Bidirectional substrate fluxes through the system N (SNAT5) glutamine transporter may determine net glutamine flux in rat liver.

System N (SNAT3 and SNAT5) amino acid transporters are key mediators of glutamine transport across the plasma membrane of mammalian cell types, including hepatocytes and astrocytes. We demonstrate that SNAT5 shows simultaneous bidirectional glutamine fluxes when overexpressed in Xenopus oocytes. Influx and efflux are both apparently Na+ dependent but, since they are not directly coupled, the carrier is capable of mediating net amino acid movement across the cell membrane. The apparent Km values for glutamine influx and efflux are similar (approximately 1 mm) and the transporter behaviour is consistent with a kinetic model in which re-orientation of the carrier from outside- to inside-facing conformations (either empty or substrate loaded) is the limiting step in the transport cycle. In perfused rat liver, the observed relationship between influent (portal) glutamine concentration and net hepatic glutamine flux may be described by a simple kinetic model, assuming the balance between influx and efflux through System N determines net flux, where under physiological conditions efflux is generally saturated owing to high intracellular glutamine concentration. SNAT5 shows a more periportal mRNA distribution than SNAT3 in rat liver, indicating that SNAT5 may have particular importance for modulation of net hepatic glutamine flux.

A role for thyroid hormone transporters in transcriptional regulation by thyroid hormone receptors.

Thyroid hormones (THs) must be taken up by target cells to act at the genomic level through binding to nuclear thyroid hormone receptors (TRs). Extensive study has been made of mechanisms by which TH-bound TRs regulate transcription, yet little is known about the critical upstream step, i.e. how THs enter the cell. Growing evidence suggests that saturable transport mechanisms mediate the greater part of TH movement across the plasma membrane and have important roles in the regulation of TH bioavailability. For example, System L is a multifunctional transport system serving as a plasma membrane transporter of THs and amino acids in mammalian cells. We have used two complementary systems, the Xenopus oocyte (which has negligible basal System L activity) and the mammalian BeWo cell line (which has System L activity for TH transport), to investigate the role of this representative TH transporter in nuclear action of THs. We demonstrate that overexpression of System L in Xenopus oocytes increases both cytoplasmic and nuclear delivery of THs from external medium and also enhances transcriptional activation by TRs. Conversely, blocking endogenous System L activity in BeWo cells with specific inhibitors reduces both TH uptake and TR function. These results indicate that plasma membrane TH transporters such as System L may have important roles in gene regulation by TRs.

Mechanisms of glutamine transport in rat adipocytes and acute regulation by cell swelling.

Adipose tissue is a major site for whole-body glutamine synthesis and we are investigating mechanisms and regulation of glutamine transport across the adipocyte membrane. Glutamine transport in adipocytes includes both high- and low-affinity Na+-dependent components (consistent with observed expression of ASCT2 and ATA2/SAT2 transporter mRNAs respectively) and a Na+-independent transport component (consistent with observed expression of LAT1/2 transporter mRNAs). Hypo-osmotic (235 mosmol/kg) swelling of adipocytes transiently stimulated glutamine uptake (180% increase at 0.05 mM glutamine) within 5 mins. Stimulation was blocked by the tyrosine kinase inhibitor genistein and the MAP kinase pathway inhibitors PD98059 and SB203580, but not by wortmannin (PI 3-kinase inhibitor) or rapamycin (mTOR pathway inhibitor). Cell-swelling also stimulated uptake of glucose but not MeAIB (indicating that ASCT2 rather than ATA2 was stimulated by swelling). Insulin (66 nM) treatment for up to 1 h stimulated Na+-dependent glutamine transport and increased adipocyte water space. Activation of the ERK1-2 MAP kinase pathway by cell swelling or insulin may be important for rapid activation of the ASCT2 glutamine transporter in adipocytes. Insulin may also exert a minor additional stimulatory effect on adipocyte glutamine transport indirectly via cell swelling. The mechanisms regulating glutamine transport in adipose tissue are distinct from those in other major sites of glutamine turnover in the body (notably liver and skeletal muscle).