Ultrastructural changes in isolated plastids

Summary Etio-chloroplasts were isolated from greening maize leaves and their ultrastructure was investigated immediately after isolation, as well as at intervals of several hours after their exposure to light or darkness. The following ultrastructural changes have been observed:In plastids isolated from etiolated leaves illuminated for 1–2 hours, the crystalline structure of the prolamellar bodies is partly restored during the isolation. In some plastids, regions with a regular, crystalline structure of densely packed tubules are even observed. The prolamellar bodies do not change further, either in light or in darkness.In young chloroplasts—i.e., in plastids isolated from etiolated leaves, illuminated for 6 or 15 hours—many prolamellar bodies, usually lying between the grana, appearde novo during isolation. These prolamellar bodies do not disappear in light either. They do not develop at all, however, if the isolation is performed at low temperature (4 °C).The results of the present paper indicate that in isolated etio-chloroplasts some tubular structures are newly formed, but that the conversion of this material into the thylakoids is not possible under the experimental conditions used.     

Light-induced fluorescence decay during the greening of normal and lincomycin-treated maize leaves

Light-induced fluorescence decay was examined during the greening of control and lincomycintreated maize (Zea mays L.) leaves. Assuming that this decay to a first approximation is the result of two parallel first-order reactions, the fluorescence induction curves were linearized on the logarithm plot and the parameters were determined. The variable fluorescence increased, and the parameters of the two linear sections of the fluorescence decay—that is, the kinetics of the induction curves—changed during the greening of the control leaves. Lincomycin treatment caused some chlorophyll deficiency and the lowering of the chlorophyll a/b ratio, changed the fluorescence emission spectra and the effect of Mg²⁺ on the regulation of the excitation energy distribution. The structure of the thylakoids and the kinetics of the fluorescence decay were also changed in the treated leaves. The possible relationship between the change of the kinetics of the fluorescence decay and the change of spillover during greening and after lincomycin treatment is discussed.Abbreviations LHC light-harvesting complex - Chl chlorophyll - LM lincomycin - PS photosystem - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

Ultrastructural localization of photosynthetic activity in thylakoids during chloroplast development in maize

The localization of photosynthetic activity in developing maize (Zea mays L.) chloroplasts was studied in situ by two electron-microscopic-cytochemical methods. The activity of photosystem I was detected by photooxidation of 3,3-diaminobenzidine (DAB) and the activity of the photosystem II by photoreduction of thiocarbamyl nitrotetrazolium blue (TCNBT). During the transformation of proplastids into chloroplasts, at the base of the leaf blade the DAB reaction appeared before the TCNBT reaction. A positive DAB reaction was observed in the single thylakoids of plastids in cells located only about 0.5 mm above the base. Dark, osmiophilic DAB polymers accumulated in the lumina of the thylakoids. Plastid envelopes and tubules of the prolamellar bodies in immature chloroplasts were DAB-negative. In fully differentiated leaf tissue the DAB reaction was intense in the thylakoids of bundle-sheath chloroplasts, as well as in the stroma thylakoids and the peripheral grana thylakoids of mesophyll chloroplats. The photoreduction of TCNBT started in leaf tissue about 1 mm above the base. Dark granular material of reduced TCNBT appeared mostly in the partitions of grana, i.e. interthylakoidally, but some granules were also attached to the stroma thylakoids. The membranes of plastid envelopes and the tubules of prolamellar bodies showed a negative TCNBT reaction. Young bundle-sheath chloroplasts contained some reduced TCNBT in their grana; these deposits largely disappeared in the course of further differentiation. In mature leaf tissue the photoreduction of TCNBT was conspicuous in the grana of mesophyll chloroplasts, but very weak in the single thylakoids and in the granal rudiments of bundle-sheath chloroplasts.Abbreviations DAB 3,3-diaminobenzidine·4 HCl - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PS(I,II) photosystem (I,II) - TCNBT thiocarbamyl nitrotetrazolium blue chloride     

Phosphorylation of thylakoid proteins during chloroplast biogenesis in greening etiolated and light-grown wheat leaves

Phosphorylation of polypeptides in isolated thylakoids was examined during chloroplast biogenesis in greening etiolated wheat leaves and 4 day-old wheat leaves grown under a diurnal light regime. At early stages of plastid development standard thylakoid preparations were heavily contaminated with nuclear proteins, which distorted the polypeptide phosphorylation profiles. Removal of contamination from membranes by sucrose density centrifugation demonstrated that the major membrane phosphoprotein in etioplasts was at 35 kDa. During etioplast greening a number of phosphoproteins appeared, of which the 25–27 kDa apoproteins of the light-harvesting chlorophylla/b protein complex associated with photosystem II (LHCII) became the most dominant. At the early stages of thylakoid development found at the base of the 4-day-old light grown leaf the LHCII apoproteins were evident as phosphoproteins; however the major phosphoprotein was polypeptide atca. 9kDA. Phosphorylation of both the LHCII apoproteins and the 9 kDa polypeptide in these thylakoids was not light-dependent. In the older thylakoids isolated from the leaf tip the LHCII apoproteins were the major phosphoproteins and their phosphorylation had become light-regulated; however phosphorylation of the 9 kDa polypeptide remained insensitive to light.     

Intracellular location of cytochrome oxidase active in vivo in the cyanophytes,Synechocystis sp. PCC6714 andAnacystis nidulans Tx20 and R2, grown under various conditions

Summary Intracellular location of cytochrome oxidase (cytoxidase) active in vivo was studied cytochemically with four strains of cyanophytes, using 3,3-diaminobenzidine (DAB) oxidation. DAB was oxidized in the dark bySynechocystis sp. PCC6714 and two strains ofAnacystis nidulans (Tx20 and R2) grown under photoautotrophic, heterotrophic and salt-stressed conditions, respectively. Electron microscopic observations showed that DAB-oxidation in the dark occurred in the thylakoids, but was insignificant on or around the cytoplasmic membrane. However, deposition of DAB-oxidation product around the cytoplasmic membrane was observed with cells of the thylakoid-less cyanophyteGlaeobacter violaceus ATCC29082. All DAB oxidations observed with the four strains were inhibited completely by cyanide, the inhibitor of cyt-oxidase, but not by 3-amino-1,2,4-triazole, the inhibitor of peroxidase. The results show that (1) DAB was oxidized by the cyt-oxidase functioning in the respiratory system, and that (2) cyt-oxidase in thylakoids was active in vivo.Abbreviations AT 3-amino-1,2,4-triazole - Cyt oxidase cytochrome oxidase - ETS electron transport system - DAB 3,3-diaminobenzidine     

Development of chloroplast membranes during light induced greening ofChlorella fusca g-2

Summary The development of thylakoid protein complexes during light induced greening of a mutant ofChlorella fusca was studied. Separation of chlorophyll-protein complexes and thylakoid polypeptides by LDS-polyacrylamide gel electrophoresis show that cells grown in the dark contain proteins belonging to coupling factor and cytochrome f/b₆ complex. Parts of both reaction centers are present also. The antennae complexes are specifically lost in yellow cells. The changes in polypeptide pattern at different stages of development in the light are related to ultrastructural changes. The beginning of membrane appression can be correlated with the appearance of the light-harvesting complex II. While the average diameter of EF-particles increases throughout the greening process, their densitiesapart from the rearrangement due to membrane stacking-remain fairly constant. The kinetics of EF_u-particle enlargement are different from those of EF_s-particles.PF-faces in thylakoids grown in the dark contain particles of uniform diameter but some of them protrude more from the fracture plane than do their neighbors. During the first hours of greening, their density increases and two classes develop. From the beginning of membrane stacking, the composition of PF_u-faces remains constant and PF_s-particles increase in number for some time.Results are discussed on the basis of present knowledge of structurefunction relations in thylakoids.Abbreviations CF _o intrinsic membrane complex of the coupling factor - EF, EF _s ,EF _u exoplasmic fracture face, stacked and unstacked region, respectively - LDS lithium dodecyl sulfate - LHCII light-harvesting complex of Photosystem II - PF, PF _s ,PF _u protoplasmic fracture face, stacked and unstacked region, respectively - PS I andPS II Photosystem I and Photosystem II     

Ultrastructural changes in isolated plastids

Summary Etioplasts were isolated from maize leaves and the changes in their ultrastructure were followed in light and in darkness for several hours. It has been shown that the regular crystalline structures of prolamellar bodies, present after the isolation in darkness, disappear after 30 to 60 minutes of illumination, and long straight tubules appear within prolamellar bodies. Their appearance is influenced by the molarity of the isolation medium used, by light intensity, duration of illumination and by the temperature at which the isolates are kept. Long tubules appear, however, also in isolated etioplasts incubated for several hours in complete darkness.In isolates illuminated for 2–3 hours long tubules disappear again, and prolamellar bodies produced eventually consist of irregularly connected short tubules. In prolamellar bodies, regions with regular and very dense arrangement of tubules sometimes develop at this stage. The thylakoids (usually perforated) are now arranged concentrically in the plastids. True grana or poly-thylakoids can never be found in isolated etioplasts, not even when the etioplasts have been illuminated for 6 hours or more (up to 24).The present investigations have indicated that in isolated etioplasts in light, tubular elements, which build up the prolamellar bodies, cannot normally be transformed into thylakoids as is the case with intact tissue.The survival of isolated etioplasts is limited at present, and for this reason changes in their fine structure could be followed successfully for as long as 6 hours (in light at 15 °C), although a certain percentage of plastids survive up to 24 hours.     

Quality control of Photosystem II under light stress – turnover of aggregates of the D1 protein in vivo

When photodamaged under excessive light, the D1 protein is digested and removed from Photosystem (PS) II to facilitate turnover of the protein. In vitro studies have shown that part of the photodamaged D1 protein forms aggregates with surrounding polypeptides before being digested by a protease(s) in the stroma [Yamamoto Y (2001) Plant Cell Physiol 42: 121–128]. The aim of this study was to examine whether light-induced aggregation of the D1 protein also occurs in vivo. The following results were obtained: (1) PS II activity in spinach leaves was significantly inhibited by weak illumination (light intensity, 20–100 μE m⁻² s⁻¹), as monitored by chlorophyll fluorescence Fv/Fm, when the leaves were kept at higher temperatures (35–40 °C); (2) aggregation of the D1 protein, as well as cleavage of the protein, was detected in thylakoids isolated from spinach leaves that had been subjected to heat/light stress; (3) aggregates of the D1 protein disappeared after incubation of the leaves at 25 °C in the dark or under illumination with weak light. Since it is dependent on the presence of oxygen, aggregation of the D1 protein is probably induced by reactive oxygen species produced in thylakoids upon illumination at elevated temperatures. Consistent with this notion, singlet oxygen production in thylakoid samples under illumination was shown to be stimulated significantly at higher temperatures.     

Discrete character of the development of the photosynthetic apparatus in greening barley leaves

Biogenesis of the photosynthetic apparatus in greening etiolated leaves of barley (Hordeum vulgare L) was investigated by an approach permitting investigation of this process under conditions that minimize differences in plastid development. Distributions of barley leaves greening for 24 h as to chlorophyll content and of chloroplast grana as to number of thylakoids were shown to be of a multimodal character. The shape of time-course curves of chlorophyll accumulation in local sites of greening etiolated leaves was of a stepped or (at the end of greening) undulated character. The stepwise accumulation of chlorophyll was accompanied by wave-like changes in chlorophyll b/a ratio, intensity of low-temperature chlorophyll fluorescence and photosynthetic activity with minima at the time points of transition to accelerated chlorophyll accumulation. It is assumed that (1) development of the photosynthetic apparatus in local sites of greening etiolated leaves occurs stepwise, from one steady level to another, but not as gradually as is generally accepted, and (2) every separate step in development of the photosynthetic apparatus seems to begin with formation of photosystem cores and to end with the synthesis of light-harvesting complexes. This revised version was published online in June 2006 with corrections to the Cover Date.     

Accumulation of delta-Aminolevulinic Acid and Its Relation to Chlorophyll Synthesis and Development of Plastid Structure in Greening Leaves

Levulinic acid inhibited the greening of etiolated maize (Zea mays) and bean (Phaseolus vulgaris) leaves and caused accumulation of δ-aminolevulinic acid (ALA). ALA accumulation in maize was equivalent to the decrease in chlorophyll, over a wide range of experimental conditions. It was saturated at low light intensities and was not limited by the supply of substrates during the early hours of greening. During 20 hours in light, levulinic acid had little effect on the structural development of thylakoids in bundle sheath chloroplasts but significantly reduced the number and size of thylakoids in grana of mesophyll chloroplasts. Recrystallization of prolamellar bodies and their reformation was inhibited. Mitochondria appeared not to be affected.     

THE GREENING OF ETIOLATED BEAN LEAVES AND THE DEVELOPMENT OF CHLOROPLAST FINE STRUCTURE IN ABSENCE OF PHOTOSYNTHESIS

CMU inhibits oxygen evolution in greening etiolated bean leaves.In the presence of this compound chlorophyll content is reducedand fine structure development of the chloroplasts is markedlyaffected. The number of grana per chloroplast is reduced butthe grana are larger and contain more thylakoids than the granain chloroplasts of the greening control leaves. Sucrose reversesthe effect of CMU on pigment content and fine structure developmentof chloroplasts. (Received September 14, 1965; )     

Greening of etiolated bean leaves in far red light

Eight-day-old dark-grown bean leaves were greened by prolonged irradiation with far red light. Growth, chlorophyll content, oxygen-evolving capacity, photophosphorylation capacity, chloroplast structure (by electron microscopy), and in vivo forms of chlorophyll (by low temperature absorption and derivative spectroscopy on intact leaves) were followed during the greening process. Chlorophyll a accumulated slowly but continuously during the 7 days of the experiment (each day consisted of 12 hours of far red light and 12 hours of darkness). Chlorophyll b was not detected until the 5th day. The capacity for oxygen evolution and photophosphorylation began at about the 2nd day. Electron microscopy showed little formation of grana during the 7 days but rather unfused stacks of primary thylakoids. The thylakoids would fuse to give grana if the leaves were placed subsequently in white light. The low temperature spectroscopy of intact leaves showed that the chlorophyll a was differentiated into three forms with absorption maxima near 670, 677, and 683 nanometers at −196 C during the first few hours and that these forms accumulated throughout the greening process. Small amounts of two longer wavelength forms with maxima near 690 and 698 nanometers appeared at about the same time as photosynthetic activity.     

Light-induced structural changes during incubation of isolated maize etioplasts

Summary Etioplasts were isolated from leaves of 9-day-old etiolated maize (Zea mays L.) seedlings and incubated in a relatively simple medium in light and in the dark. During the first 5 h no changes occurred in the fine structure of the isolated etioplasts in the dark. In light the size of the prolamellar bodies decreased and significantly more plastid sections without prolamellar bodies were counted. The total length of the thylakoids per plastid section increased, but there was no evidence for bi- and polythylakoid formation. It is concluded that light induces the structural transformation of the prolamellar body membranes into primary thylakoids also in isolated etioplasts.     

Partial Restoration of the High Rate of Plastid Pigment Development and the Ultrastructure of Plastids in Detached Water-stressed Wheat Leaves

Detached etiolated wheat (Triticum aestivum L. cv. Chris) leaves accumulated plastid pigments at a high rate, developed chloroplasts with stacked thylakoids, and stored plastid starch when wetted on filter paper in light. A moderate water deficit of — 10 bars markedly reduced the accumulation of chlorophyll and carotenoids in the 8-day-old detached leaves during greening. δ-Aminolevulinic acid treatment of stressed leaf segments resulted in slightly increased pigment accumulations but benzyladenine application restored plastid pigment formation in stressed tissue to within 15% of the pigment content of the nonstressed detached leaves. The addition of δ-aminolevulinic acid to benzyladenine-treated stressed leaf segments improved both chlorophyll and carotenoid formation to nearly the amounts found in nonstressed leaf tissue. Stressed leaf sections developed plastids that were small, lacked starch, contained few thylakoids per granum, and possessed dilated thylakoids. Benzyladenine application to the stressed leaf segments did not restore normal plastid stacking but benzyladenine induced the formation of extended intergranal lamellae and stimulated pigment accumulations in both stressed and nonstressed detached leaves. Starch was absent in plastids of benzyladeninetreated leaf sections.     

Ultrastructural aspects of petal development inCucumis sativus with particular reference to the chromoplasts

Summary Changes in fine structure in petals ofCucumis have been followed from an early green stage, through maturity, to a senescent dark yellow stage. The most noticable changes occur in the plastids. In chloroplasts of young green petals bundles of tubules appear in the stroma and increase in number as the thylakoids disappear. The entire plastid is eventually filled by groups of tubules orientated in different planes, separated by a few remaining swollen thylakoids. It is proposed that these chromoplast tubules represent a reorganization of the thylakoid material. In the mature chromoplast these tubules have become widely separated and randomly orientated, the whole plastid being approximately five times the volume of the chloroplast from which it was derived. Chromoplasts in senescent petals show a number of cytoplasmic invaginations.Other cytoplasmic components show degredative changes throughout petal maturation corresponding to the senescence syndrome found in cucumber leaves and cotyledons.The significance of the observations is discussed.One of us (M. S.) acknowledges receipt of a Science Research Council Studentship.     

Light-induced Changes in the Ultrastructure of Pea Chloroplasts in Vivo: Relationship to Development and Photosynthesis

Light-induced structural changes of chloroplasts and their lamellae were studied in leaves of Pisum sativum L., cv. Blue Bantam, using electron microscopy. Upon illumination of 14-day-old plants with 2000 lux, the chloroplasts decreased in thickness by about 23% with an accompanying increase in electron scattering by the stroma. Concomitantly, the average thickness of granal lamellae (thylakoids) decreased from 195 ± 4 angstroms in the dark to 152 ± 4 angstroms in the light, and this change was half-saturated at only 50 lux. Lamellar flattening at 50 lux and its reversal in the dark both had half-times of a minute or less. The thickness of a partition (a pair of apposed lamellar membranes) was 140 ± 9 angstroms in both the light and the dark, indicating that the observed light-induced change was in the volume enclosed within the thylakoid. The effect of illumination could be inhibited by various uncouplers of photophosphorylation but not by 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea, suggesting that it depended on ATP (or its precursor). In the presence of 0.5 micromolar nigericin, the thickness of the granal lamellae increased in the light to 213 ± 3 angstroms; this may reflect an uptake of K⁺ into an osmotically responding space within the thylakoids.     

Photothermal Spectra of Thylakoids Isolated from Cucumber Cotyledons at Various Stages of Greening

The character of interaction between carotenoids (Cars) and chlorophylls (Chls) in thylakoids isolated from cucumber cotyledons at three stages of greening (3, 6, and 24 h of irradiation with 120 µmol m^–2 s^–1) was studied. The shapes of the steady state photoacoustic spectra were changed with the change in time of greening and with the frequency of radiation modulation. The shapes show that changes not only in the contents of various pigments but also in pigment interactions with surrounding occur and that processes of thermal deactivation characterised by different kinetics take place. Slow processes of thermal deactivation are in most cases due to deactivation of triplet states. Long living triplet states are very often engaged in photochemical reactions that can destroy the tissue. Analysis of the time-resolved photothermal spectra shows that at later stage of greening, the chlorophyll (Chl) molecules are better shielded against photo-destruction because Cars more efficiently quench their triplet states. The yield of formation of the pigment triplet states measured by the time resolved photothermal method, always at the same energy absorbed by pigment mixture, declined during sample greening. The decay time of the slow component of pigment thermal deactivation, due predominantly to deactivation of the triplet state of Chl, decreases with the increase of time of greening from 6.2 µs for the 3-h sample to 1.5 µs for the 24 h sample. The energy taken by Cars from Chls is dissipated into heat, therefore the steady state and quick thermal deactivation values increased during the greening process. The Cars/Chls ratio in the thylakoids decreased during greening approximately 2 fold. Hence at a later phase of greening the Cars can quench the triplet states of Chls more efficiently than at an earlier phase of greening.     

Photosystem Damage and Spatial Architecture of Thylakoids in Chloroplasts of Pea Chlorophyll Mutants

The effect of chlorophyll–protein complexes on the ultrastructure of chloroplasts was studied in the leaves of pea, the parent cultivar Torsdag and mutants chlorotica 2004 and 2014. The mutants were shown to accumulate 80 and 55% of chlorophyll, relative to the control, while the composition of the synthesized photosystem complexes was the same as in the parent cultivar Torsdag. The size of the light-harvesting antenna was similar to the control in the 2014 mutant but considerably increased (by 30%) in the 2004 mutant. These changes were due to a proportional decrease in the number of all complexes (by 40–45%) in the 2014 mutant. At the same time, the number of reaction center complexes of photosystem I (PS I) decreased by 50% while that of photosystem II (PS II) remained virtually constant in the 2004 mutant. A proportional decrease in the number of the PS I and PS II complexes in the chlorotica 2014 mutant was accompanied by a partial reduction of the entire chloroplast membrane system against the background of normal development of both granal and intergranal sites of thylakoids. Conversely, the loss of PS I reaction centers led mainly to the reduction of the intergranal sites of thylakoids in chloroplasts. This effect is attributed to the prevalence of PS I complexes in the intergranal thylakoids.     

Cytochemical Detection of Cell Wall Bound Peroxidase in Rust Infected Broad Bean Leaves*

Cell wall bound peroxidase activity, cytochemically detected by 3,3-diaminobenzidine (DAB), appears unevenly distributed in areolae of broad bean (cv. Aguadulce) leaves infected by the rust fungus Uromyces viciae-fahae (Pers.) Schroet. DAB positivity is not significantly traceable at the periphery of the areola and close to the site of uredinium formation; heavy DAB deposits occur on walls of haustoria containing mesophyll cells. Induction of localized peroxidase activity appears strictly related to the haustorium mother cell differentiation, i.e. to the incipient parasitic phase; it does not, however, counteract the intracellular growth of the haustorium.     

Effect of preincubation temperature on in vitro light saturated photosystem I activity in thylakoids isolated from cold hardened and nonhardened rye

Thylakoids isolated from winter rye (Secale cereale L. cv Muskateer) grown at 5°C or 20°C were compared with respect to their capacity to exhibit an increase in light saturated rates of photosystem I (PSI) electron transport (ascorbate/dichlorophenolindophenol → methylviologen) after dark preincubation at temperatures between 0 and 60°C. Thylakoids isolated in the presence or absence of Na⁺/Mg²⁺ from 20°C grown rye exhibited transient, 40 to 60% increases in light saturated rates of PSI activity at all preincubation temperatures between 5 and 60°C. This increase in PSI activity appeared to occur independently of the electron donor employed. The capacity to exhibit this in vitro induced increase in PSI activity was examined during biogenesis of rye thylakoids under intermittent light conditions at 20°C. Only after exposure to 48 cycles (1 cycle = 118 minutes dark + 2 min light) of intermittent light did rye thylakoids exhibit an increase in light saturated rates of PSI activity even though PSI activity could be detected after 24 cycles. In contrast to thylakoids from 20°C grown rye, thylakoids isolated from 5°C grown rye in the presence of Na⁺/Mg²⁺ exhibited no increase in light saturated PSI activity after preincubation at any temperature between 0 and 60°C. This was not due to damage to PSI electron transport in thylakoids isolated from 5°C grown plants since light saturated PSI activity was 60% higher in 5°C thylakoids than 20°C thylakoids prior to in vitro dark preincubation. However, a two-fold increase in light saturated PSI activity of 5°C thylakoids could be observed after dark preincubation only when 5°C thylakoids were initially isolated in the absence of Na⁺/Mg²⁺. We suggest that 5°C rye thylakoids, isolated in the presence of these cations, exhibit light saturated PSI electron transport which may be closer to the maximum rate attainable in vitro than 20°C thylakoids and hence cannot be increased further by dark preincubation.