Ryuko Anzawa scite author profile

ObjectiveSodium-glucose cotransporter 1 (SGLT1) is thought to be expressed in the heart as the dominant isoform of cardiac SGLT, although more information is required to delineate the subtypes of SGLTs in human hearts. Moreover, the functional role of SGLTs in the heart remains to be fully elucidated. We herein investigated whether SGLT1 is expressed in human hearts and whether SGLTs significantly contribute to cardiac energy metabolism during ischemia-reperfusion injury (IRI) via enhanced glucose utilization in mice.Methods and ResultsWe determined that SGLT1 was highly expressed in both human autopsied hearts and murine perfused hearts, as assessed by immunostaining and immunoblotting with membrane fractionation. To test the functional significance of the substantial expression of SGLTs in the heart, we studied the effects of a non-selective SGLT inhibitor, phlorizin, on the baseline cardiac function and its response to ischemia-reperfusion using the murine Langendorff model. Although phlorizin perfusion did not affect baseline cardiac function, its administration during IRI significantly impaired the recovery in left ventricular contractions and rate pressure product, associated with an increased infarct size, as demonstrated by triphenyltetrazolium chloride staining and creatine phosphokinase activity released into the perfusate. The onset of ischemic contracture, which indicates the initiation of ATP depletion in myocardium, was earlier with phlorizin. Consistent with this finding, there was a significant decrease in the tissue ATP content associated with reductions in glucose uptake, as well as lactate output (indicating glycolytic flux), during ischemia-reperfusion in the phlorizin-perfused hearts.ConclusionsCardiac SGLTs, possibly SGLT1 in particular, appear to provide an important protective mechanism against IRI by replenishing ATP stores in ischemic cardiac tissues via enhancing availability of glucose. The present findings provide new insight into the significant role of SGLTs in optimizing cardiac energy metabolism, at least during the acute phase of IRI.

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Intracellular sodium increase and susceptibility to ischaemia in hearts from type 2 diabetic db/db mice

Anzawa

Bernard

Tamareille

et al. 2006

Diabetologia

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Aims/hypothesis: An important determinant of sensitivity to ischaemia is altered ion homeostasis, especially disturbances in intracellular Na + Na þ i À Á handling. As no study has so far investigated this in type 2 diabetes, we examined susceptibility to ischaemia-reperfusion in isolated hearts from diabetic db/db and control db/+ mice and determined whether and to what extent the amount of Naincrease during a transient period of ischaemia could contribute to functional alterations upon reperfusion. Methods: Isovolumic hearts were exposed to 30-min global ischaemia and then reperfused. 23Na nuclear magnetic resonance (NMR) spectroscopy was used to monitor Na þ i and 31 P NMR spectroscopy to monitor intracellular pH (pH i ). Results: A higher duration of ventricular tachycardia and the degeneration of ventricular tachycardia into ventricular fibrillation were observed upon reperfusion in db/db hearts. The recovery of left ventricular developed pressure was reduced. The increase in Na þ i induced by ischaemia was higher in db/db hearts than in control hearts, and the rate of pH i recovery was increased during reperfusion. The inhibition of Na + /H + exchange by cariporide significantly reduced Na þ i gain at the end of ischaemia. This was associated with a lower incidence of ventricular tachycardia in both heart groups, and with an inhibition of the degeneration of ventricular tachycardia into ventricular fibrillation in db/db hearts. Conclusions/ interpretation: These findings strongly support the hypothesis that increased Na þ i plays a causative role in the enhanced sensitivity to ischaemia observed in db/db diabetic hearts.

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Ryuko Anzawa

Expression of SGLT1 in Human Hearts and Impairment of Cardiac Glucose Uptake by Phlorizin during Ischemia-Reperfusion Injury in Mice

Intracellular sodium increase and susceptibility to ischaemia in hearts from type 2 diabetic db/db mice

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