Adenine nucleotide translocation in yeast mitochondria. Effect of inhibitors of mitochondrial biogenesis on the ADP translocase

1. Optimal test conditions for adenine nucleotide translocation in Candida utilis mitochondria are a standard medium, consisting of 0.63 M mannitol, 2 mM EDTA (or ethylene glycol tetraacetic acid, EGTA), 10 mM morpholinopropane sulfonic acid (pH 6.8), and a temperature of 0 °C.

2. Adenine nucleotide translocation in C. utilis mitochondria is an exchange-diffusion process. The whole pool of internal adenine nucleotides is exchangeable, ADP being the most readily exchangeable nucleotide. The rate of mitochondrial ADP exchange, but not the K_m value, depends on growth conditions. At 0 °C, the rate is about 3 to 4 nmoles ADP/min per mg protein for mitochondria obtained from yeast grown in the presence of 1.5% glucose; it rises to 11.5 nmoles when glucose is replaced by 3% ethanol in the growth medium. The K_m value for ADP is 2 μM. The Q₁₀ is about 2 between 0 and 20 °C. Among other exchangeable adenine nucleotides are ATP, dADP and the methylene and the hypophosphate analogues of ADP. Unlike mammalian mitochondria, C. utilis mitochondria are able to transport external UDP by a carboxyatractyloside-sensitive process.

3. Under conditions of oxidative phosphorylation (phosphate and substrate present in an aerated medium), added ADP is exchanged with internal ATP. A higher ATP/ADP ratio was found in the extramitochondrial space than in the intramito-chondrial space. The difference between the calculated phosphate potentials in the two spaces was 0.9–1.7 kcal/mole.

4. Atractyloside, carboxyatractyloside, bongkrekic acid and palmityl-CoA inhibit mitochondrial adenine nucleotide translocation in C. utilis as they do in mammalian mitochondria, but 2 to 4 times less efficiently. The inhibition due to atractyloside or palmityl-CoA is competitive with respect to ADP whereas that due to bongkrekic acid and carboxyatractyloside is non-competitive. Carboxyatractyloside and atractyloside inhibitions are additive. The apparent K_d for the binding of [³⁵S]-carboxyatractyloside and [¹⁴C]bongkrekic acid is 10–15 nM and the concentration of sites 0.4–0.6 nmole/mg protein in both cases. [³⁵S]Carboxyatractyloside binding is competitively displaced by atractyloside and vice versa.

5. Binding of [¹⁴C]ADP has been carried out with mitochondria depleted of their endogenous adenine nucleotides by incubation with phosphate and Mg²⁺ at 20 °C. The amount of bound [¹⁴C]ADP which is atractyloside removable is 0.08–0.16 nmole/mg protein.

6. The rate of ADP transport is quite different in mitochondria isolated from C. utilis, according to whether it is grown on glucose, or on ethanol or in the presence of chloramphenicol; for instance, it decreases by 10 times when 3% ethanol in the growth medium is replaced by 10% glucose and by 5 times when chloramphenicol is added to the medium. These variations are accompanied by parallel variations in cytochrome aa₃. The number of atractyloside-sensitive ADP binding sites is not modified by the above conditions of culture, nor the number of [³⁵S]carboxyatractyloside binding sites. The affinity for ADP is apparently not significantly modified, nor the size of the endogenous adenine nucleotide pool. In contrast to glucose repression or chloramphenicol inhibition, semi-anaerobiosis in C. utilis lowers significantly the mitochondrial binding capacity for carboxyatractyloside. Strict anaerobiosis in S. cerevisiae results in a practical loss of the cytochrome oxidase activity, and also of the carboxyatractyloside and ADP binding capacity. Transition from anaerobiosis to aerobiosis restores the cytochrome oxidase activity and the ADP and carboxyatractyloside binding capacities.     

Adenine nucleotide transport in sonic submitochondrial particles. Kinetic properties and binding of specific inhibitors.

1. A procedure for preparation of sonic submitochondrial particles competent for adenine nucleotide transport is described. ADP or ATP transport was assayed, in the presence of oligomycin, in a saline medium made of 0.125 M KCl, 1 mM EDTA, 10 mM 4-morpholinopropane sulfonic acid buffer, pH 6.5. 2. Sonic particles transport ADP and ATP by an exchange diffusion process. Externally added ADP (or ATP) is exchanged with internal ADP and ATP with a stoichiometry of one to one. The V value for ADP transport 5 degrees C was between 2 and 3 nmol/min per mg protein. 3. The transport system in sonic particles is specific for ADP and ATP. It is strongly dependent on temperature. The activation energy between 0 and 9 degrees C is approx. 35 kcal/mol. The optimum pH is 6.5, 4, Like in intact mitochondria, externally added ADP is transported into sonic particles faster at a given concentration than externally added ATP. The V value for ADP transport is 1.5-2 times higher than the V value for ATP transport. 5. The transition from the energized to the deenergized state in sonic particles results in a decrease of the pH gradient across the membrane (internal pH less than external pH) and in a 2-4 fold increase in the Km value for ATP. This latter effect is opposite that found for transport of added ATP in intact mitochondria (Souverijn, J.H.M., Huisman, L.A., Rosing J. and Kemp, Jr., A. (1973) Biochim. Biophys. Acta 305, 185-198). Energization has no effect on the V value of ATP transport in sonic particles. 6. In contrast to intact mitochondria, inhibition of ADP transport in sonic particles by bongkrekic acid does not have any lag-time and does not depend on pH. The inhibition caused by bongkrekic acid is a mixed type inhibition with a Ki value of 1.2 micronM. Atractyloside and carboxyatractyloside do not inhibit ADP transport in sonic particles, unless the particles have been preloaded with these inhibitors during the sonication. 7. Palmityl-CoA added to sonic particles inhibits efficiently ADP transport. The mixed type inhibition found with palmityl-CoA has a Ki value of 1.6 micronM. 8. [3H]Bongkrekic acid binds to sonic particles readily and with high affinity. Bongkrekic acic binding to sonic particles does not depend on pH and it has a saturation plateau, corresponding approximately to 1.3 mol of site per mol of cytochrome a. The number of [3H]atracytloside binding sites is much lower (one-fifth of the bongkrekic acid). External carboxyatractyloside does not compete with [3H]bongkrekic acid for binding to sonic particles. However, when carboxyatractyloside is present inside the particles, it inhibits the binding of [3H]bongkrekic acid.     

Characterization of nucleotide binding sites on the membrane-bound chloroplast ATP synthase (coupling factor CF1)

Phosphorylation of ADP and nucleotide exchange by membrane-bound coupling factor CF₁ are very fast reactions in the light, so that a direct comparison of both reactions is difficult. By adding substrate ADP and phosphate to illuminated thylakoids together with the uncoupler FCCP, the phosphorylation time is limited and the amount of ATP formed can be reduced to less than 1 ATP per enzyme. Low concentrations of medium nucleotides during illumination increase the amount of ATP formed during uncoupling presumably by binding to the tight nucleotide binding site (further designated as ‘site A’) with an affinity of 1 to 7 μM for ADP and ATP. ATP formation itself shows half-saturation at about 30 μM. Loosely bound nucleotides are exchanged upon addition of nucleotides with uncoupler (Schumann, J. (1984) Biochim. Biophys. Acta 766, 334–342). Release depends binding of nucleotides to a second site. The affinity of this site for ADP (in the presence of phosphate) is about 30 μM. It is assumed that phosphorylation and induction of exchange both occur on the same site (site B). During ATP hydrolysis, an ATP molecule is bound to site A, while on another site, ATP is hydrolyzed rapidly. The affinity of ADP for the catalytic site (70 μM) is in the same range as the observed Michaelis constant of ADP during phosphorylation; it is assumed that site B is involved in ATP hydrolysis. Site A exhibits some catalytic activity; it might be that site A is involved in ATP formation in a dual-site mechanism. For ATP hydrolysis, however, direct determination of exchange rates showed that the exchange rate of ATP bound to site A is about 30-times lower than ATP hydrolysis under the same conditions.     

Fuscin, an inhibitor of mitochondrial SH-dependent transport-linked functions

1. 1. Fuscin, a mould metabolite, is a colored quinonoid compound which reacts readily with −SH groups to give colorless addition derivatives.

2. 2. Binding of fuscin to mitochondria has been monitored spectrophotometrically. Fuscin binding is prevented by −SH reagents such as N-ehylmaleimide, N-Methylmaleimide, mersalyl or p-chloromercuribenzoate. Conversely, fuscin prevents the binding of −SH reagents as shown with N-[¹⁴C]ethylmaleimide. Once bound to mitochondria, fuscin is not removable by washing of mitochondria.

3. 3. High affinity-fuscin binding sites (K_d = 1 μM, N = 4–8 nmoles/mg protein) are present in whole mitochondria obtained from rat heart, rat liver, pigeon heart or yeast (Candida utilis). They are lost upon sonication but are still present in digitonin inner membrane + matrix vesicles. On the other hand, lysis of mitochondria by Triton X-100 does not increase the number of high affinity binding sites indicating that all these sites are accessible to fuscin in whole mitochondria. The number of fuscin high affinity sites appears to correlate with the glutathione content of mitochondrial preparations.

4. 4. Fuscin as well as N-ethylmaleimide and avenaciolide are penetrant SH-reagents;

5. 5. Fuscin interferes with the ADP-stimulated respiration of mitochondria on NAD-linked substrates, several functions of the mitochondrial respiratory apparatus being inhibited by fuscin in a non-competitive manner, but to various extents: (a) The electron transfer chain (K_i in the range of 0.1 mM); (b) the lipoamide dehydrogenase system (K_i = 5–10 μM); (c) the transport systems of phosphate (K_i ≈ 20 μM) and of glutamate (K_i = 3–5 μM); (d) the ADP transport, indirectly (K_i ≈ 10 μM).

6. 6. Like N-ethylmaleimide, fuscin inhibits the glutamate-OH⁻ carrier, the inhibition of that carrier bringing about an apparent increase of aspartate entry in glutamate-loaded mitochondria by the glutamate-aspartate carrier.

7. 7. The inhibition of phosphate transport by fuscin probably accounts for the inhibition of the reduction of endogenous NAD by succinate in intact pigeon heart mitochondria.

8. 8. By binding the −SH groups of mitochondrial membrane specifically unmasked by addition of micromolar amounts of ADP, fuscin, like N-ethylmaleimide, prevents the functioning of ADP translocation.

9. 9. Because of their specific and analogous effects on some well defined mitochondrial functions such as glutamate transport and ADP transport, fuscin and N-ethylmaleimide can be distinguished from other −SH reagents. The lipophilic nature of fuscin and N-ethylmaleimide which accounts for the accessbility of these compounds to hydrophobic sites in the mitochondrial membrane or on the matrix side of this membrane may be partly responsible for their characteristic inhibitory effects on mitochondrial functions.

The (Na + K)-dependent ATPase: mode of inhibition of ADP/ATP exchange activity by MgCl2

Na⁺-dependent ADP/ATP exchange activity, of a (Na⁺ + K⁺)-dependent ATPase preparation from eel electric organ, was measured in terms of the incorporation of ¹⁴C into ATP during incubations with unlabeled ATP and [¹⁴C]ADP. Estimates of initial rates of exchange were possible by keeping changes in nucleotide concentrations, from both exchange and extraneous hydrolytic processes, to less than 10%. Under these conditions, increases in MgCl₂ concentration, from 0.2 to 3 mM, generally inhibited this exchange activity. The concentrations of free Mg²⁺, Mg · ATP, and Mg · ADP present, with a range of MgCl₂, ATP, and ADP concentrations, were calculated from measured dissociation constants. Inhibition was associated with Mg · ATP as well as with Mg²⁺, at concentrations from 0.4 to 1 mM (Mg · ADP, in the same concentration range, probably inhibited also). The affinity of the enzyme for these inhibitors is in fair correspondence with demonstrated affinities for Mg²⁺, Mg · ATP, and Mg · ADP at low affinity substrate sites, measured kinetically. These observations are considered in terms of a dimeric enzyme with high and low affinity substrates sites: ADP/ATP exchange being catalyzed at the high affinity sites, with inhibition occurring through occupancy by Mg²⁺, Mg · ATP, or Mg · ADP, of the low affinity sites, thereby pulling the reaction process away from those steps involved in exchange.     

Binding of radioactively labeled carboxyatractyloside, atractyloside and bongkrekic acid to the ADP translocator of potato mitochondria

1. 1. The inhibition of the ADP-stimulated respiration of potato mitochondria by carboxyatractyloside is relieved by high concentration of ADP or by the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP). Atractyloside is a much less potent inhibitor than carboxyatractyloside. The inhibition of the ADP-stimulated respiration required about 60-times more atractyloside than carboxyatractyloside.

2. 2. [³⁵S]carboxyatractyloside and [³H]bongkrekic acid bind to potato mitochondria with high affinity (K_d = 10 to 20 nM, n = 0.6–0.7 nmol per mg protein). Added ADP competes with carboxyatractyloside for binding; on the contrary ADP increases the amount of bound bongkrekic acid. [³H]atractyloside binds to potato mitochondria with a much lower affinity (K_d = 0.45 μM) than carboxyatractyloside or bongkrekic acid.

3. 3. Bound [³H]atractyloside is displaced by ADP, carboxyatractyloside and bongkrekic acid. The displacement of bound [³⁵S]carboxyatractyloside by bongkrekic acid and of bound [³H]bongkrekic acid by carboxyatractyloside is markedly increased by ADP.

4. 4. Bongkrekic acid competes with [³⁵S]carboxyatractyloside for binding. Addition of a small concentration of ADP considerably enhances the inhibitory effect of bongkrekic acid on [³⁵S]carboxyactratyloside binding.

5. 5. The adenine nucleotide content of potato mitochondria is of the order of 1 nmol per mg protein. ADP transport in potato mitochondria is inhibited by atractyloside 30- to 40-times less efficiently than by carboxyatractyloside.

Specificity of nucleotide binding and coupled reactions utilising the mitochondrial ATPase

1. 1. Tightly bound ATP and ADP, found on the isolated mitochondrial ATPase, exchange only slowly at pH 8, but the exchange is increased as the pH is reduced. At pH 5.5, more than 60% of the bound nucleotide exchanges within 2.5 min.

2. 2. Preincubation of the isolated ATPase with ADP leads to about 50% inhibition of ATP hydrolysis when the enzyme is subsequently assayed in the absence of free ADP. This effect, which is reversed by preincubation with ATP, is absent on the membrane-bound ATPase. This inhibition seems to involve the replacement of tightly bound ATP by ADP.

3. 3. Using these two findings, the binding specificity of the tight nucleotide binding sites was determined. iso-Guanosine, 2′-deoxyadenosine and formycin nucleotides displaced ATP from the tight binding sites, while all other nucleotides tested did not. The specificities of the tight sites of the isolated and membrane-bound ATPase were similar, and higher than that of the hydrolytic site.

4. 4. The nucleotide specificities of ‘coupled processes’ nucleoside triphosphate-driven reversal of electron transfer, nucleoside triphosphate-³²P_i exchange and phosphorylation were higher than that of the hydrolytic site of the ATPase and similar to that of the tight nucleotide binding sites.

5. 5. The different nucleotide specificities of uncoupled ATP hydrolysis and coupled processes can be explained even if both processes involve a single common site on the ATPase molecule. This model requires that energy can be ‘coupled’ only when it is released/utilised in the nucleotide binding steps of the mechanism.

6. 6. Adenosine β,γ-imidotriphosphate (AMP-PNP) is not a simple reversible inhibitor of the ATPase, since incubation requires preincubation and is not reversed when the compound is diluted out, or by addition of ATP. This compound inhibits the isolated and membrane-bound ATPase equally well. Its guanosine analogue does not act in this way.

7. 7. In submitochondrial particles, ADP inhibited uncoupled hydrolysis of ATP much more effectively than coupled hydrolysis, the latter being measured both directly (from ATP hydrolysis in the absence of uncoupler) or indirectly, by monitoring ATP-driven reduction of NAD⁺ by succinate.

8. 8. The effects of ADP and AMP-PNP were interpreted as providing evidence for two of the intermediates in the proposed scheme for coupled triphosphate hydrolysis.

Effects of α,β-methylene-adenosine-5′-diphosphate on blood platelet aggregation

The effects on platelet aggregation of α,β-methylene-adenosine-5′-diphosphate (Ado-PCP) have been investigated. Using human citrated platelet-rich plasma it has been shown that: (i) at concentrations of 10^?3 M or higher Ado-PCP is able to induce platelet aggregation; (ii) the rate of Ado-PCP-induced aggregation increases on raising the pH of platelet-rich plasma above the pK_a for the secondary phosphonyl dissociation of Ado-PCP; (iii) at concentrations from 1 · 10^?4 to 5 · 10^?4 M Ado-PCP does not cause platelet aggregation itself, but it inhibits ADP-induced aggregation. This inhibition is also observed in washed platelet suspensions. The data suggest that Ado-PCP acts at the same site on the platelet membrane as does ADP and that ADP to AMP transformation is not a prerequisite for the process of aggregation. The observed effect of pH on the rate of Ado-PCP induced aggregation suggests that the ionization state of a nucleotide terminal acid group is important in the process of aggregation.     

Interaction of a synthetic polyanion with rat liver mitochondria

The effect of a polyanion (a copolymer of methacrylate, malaete and styrene in a 1:2:3 proportion with an average molecular weight of 10 000) on respiration, ATPase activity and ADP/ATP exchange activity of rat liver mitochondria and submitochondrial particles has been studied.The polyanion (at 17–150 μg/ml concentration, 100 μg polyanion corresponding to 0.83 μequiv. of carboxylic groups) inhibits the oxidation of succinate and NAD-linked substrates in state 3 in a concentration-dependent manner. The extent of this inhibition can be decreased by elevating the concentration of ADP. State 4 respiration is not affected by the polyanion. It has also a slight inhibitory effect on the oxidation of the above mentioned substrates in the uncoupled state (a maximum inhibition of 37% at 166 μg/ml polyanion concentration), which is unaffected by ADP. The strong inhibition of state 3 respiration can be relieved by 2,4-dinitrophenol to the low level observed in the uncoupled state. Ascorbate+TMPD oxidation is slightly inhibited in state 3, while it is not inhibited at all in the uncoupled state.The polyanion, depending on its concentration, strongly inhibits also the DNP-activated ATPase activity of mitochondria (50% inhibition at 40 μg/ml polyanion concentration).The ATPase activity of sonic submitochondrial particles is also inhibited. However, this inhibition is incomplete (reaching a maximum of 65%) and higher concentrations of the polyanion are required than to inhibit the ATPase activity of intact mitochondria.The polyanion inhibits the ADP/ATP translocator activity of mitochondria, measured by the “back exchange” of [2-³H]ADP. After a short preincubation of the mitochondria with the polyanion, the concentration dependence of the inhibition by the polyanion corresponds to that of the DNP-activated ATPase activity of intact mitochondria.It is concluded that, in intact mitochondria, the polyanion has at least a dual effect, i.e. it partially inhibits the respiratory chain between cytochrome b and cytochrome c, and strongly oxidative phosphorylation by blocking the ADP/ATP translocator.     

A new inhibitor of adenine nucleotide translocase in mitochondria: agaric acid.

The effect of agaric acid (α cetyl citric acid) on the transport of ADP and ATP has been examined in rat liver mitochondria. Respiration stimulated by ADP is progresively inhibited by agaric acid; maximal inhibition is attained at 40 μM agaric acid. ATPase activity is inhibited 30% by 20 μM agaric acid. The exchange of adenine nucleotides is competitively inhibited by agaric acid.     

Energy transduction in photosynthetic bacteria IV. Light-dependent ATPase in photosynthetic membranes from Rhodopseudomonas capsulata

ATPase activity of photosynthetic membrane fragments from the bacterium Rhodopseudomonas capsulata can be stimulated by continuous illumination under conditions of active cyclic electron flow. The activation corresponds to an increase in the maximum velocity of the reaction and does not affect the apparent K_m for ATP (0.11 mM). No stimulation in the light is observed in the presence of classical uncouplers or oxidized 2,6-dichlorophenolindophenol (DCIP), which, per se, stimulate ATPase in the dark. It is demonstrated, however, that oxidized DCIP acts as an uncoupler of bacterial photophosphorylation.

The effect of light is elicited after a few minutes of preillumination, or in a much shorter time if an ADP trapping system is supplied. Activation does not occur if ADP is added during the preillumination (apparent K_m for inhibition by ADP = 1 μM). The effect of ADP is not related to competitive inhibition with ATP, which can be observed at higher concentrations (apparent K_i = 0.26 mM). ADP, however, is not effective if added after some minutes of preillumination.     

Characterization of the catalytic and noncatalytic ADP binding sites of the F1-ATPase from the thermophilic bacterium, PS3

Two classes of ADP binding sites at 20 degrees C have been characterized in the F1-ATPase from the thermophilic bacterium, PS3 (TF1). One class is comprised of three sites which saturate with [3H]ADP in less than 10 s with a Kd of 10 microM which, once filled, exchange rapidly with medium ADP. The binding of ADP to these sites is dependent on Mg2+. [3H]ADP bound to these sites is removed by repeated gel filtrations on centrifuge columns equilibrated with ADP free medium. The other class is comprised of a single site which saturates with [3H]ADP in 30 min with a Kd of 30 microM. [3H]ADP bound to this site does not exchange with medium ADP nor does it dissociate on gel filtration through centrifuge columns equilibrated with ADP free medium. Binding of [3H]ADP to this site is weaker in the presence of Mg2+ where the Kd for ADP is about 100 microM. [3H]ADP dissociated from this site when ATP plus Mg2+ was added to the complex while it remained bound in the presence of ATP alone or in the presence of ADP, Pi, or ADP plus Pi with or without added Mg2+. Significant amounts of ADP in the 1:1 TF1.ADP complex were converted to ATP in the presence of Pi, Mg2+, and 50% dimethyl sulfoxide. Enzyme-bound ATP synthesis was abolished by chemical modification of a specific glutamic acid residue by dicyclohexylcarbodiimide, but not by modification of a specific tyrosine residue with 7-chloro-4-nitrobenzofurazan. Difference circular dichroism spectra revealed that the three Mg2+ -dependent, high affinity ADP binding sites that were not stable to gel filtration were on the alpha subunits and that the single ADP binding site that was stable to gel filtration was on one of the three beta subunits. It has also been demonstrated that enzyme-bound ATP is formed when the TF0.F1 complex containing bound ADP was incubated with Pi, Mg2+, and 50% dimethyl sulfoxide.     

Interaction of the chloroplast ATP synthetase with the photoreactive nucleotide 3′-O-(4-benzoyl)benzoyl adenosine 5''-diphosphate

The photoreactive nucleotide 3'-O-(4-benzoyl)benzoyl ADP (BzADP) is not a substrate for photophosphorylation but is a strong competitive inhibitor (K_i 2-25μM) with respect to ADP and ATP in photophosphorylation or ATP hydrolysis and P_i-ATP exchange reactions, respectively. The analog binds tightly to the membrane-bound CF₁, competes with the right binding of ADP, and prevents the inactivation of the enzyme by tight binding of ADP. Upon irradiation with long wavelength ultraviolet light, the tightly bound BzADP becomes covalently attached to both the - and β-subunits of the enzyme.     

Effect of plant growth hormones and polyamines on ornithine decarboxylase activity during the germination of barley seeds

Gibberellic acid (GA₃) and β-indolylacetic acid (IAA), two of the well known growth hormones, induce four fold the activity of ornithine decarboxylase (ODC) during the germination of barley seeds ( Hordeum vulgare L. var. Beca). The optimal concentration for induction of ODC was 10^–5 M for GA₃ and 10^–3 M for IAA. When 10^–3 M of a polyamine, putrescine or spermidine, is added to the growth medium, ODC activity is significantly inhibited. This inhibition is due to the induction of a protein inhibitor of ODC (antizyme), whose apparent molecular weight is 16 000 ± 2 000 daltons. Addition of GA₃ to cultures which have been grown for 50 or 98 h in the presence of polyamines, abolishes the observed inhibition of ODC activity, while in the reverse experiment, addition of polyamines at 50 or 98 h does not affect the ODC activity induced by GA₃. Cadaverine, a physiological plant diamine, enhances ODC activity; whereas 1,8-diaminooctane (the alkyl analogue of spermidine) does not have any effect.     

The effect of agaric acid on citrate transport in rat liver mitochondria

The effect of agaric acid (αcetyl citric acid) , a competitive inhibitor of the adenine nucleotide translocase, was studied on the citrate uptake in rat liver mitochondria. The experiments carried out reveal that citrate uptake is progressively inhibited by increasing concentrations of agaric acid, showing a typical competitive type of inhibition. The apparent Ki for agaric acid is 5.2 μM, a concentration lower than that which inhibits the adenine nucleotide translocase. The results also show that mersalyl diminishes the Ki to 3.4 μM; 10 mM KCl reverses the inhibitory action of agaric acid on the ADP and ATP exchange but does not affect the agaric acid induced inhibition of citrate uptake.     

trans-2,5-Bis-(3,4,5-trimethoxyphenyl)tetrahydrofuran. An orally active specific and competitive receptor antagonist of platelet activating factor

trans-2,5-Bis(3,4,5-trimethoxyphenyl)tetrahydrofuran (L-652,731) is found to be a potent and orally active platelet activating factor (PAF)-specific and competitive receptor antagonist. It potently inhibits [3H]PAF (1 nM) binding to receptor sites on rabbit platelet membranes with an ED50 of 2 X 10(-8) M under the assay condition without the addition of mono- or divalent cations. In a comparative study, it is more potent than CV-3988, kadsurenone, and ginkgolide B as a receptor antagonist. The equilibrium dissociation constants (KB) of L-652,731 obtained either from the inhibition of receptor binding or from the inhibition of PAF-induced aggregation of gel-filtered rabbit platelet are 2.7 X 10(-8) and 2.1 X 10(-8) M, respectively. The agreement of these KB determinations based on receptor and cellular function suggests that L-652,731 does not inhibit other steps following PAF-receptor binding. L-652,731 does not antagonize the binding of several radioligands to their respective receptor. It shows no inhibitory effect on platelet aggregation induced by other aggregating agents including thrombin, collagen, A-23187, arachidonic acid, epinephrine, and ADP. L-652,731 is orally active; it inhibits PAF-induced rat cutaneous vascular permeability with an ED50 of 30 mg/kg orally. Significant inhibitory results of L-652,731 suggest that PAF may be partially involved in cutaneous vascular permeability induced by histamine and bradykinin.     

A high-activity ATP translocator in mesophyll chloroplasts of Digitaria sanguinalis, a plant having the C-4 dicarboxylic acid pathway of photosynthesis

The effect of exogenous adenine nucleotides on CO₂ fixation and oxygen evolution was studied with mesophyll protoplast extracts of the C₄ plant Digitaria sanguinalis. Exogenous ATP was found to stimulate the rate of pyruvate and pyruvate + oxalacetate induced CO₂ fixation, as well as reverse the inhibition of CO₂ fixation by carbonyl cyanide m-chlorophenyl hydrazone and several electron transport inhibitors. The ATP-dependent stimulation of CO₂ fixation varied from 40 to 70 μmol CO₂ fixed/mg chlorophyll per h, suggesting that ATP was crossing the chloroplast membranes at rates of 80–140 μmol/mg chlorophyll per h, since 2 ATP are required for each CO₂ fixed. Fixation of CO₂ could also be induced in the dark by exogenous ATP, in which case ADP accumulated outside the chloroplasts. This suggests that external ATP is exchanging for internal ADP. In contrast, ADP and AMP were found not to traverse chloroplast membranes, on the basis that neither nucleotide inhibited CO₂ fixation or stimulated oxygen evolution that was limited by available ADP for phosphorylation. Further evidence that ATP can enter the chloroplasts was obtained by direct measurements of the increase in ATP in the chloroplasts due to addition of exogenous ATP in the dark. These studies yielded minimal rates of ATP uptake on the order of 30–40 μmol/mg chlorophyll per h. It is suggested that a membrane translocator exists that specifically transports ATP into the chloroplasts in exchange for ADP. The significance of these findings are considered with respect to the C₄ pathway of photosynthesis.     

Der nucleotidaustausch des F-Actin in kontrahierten, erschlafften und totenstarren Fibrillen in seiner Bedeutung für den molekularen Mechanismus der Muskelkontraktion

Nucleotide exchange on the F-actin component of muscle fibrils in the states of contraction, relaxation, and rigor. The exchange as argument in the discussion of the contractile mechanism

1. 1. Exchange of the bound nucleotide with added nucleotide is qualitatively the same in solutions of isolated F-actin and in fibrils for the states of contraction, relaxation, and rigor.

1.1. (a) Exchange with ATP is always coupled with ATP splitting.

1.2. (b) A momentary exchange is always continued by a delayed exchange; the kinetics of the exchanges are different.

1.3. (c) Amount and speed of the exchange increase with increasing concentration of added nucleotide but do not depend on the concentration of the free Mg²⁺.

1.4. (d) Exchange with ATP is always significantly greater than the exchange with ADP.

2. 2. The exchange of the bound nucleotide is quantitatively different in the different systems quoted.

2.1. (a) The exchange in extracted fibrils is greatest during contraction, significantly smaller during relaxation and significantly smallest during rigor.

2.2. (b) If F-actin is isolated according to our method of preparation the exchange of isolated F-actin with ATP is quantitatively equal to the exchange of contracted fibrils and the exchange with ADP is equal to the exchange of fibrils in rigor.

2.3. (c) The amount of exchange of extracted fibrils is well reproducible, but the exchange of isolated F-actin is rather different in different laboratories; apparently the amount depends on the treatment during preparation of the F-actin.

3. 3. All results quoted are consistent and also are consistent with the nucleotide exchange observed in living muscle if it is supposed that the exchange takes place only at defectives sites of the double helix some of which exchange immediately and some of which only exchange under the influence of an additional factor (like concentration and type of the nucleotide added). This interpretation does not favour a physiological correlation of nucleotide exchange with muscle contraction.

Adenine nucleotide translocation in plant mitochondria

The rapid translocation of external ADP-[^14C]by corn mitochondria is inhibited by high concentrations of atractyloside with enhanced inhibition occurring in the presence of Mg²⁺. This translocation is also inhibited by AMP or ATP but CDP, GDP, IDP or UDP have little effect. Backward exchange of internal ADP-[¹⁴C] occurs in the presence of AMP, ADP or ATP but is not promoted by other nucleoside diphosphates. It is suggested that the adenine nucleotide (AdN) carrier is specific for ADP and ATP and that apparent translocation of AMP is a result of adenylate kinase activity. The translocated ADP can be separated into 3 components: (1) atractyloside-insensitive binding; (2) carrier-bound ADP saturated at ca 30 μM external ADP; and (3) exchanged ADP saturated as ca 5 μM external ADP. It is suggested that the adenine nucleotide carrier of plant mitochondria possesses similar properties to the classical carrier of vertebrate mitochondria.