Measurements of Na+-occluded intermediates during the catalytic cycle of the Na+/K+-ATPase provide novel insights into the mechanism of Na+ transport

Na+-K+-ATPase/GLT-1 interaction participates in EGCG protection against cerebral ischemia-reperfusion injury in rats

BACKGROUND

In China, stroke is the primary cause of adult death and disability. Because of the increased rate of blood vessel reperfusion, it is important to prevent cerebral ischemia-reperfusion injury, in which glutamate (Glu) excitotoxicity plays a critical role. The most important Glu transporter, GLT-1, is essential for the regulation of Glu, which is dependent on Na+-K+-ATPase (NKA)-induced ion concentration gradient differences. EGCG, a substance found in tea polyphenols, can reduce infarct areas in ischemia-reperfusion models, reduce stroke incidence, and prolong life in which NKA is involved.

PURPOSE

In this study, we investigated the potential of EGCG in protecting against cerebral ischemia-reperfusion injury by regulating the interaction between NKA and GLT-1.

STUDY DESIGN

This study was designed to investigate the protective effects of EGCG against cerebral ischemia-reperfusion injury by modulating the interaction between NKA and GLT-1, utilizing both the rat middle cerebral artery occlusion/reperfusion (MCAO/R) model and the oxygen-glucose deprivation/reoxygenation (OGD/R) model in co-cultures of rat hippocampal neurons and astrocytes.

METHODS

The neuronal survival rate was assessed using CCK8, and the cerebral infarction area and neurological function were determined by TTC staining and neurological deficit scores. NKA activity was measured using an inorganic phosphorous detection method, and NKA and GLT-1 expression was detected using western blotting. The interaction between NKAα2 and GLT-1 was identified by co-immunoprecipitation (CoIP) assay, laser confocal microscopy, and Imaris 3D confocal rendering technology. An adenovirus vector with overexpression of NKAα2 was constructed, packaged, and injected into the rat lateral ventricle. Neurological function and the cerebral infarction area were identified, and the interaction between NKAα2 and GLT-1 was identified using CoIP assay.

RESULTS

EGCG reduced the infarction area and neurological deficit scores, restored NKA activity, alleviated the decrease in membrane NKAα2 and GLT-1 expression, and relieved the uncoupling of NKAα2 and GLT-1 in the hippocampal CA1 after rat MCAO/R injury. By promoting the coupling of NKAα2 and GLT-1 in rat MCAO/R models, overexpression of NKAα2 reduced the cerebral infarction area and neurological impairment scores.

CONCLUSION

EGCG improved cerebral ischemia-reperfusion injury by restoring NKA activity and increasing membrane GLT-1 expression due to NKA-GLT-1 interaction. For the first time, our findings demonstrate the critical role that NKA and GLT-1 colocalization plays in cerebral ischemia-reperfusion damage. Our findings provide new strategic directions for the pathogenesis and prevention of thrombolytic injury in the clinical treatment of stroke, while also serving as a basis for further development and utilization of EGCG.

Molecular Basis of Na, K-ATPase Regulation of Diseases: Hormone and FXYD2 Interactions

The Na, K-ATPase generates an asymmetric ion gradient that supports multiple cellular functions, including the control of cellular volume, neuronal excitability, secondary ionic transport, and the movement of molecules like amino acids and glucose. The intracellular and extracellular levels of Na+ and K+ ions are the classical local regulators of the enzyme's activity. Additionally, the regulation of Na, K-ATPase is a complex process that occurs at multiple levels, encompassing its total cellular content, subcellular distribution, and intrinsic activity. In this context, the enzyme serves as a regulatory target for hormones, either through direct actions or via signaling cascades triggered by hormone receptors. Notably, FXYDs small transmembrane proteins regulators of Na, K-ATPase serve as intermediaries linking hormonal signaling to enzymatic regulation at various levels. Specifically, members of the FXYD family, particularly FXYD1 and FXYD2, are that undergo phosphorylation by kinases activated through hormone receptor signaling, which subsequently influences their modulation of Na, K-ATPase activity. This review describes the effects of FXYD2, cardiotonic steroid signaling, and hormones such as angiotensin II, dopamine, insulin, and catecholamines on the regulation of Na, K-ATPase. Furthermore, this review highlights the implications of Na, K-ATPase in diseases such as hypertension, renal hypomagnesemia, and cancer.

The Na+,K+-ATPase and its stoichiometric ratio: some thermodynamic speculations

 Almost seventy years after its discovery, the sodium-potassium adenosine triphosphatase (the sodium pump) located in the cell plasma membrane remains a source of novel mechanistic and physiologic findings. A noteworthy feature of this enzyme/transporter is its robust stoichiometric ratio under physiological conditions: it sequentially counter-transports three sodium ions and two potassium ions against their electrochemical potential gradients per each hydrolyzed ATP molecule. Here we summarize some present knowledge about the sodium pump and its physiological roles, and speculate whether energetic constraints may have played a role in the evolutionary selection of its characteristic stoichiometric ratio.