Iodination of chloroplasts. I. Properties of iodinated chloroplasts

Spinach chloroplasts exposed to iodide can be washed free of the bulk of the iodide. In the presence of lactoperoxidase and H₂O₂, iodide can be introduced into chloroplasts in high amounts and in non diffusible forms. The resultant particles, which have been named iodochloroplasts, extrude their iodide upon stimulation by light. The form and the amount of extruded iodide bears a definite relationship to the amount of incident light. A flash of marginally effective light is additive to the next such flash even after a lapse of 10 min of darkness. These and other properties of iodochloroplasts may make them of great use in the study of intermediate reactions of photosynthesis.     

Electron paramagnetic resonance Signal II in spinach chloroplasts. I. Kinetic analysis for untreated chloroplasts

An analysis of electron paramagnetic resonance Signal II in spinach chloroplasts has been made using both continuous and flashing light techniques. In order to perform the experiments we developed a method which allows us to obtain fresh, untreated chloroplasts with low dark levels of Signal II. Under these conditions a single 10-μs flash is sufficient to generate greater than 80% of the possible light-induced increase in Signal II spin concentration. The risetime for this flash-induced increase in Signal II is approx. 1 s. The close association of Signal II with Photo-system II is confirmed by the observations that red light is more effective than is far red light in generating Signal II, and that 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) does not inhibit the formation of the radical. Single flash saturation curves for the flash-induced increase in Signal I and Signal II indicate that the quantum efficiency for Signal II formation is close to that for Signal I. While one or two flashes (spaced 10 ms apart) are quite efficient in generating Signal II, three or four flashes are much less effective. However, if this spacing is decreased to 100 μs, three or four flashes become as efficient as one or two flashes. From observations of a deficiency of O₂ evolved during the initial flashes of dark-adapted chloroplasts, we conclude that the species which gives rise to Signal II is able to compete with water for oxidizing equivalents generated by Photosystem II. On the basis of these results we postulate a model in which Signal II arises from an oxidized radical which is produced by a slow electron transfer to the specific states S₂ and S₃ on the water side of Photo-system II.     

Photoswelling and light-inactivation of isolated chloroplasts I. Change in lipid content in light-aged chloroplasts

The formation of lipid peroxide and changes in the lipid compositionof isolated chloroplasts aged in the light or dark, were investigatedin more detail. Lipid peroxide formation was observed in thethylakoid membrane as well as in the supernatant from dark-agedchloroplasts. Light was necessary for its formation in bothsystems. We confirmed that the peroxidation of lipids formedduring aging did not induce the inhibition of photochemicalactivities in chloroplasts. Aged chloroplasts underwent decompositionof their endogeneous monogalactolipid and phosphatidylcholine(lecithin) resulting in free fatty acids and lysophosphatidylcholine(lysolecithin). Decomposition of monogalactolipid occurred inboth the light- and dark-aged chloroplasts. The change of lecithinto lysolecithin was stimulated by illumination. This suggeststhat the peroxidation of lipids occurs as a result of the illuminationof free fatty acids released from monogalactolipid and lecithinin the thylakoid membranes, and that the change of lecithinto lysolecithin is related to the inactivation of photochemicalactivities and to swelling in light-aged chloroplasts. ¹ Present address: Department of Microbiology, Ishikawa ResearchLaboratory for Public Health and Environment, Minma, Kanazawa,Japan. (Received August 15, 1974; )     

Protein import into chloroplasts.

Chloroplasts have evolved an elaborate system of membrane and soluble subcompartments to organize and regulate photosynthesis and essential aspects of amino acid and lipid metabolism. The biogenesis and maintenance of organellar architecture rely on protein subunits encoded by both nuclear and plastid genomes. Import of nuclear-encoded proteins is mediated by interactions between the intrinsic N-terminal transit sequence of the nuclear-encoded preprotein and a common import machinery at the chloroplast envelope. Recent investigations have shown that there are two unique membrane-bound translocation systems, in the outer and inner envelope membranes, which physically associate during import to transport preproteins from the cytoplasm to the internal stromal compartment. This review discusses current understanding of these translocation systems and models for the way in which they might function.     

Enhancement studies on algae and isolated chloroplasts. Part II. Enhancement of oxygen evolution in intact chloroplasts.

Intact isolated chloroplasts were shown to exhibit a characteristic three-phase pattern of development of oxygen evolution activity. The first phase, Phase I, appeared to be an equilibration phase in which the isolated chloroplasts adapted to the conditions on the electrode surface. It was characterised by a rapidly increasing rate of oxygen evolution accompanied by decreasing enhancement signals. The second phase, Phase II, was an intermediate phase in which the rate of oxygen evolution was maximal and no enhancement was observed. In the last phase, Phase III, the rate of oxygen fell again, normal enhancement was still missing, but the samples appeared to undergo slow adaptive changes closely related to the State I-State II changes previously reported for whole cell systems. The concentrations of Mg2+ within the chloroplast were shown to play an important role in the control of the development of both the oxygen evolution and enhancement signals. It was shown how these signals could be explained in terms of a model that was consistent with that developed in Part I of this investigation to account for the variability of enhancement of the alga Chlorella pyrenoidosa.     

Cytochrome b-563 redox changes in intact CO-fixing spinach chloroplasts and in developing pea chloroplasts.

Intact spinach chloroplasts, capable of high rates of photochemical oxygen evolution with CO2 as electron acceptor (120-350 mumol O2 mg chlorophyll-1 h-1) were examined for cytochrome redox changes. The response of the cytochromes in intact chloroplasts to oxidants and reductants appears to be governed by the permeability of the chloroplast envelope. The low potential cytochromes (b-559LP and b-563) were more slowly reduced at 25 degrees C by dithionite than is the case with broken chloroplasts. At 0 degrees C, the reduction of the low potential cytochromes in intactchloroplasts was extremely slow. The chloroplast envelope is impermeable to ferricyanide, slowly permeable to ascorbate and rapidly permeable to reduced dichlorophenolindophenol. Light-induced redox changes of cytochrome b-563 in intact chloroplasts were examined both at 0 degrees and 25 degrees C. A red/far-red antagonism on the redox changes of cytochrome b-563 was observed at 0 degrees C under anaerobic conditions. 3-(3,4-dichlorophenyl)-1, 1-dimethlyurea (DCMU) inhibited the photoreduction of cytochrome b-563 in red light following far-red illumination. The photooxidation of cytochrome b-563 under anaerobic conditions was not influenced by DCMU or 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB). The photoreduction of cytochrome b-563 under aerobic conditions was much less efficient than its photooxidation under anaerobic conditions. Developing pea chloroplasts showed much greater light-induced redox changes of cytochrome b-563 than did intact spinach chloroplasts. Our data are consistent with the view that cytochrome b-563 functions on a cyclic pathway around Photosystem I, but it appears that cyclic flow is sensitive to the relative poising of the redox levels of cytochrome b-563 and the components of the non-cylic pathway.     

Enhancement studies on algae and isolated chloroplasts. Part II. Enhancement of oxygen evolution in intact chloroplasts

Intact isolated chloroplasts were shown to exhibit a characteristic three-phase pattern of development of oxygen evolution activity. The first phase, Phase I, appeared to be an equilibration phase in which the isolated chloroplasts adapted to the conditions on the electrode surface. It was characterised by a rapidly increasing rate of oxygen evolution accompanied by decreasing enhancement signals. The second phase, Phase II, was an intermediate phase in which the rate of oxygen evolution was maximal and no enhancement was observed. In the last phase, Phase III, the rate of oxygen fell again, normal enhancement was still missing, but the samples appeared to undergo slow adaptive changes closely related to the State I-State II changes previously reported for whole cell systems.The concentrations of Mg²⁺ within the chloroplast were shown to play an important role in the control of the development of both the oxygen evolution and enhancement signals. It was shown how these signals could be explained in terms of a model that was consistent with that developed in Part I of this investigation to account for the variability of enhancement of the alga Chlorella pyrenoidosa.     

Biosynthesis in isolatedAcetabularia chloroplasts II. Plastid pigments

Summary The plastid pigments — chlorophylls and carotenoids — of the alga,Acetabularia, have been chromatographically separated and identified. These pigments were found to become radio-active during incubations of an isolated chloroplast fraction with¹⁴CO₂. Specific activity calculations indicate that appreciable amounts of synthesis were occurringin vitro. The phytol and porphyrin moieties of chlorophyll a were both radioactive; thus the pigments were being formed completely from recent photosynthetic products. A comparison of the incorporation of¹⁴CO₂ into plastid pigmentsin vivo andin vitro suggests that the isolated chloroplasts form the pigments at their normalin vivo rates.     

Intramembranous particles and chlorophyll complexes in chloroplasts.

The size and population density of large and small particles from freeze-fractured chloroplasts of three wild-type algae and of normal spinach were determined. Computer analyses of low-temperature absorption spectra of chloroplast preparations from these species were performed, and a possible correlation between the occurrence of seven chlorophyll complexes and the aforementioned properties of the intramembranous particles was studies. It was found that only single-sized particles occur in a species containing neither chlorophyll b nor chlorophyll a-685 complexes. The three remaining species carry particles of two sizes, termed large and small particles. However, from quantitative considerations it is concluded that the chlorophyll content of none of the various pigment complexes is related to the size and the population density of the studied particles. If such a relationship exists, it seems likely to be due to the carrier moiety of the chorophyll b-chlorophyll a-685 complex.     

Properties of ATP-induced chlorophyll luminescence in chloroplasts.

1. The recently described reaction of ATP-induced luminescence is analyzed for its relation to other ATP-induced reactions such as ATP-driven transmembrane proton gradient formation and ATP-driven reverse electron flow. 2. In the absence of phenazine methosulfate ATP-induced luminescence is optimal while the main phase of ATP-driven reverse electron flow is eliminated. 3. DCMU which by itself causes a much smaller luminescence, inhibits the ATP-induced luminescence. 4. Nigericin plus valinomycin, but not each by itself, fully inhibit the ATP-induced luminescence. 5. The observations are interpreted as indicating that ATP stimulates luminescence by a 2-fold mechanism: (a) increasing the amount of the reducing primary electron acceptor of Photosystem II, Q, and (b) creating a transmembrane electrochemical potential which serves to decrease the activation energy required for the charge recombination reaction which leads to luminescence.