沙冬青叶肉细胞中一种特殊内含物的发育

用透射电镜观察了沙冬青（Ａｍ ｍ ｏｐｉｐｔａｎｔｈｕｓｍ ｏｎｇｏｌｉｃｕｓ）叶肉细胞中一种电子密度很高的近似椭圆形的特殊内含物的发育． 它始于中央液泡外侧,起初只是少量的泡状成分和电子密度很高的物质,然后两种成分逐渐增多,并随液泡膜内吞形成突起,不断伸向液泡中央,有的突起占据了液泡很大一部分体积． 接着突起中的泡状成分开始解体,电子密度很高的物质越来越多,直至充满整个突起． 当突起继续内伸时,它的尾部不断收缩变小,最后完全脱离液泡膜而游离在中央液泡里面． 这种内含物一般只出现在严冬季节,里面含有大量的脂．     

Ultrastructure and cytochemical localization of acid phosphatase of laticifers in Euphorbia kansui Liou

Acid phosphatase (AcPase) activities are involved in the degeneration process of cytoplasm in plants. In this study, acid phosphatase was detected by the method of lead nitrate and cytochemical electron microscopy during the development of nonarticulated laticifers in Euphorbia kansui Liou. The most important feature in the differentiation of the laticifers in E. kansui is that the development of small vacuoles arises from endoplasmic reticulum (ER). The mature laticifers possess a thin layer of electron-dense peripheral cytoplasm in which the organelle cannot be distinguished and a large central vacuole filled with latex particles. AcPase cytochemistry studies show AcPase reaction products congregated into heaps are distributed along the tonoplast of central vacuole and around the mitochondria and plastids. Some small vacuoles which develop at later developmental stages of laticifers contain AcPase reaction products. As a result, the central vacuole is formed by cellular autophagy and fusion of small vacuoles which apparently arises from ER.     

箭舌豌豆根瘤液泡中细菌周膜来源的研究

电镜观察结果表明,幼龄箭舌豌豆根瘤侵染细胞的细胞质较少,中央是一些体积较大的液泡。细胞质中侵入线经常可见,由侵入线释放出来的细菌均有细菌周膜。这些细菌只位于细胞质中,不出现在液泡里面。成熟根瘤中的侵染细胞与此不同,它们中有大量的成熟侵染细胞,细胞质丰富,里面充满大量细菌,中央常有一个大液泡。当中央液泡发育到一定程度时,位于其附近的细菌可通过液泡膜内吞、液泡膜与细菌周膜融合及液泡膜破裂3种途径进入液泡,后一种途径常伴有寄主细胞质。液泡中的细菌绝大部分裸露在外,只有个别细菌具有细菌周膜且多位于液泡膜的破损处附近,因此细菌周膜可能是原来就有的。     

Ultrastructural and cytochemical studies on the developing adhesive disc of Boston Ivy tendrils

Summary Ultrastructural observations of the immature adhesive disc from tendrils of Boston Ivy showed that the peripheral cells, which are the presumptive contact layer, contain vacuoles of varied sizes which are filled with electron-dense aggregates. In small vacuoles, these deposits were appressed to the tonoplast and fusion of these small vacuoles with the large vacuoles apparently occurs. Cells from the central zone were largely parenchymatous. The vacuoles of many of these parenchyma cells contained electron-dense spheres and hemispheres of material either appressed to the tonoplast or within the vacuole lumen. In these cells, the vacuole-cytoplasm interface was characterized by a filiform network of interconnected membranes. Positive reactions with reagents for the identification of polyphenols indicate that the vacuoles of nearly all the peripheral cells and scattered cells of the central zone contain tanniniferous substances. Insoluble carbohydrates also occur in the vacuoles of the peripheral cells, but they contain little or no protein or lipid.     

Secretory cells in Piper umbellatum (Piperaceae) leaves: A new example for the development of idioblasts

This work aims to investigate the origins and development of secretory cells in Piper umbellatum (L.) Miq. (Piperaceae) leaves as well as the course and the nature of their secretion. The results were compared with studies in oil-secreting cells of several species. Fully expanded fresh leaves were sectioned and subjected to different histochemical tests. Leaves in different developmental stages were fixed and processed for study under light and scanning and transmission electron microscopy techniques. The secretory cells show mixed secretion made up of hydrophobic (oleoresin) and hydrophilic (phenolic compounds and alkaloids) compounds. Secretory cells originate either from the protodermis or the ground meristem. The growth of these cells occurs primarily by increasing the volume of the central vacuole, which corresponds to an extraplasmatic space connected to a protuberance of the wall. Electron-opaque compounds are observed initially in leucoplasts, while electron-dense compounds occur in small vesicles in the cytoplasm. Both are accumulated in the central vacuole which is already developed. Besides the mixed chemical nature of the secretion identified in secretory cells of P. umbellatum leaves, these secretory cells differ from those that have already been described mainly because of the development of the central vacuole prior to the accumulation of the secretion.     

The effect of hydrostatic pressure on structural organization of maize root cells

We analyzed the effect of hydrostatic pressure at the 2–4 MPa level on the growth and organization of maize seedlings cells. At a pressure value of 2 MPa, we observed clarification of mitochondrial matrix, clusterization of endoplasmic reticulum elements with formation of ergastoplasm sites, and an increase of the number of small vacuoles in the cytoplasm. On the trans-side of dictyosomes, we revealed accumulation of vesicles with an electron-dense content, which indicates changes of transport in the endomembranous system. A decrease in the electronic density of tonoplast was accompanied by a reduction of the osmophilic inclusion amount in vacuoles. An elevation of pressure up to 4 MPa has been shown to cause destructive alterations in the tonoplast. None of the variants showed any destruction of the plasmalemma integrity, which was confirmed by staining with Evans blue. At a fall of the pressure to an atmospheric value, the frequency of structural disturbances of the tonoplast membrane was proportional to the pressure difference: minimum at a drop from 2 to 0 MPa and maximum at a drop from 4 to 0 MPa. Thus, it was concluded that the endomembranous system was among the targets of the pressure effect on the plant cells.     

Changes in tonoplast protein and density with the development of pear fruit

Protoplasts isolated from pear fruit at the end of the cell‐division stage, 30 days after flowering (DAF), had already formed a large central vacuole and the vacuole occupied most of the protoplast. The changes in protein composition and density of the tonoplast (vacuolar membrane) were investigated during fruit development. After a linear sucrose density gradient centrifugation, the distribution of tonoplasts at 30 and 48 DAF was broad and began to narrow with further fruit development. This suggests that the tonoplast of young fruit is heterogeneous and becomes homogeneous with fruit development. The apparent density of the tonoplast at 30 DAF was approximately 1.12 g ml⁻¹; it decreased with fruit development and was finally 1.09 g ml⁻¹ in mature fruit. The phospholipid amount on the basis of tonoplast protein was 0.80 mg mg⁻¹ at 30 DAF. It increased with fruit development, and finally reached 7.49 mg mg⁻¹. This result indicates that the decrease in the density of the tonoplast was caused by the increase in the ratio of phospholipid to membrane protein. The protein composition of the tonoplast at each stage was quite different. The level of polypeptides of 94, 70, 61, 52, 48 and 41 kDa was low in young fruit and high in the middle or later stages of fruit development. In contrast, the level of a 76‐kDa polypeptide was high in young fruit and decreased with fruit development. Although their functions are still unclear, these tonoplast proteins may play important roles in fruit development.     

Development of secretory cells and crystal cells in Eichhornia crassipes ramet shoot apex

The distribution and development of secretory cells and crystal cells in young shoot apexes of water hyacinth were investigated through morphological and cytological analysis. The density of secretory cells and crystal cells were high in parenchyma tissues around the vascular bundles of shoot apexes. Three developmental stages of the secretory cells can be distinguished under transmission electron microscopy. Firstly, a large number of electron-dense vesicles formed in the cytoplasm, then fused with the tonoplast and released into the vacuole in the form of electron-dense droplets. As these droplets fused together, a large mass of dark material completely filled the vacuole. To this end, a secretion storage vacuole (SSV) formed. Secondly, an active secretion stage accompanied with degradation of the large electron-dense masses through an ill-defined autophagic process at periphery and in the limited internal regions of the SSV. Finally, after most storage substances were withdrawn, the materials remaining in the spent SSV consisted of an electron-dense network structure. The distribution and development of crystal cells in shoot apical tissue of water hyacinth were also studied by light and electron microscopy. Crystals initially formed at one site in the vacuole, where tube-like membrane structures formed crystal chambers. The chamber enlarged as the crystal grew in bidirectional manner and formed needle-shaped raphides. Most of these crystals finally occurred as raphide bundles, and the others appeared as block-like rhombohedral crystals in the vacuole. These results suggest that the formation of both secretory cells and crystal cells are involved in the metamorphosis of vacuoles and a role for vacuoles in water hyacinth rapid growth and tolerance.     

Ultrastructural transitions associated with the development of the bladder cells of the trichomes of Atriplex

Early in development, bladder cells are characterized by the absence of a vacuole or vacuoles, the presence of autophagic vesicles, and numerous, unaggregated ribosomes. With the formation and expansion of the central vacuole, the ribosomes become aggregated and elements of rough endoplasmic reticulum become apparent. This developmental transition is probably related to the production of proteins involved in ion accumulation in the vacuole. Throughout expansion, invaginations of the tonoplast and membraneous structures are associated with the vacuole. These may be indicative of a continued lytic function for this compartment. Also, dictyosomes are continuously present and dictyosome vesicles are associated with both the plasmalemma and tonoplast, which suggest that they contribute to both membrane systems during expansion of the cell and vacuole.     

Ultrastructure of vacuolar inclusions in root tips

Summary Vacuoles in plant cells often contain inclusions which at early stages of development are bounded by a single membrane. The inclusion bodies (IBs) comprise a diversity of forms and various stages of differentiation are recognizable. IBs are divided into two categories: those which have a matrix without internal membranes, and those which contain cytoplasmic organelles and other membranous material. The internal membranes may be tightly coiled or in the form of vesicles. IBs develop from invaginations of the tonoplast which become detached into the vacuole. They are initiated mainly during active cell growth but may remain within the vacuole in differentiated cells. Various components contribute to the contents of IBs: endoplasmic reticulum, nuclear envelope, Golgi vesicles, extruded portions of mitochondria and plastids, ribosomes and groundplasm. In most IBs the limiting membrane and contents eventually disappear within the vacuole. Some IBs prior to their breakdown within the vacuole also function as sites for the formation of material not found elsewhere in the cell. The disappearance of IBs from vacuoles suggests that such vacuoles behave as lysosomes.     

Immunocytological localization of two enzymes involved in berberine biosynthesis

Using post-embedding immunogold techniques the cytological localization of the two branchpoint enzymes of isoquinoline biosynthesis, berberine bridge enzyme (BBE) and (S)-tetrahydroprotoberberine oxidase (STOX), was demonstrated. Electron-microscopic examination revealed their exclusive compartmentation within vesicles. After these vesicles have fused with the central vacuole, they release their contents, resulting in a characteristic electron-dense precipitate at the tonoplast. Vesicles of similar structure could be identified in young meristematic tissues of roots or shoots from different Berberis species and Papaver somniferum L. The appearance of electron-dense osmiophilic material is strictly correlated with the alkaloid content of the tissue. Immunocytological staining of P. somniferum tissue with antibodies directed against BBE led to a characteristic labeling of electron-dense aggregates in idioblasts that are not connected to the laticifer system. This localization demonstrates the strictly cytological separation of benzophenanthridine and morphine biosyntheses within this plant.     

Differential Translocation of Host Cellular Materials into the Chlamydia trachomatis Inclusion Lumen during Chemical Fixation

Chlamydia trachomatis manipulates host cellular pathways to ensure its proliferation and survival. Translocation of host materials into the pathogenic vacuole (termed ‘inclusion’) may facilitate nutrient acquisition and various organelles have been observed within the inclusion, including lipid droplets, peroxisomes, multivesicular body components, and membranes of the endoplasmic reticulum (ER). However, few of these processes have been documented in living cells. Here, we survey the localization of a broad panel of subcellular elements and find ER, mitochondria, and inclusion membranes within the inclusion lumen of fixed cells. However, we see little evidence of intraluminal localization of these organelles in live inclusions. Using time-lapse video microscopy we document ER marker translocation into the inclusion lumen during chemical fixation. These intra-inclusion ER elements resist a variety of post-fixation manipulations and are detectable via immunofluorescence microscopy. We speculate that the localization of a subset of organelles may be exaggerated during fixation. Finally, we find similar structures within the pathogenic vacuole of Coxiella burnetti infected cells, suggesting that fixation-induced translocation of cellular materials may occur into the vacuole of a range of intracellular pathogens.     

箭舌豌豆根瘤细胞液泡中一种特殊内含物的研究

用透射电镜观察了箭舌豌豆根瘤侵染细胞。结果表明,有一些小泡出现在细胞质膜和侵入线附近,它们不断向中央液泡运动,并在运动中相互靠近形成小泡团。当其到达中央液泡时,附近的液泡膜产生内吞,形成突起。最后,这些突起脱离液泡膜,在中央液泡中形成一种由管状结构和小泡组成、表面具有一层被膜的特殊内含物。本文还讨论了此种内含物的起源及其与根瘤抗旱和细菌周膜扩增的关系。     

甜菊愈伤组织细胞中的液泡膜内突和液泡内囊泡

对生长在分化培养基上的甜菊愈伤组织分生区细胞的液泡膜内突和液泡内囊泡,进行了超微结构和酸性磷酸酶细胞化学研究。在不同液泡化时期的细胞中,都存在不同大小和形态的液泡膜内突,它们有的缺乏明显的内含物;有的含有许多小泡或复杂膜系;有的含有一个较大的具许多小泡或复杂膜系的膜束缚囊泡。在液泡内还存在一些游离的液泡内囊泡,它们通常具有两层紧贴的界膜或为多层同心膜,推测它们来自液泡膜内突。ＡｃＰａｓｅ定位结果显     

葡萄果实发育过程中果肉细胞超微结构的观察

用透射电镜观察了“巨峰”葡萄(Vitis vinifera×V.labrusca)果实3个发育时期中果肉细胞超微结构的变化。果实第一次快速生长期的果肉细胞超微结构表现出物质和能量代谢旺盛的特点。缓慢生长期的果实虽外部形态平静少变,但果肉细胞超微结构表现出深刻的变化:细胞核形状特化为裂瓣状是最显著的特点;线粒体数目丰富;粗面内质网槽库膨大形成的囊泡富集,出现向液泡汇融和向质膜靠近的现象;质膜内陷;液泡膜完整。另外,原生质也出现一些降解的现象。但总体结构特点表明果肉细胞在此期处于十分活跃的物质周转代谢和信息交换过程中。果实第二次快速生长期果肉细胞超微结构表现出衰老降解的特点,但线粒体结构依然完整,数量仍然丰富,原生质膜也保持了很好的完整性,这似乎与维持第二次快速生长或成熟有关。     

Architectural remodeling of the tonoplast during fluid-phase endocytosis

During fluid phase endocytosis (FPE) in plant storage cells, the vacuole receives a considerable amount of membrane and fluid contents. If allowed to accumulate over a period of time, the enlarging tonoplast and increase in fluids would invariably disrupt the structural equilibrium of the mature cells. Therefore, a membrane retrieval process must exist that will guarantee membrane homeostasis in light of tonoplast expansion by membrane addition during FPE. We examined the morphological changes to the vacuolar structure during endocytosis in red beet hypocotyl tissue using scanning laser confocal microscopy and immunohistochemistry. The heavily pigmented storage vacuole allowed us to visualize all architectural transformations during treatment. When red beet tissue was incubated in 200 mM sucrose, a portion of the sucrose accumulated entered the cell by means of FPE. The accumulation process was accompanied by the development of vacuole-derived vesicles which transiently counterbalanced the addition of surplus endocytic membrane during rapid rates of endocytosis. Topographic fluorescent confocal micrographs showed an ensuing reduction in the size of the vacuole-derived vesicles and further suggest their reincorporation into the vacuole to maintain vacuolar unity and solute concentration.     

Structure, Cytochemistry, and Locomotion of Haemogregarina sp. from Rana berlandieri

Intra- and extracellular gametocytes of Haemogregarina sp. from Rana berlandieri were studied by light and electron microscopy. Locomotion in free gametocytes appears to be related to series of horizontal “peristaltic” waves of constriction, passing from anterior to posterior along the body. Intracellular gametocytes lie within a vacuole in the erythrocyte cytoplasm. The pellicle of the parasite consists of a trilaminar plasmalemma and an inner electron dense layer, beneath which lies a ring of 80 microtubules. The inner dense layer becomes thickened and modified in the apical region, to form a cap-like structure. The gametocytes contain a prominent nucleus, several mitochondria, and many granular inclusions. One type of inclusion consists of elliptical, electron-dense, profeinaceous bodies scattered throughout the cytoplasm, while other inclusions are larger and electron-opaque, polysaccharide in nature, and occur predominantly in the pre- and post-nuclear regions. In the electron microscope, pronounced pellicular folds were observed in longitudinally sectioned extracellular gametocytes. These folds are thought to represent the waves of constriction seen in motile specimens by light microscopy. The mechanism of movement of the parasite is discussed and compared with that in haemosporidian ookinetes, as well as in gregarines.     

Life with and without AtTIP1;1, an Arabidopsis aquaporin preferentially localized in the apposing tonoplasts of adjacent vacuoles

The Arabidopsis thaliana Tonoplast Intrinsic Protein 1;1 (AtTIP1;1) is a member of the tonoplast aquaporin family. The tissue-specific expression pattern and intracellular localization of AtTIP1;1 were characterized using GUS and GFP fusion genes. Results indicate that AtTIP1;1 is expressed in almost all cell types with the notable exception of meristematic cells. The highest level of AtTIP1;1 expression was detected in vessel-flanking cells in vascular bundles. AtTIP1;1-GFP fusion protein labelled the tonoplast of the central vacuole and other smaller peripheral vacuoles. The fusion protein was not found evenly distributed along the tonoplast continuum but concentrated in contact zones of tonoplasts from adjacent vacuoles and in invaginations of the central vacuole. Such invaginations may result from partially engulfed small vacuoles. A knockout mutant was isolated and characterized to gain insight into AtTIP1;1 function. No phenotypic alteration was found under optimal growth conditions indicating that AtTIP1;1 function is not essential to the plant and that some members of the TIP family may act redundantly to facilitate water flow across the tonoplast. However, a conditional root phenotype was observed when mutant plants were grown on a glycerol-containing medium.     

Ultrastructural changes associated with the accumulation and secretion of sanguinarine in Papaver bracteatum suspension cultures treated with fungal elicitor

Suspension cultures of Papaver bracteatum Arya II Lindl., grown without hormone in the presence of conidial extracts of Verticillium dahliae Kleb., accumulate millimolar quantities of the benzophenanthridine alkaloid, sanguinarine. Under the fluorescence microscope, the elicitor-treated cells display an orange-yellow fluorescence characteristic of sanguinarine, primarily near the periphery of the cells. Electron-microscopic inspection showed the presence of slightly dilated endoplasmic reticulum and of electron-dense protuberances on the tonoplast of large central vacuoles. These osmiophilic aggregates lining the tonoplast bud into spherical bodies, appear to become detached from the membrane and are released into the vacuole. Upon subcellular fractionation of elicited cells on Renografin step gradients, sanguinarine was found to be distributed in all bands but with 86% concentrated in the gradient pellet. Analysis of the pellet by electron microscopy showed that it contained electron-dense fragments similar to the osmiophilic bodies observed on the tonoplast of intact elicited cells. In elicited cell cultures, most of the sanguinarine was recovered from medium in a 100·g sedimenting, cell-free, particulate fraction accounting for as much as 85% of the media sanguinarine and 62% of the total sanguinarine. The sanguinarine-rich 100·g media pellet was determined to be two-thirds protein, one-third RNA and was essentially devoid of phenolics, phospholipid and DNA. The pellet consisted of electrondense material and cytoplasmic remnants resembling those found in the Renografin pellet and tonoplast aggregates of intact cells. When placed under hypotonic conditions or extracted with aqueous buffer, pH 3–11, the pellet did not release sanguinarine. These observations provide evidence for storage of sanguinarine at electron-dense deposits which occur on the tonoplast and as freely floating bodies in vacuoles.Abbreviations BA N⁶-benzyladenine - 2,4-D 2,4-dichlorophenoxyacetic acid - EM electron microscopy - ER endoplasmic reticulum - HPLC high-pressure liquid chromatography - MRST Murashige and Skoog's revised tobacco medium     

Effects of Water Stress on the Ultrastructure of Leaf Cells of Sorghum bicolor

The subcellular changes which occurred in sorghum leaves during increasing water stress and subsequent rewatering are described. Stomata were closed, abscisic acid levels were elevated, and the amounts of starch in the bundle sheath chloroplasts were much reduced by - 14 bars leaf water potential. Swelling of the outer chloroplast membrane, and reorganization of the tonoplast to form small vesicles from the large central vacuole, occurred by a leaf water potential of - 37 bars. Complete structural disruption of the tonoplast, as previously described for maize was not found. On rewatering, large amounts of starch reappeared within three hours. These findings strengthen the hypothesis that maintenance of tonoplast integrity is an important factor in the ability of plants to withstand drought.