Membrane energization at subzero temperatures: calcium uptake and oxonol-V responses

Slow Ca2+-induced inactive/active transition of the energy-dependent Ca2+ transporting system of rat liver mitochondria: clue for Ca2+ influx cooperativity

Rat liver mitochondria essentially free of endogenous Ca2+ show low initial rate of energy-dependent Ca2+ uptake. Preincubation of mitochondria under de-energized conditions in the presence of small amounts of external Ca2+ results in a 8-10-fold time-dependent increase of energy-dependent Ca2+ uptake. Ca2+-dependent activation of the Ca2+-transporting system follows first-order kinetics (t1/2 approximately 1 min in the presence of 5 microM Ca2+ at 20 degrees C). Ca2+-activated mitochondria demonstrate a simple hyperbolic initial rate-Ca2+ concentration dependence, whereas strong apparent cooperativity is observed in the velocity-substrate curves for Ca2+-depleted mitochondria. It is concluded that apparent cooperativity of the energy-dependent Ca2+ uptake is due to slow (as compared with the 'turnover number') activation of a Ca2+-specific uniporter which is inactive in the absence of external Ca2+.

A stopped-flow kinetic study of the interaction of potential-sensitive oxonol dyes with lipid vesicles

The interaction of the dyes oxonol V and oxonol VI with unilamellar dioleoylphosphatidylcholine vesicles was investigated using a fluorescence stopped-flow technique. On mixing with the vesicles, both dyes exhibit an increase in their fluorescence, which occurs in two phases. According to the dependence of the reciprocal relaxation time on vesicle concentration, the rapid phase appears to be due to a second-order binding of the dye to the lipid membrane, which is very close to being diffusion-controlled. The slow phase is almost independent of vesicle concentration, and it is suggested that this may be due to a change in dye conformation or position within the membrane, possibly diffusion across the membrane to the internal monolayer. The response times of the dyes to a rapid jump in the membrane potential has also been investigated. Oxonol VI was found to respond to the potential change in less than 1 s, whereas oxonol required several minutes. This has been attributed to lower mobility of oxonol V within the lipid membrane.

The bioenergetics of mitochondria after cryopreservation

The functional characteristics of rat liver mitochondria after cryopreservation with and without the addition of the cryoprotectant dimethyl sulfoxide (Me2SO) were evaluated. As criteria of functional integrity, polarographic measurements of substrate-linked oxygen consumption and luminescent assay of adenosine triphosphate (ATP) synthesis were considered before and after cryopreservation. The results demonstrated that mitochondrial damage after freezing was indicated by the polarographic studies but was not evident when ATP synthesis was considered. Me2SO present during cryopreservation was partially protective for mitochondrial substrate-linked oxygen consumption; however, simple exposure to and dilution from Me2SO effected some changes in mitochondrial function.

Membrane function in mammalian hibernation

For homeotherms the maintenance of a high, uniform body temperature requires a constant energy supply and food intake. For many small mammals, the loss of heat in winter exceeds energy supply, particularly when food is scarce. To survive, some animals have developed a capacity for adaptive hypothermia in which they lower their body temperature to a new regulatory set-point, usually a few degrees above the ambient. This process, generally known as hibernation, reduces the temperature differential, metabolic activity, as well as the energy demand, and thus facilitates survival during winter. Successful hibernation in mammals requires that the enzymatic processes are regulated in such a manner that metabolic balance is maintained at both the high body temperature of the summer-active animal (37 degrees C) and the low body temperature of the winter-torpid animal (approx. 5 degrees C). This means that the cellular membranes have thermal properties capable of maintaining a balanced metabolism at these extreme physiological temperatures. The available evidence indicates that, for some tissues, preparation for hibernation involves an alteration in the lipid composition and thermal properties of cellular membranes. Marked differences in the thermal response of cellular membranes have been observed on a seasonal basis and, in some membranes, differences in lipid composition have been associated with the torpid state. However, to date, no consistent changes in lipid composition which would account for, or explain, the changes in membrane thermal response, have been detected. An important point to emphasize is that the process of 'homeoviscous adaptation', which occurs in procaryotes and some poikilotherms during acclimation to low temperatures, is not a characteristic feature of most membranes of mammalian hibernators.

Electron-dense endoplasmic reticulum-like profiles closely associated with mitochondria in glomus cells of the carotid body after fixation with oxalate

Fixation in the presence of oxalate was used to demonstrate the electron-dense Ca2+ precipitates in the endoplasmic reticulum in glomus cells of the carotid body. Glomus cells in intact carotid bodies or cells dissociated from the organ by treatment with collagenase were studied electron microscopically. In the intact organ as well as in dissociated glomus cells, electron-dense endoplasmic reticulum-like profiles were seen closely associated with mitochondria, while these lacked reaction product. The interspace between mitochondria was occupied by electron-dense, slightly distended ER, which appeared to contact the outer membrane of the mitochondria. Occasionally, a mitochondrion was in contact with several ER profiles or the ER formed an electron-dense 'cap' on the mitochondrion. The electron-dense precipitates could be removed from ultrathin sections with the calcium chelator ethyleneglycol-2(2-aminoethyl tetra-acetic acid) (EGTA). It is tentatively suggested that the endoplasmic reticulum could be involved in intracellular buffering of Ca2+ in the glomus cell, as has been previously suggested for neurons.

An assessment of the calcium content of rat liver mitochondria in vivo

The effect of systematically altering the isolation conditions on the total calcium content of mitochondria isolated from perfused rat liver was examined. We showed that, under most isolation conditions, significant redistributions of mitochondrial calcium occurred resulting in up to 5-fold changes of the total calcium content. Mitochondrial Ca2+ flux inhibitors such as Ruthenium Red and nupercaine were only partially effective in inhibiting such redistributions. We present evidence indicating that the total calcium content of rat liver mitochondria in situ may approximate 2 nmol X (mg of protein)-1.

The effect of the energy state of mitochondria on the kinetics of unidirectional cation fluxes

Unidirectional fluxes of triphenylmethylphosphonium and of Cs+ as its valinomycin complex were studied using trace concentrations of the cations. The rate constants of influx and efflux were estimated mainly at 0 degrees C from the uptake kinetics in respiring mitochondria and the in/out ratios in the steady state. The efflux rate constants in the energized state were also measured after dilution of the mitochondrial suspension in the steady state, and in deenergized mitochondria from the efflux rates of cations after inhibition of respiration. It was found that the energy state of mitochondria had little effect on the rate constants of efflux, while the rate of influx was strongly stimulated by respiration. The former finding is not readily explained by the classical chemiosmotic theory, since a transmembrane potential, negative on the inside, formed on energization would be expected to strongly inhibit the efflux of cations. The data may be explained by a pump-and-leak model in which localized electrical fields in hydrophobic domains of the membrane are coupled to the pumping of hydrophobic cations against an electrochemical gradient, while leaks would effect efflux.

Calcium permeability of Ehrlich ascites tumour cell plasma membrane in vivo

Passive Ca2+ entry into Ehrlich ascites tumour cells has been investigated. Passive equilibrium of Ca2+ takes place in ascites tumour cells only under conditions of exhaustive energy depletion. The specific Ca2+ ionophore A23187 does not affect Ca2+ entry into ascites tumour cells under active metabolic conditions, but it increases the rate of Ca2+ equilibration in ascites tumour cells in the early stages of energy depletion. The results of the present experiments lead to the conclusion that in ascites tumour cell plasma membrane Ca2+ permeability is not a limiting step in the regulation of intracellular calcium content, while the energy-dependent Ca2+ extrusion is the main mechanism that prevents uncontrolled intracellular Ca2+ increase. The results taken together support the hypothesis that increased Ca2+ influx into the cell, caused by plasma membrane alteration, is responsible for permanently elevated mitotic activity and for deranged metabolic behavior of these neoplastic cells.