Influence of pH upon the Warburg Effect in Isolated Intact Spinach Chloroplasts: II. Interdependency of Glycolate Synthesis upon pH and Calvin Cycle Intermediate Concentration in the Absence of Carbon Dioxide Photoassimilation

Glycolate Induces Redox Tuning Of Photosystem II in Vivo: Study of a Photorespiration Mutant

Bicarbonate removal from the nonheme iron at the acceptor side of photosystem II (PSII) was shown recently to shift the midpoint potential of the primary quinone acceptor Q_A to a more positive potential and lowers the yield of singlet oxygen (¹O₂) production. The presence of Q_A^- results in weaker binding of bicarbonate, suggesting a redox-based regulatory and protective mechanism where loss of bicarbonate or exchange of bicarbonate by other small carboxylic acids may protect PSII against ¹O₂ in vivo under photorespiratory conditions. Here, we compared the properties of Q_A in the Arabidopsis (Arabidopsis thaliana) photorespiration mutant deficient in peroxisomal HYDROXYPYRUVATE REDUCTASE1 (hpr1-1), which accumulates glycolate in leaves, with the wild type. Photosynthetic electron transport was affected in the mutant, and chlorophyll fluorescence showed slower electron transport between Q_A and Q_B in the mutant. Glycolate induced an increase in the temperature maximum of thermoluminescence emission, indicating a shift of the midpoint potential of Q_A to a more positive value. The yield of ¹O₂ production was lowered in thylakoid membranes isolated from hpr1-1 compared with the wild type, consistent with a higher potential of Q_A/Q_A^- In addition, electron donation to photosystem I was affected in hpr1-1 at higher light intensities, consistent with diminished electron transfer out of PSII. This study indicates that replacement of bicarbonate at the nonheme iron by a small carboxylate anion occurs in plants in vivo. These findings suggested that replacement of the bicarbonate on the nonheme iron by glycolate may represent a regulatory mechanism that protects PSII against photooxidative stress under low-CO₂ conditions.

Characterization of an Electron Transport Pathway Associated with Glucose and Fructose Respiration in the Intact Chloroplasts of Chlamydomonas reinhardtii and Spinach

The role of an electron transport pathway associated with aerobic carbohydrate degradation in isolated, intact chloroplasts was evaluated. This was accomplished by monitoring the evolution of (14)CO(2) from darkened spinach (Spinacia oleracea) and Chlamydomonas reinhardtii chloroplasts externally supplied with [(14)C]fructose and [(14)C]glucose, respectively, in the presence of nitrite, oxaloacetate, and conventional electron transport inhibitors. Addition of nitrite or oxaloacetate increased the release of (14)CO(2), but it was shown that O(2) continued to function as a terminal electron acceptor. (14)CO(2) evolution was inhibited up to 30 and 15% in Chlamydomonas and spinach, respectively, by 50 mum rotenone and by amytal, but at 500- to 1000-fold higher concentrations, indicating the involvement of a reduced nicotinamide adenine dinucleotide phosphate-plastoquinone oxidoreductase. (14)CO(2) release from the spinach chloroplast was inhibited 80% by 25 mum 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone. (14)CO(2) release was sensitive to propylgallate, exhibiting approximately 50% inhibition in Chlamydomonas and in spinach chloroplasts of 100 and 250 mum concentrations, respectively. These concentrations were 20- to 50-fold lower than the concentrations of salicylhydroxamic acid (SHAM) required to produce an equivalent sensitivity. Antimycin A (100 mum) inhibited approximately 80 to 90% of (14)CO(2) release from both types of chloroplast. At 75 mum, sodium azide inhibited (14)CO(2) evolution about 50% in Chlamydomonas and 30% in spinach. Sodium azide (100 mm) combined with antimycin A (100 mum) inhibited (14)CO(2) evolution more than 90%. (14)CO(2) release was unaffected by uncouplers. These results are interpreted as evidence for a respiratory electron transport pathway functioning in the darkened, isolated chloroplast. Chloroplast respiration defined as (14)CO(2) release from externally supplied [1-(14)C]glucose can account for at least 10% of the total respiratory capacity (endogenous release of CO(2)) of the Chlamydomonas reinhardtii cell.

Aerobic and anaerobic respiration in the intact spinach chloroplast

Aerobic and anaerobic chloroplastic respiration was monitored by measuring (14)CO(2) evolution from [(14)C]glucose in the darkened spinach (Spinacia oleracea) chloroplast and by estimating the conversion of fructose 1,6-bisphosphate to glycerate 3-phosphate in the darkened spinach chloroplast in air with O(2) or in N(2) with nitrite or oxaloacetate as electron acceptors. The pathway of (14)CO(2) evolution from labeled glucose in the absence and presence of the inhibitors iodoacetamide and glycolate 2-phosphate under air or N(2) were those expected from the oxidative pentose phosphate cycle and glycolysis. Of the electron acceptors, O(2) was the best (2.4 nanomoles CO(2) per milligram chlorophyll per hour), followed by nitrite and oxaloacetate. With respect to glycerate 3-phosphate formation from fructose 1,6-bisphosphate, methylene blue increased the aerobic rate from 3.7 to 5.4 micromoles per milligram chlorophyll per hour. A rate of 4.8 micromoles per milligram chlorophyll per hour was observed under N(2) with nitrite and oxaloacetate.

Inhibition of chloroplastic respiration by osmotic dehydration

The respiratory capacity of isolated spinach (Spinacia oleracea L.) chloroplasts, measured as the rate of (14)CO(2) evolved from the oxidative pentose phosphate cycle in darkened chloroplasts exogenously supplied with [(14)C]glucose, was progressively diminished by escalating osmotic dehydration with betaine or sorbitol. Comparing the inhibitions of CO(2) evolution generated by osmotic dehydration in chloroplasts given C-1 and C-6 labeled glucose, 54% and 84% respectively, indicates that osmotic dehydration effects to a greater extent the recycling of the oxidative pentose phosphate intermediates, fructose-6P and glyceraldehyde-3P. Respiratory inhibition in the darkened chloroplast could be alleviated by addition of NH(4)Cl (a stromal alkylating agent), iodoacetamide) an inhibitor of glyceraldehyde-3P dehydrogenase), or glycolate-2P (an inhibitor of phosphofructokinase). It is concluded that the site which primarily mediates respiratory inhibition in the darkened chloroplast occurs at the fructose 1,6-bisphosphatase/phosphofructokinase junction.

Spinach Leaf Chloroplast CO(2) and NO(2) Photoassimilations Do Not Compete for Photogenerated Reductant: Manipulation of Reductant Levels by Quantum Flux Density Titrations

Potential competition between CO(2) and NO(2) (-) photoassimilation for photogenerated reductant (e.g. reduced ferredoxin and NADPH) was examined employing isolates of mesophyll cells and intact chloroplasts derived from mature ;source' spinach leaves. Variations in the magnitude of incident light energy were used to manipulate the supply of reductant in situ within chloroplasts. Leaf cell and plastid isolates were fed with saturating CO(2) and/or NO(2) (-) to produce the highest demand for reductant by CO(2) and/or NO(2) (-) assimilatory processes (enzymes). Even in the presence of CO(2) fixation, NO(2) (-) reduction in intact leaf cell isolates as well as plastid isolates was maximal at light energies as low as 50 to 200 microeinsteins per second per square meter. Simultaneously, 500 to 800 microeinsteins per second per square meter were required to support maximal CO(2) assimilation. Regardless of the magnitude of the incident light energy, CO(2) assimilation did not repress NO(2) (-) reduction, nor were these two processes mutually repressed. These observations have been interpreted to mean that reduced ferredoxin levels in situ in the plastids of mature source leaf mesophyll cells were adequate to supply the concurrent maximal demands exerted by enzymes associated with CO(2) as well as with inorganic nitrogen photoassimilation.

Influence of Hydrogen Peroxide upon Carbon Dioxide Photoassimilation in the Spinach Chloroplast: I. HYDROGEN PEROXIDE GENERATED BY BROKEN CHLOROPLASTS IN AN "INTACT" CHLOROPLAST PREPARATION IS A CAUSAL AGENT OF THE WARBURG EFFECT

Photosynthesis and the Warburg effect (O(2) inhibition of photosynthesis) were evaluated in preparations of intact spinach chloroplasts enriched with varying amounts of lysed chloroplasts. Increasing the ratio of broken to intact plastids resulted in decreased rates of CO(2) assimilation.Hydrogen peroxide when added at 10 or more micromolar also inhibited photosynthesis in these preparations. Inhibition of the photosynthetic rate by both factors was eliminated by addition of catalase. These findings indicate that H(2)O(2) presumably generated by the broken chloroplasts was the causal agent of this inhibition.The Warburg effect also became more pronounced by increasing the level of broken to intact chloroplasts. This effect was examined as a function of added catalase, pH, and O(2) concentration. At 21% O(2) and 0.44 to 0.68 millimolar CO(2), catalase relieved the effect almost completely at pH 7.5, but at pH 8.3, the rate was restored only to about half or less of the control. At pH 7.6, 0.44 millimolar CO(2), and 100% O(2), the effect was only slightly overcome by catalase.A rise in glycolate synthesis by the isolated spinach chloroplast has been shown previously to be coupled to an increase in pH and O(2) (Kow, Robinson, Gibbs 1977 Plant Physiol 60: 492-495; Robinson, Gibbs, Cotler 1977 Plant Physiol 59: 530-534). At 21% O(2), glycolate synthesis was not affected by the addition of catalase at pH 7.5 or 8.3. It is proposed that at 21% O(2) and without some means of removing H(2)O(2), that portion of the Warburg effect attributed to glycolate synthesis has been overestimated at pH values in the order of 7.5. In contrast, that portion of the Warburg effect which was, at alkaline pH, insensitive to catalase represented the stress placed upon the photosynthetic carbon reduction cycle which resulted from an enhanced synthesis of glycolate. At 100% O(2) aeration and pH 7.5 to 8.5, the Warburg effect may also represent O(2)-mediated inhibition of a Calvin cycle enzyme within the intact plastid.

Effect of pH on chloroplast photosynthesis. Inhibition of O2 evolution by inorganic phosphate and magnesium

1. The pH optimum of CO2-dependent O2 evolution by barley (Hordeum vulgare L.) chloroplasts was found to be between 7.8 and 8.2. The addition of 1 mM MgCl2 in the dark inhibited O2 evolution over the entire pH range tested and resulted in a much sharper pH profile centered around pH 8.2. 2. The pH optimum for O2 evolution, in the presence and absence of 1 mM MgCl2, was acid-shifted 0.3--0.4 pH units by 2 mM NH4Cl. The pH optimum of O2 evolution, with and without 1 mM MgCl2, was base-shifted by 2 mM sodium acetate, approx. 0.5 pH units relative to the controls. 3. O2 evolution in the presence of bicarbonate plus 3-phosphoglycerate or ribose-5-phosphate was considerably less sensitive to pH than CO2-dependent O2 evolution in the absence of substrate. With these substrates, both in the presence and absence of 1 mM MgCl2, the pH optimum was broad and was centered around pH 7.8. 4. Inhibition of CO2-dependent O2 evolution by inorganic phosphate and magnesium increased as the pH of the reaction mixture was decreased below the optimum. Decreasing the pH from 8.2 to 7.6, reduced over 3-fold the concentration of inorganic phosphate required to inhibit O2 evolution completely. For magnesium, a similar change in pH reduced the concentration required to inhibit O2 evolution 50% approx. 5-fold. At pH 8.2, magnesium inhibition required inorganic phosphate. Magnesium was not required for inhibition of O2 evolution by inorganic phosphate, but incresaed the relative inhibition observed. 5. Illumination of intact barley chloroplasts increased the activity of NADP-glyceraldehyde-3-P dehydrogenase, phosphoribulokinase and fructose-1,6-diphosphatase. MgCl2 and inorganic phosphate prevented this increase in enzyme activity at concentrations that completely inhibited CO2-dependent O2 evolution. 6. The results obtained suggest that magnesium inhibition of O2 evolution may be caused by enhanced phosphate exchange across the chloroplast envelope.