Cell‐specific expression of the glutamine transporter SN1 suggests differences in dependence on the glutamine cycle

Boulland, Jean-Luc; Osen, Kirsten K.; Levy, Line M.; Danbolt, Niels Christian; Edwards, Robert H.; Storm‐Mathisen, Jon; Chaudhry, Farrukh A.

doi:10.1046/j.1460-9568.2002.01995.x

Cited by 130 publications

(149 citation statements)

References 85 publications

(121 reference statements)

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“…SNAT3 is highly expressed in brain astrocytes, and is believed to play a role in the glutamate-glutamine cycle involved in neurotransmission [5,15,22]. The lethargy and an altered, uncoordinated gait observed in mutant mice suggested impaired neurotransmission after Snat3 deletion in brain.…”

Section: The Glutamate-glutamine Cycle Is Defective In the Brain Of Smentioning

confidence: 99%

“…have been hypothesized to be responsible for the efflux of glutamine from astrocytes which is a crucial step in the recycling of glutamate and GABA neurotransmitters between astrocytes and neurons [5,22]. In the liver, SNAT3 is likely to be a candidate for both periportal uptake and perivenous efflux of glutamine, which is essential for the detoxification of ammonia delivered via the portal blood and excreted as urea [6,21].…”

Section: Introductionmentioning

confidence: 99%

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Loss of function mutation of the Slc38a3 glutamine transporter reveals its critical role for amino acid metabolism in the liver, brain, and kidney

Chan

Busque

Sailer

et al. 2015

Pflugers Arch - Eur J Physiol

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Glutamine, the most abundant amino acid in mammals, is critical for cell and organ functions. Its metabolism depends on the ability of cells to take up or release glutamine by transporters located in the plasma membrane. Several solute carrier (SLC) families transport glutamine, but the SLC38 family has been thought to be mostly responsible for glutamine transport. We demonstrate that despite the large number of glutamine transporters, the loss of Snat3/Slc38a3 glutamine transporter has a major impact on the function of organs expressing it. Snat3 mutant mice were generated by N-ethyl-N-nitrosurea (ENU) mutagenesis and showed stunted growth, altered amino acid levels, hypoglycemia, and died around 20 days after birth. Hepatic concentrations of glutamine, glutamate, leucine, phenylalanine, and tryptophan were highly reduced paralleled by downregulation of the mTOR pathway possibly linking reduced amino acid availability to impaired growth and glucose homeostasis. Snat3-deficient mice had altered urea levels paralleled by dysregulation of the urea cycle, gluconeogenesis, and glutamine synthesis. Mice were ataxic with higher glutamine but reduced glutamate and gamma-aminobutyric acid (GABA) levels in brain consistent with a major role of Snat3 in the glutamine-glutamate cycle. Renal ammonium excretion was lower, and the expression of enzymes and amino acid transporters involved in ammoniagenesis were altered. Thus, SNAT3 is a glutamine transporter required for amino acid homeostasis and determines critical functions in various organs. Despite the large number of glutamine transporters, loss of Snat3 cannot be compensated, suggesting that this transporter is a major route of glutamine transport in the liver, brain, and kidney. ABSTRACTGlutamine, the most abundant amino acid in mammals, is critical for cell and organ functions. Its metabolism depends on the ability of cells to take up or release glutamine by transporters located in the plasma membrane. Several solute carrier (SLC) families transport glutamine, but the SLC38 family has been thought to be mostly responsible for glutamine transport. We demonstrate that despite the large number of glutamine transporters, loss of the Snat3/Slc38a3 glutamine transporter has a major impact on the function of organs expressing it. Snat3 mutant mice were generated by N-ethyl-N-nitrosurea (ENU) mutagenesis and showed stunted growth, altered amino acid levels, hypoglycemia, and died around 20 days after birth. Hepatic concentrations of glutamine, glutamate, leucine, phenylalanine, and tryptophan were highly reduced paralleled by downregulation of the mTOR pathway possibly linking reduced amino acid availability to impaired growth and glucose homeostasis. Snat3 deficient mice had altered urea levels paralleled by dysregulation of the urea cycle, gluconeogenesis, and glutamine synthesis. Mice were ataxic with higher glutamine but reduced glutamate and GABA levels in brain consistent with a major role of Snat3 in the glutamine-glutamate cycle. Renal ammonium excretion ...

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Section: The Glutamate-glutamine Cycle Is Defective In the Brain Of Smentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Loss of function mutation of the Slc38a3 glutamine transporter reveals its critical role for amino acid metabolism in the liver, brain, and kidney

Chan

Busque

Sailer

et al. 2015

Pflugers Arch - Eur J Physiol

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“…The molecular bases of Gln passage across the astrocytic membrane and neuronal plasma membranes have been investigated extensively over the last few years [12,20,44]. Gln efflux from astrocytes appears to be mediated by sodium-coupled neutral amino acid transporter 3 (SNAT3, SN1), a system N amino acid transporter that is localized to perisynaptic astrocytes and specifically accepts only glutamine, histidine and asparagine [13,19,21]. Gln uptake into neurons is mediated by sodium-dependent transporters of the system A family, two of which, SNAT1 (GlnT, SAT1, ATA1, SA2) and SNAT2 (SAT2, ATA2), are thought to be capable of affecting Glu and/or GABA recycling, and, thereby, synaptic function.…”

Section: Introductionmentioning

confidence: 99%

Methylmercury induces oxidative injury, alterations in permeability and glutamine transport in cultured astrocytes

Yin¹,

Milatović²,

Aschner³

et al. 2007

Brain Research

161

100

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The neurotoxicity of high levels of methylmercury (MeHg) is well established both in humans and experimental animals. Astrocytes accumulate MeHg and play a prominent role in mediating MeHg toxicity in the central nervous system (CNS). Although the precise mechanisms of MeHg neurotoxicity are ill-defined, oxidative stress and altered mitochondrial and cell membrane permeability appear to be critical factors in its pathogenesis. The present study examined the effects of MeHg treatment on oxidative injury, mitochondrial inner membrane potential, glutamine uptake and expression of glutamine transporters in primary astrocyte cultures. MeHg caused a significant increase in F 2 -isoprostanes (F 2 -IsoPs), lipid peroxidation biomarkers of oxidative damage, in astrocyte cultures treated with 5 or 10 μ M MeHg for 1 or 6 hours. Consistent with this observation, MeHg induced a concentration-dependant reduction in the inner mitochondrial membrane potential (ΔΨm), as assessed by the potentiometric dye, tetramethylrhodamine ethyl ester (TMRE). Our results demonstrate that ΔΨ m is a very sensitive endpoint for MeHg toxicity, since significant reductions were observed after only 1 h exposure to concentrations of MeHg as low as 1 μ M. MeHg pretreatment (1, 5 and 10 μ M) for 30 min also inhibited the net uptake of glutamine ( 3 H-glutamine) measured at 1 min and 5 min. Expression of the mRNA coding the glutamine transporters, SNAT3/SN1 and ASCT2, was inhibited only at the highest (10 μ M) MeHg concentration, suggesting that the reduction in glutamine uptake observed after 30 min treatment with lower concentrations of MeHg (1 and 5 μ M) was not due to inhibition of transcription. Taken together, these studies demonstrate that MeHg exposure is associated with increased mitochondrial membrane permeability, alterations in glutamine/glutamate cycling, increased ROS formation and consequent oxidative injury. Ultimately, MeHg initiates multiple additive or synergistic disruptive mechanisms that lead to cellular dysfunction and cell death.Please send request for reprints to Michael Aschner, Ph.D.,

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“…SN1 was the first isoform characterized and it has been described as the primary transporter responsible for the release of glutamine from astrocytes. It preferentially transports glutamine, promoting its efflux under physiological concentrations of this amino acid (~400 μM) (Boulland et al, 2002;Chaudhry et al, 1999). One important property of this amino acid transporter is its capacity of flux reversal, which is dependent on pH and also on the extracellular Na + concentration, i.e.…”

Section: Introductionmentioning

confidence: 99%

“…The importance of this transporter in relation to the glutamate/GABA-glutamine cycle is highlighted by the observation that exogenous glutamate mediates a decrease in the Km for SN1 in astrocyte cultures (Bröer et al, 2004). Similarly, the SN2 isoform is also functionally related to glutamine efflux from astrocytes, although it also releases glycine serving as a co-transmitter at NMDA receptors Hamdani et al, 2012).With respect to the CNS localization of these transporters, SN1 has been shown to be confined to astroglial processes ensheathing glutamatergic and GABAergic synapses in different brain structures (Boulland et al, 2002;Chaudhry et al, 1999), while SN2 has also been found in astrocytes predominantly close to glutamatergic synapses .…”

Section: Introductionmentioning

confidence: 99%

Expression of glutamine transporter isoforms in cerebral cortex of rats with chronic hepatic encephalopathy

Leke

Escobar

Rao

et al. 2015

Neurochemistry International

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Rama Rao, Kakulavarapu V.; Silveira, Themis Reverbel; Norenberg, Michael D.; and Schousboe, Arne, "Expression of glutamine transporter isoforms in cerebral cortex of rats with chronic hepatic encephalopathy" (2015 Keywords:Chronic hepatic encephalopathy Glutamine transporters Glutamine GABA A B S T R A C THepatic encephalopathy (HE) is a neuropsychiatric disorder that occurs due to acute and chronic liver diseases, the hallmark of which is the increased levels of ammonia and subsequent alterations in glutamine synthesis, i.e. conditions associated with the pathophysiology of HE. Under physiological conditions, glutamine is fundamental for replenishment of the neurotransmitter pools of glutamate and GABA. The different isoforms of glutamine transporters play an important role in the transfer of this amino acid between astrocytes and neurons. A disturbance in the GABA biosynthetic pathways has been described in bile duct ligated (BDL) rats, a well characterized model of chronic HE. Considering that glutamine is important for GABA biosynthesis, altered glutamine transport and the subsequent glutamate/GABA-glutamine cycle efficacy might influence these pathways. Given this potential outcome, the aim of the present study was to investigate whether the expression of the glutamine transporters SAT1, SAT2, SN1 and SN2 would be affected in chronic HE. We verified that mRNA expression of the neuronal glutamine transporters SAT1 and SAT2 was found unaltered in the cerebral cortex of BDL rats. Similarly, no changes were found in the mRNA level for the astrocytic transporter SN1, whereas the gene expression of SN2 was increased by two-fold in animals with chronic HE. However, SN2 protein immuno-reactivity did not correspond with the increase in gene transcription since it remained unaltered. These data indicate that the expression of the glutamine transporter isoforms is unchanged during chronic HE, and thus likely not to participate in the pathological mechanisms related to the imbalance in the GABAergic neurotransmitter system observed in this neurologic condition.

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Cell‐specific expression of the glutamine transporter SN1 suggests differences in dependence on the glutamine cycle

Cited by 130 publications

References 85 publications

Loss of function mutation of the Slc38a3 glutamine transporter reveals its critical role for amino acid metabolism in the liver, brain, and kidney

Loss of function mutation of the Slc38a3 glutamine transporter reveals its critical role for amino acid metabolism in the liver, brain, and kidney

Methylmercury induces oxidative injury, alterations in permeability and glutamine transport in cultured astrocytes

Expression of glutamine transporter isoforms in cerebral cortex of rats with chronic hepatic encephalopathy

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