Photosynthesis, Photorespiration and Respiration of Chloroplasts From Acetabularia mediterrania

A chloroplast fraction isolated from Acetabularia mediterrania carries on photosynthesis at rates essentially equal to those of whole cells. Electron and phase contrast microscopy reveals that the chloroplasts are intact and well preserved. Preparations contain no identifiable peroxisomes, but some cytoplasmic and mitochondrial contamination is present. Photosynthesis and CO₂ production in light by chloroplast preparations are in many respects similar to that of bean leaves, although the measured rates are somewhat lower. Respiration and photosynthesis of chloroplast preparations and whole cells of Acetabularia is essentially similar except that cells have a strong dark-type respiration which continues in light and is CO₂ dependent, the substrate being mainly recent photosynthate. The data suggest that chloroplasts are the site of photorespiration.     

Isolation of Intact Chloroplasts from Dunaliella tertiolecta

Cells of Dunaliella tertiolecta from the log phase of growth were broken by rapid extrusion at low pressure through a Yeda press and the chloroplasts were isolated by centrifugation through a Percoll gradient. Osmolarity of the growth media, the suspending media, and the Percoll gradient was kept identical to minimize change in chloroplast volume and mitochondrial entrapment. The isolated intact chloroplasts were obtained in a 30 to 50% yield based on chlorophyll and were stable to washing with buffered medium. Isolated chloroplast yield and purity was dependent on cell culture condition; a cycle of 16 hours light and 8 hours dark with continuous high CO₂ was optimum. Isolated chloroplasts were about 90% intact by microscopic examination, ferricyanide-dependent O₂ evolution, and the distribution of four stromal enzymes. Enzymes associated with glycolate metabolism were not in the chloroplast fraction. The isolated chloroplasts with 10 millimolar bicarbonate evolved 24 micromoles of O₂ and fixed 21 micromoles of CO₂ per hour per milligram of chlorophyll, which rates were about one-third of those by whole cells. The inhibition of oxygen evolution by 10 millimolar phosphate was reversed by P-glycerate. Whole chloroplasts were also isolated from cells adapted to low CO₂ in air for 24 hours. On low CO₂ the cells excreted more gelatinous material, which had to be removed with additional washing of the cells, before it was possible to obtain good chloroplast preparations.     

Photosynthesis in chloroplasts rapidly isolated from primary leaves of oat (Avena sativa L.): effects of orthophosphate, metal ion and chelators

Abstract A simple mechanical method for the rapid isolation of chloroplasts with high rates of photosynthesis from young leaves of oat (Avena sativa L.) was described. The photosynthetic activity of these chloroplasts was stable for at least 2 h with rates of CO₂-dependent O₂ evolution of 30–40 μmol g ¹ Chl s ¹. The photosynthetic properties of these chloroplasts were similar to those reported for spinach and pea chloroplasts isolated by mechanical disruption. The pH optimum for photosynthetic O₂ evolution was pH 7.6. The induction time was 0.5–2 min. Maximal rates of photosynthetic O₂ evolution in these chloroplast preparations were obtained in the absence of both divalent cations and EDTA. Addition of divilent cations strongly inhibited photosynthesis which could be partially restored by the subsequent addition of EDTA. But when these cations were not present in the assay medium the addition of EDTA greater than 1 mol m ³ decreased photosynthetic activity. The optimal orthophosphate concentration required for photosynthesis in these chloroplast preparations was 0.2–0.3 mol m ³. In contrast, the addition of pyrophosphate either in the light or dark inhibited photosynthesis. In a comparative study, chloroplasts were also isolated from oat and wheat (Triticum aestivum L., cultivar Hybrid C306) protoplasts. These chloroplast preparations were found to have properties similar to those determined for oat chloroplasts isolated by the mechanical method reported above.     

Isolation of Bundle Sheath Cell Chloroplasts from the NADP-ME Type C(4) Plant Zea mays: Capacities for CO(2) Assimilation and Malate Decarboxylation

Bundle sheath chloroplasts have been isolated from Zea mays leaves by a procedure involving enzymic digestion of mechanically prepared strands of bundle sheath cells followed by gentle breakage and filtration. The resulting crude chloroplast preparation was enriched by Percoll density layer centrifugation to yield intact chloroplasts (about 20 micrograms chlorophyll per 10-gram leaf tissue) with high metabolic activities. Based on activities of marker enzymes in the chloroplast and bundle sheath cell extracts, the chloroplasts were essentially free of contamination by other organelles and cytoplasmic material, and were generally about 70% intact. Chlorophyll a/b ratios were high (about 10). With appropriate substrates these chloroplasts displayed high rates of malate decarboxylation, measured as pyruvate formation, and CO₂ assimilation (maximum rates approximately 5 and 3 micromoles per minute per milligram chlorophyll, respectively). These activities were light dependent, linear for at least 20 minutes at 30°C, and displayed highest rates at pH 8.0. High metabolic rates were dependent on addition of an exogenous source of carbon to the photosynthetic carbon reduction cycle (3-phosphoglycerate or dihydroxyacetone phosphate) and a nucleotide (ATP, ADP, or AMP), as well as aspartate. Generally, neither malate decarboxylation nor CO₂ assimilation occurred substantially in the absence of the other activity indicating a close relationship between these processes. Presumably, NADPH required for the photosynthetic carbon reduction cycle is largely supplied during the decarboxylation of malate by NADP-malic enzyme. The results are discussed in relation to the role of bundle sheath chloroplasts in C₄ photosynthesis by species of the NADP-malic enzyme type.     

Photosynthetic Reactions in the Marine Alga Codium vermilara: II. Structural Studies

Chloroplasts from Codium vermilara, isolated by relatively crude methods, are able to fix CO₂ at rates comparable to the rates of intact plants. Sections in thalli of Codium vermilara show that the chloroplasts are surrounded by a thin layer of cytoplasm. This surrounding layer of cytoplasm, is retained also in isolated chloroplasts, and presumably preserves the intactness of the chloroplast envelope.     

Effect of Cd and UV-B radiation on polypeptide composition and photosystem activities ofVigna unguiculata chloroplasts

Rates of whole chain and photosystem 2 activities in chloroplasts isolated fromVigna unguiculata L. seedlings grown under ultraviolet-B (UV-B) enhanced radiation were less affected by 3, 6 and 9 mM CdCl₂ for 60 min at 0 °C in the dark than the rates in chloroplasts from control plants grown under normal irradiation. The results are in agreement with changes in contents of chloroplast 55, 47, 43, 33, 29, 27–25, 23 and 17 kDa polypeptides that were significantly lowered at 3, 6 and 9 mM CdCl₂ only in chloroplasts from control plants. On the other hand, in the simultaneous treatment of chloroplast isolated from control plants the UV-B supported the inhibitory effect of all applied concentrations of CdCl₂. The photosystem 1 activity was only marginally affected in the all experimental variants.     

Uptake of bicarbonate ion in darkness by isolated chloroplast envelope membranes and intact chloroplasts of spinach

Bicarbonate uptake by isolated chloroplast envelope membranes and intact chloroplasts of spinach (Spinacia oleracea L. var. Viroflay) in darkness exhibited a similar dependency upon temperature, pH, time, and concentrations of isolated or attached envelope membranes. This similarity in uptake properties demonstrates the usefulness of the envelope membranes for the study of chloroplast permeability. Maximal rates for dark HCO₃^- uptake by isolated envelope membranes and intact chloroplasts were more than sufficient to account for the maximal rates of photosynthetic CO₂ fixation observed with intact chloroplasts. The active species involved in the uptake process was found to be HCO₃^- and not CO₂. The significance of HCO₃^- uptake and its relationship to carbonic anhydrase and ribulose diphosphate carboxylase is discussed. Conditions for maximal HCO₃^- uptake in darkness by intact chloroplasts were found to be similar to those required for maximal photosynthetic CO₂ fixation, suggesting that HCO₃^- uptake by the envelope membrane may regulate photosynthetic CO₂ fixation.     

Partial Purification of Intact Chloroplasts from Chlamydomonas reinhardtii

Partially purified intact chloroplasts were prepared from batch cultures of both wild type (Wt) and a mutant strain of Chlamydomonas reinhardtii. Protoplasts were generated from log phase cultures of Wt (137c) and the phosphoribulokinase-deficient mutant F60 by incubation of the cells in autolysine. These protoplasts were suspended in an osmoticum, cooled, and then subjected to a 40 pounds per square inch pressure shock using a Yeda pressure bomb. The resulting preparation was fractionated on a Percoll step gradient which separated the intact chloroplasts from both broken chloroplasts and protoplasts.

The chloroplast preparation was not significantly contaminated with the cytoplasmic enzyme activity phosphoenolpyruvate carboxylase (>5%), and contained (100%) stromal enzyme activity ribulose-1,5-bisphosphate carboxylase. The chloroplast preparation is significantly contaminated by mitochondria, as determined by succinate dehydrogenase activity. Chloroplasts prepared from Wt cells retained CO₂-dependent O₂ photoevolution at rates in excess of 60 micromoles per milligram chlorophyll per hour, an activity which is severely inhibited by the addition of 10 millimolar KH₂PO₄. The chloroplasts are osmotically sensitive as determined by ferricyanide-dependent O₂ photoevolution.

     

Effect of nano-TiO2 on photochemical reaction of chloroplasts of spinach

The effects of nano-TiO₂ (rutile) on the photochemical reaction of chloroplasts of spinach were studied. The results showed that when spinach was treated with 0.25% nano-TiO₂, the Hill reaction, such as the reduction rate of FeCy, and the rate of evolution oxygen of chloroplasts was accelerated and noncyclic photophosphorylation (nc-PSP) activity of chloroplasts was higher than cyclic photophosphorylation (c-PSP) activity, the chloroplast coupling was improved and activities of Mg²⁺-ATPase and chloroplast coupling factor I (CF₁)-ATPase on the thylakoid membranes were obviously activated. It suggested that photosynthesis promoted by nano-TiO₂ might be related to activation of photochemical reaction of chloroplasts of spinach.     

Evidence for the nuclear location of the gene for chloroplast elongation factor G.

The chloroplast protein synthesis factor responsible for the translocation step of polypeptide synthesis on chloroplast ribosomes (chloroplast elongation factor G [EF-G]) has been detected in whole cell extracts and in isolated chloroplasts from Euglena gracilis. This factor can be detected by its ability to catalyze translocation on 70 S prokaryotic ribosomes such as those from E. coli. Chloroplast EF-G is present in low levels when Euglena is grown in the dark and can be induced more than 20-fold when the organism is grown in the light. The induction of this factor by light is inhibited by cycloheximide, a specific inhibitor of protein synthesis on cytoplasmic ribosomes. However, inhibitors of chloroplast protein synthesis such as streptomycin or spectinomycin have no effect on the induction of this factor by light. Furthermore, chloroplast EF-G can be partially induced by light in an aplastidic mutant (strain W₃BUL) which has neither significant plastid structure nor detectable chloroplast DNA. These data strongly suggest that the genetic information for chloroplast EF-G resides in the nuclear genome, and that this protein is synthesized on cytoplasmic ribosomes prior to compartmentalization within the chloroplasts.     

Chloroplast cysteine synthases of Trifolium repens and Pisum sativum

About 68–86% of the cysteine synthase activity in leaf tissue of white clover (Trifolium repens) and peas (Pisum sativum cultivar Massey Gem) was associated with chloroplasts. The enzymes from white clover and peas were purified ca 66 and 12-fold respectively. For clover, the K_m values determined by calorimetric and S^2? ion electrode methods were: S^2? 0.51 and 0.13 mM; O-acetylserine (OAS), 3.5 and 2.O mM respectively. The analogous values for the pea enzyme were: S^2?, 0.24 and 0.06 mM; OAS, 3.1 and 0.24 mM. Both enzymes were inhibited by cystathionine and cysteine. Pretreatment with cysteine inactivated the enzyme, but addition of pyridoxal phosphate caused partial reactivation. Isolated pea chloroplasts (70–75 % intact) catalysed OAS-dependent assimilation of sulphide at a mean rate of 88 μmol/mg Chl/hr. About 85 % of the OAS-dependent sulphide assimilated was recovered as cysteine. The rates were unaffected by light and 2 μM DCMU. Sonicating the chloroplasts enhanced the rate by 1.3–2 fold. Cysteine synthase activity was associated with the chloroplast stroma. Similar results were obtained for clover chloroplasts except that both the intactness and the rates were lower.     

Response of carbon dioxide fixation to water stress: parallel measurements on isolated chloroplasts and intact spinach leaves

Application of water stress to isolated spinach (Spinacia oleracea) chloroplasts by redutcion of the osmotic potentials of CO₂ fixation media below −6 to −8 bars resulted in decreased rates of fixation regardless of solute composition. A decrease in CO₂ fixation rate of isolated chloroplasts was also found when leaves were dehydrated in air prior to chloroplast isolation. An inverse response of CO₂ fixation to osmotic potential of the fixation medium was found with chloroplasts isolated from dehydrated leaves—namely, fixation rate was inhibited at −8 bars, compared with −16 or −24 bars.     

Nomenclature for Isolated Chloroplasts

THE nomenclature used to describe the “intactness” or degree of breakage of isolated chloioplasts has been most confusing in the past few years. This resulted chiefly from reports that chloroplasts should be isolated carefully and rapidly to obtain high rates of CO₂ fixation (50–250 µmol/mg chlorophyll/h). This type of chloroplast cannot translocate NADP, ferricyanide or ADP through its intact limiting membrane or envelope. “Class I” chloroplasts, as seen by phase contrast microscopy, had previously been considered to be similar to the in vivo situation. Unfortunately, in vitro they showed only low rates of CO₂ a fixation and easily transported NADP, ferricyanide and ADP into the chloroplast.     

Osmotic adjustment by intact isolated chloroplasts in response to osmotic stress and its effect on photosynthesis and chloroplast volume

Spinach leaf chloroplasts isolated in isotonic media (330 millimolar sorbitol, −1.0 megapascals osmotic potential) had optimum rates of photosynthesis when assayed at −1.0 megapascals. When chloroplasts were isolated in hypertonic media (720 millimolar sorbitol, −2.0 megapascals osmotic potential) the optimum osmotic potential for photosynthesis was shifted to −1.8 megapascals and the chloroplasts had higher rates of CO₂-dependent O₂ evolution than chloroplasts isolated in 330 millimolar sorbitol when both were assayed at high solute concentrations.

Transfer of chloroplasts isolated in 330 millimolar sorbitol to 720 millimolar sorbitol resulted in decreased chloroplast volume but this shrinkage was only transient and the chloroplasts subsequently swelled so that within 2 to 3 minutes at 20°C the chloroplast volume had returned to near the original value. Thus, actual steady state chloroplast volume was not decreased in hypertonic media. In isotonic media, there was a slow but significant uptake of sorbitol by chloroplasts (10 to 20 micromoles per milligram chlorophyll per hour at 20°C). Transfer of chloroplasts from 330 millimolar sorbitol to 720 millimolar sorbitol resulted in rapid uptake of sorbitol (up to 280 micromoles per milligram chlorophyll per hour at 20°C) and after 5 minutes the concentration of sorbitol inside the chloroplasts exceeded 500 millimolar. This uptake of sorbitol resulted in a significant underestimation of chloroplast volume unless [¹⁴C]sorbitol was added just prior to centrifuging the chloroplasts through silicone oil. Sudden exposure to osmotic stress apparently induced a transient change in the permeability of the chloroplast envelope since addition of [¹⁴C]sorbitol 3 minutes after transfer to hypertonic media (when chloroplast volume had returned to normal) did not result in rapid uptake of labeled sorbitol.

It is concluded that chloroplasts can osmotically adjust in vitro by uptake of solutes which do not normally penetrate the chloroplast envelope, resulting in a restoration of normal chloroplast volume and partially preventing the inhibition of photosynthesis by high solute concentrations. The results indicate the importance of matching the osmotic potential of isolation media to that of the tissue, particularly in studies of stress physiology.

     

A membrane-bound alkaline inorganic pyrophosphatase in isolated spinach chloroplasts

An alkaline inorganic pyrophosphatase is found in association with isolated spinach chloroplast membranes. The enzyme is not removed from chloroplasts by repeated washings in an iso-osmotic medium. Suspension of the chloroplasts in hyper- or hypo-osmotic medium, however, results in the loss of pyrophosphatase activity in the chloroplasts. Fractionation of an isolated chloroplast suspension by differential centrifugation yields chloroplast fractions possessing high levels of alkaline pyrophosphatase activity but practically devoid of cytoplasmic acid pyrophosphatase.The alkaline pyrophosphatase exhibits a pH optimum of 8.2–8.5. In addition, there is an absolute requirement for Mg²⁺, with maximal rates of pyrophosphate hydrolysis occurring at $\text{Mg}{}^{\mathrm{2+}}\text{PP}{}_{\mathrm{i}}$ ratios greater than 2. From these findings the actual substrate for the enzyme is evidently Mg₂P₂O₇⁰ with pyrophosphate (P₂O₇^4?) acting as a potent inhibitor.The enzyme is inhibited by high concentrations of ATP (>3 mm), but increasing the concentration of Mg²⁺ effectively relieves this inhibition. At lower ATP concentrations, however, there is a stimulation of pyrophosphatase activity.The rate of hydrolysis of pyrophosphate by isolated chloroplasts is not affected by methylamine, 4′-deoxyphlorizin, and light. The possible role of this enzyme in photophosphorylation is discussed.     

Inhibition of chloroplast protein synthesis by lincomycin and 2-(4-methyl-2,6- dinitroanilino)-N-methylpropionamide

Selective effects of lincomysin and cycloheximide in detached shoots of Pisum sativum on the synthesis of photosystem I and II proteins, and a chloroplast membrane protein of molecular weight 32000, confirm results obtained from studies of protein synthesis by isolated chloroplasts. A model is proposed in which one role of chloroplast ribosomes is to synthesize membrane proteins required for the immobilization of chloroplast components, such as photosystem I protein, which are synthesized by cytoplasmic ribosomes. 2-(4-Methyl-2,6-dinitroanilino)-N-methylpropionamide rapidly inhibits the synthesis of both the large and small subunits of Fraction I protein in greening detached pea shoots. This observation can be reconciled with the site of synthesis of the large subunit being in the chloroplast by a model which proposes that the small subunit is a positive initiation factor for the synthesis or translation of the messenger RNA for the large subunit.     

The apparent absence of a pathway for synthesis of acetyl coenzyme A in pea chloroplasts: Lack of 14CO2 incorporation into lipids by the isolated organelle

Summary We have examined the extent to which isotopic lable derived from photosynthetically fixed ¹⁴CO₂ can be transferred to lipids by aqueously isolated chloroplasts of Pisum sativum. Although photosynthetically active, chloroplast preparations incubated with ¹⁴CO₂ showed little or no accumulation of label in lipids under any condition tested. Under identical conditions the chloroplasts were readily able to incorporate [¹⁴C]acetate into the lipid fraction; a fatty-acid synthesizing system was therefore operative in these chloroplasts.The essential failure of the isolated chloroplasts to incorporate label from fixed ¹⁴CO₂ into fatty acids supports the view that the organelle itself does not possess a self-contained pathway for the synthesis of acetyl coenzyme A, and favours the possibility that a shuttle mechanism involving the participation of extra-chloroplastic enzymes may be responsible for supplying the chloroplast with acetyl coenzyme A in vivo.     

3-phosphoglycerate phosphatase activity in chloroplast preparations as a result of contamination by Acid phosphatase

The presence of a nonspecific acid phosphatase which had high activity with 3-phosphoglycerate as substrate has recently been reported in Spinacia oleracea L. chloroplasts (Mulligan, Tolbert 1980 Plant Physiol 66: 1169-1173). The subcellular localization of this activity has been reinvestigated by differential centrifugation of spinach leaf homogenates. The fraction sedimenting at 1,200g comprised mostly intact chloroplasts and contained more than half the chlorophyll but only 5% of the 3-phosphoglycerate phosphatase activity present in the homogenate. The fraction of the homogenate pelleting at 5,000g contained broken chloroplasts and had considerable 3-phosphoglycerate phosphatase activity. Further purification of the 1,200g pellet fraction on a Percoll step gradient yielded greater than 95% intact chloroplasts, yet the phosphatase activity was reduced more than 15-fold on a chlorophyll basis by this purification.

When the intact chloroplast and cytoplasmic fractions of mesophyll protoplasts were separated by silicone oil filtering centrifugation, the chloroplast fraction contained more than 90% of the chlorophyll but had less than 12% of the 3-phosphoglycerate phosphatase activity. By contrast, more than 60% of the 2-phosphoglycolate phosphatase was recovered in this chloroplast fraction supporting previous evidence that this phosphatase is localized in the chloroplast stroma.

It is concluded that 3-phosphoglycerate phosphatase activity is not localized in the chloroplast but that the activity present in chloroplast preparations results from contamination by acid phosphatase, which either binds to the thylakoid membranes during preparation or is present as some other contaminant in the preparation. Inasmuch as the enzyme acts on a broad range of substrates its presence in chloroplast preparations, particularly when the percentage of intact chloroplasts is low, could produce artifacts in metabolic studies such as measurement of phosphorylation.

     

Correlation between the activity of membrane-bound ATPase and the decay rate of flash-induced 515-nm absorbance change in chloroplasts in intact leaves,assayed by means of rapid isolation of chloroplasts

(1) The relationship between activation of the membrane-bound ATPase and the stimulation of dissipation of the flash-induced membrane potential by preillumination was studied in intact spinach leaves by measuring the ATPase activity of rapidly isolated chloroplasts and the decay of the flash-induced 515-nm absorbance change (ΔA₅₁₅) in intact leaves. (2) The decay of ΔA₅₁₅ was accelerated by preillumination. The ΔA₅₁₅ decay in leaves treated with N,N′-dicyclohexylcarbodiimide (DCCD) became slower and was not accelerated by preillumination. However, treatment with DCCD did not lower the intensity of delayed fluorescence. (3) Membrane-bound ATPase of chloroplasts which were rapidly isolated from the preilluminated leaves (90 s preparation time) showed a higher activity (over 200 μmol P_i/mg chlorophyll per h in the case of 2-min preillumination) than that of chloroplasts isolated from dark-adapted leaves. (4) The acceleration of ΔA₅₁₅ decay and the activation of ATPase showed similar dependences on illumination time in intact leaves. 3-(3′,4′-Dichlorophenyl)-1,1-dimethylurea, carbonyl cyanide p-chlorophenylhydrazone and DCCD inhibited the activation of ATPase and the acceleration of the ΔA₅₁₅ decay by preillumination. (5) The ATPase activity of chloroplasts isolated from illuminated leaves showed a single exponential decay (‘dark inactivation in vitro’). The ATPase activity induced by illuminating the leaves became lower as the dark interval between illumination and the isolation of chloroplasts was increased (‘dark inactivation in vivo’). The time course of the decay of activity had a lag and showed a sigmoidal curve when plotted semilogarithmically. The decay had an apparent half-time of 25 min. (6) The recovery of the accelerated ΔA₅₁₅ decay in preilluminated leaves to the original slow rate showed a sigmoidal decay similar to that of the activity of ATPase in intact leaves with a half-time of about 23 min in the dark. (7) It was concluded that the decay rate of ΔA₅₁₅ reflected the chloroplast ATPase activity in intact leaves and that the ion conductance of thylakoid membrane was mainly determined by the H⁺ flux through the ATPase, the activity of which was increased after the formation of the high-energy state.