叶绿体小分子RNA的分离纯化和鉴定

本文采用低速匀浆、过筛的方法从植物叶中分离得到了完整、纯净的叶绿体。将叶绿体与提取缓冲液、苯酚混合匀浆抽提叶绿体 RNA。通过聚丙烯酰胺凝胶电泳与文献已发表的已知酵母5S RNA、菠菜叶绿体4.5S RNA 及小麦5S RNA、4.5S RNA 的电泳迁移距离进行比较,发现芹菜叶绿体中小分子 RNA(沉降系数为5S 左右的 RNA)中除含有5S RNA 和4S RNA 外,还含有两种4.5S RNA。而水杉和银杏叶绿体小分子 RNA 中只含有5S RNA 和4S RNA。     

Purity of Chloroplasts Prepared from the Siphonous Green Alga, Caulerpa simpliciuscula, as Determined by Their Ultrastructure and Their Enzymic Content

The ultrastructure and enzyme distribution in chloroplasts and other subcellular fractions isolated from the siphonous green alga, Caulerpa simpliciuscula, are described. The isolated chloroplasts were similar in appearance to those in the tissue from which they were derived, and in typical preparations 70% or more were intact. Chloroplasts which had lost their outer envelopes could be separated from intact plastids by centrifugation at low speeds through gradients of colloidal silica. Intact chloroplasts separated in this way retained their photosynthetic capacity and were impermeable to ferricyanide ions. The chloroplast preparations separated by differential centrifugation and refractionated using either discontinuous or continuous Percoll gradients contained non-chloroplast material. It was estimated that this amounted to a maximum of 10% of the mitochondrial population and 6% of cytoplasm extracted from the plant. The contaminating material surrounded the chloroplasts in a thin layer and was surrounded by a membrane.     

Glycerolipid labelling kinetics in isolated intact chloroplasts.

Glycerolipid synthesis was studied in intact chloroplasts isolated from three different plant species. The sequential acylation of sn-glycerol 3-phosphate and lysophosphatidate (1-acyl-sn-glycerol 3-phosphate) was confirmed by monitoring the incorporation of oleate synthesized in situ into lysophosphatidate, phosphatidate and diacylglycerol. Lysophosphatidate was not only readily detected in these experiments, but was also present in the chloroplasts at the beginning of the time courses. The rate of glycerolipid synthesis depended primarily on sn-glycerol 3-phosphate supply, and given adequate sn-glycerol 3-phosphate, the proportion of newly synthesized fatty acids diverted into glycerolipids appeared to be determined by differing acyltransferase activities in the chloroplasts isolated from different plant species.     

Chloroplast nitrite uptake is enhanced in Arabidopsis PII mutants

In higher plants, the PII protein is a nuclear-encoded plastid protein that regulates the activity of a key enzyme of arginine biosynthesis. We have previously observed that Arabidopsis PII mutants are more sensitive to nitrite toxicity. Using intact chloroplasts isolated from Arabidopsis leaves and (15)N-labelled nitrite we show that a light-dependent nitrite uptake into chloroplasts is increased in PII knock-out mutants when compared to the wild-type. This leads to a higher incorporation of (15)N into ammonium and amino acids in the mutant chloroplasts. However, the uptake differences do not depend on GS/GOGAT activities. Our observations suggest that PII is involved in the regulation of nitrite uptake into higher plant chloroplasts.     

The Involvement of Aspartate and Glutamate in the Decarboxylation of Malate by Isolated Bundle Sheath Chloroplasts from Zea mays

Aspartate or glutamate stimulated the rate of light-dependent malate decarboxylation by isolated Zea mays bundle sheath chloroplasts. Stimulation involved a decrease in the apparent K_m (malate) and an increased maximum velocity of decarboxylation. In the presence of glutamate other dicarboxylates (succinate, fumarate) competitively inhibited malate decarboxylation by intact chloroplasts with respect to malate with an apparent K_i of about 6 millimolar. For comparison the K_i for inhibition of nicotinamide adenine dinucleotide phosphate-malic enzyme from freshly lysed chloroplasts by these dicarboxylates was 15 millimolar. A range of compounds structurally related to aspartate stimulated malate decarboxylation by intact chloroplasts. K_a values for stimulation at 5 millimolar malate were 1.7, 5, and 10 millimolar for l-glutamate, l-aspartate, and β-methyl-dl-aspartate, respectively. Certain compounds, notably cysteic acid, which stimulated malate decarboxylation by intact chloroplasts inhibited malate decarboxylation by nicotinamide adenine dinucleotide phosphate-malic enzyme obtained from lysed chloroplasts and assayed under comparable conditions. It was concluded that aspartate, glutamate, and related compounds affect the transport of malate into the intact chloroplasts and that malate translocation does not take place on the general dicarboxylate translocator previously reported for higher plant chloroplasts.     

High-yield isolation of chloroplast DNA from Hordeum vulcare barley protoplasts

A fraction of intact chloroplasts free of other cell components in isolated from barley leaf chloroplasts. Instead of mechanical desintegration of plant tissue, the method described includes the cellulysine treatment, thus increasing the yeild of chloroplast DNA. The mean content of DNA per barley chloroplast is found to be 1.10(-4) g. Base composition of barley chloroplast DNA is 39.8 mol.% of G+C. The treatment of chloroplast DNA with restriction endonuclease EcoRI results in the appearance of 17-19 bands under agarose gel electrophoresis.     

The subcellular distribution and biosynthesis of castaprenols and plastoquinone in the leaves of Aesculus hippocastanum

Intact chloroplasts and cell walls were prepared from horse-chestnut leaves that had previously metabolized [2-(14)C]mevalonate. The bulk of the castaprenols and plastoquinone-9 was found within the chloroplasts. The remaining portion of the castaprenols was associated with the cell-wall preparation whereas that of the plastoquinone-9 was probably localized in the soluble fraction of the plant cell. The (14)C content of these compounds of different cell fractions indicated the presence of polyisoprenoid-synthesizing activity both inside and outside the chloroplasts. This was confirmed by the relative incorporation of (14)C when ultrasonically treated and intact chloroplasts were incubated with [2-(14)C]mevalonate. As the leaves aged (on the tree) an increase in extraplastidic castaprenols and plastoquinone-9, together with associated synthesizing activities, was observed.     

Intercalation of psoralen into DNA of plastid chromosomes decreases late during barley chloroplast development.

We have used a DNA crosslinking assay to measure intercalation of the psoralen derivative HMT (4'-hydroxymethyl-4,5',8-trimethylpsoralen) into barley (Hordeum vulgare) plastid chromosomal DNA during chloroplast and etioplast development. Intercalation into DNA in intact plastids in vivo and in plastid lysates in vitro shows that chromosomal DNA in the most mature chloroplasts intercalates HMT less efficiently than DNA in younger chloroplasts. In contrast, there is no change in HMT intercalation during etioplast differentiation in the dark. Our results also show that DNA in higher plant plastid chromosomes is under superhelical tension in vivo. The lower susceptibility to HMT intercalation of DNA in the most mature chloroplasts indicates that late during chloroplast development the superhelical tension or the binding of proteins to the DNA or both change.     

Rust fungal effectors mimic host transit peptides to translocate into chloroplasts

Parasite effector proteins target various host cell compartments to alter host processes and promote infection. How effectors cross membrane‐rich interfaces to reach these compartments is a major question in effector biology. Growing evidence suggests that effectors use molecular mimicry to subvert host cell machinery for protein sorting. We recently identified chloroplast‐targeted protein 1 (CTP1), a candidate effector from the poplar leaf rust fungus Melampsora larici‐populina that carries a predicted transit peptide and accumulates in chloroplasts and mitochondria. Here, we show that the CTP1 transit peptide is necessary and sufficient for accumulation in the stroma of chloroplasts. CTP1 is part of a Melampsora‐specific family of polymorphic secreted proteins. Two members of that family, CTP2 and CTP3, also translocate in chloroplasts in an N‐terminal signal‐dependent manner. CTP1, CTP2 and CTP3 are cleaved when they accumulate in chloroplasts, while they remain intact when they do not translocate into chloroplasts. Our findings reveal that fungi have evolved effector proteins that mimic plant‐specific sorting signals to traffic within plant cells.     

Inhibiton of fatty acid biosynthesis in isolated chloroplasts by cycloxydim and other cyclohexane-1,3-diones

Kobek, K., Focke, M., Lichtenthaler, H.K., Retzlaff, G. and Würzer, B. 1988. Inhibiton of fatty acid biosynthesis in isolated chloroplasts by cycloxydim and other cyclohexane-1,3-diones. - Physiol. Plant. 72: 492–498.
The effect of the three cyclohexane-1,3-dione herbicides cycloxydim, sethoxydim and clethodim (proposed common name) on the de novo fatty acid biosynthesis of isolated chloroplasts as test system was investigated with intact chloroplasts isolated from sensitive grasses (Poaceae) and tolerant dicotyledonous plants. All three herbicides blocked the de novo fatty acid biosynthesis ([¹⁴C]-acetatc incorporation into total fatty acid fraction) in Avena sativa L. cv. Flämingnova chloroplasts in a dose-dependent manner. The I₅₀-values are lower for cycloxydim and clethodim than for sethoxydim. The rate of de novo fatty acid biosynthesis in isolated, intact and photosynthetically active Avena chloroplasts was higher in the light than in the dark, which appeared to be due to the light-dependent regeneration of the cofactors ATP and NADPH. The de novo fatty acid biosynthesis by isolated chloroplasts from the tolerant dicotyledonous species pea ( Pisum savivum L. cv. Kleine Rheinländerin), spinach ( Spinacea oleracea L. cv. Matador) and tobacco ( Nicotiana tabacum L. cv. su/su) was insensitive to the three herbicides. It is assumed that one of the enzymes of the fatty acid biosynthesis is modified in the dicotyledonous plants and not accessible to the cyclohexane-1,3-dione herbicides. In the case of Poa annua L., which as a whole plant is tolerant towards sethoxydim, the tolerance seems not to lie in the chloroplasts but in properties of the cytoplasm, since the isolated chloroplasts are sensitive to the herbicide.     

Subcellular aspects of the protective effect of spermine against atrazine in pea plants

The action of the exogenously applied tetraamine spermine in reversing the effect of atrazine stress on intact pea plants (Pisum sativum L., cv. Koray) was investigated at the ultrastructural level. The results indicate that atrazine increases cell senescence by lipid peroxidation and loss of unsaturated fatty acids from thylakoid membranes of pea plant chloroplasts. Spermine acts as a polyfunctional effector. It stabilises the molecular composition of the membranes by preventing lipid peroxidation and as a consequence protects the conformation of the thylakoid system and structural integrity of the chloroplasts. Spermine treatment also contributes to the process of neutralisation of the free radicals by peroxisomes.     

Energy charge,phosphorylation potential and proton motive force in chloroplasts

Adenylate concentrations were measured in intact chloroplasts under a variety of conditions. Energy charge was significant in the dark and increased in the light, but remained far below values expected from observed phosphorylation potentials in broken chloroplasts, which were 80 000 M^?1 or more in the light. With nitrite as electron acceptor, phosphorylation potentials in intact chloroplasts were about 80 M^?1 in the dark and only 300 M^?1 in the light. Similar phosphorylation potentials were observed, when oxaloacetate, phosphoglycerate or bicarbonate were used as substrates. ΔG′_ATP was ?42 kJ/mol in darkened intact chloroplasts, ?46 kJ/mol in illuminated intact chloroplasts and ?60 kJ/mol in illuminated broken chloroplasts. Uncoupling by NH₄Cl, which stimulated electron transport to nitrite or oxaloacetate and decreased the proton gradient, failed to decrease the phosphorylation potential of intact chloroplasts. Also, it did not increase the quantum requirement of CO₂ reduction. It is concluded that the proton motive force as conventionally measured and phosphorylation potentials are far from equilibrium in intact chloroplasts. The insensitivity of CO₂ reduction and of the phosphorylation potential to a decrease in the proton motive force suggests that intact chloroplasts are over-energized even under low intensity illumination. However, such a conclusion is at variance with available data on the magnitude of the proton motive force.     

Biosynthesis of sulfoquinovosyldiacylglycerol in higher plants: the incorporation of 35SO4 by intact chloroplasts

Isolated spinach chloroplasts have been found to incorporate 35SO4 into the plant sulfolipid, sulfoquinovosyldiacylglycerol, at rates of up to 700 pmol mg chlorophyll-1 h-1. The reaction is light-dependent, requires that the chloroplasts be intact, and is slightly stimulated by ATP and UTP. UDP-galactose inhibits the formation of sulfoquinovosyldiacylglycerol, presumably by competing for the diacylglycerol pool. The rates of synthesis observed are sufficient to conclude that the chloroplast is autonomous with respect to the synthesis of sulfoquinovose, the headgroup moiety of sulfoquinovosyldiacylglycerol. No evidence could be obtained to support the concept that the proposed sulfoglycolytic pathway is the biosynthetic route for sulfoquinovose formation.     

Grass cells ingested by ruminants undergo autolysis which differs from senescence: implications for grass breeding targets and livestock production

It is widely believed that the initial degradation of proteins contained in grazed forage is mediated by rumen micro‐organisms, but the authors’ recent work suggests that the plant cells themselves contribute to their own demise. In the present study the responses of Lolium perenne leaves to the rumen environment were investigated by using an in vitro system which simulates the main stresses of the rumen but from which rumen micro‐organisms were excluded. Degradation of leaf protein and the accumulation of amino acids in tissue and bathing medium occurred over a time‐scale that is relevant to rumen function, and in a near 1 : 1 ratio. Significant loss of nuclear material was observed after 6 h incubation and chloroplasts became morphologically more spherical as the incubation progressed. In situ localization suggested that ribulose 1,5 bisphosphate carboxylase/oxygenase was broken down within chloroplasts which from cytology were judged to be intact. We conclude from these data that plant metabolism may play a significant role in breaking down plant proteins within relatively intact organelles in the rumen. The determinations of chlorophyll content and cell viability revealed that the plant processes occurring in the simulated rumen were similar but not identical to those of natural senescence.     

Hydrogen peroxide-dependent oxidation of flavonols by intact spinach chloroplasts

Externally added quercetin (100 micromolar) was oxidized by intact spinach chloroplasts at a rate of 30 micromoles per mg chlorophyll per hour in the presence of 100 micromolar H₂O₂. The oxidation rate was increased by about 20% in a hypotonic reaction mixture. The thylakoid fraction also oxidized the flavonol in the presence of H₂O₂, and the rate was about 25% of that by intact chloroplasts. The oxidation of quercetin was inhibited by KCN and NaN₃. Ascorbate, which permeates slowly across chloroplast envelope, only slightly suppressed the initial rate of quercetin oxidation by intact chloroplasts, while the oxidation by ruptured chloroplasts was suppressed by ascorbate by about 60%. Quercetin glycosides, quercitrin and rutin, were also oxidized by chloroplasts in the presence of H₂O₂. These results suggest that flavonols are oxidized by peroxidase-like activity in chloroplasts and that externally added flavonols can permeate into the stroma through the envelope of intact chloroplasts.     

Guard Cell Chloroplasts Are Essential for Blue Light-Dependent Stomatal Opening in Arabidopsis

Blue light (BL) induces stomatal opening through the activation of H⁺-ATPases with subsequent ion accumulation in guard cells. In most plant species, red light (RL) enhances BL-dependent stomatal opening. This RL effect is attributable to the chloroplasts of guard cell, the only cells in the epidermis possessing this organelle. To clarify the role of chloroplasts in stomatal regulation, we investigated the effects of RL on BL-dependent stomatal opening in isolated epidermis, guard cell protoplasts, and intact leaves of Arabidopsis thaliana. In isolated epidermal tissues and intact leaves, weak BL superimposed on RL enhanced stomatal opening while BL alone was less effective. In guard cell protoplasts, RL enhanced BL-dependent H⁺-pumping and DCMU, a photosynthetic electron transport inhibitor, eliminated this effect. RL enhanced phosphorylation levels of the H⁺-ATPase in response to BL, but this RL effect was not suppressed by DCMU. Furthermore, DCMU inhibited both RL-induced and BL-dependent stomatal opening in intact leaves. The photosynthetic rate in leaves correlated positively with BL-dependent stomatal opening in the presence of DCMU. We conclude that guard cell chloroplasts provide ATP and/or reducing equivalents that fuel BL-dependent stomatal opening, and that they indirectly monitor photosynthetic CO₂ fixation in mesophyll chloroplasts by absorbing PAR in the epidermis.     

Free flow electrophoresis of chloroplasts

Highly purified intact chloroplasts were isolated from spinach (Spinacia oleracea L.) leaves by free flow electrophoresis. Morphological and biochemical studies showed that the fraction enriched in intact chloroplasts has a higher protein to chlorophyll ratio and a higher linolenic acid content than the broken organelles of the other fraction. The intact chloroplasts prepared by electrophoresis retained their capacity for CO₂ fixation. Sodium dodecyl sulfate polyacrylamide gel electrophoresis demonstrated that this fraction was rich in stroma and lamellae proteins. Free flow electrophoresis, which separates organelles and molecules according to their surface charges, is a good technique for producing purified chloroplasts with complete physiological activities.     

Dissipation of the proton electrochemical potential in intact and lysed chloroplasts : I. The electrical potential

Effective ionophore:chlorophyll ratios were determined for various ionophores that decrease the electrical potential across thylakoid membranes in intact and hypo-osmotically lysed chloroplasts isolated from spinach (Spinacia oleracea). The efficacy of gramicidin D, valinomycin, carbonylcyanide m-chlorophenylhydrazone, and dicyclohexano-18-crown-6 in collapsing the electrical potential was determined spectrophotometrically by the decay half-time of the absorbance change at 518 nanometers induced by a saturating, single turnover flash. The results show that the effectiveness of the ionophores in collapsing the electrical potential in intact and lysed chloroplasts depends on the amount of ionophore-accessible membrane in the assay medium. Only gramicidin exhibited a significant difference in efficacy between intact and lysed chloroplasts. The ratio of gramicidin to chlorophyll required to collapse the electrical potential was more than 50 times higher in intact chloroplasts than in lysed chloroplasts. The efficacy of carbonylcyanide m-chlorophenylhydrazone was significantly reduced in the presence of bovine serum albumin. The other ionophores tested maintained their potency in the presence of bovine serum albumin. Valinomycin was the most effective ionophore tested for collapsing the electrical potential in intact chloroplasts, whereas gramicidin was the most potent ionophore in lysed chloroplasts. The significance of the ionophore:chlorophyll ratios required to collapse the electrical potential is discussed with regard to bioenergetic studies, especially those that examine the contribution of the transmembrane electrochemical potential to protein transport into chloroplasts.     

Immobilization of photosynthetically active intact chloroplasts in a crosslinked albumin matrix

Summary Isolated higher plant chloroplasts with intact envelope membranes and bovine serum albumin were co-immobilized by treating the mixture with glutaraldehyde and then subjecting it to a freeze-thaw cycle. The immobilized chloroplasts are capable of photoinduced electron transport to lipophilic oxidants, but become compatible also with ionic oxidants after a transient hyposmotic shock.Abbreviations ASC ascorbate - Chl chlorophyll - DCIP 2,6-dichlorophenol indophenol - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethyl urea - FeCN K₃ Fe(CN)₆ - MV methyl viologen - PD_ox FeCN-oxidized p-phenylene diamine