Control of the energy coupling modes in mitochondria by mercurials

Mitochondria as an important target in heavy metal toxicity in rat hepatoma AS-30D cells

The mechanisms of toxic effects of divalent cations of three heavy metals Hg, Cd and Cu in rat ascites hepatoma AS-30D cells cultivated in vitro were compared. It was found that the toxicity of these ions, applied in the micromolar range (10-500 microM), decreased from Hg(2+) (most toxic) to Cu(2+) (least toxic). Hg(2+) and Cd(2+) produced a high percentage of cell death by both necrosis and apoptosis, whereas Cu(2+) at concentrations up to 500 microM was weakly effective. Hg(2+) at concentration of 10 microM appeared slightly uncoupling (i.e., stimulated resting state respiration and decreased the mitochondrial transmembrane potential), whereas it exerted a strong inhibitory effect on the respiratory chain and rapid dissipation of the membrane potential at higher concentrations. Cu(2+) had inhibitory effect on cell respiration only at 500 microM concentration and after incubation of 48 h but produced a significant uncoupling effect at lower concentrations. Cu(2+) induced an early and sharp increase of intracellular production of reactive oxygen species (ROS). The action of Hg(2+) and Cd(2+) on ROS generation was biphasic. They stimulated ROS generation within the cells at low concentrations and at short incubation times but decreased ROS generation at higher concentrations and at longer incubation. It is concluded that mitochondria are an important target for toxic effects of Hg(2+), Cd(2+) and Cu(2+) in AS-30D rat hepatoma cells.

Ion permeability induction by the SH cross-linking reagents in rat liver mitochondria is inhibited by the free radical scavenger, butylhydroxytoluene

The hydrophobic, potentially SH cross-linking reagent, phenylarsine oxide (PhAsO), was found to induce K+ and Ca2+ effluxes from mitochondria and to accelerate the respiration rate in state 4. The hydrophobic monofunctional electrophilic agent, N-ethylmaleimide, does not exhibit this effect but prevents the action of PhAsO. The polar potentially SH cross-linking regents (arsenite, diamide) induce ion fluxes only in the presence of Pi. Ion fluxes induced by the SH reagents are inhibited by butylhydroxytoluene (an inhibitor of free radical reactions), and N,N'-dicyclohexylcarbodiimide, not by oligomycin. It is inferred that the induction of ion fluxes in mitochondria caused by cross-linking of two juxtaposed SH groups is related to the development of free radical reactions.

Phospholipids as the molecular instruments of ion and solute transport in biological membranes

Partition studies have established that phospholipids generally have the capabilities to mediate the transmembrane transport of the full range of ions and solutes that physiologically cross biological membranes. The list of transportable species includes cations, anions, amino acids, citric acid cycle intermediates, nucleotides, and sugars. Phospholipid-mediated transport can be readily modulated by altering the phospholipid mixture or by addition of detergents, nucleotides, divalent metals, proteins, peptides, or ring compounds. Containment of phospholipid within channels in protein appears to be the precondition for the formation of the micellar structure requisite for solute transport. Phospholipid-mediated transport is postulated to be a central feature of energy coupling, membrane-spanning systems, and membrane-bound, phospholipid-requiring enzymes.

Chemical models of oxidative phosphorylation

Chemical models for coupling oxidation to phosphorylation are summarized and examined both from the standpoint of organic reaction mechanisms and with respect to their relevance to mitochondria and chloroplasts. In order to accelerate the progress of our research in bioenergetics, it is suggested to focus at least as much attention on structural biochemistry as on phenomenological observations of energy-transducing membranes.

Thiols related to mitochondrial ATPase and transports: unmasking upon conformational changes supported by the comparative effects of ethacrynate and dihydroethacrynate

Comparison between the effects on various rat liver mitochondrial functions of ethacrynate, a thiol reagent inhibitor of oxidative phosphorylations [3, 4] and those of dihydroethacrynate its saturated derivative which is not a thiol reagent, has been performed. Both, ethacrynate and dihydroethacrynate increase oxygen consumption by mitochondria in state 4 (succinate as substrate) in a concentration dependent way (from 1 to 5 X 10(-4) M EA or DHEA). This activation is followed, only with ethacrynate, by an inhibition appearing sooner with higher concentrations. After preincubation or mitochondria with ethacrynate (1 to 5 X 10(-4) M), the stimulation of respiration by (ADP + Pi) is completely inhibited whereas it is only weakly affected by dihydroethacrynate at the same concentrations. Ethacrynate and dihydroethacrynate provoke variations of intramitochondrial Mg2+ and K+ levels which need energy from the respiratory chain. These are affected by Pi or (Pi + ADP) in a different way with ethacrynate and with dihydroethacrynate. After preincubation with mitochondria, ethacrynate and to a smaller extent dihydroethacrynate, inhibit partially ADP translocation; ADP increases the inhibitory effect of EA on translocation and not that of dihydroethacrynate. Ethacrynate increases the oligomycin sensitive ATPase activity and dihydroethacrynate still more. After a ten minutes preincubation with mitochondria, ethacrynate and dihydroethacrynate hardly affect the 2.4 DNP stimulated ATPase activity. Preincubation with succinate or ADP strongly increases the ethacrynate inhibition whereas it decreases dihydroethacrynate inhibition. Ethacrynate and dihydroethacrynate do not affect the efflux of Pi produced by ATP hydrolysis but ethacrynate enforces the inhibitory effect of mersalyl (Mg2+ containing medium). After ten minutes of preincubation with mitochondria, ethacrynate binds 25 nmoles of -SH/mg protein (DTNB titration) and dihydroethacrynate has no effect. These results show an effect of ethacrynate on two types of thiols linked with energy conservation mechanisms and ADP translocation. These thiols could be unmasked or made accessible by conformational modifications of the inner membrane upon energization or addition of ADP.

Energetics of low affinity amino acid transport into brain slices

It appears possible to dissect and study some of the potential energy sources for amino acid transport in brain slices despite the apparent complexity of the tissue in comparison to that of isolated bacterial vesicles23. The uptake capability of the tissue may be inadvertently damaged in some experimental protocols so that very special controls must be used to ensure that the treatment did not somehow inactivate the very mechanism that thereafter will be tested. We have presented some evidence that brain slice amino acid transport may not be obligatorily linked to glycolysis, ATP levels, Na+, K+-ATPase activity, K+ levels or direction of flux, or to Na+ flux. However, the energy source linkage for different amino acids appears to be rather specific, so that further generalizations are difficult to sustain. For instance, the incubation media and conditions we describe here were experimentally adjusted to maximize uptake of D-glu or alpha-AIB in the absence of glucose, or in lowered K+ or Na+. Therefore, these procedures, the results of which directly challenge some common assumptions regarding the energy basis for active transport in brain slices, probably will not be universally extensible to all other actively transported amino acids.

Role of ionophores in energy coupling

If, as we deem inevitable, the principles of energy coupling are universal, then the necessity for charge-separating devices will apply across the board to all bioenergetic systems. Since, apart from the elctron transfer chain, ionophores are the only charge-separating devices available in bioenergetic systems, model of energy coupling that does not feature this central role of ionophores can be taken seriously. The ionophore approach thus opens the royal highway to the ultimate solution of all bioenergetic problems.

Paired moving charge model of energy coupling. III. Intrinsic ionophores in energy coupling systems

The experimental basis for the postulated role of intrinsic ionophores in mitochondrial ion transport and energy coupling is summarized. Intrinsic ionophores appear to be linked to, or contained within, specific ionophoroproteins localized in the inner membrane, and the isolation of these ionophores requires their release from the ionophoroproteins. At least ten different species of ionophores have been isolated from the mitochondrion, five of which have been wholly or in part chemically identified. Intrinsic ionophores have been implicated in the activation of inorganic phosphate in ATP synthesis and hydrolysis, and in the contol of the coupling modes. The presence of ionophores in soluble proteins such as troponin and in ATP-energized kinases has been demonstrated.