contribution of these two pathways represents critical information necessary to underwrite confidence in this target. In this work, hepatic influx of plasma citrate was quantified via pharmacokinetic modeling of published clinical data. The influx was then compared to independent literature estimates of intracellular citrate flux in human liver. The results indicate that, under normal conditions, <10% of hepatic citrate originates from plasma. Similar estimates were determined experimentally in mice and rats. This suggests that NaCT inhibition will have a limited impact on hepatic citrate concentrations across species.

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Electrophysiological Characterization of Human and Mouse Sodium-Dependent Citrate Transporters (NaCT/SLC13A5) Reveal Species Differences with Respect to Substrate Sensitivity and Cation Dependence

Cited by 10 publications

References 33 publications

A dynamic anchor domain in slc13 transporters controls metabolite transport

A dynamic anchor domain in slc13 transporters controls metabolite transport

The human longevity gene homolog INDY and interleukin‐6 interact in hepatic lipid metabolism

Model‐Based Assessment of Plasma Citrate Flux Into the Liver: Implications for NaCT as a Therapeutic Target

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