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Query: EC:1.13.12.5 (
aequorin
)
1,451
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The effects of fructose on the intracellular ionic changes evoked by anoxia were studied in freshly isolated rat hepatocytes maintained in agarose gel threads and perfused with Krebs-Henseleit bicarbonate buffer (KHB). Cytosolic free calcium (Ca2+i) was measured with
aequorin
, intracellular sodium (Na+i) with sodium-binding benzofuran isophthalate, intracellular pH (pHi) with 2'-7'-bis(carboxyethyl)-5,6-carboxyfluorescein, lactic dehydrogenase (LDH) by the increase in
NADH
absorbance during lactate oxidation to pyruvate, and viability by trypan blue exclusion. ATP, Pi, phosphomonoesters, and the cell phosphorylation potential assessed by the reciprocal of the Pi/ATP ratio were measured by 31P NMR spectroscopy in real time. Intracellular free Mg2+ (Mg2+i) was calculated from the chemical shift of beta-ATP relative to alpha-ATP in the NMR spectra. Anoxia was induced by perfusing the cells with KHB saturated with 95% N2, 5% CO2. When the perfusate contained 5 mM glucose as substrate, anoxia caused a fall in ATP, a rise in Pi, and in the Pi/ATP ratio, a biphasic increase in Ca2+i that reached 1.45 +/- 0.42 microM and a 6-fold increase in LDH. When 15 mM fructose was used as substrate during the anoxic period, intracellular ATP decreased much faster than with glucose, Pi did not increase, and the concentration of phosphomonoesters increased 2.5-fold. During the first hour of anoxia, the Pi/ATP ratio was higher in the fructose than in the glucose group indicating that the hepatocyte phosphorylation potential and ATP decreased faster and to lower levels with fructose than with glucose. On the other hand, ATP and the phosphorylation potential of the fructose group increased during the second hour of anoxia, in contrast to their continuous decline in the glucose group. The major surge in Ca2+i was depressed 52% when glucose was replaced by fructose: Ca2+i reached only 0.7 +/- 0.2 microM instead of 1.45 +/- 0.42 microM (p less than 0.01). Anoxia also caused an increase in Na+i and an intracellular acidosis. The rise in Na+i was significantly greater with fructose than with glucose. Na+i rose from a control value of 15.9 +/- 2.4 to 32.2 +/- 0.4 mM with glucose and to 48.7 +/- 0.7 mM with fructose (p less than 0.001). The decrease in pHi from a control value of 7.43 +/- 0.03 was consistently greater and faster with fructose than with glucose: 6.59 +/- 0.03 and 7.04 +/- 0.01, respectively. At the same time, fructose completely suppressed LDH release and reduced the loss of viability produced by anoxia from 27.7 +/- 2.9 to 14 +/- 3.1% (p less than 0.05).
...
PMID:Fructose protects rat hepatocytes from anoxic injury. Effect on intracellular ATP, Ca2+i, Mg2+i, Na+i, and pHi. 155 92
The effects of anoxia were studied in freshly isolated rat hepatocytes maintained in agarose gel threads and perfused with Krebs-Henseleit bicarbonate buffer (KHB). Cytosolic free calcium (Ca2+i) was measured with
aequorin
, intracellular sodium (Na+i) with SBFI, intracellular pH (pHi) with BCECF, lactic dehydrogenase (LDH) by the increase in
NADH
absorbance during lactate oxidation to pyruvate, ATP by 31P NMR spectroscopy in real time, and intracellular free Mg2+ (Mg2+i) from the chemical shift of beta-ATP relative to alpha-ATP in the NMR spectra. Anoxia was induced by perfusing the cells with KHB saturated with 95% N2, 5% CO2. After 1 h of anoxia, beta-ATP fell 66%, and 85% after 2 h, while the Pi/ATP ratio increased 10-fold from 2.75 to 28.3. Under control conditions, the resting cytosolic free calcium was 127 +/- 6 nM. Anoxia increased Ca2+i in two distinct phases: a first rise occurred within 15 min and reached a mean value of 389 +/- 35 nM (p less than 0.001). A second peak reached a maximum value of 1.45 +/- 0.12 microM (p less than 0.001) after 1 h. During the first hour of anoxia, Na+i increased from 15.9 +/- 2.4 mM to 32.2 +/- 1.2 mM (p less than 0.001), Mg2+i doubled from 0.51 +/- 0.05 to 1.12 +/- 0.01 mM (p less than 0.001), and pHi decreased from 7.41 +/- 0.03 to 7.06 +/- 0.1 (p less than 0.001). LDH release doubled during the first hour and increased 6-fold during the second hour of anoxia. Upon reoxygenation, ATP, Ca2+i, Mg2+i, Na+i, and LDH returned near the control levels within 45 min. To determine whether the increased LDH release was related to the rise in Ca2+i, and whether the increased Ca2+i was caused by Ca2+ influx, the cells were perfused with Ca(2+)-free KHB (+ 0.1 mM EGTA) during the anoxic period. After 2 h of anoxia in Ca(2+)-free medium, beta-ATP again fell 90%, but Ca2+i, after the first initial peak, fell below control levels, and LDH release increased only 2.7-fold. During reoxygenation, Ca2+i, ATP, Na+i, and LDH returned near the control levels within 45 min. These results suggest that the rise in Ca2+i induced by anoxia is caused by an influx of Ca2+ from the extracellular fluid, and that LDH release and cell injury may be related to the resulting rise in Ca2+i.
...
PMID:Effect of anoxia on intracellular ATP, Na+i, Ca2+i, Mg2+i, and cytotoxicity in rat hepatocytes. 163 81
Histochemical analysis was used to study the relationship between Rana temporaria tibialis anterior and lumbricalis IV fibre cross-sectional areas and concentrations of myosin ATPase and
NADH
reductase. Both tonic and twitch fibre types were histochemically identified in each muscle and the twitch fibres were subgrouped into types 1, 2, and 3. Fibres that had the largest cross-sectional areas were identified as the fibres which contained the highest myosin ATPase activity and the lowest
NADH
reductase activity (type 1 fibres). However, this relationship was more pronounced in the tibialis anterior muscle. In addition, single fibres from both muscles were isolated and injected with Ca2+ indicator
aequorin
. The fibres isolated from the tibialis anterior muscle were those with the largest cross-sectional areas relative to other fibres within a given muscle. The force responses and Ca2+ transients recorded from this group of single fibres were found to be fairly uniform, which may suggest that a single type of fibre was isolated. In contrast, the physiological properties of isolated lumbricalis IV fibres were highly variable and thus represented more than one fibre type.
...
PMID:Histochemical and physiological properties of Rana temporaria tibialis anterior and lumbricalis IV muscle fibres. 225 38
The effect of high and low pH on anoxic cell injury was studied in freshly isolated rat hepatocytes cast in agarose gel threads and perfused with Krebs-Henseleit bicarbonate buffer (KHB) saturated with 95% O2 and 5% CO2. Cytosolic free calcium (Ca2+i) was measured with
aequorin
, intracellular pH (pHi) with BCECF, and lactic dehydrogenase (LDH) by the increase in
NADH
absorbance during lactate oxidation to pyruvate. A 2 h period of anoxia was induced by perfusing the cells with KHB saturated with 95% N2 and 5% CO2. The extracellular pH (pHo) was maintained at 7.4, 6.8 or 8.0 by varying the bicarbonate concentration. The substrate was either 5 mM glucose, 15 mM glucose or 15 mM fructose. In some experiments, anoxia was performed in Ca(2+)-free media by perfusing the cells with KHB without Ca2+ but with 0.1 mM EGTA. Reducing pHo to 6.8 during anoxia did not reduce the increase in Ca2+i, but but completely abolished LDH release. Under these conditions, pHi decreased to 6.56 +/- 0.3 when glucose was the substrate and to 6.18 +/- 0.25 with 15 mM fructose. Apparently, protection against anoxic injury caused by a low pHo is associated with a low pHi but not with a reduced elevation in Ca2+i. Increasing pHo to 8.0 during anoxia increased pHi above 8.0 +/- 0.01 and doubled LDH release without significantly altering the rise in Ca2+i. When 15 mM fructose was present with a pHo of 8.0, pHi was still 8.0, but there was practically no rise in Ca2+i, and LDH release was again completely abolished. On the other hand, a Ca(2+)-free perfusate with a pHo of 8.0 kept the rise in Ca2+i below 400 nM but did not abolish the massive release of LDH caused by high pH. Since cell injury is caused by the activation of Ca(2+)-sensitive hydrolytic enzymes such as phospholipase A2, these experiments suggest that a low pH (< 6.5) prevents their activation even in the presence of a high Ca2+i. Conversely, a high pH (> 8.0) can activate hydrolytic enzymes and cause injury even in the absence of an elevated Ca2+i. The precise mechanism by which fructose protects hepatocytes against cell injury at pHi 8.0 is unclear.
...
PMID:Effects of high and low pH on Ca2+i and on cell injury evoked by anoxia in perfused rat hepatocytes. 830
The effect of fasting and anoxia on the intracellular concentration of ATP, Na+, Ca2+, Mg2+, and H+ was studied in isolated perfused rat hepatocytes. ATP and intracellular Mg2+ were measured by 31P-NMR spectroscopy, cytosolic free calcium was measured with
aequorin
, intracellular Na+ with SBFI, intracellular pH with BCECF, lactic dehydrogenase by
NADH
absorbance. In hepatocytes from fasted rats, intracellular ATP was depressed 52% (P < 0.001), Nai+ was increased 70% from 16.9 to 27.7 mM (P < 0.02), and Cai2+ was increased 79% from 137 to 245 nM (P < 0.05) when compared to fed rats. Mgi2+ and pHi were unchanged. During anoxia, ATP and the cell phosphorylation potential decreased 90% to practically the same low levels in both fed and fasted groups. On the other hand, in hepatocytes from fasted animals, Cai2+ increased faster and to significantly higher levels than in hepatocytes from fed rats: Cai2+ reached 2.19 microM in 10 min compared to 1.45 microM in 1 h, respectively (P < 0.05). Cell injury assessed by LDH release and trypan blue exclusion also occurred earlier and was more severe in hepatocytes from fasted rats. Fructose and Ca(2+)-free perfusion reduced the rise in Cai2+, abolished LDH release and significantly improved the cell viability measured by Trypan blue exclusion. The data demonstrate that fasting decreases the hepatocytes energy potential and increases Nai+ and Cai2+ which are inversely related to the cell energy potential. Consequently, in hepatocytes isolated from fasted rats, the increase in Cai2+ and the resulting cell injury evoked by anoxia occur earlier and are more severe than in fed rats. These results suggest that Ca2+ plays a crucial role in the development of anoxic cell injury.
...
PMID:Fasting enhances the effects of anoxia on ATP, Cai2+ and cell injury in isolated rat hepatocytes. 832 59
In the pancreatic beta-cell, insulin secretion is stimulated by glucose metabolism resulting in membrane potential-dependent elevation of cytosolic Ca2+ ([Ca2+]c). This cascade involves the mitochondrial membrane potential (delta psi[m]) hyperpolarization and elevation of mitochondrial Ca2+ ([Ca2+]m) which activates the Ca(2+)-sensitive
NADH
-generating dehydrogenases. Metabolism-secretion coupling requires unidentified signals, other than [Ca2+]c, possibly generated by the mitochondria through the rise in [Ca2+]m. To test this paradigm, we have established an alpha-toxin permeabilized cell preparation permitting the simultaneous monitoring of [Ca2+] with mitochondrially targeted
aequorin
and insulin secretion under conditions of saturating [ATP] (10 mM) and of clamped [Ca2+]c at substimulatory levels (500 nM). The tricarboxylic acid (TCA) cycle intermediate succinate hyperpolarized delta psi(m), raised [Ca2+]m up to 1.5 microM and stimulated insulin secretion 20-fold, without changing [Ca2+]c. Blockade of the uniporter-mediated Ca2+ influx into the mitochondria abolished the secretory response. Moreover, glycerophosphate, which raises [Ca2+]m by hyperpolarizing delta psi(m) without supplying carbons to the TCA cycle, failed to stimulate exocytosis. Activation of the TCA cycle with citrate evoked secretion only when combined with glycerophosphate. Thus, mitochondrially driven insulin secretion at permissive [Ca2+]c requires both a substrate for the TCA cycle and a rise in [Ca2+]m. Therefore, mitochondrial metabolism generates factors distinct from Ca2+ and ATP capable of inducing insulin exocytosis.
...
PMID:Mitochondrial activation directly triggers the exocytosis of insulin in permeabilized pancreatic beta-cells. 923 93
Minocycline, an antibiotic of the tetracycline family, has attracted considerable interest for its theoretical therapeutic applications in neurodegenerative diseases. However, the mechanism of action underlying its effect remains elusive. Here we have studied the effect of minocycline under excitotoxic conditions. Fluorescence and bioluminescence imaging studies in rat cerebellar granular neuron cultures using fura2/AM and mitochondria-targeted
aequorin
revealed that minocycline, at concentrations higher than those shown to block inflammation and inflammation-induced neuronal death, inhibited NMDA-induced cytosolic and mitochondrial rises in Ca(2+) concentrations in a reversible manner. Moreover, minocycline added in the course of NMDA stimulation decreased Ca(2+) intracellular levels, but not when induced by depolarization with a high K(+) medium. We also found that minocycline, at the same concentrations, partially depolarized mitochondria by about 5-30 mV, prevented mitochondrial Ca(2+) uptake under conditions of environmental stress, and abrogated NMDA-induced reactive oxygen species (ROS) formation. Consistently, minocycline also abrogates the rise in ROS induced by 75 microM Ca(2+) in isolated brain mitochondria. In search for the mechanism of mitochondrial depolarization, we found that minocycline markedly inhibited state 3 respiration of rat brain mitochondria, although distinctly increased oxygen uptake in state 4. Minocycline inhibited
NADH
-cytochrome c reductase and cytochrome c oxidase activities, whereas the activity of succinate-cytochrome c reductase was not modified, suggesting selective inhibition of complexes I and IV. Finally, minocycline affected activity of voltage-dependent anion channel (VDAC) as determined in the reconstituted system. Taken together, our results indicate that mitochondria are a critical factor in minocycline-mediated neuroprotection.
...
PMID:Mitochondria and calcium flux as targets of neuroprotection caused by minocycline in cerebellar granule cells. 1968 37
