The isolation of spinach chloroplasts in pyrophosphate media

A simplified procedure (involving disruption in sorbitol-pyrophosphate mixtures) permits the separation of spinach chloroplasts which retain the ability to catalyze the photosynthetic assimilation of carbon dioxide and its associated oxygen evolution.     

Hydrophobic affinity partition of spinach chloroplasts in aqueous two-phase systems

The surface properties of spinach chloroplasts, both of intact chloroplasts with surrounding envelope and broken chloroplasts consisting of the inner lamellar system, have been studied by partitioning them between two aqueous phases, especially using counter-current distribution technique. The two-phase system consists of poly(ethyleneglycol), dextran and water. The two polymers are enriched in opposite phases and by binding deoxycholate or palmitate to one of the polymers the affinity of chloroplasts for the corresponding phase is strongly enhanced. The partition of the two classes of chloroplasts, however, is not affected to the same degree and the affinity of the chloroplast envelope for deoxycholate and palmitate is stronger than that of the lamellar system. This has been correlated to the chemical composition of the two types of membranes. By studying the effect of salts on the partition it has been found that the lamellar system bears a larger number of negative charges as compared to the envelope of the intact chloroplast.     

Nitrite assimilation and amino nitrogen synthesis in isolated spinach chloroplasts

The assimilation of nitrite leading to de novo synthesis of amino nitrogen in a chloroplast-enriched fraction isolated from freshly harvested young spinach (Spinacia oleracea L.) leaves was demonstrated. The preparations showed approximately 55% intact chloroplasts as determined by light scattering properties and fixed CO₂ at rates of approximately 100 μmoles hr⁻¹ mg chlorophyll⁻¹.     

Isolation of Photosystem II enriched membrane vesicles from spinach chloroplasts by phase partition

Partition in an aqueous Dextran-polyethylene glycol two-phase system has been used for the separation of chloroplast membrane vesicles obtained by press treatment of a grana-enriched fraction after unstacking in a low salt buffer.

The fractions obtained were analysed with respect to chlorophyll, photochemical activities and ultrastructural characteristics. The results reveal that the material partitioning to the Dextran-rich bottom phase consisted of large membrane vesicles possessing mainly Photosystem II properties with very low contribution from Photosystem I. Measurements of the H₂O to phenyl-p-benzoquinone and ascorbate-Cl₂Ind to NADP⁺ electron transport rates indicate a ratio of around six between Photosystem II and I.

The total fractionation procedure could be completed within 2–3 h with high recovery of both the Photosystem II water-splitting activity and the Photosystem I reduction of NADP⁺.

These data demonstrate that press treatment of low-salt destabilized grana membranes yields a population of highly Photosystem-II enriched membrane vesicles which can be discriminated by the phase system. We suggest that such membrane vesicles originate from large regions in the native grana membrane which contain virtually only Photosystem II.     

Comparative studies on the properties of spinach chloroplasts prepared by media containing choline chloride or sucrose

Spinach chloroplasts were isolated and stored in a medium containing0.5 M choline chloride. The properties of these chloroplastswere compared with those of chloroplasts prepared in an ordinarysucrose medium. In marked contrast to sucrose-prepared chloroplasts, choline-preparedchloroplasts did not show "conventional uncoupling" (stimulationof ferricyanide reduction paralleling the inactivation of phosphorylation)after transient warming in the temperature range between 20?and 55?C. The thermal stability of the oxygen evolving system, the vulnerabilityof the lipophilic structure in the thylakoids to alcohol duringthe warming treatment, and the effects of amine on photophosphorylationwere similar in both chloroplast preparations. After the warming treatment, the degree of swelling in chloroplastswas larger and the intermediate electron transport systme (fromreduced 2,6-dichlorophenolindophenol to methyl viologen) wasmore stable against uncoupling, in choline-prepared chloroplaststhan in sucrose-prepared ones. The presence and absence of "conventional uncoupling" in twochloroplast preparations were ascribed to differences in thermalstability. In choline-prepared chloroplasts the uncoupling temperatureof the electron transport system was higher than the inactivationtemperature of the oxygen evolving system, but it was lowerin the sucrose-prepared ones. (Received February 13, 1974; )     

Isolation and characterisation of 14-S RNA from spinach chloroplasts.

14-S RNA was purified from spinach chloroplasts. It has a molecular weight of 0.43 . 10(6) and the following nucleotide composition: 20% CMP, 23.9% AMP, 24.2% GMP and 31.9% UMP. The accumulation of 14-S RNA in chloroplasts of cotyledons of dark-grown plants is stimulated by light. Conditions are described for the isolation of 14-S RNA in the absence of appreciable fragmentation of chloroplast 23-S rRNA and the evidence that it represents a distinct type of chloroplast RNA is discussed. Translation of 14-S RNA in a protein synthesising system from Escherichia coli gives rise to two polypeptides with molecular weights of 13 200 and 12 600 and the possible role of 14-S RNA as a chloroplast messenger is discussed.     

Photoreduction of sulfur dioxide by spinach leaves and isolated spinach chloroplasts

Labeled sulfur dioxide was found to be extensively absorbed by spinach (Spinacea oleracea L.) leaves. Labeled sulfides detected in leaf blades following fumigations with sulfur dioxide in light indicated that photoreduction of sulfur dioxide had occurred. Measurable proportions of this labeled sulfur was localized within the chloroplast fraction. Suspensions of isolated chloroplasts supplied with labeled sulfur dioxide contained labeled sulfides following a 30-minute illumination period in water-cooled reaction vessels. With reference to recent studies of the chloroplast sulfur reduction pathway, probable points of entry for sulfur dioxide and the subsequent release of hydrogen sulfide are discussed.     

Isolation of chestnut chloroplasts: membrane potentials of chestnut and spinach thylakoids

Typical chestnut thylakoid extracts isolated by mechanical disruption of leaf tissues had an equivalent of 0.28 kg m⁻³ chlorophyll (Chl) which is six times less than in thylakoids obtained from spinach, although Chl content in leaves was only half as small. According to optical microscopy, the vesicles showed a good integrity, exhibiting at 21 °C a high capacity of photon-induced potential membrane generation, which was demonstrated by the almost full 9-amino-6-chloro-2-methoxyacridine fluorescence quenching in a hyper-saline medium containing 150 mM KCl and having osmotic potential of −1.5 MPa. The half-time of the thylakoid potential generation was 11.7 s with the time of dissipation around 8.9 s. In such conditions, spinach thylakoids showed an increased swelling and also differences in the half-time generation which was almost four times faster than was observed in chestnut. However, when spinach thylakoids were incubated in a typical hypo-saline medium without KCl with osmotic potential −0.8 MPa, no additional swelling was observed. Consequently the half-time of potential dissipation was 35 s. Studies with nigericin suggested a chestnut thylakoid ΔpH significantly smaller than that observed in spinach, which was confirmed by the measurements of the ATP driven pumping activity.     

Formation of thiol groups in spinach chloroplasts by illumination

Thiol groups in chloroplasts were determined in the dark andin the light. The content of thiol groups increased with illumination.This formation of thiol groups was inhibited by inhibitors ofthe Hill reaction. Pyocyanine, a cofactor of the cyclic electronflow, stimulated the light-induced formation of thiol groups. (Received March 30, 1971; )     

Inhibition of photosynthesis by oxygen in isolated spinach chloroplasts

The inhibition of photosynthetic CO₂ fixation by O₂, commonly referred to as the Warburg effect, was examined in isolated intact spinach (Spinacia oleracea) chloroplasts. The major characteristics of this effect in isolated chloroplasts are rapid reversibility when O₂ is replaced by N₂, an increased inhibition by O₂ at low concentrations of CO₂ and a decreased effect of O₂ with increased concentrations of CO₂.