Eukaryotic cells control their intracellular pH using ion-transporting systems that are situated in the plasma membrane. This paper describes the different mechanisms that are involved and how their activity is regulated.The distribution of H + ions across the plasma membrane of most cells is such that the internal pH @Hi) is much higher than that predicted if H + were passively distributed [l]. For an average membrane potential of -60 mV and for an external pH of 7.4, a pHi value of 6.4 would be expected if H + were in electrochemical equilibrium across the membrane. Therefore, all cells have mechanisms for H + extrusion that maintain pHi at a value which is well above equilibrium and is compatible with the necessities of cytoplasmic reactions. Numerous studies performed during the last decade have demonstrated that changes in pHi occur during metabolic and developmental transitions in a large variety of cells. Acidic cytoplasmic conditions are usually associated with a quiescent or dormant cellular state while an increase in pHi often accompanies cellular activation [I, 21. These observations lead to a series of questions: (a) how is pHi regulated and how are pHi variations achieved? (b) How important is the steadystate pHi value for cell function?This paper reviews the most recent literature and focusses on two important aspects of internal pH regulation. The first aspect concerns the description of biochemically identifiable membrane ion-transport mechanisms that control pHi. One well-known mechanism is the Na+/Ht antiporter but other mechanisms also exist and they certainly play a role which has been relatively underestimated until now. The second aspect that will be discussed concerns the regulation of pHicontrolling systems.
The human P2Y1 receptor heterologously expressed in Jurkat cells behaves as a specific adenosine 5′-diphosphate (ADP) receptor at which purified adenosine triphosphate (ATP) is an ineffective agonist, but competitively antagonizes the action of ADP. This receptor is thus a good candidate to be the elusive platelet P2T receptor for ADP. In the present work, we examined the effects on ADP-induced platelet responses of two selective and competitive P2Y1 antagonists, adenosine-2′-phosphate-5′-phosphate (A2P5P) and adenosine-3′-phosphate-5′-phosphate (A3P5P). Results were compared with those for the native P2Y1 receptor expressed on the B10 clone of rat brain capillary endothelial cells (BCEC) and for the cloned human P2Y1 receptor expressed on Jurkat cells. A2P5P and A3P5P inhibited ADP-induced platelet shape change and aggregation (pA2 = 5) and competitively antagonized calcium movements in response to ADP in fura-2–loaded platelets, B10 cells, and P2Y1-Jurkat cells. In contrast, these compounds had no effect on ADP-induced inhibition of adenylyl cyclase in platelets or B10 cells, whereas known antagonists of platelet activation by ADP such as Sp-ATPαS were effective. These identical signaling responses and pharmacologic properties suggest that platelets and BCEC share a common P2Y1 receptor involved in ADP-induced aggregation and vasodilation, respectively. This P2Y1 receptor coupled to the mobilization of intracellular calcium stores was found to be necessary to trigger ADP-induced platelet aggregation. The present results, together with data from the literature, also point to the existence of another as yet unidentified ADP receptor, coupled to adenylyl cyclase and responsible for completion of the aggregation response. Thus, the term, P2T, should no longer be used to designate a specific molecular entity.
Pharmacological properties of the human P2Y1 receptor transfected in Jurkat cells and of the endogenous receptor in rat brain capillary endothelial cells were analyzed under conditions in which the purity of adenine triphosphate nucleotides was controlled by creatine phosphate/creatine phosphokinase (CP/CPK). ATP, a partial agonist of the receptor, was inactive in the presence of CP/CPK. Results further indicated that ATP was a competitive antagonist of ADP actions. Ki values were 23.0 +/- 1.5 microM in endothelial cells and 14.3 +/- 0.3 microM in Jurkat cells. Solutions prepared from commercially available 2-methylthio-ATP (2-MeSATP) or 2-chloro-ATP (2-ClATP) contained approximately 10% of ADP derivatives. ADP derivatives were removed from the solution by treatment with CP/CPK. Purified 2-MeSATP and 2-ClATP antagonized platelet aggregation induced by ADP. They did not activate P2Y1 receptors but prevented ADP actions in a competitive manner. Ki values for 2-MeSATP were 36. 5 microM in endothelial cells and 5.7 +/- 0.4 microM in Jurkat cells, and Ki values for 2-ClATP were 27.5 microM in endothelial cells and 2.3 +/- 0.3 microM in Jurkat cells. EDTA potentiated actions of ADP and ATP on endothelial cells by 2.4- and 3.6-fold, respectively. In conclusion, the rat and human P2Y1 receptors are ADP-specific receptors that recognize ADP and 2-methylthio-ADP, whereas ATP, 2-MeSATP, and 2-ClATP are competitive antagonists. The results further point to the close pharmacological similarity of the P2Y1 receptor and the platelet ADP receptor.
Vascular endothelial growth factor (VEGF) is an endothelial cell-specific mitogen that is upregulated during exposure to hypoxia. In this study, we analyzed heart and lung VEGF mRNA expression and examined pulmonary vascular remodeling as well as myocardial capillary density in two rat models of pulmonary hypertension involving exposure to chronic hypoxia (CH) and treatment with monocrotaline (MCT), respectively. The rats were studied after 0.5, 1, 3, 15, and 30 days of exposure to 10% O2 or 1, 6, and 30 days after a subcutaneous MCT injection (60 mg/kg). Both CH and MCT induced pulmonary hypertension and hypertrophy of the right ventricle (RV) with increased RV weight and atrial natriuretic peptide mRNA expression. VEGF mRNA expression as assessed by Northern blot analysis was potently induced after 12 h of hypoxia in both the right and left ventricles. After prolonged exposure to hypoxia, VEGF mRNA returned to baseline in the left ventricle (LV) but remained increased in the RV, where it peaked after 30 days. In MCT rats, VEGF mRNA was unchanged in the LV but decreased by 50% in the RV and by 90% in the lungs after 30 days. VEGF mRNA remained unchanged in the lungs from CH rats. Pulmonary vascular remodeling was more pronounced in MCT than in CH rats. The number of capillaries per RV myocyte was increased in rats exposed to 30 days of hypoxia, whereas it remained unchanged in MCT rats despite a similar degree of RV hypertrophy. Our results suggest that the sustained increase in VEGF expression in the hypertrophied RV during CH may account for the increased number of capillaries per myocyte. In contrast, reduced VEGF expression in the lungs and RV of MCT rats may aggravate pulmonary vascular remodeling and compromise RV myocardial perfusion.
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