3种龙葵表皮毛类型及发育过程观察研究

通过观察发现龙葵（Ｓｏｌａｎｕｍ ｎｉｇｒｕｍ Ｌ．）、少花龙葵（Ｓ．ｐｈｏｔｅｉｎｏｃａｒｐｕｍ Ｎａｋａｍ,ｅｔＯ－ｄｓｈｉ）和黄果龙葵（Ｓ．ｎｉｇｕｍ Ｌ．ｖａｒ．ｓｕａｖｅｏｌｅｎｓ Ｇ．Ｌ．Ｇｕｏ）的表皮毛均为腺毛,主要有单细胞头腺毛和多细胞头腺毛２种。腺毛的原始细胞都来源于原表皮细胞,经２次平周分裂产生基细胞、柄细胞和顶端细胞、在腺毛后期的形态发生中,柄细胞和顶细胞的分裂状态决定腺毛的     

The Relationship Between the Distribution of Periclinal Cell Divisions in the Shoot Apex and Leaf Initiation

Periclinal cell divisions in vegetative shoot apices of Pisumand Silene were recorded from serial thin sections by mappingall the periclinal cell walls formed less than one cell cyclepreviously. The distribution of periclinal divisions in theapical domes corresponded to the distributions subsequentlyoccurring in the apices when the young leaf primordia were forming.In Pisum, periclinal divisions were almost entirely absent fromthe I₁ region of the apical dome for half a plastochron justafter the formation of a leaf primordium and appeared, simultaneouslyover the whole of the next potential leaf site, about half aplastochron before the primordium formed. In Silene periclinaldivisions seemed to always present in the apical dome at thepotential leaf sites and also round the sides of the dome wherethe ensheathing leaf bases were to form. Periclinal divisionstherefore anticipated the formation of leaf primordia by occuring,in Pisum about one cell cycle and in Silene two or more cellcycles, before the change in the direction of growth or deformationof the surface associated with primordial initiation. Pisum, Silene, planes of cell division, orientation of cell walls, leaf primordia, shoot apical meristem, plastochron     

A developmental study of the epidermis of young roots ofZea mays L.

Summary In the apical meristems of main and young lateral roots of corn the uniseriate epidermis is clearly continuous with the most distal cell tier of the quiescent centre. These cells are characterized by the presence on their outer periclinal walls of material which forms the thin root cap junction layer over the apical pole and which thickens appreciably over the flanks of the meristem to form a distinctive extracellular deposit on the young epidermal cells. This material is polysaccharide in nature as indicated by strong periodic acid Schiff's positivity but its autofluorescence also suggests the presence of phenolic compounds.During their development the epidermal cells undergo marked shape change from periclinally flattened, polygonal at the root pole, through columnar on the meristem flank to tabular in the root hair zone. The mucigel thins markedly as cells become tabular but initiation of a root hair is characterized by deposition of polysaccharide on the inside of the periclinal wall where the hair will develop.     

Development of trichomes in the Abutilon nectary gland

Nectary trichomes of Abutilon striatum var. thompsonii arise by sequential periclinal divisions of outpushings from epidermal cells so producing trichomes that, when mature, are about 12 cells long. All epidermal cells within the nectary undergo this transformation. Later, anticlinal divisions lead to a multiseriate lower part of the trichome. The original epidermal cell becomes the basal cell which increases substantially in volume during development, thus leading to lateral separation of the trichomes. Above the basal cell is the stalk cell which develops an apoplastic barrier in its anticlinal (outer) wall. Secretion ultimately takes place from a capitate tip cell. An initially very thin cuticular layer, which overlies the whole trichome, eventually becomes as thick as the cell wall itself (approx. 0.4 μm). The pre-secretory hairs contain numerous small, condensed mitochondria; poorly differentiated plastids; dictyosomes with coated vesicles; small vacuoles; and a large amount of smooth endoplasmic reticulum ("secretory reticulum") which contrasts with the rough endoplasmic reticulum seen during earlier developmental stages. As secretion proceeds, vacuolation becomes more extensive. Plasmodesmata are present between all the cells of the trichome and diminish in frequency from about 12.0 μm^-2 in the stalk cell to about 4.0 μm^-2 in the apical cells. This variation in plasmodesmatal frequency along the trichome is seen at all stages of development. The ultrastructural evidence would be consistent with the hypothesis that the pre-nectar flows through the plasmodesmata from cell to cell, is loaded into a "secretory compartment", and is then unloaded into the apoplast from all cells of the trichome distal to the stalk 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.     

Development of the endosperm in rice (Oryza sativa L.): Cellularization

The syncytial endosperm of rice undergoes cellularization according to a regular morphogenetic plan. At 3 days after pollination (dap) mitosis in the peripheral synctium ceases. Radial systems of microtubules emanating from interphase nuclei define nuclear-cytoplasmic domains (NCDs) which develop axes perpendicular, to the embryo sac wall. Free-growing anticlinal walls between adjacent NCDs compart-mentalize the cytoplasm into open-ended alveoli which are overtopped by syncytial cytoplasm adjacent to the central vacuole. At 4 dap, mitosis resumes as a wave originating adjacent to the vascular bundle. The spindles are oriented parallel to the alveolar walls and cell plates formed in association with interzonal phragmoplasts result in periclinal walls that cut off a peripheral layer of cells and an inner layer of alveoli displaced toward the center. Polarized growth of the newly formed alveoli and elongation of the anticlinal walls occurs during interphase. The next wave of cell division in the alveoli proceeds as the first and a second cylinder of cells is cut off inside the peripheral layer. The periods of polarized growth/anticlinal wall elongation alternating with periclinal cell division are repeated 3–4 times until the grain is filled by 5 dap.     

MITOTIC ACTIVITY IN THE ROOT APICAL MERISTEM OF AZOLLA FILICULOIDES LAM., WITH SPECIAL REFERENCE TO THE APICAL CELL

The meristematic activity of the apical cell and its derivatives (merophytes) in the unbranched, determinate roots of Azolla filiculoides Lam. was investigated. The plane of division of the apical cell indicates that it is the initial of each merophyte. The division plane of each newly formed merophyte is strictly periclinal to the root surface and provides confirmation that the immediate derivatives of the apical cell cannot be the ultimate root initials. The frequency of cell division as determined by the mitotic index, and by the duration of the cell cycle as determined by the colchicine method, confirmed the meristematic activity of the apical cell. As roots increase in length, the duration of the cell cycle in the total meristem increases, with the apical cell possessing the longest cell cycle, whereas the immediate derivatives maintain approximately the same cycle duration as in shorter roots. In determinate Azolla roots, cell division appears to play a major role up to a certain root length, then increase in length is produced mainly by cell elongation.     

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     

Abnormal cell divisions in leaf primordia caused by the expression of the rice homeobox geneOSH1 lead to altered morphology of leaves in transgenic tobacco

Transgenic tobacco plants were generated carrying a rice homeobox gene,OSH1, controlled by the promoter of a gene encoding a tobacco pathogenesis-related protein (PR1a). These lines were morphologically abnormal, with wrinkled and/or lobed leaves. Histological analysis of shoot apex primordia indicated arrest of lateral leaf blade expansion, often resulting in asymmetric and anisotropic growth of leaf blades. Other notable abnormalities included abnormal or arrested development of leaf lateral veins. Interestingly,OSH1 expression was undetectable in mature leaves with the aberrant morphological features. Thus,OSH1 expression in mature leaves is not necessary for abnormal leaf development. Northern blot and in situ hybridization analyses indicate thatPR1a-OSH1 is expressed only in the shoot apical meristem and in very young leaf primordia. Therefore, the aberrant morphological features are an indirect consequence of ectopicOSH1 gene expression. The only abnormality observed in tissues expressing the transgene was periclinal (rather than anticlinal) division in mesophyll cells during leaf blade initiation. This generates thicker leaf blades and disrupts the mesophyll cell layers, from which vascular tissues differentiate. TheOSH1 product appears to affect the mechanism controlling the orientation of the plane of cell division, resulting in abnormal periclinal division of mesophyll cell, which in turn results in the gross morphological abnormalities observed in the transgenic lines.     

Abnormal cell divisions in leaf primordia caused by the expression of the rice homeobox geneOSH1 lead to altered morphology of leaves in transgenic tobacco

Transgenic tobacco plants were generated carrying a rice homeobox gene,OSH1, controlled by the promoter of a gene encoding a tobacco pathogenesis-related protein (PR1a). These lines were morphologically abnormal, with wrinkled and/or lobed leaves. Histological analysis of shoot apex primordia indicated arrest of lateral leaf blade expansion, often resulting in asymmetric and anisotropic growth of leaf blades. Other notable abnormalities included abnormal or arrested development of leaf lateral veins. Interestingly,OSH1 expression was undetectable in mature leaves with the aberrant morphological features. Thus,OSH1 expression in mature leaves is not necessary for abnormal leaf development. Northern blot and in situ hybridization analyses indicate thatPR1a-OSH1 is expressed only in the shoot apical meristem and in very young leaf primordia. Therefore, the aberrant morphological features are an indirect consequence of ectopicOSH1 gene expression. The only abnormality observed in tissues expressing the transgene was periclinal (rather than anticlinal) division in mesophyll cells during leaf blade initiation. This generates thicker leaf blades and disrupts the mesophyll cell layers, from which vascular tissues differentiate. TheOSH1 product appears to affect the mechanism controlling the orientation of the plane of cell division, resulting in abnormal periclinal division of mesophyll cell, which in turn results in the gross morphological abnormalities observed in the transgenic lines.     

Differential growth resulting in the specification of different types of cellular architecture in root meristems

Symplastic growth of plant organs may be described by a continuous growth tensor field. In tensorial analysis of meristems, the trajectories of periclinal and anticlinal cell walls represent trajectories of the principal directions of growth (PDGs); this follows from the maintenance of mutual orthogonality between periclinal and anticlinal wall trajectories during growth. Periclinal and anticlinal cell divisions are also oriented in the principal planes of growth. The growth tensor for the root apex is specified in such a way that the principal directions of the tensor fit the pattern of periclinal and anticlinal walls in the apex, and that the grid formed by material particles aligned along PDG trajectories preserve this alignment during growth. Two growth tensors are formulated--one giving a maximum and the other giving a minimum of the volumetric relative elemental growth rate at the region of the initial cell(s). Temporal sequences of deformation of a grid formed by lines coinciding with the principal directions of growth are shown. The formation of cellular patterns in root apices is simulated. Two types of patterns are obtained: one with an apical cell and merophytes, and another with files of cells converging towards a quiescent centre.     

安徽产两种山罗花属植物及其居群叶的微形态比较

利用离析法、扫描电镜和石蜡切片法对安徽产2种3居群山罗花属植物的叶进行了微形态比较研究,结果表明：该属植物叶表皮细胞形状为不规则形,垂周壁呈波状、深波状至重波状;表皮细胞内含叶绿体;角质层具条状纹饰;表皮上有表皮毛和腺毛分布,扫描电镜下表皮毛具瘤状突起的纹饰;栅栏组织只有1层,排列比较疏松,海绵组织有发达的胞间隙;气孔器多为无规则型,极少数仅有一个副卫细胞,仅分布于下表皮,扫描电镜下气孔外拱盖内缘近光滑或浅波状。2种植物在垂周壁式样、表皮毛密度、气孔器长宽比、栅栏组织和海绵组织的厚度比以及中脉的结构特征等具有明显的差异,而山罗花3居群间的差异不明显。     

A Dispersed Cuticle of Cordaites from the Coal of Late Paleozoic,North China

A dispersed cuticle from the coal of Taiyuan Formation, Xuzhou Coalfield, Jiangsu Province, North China was described. It was considered as the cuticle of Cordaites because of its epidermal structures and other features evidenced by optical and scanning electronic microscopic study. Compared with the known cuticles of other species of Cordaites, it was clear that the specimen under discussion was a new type of cuticle of Cordaites. Stomata were few in number on the upper cuticle, and usually arranged in a lengthwise and intermittent file, seperated by nonstomatal cell rows. Stomatal apparatus haplocheillic nearly square in shape, 30--50 μm long and 35--55 μm wide in size and consisted of a pair of slightly sunken guard cells surrounded by 2 lateral and 2 polar subsidiary cells, orientation longitudinal and regular. Numerous stomatal apparatus on the lower cuticle were arranged mostly in a defenite file seperated by nonstomatic band with 1--10 (often 3--5) rectangular cell rows. Usually small papillae were situated on the outer periclinal wall. The guard cell was reniform and bean-shaped, 10--14 μm long and 3--5 μm wide in size. The lateral subsidiary cell was more or less rectangular or elliptical in shape, 40--125 μm long and 17—25 μm wide in size, and with papillae on the outer periclinal wall. The polar subsidiary cell was some what round, short-elliptical or some rhomboid in shape and usually shared by adjacent stomatal apparatus in the same file.     

Rearrangements of F-actin during Stomatogenesis Visualised by Confocal Microscopy in Fixed and Permeabilised Tradescantia Leaf Epidermis

Abstract: New details of F-actin organisation in leaf epidermal and stomatal cells were revealed by rhodamine — and fluorescein — phalloidin staining of fixed epidermal peels of Tradescantia virginiana and visualisation by confocal microscopy. Non-specialised epidermal cells contain highly organised arrays of fine cortical actin filaments aligned in transverse or oblique orientations. In interphase guard mother cells (GMCs), the arrangement of cortical F-actin changes on the periclinal and anticlinal cell walls at different times during differentiation. Initially, cortical F-actin on the periclinal surfaces is oriented transversely and F-actin is evenly distributed around the anticlinal walls. Following polarisation of the adjacent subsidiary mother cells (SMCs), actin in GMCs concentrates on the lateral anticlinal walls, but not on the transverse walls. Subsequently, F-actin on the periclinal walls reorients to radial and then longitudinal. Organisation of F-actin in SMCs appears to be influenced by the adjacent GMCs and co-ordination in F-actin arrangements in cells of the stomatal complex continues through to the formation of the guard cell pair. Our studies indicate that actin bands marking the division site in prophase cells, and detected in microinjected living material, are a particularly labile subset of F-actin. Actin bands were difficult to preserve, even when aldehyde fixation was avoided, in contrast to all interphase and mitotic F-actin.     

天南星科叶表皮研究

利用光学显微镜对天南星科18属27种及菖蒲科1属1种植物的叶表皮微形态进行观察,同时用扫描电镜对具代表性的14种植物作了研究,结果显示：天南星科气孔类型变异较大,有不规则型,辐射型,平列型,胞环型及平列型和胞环型间的过渡类型,副卫细胞数目0－12个;表皮细胞长宽近相等,平周壁具条纹或否,垂周壁平直,弧形或波浪形,虽然气孔类型对天南星科分类上的意义不大,但与表皮细胞垂周壁形状,副卫细胞角质层纹饰等特征相结合对种间分类有一定意义,天南星科与菖蒲科叶表皮微形态明显不同,从而支持菖蒲属从天南星科中分出另立为科的观点。     

THE ROOT APICAL MERISTEM OF ASPLENIUM BULBIFERUM: STRUCTURE AND DEVELOPMENT

The root apical meristem of Asplenium bulbiferum Forst. f. has a prominent four-sided pyramidal cell with its base in contact with the rootcap. Derivatives (merophytes) that contribute to the main body of the root are produced from the three proximal faces of the apical cell. The rootcap has its origin from the fourth (distal) face of the apical cell. The first division in a proximal merophyte is periclinal to the root surface, separating an outer cell and an inner cell. The outer cell is the origin of the outer part of the cortex and the epidermis; the larger inner cell is the origin of the inner cortex, endodermis, pericycle, and vascular tissue. After the establishment of the basic number of cells in a unilayered merophyte, the cells undergo transverse divisions forming longitudinal files of cells. The mitotic index of the apical cell indicates that it is not a quiescent cell. Also, the first plane of division in a newly formed merophyte dictates that the apical cell is the originator of merophytes.     

Microtubule and actin filament organization during stomatal morphogenesis in the fernAsplenium nidus

Summary The newly-formed guard cell mother cells (GMCs) ofAsplenium nidus are small, lens-shaped and are formed by one or two asymmetrical divisions. Their growth axis is parallel to the plane of their future division, a process during which the internal periclinal wall (IPW) is detached from the partner wall of the underlying cell(s). This oriented GMC expansion occurs transversely to a microfibril bundle, which is deposited externally to a U-like microtubule (Mt) bundle and a co-localized actin filament (Af) bundle. They line the IPW and the major part of the anticlinal walls. The deposition of the microfibril bundle is followed by the slight constriction of the internal part of the GMCs and the broadening of the substomatal cavity. The IPW forms a distinct bulging distal to the neighbouring leaf margin, as well as a less defined proximal one. During the IPW bulging, the Mts and Afs under the external periclinal wall (EPW) attain a radial organization. This is followed by thinning of the central EPW region, which becomes impregnated with a callose-like glucan. The rest of the EPW becomes unequally thickened. The disintegration of the U-like Mt bundle is succeeded by the organization of radial Mt and Af arrays under the IPW. The radial Mt systems, controlling the alignment of the newly-deposited microfibrils, allow the GMC to assume a round paradermal profile. The GMCs form a preprophase Mt band (PPB) perpendicular to the interphase U-like Mt bundle. The anticlinal PPB portions appear first and those lining the periclinal walls later. The cytoplasm adjacent to the latter walls retain the radial Mt systems during early preprophase, simultaneously with the anticlinal PPB portions. The observations suggest that the GMCs of the fernA. nidus obtain a unique form, as a result of a particular polarity established in the cortical cytoplasm of the periclinal walls, in which Mts and Afs appear involved. This polarity persists in cell division and is inherited to guard cells (GCs). It provides primary morphogenetic information not only to GMCs but also to GCs.Abbreviations Af actin filament - EPW external periclinal wall - GC guard cell - GMC guard cell mother cell - IPW internal periclinal wall - Mt microtubule - MTOC microtubule organizing centre - PPB preprophase microtubule band     

Microtubules and morphogenesis in stomata of the water fernAzolla: An unusual mode of guard cell and pore development

Summary A mature stomate of the water fernAzolla consists of a single apparently unspecialized annular guard cell (GC) with two nuclei surrounding an elongated pore aligned longitudinally in the leaf. During development, the guard mother cell develops a preprophase band (PPB) of microtubules (MTs) oriented transverse to the leaf axis. This is followed by a cell plate which fuses with the parental walls at the PPB site. Subsequently only the central part of the cell plate is consolidated, while the parts to either side become perforated and tenuous and may disperse completely, forming a single composite GC.Meanwhile, a dense array of MTs appears along both faces of the central part of the new wall, oriented normal to the leaf surface. Further MT arrays radiate out across the periclinal walls from the region of the consolidated cell plate. Putative MT nucleating sites are seen along the cell edges between these anticlinal and periclinal arrays. Polarized light microscopy reveals cellulose deposition parallel to the periclinal MT arrays. At the same time lamellar material is deposited within the new anticlinal wall. As the GC complex elongates, a split appears in these lamellae creating an initially transverse slit which then opens up to become first circular and ultimately an elongated pore aligned in the long axis of the leaf,i.e., at right angles to the wall in which it originated. The radiating pattern of cellulose microfibrils in the periclinal walls contributes to the shaping of the pore. Elongation at the apical and basal ends of the GC is restricted by longitudinal microfibril orientation, while that at the sides is facilitated by transverse alignment.     

Glandular scale development and essential oil secretion in Origanum dictamnus L.

Glandular scales of Origanum dictamnus L. originate from a single protodermal cell. They are composed of a 12-celled head and an unicellular stalk and foot. During the early stages of gland differentiation, the head cells possess a small number of plastids which contain globular inclusions. Similar inclusions are also observed in the plastids of the stalk and the foot cell. The lateral walls of the stalk cell progressively undergo cutinization which does not extend to the upper and lower periclinal walls. At the onset of secretion the electron density of the plasmalemma region lining the apical walls of the head cells remarkably increases. These walls are impregnated with an osmiophilic substance identical in appearance to the content of the subcuticular space. In a following stage of the secretory process osmiophilic droplets of various size arise in the cytoplasm of the secretory cells which undergoes simultaneously a reduction of its initial density. After secretion has been concluded the protoplast of the head cells becomes gradually degenerated. The chlorenchyma cells of the mesophyll possess numerous microbodies closely associated with various organelles. In the cytoplasm of these cells crystalloids occasionally occur.     

Developmental Morphology and Histogenesis of Reproductive Structures of the Millet,Panicum miliaceum L. Histogenesis of the Inflorescence and Flower

The branches of successive orders of the inflorescence of Panicum miliaceum L. arise in the axils of the bracts of the branches of next lower order. Their initiation is evidenced by periclinal division of sub-hypodermal cells. The primordia of branches arise in initiation like a normal axillary bud. The floral histogenesis of Panicum miliaceum L. is similar to that of Triticum. Primordia of the spikelet, flower and stamen are initiated by the activity of the periclinal division of the sub-hypodermal cell or cells. Sometimes, periclinal divisions also occur in a few hypodermal cells during these primordial developments; such divisions are more frequent in the formation of the flower and stamen primordia than in the formation of the spikelet primordia. The periclinal division of the dermatogen ceils never occurs in the formation of these organs. Glumes and lemma are initiated in the periclinal division of the dermatogen and hypodermal cell or cells. The primordia of the palea, lodicule and carpel are initiated by means of the periclinal division in the dermatogen cell or cells. In the formation of the palea and carpel, periclinal divisions also occur in hypodermat cells, but their derivatives are protruding into the bases of the primordia and do not constitute the tissues of the palea and carpel. The growing point of the flower axis develops into the ovule. The integuments arise from the periclinal division of dermatogen cells. The periclinal division of dermatogen cells is characteristic of the initiation of the phylloid organs in the Gramineae.