Calcium depletion and repletion in cultured chick heart muscle cells.

Calcium-free incubation followed by exposure to calcium damages naturally occurring cardiac muscle preparations irreversibly. Whether the observed calcium overload during calcium repletion is a primary cause for, or a secondary consequence of, sarcolemmal disruption and cell injury is controversial. We used cultured embryonic chicken heart muscle cells to correlate ionic, metabolic, and ultrastructural changes during calcium depletion (0Ca, 1 mM EGTA) and repletion. After 10 min of calcium depletion, intracellular Na increased four-fold above control levels, intracellular K decreased by 26%, total cell Ca decreased by 81%, and cytosolic ionized Ca concentration decreased by 87%. Within 10 min of subsequent calcium repletion, total cell Ca transiently increased to four-fold above control, cytosolic ionized Ca concentration transiently increased to twice control, and both Na and K returned toward control levels; by 3 h of calcium repletion, physiological cation (Na, K, Ca) contents were restored and adenine nucleotide contents were normal. Long-term (i.e. 120 min) calcium depletion did not significantly reduce cell ATP levels, but increased adenine nucleotide turnover as indicated by adenosine and lactate release; after 60 min of subsequent calcium repletion, ionic and metabolic parameters were returned to control levels. During calcium depletion (both short- and long-term) and subsequent repletion, no ultrastructural changes occurred. When Mg was also removed during calcium depletion, the ionic changes during depletion and subsequent repletion were enhanced. When 10 microM CCCP was present during calcium depletion and repletion, cytosolic ionized Ca concentration increased to six-fold above control with no increase in total cell Ca content, suggesting that the increased Ca is buffered, in part, by mitochondria. These results indicate that an increase in Ca per se, occurring when high energy phosphate levels and/or cellular Ca buffering capacity are maintained, does not seem to be associated with irreversible cell injury.

In situ cryofixation of kidney for electron probe X-ray microanalysis.

Cell physiological and pathophysiological studies often require information about the elemental composition of intracellular organelles in situ. Electron probe X-ray microanalysis (EPXMA) is one of the few methods by which intracellular elemental content and distribution can be measured simultaneously. While several cryofixation techniques for EPXMA have been utilized on isolated cells, few have been applied successfully to whole tissue in vivo or in situ. A recently developed, commercial, portable, metal-mirror device was used for preserving kidney in situ to determine the intracellular element distribution in proximal tubule cells. Kidneys of male rats were exposed, cryofixed, and analyzed for organelle elemental contents by EPXMA imaging. In addition, some portions of the frozen tissue were prepared for conventional transmission electron microscopy. Proximal tubules were preserved with intact brush borders and open lumens. The quality of preservation of tubule cell organelles varied inversely as a function of depth from the point of first contact with the mirror surface; the best preservation was within 15 microns, while the poorest preservation was deeper than 30 microns. Analysis of EPXMA images from the best-preserved regions revealed that proximal tubule cell cytoplasmic K/Na was approximately 6, cytoplasmic Cl was low relative to other subcellular compartments, and mitochondrial Ca levels were 1.8 nmole/mg dry weight; these observations indicate that the cells were physiologically viable at the time of cryofixation. The advantages of in situ cryofixation by this metal-mirror method include acquisition of organelle elemental content data in vivo, ease of use, reproducibility, portability, applicability to other tissues, and suitability for pathophysiological studies.

Magnesium homeostasis in cardiac cells.

Several aspects of Mg2+ homeostasis were investigated in cultured chicken heart cells using the fluorescent Mg2+ indicator, FURAPTRA. The concentration of cytosolic Mg2+ ([Mg2+]i) is 0.48 +/- 0.03 mM (n = 31). To test whether a putative Na/Mg exchange mechanism controls [Mg2+]i below electrochemical equilibrium, we manipulated the Na+ gradient and assessed the effects on [Mg2+]i. When extracellular Na+ was removed, [Mg2+]i increased; this increase was not altered in Mg-free solutions, but was attenuated in Ca-free solutions. A similar increase in [Mg2+]i, which was dependent upon extracellular Ca2+, was observed when intracellular Na+ was raised by inhibiting the Na/K pump with ouabain. These results do not provide evidence for Na/Mg exchange in heart cells, but they suggest that Ca2+ can modulate [Mg2+]i. In addition, removing extracellular Na+ caused a decrease in intracellular pH (pHi), as measured by pH-sensitive microelectrodes, and this acidification was attenuated when Ca2+ was also removed from the solution. These results suggest that Ca2+ and H+ interact intracellularly. Since changes in the Na+ gradient can also alter pHi, we questioned whether pH can modulate [Mg2+]i. pHi was manipulated by the NH4Cl prepulse method. NH4(+)-evoked changes in pHi, as measured by the fluorescent indicator BCECF, were accompanied by opposite changes in [Mg2+]i; [Mg2+]i changed by -0.16 mM/unit pH. These NH4(+)-evoked changes in [Mg2+]i were not caused by movements of Mg2+ or Ca2+ across the sarcolemma or by changes in cytosolic Ca2+. Additionally, pHi was manipulated by changing extracellular pH (pHo).(ABSTRACT TRUNCATED AT 250 WORDS)

Intracellular pH modulates cytosolic free magnesium in cultured chicken heart cells.

To assess the role of pH in cellular Mg homeostasis, cytosolic pH (pHi) was manipulated by the NH4Cl prepulse technique; pHi, cytosolic Mg2+ (Mgi), and cytosolic Ca2+ (Cai) were measured fluorometrically in single cultured embryonic chicken heart cells loaded with 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF), FURAPTRA, and fura-2, respectively. The basal values obtained were as follows: pHi = 7.21 +/- 0.10 (n = 7), [Mg]i = 0.51 +/- 0.08 mM (n = 9), [Ca]i = 126 +/- 15 nM (n = 7). When cells were perfused with 10 mM NH4Cl solution for 5 min, a transient alkalinization (0.53 U) of the cytosol was accompanied by a transient decrease (0.12 mM) in [Mg]i and a transient increase (59 nM) in [Ca]i; these changes approached control levels within 5 min. Upon removal of NH4Cl, a transient acidification (0.89 U) of the cytosol was accompanied by a transient increase (0.10 mM) in [Mg]i and a transient increase (125 nM) in [Ca]i; again, these changes returned toward control levels within 5 min. No significant changes in total cell Mg or Ca were observed during these manipulations. NH4Cl-evoked changes in [Mg]i were not altered significantly by either Mg-free or Ca-free conditions. Changes in [Mg]i were inversely correlated with changes in pHi and were not secondary to changes in [Ca]i. The results suggest that pHi modulates Mgi, probably by affecting cytosolic Mg binding and/or the transport of Mg across subcellular organelles.

Monitoring cytosolic free magnesium in cultured chicken heart cells by use of the fluorescent indicator Furaptra.

Cytosolic free magnesium concentration [Mg2+]i and its regulation were studied in cultured embryonic chicken heart cells by use of the fluorescent indicator 2-[2-(5-carboxy)oxazole]-5-hydroxy-6-aminobenzofuran-N,N,O-triacet ic acid (Furaptra). The intracellular location of Furaptra was confirmed by its complete release from cells upon addition of saponin. The basal [Mg2+]i, which averaged 0.48 +/- 0.03 mM (n = 31), increased 3-fold on perfusion with sodium-free solution. This increase could not simply be attributed to intracellular sodium-extracellular magnesium exchange because a similar increase in [Mg2+]i occurred with magnesium-free, sodium-free perfusion. Furthermore, the increase in [Mg2+]i was largely attenuated when calcium was removed from the sodium-free perfusate. Thus, a substantial part of the increase in [Mg2+]i that occurs upon sodium-free perfusion is dependent on an increase in cytosolic free calcium (intracellular sodium-extracellular calcium exchange). The data suggest that [Mg2+]i is altered by calcium, most likely due to a competition for intracellular binding sites.

The effects of adrenalectomy on the alpha-adrenergic regulation of cytosolic free calcium in hepatocytes.

We have previously published that bilateral adrenalectomy in the rat reduces the Ca2+-mediated alpha-adrenergic activation of hepatic glycogenolysis, while it increases the cellular calcium content of hepatocytes. In the experiments presented here, the concentration of cytosolic free calcium (Ca2+i) at rest and in response to epinephrine was measured in aequorin-loaded hepatocytes isolated from sham and adrenalectomized male rats. We found that in adrenalectomized rats the resting Ca2+i was elevated, the rise in Ca2+i evoked by epinephrine was reduced, and the rise in 45Ca efflux that follows such stimulation was depressed. Furthermore, the slope of the relationship between Ca2+i and calcium efflux was decreased 60% in adrenalectomized. Adrenalectomy did not change Ca2+ release from intracellular calcium pools in response to IP3 in saponin-permeabilized hepatocytes. The EC50 for inositol 1,4,5-triphosphate and the maximal Ca2+ released were similar in both sham and adrenalectomized animals. Finally, the liver calmodulin content determined by radioimmunoassay was not significantly different between sham and adrenalectomized rats. These results suggest that 1) adrenalectomy reduces calcium efflux from the hepatocyte, probably by an effect on the plasma membrane (Ca2+-Mg2+)-ATPase-dependent Ca2+ pump and thus alters cellular calcium homeostasis; 2) adrenalectomy decreases the rise in Ca2+i in response to epinephrine; 3) this decreased rise in Ca2+i is not due to defects in the intracellular Ca2+ storage and mobilization processes; and 4) the effects of adrenalectomy on cellular calcium metabolism and on alpha-adrenergic activation of glycogenolysis are not caused by a reduction in soluble calmodulin.

Intracellular messenger for action of angiotensin II on fluid transport in rabbit proximal tubule.

These studies were designed to examine the cellular messenger that mediates the action of angiotensin II on fluid transport (Jv) in the rabbit proximal tubule. We measured the effects of angiotensin II on Jv, activation of adenylate cyclase, and the concentration of cytosolic free calcium (Cai) in the rabbit proximal tubule. In nine rabbit proximal convoluted tubules (PCT), angiotensin II, 10(-8) M and 10(-6) M, decreased Jv by 18 and 25%, P less than 0.05. In eleven rabbit proximal straight tubules (PST), 10(-8) and 10(-6) M angiotensin II decreased Jv by 20 and 23%, P less than 0.02. Angiotensin II did not affect lumen-to-bath phosphate fluxes in PCT or PST, and it did not activate adenylate cyclase in PST. In a preparation of proximal tubules (PCT and PST) loaded with aequorin, angiotensin II, 10(-8) and 10(-6) M, transiently increased Cai by 13 and 32%, P less than 0.001. We propose that Cai surges, activated by angiotensin II, are part of a cellular message that inhibits Jv in the rabbit proximal tubule.

A simple method for incorporating aequorin into mammalian cells.

A simple method for incorporating aequorin into mammalian cells to measure cytosolic ionized Ca2+ is described and compared with scrape loading and hypoosmotic treatment (HOST). The procedure consists of incubating the cells for 10 min and centrifuging them at 200 g for 30 s in the presence of aequorin. This method incorporates the same amount of photoprotein as scrape loading but 70% less than HOST. Cytosolic ionized Ca2+ has been measured in hepatocytes, kidney cells and tubules, macrophages, and cardiac myocytes loaded with aequorin by this new procedure.

The effects of anoxia on cytosolic free calcium, calcium fluxes, and cellular ATP levels in cultured kidney cells.

The effect of anoxia and substrate removal on cytosolic free calcium (Ca2+i), cell calcium, ATP content, and calcium efflux was determined in cultured monkey kidney cells (LLC-MK2) exposed to 95% N2, 5% CO2 for 60 min. In the control period, the basal Ca2+i level was 70.8 +/- 9.4 nM. During 1 h of anoxia without substrate, ATP content decreased 70%, Ca2+i and calcium efflux increased 2.5-fold, while the total cell calcium did not change. When the cells were perfused again with O2 and 5 mM glucose, the ATP concentration, Ca2+i, and calcium efflux returned to control levels within 15-20 min. In the presence of 20 mM glucose, anoxia did not produce any change in ATP, in Ca2+i or in calcium efflux. An important source of calcium contributing to the rise in Ca2+i induced by anoxia appears to be extracellular because the rate of rise in Ca2+i is proportional to the extracellular calcium concentration, and because La3+ which blocks calcium influx greatly reduces the rise in Ca2+i. Mitochondria appear to control Ca2+i as well since the early rise in Ca2+i cannot be blocked by La3+ during the initial phase of anoxia, and since the mitochondrial inhibitor carbonyl cyanide p-trifluoromethoxyphenylhydrazone increases Ca2+i further during reoxygenation and slows the return of Ca2+i to control levels.