Effect of palmitoylcarnitine on mitochondrial activities

Mitochondria from pea (Pisum sativum L.) cotyledons and potato (Solanum tuberosum L.) tubers exhibited a palmitoyl carnitine-dependent, KCN-sensitive stimulation of the oxygen uptake measured in the presence of 0.2mmol·^–1 malate (sparker malate), provided a certain concentration range of palmitoylcarnitine was observed. Above this concentration range, which was dependent on the bovine serum albumin (BSA) concentration of the reaction mixture, the mitochondrial oxygen uptake was inhibited by palmitoylcarnitine. Palmitoylcarnitine (racemate) and palmitoyl-l-carnitine were equally effective in stimulating/inhibiting mitochondrial oxygen uptake in the presence of sparker malate. The mitochondrial membrane potential generated in the presence of sparker malate was partially dissipated by palmitoyl-lcarnitine concentrations stimulating the mitochondrial oxygen uptake. The formation of acid-soluble radioactivity in reaction mixtures provided with [1-¹⁴C]palmitoyll-carnitine was considerably lower than that expected minimally if the palmitoyl-l-carnitine-stimulated oxygen uptake resulted from palmitoyl-l-carnitine oxidation sparked by malate. Palmitoylcarnitine concentrations resulting in stimulation of the mitochondrial oxygen uptake in the presence of sparker malate also led to a stimulation of succinate-cytochrome c reductase activity, as well as to an increase in the measurable activities of mitochondrial matrix enzymes, indicating loss of both mitochondrial integrity and mitochondrial enzyme latency in the presence of palmitoylcarnitine. Correspondingly, malate-dependent NADH formation was stimulated by palmitoylcarnitine. Neither NAD reduction nor oxygen uptake were observed when the mitochondria were provided with palmitoylcarnitine only. The oxygen uptake due to glycine oxidation by mitochondria from green sunflower (Helianthus annuus L.) cotyledons was affected by palmitoylcarnitine in a similar manner to the oxygen uptake of pea cotyledon and potato tuber mitochondria in the presence of sparker malate. The results lead to the conclusion that the palmitoylcarnitine-dependent stimulation of mitochondrial oxygen uptake observed in the presence of sparker malate results substantially from an enhanced malate oxidation due to the detergent effect of palmitoylcarnitine on the mitochondrial membranes, rather than from palmitoylcarnitine -oxidation.Abbreviations BSA bovine serum albumin - CCCP carbonylcyanide m-chlorophyenylhydrazone The work was supported by the Deutsche Forschungsgemeinschaft.     

Rapid auxin- and fusicoccin-enhanced Rb+ uptake and malate synthesis in Avena coleoptile sections

The short-term effects of auxin (indole-3-acetic acid) and fusicoccin (FC) on Rb⁺ uptake and malate accumulation in Avena sativa L. coleoptile sections have been investigated. FC stimulates ⁸⁶Rb⁺ uptake within 1 min while auxin-enhanced uptake begins after a 15–20-min lag period. Auxin has little or no effect on ⁸⁶Rb⁺ uptake at external pHs of 6.0 or less, but substantial auxin effects can be observed in the range of pH 6.5 to 7.5. Competition studies indicate that the uptake mechanism is specific for Rb⁺ and K⁺. After 3 h of auxin treatment the total amount of malate in the coleoptile sections is doubled compared to control sections. FC causes a doubling of malate levels within 60 min of treatment. Auxin-induced malate accumulation exhibits a sensitivity to inhibitors and pH which is similar to that observed for the H⁺-extrusion and Rb⁺-uptake responses. Both auxin- and FC-enhanced malate accumulation are stimulated by monovalent cations but this effect is not specific for K⁺.Abbreviations FC fusicoccin - IAA indole-3-acetic acid     

Identification with a photoaffinity reagent of a tonoplast protein involved in vacuolar malate transport of Catharanthus roseus

The effect of N-(4-azido-salicylyl) aspartic acid (AzSA), a photolysable analogue of malate, was tested on the malate transport activity of tonoplast vesicles isolated from Catharanthus roseus cell suspension cultures. AzSA inhibited malate uptake in a competitive manner with a K_ti of 1.7 millimolar. When iodinated, the malate analogue was found to be still photolysable and a competitive inhibitor of malate uptake. Photolysis of ¹²⁵I-labelled AzSA in the presence of purified tonoplast vesicles led to label incorporation into several polypeptides after analysis by gel electrophoresis. Only one polypeptide, with an apparent molecular mass of 37 kDa, was totally protected by the inclusion of 50 millimolar malate, the original substrate, in the photolysis medium. The labelled polypeptide is therefore apparently a specific malate-binding protein. Diethylpyrocarbonate (DEPC), a very potent inhibitor of malate transport acting at the active site of the transporter, also protected the 37 kDa polypeptide from labelling. Citrate and, to a lesser extent, quinate afforded protection from labelling whilst other organic acids or aspartic acid (100 millimolar) did not. These photoprotection results are in good agreement with the data concerning the specificity of malate transport across the tonoplast. Polyclonal antibodies against the 37 kDa polypeptide strongly inhibited malate uptake both in tonoplast vesicles and in isolated vacuoles. These results suggest the involvement of the 37 kDa polypeptide in vacuolar malate transport.     

Malate Uptake into Isolated Vacuoles from Catharanthus roseus Cells: Role of the Membrane Potential

The mechanisms involved in the transport of malate into isolated vacuoles of Catharanthus roseus (L.) cells were investigated with special reference to the effects of induced changes in membrane potential and surface charges of the tonoplast. For this purpose, thiocyanate (SCN^?), a highly permeant anion often used as a membrane potential probe, was extensively exploited. In the absence of Mg-ATP, the low accumulation ratio of ¹⁴C SCN^? could be related to the presence of negative charges at the outer surface of the tonoplast exerting a screening effect on the displacement of lipophilic anionic species. Nevertheless, malate was taken up continuously by vacuoles supporting the concept of a transport component which facilitates its transfer through the tonoplast. From experiments showing the pH dependence of malata uptake, it is suggested that the protonated form of the transporter is implicated in this process. Moreover, when the vacuoles are energized by Mg-ATP, the study of the equilibrium distribution of ¹⁴C SCN^? indicated an inside positive membrane potential difference. Advantage was taken of these results to modulate the membrane potential with high levels of thiocyanate. The data obtained demonstrate that malate uptake results from electrophoretic movement in response to the positive potential difference.     

Effects of increasing inorganic carbon supply to roots on net nitrate uptake and assimilation in tomato seedlings

We investigated the influence of an increased inorganic carbon supply in the root medium on NO^?₃ uptake and assimilation in seedlings of Lycopersicon esculentum (L.) Mill. cv. F144. The seedlings were pre-grown for 4 to 7 days with 0 or 100 mM NaCl in hydroponic culture using 0.2 mM NO^?₃ (group A) or 0.2 mM NH⁺₄ (group B) as nitrogen source. The nutrient solution for group A plants was aerated with air or with air containing 4 800 μumol mol^?1 CO₂. Nitrate uptake rate and root and leaf malate contents in these plants were determined. The plants of group B were subdivided into two sets. Plants of one set were transferred either to N-free solution containing 0 or 5 mM NaHCO₃, or to a medium containing 2 mM NO^?₃ and 5 mM NaHCO₃. Both sets of group B plants were grown for 12 h in darkness prior to 2 h of illumination, and were assayed for malate content and NO^?₃ uptake rate (only for plants grown in N-free solution). The second set of group B plants was labeled with ¹⁴C by a 1-h pulse of H¹⁴CO^?₃ which was added to a 5 mM NaHCO₃ solution containing 0 or 100 mM NaCl and 0 or 2 mM NO^?₃, and ¹⁴C-assimilates were extracted and fractionated. The roots of group B plants growing in carbonated medium accumulated twice as much malate as did control plants. This malate was accumulated only when NO^?₃ was absent from the root medium. Both a high level of root malate and aeration with CO₂-enriched air stimulated NO^?₃ uptake. Analysis of ¹⁴C-assimilates indicated that with no NO^?₃ in the medium, the ¹⁴C was present mainly in organic acids, whereas with NO^?₃, a large proportion of ¹⁴C was incorporated into amino acids. Transport of root-incorporated ¹⁴C to the shoot was enhanced by NO^?₃, while the amino acid fraction was the major ¹⁴C-assimilates in the shoot. It is concluded that inorganic carbon fixed through phosphoenolpyruvate carboxylase (EC 4.1.1.31) in roots of tomato plants may have two fates: (a) as a carbon skeleton for amino acid synthesis; and (b) to accumulate, mainly as malate, in the roots, in the absence of a demand for the carbon skeleton. Inorganic carbon fixation in the root provides carbon skeletons for the assimilation of the NH⁺₄ resulting from NO₃ reduction, and the subsequent removal of amino acids through the xylem. This ‘removal’ of NO^?₃ from the cytoplasm of the root cells may in turn increase NO^?₃ uptake.     

Effects of fusicoccin on the activity of a key pH-stat enzyme,PEP-carboxylase

The phytotoxin fusicoccin (FC) causes rapid synthesis of malate in coleoptile tissues, presumably via phosphoenolpyruvate (PEP) carboxylase coupled with malate dehydrogenase. The possibility that FC directly affects PEP carboxylase in Avena sativa L. and Zea mays L. coleoptiles was studied and rejected. The activity of this enzyme is unaffected by FC whether FC is added in vitro or a pretreatment to the live material. FC does not change the sensitivity of the enzyme to bicarbonate or malate. The activity of FC, instead, appears to be indirect. The pH sensitivity of PEP carboxylase is such that its activity, and thus the rate of malate synthesis, may be enhanced by an increase in cytoplasmic pH accompanying FC-induced H⁺ excretion. Since the enzyme is also particularily sensitive to bicarbonate levels, malate synthesis may also be enhanced by FC-induced uptake or generation of CO₂.     

Effect of Phloem-Translocated Malate on NO(3) Uptake by Roots of Intact Soybean Plants

In soybean (Glycine max L. Merr. cv Kingsoy), NO₃⁻ assimilation in leaves resulted in production and transport of malate to roots (B Touraine, N Grignon, C Grignon [1988] Plant Physiol 88: 605-612). This paper examines the significance of this phenomenon for the control of NO₃⁻ uptake by roots. The net NO₃⁻ uptake rate by roots of soybean plants was stimulated by the addition of K-malate to the external solution. It was decreased when phloem translocation was interrupted by hypocotyl girdling, and partially restored by malate addition to the medium, whereas glucose was ineffective. Introduction of K-malate into the transpiration stream using a split root system resulted in an enrichment of the phloem sap translocated back to the roots. This treatment resulted in an increase in both NO₃⁻ uptake and C excretion rates by roots. These results suggest that NO₃⁻ uptake by roots is dependent on the availability of shoot-borne, phloem-translocated malate. Shoot-to-root transport of malate stimulated NO₃⁻ uptake, and excretion of HCO₃⁻ ions was probably released by malate decarboxylation. NO₃⁻ uptake rate increased when the supply of NO₃⁻ to the shoot was increased, and decreased when the activity of nitrate reductase in the shoot was inhibited by WO₄²⁻. We conclude that in situ, NO₃⁻ reduction rate in the shoot may control NO₃⁻ uptake rate in the roots via the translocation rate of malate in the phloem.     

Oxygen and carbon dioxide exchanges in crassulacean-acid-metabolism-plants

The 24 h O₂ uptake and release together with the CO₂ balance have been measured in two CAM plants, one a non-succulent Sempervivum grandifolium, the other a succulent Prenia sladeniana. The O₂ uptake was estimated by the use of ¹⁸O₂. It was found that the mean hourly O₂ uptake in the light was 7 times that in the dark for Sempervivum and 5 times that for Prenia, after correction for the lightdark temperature difference. It was estimated that oxygen uptake in the light was 2.4 times greater than oxygen release (=net photosynthesis) in Sempervivum and 1.4 times greater in Prenia. In both plants there was a positive carbon balance over the 24 h period under the experimental conditions. It was estimated that malate formed during the night could, if completely oxidized to CO₂ and water, account for 74% of the light phase O₂ uptake in Sempervivum. In Prenia the O₂ uptake was more than sufficient to account for a full oxidation of malate.Abbreviations CAM Crassulacean acid metabolism - PAR photosynthetically active radiation - PEP phosphoenolpyruvate - RrBP ribulose-1,5-bisphosphate - TCA tricarboxylic acid cycle     

CO2 and malate metabolism in starch-containing and starch-lacking guard-cell protoplasts

Isolated, purified mesophyll and guard-cell protoplasts of Vicia faba L. and Allium cepa L. were exposed to ¹⁴CO₂ in the light and in the dark. The guard-cell protoplasts of Vicia and Allium did not show any labeling in phosphorylated products of the Calvin cycle, thus appearing to lack the ability to reduce CO₂ photosynthetically. In Vicia, high amounts of radioactivity (35%) appeared in starch after 60-s pulses of ¹⁴CO₂ both in the light and in the dark. Presumably, the ¹⁴CO₂ is fixed into the malate via PEP carboxylase and then metabolized into starch as the final product of gluconeogenesis. This is supported by the fact that guard-cell protoplasts exposed to malic acid uniformly labeled with ¹⁴CO₂ showed high amounts of labeled starch after the incubation, whereas cells labeled with [4-¹⁴C]malate had minimal amounts of labeled starch (1/120).In contrast, the starch-deficient Allium, guard-cell protoplasts did not show any significant ¹⁴CO₂ fixation. However, adding PEP to an homogenate stimulated ¹⁴CO₂ uptake, thus supporting the interpretation that the presence of starch as a source of PEP is necessary for incorporating CO₂ and delivering malate. With starch-containing Vicia guard-cell protoplasts, the correlation between changes in volume and the interconversion of malate and starch was demonstrated. It was shown that the rapid gluconeogenic conversion of malate into starch prevents an increase of the volume of the protoplasts, whereas the degradation of starch to malate is accompanied by a swelling of the protoplasts.Abbreviations GCPs guard-cell protoplasts - MCPs mesophyll cell protoplasts - PEP phosphoenolpyruvate - DTT dithiothreitol - 3-PGA 3-phosphoglyceric acid - RiBP ribulose 1,5 bisphosphate - MDH malate dehydrogenase - MES 2-(N-morpholino)ethane sulfonic acid - CAM crassulacean acid metabolism     

Dicarboxylate transport in maize mesophyll chloroplasts

Evidence is presented for high rates of carrier-mediated dicarboxylate anion transport in maize mesophyll chloroplasts. Radioactively labeled malate is transported across the chloroplast envelope leading to accumulation in the stroma. Malate in the stroma will exchange for external malate, oxaloacetate, glutamate, aspartate, and oxoglutarate. At 4 °C the V of malate uptake is 50 μmol·h^?1·mg Chl^?1 and the K_m for malate is 0.5 mm. Oxaloacetate competitively inhibits malate uptake with a K_i estimated to be 0.3 mm. The temperature dependence of malate uptake indicates an activation energy of 12 kcal/mol, and extrapolation using this value gives a rate of transport at 30 °C of approximately 300 μmol·h^?1·mg Chl^?1. This rate approximates the rates of photosynthetic malate production by these chloroplasts.     

Specificity and regulation of the dicarboxylate carrier on the peribacteroid membrane of soybean nodules

Malate and succinate were taken up rapidly by isolated, intact peribacteroid units (PBUs) from soybean (Glycine max (L.) Merr.) root nodules and inhibited each other in a competitive manner. Malonate uptake was slower and was severely inhibited by equimolar malate in the reaction medium. The apparent K_m for malonate uptake was higher than that for malate and succinate uptake. Malate uptake by PBUs was inhibited by (in diminishing order of severity) oxaloacetate, fumarate, succinate, phthalonate and oxoglutarate. Malonate and butylmalonate inhibited only slightly and pyruvate,isocitrate and glutamate not at all. Of these compounds, only oxaloacetate, fumarate and succinate inhibited malate uptake by free bacteroids. Malate uptake by PBUs was inhibited severely by the uncoupler carbonylcyanidem-chlorophenyl hydrazone and the respiratory poison KCN, and was stimulated by ATP. We conclude that the peribacteroid membrane contains a dicarboxylate transport system which is distinct from that on the bacteroid membrane and other plant membranes. This system can catalyse the rapid uptake of a range of dicarboxylates into PBUs, with malate and succinate preferred substrates, and is likely to play an important role in symbiotic nitrogen fixation. Energization of both the bacteroid and peribacteroid membranes controls the rate of dicarboxylate transport into peribacteroid units.     

Binding protein dependent transport of C4-dicarboxylates in Rhodobacter capsulatus

The characteristics of malate transport into aerobically grown cells of the purple photosynthetic bacterium Rhodobacter capsulatus were determined. A single transport system was distinguished kinetically which displayed a K_t value of 2.9 ± 1.2 μM and V_max of 43 ± 6 nmol · min^-1 · mg^-1 protein. Competition experiments indicated that the metabolically related C4-dicarboxylates succinate and fumarate are also transported by this system. Malate uptake was sensitive to osmotic shock and evidence from the binding of radiolabelled malate and succinate to periplasmic protein fractions indicated that transport is mediated by a dicarboxylate binding protein. The activity of the transport system was studied as a function of external and internal pH and it was found that a marked activation of uptake occurred at intracellular pH values greater than 7. The use of a high affinity binding protein dependent system to transport a major carbon and energy source suggests that Rhodobacter capsulatus would be capable of obtaining growth sustaining quantities of C4-dicarboxylates even if these were present at very low concentrations in the environment.     

Characteristics,partial purification and reconstitution of the vacuolar malate transporter of the CAM plant Kalanchoë daigremontiana Hamet et Perrier de la Bâthie

When native tonoplast vesicles of Kalanchoë daigremontiana Hamet et Perrier de la Bâthie were energized by an artificial K⁺ gradient establishing only an inside-positive electrical membrane potential (), it was shown that was sufficient as the sole driving force and that a proton gradient (pH) is not required for malate uptake. Following [¹⁴C]malate uptake, K _m-malate of the malate transporter was estimated as 2.7–3.0 mM, a value that would allow malate synthesis via phosphoenolpyruvate carboxylase and malate accumulation in vivo in view of the feed-back inhibition of cytosolic phosphoenolpyruvate carboxylase by malate. The maximum reaction velocity (V _max) was found to be between 30 and 85 nmol malate·min^–1·mg _protein ^–1 , a value that would explain nocturnal malate accumulation in K. daigremontiana even if the transporter were operating below substrate saturation. Citrate (50 mM at pH 7) inhibited transport by 78%. The malate-transport protein of the tonoplast of K. daigremontiana may be a carboxylate uniporter with strong affinities for malate and citrate. From total tonoplast proteins solubilized from native tonoplast vesicles the malate transporter was functionally reconstituted into phospholipid liposomes. The malate transporter was purified and separated from the tonoplast H⁺-ATPase by hydroxyapatite chromatography, but not from the tonoplast H⁺-pyrophosphatase. The partially purified malate-transport protein was functionally reconstituted into phospholipid liposomes. In these final proteoliposomes, 0.6% of the protein of the initial tonoplast-vesicle preparation used for solubilization of membrane proteins was recovered. Using the specific rates of malate transport as a reference, i.e. rates of transport related to protein in the preparations, enrichment of the malate transporter in the final proteoliposomes obtained with the reconstitution of the hydroxyapatite eluate was 44-fold compared to the initial native tonoplast vesicles and 2000-fold compared to the liposomes reconstituted from solubilized tonoplast proteins. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of the peptides from the final proteoliposomes, which were functional in malate transport, showed only a few polypeptide bands among which the malate transporter must be found.Abbreviations and Symbols CAM Crassulacean acid metabolism - DIDS 4,4-diisothiocyanatostilbene-2,2-disulfonic acid - Triton X-100 polyoxyethylene(9,10)p-t-octylphenol - pH proton gradient at the tonoplast - membrane potential at the tonoplast This work was supported by the Deutsche Forschungsgemeinschaft and by the Fonds der Chemischen Industrie and is now funded in SFB 199 (Teilprojekt B2) of the Deutsche Forschungsgemeinschaft. We thank Dr. Elke Fischer-Schliebs for valuable discussions and Dr. E. Martinoia for making us acquainted with his experimental approaches in his laboratory in Zürich, Switzerland, and for much valuable exchange. Dr. D.P.S. Verma, Ohio, USA, kindly provided Nod-26 antibodies, and the tonoplast H⁺-pyrophosphatase antibodies were a generous gift of Dr. M. Maeshima, Sapporo, Japan.     

Circadian rhythms in Kalanchoë: effects of irradiance and temperature on gas exchange and carbon metabolism

Gas exchange in K. blossfeldiana shows a circadian rhythm in net CO₂ uptake and transpiration when measured under low and medium irradiances. The period length varies between 21.4 h at 60 W m^-2 and 24.0 h at 10 W m^-2. In bright light (80 W m^-2) or darkness there are no rhythms. High leaf temperatures result in a fast dampening of the CO₂-uptake rhythm at moderate irradiances, but low leaf temperatures can not overcome the dampening in bright light. The rhythm in CO₂ uptake is accompanied by a less pronounced and more rapidly damped rhythm in transpiration and by oscillations in malate levels with the amplitude being highly reduced. The oscillations in starch content, usually observed to oscillate inversely to the acidification in light-dark cycles, disappear after the first cycle in continuous light. The balance between starch and malate levels depends in continuous light on the irradiance applied. Leaves show high malate and low starch content at low irradiance and high starch and low malate in bright light. During the first 12 h in continuous light replacing the usual dark period, malate synthesis decreases with the increasing irradiance. Up to 50 W m^-2 starch content decreases; at higher irradiances it increases above the values usually measured at the end of the light period of the 12:12 h light-dark cycle.Abbreviations CAM Crassulacean acid metabolism - FW fresh weight - PEP phosphoenolpyruvate     

Citrate transport in corn mitochondria

Citrate uptake by corn mitochondria (Zea mays L. B73 × Mol9) was investigated by osmotic swelling and [¹⁴C]citrate accumulation. Uptake driven by passive influx, ammonium gradients, and respiration was followed. There was no requirement for phosphate and/or malate to secure citrate uptake, although under some conditions these additives were promotive. Inhibition of the phosphate and dicarboxylate carriers did not eliminate citrate uptake. Citrate_in/malate_out exchange occurs, but at a rate too slow to account for observed citrate uptake, and depletion of endogenous malate only reduced citrate uptake by 38%. It was concluded that citrate can be rapidly accumulated by a mechanism other than by exchange for dicarboxylates. The effect of uncoupler on respiration-driven [¹⁴C]citrate accumulation, and studies of passive swelling using ionophores and uncouplers indicated that the major avenue of citrate uptake is by H⁺/citrate co-transport with a pH optimum near 4.5. The in vivo role of this mechanism is not yet understood.     

The effect of phosphoenolypyruvate on calcium transport by mitochondria

Phosphoenolpyruvate was found to inhibit net uptake of Ca²⁺ by rat heart and liver mitochondria. The main action of phosphoenolpyruvate is to increase the rate of efflux of mitochondrial Ca²⁺. The effect of phosphoenolpyruvate on mitochondrial Ca²⁺ transport is antagonized by ATP and by atractylate and is observed when mitochondria are respiring in the presence of NAD-linked subtrates such as glutamate and pyruvate plus malate. In liver mitochondria phosphoenolpyruvate is also effective in the presence of succinate but not when rotenone is added. Glycolytic intermdiates other than phosphoenolpyruvate had little effect on mitochondrial Ca²⁺ transport.     

Citrate transport into barley mesophyll vacuoles — comparison with malate-uptake activity

Citrate uptake into barley (Hordeum vulgare L.) mesophyll vacuoles was found to be saturable with a K _m of about 200 M. Uptake appears to occur via the citrate^3- form, as indicated by concentration-dependent uptake studies at different pHs. Free citrate and not the Mg-citrate complex was taken up by the vacuoles, even though slow transport of the Mg complex could not be excluded. Citrate transport into vacuoles was competitively inhibited by malate (K _i=0.68 mM). Various organic acids and protein-modifying agents affected the uptake of malate and citrate to a similar extent. These results indicate that both organic acids cross the tonoplast by means of the same carrier. Accumulation of citrate was ATP-dependent and could be inhibited by ionophores. Bovine serum albumin strongly stimulated citrate uptake, but other proteins tested did not show a similar stimulatory effect.Abbreviation BSA bovine serum albumin We wish to thank Esther Vogt for her help with the experiments and Professor N. Amrhein (ETH, Zürich, Switzerland) and Dr. Michael Kertesz (ETH, Zürich) for helpful discussions. This work was supported by the Swiss National Foundation grant No. 31-25196.88.     

Some Reactions of Isolated Corn Mitochondria Influenced by Juglone

The effects of juglone on the uptake of O₂ by excised corn roots (Zea mays L., Wf9 cms- T × M14) and isolated corn mitochondria arc reported. The O₂ uptake by excised corn roots, as measured by an O₂ electrode, was inhibited more than 90% after a one-hour treatment of 500 μM juglone. Lesser inhibitions were observed with 50 μM and 250 μM juglone. In a KC1 reaction medium in the absence of inorganic phosphate (Pi), juglone stimulated the rate of O₂ uptake by isolated mitochondria oxidizing NADH, succinate, or malate + pyruvate. In the presence of Pi, juglone concentrations of 3 μM and greater inhibited the state 3 oxidation rates of succinate and malate + pyruvate, lowered respiratory control and ADP/O ratios obtained from the oxidation of NADH, malate + pyruvate, or succinate, and reduced the coupled deposition of calcium phosphate within isolated mitochondria driven, by the oxidation of malate + pyruvate. The inhibition of state 3 O₂ uptake by isolated mitochondria, an oxidative state in which electron transfer is coupled to ATP production, is seen to correlate with the inhibition affected by juglone when applied to tissues in vivo.     

Kinetics of malate transport and decomposition in acid soils and isolated bacterial populations: The effect of microorganisms on root exudation of malate under Al stress

The kinetics and characteristics of malate degradation were studied in four acid soils ranging in both pH (4.30 to 5.00) and vegetation type. The breakdown of malate was rapid in all soils with a half life of approximately 1.7 h, K_m of 1.7 mM and V_max of 70 nmol g^–1 soil h^–1. No relationship was observed between malate decomposition rate and pH. Co-metabolism studies with other C and N substrates (glucose, glycine, glutamate, citrate and succinate) indicated that the microorganisms were not N limited and competitive inhibition of malate breakdown was only observed in the presence of succinate. Studies with isolated mixed bacterial cultures indicated that the bacterial malate uptake was mediated by an energy dependent, dicarboxylate transporter which can be inhibited by succinate and is independent of pH between pH 5.0 and 7.0. The K_m and V_max parameters ranged from 279–955 M and 0.1–17 mol mg^–1 protein h^–1 for the mixed bacterial cultures depending on the bacteria's previous C source. The results indicate that in acid topsoils where microbial populations are high, the microbes may provide a considerable sink for organic acids. If organic acids are being released by roots in response to an environmental stress (e.g. Al toxicity, P deficiency) it can be expected that the efficiency of these root mediated metal resistance mechanisms will be markedly reduced by rapid microbial degradation.     

Malate Metabolism in the Dark After CO(2) Fixation in the Crassulacean Plant Kalanchoë tubiflora

The metabolism of [¹³C]malate was studied in the Crassulacean plant Kalanchoë tubiflora following exposure to ¹³CO₂ for 2 hour intervals during a 16 hour dark cycle. Nuclear magnetic resonance spectroscopy of [¹³C]malate extracted from labeled tissue revealed that the transient flux of malate to the mitochondria, estimated by the randomization of [4-¹³C]malate to [1- ¹³C]malate by fumarase, varied substantially during the dark period. At both 15 and 25°C, the extent of malate label randomization in the mitochondria was greatest during the early and late parts of the dark period and was least during the middle of the night, when the rate of ¹³CO₂ uptake was highest. Randomization of labeled malate continued for many hours after malate synthesis had initially occurred. Internally respired ¹²CO₂ also served as a source of carbon for malate formation. At 15°C, 15% of the total malate was formed from respired ¹²CO₂, while at 25°C, 49% of the accumulated malate was derived from respired ¹²CO₂. Some of the malate synthesized from external ¹³CO₂ was also respired during the night. The proportion of the total [¹³C]malate respired during the dark period was similar at 15 and 25°C, and respiration of newly formed [¹³C]malate increased as the night period progressed. These data are discussed with regard to the relative fluxes of malate to the mitochondria and the vacuole during dark CO₂ fixation.