Stimulatory effects of 2,4-dichlorophenoxyacetic acid and of 1-naphthylacetic acid on sucrose level,invertase activity and sucrose utilization in the latex ofHevea brasiliensis

Summary Treatment of the bark ofHevea brasiliensis with 2,4-dichlorophenoxyacetic acid (2,4-D) or l-naphthylacetic acid (NAA) greatly increases sucrose level, invertase activity and sucrose utilization in the latex; the efficacy of 2,4-D is considerably greater than that of NAA. The greater sucrose utilization is the consequence of increased invertase activity. The changes occur as soon as the first tapping following bark treatment. It is suggested that the rise in both sucrose level and utilization in the latex serum mediate the effect of auxins on latex production. This is most likely related to a faciliation of latex outflow resulting from an increase in the osmotic and turgor pressure in the laticiferous tissue, as well as to enhanced regeneration of latex.The latex invertase has been found to be of a weakly alkaline type, with a sharp pH optimum at 7.15–7.20 in citrate-phosphate buffer. Its activity falls of rapidly on the acid side, being almost zero at pH 6.4. Since the natural pH of latex generally varies between pH 6.5 and 7.0, it is suggested that pH is an important factor in the regulation of invertase activity in the latex, and that the limiting nature of invertase-mediated sucrose hydrolysis in latex serum is caused by unfavourable conditions for invertase activity rather than by a scarcity of this enzyme.Expert of the International Atomic Energy Agency.     

The Regulation of Invertase Activity in the Latex of Hevea brasiliensis Muell. Arg: THE EFFECTS OF GROWTH REGULATORS, BARK WOUNDING, AND LATEX TAPPING

Treatments which increase latex yield, e. g. bark scraping,latex tapping, and bark application of 2, 4-D or 2-chloroethylphosphonicacid (CEPA) were found to enhance the activity of latex invertase.In previously untapped trees, both the introduction of tappingand the application of 2, 4-D brought about an increase in thelevel of invertase. In regularly tapped trees, the amount oflatex invertase is several times higher than in untapped treesand evidence was obtained that its activity is regulated bythe variation of latex pH. The pH of latex of the clone investigated(PR 107) was shown to vary between 6.3 and 7.1 whereas the activityof invertase, as assayed directly in the latex, has a sharpoptimum at pH 7.5 and falls rapidly with the shift of pH tothe acid side. There was no increase in the content of latexinvertase when trees adapted to regular tapping were treatedwith 2, 4-D. The effect of auxin on actual invertase activitywas essentially mediated through related increase of latex pH.The CEPA and bark scraping were also shown to increase latexpH in tapped trees. The treatment of the bark of tapped trees with CEPA increasedthe level of latex sucrose, as did auxins. Bark scraping alsohad a slight stimulatory effect. The K_m of latex invertase asa function of pH was found to change in the same way as V_max,being highest at pH optimum.     

Some aspects of sucrose transport and utilization in latex producing bark ofHevea brasiliensis Muel. Arg

The radiotracer technique is described for transport and metabolic studies in latex producing bark. This technique provided further evidence that carbohydrates are supplied to latex vessels as sucrose and that sucrose is readily used for rubber synthesis. Bark treatment with ethylene resulting in latex flow stimulation is shown to activate within a few hours sucrose and water transport into the latex vessels. The available knowledge suggests an implication of an energy-dependent process of proton excretion which could explain the earlier observed ethylene induced alkalization of latex cytosol enhancing invertase and sucrose utilization. An increase of tapping intensity decreases the level of latex sucrose and changes its distribution pattern in drained bark. There is a clonal difference in the early response to exploitation. Bark excision by conventional tapping inhibits downward sucrose translocation, the inhibition being proportional to the surface of consumed bark above the tapping cut. Seasonal variation in the level of latex sucrose is related to variations in sunshine duration and sucrose concentration rises during the process of refoliation. The results stress the importance of sucrose supply to latex vessels for latex producing potentialities and indicate an association of low sucrose availability in latex vessels with premature latex vessel degeneration and bark dryness.     

Photosynthate allocation and productivity of latex vessels inHevea brasiliensis

Manipulations of production systems in rubber tree which were intended to improve sucrose translocation in tapped bark resulted in an increase of latex sucrose and of latex production and reduced the incidence of nonyielding laticiferous tissue. This was achieved by shortening the tapping cut from full to half spiral, by changing the descending direction into an ascending mode of tapping or by annual change-over of tapping panel allowing for a longer time the regeneration of bark removed above the location of the cut. The increase of latex yield did not result in a significant decrease in the growth of trees over a period of three years. Clonal differences in nonyielding bark appeared to be related to differences in sucrose depletion by tapping. In clone PB 235 which exhibited low latex sucrose, a reduction of tapping frequency resulted in an increase in sucrose level and in a decrease of bark “dryness” tending to an increase in total yield. The tapping manipulations examined did not affect latex flow characteristics such as the plugging index of latex vessels and the bursting index of lutoids. The results stress the importance of photosynthate allocation for the physiology of laticiferous system productivity and indicate the possibilities of improving assimilate economy in rubber trees. On mission as export of the International Atomic Energy Agency.     

Characterization and properties of the pyruvate phosphorylation system of Acetobacter xylinum

The enzyme responsible for the direct phosphorylation of pyruvate during gluconeogenesis in Acetobacter xylinum has been purified 46-fold from ultrasonic extracts and freed from interfering enzyme activities. The enzyme was shown to catalyze the reversible Mg(2+) ion-dependent conversion of equimolar amounts of pyruvate, adenosine triphosphate (ATP), and orthophosphate (P(i)) into phosphoenolpyruvate (PEP), adenosine monophosphate (AMP), and pyrophosphate (PP). The optimal pH for PEP synthesis was pH 8.2; for the reversal it was pH 6.5. The ratio between the initial rates of the reaction in the forward and reverse directions was 5.1 at pH 8.2 and 0.45 at pH 6.5. The apparent K(m) values of the components of the system in the forward reaction were: pyruvate, 0.2 mm; ATP, 0.4 mm; P(i), 0.8 mm; Mg(2+), 2.2 mm; and for the reverse reaction: PEP, 0.1 mm; AMP, 1.6 mum; PP, 0.067 mm; Mg(2+), 0.87 mm. PEP formation was inhibited by AMP and PP. The inhibition by AMP was competitive with regard to ATP (K(i) = 0.2 mm). The reverse reaction was inhibited competitively by ATP and noncompetitively by pyruvate. The enzyme was strongly inhibited by p-hydroxymercuribenzoate. The inhibition was reversed by dithiothreitol and glutathione. The properties of the enzyme are discussed in relation to the regulation of the opposing enzymatic activities involved in the interconversion of PEP and pyruvate in A. xylinum.     

The pH dependence of the allosteric response of human liver pyruvate kinase to fructose-1,6-bisphosphate, ATP, and alanine

The allosteric regulation of human liver pyruvate kinase (hL-PYK) by fructose-1,6-bisphosphate (Fru-1,6-BP; activator), ATP (inhibitor) and alanine (Ala; inhibitor) was monitored over a pH range from 6.5 to 8.0 at 37 °C. As a function of increasing pH, hL-PYK’s affinity for the substrate phosphoenolpyruvate (PEP), and for Fru-1,6-BP decreases, while affinities for ATP and alanine slightly increases. At pH 6.5, Fru-1,6-BP and ATP elicit only small allosteric impacts on PEP affinity. As pH increases, Fru-1,6-BP and ATP elicit greater allosteric responses, but the response to alanine is relatively constant. Since the magnitudes of the allosteric coupling for ATP and for alanine inhibition are different and the pH dependences of these magnitudes are not similar, these inhibitors likely elicit their responses using different molecular mechanisms. In addition, our results fail to support a general correlation between pH dependent changes in effector affinity and pH dependent changes in the corresponding allosteric response.     

Anaerobic respiration in latex ofHevea brasiliensis substrate and limiting factors

The site of anaerobic respiration in the latex is the serum. The main respiratory substrate is fructose. The CO₂ formation in serum is increased by additional fructose on the average about 2.5–3 times. Glucose does not influence CO₂ evolution by serum but slightly increases O₂ consumption. With respect to sugars, latex serum contains essentially only sucrose and a low amount of raffinose. During the incubation of serum sucrose is hydrolysed, the fructose component is immediately utilized in respiration and glucose accumulates. The rate of CO₂ formation in latex as influenced by fructose is negatively related to the rubber content of the latex. Latex with a high rubber content reacts only slightly or not at all on additional fructose. The main limiting factors of latex respiration and sugar utilization are the following:

1. The deficiency of substrate, due to low activity of β-fructofuranosidase.
2. The rate of glucose phosphorylation (D'Auzac, Jacob 1967).
3. Presumably the low activity of phosphoglucoisomerase.
4. The rubber content of the latex.
5. The concentration of CO₂ in latex; this factor may be important in vivo, in the laticiferous system.

     

Entamoeba histolytica: kinetic and molecular evidence of a previously unidentified pyruvate kinase

We report the kinetic characterization of a previously unidentified pyruvate kinase (PK) activity in extracts from Entamoeba histolytica trophozoites. This activity was about 74% of the activity of pyruvate phosphate dikinase. EhPK differed from most PKs in that its pH optimum was 5.5-6.5 and was inhibited by high PEP concentrations (1-5mM); these are concentrations at which PK is usually assayed. The optimal temperature was above 40 degrees C with negligible activity below 20 degrees C. EhPK exhibited hyperbolic kinetics with respect to both PEP (K(m) = 0.018 mM) and ADP (K(m) = 1.05 mM). However, it exhibited a sigmoidal behavior with respect to PEP at sub-saturating ADP concentrations. EhPK did not require monovalent cations for activity. Fructose-1,6 bisphosphate was a potent non-essential activator; it increased the affinity for ADP without modification of the V(max) or the affinity for PEP. Phosphate, citrate, malate, and alpha-ketoglutarate significantly inhibited EhPK activity. A putative EhPK gene fragment found in EhDNA was analyzed. The data indicate that E. histolytica trophozoites contain an active PK, which might contribute to the generation of glycolytic ATP for parasite survival.     

Depolymerization of beta-chitin to mono- and disaccharides by the serum fraction from the para rubber tree, Hevea brasiliensis

The serum fraction of latex from Hevea brasiliensis, the para rubber tree, is known to contain an endo-chitinolytic enzyme, hevamine. Herein the activity of the rubber serum towards beta-chitin is investigated. The serum contained 6 mg/mL of protein and a chitinolytic activity of 18 mU permg of protein. The optimum ratio of enzyme to chitin was 0.22 mU/mg, and the optimum substrate concentration was 60 mg/mL. The optimum pH range was pH2-4, and the optimum temperature was 45 degrees C. At these conditions both (GlcNAc)2 and GlcNAc were produced in a molar ratio of approximately 2:1. The hydrolysis of 300 mg of chitin with 64 mU of the rubber serum for 8 days under the optimum conditions gave 39 mg of GlcNAc and 108 mg of (GlcNAc)2 as determined by HPLC. Mixing the rubber serum preparation with an Aspergillus niger pectinase preparation containing beta-N-acetylhexosaminidase can be used to produce almost exclusively the GlcNAc monomer in about 50% yield.     

Interference by phosphatases in the spectrophotometric assay for phosphoenolpyruvate carboxylase

The aim of this work was to discover the extent of interference by phosphoenolpyruvate (PEP) phosphatase in spectrophotometric assays of PEP carboxylase (EC 4.1.1.31) in crude extracts of plant organs. The presence of PEP phosphatase and lactate dehydrogenase (EC 1.1.1.27) in extracts leads to PEP-dependent NADH oxidation that is independent of PEP carboxylase activity, and hence to overestimation of PEP carboxylase activity. In extracts of three organs of pea (Pisum sativum L.: leaves, developing embryos, and Rhizobium nodules), two organs of wheat (Triticum aestivum L.: developing grain and endosperm), and leaves of Moricandia arvensis (L.) D.C., lactate dehydrogenase activity was at most only 16% of that of PEP carboxylase at the pH optimum for PEP carboxylase activity. Endogenous PEP phosphatase and lactate dehydrogenase are thus unlikely to interfere seriously with the assay for PEP carboxylase at its optimum pH. Addition of lactate dehydrogenase to PEP carboxylase assays— a proposed means of correcting for nonenzymic decarboxylation of oxaloacetate to pyruvate—resulted in increases in PEP-dependent NADH oxidation from zero (Rhizobium nodules) to 131% (wheat grains). There was no obvious relationship between the magnitude of this increase and conditions in the assay that might promote oxaloacetate decarboxylation. However, the magnitude of the increase was highly positively correlated with the activity of PEP phosphatase in the extract. Addition of lactate dehydrogenase to PEP carboxylase assays can thus result in very large overestimations of PEP carboxylase activity, and should only be used as a means of correction for oxaloacetate decarboxylation for extracts with negligible PEP phosphatase activity.     

Ethrel (Ethylene Releaser)-Induced Increases in the Adenylate Pool and Transtonoplast DeltapH within Hevea Latex Cells

The treatment of rubber tree (Hevea brasiliensis) bark with chloro-2-ethyl phosphonic acid (ethrel), an ethylene-releasing chemical, induced, after a lag period of 13 to 21 hours, a marked increase in the total adenine nucleotides (essentially ATP and ADP) of latex cells. This rise in the latex adenylate pool was concomitant with a marked decrease in the [ATP]/[ADP] ratio without significant changes in the adenylate energy charge. The apparent equilibrium constant for the adenylate kinase, which appeared to behave as a key enzyme in maintaining the adenylate energy charge in the latex, was considerably reduced, probably as a consequence of the alkalinization of the latex cytosol induced by the treatment with ethrel. To reduce the “sink effect” and activation of the metabolism induced in Hevea bark by regular tapping, the latex was collected by micropuncture (few drops) at increasing distance (5-50 centimeters) above and below an ethrel-treated area on the virgin bark of resting trees. The effect of ethrel was shown to spread progressively along the trunk. The increase in the adenylate pool (essentially ATP) was detectable as early as 24 hours after the bark treatment and was maximum after 6 or 8 days, 5 centimeters as well as 50 centimeters above and below the stimulated bark ring. The correlative vacuolar acidification and cytosolic alkalinization, i.e. the increase in the transtonoplast ΔpH, induced in the latex cells by ethrel were shown to be concomitant with the rise in ATP content of the latex. This suggests that the tonoplast H⁺-pumping ATPase, which catalyzes vacuolar acidification in the latex, is directly and essentially under the control of the availability of its substrate (i.e. ATP) in the latex. The results are discussed in relation to energy-dependent activation of metabolism, and increased rubber production, as induced by the stimulation of rubber trees with ethrel.     

The proton transfer step catalyzed by yeast pyruvate kinase

The nature of the proton donor to the C-3 of the enolate of pyruvate, the intermediate in the reaction catalyzed by yeast pyruvate kinase, was investigated by site-directed mutagenesis and physical and kinetic analyses. Thr-298 is correctly located to function as the proton donor. T298S and T298A were constructed and purified. Both mutants are catalytically active with a decrease in k(cat) and k(cat)/K(m)(,PEP). Mn(2+)-activated T298S and T298A do not exhibit homotropic kinetic cooperativity with phosphoenolpyruvate (PEP) in the absence of fructose 1,6-bisphosphate, although PEP binding to enzyme-Mn(2+) is cooperative. The pH dependence of k(cat) for T298A indicates the loss of pK(a)(,2) = 6.4-6.9. Thr-298 affects the ionization (pK(a) approximately 6.5) responsible for modulation of k(cat). Fluorescence studies show altered dissociation constants of ligands to each enzyme complex upon Thr-298 mutations. The rates of the phosphoryl transfer and proton transfer steps in the pyruvate kinase-catalyzed reaction are altered; pyruvate enolization is affected to a greater extent. Proton inventory studies demonstrate solvent isotope effects on k(cat) and k(cat)/K(m)(,PEP). Fractionation factors are metal-dependent and significantly <1. The data suggest that a water molecule in a water channel is the direct proton donor to enolpyruvate and that Thr-298 affects a late step in catalysis.     

Laser diffraction: A new tool for identification and studies of physiological effectors involved in aggregation-coagulation of the rubber particles from Hevea latex

Latex coagulation is the main limiting factor of rubber yield in Hevea brasiliensis (rubber tree). Using laser diffraction, we set up and optimized a new method for monitoring the kinetics of rubber particle (RP) aggregation, a prerequisite for latex coagulation. In contrast to any previous method used, laser diffraction allows continuous monitoring changes in size of RP aggregates, thereby allowing characterization and quantification of the processes involved in latex coagulation. Using this technique, we confirm that RP aggregating factors are proteins compartmentalized within latex cell vacuoles (lutoids), which, especially at relatively acidic physiological pH, can induce formation of RP aggregates large enough to induce plugging of severed latex vessel extremities. Conversely, latex cytosol was found to harbor anti-aggregating proteins. Further, we were able to titrate the RP-aggregating efficiency of the intralutoidic serum and the anti-aggregating efficiency of the cytosol. Preliminary assays showed that these two parameters were correlated with the yield potential of the tested rubber clones. This method will allow identification and characterization of proteins involved in latex coagulation, hence in rubber yield. We suggest that laser diffraction could be used to monitor the kinetics and characterize the physiological processes involved in aggregation of any particles, organelles or cells.     

The sucrose transporter HbSUT3 plays an active role in sucrose loading to laticifer and rubber productivity in exploited trees of Hevea brasiliensis (para rubber tree)

Efficient sucrose loading in rubber‐producing cells (laticifer cells) is essential for retaining rubber productivity in Hevea brasiliensis, but the molecular mechanisms underlying the regulation of this process remain unknown. Here, we functionally characterized a putative Hevea SUT member, HbSUT3, mainly in samples from regularly exploited trees. When expressed in yeast, HbSUT3 encodes a functional sucrose transporter that exhibits high sucrose affinity with a K_m value of 1.24 mm at pH 4.0, and possesses features typical of sucrose/H ⁺ symporters. In planta, when compared to the expression of other Hevea SUT genes, HbSUT3 was found to be the predominant member expressed in the rubber‐containing cytoplasm (latex) of laticifers. The comparison of HbSUT3 expression among twelve Hevea tissues demonstrates a relatively tissue‐specific pattern, i.e. expression primarily in the latex and in female flowers. HbSUT3 expression is induced by the latex stimulator Ethrel (an ethylene generator), and relates to its yield‐stimulating effect. Tapping (the act of rubber harvesting) markedly increased the expression of HbSUT3, whereas wounding alone had little effect. Moreover, the expression of HbSUT3 was found to be positively correlated with latex yield. Taken together, our results provide evidence favouring the involvement of HbSUT3 in sucrose loading into laticifers and in rubber productivity.     

使用微丝骨架解聚剂对橡胶树进行刺激采胶的研究

初步研究了不同浓度的(1%,5%,10%)KI、饱和浓度的大环内酯作为微丝骨架解聚剂对橡胶树的刺激排胶效果.2%的甲基纤维素处理的橡胶树作为空白.测定了各处理橡胶树的胶乳产量及胶乳的6种生理参数,即干胶含量、总固形物含量、蔗糖含量、无机磷含量、硫醇含量以及镁离子含量.结果表明施用1%KI和饱和浓度大环内酯的橡胶树胶乳产量大量增加,其增产幅度与作为天然橡胶常用刺激采胶剂--0.3%的乙烯利的增产幅度大致相当.比较通过1%KI和饱和浓度大环内酯刺激采胶的胶乳和0.3%的乙烯利刺激采胶的胶乳的各生理参数发现,3种处理得来的胶乳干胶含量和总固形物含量并没有明显的差别,但各处理的其它4个生理参数却差别明显,这意味着KI和饱和浓度大环内酯使橡胶树胶乳增产机制可能与乙烯利的机制不同.值得一提的是,高浓度的KI对橡胶树有明显的副作用,长时间的使用会引起橡胶树死皮病的发生.     

Characterization of two sucrose synthase isoforms in sugarbeet root

Two sucrose synthase isoforms (EC 2.4.1.13) have been identified in developing sugarbeet (Beta vulgaris L.) roots. To aid in understanding the physiological significance of these multiple sucrose synthase isoforms, the two isoforms were partially purified and some of their physical and kinetic properties determined. Both isoforms were tetrameric proteins with native molecular masses of 320 kDa. The isoforms exhibited similar kinetic properties as well as similar changes in activity in response to changes in temperature. The isoforms differed, however, in their subunit composition. Sucrose synthase isoform I (SuSyI) was composed of two 84 kDa subunits and two 86 kDa subunits. Sucrose synthase isoform II (SuSyII) was a homotetramer with a subunit size of 86 kDa. The amino acid composition of the two subunits was similar, although differences in alanine, glycine, isoleucine and lysine content were noted. The activity of the two isoforms differed in response to varying pH conditions. The optimum pH for sucrose cleaving activity was observed at pH 6.0 and 6.5 for SuSyI and SuSyII, respectively. The optimum pH for sucrose synthesizing activity occurred at pH 7.5 and 7.0 for SuSyI and SuSyII, respectively. The observed differences in subunit composition and reactivity at different pH values suggest that multiple isoforms of sucrose synthase may provide a mechanism to regulate sucrose metabolism in sugarbeet root by differential regulation of expression of the two isoforms and modulation of their activity by changes in cellular pH.     

Use of [3,4-14C]Glucose to Assess in vivo Competition for Phosphoenolpyruvate Between Phosphoenolpyruvate Carboxylase and Pyruvate Kinase in Developing Soybean Seeds

According to the conventional glycolytic sequence [3,4-¹⁴C]glucoseyields phosphoenolpyruvate (PEP) labeled in position C-1. Thisyields pyruvate through pyruvate kinase reaction also labeledin C-1. Subsequent metabolism of pyruvate to acetyl CoA releasesradioactive carbon dioxide. Alternatively PEP may be convertedto oxalacetate by PEP carboxylase and then into organic andamino acids which retain the label. The procedure adopted wasto trap carbon dioxide evolved and isolate organic acids producedafter feeding [3,4-¹⁴C]glucose to developing soybean cotyledons.Under conditions of 27?C and pH of 7.5 and 8.5 about 60% ofthe glycolytic carbon was processed by pyruvate kinase and 40%by PEP carboxylase. At lower temperature (15?C) 60% of the carbonwas directed through the PEP carboxylase reaction. This maybe caused by cold lability of pyruvate kinase which was demonstratedin in vitro assays. Low pH, down to 5.5, reduced organic acidproduction by inhibition of PEP carboxylase activity. Pyruvatekinase was not affected and carbon dioxide evolution remainedconstant at varying pH. PEP carboxyiase and pyruvate kinaseindependently feed their products into two separate metabolicpools. Possibly they should jointly be considered as final enzymesin the glycolytic pathway of plants. (Received April 3, 1982; Accepted June 12, 1982)     

Fasting-induced inhibition of collagen biosynthesis in rat skin. A possible role for phosphoenolpyruvate in this process

Fasting is accompanied by a decrease in collagen biosynthesis. The mechanism of this phenomenon involves inhibition of prolidase activity, an enzyme that plays a key role in upregulation of collagen metabolism. The mechanism of fasting-induced inhibition of prolidase activity is not known. Phosphoenolpyruvate (PEP) is known as a strong inhibitor of prolidase activity. It exerts this effect by inhibition of the enzyme phosphorylation. Unphosphorylated prolidase is inactive. One may expect that fasting-associated increase in posphoenolpyruvate content in animal tissues may be a factor which inactivates prolidase and makes it inactive in collagen biosynthesis. We measured the levels of phosphoenolpyruvate, pyruvate, and pyruvate kinase in the skin of control and fasted rats and correlated these parameters with prolidase expression, prolidase activity and collagen biosynthesis in this tissue. Significant increase of PEP concentration (about 30%) was found in the skin of fasted rats. In the same time prolidase activity and collagen biosynthesis decreased by about 50% and 30%, respectively, compared to controls. It is known that phosphoenolpyruvate is converted to pyruvate by the action of pyruvate kinase. Since fasting significantly decreases the activity of this enzyme, one may suggest that the accumulation of PEP is caused by a reduced utilisation of this metabolite. As demonstrated by Western immunoblot analysis the decrease in prolidase activity was not accompanied by a decrease in the amount of the enzyme protein. Instead, a decrease in the enzyme phosphorylation was observed. The reduction in phosphorylation seems to be responsible for the decrease in prolidase activity. These data suggest that fasting-evoked accumulation of PEP reduces the activity of prolidase, providing a mechanism for inhibition of collagen biosynthesis in the skin.     

The effect of fatigue on the binding of glycolytic enzymes in the isolated gastrocnemius of Rana pipiens

Fatigue of isolated gastrocnemius muscles from R. pipiens leads to a marked increase in the proportion of phosphofructokinase bound to the particulate fraction and a decrease in the binding of lactate dehydrogenase, pyruvate kinase, creatine phosphokinase and glyceraldehyde-3-phosphate dehydrogenase. Only the proportion of aldolase bound to the particulate fraction was unaffected by fatigue. This pattern was unchanged when fatigued muscles were extracted at pH 6.5 rather than 7.5. Thus, muscle fatigue leads to opposite changes in the binding of the glycolytic enzymes.     

Maize leaf phosphoenolpyruvate carboxylase : oligomeric state and activity in the presence of glycerol

Maize (Zea mays L.) leaf phosphoenopyruvate (PEP) carboxylase activity at subsaturating levels of PEP was increased by the inclusion of glycerol (20%, v/v) in the assay medium. The extent of activation was dependent on H⁺ concentration, being more marked at pH 7 (with activities 100% higher than in aqueous medium) than at pH 8 (20% activation). The determination of the substrate concentration necessary to achieve half-maximal enzyme activity (S_0.5) (PEP) and maximal velocity (V) between pH 6.9 and 8.2 showed a uniform decrease in S_0.5 in the presence of glycerol over the entire pH range tested, and only a slight decrease in V at pH values near 8. Including NaCl (100 millimolar) in the glycerol containing assay medium resulted in additional activation, mainly due to an increase in V over the entire range of pH. Glucose-6-phosphate (5 millimolar) activated both the native and the glycerol-treated enzyme almost to the same extent, at pH 7 and 1 millimolar PEP. Inhibition by 5 millimolar malate at pH 7 and subsaturating PEP was considerably lower in the presence of glycerol than in an aqueous medium (8% against 25%, respectively). Size-exclusion high performance liquid chromatography in aqueous buffer revealed the existence of an equilibrium between the tetrameric and dimeric enzyme forms, which is displaced to the tetramer as the pH was increased from 7 to 8. In the presence of glycerol, only the 400 kilodalton tetrameric form was observed at pH 7 or 8. However, dissociation into dimers by NaCl could not be prevented by the polyol. We conclude that the control of the aggregation state by the metabolic status of the cell could be one regulatory mechanism of PEP carboxylase.