Light-Induced Chloroplast Shrinkage in vivo Detectable After Rapid Isolation of Chloroplasts From Pisum sativum

A light-induced shrinkage of chloroplasts in vivo could be detected with chloroplasts isolated within 2 minutes of harvesting pea plants. As determined both by packed volume and Coulter counter, the mean volume of chloroplasts from plants in the dark was 39 μ³, whereas it was 31 μ³ for chloroplasts from plants in the light. Upon illumination of the plants, the half-time for the chloroplast shrinkage in vivo was about 3 minutes, and the half-time for the reversal in the dark was about 5 minutes. A plant growth temperature of 20° was optimal for the volume change. The chloroplast shrinkage was half-maximal for a light intensity of 400 lux incident on the plants and was light-saturated near 2000 lux. The light-absorbing pigment responsible for the volume change was chlorophyll. This light-induced shrinkage resulted in a flattening and slight indenting of the chloroplasts. This chloroplast flattening upon illumination of the plants may accompany an increase in the photosynthetic efficiency of chloroplasts.     

Preparation and characterization of phospholipid-depleted chloroplasts

Spinach class II chloroplasts were treated with snake venom phospholipase A2 in the presence of bovine serum albumin, and separated by sucrose-density centrifugation. The treatment yielded phospholipid-depleted chloroplasts which had lost 82.6% of the original phospholipids. About 20% of the phospholipids of chloroplasts were resistant to enzyme attack. These results suggest that phospholipids exist in two states in chloroplast membranes. In spite of considerable phospholipid depletion, the chloroplast preparations retained a large portion of their photoactivities, i.e. light-induced electron transport, light-induced H+ uptake, and light-induced shrinkage. However, cyclic photophosphorylation was significantly affected with the phospholipid removal.     

Energetic basis of the light-induced chloroplast shrinkage in vivo

A light-induced chloroplast shrinkage occurring in vivo wasmeasured with a Coulter counter and a packed weight techniqueusing chloroplasts isolated within two minutes of harvestingpea plants. Introduction of the photosynthetic inhibitor DCMU(5 µM) into the plant either by bathing the cut stem orinjection through a fine hypodermic needle decreased the light-inducedchloroplast shrinkage in vivo 11 to 20%. The uncoupler tri-Fl-CCP(5 µM) inhibited the light-induced shrinkage 80 % , whilenigericin (0.5 µM) completely abolished it. An actionspectrum for the chloroplast volume decrease in vivo had a shoulderat 700-715 mµ. These results are considered in terms ofthe various forms of energy available during photosynthesis.A consistent interpretation is that the lightinduced chloroplastshrinkage in vivo depends either on a high energy state createdby electron flow or on ATP. This chloroplast volume change uponillumination of the plants may increase the photosynthetic efficiency. (Received April 15, 1968; )     

Light-induced changes of NADPH fluorescence in isolated chloroplasts: a spectral and fluorescence lifetime study

Isolated chloroplasts show a light-induced reversible increase in blue-green fluorescence (BGF), which is only dependent on NADPH changes. In the present communication, we report a time-resolved and spectral analysis of this BGF in reconstituted chloroplasts and intact isolated chloroplasts, in the dark and under actinic illumination. From these measurements we deduced the contribution of the different forms of NADPH (free and bound to proteins) to the light-induced variation of BGF and conclude that this variation is due only to the redox change of the NADP pool. A simple model estimating the distribution of NADPH between the free and bound form was designed, that explains the differences measured for the BGF of reconstituted chloroplasts and intact chloroplasts. From the decay-associated spectra of the chloroplast BGF, we also deduced the participation of flavins to the green peak of chloroplast fluorescence emission spectrum, and the existence of excitation energy transfer from proteins to bound NADPH in chloroplasts. In addition, we re-examined the use of chloroplast BGF as a quantitative measure of NADPH concentration, and confirmed that chloroplast BGF can be used for non-destructive, continuous and probably quantitative monitoring of light-induced changes in NADP redox state.     

Energy-dependent uptake of phenazinemethosulfate in isolated chloroplasts]

The concentration and absorption of methylphenazinium cations (MP+) in suspensions of pea chloroplasts are simultaneously lowered during rapid (approximately 10s) illumination. The light-induced changes of absorption and concentration of MP+ reveal similar sensitivity towards some inhibitors and uncouplers and are determined by MP+ uptake by the thylakoids. The time-course of light-induced MP+ uptake was found to be modified in the presence of dithioerythritol, Mg2+ and ATP, i. e. under conditions which induce the ATPase activity and ATP hydrolysis in chloroplasts. The kinetic curve of light-induced MP+ uptake under these conditions consists of a relatively fast (approximatley 10 s) and a slow (approximately 10 min) components. The slow ATP-dependent component of MP+ uptake is enhanced by low concentrations of gramicidin and is completely inhibited by the energy transfer inhibitor--dicyclohexylcarbodiimide. The data obtained suggest that the light-induced energization of the chloroplast membrane is accompanied by the transport of MP+ into the thylakoids against the electrical potential and concentration gradients.     

The high-energy state of the thylakoid system as indicated by chlorophyll fluorescence and chloroplast shrinkage

Certain long-term fluorescence phenomena observed in intact leaves of higher plants and in isolated chloroplasts show a reverse relationship to light-induced absorbance changes at 535 nm (“chloroplast shrinkage”).

1. 1. In isolated chloroplasts with intact envelopes strong fluorescence quenching upon prolonged illumination with red light is accompanied by an absorbance increase. Both effects are reversed by uncoupling with cyclohexylammonium chloride.

2. 2. The fluorescence quenching is reversed in the dark with kinetics very similar to those of the dark decay of chloroplast shrinkage.

3. 3. In intact leaves under strong illumination with red light in CO₂-free air a low level of variable fluorescence and a strong shrinkage response are observed. Carbon dioxide was found to increase fluorescence and to inhibit shrinkage.

4. 4. Under nitrogen, CO₂ caused fluorescence quenching and shrinkage increase at low concentrations. At higher CO₂ levels fluorescence was increased and shrinkage decreased.

5. 5. In the presence of CO₂, the steady-state yield of fluorescence was lower under nitrogen than under air, whereas chloroplast shrinkage was stimulated in nitrogen and suppressed in air.

6. 6. These results demonstrate that the fluorescence yield does not only depend on the redox state of the quencher Q, but to a large degree also on the high-energy state of the thylakoid system associated with photophosphorylation.

Phenylmereuric Acetate and Phosphate Control of Light-Dependent Shrinkage and Reactions in Chloroplasts

An investigation of the action of phenylmereuric acetate (PMA) and phosphate on light-induced shrinkage (measured by light scattering and Coulter Counter techniques) and on photosynthetic reactions in spinach chloroplasts led to the following conclusions:

• 1) PMA stimulated light-induced shrinkage (under conditions of cyclic and non-cyclic electron flow) at concentrations which completely inhibited cyclic and non-cyclic photophosphorylation and nicotinamide adenine dinucleotide phosphate (NADP) reduction, though ferricyanide reduction was activated. Although PMA inhibited NADP reduction (probably because this sulfhydryl reagent interfered with the ferredoxin-NADP rednetase) it ean also be considered an uncoiipler (when ferricyanide is the electron acceptor).
• 2) Phosphate maximized light-induced shrinkage (under conditions of cyclic and non cyclic electron flow) at concentrations which did not affect ferricyanide reduction but caused a 40 to 50 per cent inhibition of NADP reduction.
• 3) The pattern of the light scattering response to these two compounds was quite different. In the presence of PMA, the forward (light on) and hack (light off) reactions went to completion rapidly. In the presence of phosphate, the back reaction was rapid but, in the light-induced reaction, three phases were discernible.
• 4) Compared with uncouplers such as NH₄Cl, carbonyl cyanide m-chlorophenyl-hydrazone, pentachlorophenol, and dicoumarol, all of which inhibited both photophosphorylation and conformational changes in chloroplasts, PMA (like quinacrine) had a specific action since it inhibited photophosphorylation while shrinkage was stimulated.
• 5) It appeared that PMA acted at a site beyond the formation of high energy inter-mediates and that, in the absence of photophosphorylation, more energy was diverted to mechanical work (shrinkage). It would seem that, in a cyclic electron flow system, in which ATP synthesis is blocked at a late step (e.g. by PMA), shrinkage may be an indirect method for measuring electron flow.

     

Light-dependent chloroplast volume changes in chloride media

In the past, some workers have reported that isolatedSpinacea oleracea chloroplasts show light-induced swelling in chloride media, while another group showed that chloroplasts may exhibit light-induced shrinkage in chloride media. The difference cannot be due to nuances of individual technique because the present authors, one from each of the above-mentioned groups, worked together each using his usual techniques and found that the chloroplasts used in this study did not show light-induced swelling in chloride media. A slight shrinkage occured with these plastids in chloride media. The criteria used to determine the nature of the volume changes were 0°–90° light-scattering measurements and Coulter Counter particle volume measurements.It is not known exactly what determines whether chloroplasts will show light-induced shrinkage or swelling in a chloride medium.Contribution No. 415 from the C. F. Kettering Research Laboratory.The research was supported in part by Grant No. B6-0851R from the National Science Foundation (grant to R.A.D.).     

The relation of light-induced slow absorbancy and scattering changes about 520 nm and structure of chloroplast thylakoids—A theoretical investigation

A theoretical analysis is made on the relation between light-induced thylakoid shrinkage, slow light-induced absorbancy changes about 520 nm, and light-induced scattering changes observed at 90°, which occur in isolated chloroplasts. A simple model of the thylakoids stacks (grana) is assumed and by a mathematical formalism a correlation of these effects is shown. The light minus dark difference spectrum is shown to peak around 520 nm, a fact that confirms earlier suggestions that this difference band is due to the combined effects of the selective dispersion and optical-conformational changes in the grana.     

Light-induced chloroplast movements in Lemna trisulca. Identification of the motile system

In mesophyll cells of the water plant Lemna trisulca L. chloroplasts redistribute in response to blue light. In the present study it is shown that an actin depolymerizing agent cytochalasin D, a crosslinker of actin subunits in F-actin m-maleimidobenzoic acid N-hydroxysuccinimide ester (MBS) as well as N-ethylmaleimide (NEM)—a sulfhydryl group reagent, are potent inhibitors of these blue light-induced chloroplast movements in Lemna. Extraction with cold, buffered glycerol solution preserves light-induced chloroplast arrangements within cells producing permeabilized cell models. ‘Reactivation’ of these cell models by Mg-ATP results in remarkable movements which can be inhibited by treatment with NEM and cytochalasin D. Immunofluorescence microscopy demonstrates that a component which is associated with isolated Lemna chloroplasts cross-reacts with antibodies directed against bovine myosin. These results indicate that a contractile actomyosin system is involved in blue light-induced chloroplast movements in Lemna and a putative motor protein, similar to myosin, is associated with the surface of Lemna chloroplasts.     

Cation-induced inhibition of the 515-nm absorption change in chloroplasts: relation to structural changes

Divalent cations were found to inhibit the light-induced 515-nm absorption change in chloroplasts with half-maximal effects occurring between 0.3 and 0.7 mm. Monovalent cations were also effective but higher concentrations (~ 30–40 mm) were required for half-maximal effects. Divalent and monovalent cations also caused absorption changes of chloroplasts in the dark which superficially resemble 515-nm absorption changes. However, they can be correlated with volume changes and represent a combination of turbidity and pigment-absorption changes (flattening) which result from shrinkage. Half-maximal effects occurred at 0.8–1.2 mm for divalent cations and between 15 and 20 mm for monovalent cations. The relationship between salt-induced and osmotic-induced structural changes is also discussed.     

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.     

Photorespiration and light act in concert to regulate the expression of the nuclear gene for chloroplast glutamine synthetase.

In Pisum sativum, distinct chloroplast and cytosolic forms of glutamine synthetase (GS) are encoded by homologous nuclear genes that are differentially expressed in vivo (Tingey, S. V., Tsai, F.-Y., Edwards, J. W., Walker, E. L., and Coruzzi, G. M. [1988]. J. Biol. Chem. 263, 9651-9657). In leaves, light selectively affects the expression of the nuclear gene for chloroplast GS2. Differences in the maximal levels of GS2 mRNA in etiolated plants treated with red or white light indicate that only part of the white-light-induced accumulation of GS2 mRNA is due to a phytochrome-mediated response. The kinetics of GS2 mRNA accumulation in response to white-light illumination of etiolated or dark-adapted green plants indicates that GS2 mRNA accumulates more rapidly in plants containing mature, photosynthetically competent chloroplasts. Other evidence that GS2 mRNA levels are affected by the metabolic status of chloroplasts concerns the selective induction of GS2 mRNA in plants grown under conditions that result in the production of photorespiratory ammonia. These results indicate that the light-induced accumulation of GS2 mRNA in leaves results from the action of phytochrome as well as light-induced changes in chloroplast metabolism.     

Effect of dicyclohexylcarbodiimide on the proton conductance of thylakoid membranes in intact chloroplast

The effects of dicyclohexylcarbodiimide, a potent inhibitor of chloroplast ATPase, on the light-induced electric potential changes in intact chloroplasts of Peperomia metallica and of a hornwort Anthoceros sp. were investigated by means of glass microcapillary electrodes. The characteristics of potential changes induced by flashes or continuous light in chloroplasts of both species are similar except for the phase of potential rise in continuous light, which is clearly biphasic in Anthoceros chloroplasts. Dicyclohexylcarbodiimide at concentration 5 · 10⁻⁵ M completely abolishes the transient potential undershoot in the light-off reaction but has little effect on the peak value of the photoelectric response. The membrane conductance in the light and in the dark was tested by measuring the decay kinetics of flash-generated potential in dark-adapted and preilluminated chloroplasts. In the absence of dicyclohexylcarbodiimide, preillumination causes a significant acceleration of the potential decay. The light-induced changes in the decay kinetics of flash-induced responses were abolished in the presence of dicyclohexylcarbodiimide, whereas the rate of potential decay in dark-adapted chloroplasts was not altered by dicyclohexylcarbodiimide. The results are consistent with the notion that dicyclohexylcarbodiimide diminishes H⁺ conductance of energized thylakoid membranes by interacting with the H⁺ channel of ATPase. The occurrence of a lag (approx. 300 ms) on the plot of potential undershoot (diffusion potential) versus illumination time might suggest the increase in H⁺ permeability coefficient of thylakoid membrane during illumination.     

LIGHT-INDUCED VOLUME CHANGES IN SPINACH CHLOROPLASTS

A light-dependent mechanism that results in a slow, high-amplitude swelling of spinach chloroplasts in vitro has been discovered. The swelling is readily observed by optical and gravimetric methods, and by the use of an electronic particle counter; all show a 100 per cent increase of chloroplast volume in the light with an approximately 10-minute half-time. The existence of an osmotic mechanism for chloroplast swelling in the dark is confirmed. The volume of illuminated chloroplasts versus NaCl concentration represents the addition of osmotic and light effects. The action of light is enhanced by electron flow cofactors, such as phenazine methosulfate (PMS). However, neither conditions for ATP hydrolysis or synthesis nor NH₄Cl influence the time course and extent of swelling. Hence, high-amplitude chloroplast swelling is light- (or electron flow), but not energy-dependent. A remarkable inhibitory effect of inorganic phosphate on chloroplast swelling is observed in the light, but not in the dark. Another action of light on chloroplasts is known to result in a shrinkage of chloroplasts which is rapid, reversible, energy-dependent, and requires phosphate. Thus phosphate determines the action of light on chloroplast volume. Since shrinkage is reversible, but swelling is not, it may be that they reflect physiological and deteriorative processes, respectively. Chloroplasts and mitochondria appear to control their volume by similar mechanisms.     

Sensitivity of light-grown and dark-grown Euglena cells to gamma-irradiation.

Light-grown cells which contain fully developed chloroplasts were found to be more resistant to gamma-irradiation than dark-grown cells which are devoid of chloroplasts. The radio-resistance of dark-grown cells progressively increased during light-induced development of chloroplasts and, conversely, radio-resistance of light-grown cells decreased progressively with chloroplast de-development during growth in the dark. The presence of chloroplasts seemed to play a major role in the capacity of cells to recover from radiation damage, the efficiency of cellular recovery being correlatable with the degree of chloroplast development.     

Light-induced absorption changes at 590 nm in isolated pea chloroplasts and their relation to plastocyanin]

The light-induced decrease in absorption with the minimum at 590-595 nm has been found in chloroplasts of etiolated pea seedlings by the method of dual-wavelength difference spectrophotometry. It has been shown that this effect is caused by photoreduction of the electron carrier with the absorption maximum of its oxidized form at 590 nm. Photoreduction of the carrier has been observed after excitation both by the short-wave (646 nm) and long-wave (709 nm) red light, although the latter is less effective. It has been suggested that the absorption changes at 590 nm are caused by light-induced redox conversions of plastocyanin bound to chloroplast membrane.     

Phototropins and neochrome1 mediate nuclear movement in the fern Adiantum capillus-veneris

In gametophytic cells (prothalli) of the fern Adiantum capillus-veneris, nuclei as well as chloroplasts change their position according to light conditions. Nuclei reside on anticlinal walls in darkness and move to periclinal or anticlinal walls under weak or strong light conditions, respectively. Here we reveal that red light-induced nuclear movement is mediated by neochrome1 (neo1), blue light-induced movement is redundantly mediated by neo1, phototropin2 (phot2) and possibly phot1, and dark positioning of both nuclei and chloroplasts is mediated by phot2. Thus, both the nuclear and chloroplast photorelocation movements share common photoreceptor systems.     

Chlorophyll Formation and Photosynthetic Competence in Euglena During Light-Induced Chloroplast Development in the Presence of 3, (3,4-dichlorophenyl) 1,1-Dimethyl Urea (DCMU)

The possibility that photosynthetic competence is gratuitous for light-induced chloroplast development in Euglena gracilis var. bacillaris was examined by incubating dark-grown resting cells in the light with DCMU, an inhibitor of photosynthesis. Under these conditions photosynthetic carbon dioxide fixation was inhibited essentially completely at all times during chloroplast development, but about 70% of the chlorophyll was formed with essentially the same pattern of accumulation found for cells incubated in the absence of the inhibitor. Electron microscopy of cells incubated with DCMU in the light revealed the formation of morphologically recognizable chloroplasts having comparable overall dimensions and structural elements to those found in normally developed chloroplasts, but frequently lacking a readily detectable pyrenoid with paramylum sheaths, and often containing increased numbers of discs per lamella. Such abnormalities are considered minor since upon removal of DCMU by centrifugation, the cells usually regained almost full photosynthetic competence on a chlorophyll basis.

It is concluded that photosynthetic competence is not necessary for chloroplast development in Euglena and supports the hypothesis, already suggested from other evidence, that light induction results in activation of synthetic machinery external to the developing chloroplast.

     

Photophosphorylation and related properties of reaggregated vesicles from spinach photosystem I particles.

The small Photosystem I particles prepared from spinach chloroplasts by the action of Triton X-100 (TSF 1 particles) reaggregate into membrane structures when they are incubated with soybean phospholipids and cholate and then subjected to a slow dialysis. The membranes so formed are vesicular in nature and show the capability of catalyzing phenazine methosulfate-mediated cyclic photophosphorylation at rates which are usually about 20% of those observed with chloroplasts, but higher rates have been obtained. When coupling factor is removed from the chloroplasts by treatment with EDTA, a requirement for coupling factor can be shown for the subsequent ATP formation. The uncouplers carbonylcyanide 3-chlorophenyl-hydrazone, valinomycin, Triton X-100 and NH+4 are effective with the reformed vesicles, which do not show the typical light-induced pH gradient observed with chloroplasts. Incubation of the TSF 1 particles with phospholipids alone allows for the formation of membrane vesicles, but such vesicles are only slightly active in ATP formation. In most properties investigated, the reformed membrane vesicles resemble the original chloroplast membrane so far as phenazine methosulfate-mediated cyclic photophosphorylation is concerned, which indicates a high degree of selectivity in the reaggregation process. The major difference between chloroplasts and the reformed vesicles is the failure of the latter to show a light-induced pH gradient.