Sodium-induced calcium release from mitochondria in brown adipose tissue (original) (raw)
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European Journal of Biochemistry, 1983
The ability of isolated mitochondria from rat brown-adipose tissue to regulate extramitochondrial Ca2+ (measured by arsenazo) was studied in relation to their ability to produce heat (measured polarographically). The energetic state of the mitochondria was expressed as a membrane potential, delta psi (estimated with safranine), and was varied semi-physiologically by the use of different GDP concentrations. In these mitochondria GDP binds to the 32-kDa polypeptide, thermogenin, which regulates coupling. Ca2+ uptake (at 5 microM extramitochondrial Ca2+) was maximal at delta psi greater than 150 mV. Basal Ca2+ release increased from 1 to 2 nmol x min-1 x mg-1 below 150 mV. Na+ -stimulated rate of Ca2+ release was stable within the investigated delta psi span (100-160 mV). Initial Ca2+ levels were maintained below 0.2 microM for 100 mV less than delta psi less than 160 mV. Ca2+ levels maintained after Ca2+ challenge (20 nmol Ca2+ x mg-1) were below 0.4 microM for delta psi greater than 135 mM. Respiration was unstimulated for delta psi greater than 150 mV and was maximal at delta psi less than or equal to 135 mV. In the presence of well-oxidised substrates, the respiration at maximally activated thermogenin was markedly below fully uncoupled respiration and was probably limited by thermogenin activity--i.e. by a limited H+ reentry (OH- exit) and therefore by a membrane potential maintained at about 135 mV. It is concluded that at membrane potentials of 135 mV and above the mitochondria exhibit full Ca2+ control and are able to regulate thermogenic output up to maximum without interfering with this Ca2+ control. Membrane potential probably does not decrease below 135 mV in vivo. Therefore, Ca2+ homeostasis and thermogenesis are non-interfering and can be hormonally independently regulated, e.g. by alpha-adrenergic and beta-adrenergic stimuli, respectively.
The Journal of biological chemistry, 1988
Rapid, unidirectional Ca2+ influx was examined in isolated brown adipocytes by short incubations (30 s) with 45Ca2+. Ca2+ uptake was found to be large in the resting brown adipocyte, but was markedly inhibited when the cells were presented with norepinephrine. Specific alpha 1-adrenergic stimulation was without effect on Ca2+ uptake. The effect of norepinephrine (which had an EC50 of 140 nM) could be inhibited by beta-adrenergic blockade and could be mimicked by forskolin (an adenylate cyclase activator) and theophylline (a phosphodiesterase inhibitor). Exogenous free fatty acids such as octanoate and palmitate (classical stimulators of respiration in brown adipocytes) were also able to dramatically inhibit Ca2+ uptake by the cells. The artificial mitochondrial uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) induced a large reduction in cellular Ca2+ uptake (even in the presence of the ATPase inhibitor oligomycin), and in the presence of FCCP the inhibitory effec...
PLoS ONE, 2010
Brown adipose tissue (BAT) mitochondria thermogenesis is regulated by uncoupling protein 1 (UCP 1), GDP and fatty acids. In this report, we observed fusion of the endoplasmic reticulum (ER) membrane with the mitochondrial outer membrane of rats BAT. Ca 2+ -ATPase (SERCA 1) was identified by immunoelectron microscopy in both ER and mitochondria. This finding led us to test the Ca 2+ effect in BAT mitochondria thermogenesis. We found that Ca 2+ increased the rate of respiration and heat production measured with a microcalorimeter both in coupled and uncoupled mitochondria, but had no effect on the rate of ATP synthesis. The Ca 2+ concentration needed for half-maximal activation varied between 0.08 and 0.11 mM. The activation of respiration was less pronounced than that of heat production. Heat production and ATP synthesis were inhibited by rotenone and KCN. Liver mitochondria have no UCP1 and during respiration synthesize a large amount of ATP, produce little heat, GDP had no effect on mitochondria coupling, Ca 2+ strongly inhibited ATP synthesis and had little or no effect on the small amount of heat released. These finding indicate that Ca 2+ activation of thermogenesis may be a specific feature of BAT mitochondria not found in other mitochondria such as liver. Citation: de Meis L, Ketzer LA, da Costa RM, de Andrade IR, Benchimol M (2010) Fusion of the Endoplasmic Reticulum and Mitochondrial Outer Membrane in Rats Brown Adipose Tissue: Activation of Thermogenesis by Ca 2+ . PLoS ONE 5(3): e9439.
European Journal of Histochemistry, 2014
Mitochondria are key organelles maintaining cellular bioenergetics and integrity, and their regulation of [Ca 2+ ] i homeostasis has been investigated in many cell types. We investigated the short-term Ca-SANDOZ ® treatment on brown adipocyte mitochondria, using imaging and molecular biology techniques. Two-monthold male Wistar rats were divided into two groups: Ca-SANDOZ ® drinking or tap water (control) drinking for three days. Alizarin Red S staining showed increased Ca 2+ level in the brown adipocytes of treated rats, and potassium pyroantimonate staining localized electrondense regions in the cytoplasm, mitochondria and around lipid droplets. Ca-SANDOZ ® decreased mitochondrial number, but increased their size and mitochondrial cristae volume. Transmission electron microscopy revealed numerous enlarged and fusioned-like mitochondria in the Ca-SANDOZ ® treated group compared to the control, and megamitochondria in some brown adipocytes. The Ca 2+ diet affected mitochondrial fusion as mitofusin 1 (MFN1) and mitofusin 2 (MFN2) were increased, and mitochondrial fission as dynamin related protein 1 (DRP1) was decreased. Confocal microscopy showed a higher colocalization rate between functional mitochondria and endoplasmic reticulum (ER). The level of uncoupling protein-1 (UCP1) was elevated, which was confirmed by immunohistochemistry and Western blot analysis. These results suggest that Ca-SANDOZ ® stimulates mitochondrial fusion, increases mitochondrial-ER contacts and the thermogenic capacity of brown adipocytes.
Na+-dependent regulation of extramitochondrial Ca2+ by rat-liver mitochondria
European Journal of Biochemistry, 1984
The presence and significance of Na+-induced Ca2+ release from rat liver mitochondria was investigated by the arsenazo technique. Under the experimental conditions used, the mitochondria, as expected, avidly extracted Ca2+ from the medium. However, when the uptake pathway was blocked with ruthenium red, only a small rate of 'basal' release of Ca2+ was seen (0.3 nmol Ca2+ X min-1 X mg-1), in marked contrast to earlier reports on a rapid loss of sequestered Ca2+ from rat liver mitochondria. The addition of Na+ in 'cytosolic' levels (20 mM) led to an increase in the release rate by about 1 nmol Ca2+ X min-1 X mg-1. This effect was specific for Na+. The significance of this Na+-induced Ca2+ release, in relation to the Ca2+ uptake mechanism, was investigated (in the absence of uptake inhibitors) by following the change in the extramitochondrial Ca2+ steady-state level (set point) induced by Na+. A five-fold increase in this level, from less than 0.2 microM to more than 1 microM, was induced by less than 20 mM Na+. The presence of K+ increased the sensitivity of the Ca2+ homeostat to Na+. The effect of Na+ on the extramitochondrial level was equally well observed in an K+/organic-anion buffer as in a sucrose buffer. Liver mitochondria incubated under these circumstances actively counteracted a Ca2+ or EGTA challenge by taking up or releasing Ca2+, so that the initial level, as well as the Na+-controlled level, was regained. It was concluded that liver mitochondria should be considered Na+-sensitive, that the capacity of the Na+-induced efflux pathway was of sufficient magnitude to enable it to influence the extramitochondrial Ca2+ level biochemically and probably also physiologically, and that the mitochondria have the potential to act as active, Na+-dependent regulators of extramitochondrial ('cytosolic') Ca2+. It is suggested that changes of cytosolic Na+ could be a mediator between certain hormonal signals (notably alpha 1-adrenergic) and changes in this extramitochondrial ('cytosolic') Ca2+ steady state level.
Identification of a Ca2+-ATPase in Brown Adipose Tissue Mitochondria
Journal of Biological Chemistry, 2006
In brown adipose tissue (BAT) adrenaline promotes a rise of the cytosolic Ca 2؉ concentration from 0.05 up to 0.70 M. It is not known how the rise of Ca 2؉ concentration activates BAT thermogenesis. In this report we compared the effects of Ca 2؉ in BAT and liver mitochondria. Using electron microscopy and immunolabeling we identified a sarco/endoplasmic reticulum (ER) Ca 2؉-ATPase bound to the inner membrane of BAT mitochondria. A Ca 2؉-dependent ATPase activity was detected in BAT mitochondria when the respiratory substrates malate and pyruvate were included in the medium. ATP and Ca 2؉ enhanced the amount of heat produced by BAT mitochondria during respiration. The Ca 2؉ concentration needed for half-maximal activation of the ATPase activity and rate of heat production were the same and varied between 0.1 and 0.2 M. Heat production was partially inhibited by the proton ionophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone and abolished by thapsigargin, a specific ER Ca 2؉-ATPase inhibitor, and by both rotenone and KCN, two substances that inhibit the electron transfer trough the mitochondrial cytochrome chain. In liver mitochondria Ca 2؉ did not stimulate the ATPase activity nor increase the rate of heat production. Thapsigargin had no effect on liver mitochondria. In conclusion, this is the first report of a Ca 2؉-ATPase in mitochondria that is BAT-specific and can generate heat in the presence of Ca 2؉ concentrations similar to those noted in the cell during adrenergic stimulation.
Characterisation of Ca2+ transport activity by white adipose tissue mitochondria
FEBS Letters, 1983
Ca2' transport in mitochondria isolated from rat white adipocytes has been examined and many of the properties found to be similar to those reported for mitochondria isolated from rat liver. Ca" transport is ruthenium red-sensitive (Ki -5 pmol . mg protein-'), the affinity for free Ca2' is high (Km -3.3 PM) and the V,, is 135 nmol Ca2+ .min-'.mg protein-' at 4°C with 0.2 mM Pi present. Ca" transport is stimulated by increasing the medium [Pi], and is inhibited when ATP or Mg2+ is added to the incubation system and in contrast to brown adipocyte mitochondria, Ca2' efflux is not promoted by Na+. White adipocyte mitochondria may play a role in the regulation of total cell calcium in this tissue.
Sodium-Dependent Calcium Release from Vascular Smooth Muscle Mitochondria
Hypertension Research, 2000
Interest in mitochondrial calcium (Ca2+) uptake and release waned as it became apparent that sarcoplasmic reticulum calcium stores dominate the control of cytoplasmic calcium concentration. Our recent demonstration of a very large rise in vascular smooth muscle (VSM) cytoplasmic sodium (Na+) concentration after inhibition of the sodium, potassium-ATPase (sodium pump) led us to several questions. Do VSM mitochondria show Na+-dependent Ca2+ release? Are the documented changes in cytoplasmic Na+ concentration sufficient to cause Ca2+ release? Do features of the cardiac mitochondrial exchange system, including differential sensitivity to a number of calcium antagonists and cation specificity, apply to VSM? We isolated mitochondria from bovine aorta and mesenteric arteries and employed arsenazo III as the Ca2+ indicator. Mitochondria from arterial vessels accumulated added calcium (up to 50 nmol Ca2+/mg protein) and released Ca2+ on exposure to Na+. This concentration-dependent relationship was linear from 0 to 10 mM of Nat, and it plateaued between 20 mM and 40 mM of Nat. VSM mitochondria exposed to 20 mM Na+ released 118±25 nmol Ca2+ per mg mitochondrial protein in 20 min, when a new equilibrium was reached. Lithium (Li+), in contrast to Na+, produced much smaller amounts of Ca2+ release from the VSM mitochondria. Na+-dependent Ca2+ release was antagonized in a concentration-dependent manner by diltiazem (0-320 pM) with a Ki of 10.2 hM. Nifedipine had a lesser effect, and verapamil produced almost no inhibition. VSM mitochondria responses resemble those from heart mitochondria in that Na+-dependent Ca2+ release is present with a similar range of sensitivity to Na+ and a similar pattern of influence of diltiazem, nifedipine and verapamil. However, the influence of Li+ on Ca2+ release was much smaller and the amount of the Ca2+ released was much greater for VSM mitochondria compared with that reported for heart mitochondria. The large amount of Ca2+ released and the range of Na+ concentration that provoked Ca2+ release being within the physiologically achievable range raise the interesting possibility that these mechanisms may modify intramitochondrial cytosolic Ca2+ concentration, and hence could potentially contribute to the contractile response that follows inhibition of the sodium pump.
Journal of Bioenergetics and Biomembranes, 1996
The role of the adenine nucleotide translocase on Ca2+ homeostasis in mitochondria from brown adipose tissue was examined. It was found that in mitochondria incubated with 50 μM Ca2+, ADP was not needed to retain the cation, but it was required for strengthening the inhibitory effect of cyclosporin on membrane permeability transition as induced by menadione. In addition, carboxyatractyloside was unable to promote matrix Ca2+ release, even though it inhibits the ADP exchange reaction. However, when the Ca2+ concentration was increased to 150 μM, carboxyatractyloside did induce Ca2+ release, and ADP favored Ca2+ retention. Determination of cardiolipin content in the inner membrane vesicles showed a greater concentration in brown adipose tissue mitochondria than that found in kidney mitochondria. It is suggested that the failure of the adenine nucleotide translocase to influence membrane permeability transition depends on the lipid composition of the inner membrane.