The effect of calcium on the respiratory responses of corn mitochondria.

Tightly coupled respiring corn mitochondria (Zea mays L.) respond to calcium addition with a transitory respiratory increase, proton extrusion, and Ca2+ binding. The extent of response is dependent upon the level of endogenous phosphate, and a large sustained respiratory increase can be obtained with addition of phosphate. However, calcium does not act as a permeant cation in that it will not penetrate with acetate. It appears that the transitory respiratory increase must be linked to the uptake of a calcium phosphate complex, but there is no evidence that transport of the complex serves to produce an electrophoretic calcium uniport. It is believed that calcium phosphate transport in corn is a constitutive property, and not produced by membrane damage.     

Oxidation of reduced nicotinamide adenine dinucleotide phosphate by isolated corn mitochondria

Isolated corn (Zea mays L.) mitochondria were found to oxidize reduced nicotinamide adenine dinucleotide phosphate in a KCl reaction medium. This oxidation was dependent on the presence of calcium or phosphate or both. Strontium and manganese substituted for calcium, but magnesium or barium did not. The oxidation of NADPH produced contraction of mitochondria swollen in KCl. Further evidence that the oxidation of NADPH was coupled was observed in respiratory control and adenosine diphosphate-oxygen ratios that were comparable to those reported for reduced nicotinamide adenine dinucleotide. The pathways of electron flow from NADH and NADPH were compared through the addition of electron transport inhibitors. The only difference between the two dinucleotides was that amytal was found to inhibit almost totally the state 3 oxidation of NADPH, but had little effect on the state 3 oxidation of NADH. The hypothetical pathways for electron flow from NADPH are discussed, as are the possible sites of calcium and phosphate stimulation.     

Inhibition of postoxidative calcium release in corn mitochondria by inorganic phosphate

Respiration drives the accumulation of a small amount of calcium in corn (Zea mays L.) mitochondria, and this calcium is released when respiration ceases. A postenergized addition of phosphate leads to phosphate uptake and enhaced calcium retention. Oligomycin, KCN, 2,4-dinitrophenol, or mersalyl are without effect on the phosphate-induced calcium retention. Addition of phosphate also inhibits the release of endogenous phosphate which normally accompanies the calcium. It is suggested that passive phosphate uptake retards the release of endogenous phosphate which is complexed with the calcium.     

Effects of calcium and lanthanum on phosphate efflux from nonmyelinated nerve fibers

Summary Phosphate efflux was measured as the fractional rate of loss of radioactivity from rabbit vagus loaded with radiophosphate. The effects of changes in extracellular calcium and of lanthanum have been investigated. In Locke solution with normal, 0.9mm, calcium and without phosphate, the fractional rate of loss was 1.62×10^–3 min^–1 at 120 min after the beginning of the washing period and fell slowly (9% hr^–1) during washing from 2 to 6 hr. Addition of calcium to the Locke solution produced a transient increase followed by a reversible maintained increase in phosphate efflux. The latter was 40 and 75% above efflux in normal calcium for 20 and 50mm calcium, respectively. Removal of calcium, with or without addition of EGTA, produced only a transient increase in phosphate efflux, with no subsequent maintained change. Addition of low concentrations of lanthanum produced a reversible inhibition of phosphate efflux. Half-maximal inhibition was at 3.5 m lanthanum and appeared to be due to binding of lanthanum to more than one, probably two, sites. Measurements of inhibition by lanthanum at different calcium concentrations did not indicate any competition between calcium and lanthanum. It is suggested that at least a part of phosphate efflux depends on internal calcium and that lanthanum acts by preventing release of phosphate from the phosphate transport mechanism.     

Regulation of the reconstituted chloroplast phosphate translocator by an H+ gradient

This report describes the influence of ΔpH on the transport of phosphate, triose phosphate and 3-phosphoglycerate catalyzed by the phosphate translocator in a reconstituted system. The H⁺ gradient across the liposome membrane is adjusted by the addition of external buffer solution and maintained for several minutes. The following results are obtained: (1) An inward directed H⁺ gradient leads to an increase of 3-phosphoglycerate transport and to a decrease of phosphate and triose phosphate transport. (2) An H⁺ gradient in the opposite direction results in a restriction of 3-phosphoglycerate influx whereas the influx of phosphate and triose phosphate is enhanced. (3) The magnitude of the pH effect depends on the internal substrate. Compared to the homoexchange mode, the effect of applied ΔpH is more pronounced in the heteroexchange mode. (4) Transport of phosphate and 3-phosphoglycerate is influenced by ΔpH in a different manner. In the case of phosphate and triose phosphate transport the observed effects are associated with changes in the apparent K_m values whereas in the case of 3-phosphoglycerate transport the application of a pH gradient is linked to a change of V_max. (5) In competition experiments with both substrates in the external medium, ΔpH influences the effect of phosphate as a competitive inhibitor of 3-phosphoglycerate transport whereas the effect of 3-phosphoglycerate on phosphate transport is not affected by a pH gradient. (6) The measured apparent K_m and V_max values under the influence of ΔpH can be used for the calculation of substrate fluxes across the envelope during illumination. It can be demonstrated that the increase of stromal pH in the light gives rise to a considerable change in the ratio of the substrates transported. Under conditions without pH gradient, the species transported out is mainly 3-phosphoglycerate and the species transported in is mainly triose phosphate. These fluxes are reversed when a pH gradient is applied (light conditions).     

Phosphate absorption rates and adenosine 5'-triphosphate concentrations in corn root tissue

The correlations between ATP concentration in corn (Zea mays) root tissue and the rate of phosphate absorption by the tissue have been examined. Experimental variation was secured with 2,4-dinitrophenol, oligomycin, mersalyl, l-ethionine, 2-deoxyglucose, N₂ gassing and inhibition of protein synthesis. It is concluded that ATP could be the energy source for potassium phosphate absorption, but only if the transport mechanism possesses certain properties: oligomycin-sensitivity; creation of a proton gradient susceptible to collapse by uncouplers; phosphate transport via a mersalyl-sensitive Pi⁻-OH⁻ transporter; good activity at energy charge as low as 0.4; short enzymatic half-life for the ATPase or phosphate transporter; a linked mechanism for K⁺-H⁺ exchange transport, possibly electrogenic.     

Potassium and Phosphate Uptake in Corn Roots: Further Evidence for an Electrogenic H/K Exchanger and an OH/Pi Antiporter

Evidence is presented that K⁺ uptake in corn root segments is coupled to an electrogenic H⁺/K⁺ -exchanging plasmalemma ATPase while phosphate uptake is coupled to an OH⁻/Pi antiporter. The plasmalemma ATPase inhibitor, diethylstilbestrol, or the stimulator, fusicoccin, altered K⁺ uptake directly and phosphate uptake indirectly. On the other hand, mersalyl, an OH⁻/Pi antiporter inhibitor, inhibited phosphate uptake instantly but only slightly affected K⁺ uptake. Collapse of the proton gradient across the membrane by (p-trifluoromethoxy) carbonyl cyanide phenylhydrazone resulted in immediate inhibition of K⁺ uptake but only later inhibited phosphate uptake. Changing the pH of the absorption solution had opposite effects on K⁺ and phosphate uptake. In addition, a 4-hour washing of corn root tissue induced a 5-fold increase in the rate of K⁺ uptake with little or no lag, but only a 2- to 3-fold increase in phosphate uptake with a 30- to 45-minute lag. Collectively these differences strongly support the coupling of an electrogenic H⁺/K⁺ -exchanging ATPase to an OH⁻/Pi antiporter in corn root tissue.     

Effects of monovalent cations on derepression of phosphate transport in yeast

The effect of monovalent cations on derepression of phosphate transport was studied. It was found that ammonium, K⁺ and Rb⁺ accelerate the derepression of phosphate transport produced by glucose in yeast (Saccharomyces cerevisiae). Na⁺ and Li⁺ were ineffective in accelerating derepression; Cs⁺ produced only a minor stimulation. The concentration range of both K⁺ and NH₄⁺ that accelerated derepression was similar to that required for transport to occur. In the case of ammonium, the effects seem to depend exclusively on the so-called low-affinity transport system. The effect was strongly dependent on pH, with an optimum around 6; however, the increase in the pH of the medium did not produce in itself a high increase of the depression. Derepression was dependent on the presence of glucose, and it was very low with ethanol as substrate. The mechanism seems to depend on the ability that both K⁺ and NH₄⁺ have to decrease the membrane potential of the cell while transported, and not on the capacity to produce the alkalinization of the cell interior. In addition, the phenomenon depends on the presence of glucose as substrate, which indicates the involvement of some product of glucose metabolism in the mechanism, and possibly some relation to catabolic repression.     

The Deactive Form of Respiratory Complex I from Mammalian Mitochondria Is a Na+/H+ Antiporter

In mitochondria, complex I (NADH:ubiquinone oxidoreductase) uses the redox potential energy from NADH oxidation by ubiquinone to transport protons across the inner membrane, contributing to the proton-motive force. However, in some prokaryotes, complex I may transport sodium ions instead, and three subunits in the membrane domain of complex I are closely related to subunits from the Mrp family of Na⁺/H⁺ antiporters. Here, we define the relationship between complex I from Bos taurus heart mitochondria, a close model for the human enzyme, and sodium ion transport across the mitochondrial inner membrane. In accord with current consensus, we exclude the possibility of redox-coupled Na⁺ transport by B. taurus complex I. Instead, we show that the “deactive” form of complex I, which is formed spontaneously when enzyme turnover is precluded by lack of substrates, is a Na⁺/H⁺ antiporter. The antiporter activity is abolished upon reactivation by the addition of substrates and by the complex I inhibitor rotenone. It is specific for Na⁺ over K⁺, and it is not exhibited by complex I from the yeast Yarrowia lipolytica, which thus has a less extensive deactive transition. We propose that the functional connection between the redox and transporter modules of complex I is broken in the deactive state, allowing the transport module to assert its independent properties. The deactive state of complex I is formed during hypoxia, when respiratory chain turnover is slowed, and may contribute to determining the outcome of ischemia-reperfusion injury.     

Respiratory activation of 2,4-dinitrophenol-stimulated ATPase activity in plant mitochondria

A comparison has been made of cauliflower mitochondria, which have no 2,4-dinitrophenol-stimulated ATPase (EC 3,6,1,4), with corn mitochondria, which do. Unlike corn mitochondria, cauliflower mitochondria show poor initial respiratory control ratios and phosphate uptake, but these are normalized after the first ADP addition. Sonication or high pH treatment releases a high rate of oligomycin-sensitive ATPase, indicating ATP transport into cauliflower mitochondria is the limiting factor. A brief period of respiration will activate, or “prime,” the 2,4-dinitrophenol-stimulated ATPase of cauliflower mitochondria, and the activity is inhibited by atractyloside, mersalyl, and oligomycin. Influx pumping of phosphate or arsenate extends the time the priming period lasts after respiration ceases to 1–2 min unless the 2,4-dinitrophenol is added before the ATP, in which case the priming is collapsed. Respiratory priming seems to consist of creating a transmembrane potential, possibly in the form of a phosphate gradient, for driving the ATP^4?-ADP^3? transporter.     

Calcium and pancreatic β-cell function: 4. Evidence that glucose and phosphate stimulate calcium-45 incorporation into different intracellular pools

β-Cell-rich pancreatic islets were microdissected from ob/ob-mice and used for studies of ⁴⁵Ca uptake and washout. Irrespective of whether the experiments were performed at 21 or 37°C both glucose and phosphate stimulated the net uptake of lanthanum-nondisplaceable ⁴⁵Ca. The stimulatory effect of phosphate was additive to that produced by glucose. ⁴⁵Ca incorporated in response to phosphate differed from that taken up in the presence of 20 mM glucose in being easily washed out although it was not affected by the glucose concentration of the washing medium. The efflux of ⁴⁵Ca was reduced after introducing phosphate into a medium used to perifuse islets which had accumulated ⁴⁵Ca in response to 20 mM glucose. This suggests that the outward calcium transport can be influenced also by intracellular trapping of the cation. The glucose-stimulated insulin release was inhibited by phosphate; an effect reversed by the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine. It is concluded that a common effect of glucose and phosphate is to trap calcium in the pancreatic β-cells but that there are fundamental differences between their effects on intracellular distribution of calcium and on insulin release.     

Characterization of energy-dependent ca transport in maize mitochondria

Experimental conditions which optimize both substrate- and ATP-dependent Ca²⁺ transport in corn (Zea mays) mitochondria have been determined. It has been found that a substrate (pyruvate + succinate) dependent, Pi independent, binding of Ca²⁺ occurs. This reaction is very rapid and complete in less than 30 seconds. For massive accumulation of calcium, Pi is essential. Phosphate is accumulated along with the calcium and the ratio of Ca:Pi accumulated is about 1.6:1 indicating the precipitation of hydroxyapatite inside the mitochondria.

The activation energies and Michaelis constants for both the substrate- and ATP-driven reactions have been determined. It has also been shown that the substrate-driven system is more efficient in Ca²⁺ accumulation than the ATP-driven system. This is partially due to the fact that Mg²⁺ is essential for the ATP-driven system but not for the substrate-driven system and that Mg²⁺ acts as a strong competitor of Ca²⁺ transport. The effect of other inorganic ions on Ca²⁺ transport energized by both substrate and ATP were examined.

The results lend support to the hypothesis that high energy intermediates of oxidative phosphorylation participate directly in Ca²⁺ binding and transport in plant mitochondria.

     

Calcium transport by corn mitochondria : evaluation of the role of phosphate

Mitochondria from some plant tissues possess the ability to take up Ca²⁺ by a phosphate-dependent mechanism associated with a decrease in membrane potential, H⁺ extrusion, and increase in the rate of respiration (AE Vercesi, L Pereira da Silva, IS Martins, CF Bernardes, EGS Carnieri, MM Fagian [1989] In G Fiskum, ed, Cell Calcium Metabolism. Plenum Press, New York, pp 103-111). The present study reexamined the nature of the phosphate requirement in this process. The main observations are: (a) Respiration-coupled Ca²⁺ uptake by isolated corn (Zea mays var Maya Normal) mitochondria or carbonyl cyanide p-trifluoromethoxyphenylhydrazone-induced efflux of the cation from such mitochondria are sensitive to mersalyl and cannot be dissociated from the silmultaneous movement of phosphate in the same direction. (b) Ruthenium red-induced efflux is not affected by mersalyl and can occur in the absence of phosphate movement. (c) In Ca²⁺-loaded corn mitochondria, mersalyl causes net Ca²⁺ release unrelated to a decrease in membrane potential, probably due to an inhibition of Ca²⁺ cycling at the level of the influx pathway. It is concluded that corn mitochondria (and probably other plant mitochondria) do possess an electrophoretic influx pathway that appears to be a mersalyl-sensitive Ca²⁺/inorganic phosphate-symporter and a phosphate-independent efflux pathway possibly similar to the Na²⁺-independent Ca²⁺ efflux mechanism of vertebrate mitochondria, because it is not stimulated by Na⁺.     

Phosphate transport in membrane vesicles from Escherichia coli

Escherichia coli strain AN710 possesses only the PIT system for phosphate transport. Membrane vesicles from this strain, which contain phosphate internally, perform exchange and active transport of phosphate. The energy for active transport is supplied by the respiratory chain with ascorbate-phenazine methosulphate as electron donor. To a lesser extent also the oxidation of d-lactate energizes phosphate transport; the oxidation of succinate is only marginally effective. Phosphate transport is driven by the proton-motive force and in particular by the pH gradient across the membrane. This view is supported by the observation that phosphate transport is stimulated by valinomycin, inhibited by nigericin and abolished by the uncoupler carbonyl cyanide m-chlorophenylhydrazone. Neither inhibitor affects phosphate exchange. The phosphate analogue arsenate inhibits both the exchange reaction and active transport. Both processes are stimulated by K⁺ and Mg²⁺, the highest activities being observed with both ions present.Membrane vesicles have also been isolated from Escherichia coli K10, a strain which possesses only a functional PST phosphate transport system. These vesicles perform neither exchange nor active transport of phosphate, although active transport of amino acids is observed in the presence of ascorbate-phenazine methosulphate or d-lactate.     

Stimulation of EAAC1 in C6 glioma cells by store-operated calcium influx

This study investigated how modulation of intracellular calcium alters the functional activity of the EAAC1 glutamate transporter in C6 glioma cells. Pre-incubation of C6 glioma cells with the endoplasmic reticulum Ca²⁺ ATP pump inhibitor, thapsigargin (10 μM) produced a time-dependent increase in the V_max for d-[³H]aspartate transport that reached a maximum at 15 min (143% of control; P < 0.001) that was accompanied by increased plasma membrane expression of EAAC1 and was blocked by inhibition of protein kinase C. Pre-incubation of C6 glioma cells with phorbol myristate-3-acetate (100 nM for 20 min) also caused a significant increase in the V_max of sodium-dependent d-[³H]aspartate transport (190% of control; P < 0.01). In contrast, in the absence of extracellular calcium, thapsigargin caused a significant inhibition in d-[³H]aspartate transport that was not mediated by protein kinase C. Blockade of store-operated calcium channels with 2-aminoethoxydiphenyl borate (50 μM) or SKF 96365 (10 μM) caused a net inhibition of d-[³H]aspartate uptake. Co-incubation of C6 glioma cells with both thapsigargin and 2-aminoethoxydiphenyl borate (but not SKF 96365) prevented the increase in d-[³H]aspartate transport that was observed in the presence of thapsigargin alone. Furthermore, 2-aminoethoxydiphenyl borate, but not SKF 96365, reduced the increase in intracellular calcium that occurred following pre-incubation of the cells with thapsigargin. It is concluded that, in C6 glioma cells, stimulation of EAAC1-mediated glutamate transport by thapsigargin is dependent on entry of calcium via the NSCC-1 subtype of store operated calcium channel and is mediated by protein kinase C. In contrast, in the absence of store operated calcium entry, thapsigargin inhibits transport.     

Effects of Cations on Hormone Transport in Primary Roots of Zea mays

We examined the influence of aluminum and calcium (and certain other cations) on hormone transport in corn roots. When aluminum was applied unilaterally to the caps of 15 mm apical root sections the roots curved strongly away from the aluminum. When aluminum was applied unilaterally to the cap and ³H-indole-3-acetic acid was applied to the basal cut surface twice as much radioactivity (assumed to be IAA) accumulated on the concave side of the curved root as on the convex side. Auxin transport in the apical region of intact roots was preferentially basipetal, with a polarity (basipetal transport divided by acropetal transport) of 6.3. In decapped 5 mm apical root segments, auxin transport was acropetally polar (polarity = 0.63). Application of aluminum to the root cap strongly promoted acropetal transport of auxin reducing polarity from 6.3 to 2.1. Application of calcium to the root cap enhanced basipetal movement of auxin, increasing polarity from 6.3 to 7.6. Application of the calcium chelator, ethylene-glycol-bis-(β-aminoethylether)-N,N,N′, N′-tetraacetic acid, greatly decreased basipetal auxin movement, reducing polarity from 6.3 to 3.7. Transport of label after application of tritiated abscisic acid showed no polarity and was not affected by calcium or aluminum. The results indicate that the root cap is particularly important in maintaining basipetal polarity of auxin transport in primary roots of corn. The induction of root curvature by unilateral application of aluminum or calcium to root caps is likely to result from localized effects of these ions on auxin transport. The findings are discussed relative to the possible role of calcium redistribution in the gravitropic curvature of roots and the possibility of calmodulin involvement in the action of calcium and aluminum on auxin transport.     

Active Calcium and Strontium Transport in Human Erythrocyte Ghosts

Both calcium and strontium could be transported actively from erythrocytes if adenosine triphosphate, guanosine triphosphate, or inosine triphosphate were included in the hypotonic medium used to infuse calcium or strontium into the cells. Acetyl phosphate and pyrophosphate were not energy sources for the transport of either ion. Neither calcium nor strontium transport was accompanied by magnesium exchange, and the addition of Mg⁺⁺ to the reaction medium in a final concentration of 3.0 mmoles/liter did not promote the transport of either ion. In the absence of nucleotide triphosphates, the addition of 1.5 mmoles/liter of Sr⁺⁺ to the reaction solution did not bring about active calcium transport and similarly 1.5 mmoles/liter of Ca⁺⁺ did not bring about active strontium transport. The inclusion of 1.5 mmoles/liter of Ca⁺⁺ or Sr⁺⁺ in the reaction medium did not interfere with the transport of the other ion when the erythrocytes were infused with adenosine triphosphate.     

Purification, molecular weight, amino acid, and subunit composition of arylsulfatase A from human liver.

In isolated hepatic mitochondria, the oxidation of NAD⁺-dependent substrates was decreased after chronic consumption of ethanol or by the addition of acetaldehyde in vitro. Reversed electron transport from succinate to NAD^?, which requires transfer of electrons through the NADH dehydrogenase complex and energy transduction through coupling site 1, was depressed by ethanol feeding and by acetaldehyde in vitro, whereas NADH formation from glutamate, which is mediated directly by substrate oxidation and is not energy-dependent, was slightly increased. By contrast, reactions involving the terminal portion of the phosphorylation chain, e.g., ATP-³²P exchange or dinitrophenolstimulated ATPase activity, were not affected. Adenine nucleotide translocase activity was not altered by chronic consumption of ethanol or the addition of acetaldehyde in vitro. These data suggest that the NADH-ubiquinone oxidoreductase complex of the respiratory chain, a segment which contains several iron-sulfur centers which participate in electron transport and energy transduction, may be impaired by chronic consumption of ethanol and is especially sensitive to inhibition by acetaldehyde in vitro. Neither energy coupling sites II or III, nor the terminal reactions of oxidative phosphorylation share this sensitivity. CO₂ production from various labeled intermediates of the citric acid cycle was depressed after chronic consumption of ethanol and after the addition of acetaldehyde. Acetate had no effect on these reactions, indicating that the inhibition by acetaldehyde is not mediated via acetate. Impairment of the activities of the respiratory chain and the citric acid cycle, or both, may explain the decreases in oxygen uptake and CO₂ production from citric acid cycle intermediates and fatty acids, as well as the increase in ketone body production, found in mitochondria from ethanolfed rats.     

The action of valinomycin in uncoupling corn mitochondria

Valinomycin in the presence of potassium is a potent uncoupler of corn (Zea mays L.) mitochondria, eliminating respiratory control. Valinomycin produces higher steady state potassium phosphate swelling which can be reversed to give active shrinkage if mersalyl is added to block the Pi⁻/OH⁻ antiporter. Respiration declines concurrently. Uncouplers accelerate the shrinkage and restore the respiration. The same results can be obtained with sodium phosphate if gramicidin D is substituted as ionophore.     

Reaction of Local Anesthetics with Phospholipids : A possible chemical basis for anesthesia

Local anesthetics (LA) have been found to interact with phospholipids and lipids extracted from nerve and muscle. This reaction is demonstrated by: (a) Inhibition by LA of phospholipid (and tissue lipid) facilitated transport of calcium from a methanol: water phase into chloroform. This action is dependent upon the cationic form of the LA. (b) LA increase the electrical resistance of "membranes" prepared by impregnating Millipore filters with cephalin:cholesterol or tissue lipid extracts and bathed with NaCl or KCl solutions. (c) LA coagulate aqueous dispersions of cephalin, phosphatidyl serine, phosphatidyl ethanolamine, and inositide, an action shared by calcium. The order of potency in coagulating cephalin sols is tetracaine > calcium > butacaine > procaine. Na⁺ and K⁺ do not coagulate phospholipid dispersions at 0.1 M concentration and antagonize the effect of Ca²⁺. (d) LA produce a marked fall in the pH of cephalin sols equivalent to that produced by calcium, (e) Ca²⁺ and LA form 1:2 molar complexes with phospholipids probably by ion-ion and ion-induced polar type of binding at the phosphate groups of the lipid. It is suggested that such reactions with cell membrane phospholipids may underlie inhibitory effects of LA on cellular ion fluxes and provide a chemical basis for anesthetic action.