Intrinsic H(+) ion mobility in the rabbit ventricular myocyte.

The intrinsic mobility of intracellular H(+) ions was investigated by confocally imaging the longitudinal movement of acid inside rabbit ventricular myocytes loaded with the acetoxymethyl ester (AM) form of carboxy-seminaphthorhodafluor-1 (carboxy-SNARF-1). Acid was diffused into one end of the cell through a patch pipette filled with an isotonic KCl solution of pH 3.0. Intracellular H(+) mobility was low, acid taking 20-30 s to move 40 microm down the cell. Inhibiting sarcolemmal Na(+)-H(+) exchange with 1 mM amiloride had no effect on this time delay. Net H(+)(i) movement was associated with a longitudinal intracellular pH (pH(i)) gradient of up to 0.4 pH units. H(+)(i) movement could be modelled using the equations for diffusion, assuming an apparent diffusion coefficient for H(+) ions (D(H)(app)) of 3.78 x 10(-7) cm(2) s(-1), a value more than 300-fold lower than the H(+) diffusion coefficient in a dilute, unbuffered solution. Measurement of the intracellular concentration of SNARF (approximately 400 microM) and its intracellular diffusion coefficient (0.9 x 10(-7) cm(2) s(-1)) indicated that the fluorophore itself exerted an insignificant effect (between 0.6 and 3.3 %) on the longitudinal movement of H(+) equivalents inside the cell. The longitudinal movement of intracellular H(+) is discussed in terms of a diffusive shuttling of H(+) equivalents on high capacity mobile buffers which comprise about half (approximately 11 mM) of the total intrinsic buffering capacity within the myocyte (the other half being fixed buffer sites on low mobility, intracellular proteins). Intrinsic H(+)(i) mobility is consistent with an average diffusion coefficient for the intracellular mobile buffers (D(mob)) of ~9 x 10(-7) cm(2) s(-1).

Facilitation of intracellular H(+) ion mobility by CO(2)/HCO(3)(-) in rabbit ventricular myocytes is regulated by carbonic anhydrase.

Intracellular H(+) mobility was estimated in the rabbit isolated ventricular myocyte by diffusing HCl into the cell from a patch pipette, while imaging pH(i) confocally using intracellular ratiometric SNARF fluorescence. The delay for acid diffusion between two downstream regions approximately 40 microm apart was reduced from approximately 25 s to approximately 6 s by replacing Hepes buffer in the extracellular superfusate with a 5 % CO(2)/HCO(3)(-) buffer system (at constant pH(o) of 7.40). Thus CO(2)/HCO(3)(-) (carbonic) buffer facilitates apparent H(+)(i) mobility. The delay with carbonic buffer was increased again by adding acetazolamide (ATZ), a membrane permeant carbonic anhydrase (CA) inhibitor. Thus facilitation of apparent H(+)(i) mobility by CO(2)/HCO(3)(-) relies on the activity of intracellular CA. By using a mathematical model of diffusion, the apparent intracellular H(+) equivalent diffusion coefficient (D(H)(app)) in CO(2)/HCO(3)(-)-buffered conditions was estimated to be 21.9 x 10(-7) cm(2) s(-1), 5.8 times faster than in the absence of carbonic buffer. Facilitation of H(+)(i) mobility is discussed in terms of an intracellular carbonic buffer shuttle, catalysed by intracellular CA. Turnover of this shuttle is postulated to be faster than that of the intrinsic buffer shuttle. By regulating the carbonic shuttle, CA regulates effective H(+)(i) mobility which, in turn, regulates the spatiotemporal uniformity of pH(i). This is postulated to be a major function of CA in heart.