Inhibition of energy conservation reactions in chromatophores of Rhodospirillum rubrum by antibiotics

The antibiotics efrapeptin and leucinostatin inhibited photosynthetic and oxidative phosphorylation and related reactions such as the dark and light ATP-P_i exchange reactions and the Mg-ATPase in Rhodospirillum rubrum chromatophores. Higher concentrations of leucinostatin were required for inhibition of the phenazine methosulfate-catalyzed photophosphorylation and light ATP-P_i exchange reaction than for the endogenous or succinate-induced photophosphorylation and dark ATP-P_i exchange reaction. Efrapeptin and leucinostatin inhibited the ATP-driven transhydrogenase while only the latter inhibited the light-driven transhydrogenase, proton gradient formation, and NAD⁺ reduction by succinate in chromatophores. Efrapeptin, but not leucinostatin, inhibited the soluble Ca-ATPase activity of the coupling factor obtained from chromatophores. The inhibition was competitive with ATP. It is concluded that efrapeptin is an effective energy transfer inhibitor whose site of action may be localized in the soluble coupling factor, while the effects of leucinostatin are more complex and cannot be explained as a simple uncoupling.     

Coordination of adenylate energy charge and phosphorylation state during ischemia and under physiological conditions in rat liver and kidney

The relation of the adenylate energy charge $\text{(}\text{ATP}\text{+}\text{1}\text{2}\text{ADP/ATP}\text{+}\text{ADP}\text{+}\text{AMP}\text{)}$ to the phosphorylation state (ATP)/(ADP)(HPO₄^2?) in rat liver and kidney was analyzed. Under physiological conditions and in ischemia, the two regulatory parameters, calculated from reported values for adenine nucleotides and inorganic phosphate (P_i) and from new observations, were closely coordinated. Energy charge was an inverse linear function of P_i and -log (1 - energy charge) was a positive linear function of log phosphorylation state. To evaluate experimental data with known energy charge, but unknown P_i, and to determine the theoretical relation between energy charge and phosphorylation state, P_i was estimated from a) the regression equation: P_i, μmol/g wet wt tissue = 1.05 - energy charge/0.073 and b) the empirical relationship: (P_i/2P_a) + energy charge = k, where P_a = σAMP + 2ADP + 3ATP and k = 1. With both estimates, the relation between phosphorylation state and energy charge for the experimental data was, within error, the same as that observed with measured P_i and concordant with theoretical values. Over the physiological range of energy charge (～0.85 – 0.95, log phosphorylation state ～3.3 – 4.3), apparent ΔG_ATP (×2) was closer to the range of ΔG observed by Wilson $\text{et al}$ (Biochem. J. $\text{140}$:57, 1974) for transfer of two electrons from mitochondrial NAD to the cytochrome c couple than the ΔG_ATP (×2) they reported, supporting their conclusion that near-equilibrium exists between the mitochondrial respiratory chain and the cytoplasmic phosphorylation state under physiological conditions. From evidence presented, it is postulated that the phosphorylation state is regulated by the adenylate energy charge.     

Electron transport control in chloroplasts. Effects of photosynthetic control monitored by the intrathylakoid pH

(1) In isolated chloroplasts (class B) electron flow is controlled mainly by the intrathylakoid pH (pH_in). A decrease in pH_in due to the light-driven injection of protons inside the thylakoid leads to the retardation of electron flow between two photosystems. This effect can be abolished by uncouplers or under photophosphorylation conditions (addition of Mg²⁺-ADP with P_i); Mg²⁺-ATP does not influence the steady-state rate of electron flow, (2) The steady-state pH difference, ΔpH, across the thylakoid membrane was estimated from quantitative analysis of the rate of P-700⁺ reduction. In chloroplasts, without adding Mg²⁺-ADP, ΔpH increases from 1.6 to 3.2 as the external pH rises from 6 to 9.5. Under the photophosphorylation conditions, ΔpH decreases showing a minimum at the external pH 7.5 ($\text{Δ}\text{pH}\text{? 0.5–1.0}$). (3) The value of photosynthetic control, K, measured as the ratio of the steady-state rates of P-700⁺ reduction in the presence of Mg²⁺-ADP (with P_i) and without adding Mg²⁺-ADP is dependent on external pH variations, showing a maximum value of $\text{K ? 3.5}$ at pH_out 7.5. This pH dependence coincides with that of the ADP-stimulated ΔpH decrease. (4) Experiments with spin labels provide evidence that the light-induced changes in the thylakoid membrane are sensitive to the addition of uncouplers and are affected only slightly by the addition of Mg²⁺-ADP and P_i.     

Active sodium extrusion reduces net efficiencies of oxidative phosphorylation in the strictly photoautotrophic cyanobacterium Anacystis nidulans

Efficiencies of oxidative phosphorylation ($\text{P}\text{O}$ ratios), intracellular high-energy phosphate pools (ATP and ADP) under aerobic and anaerobic dark conditions, and photosynthetic oxygen evolution measured with intact cells of Anacystis nidulans were found to be specifically depressed by NaCl, but not by KCl. A scheme is proposed which explains the deleterious effect of sodium on the energy metabolism of A. nidulans by competition for protons between ATP synthesis and active sodium extrusion.     

Thiol modulation of the chloroplast protonmotive ATPase and its effect on photophosphorylation

Thiol modulation of the chloroplast protonmotive ATPase (CF₀-CF₁) by preillumination of broken chloroplasts in the presence of dithiothreitol (or preillumination of intact chloroplasts in the absence of added thiols) had the following effects on photophosphorylation. (1) When assayed at pH 8 and saturating light, the initial rate of photophosphorylation was increased by 10–40%. There was an accompanying increase in the rate of coupled electron transport with no significant change in the overall $\text{P}\text{2}\text{e}$ ratio. (2) On lowering the pH of the assay medium to pH 7, the stimulatory effect of thiol modulation on photophosphorylation and coupled electron flow was enhanced. At pH 7, there was also a small increase in $\text{P}\text{2}\text{e}$ ratio. (3) Addition of a non-saturating amount of uncoupler to the assay medium enhanced the stimulatory effect of thiol modulation on photophosphorylation. In the presence of 1 mM NH₄Cl, there was only a small increase in coupled electron flow and a correspondingly larger increase in $\text{P}\text{2}\text{e}$ ratio. (4) Lowering the light intensity, or inhibiting electron transport, diminished the stimulatory effect of thiol modulation on photophosphorylation, coupled electron transport and $\text{P}\text{2}\text{e}$ ratio. (5) Under all the above conditions, the ΔpH maintained across the thylakoid membrane was lower after thiol modulation, even when photophosphorylation markedly increased in rate. (6) Thiol modulation of CF₀-CF₁ increased the observed Michaelis constant for ADP (K_m(ADP)) and the apparent maximum rate (V_app of photophosphorylation by the same factor, so that ratio $\text{V}{}_{\mathrm{<mtext>app</mtext>}}\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ was not altered. $\text{V}{}_{\mathrm{<mtext>app</mtext>}}\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ was also unaffected by changing the medium pH, but was significantly decreased upon addition of uncouplers to the medium. These results indicate that the observed rate of ATP synthesis catalysed by thiol demodulated chloroplasts is limited kinetically by the fraction (α) of enzyme molecules that are active during photophosphorylation. A model based on a dual pH optimum requirement for activation of CF₀-CF₁ is presented to explain the dependence of α on ΔpH. Thiol modulation of CF₀-CF₁ is proposed to stimulate photophosphorylation by causing the enzyme to become active over a lower range of ΔpH, thereby reducing the kinetic limitation on ATP synthesis imposed by the activation process.     

Energetics of sodium transport in the kidney: Saturation transfer 31P-NMR

³¹P-NMR has been used to quantify inorganic phosphate (P_i) and high-energy phosphates in the isolated, functioning perfused rat kidney, while monitoring oxygen consumption, glomerular filtration rate and sodium reabsorption. Compared with enzymatic analysis, 100% of ATP, but only 25% of ADP and 27% of P_i are visible to NMR. This is indicative that a large proportion of both ADP and P_i are bound in the intact kidney. NMR is measuring free, and therefore probably cytosolic concentrations of these metabolites. ATP synthesis rate, measured by saturation transfer NMR shows the P:O ratio of 2.45 for the intact kidney. This is close to the theoretical value, suggesting the NMR visible pool is that which is involved in oxidative phosphorylation. The energy cost of Na transport, calculated from the theoretical Na:ATP of 3.0 exceeded the measured rate of ATP synthesis. Instead, Na:ATP for active transport in the perfused kidney was 12. Since the phosphorylation potential ($\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{]×[}\text{P}{}_{\mathrm{i}}\text{]}$) by NMR was 10 000 M^?1, the free-energy of ATP hydrolysis was 52 kJ/mol. Using this figure, the rate of ATP hydrolysis observed could fully account for the observed rate of sodium reabsorption.     

Steady-state kinetics of ADP-arsenate and ATP-synthesis in Rhodospirillum rubrum chromatophores

(1) Rates of ATP synthesis and ADP-arsenate synthesis catalyzed by Rhodospirillum rubrum chromatophores were determined with the firefly luciferase method and by a coupled enzyme assay involving hexokinase and glucose-6-phosphate dehydrogenase. (2) V_m for ADP-arsenate synthesis was about 2-times lower than V_m for ATP-synthesis. With saturating [ADP], K(As_i) was about 20% higher than K(P_i). With saturating [anion], K(ADP) was during arsenylation about 20% lower than during phosphorylation. (3) Plots of $\text{1}\text{v}$ vs. $\text{1}\text{[}\text{substrate}\text{]}$ were non-linear at low concentrations of the fixed substrate. The non-linearity was such as to suggest a positive cooperativity between sites binding the variable substrate, resulting in an increased $\text{V}{}_{\mathrm{<mtext>m</mtext>}}\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ ratio. High concentrations of the fixed substrate cause a similar increase in $\text{V}{}_{\mathrm{<mtext>m</mtext>}}\text{K}{}_{\mathrm{<mtext>m</mtext>}}$, but abolish the cooperativity of the sites binding the variable substrate. (4) Low concentrations of inorganic arsenate (As_i) stimulate ATP synthesis supported by low concentrations of P_i and ADP about 2-fold. (5) At high ADP concentrations, the apparent K_i of As_i for inhibition of ATP-synthesis was 2–3-times higher than the apparent K_m of As_i for arsenylation; the apparent K_i of P_i for inhibition of ADP-arsenate synthesis was about 40% lower than the apparent K_m of P_i for ATP synthesis. (6) The results are discussed in terms of a model in which P_i and As_i compete for binding to a catalytic as well as an allosteric site. The interaction between these sites is modulated by the ADP concentration. At high ADP concentrations, interaction between these sites occurs only when they are occupied with different species of anion.     

Phosphorylation and nitrogenase activity in isolated heterocysts from Anabaena variabilis (ATCC 29413)

Adenylate-pool composition, energy charge, and nitrogenase activity were examined in isolated heterocysts from Anabaena variabilis (ATCC 29413). ATP formation was detected as a light- or oxygen-induced increase in ATP concentration. No cofactors or substrates had to be added for photophosphorylation to occur, whereas oxidative phosphorylation was dependent on hydrogen and oxygen (Knallgas reaction). The increase in ATP concentration was reflected by a decrease in AMP concentration, accompanied by small changes in ADP levels. Thus, a regulation of the adenylate pool by a myokinase (adenylate kinase) has to be assumed. Upon dark-light transitions, the energy charge in heterocysts increased from values below 0.4 to values approaching 0.8. High energy-charge values, reached in the light only, allowed for high rates of acetylene reduction in the presence of hydrogen. The increase in the energy charge in the dark to approx. 0.64 by addition of oxygen (5% ($\text{v}\text{v}$) in the presence of hydrogen) resulted in low nitrogenase activities, generally not exceeding 1–3% of the light-induced rates. In the dark, oxygen concentrations above 10% were inhibitory to both ATP formation and acetylene reduction. Increasing light intensities led to a steep increase in energy charge followed by an increase in nitrogenase activity. Plotting enzyme activity versus energy charge, a nonlinear, asymptotic relationship was observed.     

Studies on (Na+ + K+)-activated ATPase. XLIV. Single phosphate incorporation during dual phosphorylation by inorganic phosphate and adenosine triphosphate

$\text{(}\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-}\text{ATPase}$ can be phosphorylated by its substrate ATP as well as by its product inorganic phosphate. The maximal capacity for phosphorylation by either of these two substances is one mol phosphate per mol enzyme. In order to investigate whether the enzyme molecule possesses only one phosphorylation site common to ATP and P_i, or two phosphorylation sites, one for ATP and one for P_i, dual phosphorylation of the enzyme has been carried out. Under conditions, which are maximally favourable for each type of phosphorylation, successive phosphorylation by P_i and ATP leads to a maximal incorporation of only one mol phosphate per mol enzyme. The phosphorylation capacity for ATP decreases by the same amount as the P_i-phosphorylation level increases, without an effect on the apparent affinity for ATP.The results can be explained by assuming either a single common phosphorylation site for P_i and ATP, or a conformational change of the enzyme following phosphorylation by P_i, which excludes phosphorylation by ATP.     

Hydrogen bonding requirements for the insulin-sensitive sugar transport system of rat adipocytes

(1) The $\text{t}\text{1}\text{2}$ for 1.3 mM D-allose uptake and efflux in insulin-stimulated adipocytes is 1.7 ± 0.1 min. In the absence of insulin mediated uptake of D-allose is virtually eliminated and the uptake rate ($\text{t}\text{1}\text{2}\text{= 75.8 ± 4.99}\text{min}$) is near that calculated for nonmediated transport. The kinetic parameters for D-allose zero-trans uptake in insulin-treated cells are K_zt^oi = 271.3 ± 34.2 mM, V_zt^oi = 1.15 ± 0.12 mM · s^?1. (2) A kinetic analysis of the single-gate transporter (carrier) model interacting with two substrates (or substrate plus inhibitor) is presented. The analysis shows that the heteroexchange rates for two substrates interacting with the transporter are not unique and can be calculated from the kinetic parameters for each sugar acting alone with the transporter. This means that the equations for substrate analogue inhibition of the transport of a low affinity substrate such as D-allose can be simplified. It is shown that for the single gate transporter the K_i for a substrate analogue inhibitor should equal the equilibrium exchange K_m for this analogue. (3) Analogues substituted at C-1 show a fused pyranose ring is accepted by the transporter. 1-Deoxy-D-glucose is transported but has low affinity for the transporter. High affinity can be restored by replacing a fluorine in the β-position at C-1. The K_i for $\text{d}\text{-glucose}\text{= 8.62}\text{mM}$; the K_i for $\text{β-}\text{fluoro-}\text{d}\text{-glucose}\text{= 6.87}\text{mM}$. Replacing the ring oxygen also results in a marked reduction in affinity. The K_i for $\text{5-}\text{thio-}\text{d}\text{-glucose}\text{= 42.1}\text{mM}$. (4) A hydroxyl in the gluco configuration at C-2 is not required as 2-deoxy-d-galactose (K_i = 20.75 mM) has a slightly higher affinity than d-galactose (K_i = 24.49 mM). A hydroxyl in the manno configuration at C-2 interferes with transport as d-talose (K_i = 35.4 mM) has a lower affinity than d-galactose. (5) d-Allose (K_m = 271.3 mM) and 3-deoxy-d-glucose (K_i = 40.31 mM) have low affinity but high affinity is restored by substituting a fluorine in the gluco configuration at C-3. The K_i for $\text{3-}\text{fluoro-}\text{d}\text{-glucose}\text{= 7.97}\text{mM}$. (6) Analogues modified at C-4 and C-6 do not show large losses in affinity. However, 6-deoxy-d-glucose (K_i = 11.08 mM) has lower affinity than d-glucose and 6-deoxy-d-galactose K_i = 33.97 mM) has lower affinity than d-galactose. Fluorine substitution at C-6 of d-galactose restores high affinity. The K_i for $\text{6-}\text{fluoro-}\text{d}\text{-galactose}\text{= 6.67}\text{mM}$. Removal of the C-5 hydroxymethyl group results in a large affinity loss. The K_i$\text{d}\text{-xylose}\text{= 45.5}\text{mM}$. The K_i for $\text{l}\text{-arabinose}\text{= 49.69}\text{mM}$. (7) These results indicate that the important hydrogen bonding positions involved in sugar interaction with the insulin-stimulated adipocytes transporter are the ring oxygen, C-1 and C-3. There may be a weaker hydrogen bond to C-6. Sugar hydroxyls in non-gluco configurations may sterically hinder transport.     

The transport of oxaloacetate in isolated mitochondria

The mechanism of mitochondrial oxaloacetate transport has been investigated by measuring the rate and the extent of exchange reactions between intramitochondrial anions and added oxaloacetate. The exchange between oxaloacetate and intramitochondrial oxoglutarate is insensitive to mersalyl at a concentration which completely inhibits the dicarboxylate carrier. Oxaloacetate causes efflux of intramitochondrial P_i, malonate, and malate. Mersalyl inhibits completely the oxaloacetate/P_i exchange, but only partially the oxaloacetate/malonate and the oxaloacetate/malate exchanges. The inhibition of the last two reactions decreases on increasing the time of incubation. Butylmalonate inhibits more than phenylsuccinate the exchange oxaloacetate_out/³²P_iin, whereas phenylsuccinate is a more effective inhibitor than butylmalonate of the oxaloacetate_out/[¹⁴C]oxoglutarate_in exchange. The apparent K_m values ranged from 0.6 to 1.2 mm for the oxaloacetate/oxoglutarate exchange and from 6.5 to 10 mm for the oxaloacetate/P_i exchange. The inhibition of oxoglutarate uptake by oxaloacetate is competitive. Oxaloacetate inhibits the malonate/P_i exchange competitively and it is a noncompetitive inhibitor of the $\text{P}{}_{\mathrm{i}}\text{P}{}_{\mathrm{i}}$ exchange. It is concluded that oxaloacetate may be transported across the mitochondrial membrane by the oxoglutarate carrier and, much less effectively, by the dicarboxylate carrier. The implications of these findings are discussed.     

Chemical modification of mitochondria. II. Effect of labeling on oxidative phosphorylation

The labeling of rat liver mitochondria (RLM) by the uncoupler 2,4-dinitro-5-(bromoacetoxyethoxy)phenol (DNBP) was studied and related to the effect of this molecule on oxidative phosphorylation. Alkylation of the cysteine residues was measured both with respect to incubation time of RLM with DNBP and with increasing DNBP concentration. At 3.3 × 10^?5m DNBP, the amount of S-carboxymethyl-cysteine formed was found to level off after about 3 min. The rate of ATP synthesis in RLM is reduced by increasing concentrations of DNBP and falls to zero, with either hydroxybutyrate or succinate as substrate, at 2 × 10^?4m DNBP. To characterize the effect of labeling on oxidative phosphorylation, the $\text{P}\text{O}$ ratio were measured after incubating RLM with DNBP for various times between 10 and 300 sec. The $\text{P}\text{O}$ ratio increases and tends to level off as the incubation time increases. No increase in $\text{P}\text{O}$ ratio was noted when RLM were similarly incubated with the nonlabeling uncoupler 2,4-dinitro-5-(acetoxyethoxy) phenol. Further, the effect of labeling on oxidative phosphorylation was determined with RLM which had been treated with DNBP and then washed free of the excess unreacted uncoupler. DNBP produces specific labeling in RLM which, when related to the effects of this uncoupler on oxidative phosphorylation, suggests that the labeled proteins may be involved in the primary energy transduction process.     

Effects of ethanol-derived acetaldehyde on the phosphorylation potential and on the intramitochondrial redox state in intact rat liver

The role of acetaldehyde (AcH) in the ethanol-induced shift toward reduction of the cytosolic and mitochondrial free NAD⁺/free NADH ratios and its effect on the phosphorylation potential was investigated in livers of fed, intact rats given ethanol (1 g/kg ip). Calcium cyanamide, an inhibitor of mitochondrial aldehyde dehydrogenase, was administered to block predominantly intramitochondrial NADH production from AcH oxidation. Compared with ethanol alone, cyanamide almost totally reversed the elevation of the β-OH-butyrate/acetoacetate ratio but only slightly reduced the lactate/ pyruvate ratio, which was calculated to be in near equilibrium with the hepatic ethanol/ AcH ratio after cyanamide. Ethanol or cyanamide alone had no effect on ATP, ADP, or P_i, but together they significantly decreased the $\text{ATP}\text{ADP}\text{· P}{}_{\mathrm{<mtext>i</mtext>}}$ ratio by increasing both ADP and P_i levels. No association between changes in the phosphorylation potential and the redox states was, however, observed. An ethanol-induced increase in AMP was abolished by cyanamide. The results demonstrate that the effect of ethanol on the mitochondrial redox state requires active AcH oxidation and suggest that moderate AcH accumulation likely to occur during alcohol-aversive drug treatment significantly lowers the cellular phosphorylation potential.     

The oxygen dependence of cellular energy metabolism.

Suspensions of cultured C 1300 neuroblastoma cells, sarcoma 180 ascites tumor cells, and Tetrahymena pyriformis cells were used to study the oxygen dependence of cellular energy metabolism. Cellular respiration was found to be almost independent of oxygen tension to values of less than 20 μm with an apparent K_m for oxygen of less than 1 μm. In contrast, the reduction of mitochondrial cytochrome c was found to be dependent on oxygen tension at all values from 240 μm downward. Oxygen dependence was also observed in terms of cellular energy metabolism expressed as adenosine triphosphate and adenosine diphosphate concentrations. These data provide direct evidence that in intact cells mitochondrial oxidative phosphorylation is oxygen dependent throughout the physiological range of oxygen tension (air saturation and below). The respiratory rate is maintained constant when the oxygen tension is lowered by decreasing values of the cytosolic $\text{[ATP]}\text{[ADP]}\text{[P}{}_{\mathrm{<mtext>i</mtext>}}\text{]}$ and intramitochondrial $\text{[NAD]}{}^{\mathrm{+}}\text{]}\text{[NADH]}$ because these regulatory parameters adjust to maintain a constant rate of ATP synthesis. The lack of oxygen dependence in the respiratory rate means that the rate of cellular ATP utilization is essentially oxygen independent until the mitochondria can no longer synthesize ATP at the required rate and $\text{[ATP]}\text{[ADP]}\text{[P}{}_{\mathrm{<mtext>i</mtext>}}\text{]}$.     

The interaction of phenylglyoxal with soluble and membrane-bound chloroplast coupling factor 1

The rate of inhibition of cyclic photophosphorylation in chloroplast thylakoids by the arginine reagent phenylglyoxal was enhanced in the light, i.e., under conditions where membrane energization occurred. Uncouplers, but not energy-transfer inhibitors, prevented the effect of light. Chemical modification of chloroplast thylakoids by phenylglyoxal under dark or in light conditions affected differently the light-induced exchange of tightly bound ADP. In both cases the exchange was less inhibited than photophosphorylation. Complete inhibition of ATPase activity of soluble CF₁ was correlated with the incorporation of 8 mol [¹⁴C]phenylglyoxal per mol enzyme. About 50% of the incorporated radioactivity was lost at different rates depending on the buffer present and suggesting a change in the stoichiometry of the adduct from 2:1 to 1:1. Inhibition of ATPase and photophosphorylating activities of chloroplasts by modification with [¹⁴C]phenylglyoxal in the dark was associated with the incorporation of 1 and 2 mol reagent per mol membrane-bound CF₁, respectively. In the light the rate of incorporation was enhanced and both reactions were inactivated when 2 mol $\text{[}{}^{14}\text{C]phenylglyoxal}\text{CF}{}_1$ were bound. In all the labelling experiments the radioactivity was mainly recovered from the α- and β-subunits.     

Relations between extramitochondrial and intramitochondrial adenine nucleotide systems

The control of oxidative phosphorylation by the extramitochondrial $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{]}$ ratio and [P_i] was investigated by incubations of isolated mitochondria with an ADP regenerating system and by a new perifusion technique using glass filters for immobilization of mitochondria. With mitochondria from different sources oxidizing different substrates and with both techniques, similar results were obtained. Changes of the extramitochondrial $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{]}$ ratio from about 100 to 5 transfer mitochondria from the resting state (state 4) to the fully active state (state 3). The importance of the adenine nucleotide translocator in this transition was demonstrated by the influence of its specific inhibitor carboxyatractyloside. The sensitivity to the inhibitor was more pronounced in states with high $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{]}$ ratios than in the fully active state. In the hexokinase-glucose system the action of the inhibitor caused a transition to a new steady state, where a decreased $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{]}$ ratio overcomes the inhibition. Thus, a partial inhibition of the translocator shifted the control characteristics to lower $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{]}$ ratios. When the concentration of inorganic phosphate was decreased, the main effect was a reduction of the maximum rate of oxidative phosphorylation (i.e., in state 3), whereas the $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{]}$ sensitive range was not altered. This effect is caused by changes in the intramitochondrial phosphorylation potential. Furthermore, this indicates that the kinetic properties of the adenine nucleotide translocator prevent a simple equilibration of the phosphorylation potential across the inner membrane. This is also demonstrated by the fact that the extramitochondrial formation of glucose-6-phosphate and the intramitochondrial synthesis of citrulline compete for ATP.     

Spatial requirements for insulin-sensitive sugar transport in rat adipocytes

(1) Alkyl sugar inhibition of d-allose uptake into adipocytes has been used to explore the spatial requirements of the external sugar transport site in insulin-treated cells. α-methyl and β-methyl glucosides show low affinity indicating very little space around C-1. The high affinity of d-glucosamine (K_i = 9.05 ± 0.66 mM) is lost by N-acetylation. $\text{N-}\text{Acetyl-}\text{d}\text{-glucosamine}$ shows no detectable affinity, indicating that a bulky group at C-2 is not accepted. Similarly $\text{2,3-}\text{di}\text{-O-}\text{methyl-}\text{d}\text{-glucose}$ (K_i = 42.1 ± 7.5 mM) has lower affinity than $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ (K_i = 5.14 ± 0.32 mM) indicating very little space around C-2 but much more around C-3. A reduction in affinity does occur if a propyl group is introduced into the C-3 position. The K_i for $\text{3-O-}\text{propyl-}\text{d}\text{-glucose}$ is 11.26 ± 2.12 mM. $\text{6-O-}\text{Methyl-}\text{d}\text{-galactose}$ (K_i = 87.2 ± 17.9 mM) and $\text{6-O-}\text{propyl-}\text{d}\text{-glucose}$ (K_i = 78.07 ± 12.6 mM) show low affinity compared with d-galactose and d-glucose, indicating steric constraints around C-6. High affinity is restored in $\text{6-O-}\text{pentyl-}\text{d}\text{-galactose}$ (K_i = 4.66 ± 0.23 mM) possibly indicating a hydrophobic binding site around C-6). (2) In insulin treated cells $\text{4,6-O-}\text{ethylidene-}\text{d}\text{-glucose}$ (K_i = 6.11 ± 0.5 mM) and maltose (K_i = 23.5 ± 2.1 mM) are well accommodated by the site but trehalose shows no detectable inhibition. These results indicate that the site requires a specific orientation of the sugar as it approaches the transporter from the external solution. C-1 faces the inside while C-4 faces the external solution. (3) To determine the spatial and hydrogen bonding requirements for basal cells 40 μM $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ was used as the substrate. Poor hydrogen bonding analogues and analogues with sterically hindering alkyl groups showed similar K_i values to those determined for insulin-treated cells. These results indicate that insulin does not change the specificity of the adipocyte transport system.     

An analysis of proton fluxes coupled to electron transport and ATP synthesis in chloroplast thylakoids

Electron transport, phosphorylation and internal proton concentration were measured in illuminated spinach chloroplast thylakoid membranes under a number of conditions. Regardless of the procedure used to vary these parameters, the data fit a simple chemiosmotic model. Protons from Photosystem II did not appear to be utilized differently from those derived from Photosystem I. The maximal phosphorylation efficiency ($\text{P}\text{e}{}_2$) for photophosphorylation in washed thylakoids under oxidizing conditions is likely to be $\text{4}\text{3}$. This value is consistent with a proton-to-electron-pair ratio of 4 for electron flow through both photosystems and a proton-to-ATP ratio of 3 for the chloroplast proton-ATPase.     

Quantitative study of PNSB energy metabolism in degrading pollutants under weak light-micro oxygen condition

Contribution and relationship between oxidative phosphorylation and photophosphorylation pathways in purple non-sulfur bacteria (PNSB) wastewater treatment under weak light-micro oxygen condition were studied quantitatively. Results showed that under weak light-anaerobic condition, PNSB followed photophosphorylation with the first-order degradation kinetic constant k₃ of 0.0585. Under dark-micro aerobic condition, it followed oxidative phosphorylation with k₂ of 0.0896. Under weak light-micro oxygen condition, both pathways existed with k₁ of 0.108. When light and oxygen both existed, oxidative phosphorylation had a strong competitiveness, it played a dominative role and counted for 92.7% in pollutants degradation, and meanwhile photophosphorylation was restrained by 81.6%. Theoretical analysis showed the common part from coenzyme Q (CoQ) to cytochrome c2 (Cyt c2) in both respiration and photosynthetic chains might cause the competition. When oxygen existed, respiration electron transport would be enhanced. Other potential explanations included that oxygen might damage the pigment and membrane system vital to photophosphorylation.