辣椒彩色斑叶突变体叶片显微结构及超微结构研究

以彩色斑叶辣椒突变体、紫叶辣椒、白色斑叶辣椒突变体功能叶为试验材料,利用光学显微镜和透射电子显微镜,通过观察叶片不同斑区的显微结构及超微结构,分析彩色斑叶的显色部位、显色特征、细胞器数量及形态变化,从细胞水平上探讨彩色斑叶辣椒复杂叶色的成因。结果表明：(1)彩色斑叶辣椒突变体子叶为紫色,自第一片真叶展开出现异色斑块,斑块位置、频率、色彩深度无明显规律。(2)叶肉细胞内叶绿体少甚至缺失形成白斑,花色素苷在叶肉细胞和保卫细胞均有分布,其在叶肉细胞不均匀分布是紫色深度不同的主因。(3)辣椒彩色斑叶突变体绿斑区内细胞形态良好,细胞器结构较好;紫色斑区和白色斑区细胞呈中度肿胀,细胞器明显异常。(4)叶肉细胞内叶绿体少甚至缺失、花色素苷不均匀分布是叶片呈现彩色的原因,该叶斑类型属于色素型。     

Effects ofFusarium solani naphthazarin toxins on the cytology and ultrastructure of rough lemon seedlings

Two naphthazarin phytotoxins (dihydrofusarubin and isomarticin) produced byFusarium solani were used to determine their effects on the cytology of leaves of rough lemon (Citrus jambhiri Lush) seedlings maintained in a dilute solution of the toxins. Dihydrofusarubin alone or in combination with isomarticin (80:20, v/v) caused cell necrosis above the midveins and lateral veins, plasmolysis or collapse of spongy mesophyll cells, collapse of phloem, depletion of starch, swelling of chloroplasts and disruption of cellular organization. At the ultrastructural level, the toxins affected chloroplast membranes by causing swelling, breaks in outer membranes, granal stack disorganization and swelling of intergranal membranes. The interstromal lamellae appeared as vesicles and sometimes as peripheral reticulum, with an increase in plastoglobuli. The tonoplast was broken or vesiculated. The only membranes not affected by the toxins were those of the nucleus and the mitochondria. This study establishes that the initial toxin effects of these fungal phytotoxins are on organellar membranes, primarily those of the chloroplasts, plasmalemma and tonoplast.Florida Agricultural Experiment Station Journal Series No. R-00648. This paper reports the results of research only. Mention of a trademark, warranty, proprietary product, or vendor does not constitute a guarantee by the US Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable.     

Differential turnover of the photosystem II reaction centre D1 protein in mesophyll and bundle sheath chloroplasts of maize

Photoinhibition is caused by an imbalance between the rates of the damage and repair cycle of photosystem II D1 protein in thylakoid membranes. The PSII repair processes include (i) disassembly of damaged PSII-LHCII supercomplexes and PSII core dimers into monomers, (ii) migration of the PSII monomers to the stroma regions of thylakoid membranes, (iii) dephosphorylation of the CP43, D1 and D2 subunits, (iv) degradation of damaged D1 protein, and (v) co-translational insertion of the newly synthesized D1 polypeptide and reassembly of functional PSII complex. Here, we studied the D1 turnover cycle in maize mesophyll and bundle sheath chloroplasts using a protein synthesis inhibitor, lincomycin. In both types of maize chloroplasts, PSII was found as the PSII-LHCII supercomplex, dimer and monomer. The PSII core and the LHCII proteins were phosphorylated in both types of chloroplasts in a light-dependent manner. The rate constants for photoinhibition measured for lincomycin-treated leaves were comparable to those reported for C3 plants, suggesting that the kinetics of the PSII photodamage is similar in C3 and C4 species. During the photoinhibitory treatment the D1 protein was dephosphorylated in both types of chloroplasts but it was rapidly degraded only in the bundle sheath chloroplasts. In mesophyll chloroplasts, PSII monomers accumulated and little degradation of D1 protein was observed. We postulate that the low content of the Deg1 enzyme observed in mesophyll chloroplasts isolated from moderate light grown maize may retard the D1 repair processes in this type of plastids.     

Salt impact on photosynthesis and leaf ultrastructure of <Emphasis Type="Italic">Aeluropus littoralis</Emphasis>

The effects of salinity (400 mM NaCl) on growth, biomass partitioning, photosynthesis, and leaf ultrastructure were studied in hydroponically grown plants of Aeluropus littoralis (Willd) Parl. NaCl produced a significant inhibition of the main growth parameters and a reduction in leaf gas exchange (e.g. decreased rates of photosynthesis and stomatal conductance). However, NaCl salinity affected neither the composition of photosynthesis pigments nor leaf water content. The reduction in leaf gas exchange seemed to correlate with a decrease in mesophyll thickness as well as a severe disorganisation of chloroplast structure, with misshapen chloroplasts and dilated thylakoid membranes. Conspicuously, mesophyll chloroplasts were more sensitive to salt treatment than those of bundle sheath cells. The effects of NaCl toxicity on leaf structure and ultrastructure and the associated physiological implications are discussed in relation to the degree of salt resistance of A. littoralis.     

Two immunological approaches to the detection of ribulose-1,5-bisphosphate carboxylase in guard cell chloroplasts

Two immunological approaches were used to determine if ribulose bisphosphate carboxylase oxygenase (RuBisCo) is present in guard cell chloroplasts. Immunocytochemistry on thin plastic sections using tissue samples that were processed using traditional glutaraldehyde/osmium fixation and then restored to antigenicity with metaperiodate treatment, resulted in labeling over wild-type mesophyll and guard cell plastids of several green and white variegated Pelargonium chimeras. The density of immunogold labeling in guard cell chloroplasts was only about one-seventh of that noted in mesophyll chloroplasts on a square micron basis. Because guard cell chloroplasts are much smaller than mesophyll chloroplasts, and occur at lower quantities/cell, the relative differences in RuBisCo concentration between the cell types indicate that guard cells have only 0.48% of the RuBisCo of mesophyll cells. No reaction was noted over 70S ribosomeless plastids of these chimeras even though adjacent green chloroplasts were heavily stained, indicating the high specificity of the reaction for RuBisCo. Spurr's resin gave the most successful colloidal gold labeling in terms of low background staining and structural detail but L. R. White's resin appeared to be superior for antigen retention. In the white leaf edges of the white and green Pelargonium chimeras, the only green, functional chloroplasts are in the guard cells. When either whole tissue or plastid enriched extracts from this white tissue were electrophoresed, blotted, and probed with anti-RuBisCo a large subunit band was detected, identical to that in the green tissue. These data indicate that a low, but detectable, level of RuBisCo is present in guard cell chloroplasts.     

Lincomycin-induced alteration in the contents of chlorophyll-protein complexes of dimorphic maize chloroplasts and its effect on the temperature-induced spectral changes

The difference spectroscopy technique has been utilized to investigate the temperature-induced spectral changes in mesophyll and bundle sheath chloroplasts of maize ( Zea mays L. cv. Ganga-5) in order to assess the role of different pigment-protein complexes in the manifestation of temperature effect on the chloroplast membranes. Cooling and heating of both mesophyll and bundle sheath chloroplasts resulted in absorbance difference (AA) bands at similar wavelengths but the degree of absorb-ance changes were significantly higher in bundle sheath chloroplasts. For example, upon cooling to 7-8°C, positive AA bands were observed at 440, 490 and 680 nm in mesophyll chloroplasts and at 440, 495–500 and 680 nm in bundle sheath chloroplasts but the absorbance change at 680 nm was ca 2% in mesophyll chloroplasts, whereas it was ca 5% in bundle sheath chloroplasts, which have a lower content of light-harvesting pigment-protein complex. The role of chlorophyll-protein complexes was further investigated by monitoring the temperature-induced spectral changes of mesophyll and bundle sheath chloroplasts isolated from lincomycin-treated maize plants where lincomycin selectively inhibits the biosynthesis of specific chlorophyll-protein complexes. Results indicated that depletion of certain pigment-protein complexes in mesophyll chloroplasts made them more susceptible (a ca 4% vs ca 2% absorbance change upon cooling and a ca 6% vs ca 4% absorbance change upon heating) and less tolerant to temperature variation (a 76% vs 39% reversibility during ambient→Cooling→ambient temperature cycle). The data indicate that pigment-protein complexes play a significant role in protecting the chloroplast membranes against temperature variation.     

Rubisco和RCA在青菜叶绿体中的分布及病毒侵染对其细胞定位的影响

运用免疫金标电镜术观察了青菜叶细胞中光合作用关键酶Rubisco和Rubisco活化酶(RCA)的细胞化学定位,结果显示Rubisco和RCA免疫金颗粒主要分布于薄壁组织叶绿体的间质中,在基粒片层上很少,表皮的气孔保卫细胞和维管束薄壁细胞叶绿体内也有分布,在细胞质及线粒体等细胞器中无特异性分布。同时比较观察了感染芜菁花叶病毒(TuMV)的青菜叶绿体Rubisco和RCA免疫金标记结果,发现病组织中结构尚完整的叶绿体Rubisco和RCA标记率略有下降,而结构严重破坏的叶绿体中两种酶标记率分别仅为正常叶绿体的58．44％和64．67％,表明病毒侵染可导致Rubisco和RCA含量下降,影响寄主植物的光合作用。     

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.     

Ultrastructure of chloroplasts of pine needles exposed to an industrial environment

In one- and two-year-old green needles ofPinus pinaster growing downwind from a coal-fired power station (main airborne pollutant SO₂), mesophyll chloroplast alterations consisted in swelling of the lamellae (ranging in intensity from slight to pronounced), reduction of grana number, and granulation of the stroma. The most severely affected chloroplasts were almost spherical, with highly dilated and corrugated lamellae and lacunae in the stroma. There was a large increase in the amount of lipid-like material present as droplets in cytoplasm, vacuole and stroma chloroplasts; these droplets appeared to be expulsed from the chloroplasts to the cytoplasm and vacuole. The trees with the most severely affected chloroplasts stood southwest of the power station,i.e. downwind with respect to the winds prevailing most of the year. Chloroplasts from two-year-old needles were more affected than those from one-year-old needles.     

Carbohydrate distribution and cellular injuries in acid rain and cold-treated spruce needles

Summary The cellular structures of acid rain-irrigated needles of several provenances of Norway spruce (Picea abies L. Karst) seedlings were studied after winter experimental freezing. Frost injuries and recovery were characterized by visual damage scoring and classification of mesophyll cell alterations, also using histochemical methods for carbohydrate fluorescent staining. The treatment with-30° C during the late dormancy period was sufficient to cause significant injuries and intracellular degradation in the tissues of the green needles. The most affected seedlings in terms of visual injury scoring were found among those treated with clean water or at pH 3, while freezing injury, defined as an occlusion of phenolic substances in the central vacuole of the mesophyll cells, was most abundant in the needles from spruces irrigated either with clean water or at pH 4 or pH 3. Electron microscopy revealed the details of the injury, e. g. thinning out of the cytoplasm and chloroplast stroma, darkening of the chloroplasts and eventually swelling of the chloroplasts and protoplast. PAS and ConA reactions in the needle tissue revealed intense starch accumulation in the mesophyll and transfusion tissues as early as in March, with a tendency to increase, especially in the untreated needles during the recovery period. Plasma membrane disturbances were indicated by histochemical identification of callose deposits in the mesophyll cell walls, these being most abundant in the acid rain-treated needles. All these findings suggest that freezing at –30° C was more deleterious to the seedlings pretreated with acid or clean water than to those not given additional irrigation.     

Conservation of Cell Order in Desiccated Mesophyll of Selaginella lepidophylla ([Hook and Grev.] Spring)

Understanding of the basis of desiccation tolerance in matureplant tissues that survive extreme dehydration requires knowledgeof the degree of cellular order in the dry state. Generally,aqueous fixatives have been used in ultrastructural studiesof such material, and these are known to be inadequate in thepreservation of dry material. Cryopreservation provides a moreassured level of fixation fidelity than aqueous fixatives, particularlywith dry material. Using freeze substitution and electron microscopy,we examined the ultrastructure of dry mesophyll cells ofSelaginellalepidophylla ([Hook and Grev.] Spring). In this material thecells were condensed and had highly folded walls. The plasmalemmawas bounded on both sides by layers of granular material, andthe membrane was in close and continuous apposition to the walls.The conformation and position of organelles and their structureappeared to be influenced by being compacted within the shrunkencells, but the ultrastructural integrity of all organelles andcellular membranes, including mitochondria, chloroplasts andvacuoles, was maintained in the dry state. These cells had numeroussmall vacuoles clustered in aggregates, and the tonoplast membranesappeared to be coated on the internal side by a fine granularlayer. The vacuoles contained osmiophilic material of varyingdegrees of condensation and had embedment holes suggesting thepresence of salt crystals within the vacuoles. The general conclusionsfrom these studies are that a critical level of cell order ismaintained in the dry state in these desiccation-tolerant plants,and a high degree of effective packing and shape fitting ofcellular constituents with the compaction forces of dehydrationunderlies this conservation of cell order. Freeze substitution; Selaginella lepidophylla ([Hook and Grev.] Spring); ultrastructure; membrane structure; desiccation tolerance; resurrection plants     

Induction of tetraploidy in Juncus effusus by colchicine

Tetraploidy was induced in vitro in mat rush (Juncus effusus L.) cultivar Nonglin-4 by exposure to colchicine (0, 50, 100 and 500 mg dm^?3) for 6, 12 and 24 h. Flow cytometric analysis was used to confirm the ploidy level. Anatomical and ultrastructural analyses at cellular and subcellular levels in tetraploid and diploid control plants revealed differences between diploid and tetraploid plants. The leaf epidermis had larger stomata but lower stomatal density in tetraploid plants. In addition, mesophyll cells in tetraploid plants appeared more compact and showed less intercellular spaces along with increased size of vascular bundles. However, a significant reduction of chlorophyll content was observed in tetraploid plants that might be the result of structural modification in the lamellar membranes of chloroplasts.     

干旱胁迫对3种不同光合类型荒漠植物叶绿体和线粒体超微结构的影响

以荒漠木本C_3植物天山猪毛菜、C_3-C_4中间型植物松叶猪毛菜、C_4植物木本猪毛菜为研究对象,采用盆栽控水试验,设置正常供水和轻度、中度和重度干旱处理(土壤含水量分别为田间持水量的80%、60%、45%和35%),研究不同程度干旱胁迫对3种不同光合类型荒漠植物叶片超微结构的影响。结果表明:(1)正常水分条件下,叶肉细胞中各细胞器结构完整。(2)轻度干旱胁迫下,3种植物叶片超微结构未受损伤,无明显变化。(3)中度干旱胁迫下,天山猪毛菜和松叶猪毛菜叶肉细胞壁界限不清晰,类囊体片层扩张且排列不紧密,不同之处在于,天山猪毛菜线粒体最先出现降解,内含物流失,而松叶猪毛菜线粒体外膜轮廓变形,嵴减少;木本猪毛菜线粒体无明显变化,叶绿体轻微扩张。(4)重度干旱胁迫下,天山猪毛菜和松叶猪毛菜叶绿体受损且结构混乱,线粒体出现降解;木本猪毛菜叶绿体出现膨胀,线粒体外膜轮廓模糊,嵴减少且结构模糊不清楚。研究认为,不同程度干旱胁迫下木本猪毛菜叶绿体和线粒体的受损程度都最低;干旱胁迫下天山猪毛菜和松叶猪毛菜叶绿体的受损程度大致相似;松叶猪毛菜和木本猪毛菜线粒体对干旱胁迫的耐受力要比叶绿体强。     

Investigating cytoskeletal function in chloroplast protrusion formation in the arctic-alpine plant Oxyria digyna

Arctic and alpine plants like Oxyria digyna have to face enhanced environmental stress. This study compared leaves from Oxyria digyna collected in the Arctic at Svalbard (78 degrees N) and in the Austrian Alps (47 degrees N) at cellular, subcellular, and ultrastructural levels. Oxyria digyna plants collected in Svalbard had significantly thicker leaves than the samples collected in the Austrian Alps. This difference was generated by increased thickness of the palisade and spongy mesophyll layers in the arctic plants, while epidermal cells had no significant size differences between the two habitats. A characteristic feature of arctic, alpine, and cultivated samples was the occurrence of broad stroma-filled chloroplast protrusions, 2 - 5 microm broad and up to 5 microm long. Chloroplast protrusions were in close spatial contact with other organelles including mitochondria and microbodies. Mitochondria were also present in invaginations of the chloroplasts. A dense network of cortical microtubules found in the mesophyll cells suggested a potential role for microtubules in the formation and function of chloroplast protrusions. No direct interactions between microtubules and chloroplasts, however, were observed and disruption of the microtubule arrays with the anti-microtubule agent oryzalin at 5 - 10 microM did not alter the appearance or dynamics of chloroplast protrusions. These observations suggest that, in contrast to studies on stromule formation in Nicotiana, microtubules are not involved in the formation and morphology of chloroplast protrusions in Oxyria digyna. The actin microfilament-disrupting drug latrunculin B (5 - 10 microM for 2 h) arrested cytoplasmic streaming and altered the cytoplasmic integrity of mesophyll cells. However, at the ultrastructural level, stroma-containing, thylakoid-free areas were still visible, mostly at the concave sides of the chloroplasts. As chloroplast protrusions were frequently found to be mitochondria-associated in Oxyria digyna, a role in metabolite exchange is possible, which may contribute to an adaptation to alpine and arctic conditions.     

Sudden Collapse of Vacuoles in Saintpaulia sp. Palisade Cells Induced by a Rapid Temperature Decrease

It is well known that saintpaulia leaf is damaged by the rapid temperature decrease when cold water is irrigated onto the leaf surface. We investigated this temperature sensitivity and the mechanisms of leaf damage in saintpaulia (Saintpaulia sp. cv. ‘Iceberg’) and other Gesneriaceae plants. Saintpaulia leaves were damaged and discolored when subjected to a rapid decrease in temperature, but not when the temperature was decreased gradually. Sensitivity to rapid temperature decrease increased within 10 to 20 min during pre-incubation at higher temperature. Injury was restricted to the palisade mesophyll cells, where there was an obvious change in the color of the chloroplasts. During a rapid temperature decrease, chlorophyll fluorescence monitored by a pulse amplitude modulated fluorometer diminished and did not recover even after rewarming to the initial temperature. Isolated chloroplasts were not directly affected by the rapid temperature decrease. Intracellular pH was monitored with a pH-dependent fluorescent dye. In palisade mesophyll cells damaged by rapid temperature decrease, the cytosolic pH decreased and the vacuolar membrane collapsed soon after a temperature decrease. In isolated chloroplasts, chlorophyll fluorescence declined when the pH of the medium was lowered. These results suggest that a rapid temperature decrease directly or indirectly affects the vacuolar membrane, resulting in a pH change in the cytosol that subsequently affects the chloroplasts in palisade mesophyll cells. We further confirmed that the same physiological damage occurs in other Gesneriaceae plants. These results strongly suggested that the vacuoles of palisade mesophyll cells collapsed during the initial phase of leaf injury.     

Effects of Temperature Acclimation Pretreatment on the Ultrastructure of Mesophyll Cells in Young Grape Plants （Vitis vinifera L. cv. Jingxiu） Under Cross-Temperature Stresses

Leaves from annual young grape plants （Vitis vinifera L. cv. Jingxiu） were used as experimental materials. The ultrastructural characteristics of mesophyll cells in chilling-treated plants after heat acclimation （HA） and in heat-treated plants after cold acclimation （CA） were observed and compared using transmission electron microscopy. The results showed that slight injury appeared in the ultrastructure of mesophyll cells after either HA （38℃ for 10 h） or CA （8℃ for 2.5 d）, but the tolerance to subsequent extreme temperature stress was remarkably improved by HA or CA pretreatment. The increases in membrane permeability and malondialdehyde concentration under chilling （0℃） or heat （45℃） stress were markedly inhibited by HA or CA pretreatment. The mesophyll cells of plants not pretreated with HA were markedly damaged following chilling stress. The chloroplasts appeared irregular in shape, the arrangement of the stroma lamellae was disordered, and no starch granules were present. The cristae of the mitochondria were disrupted and became empty. The nucleus became irregular in shape and the nuclear membrane was digested. In contrast, the mesophyll cells of HA-pretreated plants maintained an intact ultrastructure under chilling stress. The mesophyll cells of control plants were also severely damaged under heat stress. The chloroplast became round in shape, the stroma lamellae became swollen, and the contents of vacuoles formed clumps. In the case of mitochondria of control plants subjected to heat stress, the outer envelope was digested and the cristae were disrupted and became many small vesicles. Compared with cellular organelles in control plants, those in CA plant cells always maintained an integrated state during whole heat stress, except for the chloroplasts, which became round in shape after 10 h heat stress. From these data, we suggest that the stability of mesophyll cells under chilling stress can be increased by HA pretreatment. Similarly, CA pretreatment can protect chloroplasts, mitochondria, and the nucleus against subsequent heat stress; thus, the thermoresistance of grape seedlings was improved. The results obtained in the present study are the first, to our knowledge, to offered cytological evidence of cross-adaptation to temperature stresses in grape plants.     

Na2CO3胁迫对星星草叶肉细胞超微结构的影响

利用透射电镜技术对Na2CO3胁迫下星星草叶肉细胞超微结构进行了观察。结果表明：未胁迫的叶肉细胞排列疏松,各种细胞器结构完整,叶绿体含少量淀粉粒和脂质球。轻度盐胁迫（2g/L,4g／LNa2CO3）对叶肉细胞超微结构影响较小。中度盐胁迫（6g／L,8g／L Na2CO3）引起叶肉细胞超微结构的变化,叶绿体类囊体肿胀,基粒紊乱,不含淀粉粒,脂质球数量增加,叶绿体由原来的梭形或椭球形变成圆球状;部分线粒体嵴消失,出现晶体结构;中央大液泡破裂;核逐渐降解。高度盐胁迫（10g／L,12g／LNa2CO3）下,叶绿体片层结构消失,脂质球数量增加,体积变大,被大量的膜片层所包围,叶绿体内、外膜消失,叶肉细胞中看不到叶绿体的存在;膜片层包围线粒体;叶肉细胞中可见大量的泡状结构和膜片层,叶肉细胞死亡。上述结果表明,细胞器特别是叶绿体膜结构的破坏与盐胁迫叶肉细胞最终死亡密切相关。     

Leaf anatomy and chloroplast ultrastructure of Mn-deficient orange plants

Leaf samples of Mn-deficient and Mn-sufficient (control) ‘Navelate’ orange plants grown in a greenhouse were taken to investigate the effects of Mn deficiency in leaf structure and chloroplast ultrastructure. Total leaf chlorophyll concentration was significantly lower in Mn-deficient plants than in control ones. Entire lamina thickness was not altered due to Mn deficiency. However, Mn deficiency resulted in disorganization of mesophyll cells, mainly of palisade parenchyma cells. The number of mesophyll chloroplasts per cellular area and their length were both affected negatively. The membranous system of chloroplasts was also disorganized. The percentages of starch grains and plastoglobuli per chloroplast of Mn-deficient leaves were significantly greater than those of control leaves.     

Chloroplast fine structure in the japonica-2 maize mutant exposed to continuous illumination. 1. The green tissues.

Exposure to continuous illumination causes the appearance of numerous plastoglobuli in the stroma of both the mesophyll and bundle sheath chloroplasts of the green tissues of the leaves of the japonica-2 mutant of maize. In the pale green tissues the thylakoids have markedly swollen membranes. Another feature of the plastids exposed to continuous illumination is the heavy accumulation of starch. The japonica-2 chloroplasts show a different sensitivity to light, the chloroplasts of the pale green tissues being affected more markedly than the ones of the dark green tissues, and the bundle sheath chloroplasts more than those of the mesophyll. The effects of continuous illumination may be interpreted as an acceleration of chloroplast ontogenesis.     

Ultrastructure of ferritin in the leaves of <Emphasis Type="Italic">Mesembryanthemum crystallinum</Emphasis> under stress conditions

The location and structure of ferritin in the parenchyma of leaf minor veins of the common ice plant (Mesembryanthemum crystallinum L.) treated with exogenous putrescine under salinity conditions were investigated by electron microscopy. Considerable aggregates of ferritin were detected in the chloroplasts of bundle sheath cells, in companion phloem cells, and other parenchyma cells of leaf minor veins. The structure of ferritin in the vascular parenchyma chloroplasts suggests that it was partially degraded and converted to phytosiderin. This point of view is based on indistinct structure of Fe-containing cores of ferritin molecules, break of distance between the cores, and their pronounced ability to aggregate and produce larger structures. Aggregation of Fe-containing cores apparently pointed to the destruction of ferritin protein envelope or its partial degradation. In a certain stage of ferritin destruction, electron-dense material and the structures resembling small vesicles appeared between the Fe-containing cores. Electron-dense inclusions, whose structure was similar to that of phytosiderin, were also detected in the vacuoles. Examination of the cross sections done without additional staining showed that the same as ferritin, phytosiderin in the chloroplasts and vacuoles was dark-colored against weakly colored cellular structures. In the vascular parenchyma of control plant leaves, the level of ferritin and phytosiderin was greater than in the mesophyll and much lower than in the plants simultaneously treated with NaCl and putrescine. In control material, iron cores of ferritin and phytosiderin were more light-colored and 2–3 times smaller in size than in the experimental treatment. Destruction of ferritin essentially did not occur in the mesophyll but was observed in the chloroplasts of bundle sheath cells on the border between the mesophyll and vascular bundle. The presence of much ferritin and phytosiderin on the border between the mesophyll and the vessels is accounted for by the fact that the vascular parenchyma is a buffer area that maintains a specific concentration of iron in the mesophyll of leaves and other parts of the plant. Within the cell, the role of such a buffer is performed by ferritin and vacuoles. Transformation of ferritin to insoluble hydrophobic phytosiderin is supposed to be an efficient way of withdrawing the excess of active iron from the cellular metabolism and therefore of relaxing oxidative stress. Ferritin and phytosiderin were detected not only in parenchyma cells of leaf minor veins but in sieve tubes as well. This suggests that iron may be transported within the plant as a component of protein complex.