Coupled Ca2+/H+ transport by cytoplasmic buffers regulates local Ca2+ and H+ ion signaling |
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Authors: | Pawel Swietach Jae-Boum Youm Noriko Saegusa Chae-Hun Leem Kenneth W. Spitzer Richard D. Vaughan-Jones |
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Affiliation: | aBurdon Sanderson Cardiac Science Centre, Department of Physiology, Anatomy, and Genetics, Oxford University, Oxford OX1 3PT, United Kingdom;;bDepartment of Physiology and Biophysics, College of Medicine, Inje University, Inje 621-749, Korea;;cNora Eccles Harrison Cardiovascular Research and Training Institute, University of Utah, Salt Lake City, UT; and;dDepartment of Physiology, University of Ulsan College of Medicine, Seoul, Korea |
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Abstract: | Ca2+ signaling regulates cell function. This is subject to modulation by H+ ions that are universal end-products of metabolism. Due to slow diffusion and common buffers, changes in cytoplasmic [Ca2+] ([Ca2+]i) or [H+] ([H+]i) can become compartmentalized, leading potentially to complex spatial Ca2+/H+ coupling. This was studied by fluorescence imaging of cardiac myocytes. An increase in [H+]i, produced by superfusion of acetate (salt of membrane-permeant weak acid), evoked a [Ca2+]i rise, independent of sarcolemmal Ca2+ influx or release from mitochondria, sarcoplasmic reticulum, or acidic stores. Photolytic H+ uncaging from 2-nitrobenzaldehyde also raised [Ca2+]i, and the yield was reduced following inhibition of glycolysis or mitochondrial respiration. H+ uncaging into buffer mixtures in vitro demonstrated that Ca2+ unloading from proteins, histidyl dipeptides (HDPs; e.g., carnosine), and ATP can underlie the H+-evoked [Ca2+]i rise. Raising [H+]i tonically at one end of a myocyte evoked a local [Ca2+]i rise in the acidic microdomain, which did not dissipate. The result is consistent with uphill Ca2+ transport into the acidic zone via Ca2+/H+ exchange on diffusible HDPs and ATP molecules, energized by the [H+]i gradient. Ca2+ recruitment to a localized acid microdomain was greatly reduced during intracellular Mg2+ overload or by ATP depletion, maneuvers that reduce the Ca2+-carrying capacity of HDPs. Cytoplasmic HDPs and ATP underlie spatial Ca2+/H+ coupling in the cardiac myocyte by providing ion exchange and transport on common buffer sites. Given the abundance of cellular HDPs and ATP, spatial Ca2+/H+ coupling is likely to be of general importance in cell signaling.Most cells are exquisitely responsive to calcium (Ca2+) (1) and hydrogen (H+) ions (i.e., pH) (2). In cardiac myocytes, Ca2+ ions trigger contraction and control growth and development (3), whereas H+ ions, which are generated or consumed metabolically, are potent modulators of essentially all biological processes (4). By acting on Ca2+-handling proteins directly or via other molecules, H+ ions exert both inhibitory and excitatory effects on Ca2+ signaling. For example, in the ventricular myocyte, H+ ions can reduce Ca2+ release from sarcoplasmic reticulum (SR) stores, through inhibition of the SR Ca2+ ATPase (SERCA) pump and ryanodine receptor (RyR) Ca2+ channels (5, 6). In contrast, H+ ions can enhance SR Ca2+ release by stimulating sarcolemmal Na+/H+ exchange (NHE), which raises intracellular [Na+] and reduces the driving force for Ca2+ extrusion on Na+/Ca2+ exchange (NCX), leading to cellular retention of Ca2+ (7, 8). Ca2+ signaling is thus subservient to pH.Cytoplasmic Ca2+ and H+ ions bind avidly to buffer molecules, such that <1% of all Ca2+ ions and <0.001% of all H+ ions are free. Some of these buffers bind H+ and Ca2+ ions competitively, and this has been proposed to be one mechanism underlying cytoplasmic Ca2+/H+ coupling (9). Reversible binding to buffers greatly reduces the effective mobility of Ca2+ and H+ ions in cytoplasm (10, 11) and can allow for highly compartmentalized ionic microdomains, and hence a spatially heterogeneous regulation of cell function. In cardiac myocytes under resting (diastolic) conditions, the cytoplasm-averaged concentration of free [Ca2+] ([Ca2+]i) and [H+] ([H+]i) ions is kept near 10−7 M by membrane transporter proteins. Thus, [H+]i is regulated by the balance of flux among acid-extruding and acid-loading transporter proteins at the sarcolemma [e.g., NHE and Cl−/OH− (CHE) exchangers, respectively] (4). Similarly, the activity of SERCA and NCX proteins returns [Ca2+]i to its diastolic level after evoked signaling events (3, 12). Despite these regulatory mechanisms, cytoplasmic gradients of [H+]i and [Ca2+]i do occur in myocytes and are an important part of their physiology. Gradients arise from local differences in transmembrane fluxes that alter [H+]i or [Ca2+]i. For example, spatial [H+]i gradients are produced when NHE transporters, expressed mainly at the intercalated disk region, are activated (4, 13) or when membrane-permeant weak acids, such as CO2, are presented locally (14). Similarly, release of Ca2+ through a cluster of RyR channels in the SR produces [Ca2+]i nonuniformity in the form of Ca2+ sparks (15). Given the propensity of cytoplasm to develop ionic gradients, it is important to understand their underlying mechanism and functional role.The present work demonstrates a distinct form of spatial interaction between Ca2+ and H+ ions. We show that cytoplasmic [H+] gradients can produce stable [Ca2+]i gradients, and vice versa, and that this interaction is mediated by low-molecular-weight (mobile) buffers with affinity for both ions. We demonstrate that the diffusive counterflux of H+ and Ca2+ bound to these buffers comprises a cytoplasmic Ca2+/H+ exchanger. This acts like a “pump” without a membrane, which can, for instance, recruit Ca2+ to acidic cellular microdomains. Cytoplasmic Ca2+/H+ exchange adds a spatial paradigm to our understanding of Ca2+ and H+ ion signaling. |
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Keywords: | calcium heart mobile buffer pH dual microperfusion |
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