狭基巢蕨叶表皮的结构和气孔器发育的观察

狭基巢蕨Ｎｅｏｔｏｐｔｅｒｉｓａｎｔｒｏｐｈｙｏｉｄｅｓ（Ｃｈｒｉｓｔ）Ｃｈｉｎｇ叶片的上表皮无气孔器,仅具表皮细胞,下表皮由表皮细胞和气孔器组成,气孔指数为２．５。上下表皮细胞和气孔器的细胞中均含有叶绿体。每个气孔器由２个肾形的保卫细胞和２～６个副卫细胞组成,其中以３个和４个副卫细胞的占绝大多数（３细胞的占４５．１％,４细胞的占４３．５％）。从发育上看,气孔器原始细胞进行２次分裂,产生２个保卫细胞和１个同源的副卫细胞。气孔器的发育过程大体可分为４个时期：（１）气孔器原始细胞的分化和分裂期;（２）保卫细胞母细胞成熟期;（３）保卫细胞母细胞分裂和气孔器幼期;（４）气孔器成熟期。狭基巢蕨的气孔器属于中周型     

Actin filament-organized local cortical endoplasmic reticulum aggregations in developing stomatal complexes of grasses

Endoplasmic reticulum (ER) immunolabeling in developing stomatal complexes and in the intervening cells of the stomatal rows (ICSRs) of Zea mays revealed that the cortical-ER forms distinct aggregations lining locally expanding wall regions. The polarized subsidiary cell mother cells (SMCs), displayed a cortical-ER-patch lining the wall region shared with the inducing guard cell mother cell (GMC), which disorganized during mitosis. In dividing SMCs, ER persisted in the preprophase band region and was unequally distributed in the mitotic spindle poles. The subsidiary cells (SCs) formed initially an ER-patch lining the common wall with the GMC or the young guard cells and afterwards an ER-ring in the junction of the SC wall with the neighboring ones. Distinct ER aggregations lined the ICSR wall regions shared with the SCs. The cortical-ER aggregations in stomatal cells of Z. mays were co-localized with actin filament (AF) arrays but both were absent from the respective cells of Triticum turgidum, which follow a different morphogenetic pattern. Experimental evidence showed that the interphase ER aggregations are organized by the respective AF arrays, while the mitotic ER aggregations by microtubules. These results revealed that AF and ER demarcated “cortical cytoplasmic domains” are activated below the locally expanding stomatal cell wall regions, probably via a mechanosensing mechanism triggered by the locally stressed plasmalemma/cell wall continuum. The probable role(s) of the local ER aggregations are discussed.     

Action of growth regulators on the cotyledonary stomata ofCucumis sativus L.: Structure and ontogeny

Anomocytic stomata and stomata with single subsidiary cells are commonly observed Sometimes a stoma appears anisocytic. Double cytoplasmic connections between nearby stomata and division of guard cells with persistent or degenerating nuclei are seen in GA. One or more divisions of guard cells, displaced guard cells and single guard cells with or without pore are noticed in SUC. Formation of single guard cells is a common feature in TIBA. Paracytic stomata, one and a half stomata and persistent stomatal initials are seen in SUL. COUM seems to be not inhibitory inCucumis sativus. In COL stomata with unequal guard cells, unequal stomatal cells with thickening in between but without intervening pore, stoma with double pores, persistent stomatal initials which may be solitary or in groups with varying shapes and with one or two nuclei of different shapes are noticed. The growth regulators affect the frequency of stomata, epidermal cells; stomatal index; size of guard and epidermal cells.     

Epidermal studies in some Indian cultivars of Bougainvilleas

Epidermal studies in fifteen Indian cultivars of Bougainvilleas are described. The epidermal cells are polygonal isodiametric, or elongated with thick straight arched or slightly sinuous walls. Parallel culticular striations are radiating from guard cells. The mature stomata are anomocytic, paracytic and with a single subsidiary cell. The abnormal types noticed are: single guard cells with or without pores, arrested development, variously oriented contiguous stomata, cytoplasmic connections between nearby stomata and epidermal or subsidiary cells, and persistent stomatal cells. The development of anomocytic stomata is perigenous while that of the other types is mesogenous. Fifteen cultivars of Bougainvilleas are separated on the basis of bract colour, stomatal frequency and index per unit area.     

THE ULTRASTRUCTURAL CYTOLOGY OF THE DIFFERENTIATING GUARD CELLS OF VIGNA SINENSIS

Structural differentiation of the guard cells of Vigna sinensis results from the integration of the following interrelated processes: a) intense activity of ribosomes, dictyosomes, endoplasmic reticulum (ER) membranes and mitochondria and patterned organization of microtubules; b) unequal thickening and ordered micellation of their walls and opening of the stomatal pore; and c) the divergent differentiation of the plastids. In differentiating guard cells, microtubules appear anticlinally oriented and more or less evenly distributed along the unthickened part of the dorsal wall and in the middle part of the ventral wall where thickening of the future pore occurs. In periclinal walls, microtubules fan away from the margins of the increasing thickening of the ventral wall and, later, from the rims of the stomatal pore towards the dorsal walls, parallel to the depositing radial microfibrils. Microtubules may be the cytoplasmic elements underlying guard-cell morphogenesis. Although cell-plate organization in guard-cell mother cells does not seem to differ from that of other protodermal cells, the middle lamella of the ventral wall becomes electron-translucent. The stomatal pore develops schizogenously from the internal and/or external ends of the ventral wall and proceeds inwards, remaining incomplete in most of the stomata of plants grown for 30 days in darkness and in some malformed ones which were developed after a prolonged action of colchicine. The guard cell, when approaching maturity, loses its organelle complexity and plasmodesmata, but it keeps a significant portion of its cytoplasm and organelles. Perigenous stomata generally exceed the size of mesoperigenous and mesogenous ones, develop large vacuoles and appear able to induce oriented divisions in their vicinity.     

The function of guard cells does not require an intact array of cortical microtubules

The development of stomatal guard cells is known to require cortical microtubules; however, it is not known if microtubules are also required by mature guard cells for stomatal function. To study the role of microtubules in guard cell function, epidermal peels of Vicia faba were subjected to conditions known to open or close stomata in the presence or absence of microtubule inhibitors. To verify the action of the inhibitors, microtubules in appropriately treated epidermal peels were localized by cryofixation followed by freeze substitution and embedding in butyl-methyl methacrylate. Mature guard cells had a radial array of microtubules, focused toward the thick cell wall of the pore, and the appearance of this array was the same for stomata remaining closed in darkness or induced to open by light. Treatment of epidermal peels with 1 mM colchicine for 1 h depolymerized nearly all cortical microtubules. Measurements of stomatal aperture showed that neither 1 mM colchicine nor 20 M taxol affected any of the responses tested: remaining closed in the dark, opening in response to light or fusicoccin, and closing in response to calcium and darkness. We conclude that intact microtubule arrays are not invariably required for guard cell function.     

Structure of the stomatal complex of the monocot Flagellaria indica

The structure of the mature stomatal complex of Flagellaria indica L. was studied since the Flagellariaceae is reported to be one of a handful of nongrass families with a grass-type stoma, and since relatively little is known about stomatal ultrastructure in monocots other than grasses. Both the grass guard cell and its nucleus are dumbbell-shaped, and the walls that separate adjacent grass guard cells are perforated. Electron and fluorescence microscopy reveal that the Flagellaria guard cell lacks these features. Instead, the Flagellaria guard cell is neither dumbbellnor kidney-shaped, its nucleus is roughly kidney-shaped, and the end walls are thickened and imperforate. Additional structural features of the stomatal apparatus of Flagellaria include: 1) the subsidiary cells have a protuberance that underlies the middle of the guard cell and that forms an additional and innermost aperture of the pore; 2) guard and subsidiary cell walls are thickened differentially and are layered; and 3) organelles in both cell types appear to be confined to specific domains. Although Flagellaria is closely related to grasses, it does not have a grass or dumbbell-shaped type of stomate. This suggests that the grass type of stomate may be less widespread than reported.     

DEVELOPMENT OF STOMATA IN SELAGINELLA: DIVISION POLARITY AND PLASTID MOVEMENTS

The young guard cell of Selaginella inherits a single plastid from the division of the stomatal guard mother cell (GMC). During early stomatal development the single plastid undergoes a complex series of migrations and divisions. The regular pattern of plastid behavior appears to be an expression of the genetic program controlling division plane and cytomorphogenesis. The plastid in the GMC becomes precisely aligned with its midconstriction intersected by the plane of a preprophase band of microtubules (PPB) oriented parallel to the long axis of the leaf. This alignment with respect to the future division plane of the cytoplasm ensures equal plastid distribution to the daughter cells. Cytokinesis occurs in the plane previously marked by the PPB and the plastid in each daughter cell lies between the lateral wall and the newly formed nucleus. Following cytokinesis the plastid in each young guard cell develops a median constriction and migrates to the common ventral wall where the isthmus is associated with a system of microtubules in the vicinity of the developing pore region. Plastid division is completed while the plastid is adjacent to the common ventral wall. Following division, the two daughter plastids move back toward the lateral wall. Each plastid may divide again during guard cell maturation but no further migrations occur.     

Microtubules and possible microtubule nucleation centers in the cortex of stomatal cells as visualized by high voltage electron microscopy

Summary Thick sections of fixed, embedded stomatal cells ofPhleum pratense were examined using high voltage electron microscopy and stereological procedures. The cortex of guard cells and subsidiary cells throughout differentiation contains numerous microtubules adjacent to the plasmalemma. Although microtubules are usually aligned in one net direction, individual microtubules may diverge from this orientation in various ways, producing anastomosing or crossed arrays. Also present in the cortex of both guard and subsidiary cells are collections of membranous elements and amorphous material upon which microtubules seem to focus, terminate or overlap. Such structures may constitute microtubule nucleation centers. The significance of these observations is discussed in terms of the control of microtubule development, wall microfibril deposition and cell morphogenesis.     

Three-Dimensional Reconstruction of the Stomatal Complex in Pinus canariensis Needles Using Serial Sections

Abstract: The three-dimensional (3D) morphology of the stomata in leaves of Pinus canariensis is described with respect to the spatial arrangement of guard cells, subsidiary cells, polar and lateral cells. Serial semi-thin sections of the stomatal apparatus were digitally reconstructed and analysed with regard to the position, shape and size of the cell types involved. The stomatal complex consists of 16 cells with uniquely shaped polar and lateral cells. The polar cells form a kind of roof above the epistomatal chamber thereby reducing the surface aperture. The structural features of the stomatal complex differ from other Pinus species and are presumed to be an adaptation to extreme environmental conditions.     

合意非洲铁羽片表皮及气孔器的发育研究

用光学显微镜和扫描电镜对合意非洲铁羽片表皮及气孔器的发育过程进行观察研究。结果显示,(1)在羽片发育过程中表皮细胞变化不明显,主要是细胞伸长和壁增厚的过程;表皮的角质层连续出现。(2)气孔器发育可大致分3个阶段:保卫细胞母细胞阶段、幼保卫细胞阶段和成熟保卫细胞阶段;气孔器发育方式为单唇型或周源型;成熟气孔器属单环型。(3)在羽片发育过程中,气孔密度起初很低,后急剧升高并达到峰值,之后逐渐下降并趋于稳定。(4)有早熟气孔器。(5)羽片表皮发育成熟的方式是由基部向顶部逐步推进。     

In vivo single-particle tracking of the aquaporin AtPIP2;1 in stomata reveals cell type-specific dynamics

Aquaporins such as the plasma membrane intrinsic proteins (PIPs) allow water to move through cell membranes and are vital for stomatal movement in plants. Despite their importance, the dynamic changes in aquaporins during water efflux and influx have not been directly observed in real time in vivo. Here, to determine which factors regulate these changes during the bidirectional translocation of water, we examined aquaporin dynamics during the stomatal immune response to the bacterial flagellin-derived peptide flg22. The Arabidopsis (Arabidopsis thaliana) aquaporin mutant pip2;1 showed defects in the flg22-induced stomatal response. Variable-angle total internal reflection fluorescence microscopy revealed that the movement dynamics and dwell times of AQ6]GFP-AtPIP2;1 in guard cells and subsidiary cells exhibited cell type-specific dependencies on flg22. The cytoskeleton, rather than the cell wall, was the major factor regulating AtPIP2;1 dynamics, although both the cytoskeleton and cell wall might form bounded domains that restrict the diffusion of AtPIP2;1 in guard cells and subsidiary cells. Finally, our analysis revealed the different roles of cortical actin and microtubules in regulating AtPIP2;1 dynamics in guard cells, as well as subsidiary cells, under various conditions. Our observations shed light on the heterogeneous mechanisms that regulate membrane protein dynamics in plants in response to pathogens.     

Water Supply, Evaporation, and Vapour Diffusion in Leaves

On the basis of experimental results published during the last25 years, but more particularly during the last 5 years andincluding some results presented here, the hypothesis is proposedthat an important portion of the water supply from major veinsin leaves travels within the epidermal tissue to sites of evaporationclose to the stomatal pores. These evaporation sites are innerepidermal walls especially subsidiary and guard cell walls becausethese are closest to air spaces with the highest water vapourdeficits. Less water than is traditionally supposed evaporatesfrom mesophyll cell walls. Low osmotic potentials of guard cells(large negative) are not required in building up high turgorpressures. However, they are required in competing for wateragainst the process of evaporation which causes low matric potentialsto develop in subsidiary and guard cell walls so that guardcolls can maintain the comparatively low turgor pressures whichhave been shown to operate the stomatal apparatus. Traditionalviews about leaf water relations and methods of estimating mesophyllresistances for carbon dioxide diffusion into leaves must bemodified.     

玉米叶片气孔及花环和维管束结构对水分胁迫的响应

采用盆栽种植,以玉米品种郑单958为试验材料,设置对照（CK）、轻度（LS）、中度（MS）和重度（SS）水分胁迫 (土壤含水量分别为田间持水量的75%～85%、65%～75%、55%～65%、45%～55%)4个水分梯度,从气孔开度的调控、花环结构的变化、叶片维管束水分运输等方面研究了玉米对土壤水分胁迫的应激反应.结果表明：随着水分胁迫程度的不断加剧,气孔保卫和副卫细胞中过氧化氢(H₂O₂)的积累量逐渐增多,应用荧光染色定位也发现H₂O₂荧光强度逐渐增强,而气孔开度和气孔导度均逐渐减小.同时,花环的正常结构被破坏,花环细胞排列凌乱且体积逐渐变小,维管束鞘细胞变得不规则;大维管束断面面积、木质部面积以及韧皮部细胞数均减少,总的叶片和上、下表皮的厚度逐渐变薄.此外,花环细胞和维管束鞘细胞中叶绿体数目减少,且在中度胁迫下花环细胞中叶绿体的分布发生了变化,由紧贴细胞质膜内侧环靠细胞壁分布向偏细胞中心扩散.发现玉米气孔关闭可能是由保卫细胞和副卫细胞中的H₂O₂共同调节,副卫细胞中的H₂O₂对保卫细胞主导的气孔关闭具有协同作用.总之,在水分胁迫下,玉米通过改变叶片花环结构和厚度、叶绿体的分布,减小木质部和韧皮部面积等降低叶片表面水势,促进气孔关闭,减少体内水分散失,以减轻干旱胁迫对其伤害.     

植物微管结合蛋白AtMAP65-1在拟南芥气孔保卫细胞中的定位(简报)

植物细胞微管骨架的不同排列方式对细胞的生长分化及形态建成具有重要意义,微管的这种动态组织行为不仅需要自身的组成蛋白-微管蛋白(tubulin),还要有微管辅助蛋白MAPs(Microtubule-associated proteins)的参与[1,2]。即MAPs是一类能够与微管骨架特异结合并调节其动态装配过程及其结构、进而影响微管功能的蛋白大分子。其中,MAP65是最先在烟草悬浮细胞BY-2中纯化出来的、分子量约为65KDa的一个微管结合蛋白家族。     

F-actin redistributions at the division site in livingTradescantia stomatal complexes as revealed by microinjection of rhodamine-phalloidin

Summary Microinjection of rhodamine-phalloidin into living cells of isolatedTradescantia leaf epidermis and visualisation by confocal microscopy has extended previous results on the distribution of actin in mitotic cells of higher plants and revealed new aspects of actin arrays in stomatal cells and their initials. Divisions in the stomatal guard mother cells and unspecialised epidermal cells are symmetrical. Asymmetrical divisions occur in guard mother precursor cells and subsidiary mother cells. Each asymmetrical division is preceded by migration of the nucleus and the subsequent accumulation of thick bundles of anticlinally oriented actin filaments localised to the area of the anticlinal wall closest to the polarised nucleus. During prophase, in all cell types, a subset of cortical actin filaments coaligns to form a band, which, like the preprophase band of microtubules, accurately delineates the site of insertion of the future cell wall. Following the breakdown of the nuclear envelope, F-actin in these bands disassembles but persists elsewhere in the cell cortex. Thus, cortical F-actin marks the division site throughout mitosis, firstly as an appropriately positioned band and then by its localised depletion from the same region of the cell cortex. This sequence has been detected in all classes of division inTradescantia leaf epidermis, irrespective of whether the division is asymmetrical or symmetrical, or whether the cell is vacuolate or densely cytoplasmic. Taken together with earlier observations on stamen hair cells and root tip cells it may therefore be a general cytoskeletal feature of division in cells of higher plants.Abbreviations GMC guard mother cell - MT microtubule - PPB preprophase band - Rh rhodamine - SMC subsidiary mother cell     

Cuticle micromorphology of leaves of Pinus (Pinaceae) from Mexico and Central America

Cuticle micromorphology of 34 taxa of Pinus from Mexico and Central America was studied with scanning electron microscopy, and leaf morphology was described. In total, 29 characters, 22 from the inner cuticular surfaces and seven from the outer, were described in detail. These characters have value either for testing infragenerie classifications or for identifying individual taxa. Characters relating to the periclinal wall texture of the epidermal cells, the shape and degree of development of the anticlinal walls of the epidermal cells, the basal and apical shapes of anticlinal epidermal cell walls, the continuity of the epidermal cells, the size ratio of the polar to lateral subsidiary cells, the grooves on subsidiary cells, the cuticular flanges between guard and subsidiary cells, the groove near the bristles and the elevation of the Florin ring ridge and striations on the Florin ring are particularly useful for infrageneric classification. The agreement between these characters and infrageneric classifications is discussed. Characters relating to the end wall shapes of the epidermal cells, the relative length of epidermal cells, the shape of the stomatal apparatus, the texture of guard and lateral subsidiary cell surfaces, the polar extensions, the number of subsidiary cells and epidermal cell layers between stomatal rows, the integrity of stomatal rows, cell numbers between stomata in a row, cuticular flanges between guard cells, bristle flanges and surface textures, epicuticular waxes, striations on Florin rings and stomatal shapes, contain some important information for identifying Mexican pines. The distribution of the states of each character is compared with that of the Asian pines. Cuticular characters are used to help determine the affinities of taxonomically difficult taxa.     

Microtubule organization during development of stomatal complexes inLolium rigidum

Summary Microtubule (MT) arrays in stomatal complexes ofLolium have been studied using cryosectioning and immunofluorescence microscopy. This in situ analysis reveals that the arrangement of MTs in pairs of guard cells (GCs) or subsidiary cells (SCs) within a complex is very similar, indicating that MT deployment is closely coordinated during development. In premitotic guard mother cells (GMCs), MTs of the transverse interphase MT band (IMB) are reorganized into a longitudinal array via a transitory array in which the MTs appear to radiate from the cell edges towards the centre of the walls. Following the longitudinal division of GMCs, cortical MTs are reinstated in the GCs at the edge of the periclinal and ventral walls. The MTs become organized into arrays which radiate across the periclinal walls, initially from along the length of the ventral wall and later only from the pore site. As the GCs elongate, the organization of MTs and the patterns of wall expansion differ on the internal and external periclinal walls. A final reorientation of MTs from transverse to longitudinal is associated with the elongation and constriction of GCs to produce mature complexes. During cytokinesis in the subsidiary mother cells (SMCs), MTs appear around the reforming nucleus in the daughter epidermal cells but appear in the cortex of the SC once division is complete. Our results are thus consistent with the idea that interphase MTs are nucleated in the cell cortex in all cells of the stomatal complex but not in adjacent epidermal cells.Abbreviations GMC guard mother cell - GC guard cell - IMB interphase microtubule band - MT microtubule - PPB preprophase band - SMC subsidiary mother cell - SC subsidiary cell     

中国五味子属植物叶表皮研究

用浓硫酸－铬酸离析法,在光学显微镜下观察了中国五味子属植物１４种,１亚种,２变种,共２４个样品成熟叶的叶表皮细胞及气孔器特征,结果表明：五味子属植物叶片的上、下表皮细胞呈多边形或不规则形,垂周壁式样为平直,菜或浅汉浪;少数种类上表皮有气孔器或分泌细胞,所有的种类下表皮具气孔器和分泌细胞;气孔器类型以平列型为主,并伴有侧列型,极少数出现不规则型,气孔极区呈稍角质和厚或棒形角质加厚,稀Ｔ形角质加厚,叶