Adaptive responses of mature giant chloroplasts in the deep‐shade lycopod Selaginella erythropus to prolonged light and dark periods

Deep‐shade plants have adapted to low‐light conditions by varying morphology and physiology of cells and chloroplasts, but it still remains unclear, if prolonged periods of high‐light or darkness induce additional modifications in chloroplasts' anatomy and pigment patterns. We studied giant chloroplasts (bizonoplasts) of the deep‐shade lycopod Selaginella erythropus in epidermal cells of mature fully developed microphylls and subjected them to prolonged darkness and high‐light conditions. Chloroplast size and ultrastructure were investigated by light and electron microscopy. Physiological traits were studied by pigment analyses, photosynthetic performance of photosystem II, and formation of reactive oxygen species. Results show that (a) thylakoid patterns and shape of mature bizonoplasts vary in response to light and dark conditions. (b) Prolonged darkness induces transitory formation of prolamellar bodies, which so far have not been described in mature chloroplasts. (c) Photosynthetic activity is linked to structural responses of chloroplasts. (d) Photosystem II is less active in the upper zone of bizonoplasts and more efficient in the grana region. (e) Formation of reactive oxygen species reflects the stress level caused by high‐light. We conclude that during prolonged darkness, chlorophyll persists and even increases; prolamellar bodies form de novo in mature chloroplasts; bizonoplasts have spatial heterogeneity of photosynthetic performance.     

The stacking of chloroplast thylakoids: Evidence for segregation of charged groups into nonstacked regions

Small particles derived from the digitonin treatment of chloroplast thylakoid membranes in either the stacked (grana-containing) or unstacked condition, as determined by cation concentration, have been used to study the aggregation of thylakoid membranes. At pH values above 5, the small particles from stacked chloroplasts do not aggregate in the presence of Mg²⁺ or other screening cations at concentrations sufficient to cause the restacking of thylakoids from low-salt chloroplasts. However, the small particles from stacked chloroplasts are aggregated either by lowering the pH to 4.6 or adding the binding cation La³⁺. In contrast, the small particles obtained on digitonin treatment of unstacked chloroplasts were aggregated by cations at neutral pH. Large particles (mainly grana) derived from digitonin treatment of stacked chloroplasts could not be unstacked by transfer to media of low cation concentration. It is concluded that the nonappressed regions of the chloroplast thylakoid membranes under stacking conditions carry higher than average negative surface charge densities under physiological pH conditions. Transfer of chloroplasts to media of low cation concentration causes a time-dependent lateral redistribution of charge between the appressed and nonappressed regions, but this redistribution is prevented by prior digitonin treatment of stacked chloroplasts.     

Membrane-bound Plastid Inclusions and Chloroplast Thylakoid Formation in Sunflower (Helianthus annuus L.)

The ultrastructure, distribution and frequency of membrane-boundplastid inclusions present in the epidermal cells of leavesof intact sunflower plants (Helianthus annuus L.) and in theepidermal and mesophyll cells of sunflower leaf discs culturedin darkness have been studied. These inclusions appear to bedilated thylakoids containing a granular material which, undernormal conditions, is probably involved in chloroplast membraneformation. It is suggested that this material accumulates, andinclusions form, in the chloroplasts of sunflower leaves intwo specific situations. Firstly, in the completely differentiatedcells of the epidermis where the chloroplasts, although at arelatively immature stage, have nevertheless reached a terminalstage of development. Secondly, in the mesophyll cells of youngleaves when chloroplast development has been arrested at animmature stage by a 5-day dark period. In the latter situationthe material can be remobilized if plastid development is restimulated.The plastids of sunflower leaf discs cultured in darkness containboth membrane-bound inclusions and prolamellar bodies, indicatingthat they are separate and distinct structures possibly containingdifferent membrane components. Helianthus annuus L., sunflower, chloroplast, ultrastructure, plastid inclusions, thylakoid formation     

THE EFFECT OF LIGHT INTENSITY AND TEMPERATURE ON PLANT GROWTH AND CHLOROPLAST ULTRASTRUCTURE IN SOYBEAN

Soybean plants grown in controlled environment cabinets under light intensities of 220 w/m² or 90 w/m² (400–700 nm) and day to night temperatures of 27.5–22.5 C or 20.0–12.5 C in all combinations, exhibited differences in growth rate, leaf anatomy, chloroplast ultrastructure, and leaf starch, chlorophyll, and chloroplast lipid contents. Leaves grown under the lower light intensity at both temperatures had palisade mesophyll chloroplasts containing well-formed grana. The corresponding leaves developed under the higher light intensity had very rudimentary grana. Chloroplasts from high temperature and high light had grana consisting of two or three appressed thylakoids, while grana from the low temperature were confined to occasional thylakoid overlap. Spongy mesophyll chloroplasts were less sensitive to growth conditions. Transfer experiments showed that the ultrastructure of chloroplasts from mature leaves could be modified by changing the conditions, though the effect was less marked than when the leaf was growing.     

青海高原不同海拔珠芽蓼叶绿体超微结构的比较

 用电子显微镜技术观察研究了生长于青海高原3个海拔地带(2500m、3200m、3980m)的珠芽蓼(polygonum viviparum L．)叶绿体的超微结构,发现随着海拔的升高,叶绿体结构呈现显著的变化趋势。2500m和3200m处叶绿体形状规则,分布在细胞边缘。3980m处叶绿体膨大变形,且分布在整个细胞当中。海拔升高,类囊体膜减少,膜垛叠程度减小。不同海拔珠芽蓼叶绿体的类囊体膜结构差异较大,特点显著。随海拔升高,珠芽蓼叶绿体破坏程度增加。主要表现为类囊体膜肿胀、类囊体膜溶解和叶绿体破裂。许多破裂的叶绿体中残留有发达的基粒和大而多的淀粉粒。珠芽蓼叶绿体的这些结构特征,既是环境胁迫的结果,又是植物适应性的表现。     

An alternative model for photosystem II/light harvesting complex II in grana membranes based on cryo-electron microscopy studies.

The photosynthetic protein complexes in plants are located in the chloroplast thylakoid membranes. These membranes have an ultrastructure that consists of tightly stacked 'grana' regions interconnected by unstacked membrane regions. The structure of isolated grana membranes has been studied here by cryo-electron microscopy. The data reveals an unusual arrangement of the photosynthetic protein complexes, staggered over two tightly stacked planes. Chaotrope treatment of the paired grana membranes has allowed the separation and isolation of two biochemically distinct membrane fractions. These data have led us to an alternative model of the ultrastructure of the grana where segregation exists within the grana itself. This arrangement would change the existing view of plant photosynthesis, and suggests potential links between cyanobacterial and plant photosystem II light harvesting systems.     

Photosynthesis in Salt-Adapted Heterotrophic Tobacco Cells and Regenerated Plants

Tobacco (Nicotiana tabacum L.) cells growing heterotrophically in the light on supplied sucrose (S0) have previously been adapted to grow in 428 mM NaCl (S25). Among the changes occurring in salinity-adapted cell cultures are (a) elevated levels of chlorophyll compared to unadapted cells; (b) decreased levels of starch; (c) alterations in chloroplast ultrastructure, including loss of starch grains, increased thylakoid membrane structure, and the presence of plastoglobules; and (d) increased rates of O2 evolution, CO2 fixation, and photophosphorylation relative to S0 cells. These latter changes apparently derive from the fact that thylakoid membranes in S25 cells contain higher levels of photosystem I- and II-associated proteins as well as thylakoid ATPase components. S25 chloroplasts contain immunologically detectable levels of ribulose-1,5-bisphosphate carboxylase/oxygenase, whereas S0 completely lack the enzyme. These changes taken together suggest that even in the presence of sucrose, S25 cells have acquired a significant degree of salt-tolerant photosynthetic competence. This salt-tolerant photoysynthetic capability manifests itself in plants backcrossed with normal plants for three generations. These plants contain chloroplasts that demonstrate in vitro more salt-tolerant CO2 fixation, O2 evolution, and photophosphorylation than do backcross progeny of plants regenerated from S0 cultures.     

Changes of Thylakoid Membrane Stacks and Chl a/b Ratio of Chloroplast from Sacred Lotus (Nelumbo nucifera) Seeds During Their Germination Under Light

Changes of chloroplast thylakoid membrane stacks and Chl a/b ratio in the plumule of sacred lotus (Nelumbo nucifera Gaertn) seeds during their germination under light were as follows: Before germination there were giant grana and very low Chi a/b ratio (0.9) in the chloroplasts. Two days after germination, the thylakoid membranes of the giant grana gradually loosened and even destacked (disintegrated), the Chl a/b ratio was 1.06. Four clays after germination, the newly formed grana thylakoid membranes were 3–5 times shorter than those of the supergrana thylakoid membranes before germination and less grana stacks were seen; the Chl a/b ratio was 1.42. Six days after germination, the stacked thylakoi membranes became more orderly arranged. In addition the grana increased in number, the stroma thylakoid membranes were scarce, the Chl a/b ratio was 2.16. Eiglt days after germination, the thylakoid membranes in each granum decreased, but the total number of grana increased only slightly. In the meantime, some large starch grains and more stroma thylakoid membranes appeared; the Chl a/b ratio was 2.77. Ten days after germination normal thylakoid membrane structure was formed both in grana and stroma lamellae. They were arranged orderly as in the chloroplasts of other higher plants; the Chl a/b ratio was 2.80. The following conclusions could be drawn from the above mentioned results: 1) There was a negative correlation between the degree of stacking of the grana thylakoid membranes and the Chl a/b ratio. This statement further proved that the membranes stacking might mainly be induced by LHCII. 2) Development of the grana thylakoid membranes within chloroplasts from sacred lotus plumule followed that of the stroma thylakoid membranes, and the tendency of changes of their Chl 2/b ratio being from the lowest to the highest and then to normal were quite different from those of other higher plants. The chloroplasts iri the latter plants contain long parallel stacks of nonappressed primary thylakoids at second step, and the changes of their ratio of Chl a/b tend to be from the highest to the lowest and then to normal. There are indications that sacred lotus plumule might employ a distinctive developing pathway. This provides an important basis for Nelumbo to possess an unique position in phylogeny of Angiospermae.     

Chloroplast ultrastructure changes in Pisum sativum associated with supplementary ultraviolet (UV-B) radiation

Pea plants (Pisum sativum L. cv. Greenfeast) were grown and exposed to supplementary UV-B radiation from day 17 after planting under growth cabinet conditions. The effects of this exposure on the ultrastructure of chloroplasts and the total soluble sugar and starch concentrations were estimated. Supplementary UV-B radiation was shown to damage the structure of chloroplasts, as manifested by dilation of thylakoid membranes, a progressive disruption of the thylakoid structure and disintegration of the double membrane envelope surrounding the chloroplast, accompanied by the accumulation of large starch grains. Diurnal changes observed in starch concentration suggest that the higher concentration of starch in supplementary UV-B-treated leaves is due to its immobilization, rather than to any increase in starch synthesis: soluble sugars accumulated and remained at a higher level and then later declined.     

CORRELATES OF LEAF OPTICAL PROPERTIES IN TROPICAL FOREST SUN AND EXTREME-SHADE PLANTS

Thirteen shade-adapted rain forest species were compared with twelve sun-adapted tropical forest species for correlates to leaf optical properties (described previously in Amer. J. Bot. 73: 1100–1108). The two samples were similar in absorptance of quanta for photosynthesis, but the shade-adapted taxa: 1) had significantly lower specific leaf weights, indicating a more metabolically efficient production of surface for quantum capture; 2) synthesized less chlorophyll per unit area; and 3) used less chlorophyll for capturing the same quanta for photosynthesis. The anatomical features that best correlate with this increased efficiency are palisade cell shape and chloroplast distribution. Palisade cells with more equal dimensions have more chloroplasts on their abaxial surfaces. This dense layer of chloroplasts maximizes the light capture efficiency limited by sieve effects. The more columnar palisade cells of sun-adapted taxa allow light to pass through the central vacuoles and spaces between cells, making chloroplasts less efficient in energy capture, but allowing light to reach chloroplasts in the spongy mesophyll. Pioneer species may be an exception to these two groups of species. Three pioneer taxa included in this study have columnar palisade cells that are extremely narrow and packed closely together. This layer allows little penetration of light, but exposure of the leaf undersurface may provide illumination of spongy mesophyll chloroplasts in these plants.     

Effect of Doubled-CO2 Concentration on the Ultrastructure of Chloroplasts from Medicago sativa and Setaria italica

It has been reported in quite a number of literatures that doubled CO2 concentration increased the photosynthetic rate and dry matter production of C3 plants, but substantially affected C4 plants little. However, why may CO2 enrichment promote growth and either no change or decrease reproductive allocation of the C3 species, but havinag no effects on growth characteristics of the C4 plants? So far, there has been no satisfactory explanation on that mentioned above, except the differences in their CO2 compensatory points. In the past, although some studies on ultrastructure of the chloroplasts under doubled CO2 concentration were limitedly conducted. Almost all the relevant experimental materials were only from C3 plants not from C4 plants, and even though the results were of inconsistancy. Thereby, it needs to verify whether the differences in photosynthesis of C3 and C4 plants at doubled CO2 level is caused by the difference in their chloroplast deterioration. Experiments to this subject were conducted at the Botanical Garden of Institute of Botany, Academia Sinica in 1993 and 1994. Both experimental materials from C3 plant alfalfa (Medicago sativa) and C4 plant foxtail millet (Setaria italica) were cultivated in the cylindrical open-top chambers (2.2 m in diameter × 2.4 m in height) with aluminum frames covered by polyethylene film. Natural air or air with 350× 10-6 CO2 were blown from the bottom of the chamber space with constant temperature between inside and outside of the chamber 〈0.2℃〉. Electron microscopic observation revealed that the ultrastructure of the chloroplasts from C3 plant Medicago sativa and C4 plant Seteria italica growing under the same doubled CO2 concentration were quite different from each other. The differential characteristics in ultrastructure of chloro plasts displayed mainly in the configuration of thylakoid membrances and the accumulation of starch grains. They were as follows: 1. The most striking feature was the building up of starch grains in the chloroplasts of the bundle sheath cells (BSCs) and the mesophyll cells (MCs) at doubled CO2 concentra tion. The starch grains appeared centrifugally first in the BSCs and then in the chloroplast of the other MCs. It was worthy to note that the starch grains in the chloroplasts of C4 plant Setaria ira/ica were much more than those of the C3 plant Medicago sativa . The decline of photosynthesis in the doubled CO2-grown C4 plants might be caused by an over accumulation of starch grains, that deformed the chloroplast even demaged the stroma thylakoids and grana. There might exsist a correlation between the comformation of thylakoid system and starch grain accumulation, namely conversion and transfer of starch need energy from ATP, and coupling factor (CF) for ATP formation distributed mainly on protoplastic surface (PSu) of stroma thylakoid membranes, as well as end and margin membranes of grana thylakoids. Thereby, these results could provide a conclusive evidence for the reason of non effectiveness on growth characteristics of C4 plant. 2. Under normal condition , the mature chlolroplats of higher plants usually develop complete and regularly arranged photosynthetic membrane systems . Chloroplasts from the C4 plant Setaria italica, however, exerted significant changes on stacking degree, grana width and stroma thylakoid length under doubled CO2 concentration; In these changes, the grana stacks were smaller and more numerous, and the number of thylakoids per granum was greatly increased, and the stroma thylakoid was greatly lengthened as compared to those of the control chloroplasts. But the grana were mutually intertwined by stroma thylakoid. The integrity of some of the grana were damaged due to the augmentation of the intrathylakoid space . Similarly, the stroma thylakoids were also expanded. In case. the plant was seriously effected by doubled CO2 concentration as observed in C4 plant Setaria italica , its chloroplasts contained merely the stroma (matrix) with abundant starch grains, while grana and stroma thylakoid membranes were unrecognizable, or occasionally a few residuous pieces of thylakoid membranes could be visualized, leaving a situation which appeared likely to be chloroplast deterioration. However, under the same condition the C3 plant Medicago sativa possessed normally developed chloroplasts, with intact grana and stroma thylakoid membranes. Its chloroplasts contained grana intertwined with stroma thylakoid membranes, and increased in stacking degree and granum width, in spite of more accumulated starch grains within the chloroplasts. These configuration changes of the thylakoid system were in consistant with the results of the authors another study on chloroplast function, viz. the increased capacity of chloroplasts for light absorption and efficiency of PSⅡ.     

The Development of Chloroplast Ultrastructure and Hill Reaction Activity During Leaf Ontogeny in Different Maize (Zea Mays L.) Genotypes

Changes in Hill reaction activity (HRA) and ultrastructure of mesophyll cell (MC) chloroplasts were studied during the ontogeny of third leaf of maize plants using polarographic oxygen evolution measurement, transmission electron microscopy, and stereology. The chloroplast ultrastructure was compared in young (actively growing), mature, and senescing leaves of two different inbreds and their reciprocal F1 hybrids. Statistically significant differences in both HRA and MC chloroplast ultrastructure were observed between different stages of leaf ontogeny. Growth of plastoglobuli was the most striking characteristic of chloroplast maturation and senescence. The chloroplasts in mature and senescing leaves had a more developed system of thylakoids compared to the young leaves. Higher HRA was usually connected with higher thylakoid volume density of MC chloroplasts.     

Leaf anatomy,chloroplast ultrastructure,and cellular localisation of ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCO) and RuBPCO activase in <Emphasis Type="Italic">Amaranthus tricolor</Emphasis> L.

In Amaranthus tricolor the leaf structure included three layers of chlorenchyma on the vascular bundle periphery, namely, mesophyll cells (MSCs) with few chloroplasts, outer larger round bundle sheath cells (BSCs) with many chloroplasts in a centripetal position, and inner smaller BSCs with few chloroplasts around the vascular bundle cells. The ultra-thin sections showed that BSCs had abundant organelles, namely many large and round mitochondria with well-developed cristae in the cytoplasm. The chloroplasts in the BSCs were lens-like bodies, which seemed to be oval on cross sections. Granal and intergranal thylakoids were usually distinguished. Grana were stacked in parallel with prevailing plane of thylakoid lamellae. The chloroplasts in the MSCs appeared smaller than those in the BSCs and contained less stacked thylakoids but abundant peripheral reticulum. The ultra-thin sections of immunogold-labelled anti-ribulose-1,5-bisphosphate carboxylase/oxygenase (anti-RuBPCO) exhibited high density of RuBPCO labelling in the stroma region of chloroplasts of the BSCs. Some anti-RuBPCO immunogold particles were observed in the stromal region of MSCs chloroplasts. The anti-activase (A) immunogold-labelling indicated that RuBPCOA was mainly distributed in the stroma region of both BSCs and MSCs chloroplasts. From the chloroplast ultrastructure and localisation of RuBPCO and RuBPCOA we deduced that the photosynthetic carbon reduction cycle and the formation of assimilatory power function in both MSC and BSC chloroplasts of A. tricolor.     

The Development of Chloroplast Ultrastructure and Hill Reaction Activity During Leaf Ontogeny in Different Maize (Zea Mays L.) Genotypes

Changes in Hill reaction activity (HRA) and ultrastructure of mesophyll cell (MC) chloroplasts were studied during the ontogeny of third leaf of maize plants using polarographic oxygen evolution measurement, transmission electron microscopy, and stereology. The chloroplast ultrastructure was compared in young (actively growing), mature, and senescing leaves of two different inbreds and their reciprocal F1 hybrids. Statistically significant differences in both HRA and MC chloroplast ultrastructure were observed between different stages of leaf ontogeny. Growth of plastoglobuli was the most striking characteristic of chloroplast maturation and senescence. The chloroplasts in mature and senescing leaves had a more developed system of thylakoids compared to the young leaves. Higher HRA was usually connected with higher thylakoid volume density of MC chloroplasts. This revised version was published online in June 2006 with corrections to the Cover Date.     

Fine structure of the chloroplast membranes ofEuglena gracilis as revealed by freeze-cleaving and deep-etching techniques

Summary The chloroplasts ofEuglena gracilis have been examined by freeze-cleaving and deep-etching techniques.The two chloroplast envelope membranes exhibit distinct fracture faces which do not resemble any of the thylakoid fracture faces.Freeze-cleaved thylakoid membranes reveal four split inner faces. Two of these faces correspond to stacked membrane regions, and two to unstacked regions. Analysis of particle sizes on the exposed faces has revealed certain differences from other chloroplast systems, which are discussed. Thylakoid membranes inEuglena are shown to reveal a constant number of particles per unit area (based on the total particle number for both complementary faces) whether they are stacked or unstacked.Deep-etchedEuglena thylakoid membranes show two additional faces, which correspond to true inner and outer thylakoid surfaces. Both of these surfaces carry very uniform populations of particles. Those on the external surface (the A surface) are round and possess a diameter of approximately 9.5 nm. Those on the inner surface (the D surface) appear rectangular (as paired subunits) and measure approximately 10 nm in width and 18 nm in length. Distribution counts of particles show that the number of particles per unit area revealed by freeze-cleaving within the thylakoid membrane approximates closely the number of particles exposed on the external thylakoid surface (the A surface) by deep-etching. The possible significance of this correlation is discussed. The distribution of rectangular particles on the inner surface of the thylakoid sac (D surface) seems to be the same in both stacked and unstacked membrane regions. We have found no correlation between the D surface particles and any clearly defined population of particles on internal, freeze-cleaved membrane faces. These and other observations suggest that stacked and unstacked membranes are similar, if not identical in internal structure.     

New insights in thylakoid membrane organization

High-pressure freezing (HPF) in combination with freeze substitution (FS) was used to analyse changes in the structure of barley chloroplasts during the daily change of light and darkness. In contrast to conventional treatment of samples, HPF-FS revealed substantial differences in chloroplast shape, volume and ultrastructure in the light period and during darkness. While chloroplasts have an ellipsoidal shape in the light, they have an enlarged and round form during the dark period. Samples collected in the light show the typical differentiation of stroma and grana thylakoids as observed by conventional ultrastructural analyses. In chloroplasts of samples collected during the dark period, thylakoids were swollen and grana stacks to a large extent were disintegrated. Similar changes occurred when leaves in the light were treated with the uncoupler gramicidin. The results suggest that the light-dependent changes in thylakoid membrane organization are related to the light-dependent changes in the ionic milieu of the thylakoid lumen and the stroma.     

Light-Induced Adaptive Responses under Greenhouse and Controlled Conditions in the Fern Pteris cretica var. ouvrardii

The influence of different growth irradiance conditions on plant development and foliar features were assessed in a shade-adapted fern variety, Pteris cretica var. ouvrardii. A comparison of frond morphology, anatomy, chloroplast infrastructure and chlorophyll content of plants cultivated in both greenhouse and in controlled growth chambers under moderate light, low light (control) and extreme shade revealed pronounced phenotypic modifications. Moderate light induced decreased frond surfaces, thicker leaves, lower chlorophyll content per surface unit, and a markedly reduced density of intraplastidial membranes. In contrast, morphological responses to extreme shade included the formation of larger, thinner fronds, increased chlorophyll content; and a higher membrane density in chrloplasts. A dorsi-ventral distribution of starch-gorged chlroplasts (lower mesophyll cell layers) and essentially starch-free chloroplasts (upper cell layer) characterizes low-light and moderate light fronds, while homogenous starch-free chloroplasts are present in all cell layers of extreme shade fronds. The light-induced modifications are discussed as adaptive responses.     

Fine Chloroplast Structure in Cucumber and Pea Leaves Developed under Red Light

Photosynthetic activity, the content of various photosynthetic pigments, and the chloroplast ultrastructure were examined in the leaves of cucumber (Cucumis sativus L.) and pea (Pisum sativum L.) plants of different ages grown under red light (600–700 nm, 100 W/m²). In pea leaves tolerant to red-light irradiation, chloroplast ultrastructure did not essentially change. In the first true leaves of cucumber plants susceptible to red-light irradiation, we observed a considerable increase in the number and size of plastoglobules, the appearance of chloroplasts lacking grana or containing only infrequent grana, and stromal thylakoids. In the upper leaves of 22-day-old cucumber plants, the chloroplast structure was essentially similar to that of the control chloroplasts in white light, and we therefore suppose that these plants have acclimated to red light.     

Low temperature-induced modifications in cell ultrastructure and localization of phenolics in winter oilseed rape (Brassica napus L. var. oleifera L.) leaves

Acclimation of winter oilseed plants in the cold (i.e. at temperatures >0 degrees C) followed by short exposure to sub-lethal freezing temperatures resulted in pronounced ultrastructural changes of leaf epidermal and mesophyll cells. The following major changes were observed upon acclimation at 2 degrees C: increased thickness of cell walls; numerous invaginations of plasma membranes; the appearance of many large vesicles localized in the cytoplasm in close proximity to the central vacuole; the occurrence of abundant populations of microvesicles associated with the endoplasmic reticulum (ER) cisternae or located in the vicinity of dictyosomes; and the occurrence of paramural bodies and myelin-like structures. In addition, large phenolic deposits were observed in the vicinity of the plasma membrane and membrane-bound organelles such as chloroplasts, large vesicles or cytoplasm/tonoplast interfaces. Transient freezing (-5 degrees C for 18 h) of the cold-acclimated leaves led to reversible disorganization of the cytoplasm and to pronounced structural changes of the cellular organelles. Chloroplasts were swollen, with the stroma occupying one half of their volume and the thylakoid system being displaced to the other half. Large phenolic aggregates disappeared but distinct layers of phenolic deposits were associated with mitochondrial membranes and with chloroplast envelopes. In frost-thawed cells recovered at 2 degrees C for 24 h, dictyosomes and dictyosome- or ER-derived small vesicles reappeared in the ribosome-rich cytoplasm. Aberrations in the structure of chloroplasts and mitochondria were less pronounced. Few phenolic deposits were seen as small grains associated with chloroplast envelopes and vesicle membranes. These observations demonstrate that plants undergo different changes in cell ultrastructure depending on whether they are subjected to chilling or freezing temperatures. Results are discussed in relation to membrane recycling and the possible role of phenolics during the first and second stages of plant acclimation at low temperature.     

The Ultrastructure of Chloroplasts,Content of Photosynthetic Pigments,and Photochemical Activity of Maize (Zea mays L.) as Influenced by Different Concentrations of the Herbicide Amitrole

The effect of three different concentrations of amitrole (AM), a bleaching herbicide affecting carotenogenesis, on chloroplast ultrastructure, photosynthetic pigment contents, and photochemical activity was studied in two maize genotypes differing in photosynthetic characteristics. The content of photosynthetic pigments in leaves of plants treated with low (20 M) AM concentration was similar to control plants and no damaging effect of the herbicide on the ultrastructure of either mesophyll (MC) or bundle-sheath (BSC) cell chloroplasts was observed. Higher (60 and 120 M) concentrations of AM caused a significant decrease in the content of carotenoids (especially xanthophylls), which was followed by photooxidative destruction of chlorophylls and some alterations of chloroplast ultrastructure. MC chloroplasts appeared more sensitive to the damaging effect of AM compared to BSC chloroplasts. A significant decrease in the amount of both granal and intergranal thylakoids in MC chloroplasts was observed with the increasing concentration of AM. As regards BSC chloroplasts, rapid decrease in the volume density of starch inclusions was found in plants treated with higher concentrations of AM. When 120 M AM was used, both MC and BSC chloroplasts contained just a few thylakoid membranes that were strongly altered. The changes in the ultrastructure of MC chloroplasts were accompanied by the changes in their photochemical activity. The formation of chloroplast protrusions after treatment of plants with AM as well as in control plants was also observed.