Localization of crystals in diseased oats treated with uranyl acetate

Uranyl acetate, a suppressor of victorin-induced electrolyte leakage in oat leaves when applied together with, or before, victorin, also suppressed victorin-induced changes in ultra-structure. Uranyl crystallized in cell walls and near the plasmalemma of vascular cells, but was excluded from the protoplasm. Fewer crystals occurred near the plasmalemma when leaves were allowed to take up uranyl and victorin simultaneously than when uranyl alone was absorbed, but deposition in cell walls was similar in the two treatments. No differences in crystal distribution were found in uranyl-treated leaves which subsequently took up either water or victorin. The most striking effect of prolonged exposure to uranyl was increased vesicular activity in the protoplasm, formation of complex concentric membranes, and tonoplast damage. Following victorin treatment, uranyl post-treatment was ineffective in suppressing electrolyte leakage or preserving normal cellular ultrastructure. More severe ultrastructural damage was found in victorintreated leaves after uranyl post-treatments than after post-treatment with water, a result of victorin-induced damage which facilitates uranyl entry into the protoplasm.     

Carpellary outgrowth development in the endocarp of grapefruit,Citrus paradisi (Rutaceae)

The development and function of the carpellary outgrowth was investigated in grapefruit. Carpellary outgrowths were initiated 3 d postanthesis. By 7 d postanthesis, enlarged globose cells developed that were subtended by a parenchymatous stalk. Numerous Golgi, Golgi-derived vesicles, endoplasmic reticulum, mitochondria, and thickened cell walls present in globose cells from 7 d to 3 mo postanthesis suggest that the carpellary outgrowth was secretory in nature. Lectin-gold complex binding indicated that the secreted product contained galactose and arabinose. Cessation of secretory activity, marked by protoplast degeneration, occurred between 3 and 5 mo postanthesis.     

ENDOCYTOSIS OF LANTHANUM NITRATE IN THE ORGANIC ACID-SECRETING TRICHOMES OF CHICKPEA (CICER ARIETINUM L.)

The organic acid-secreting trichomes of chickpea (Cicer arietinum L.) were exposed to 2.5 mm lanthanum nitrate for 24 hr, and this concentration did not inhibit trichome secretion compared with that of controls. We subsequently used this nontoxic concentration of lanthanum to examine endocytosis. In the stalk cells of these secretory trichomes, exogenously applied lanthanum nitrate was present in cell walls and vacuoles, as well as within both invaginations in the plasma membrane and vesicles in the peripheral cytoplasm between the plasma membrane and the tonoplast. In the head cells, lanthanum nitrate was present in cell walls and in vesicles that form a layer in the cytoplasm around the edge of the head cells, but was not present in vacuoles. We propose that fluid phase endocytosis targeted to the vacuole takes place in the stalk cells and that endocytosis occurs in the head cells to remove excess plasma membrane after the fusion of secretory vesicles with the plasma membrane. This is the first demonstration of endocytosis in secretory trichomes.     

Cytodiffrentiation in the accessory glands of Tenebrio molitor. VI. A congruent map of cells and their secretions in the layered elastic product of the male bean-shaped gland

The morphology of the bean-shaped accessory glands (BAGs) of males of Tenebrio molitor is described. All cells in the secretory epithelium are long and narrow (300–400 mμ × 5 mμ). The seven types of secretory cells are distinguished from one another by the morphology of their secretory granules. Granule substructure varies from simple spheres with homogeneous electrondense contents to complex forms with thickened exterior walls or with crystalline and membranous contents. Individual cell types were mapped by staining whole glands with Oil Red O, and the cell distributions were confirmed by wax histology and ultramicroscopy. The secretions of all seven cell types form a secretory plug composed of seven layers. During mating, the secretory plug from each BAG is forced into the ejaculatory duct by contractions of a sheath of circular muscle. The mirror image plugs from symmetrical BAGs fuse and are transformed into the wall of the spermatophore.     

Molecular machinery and mechanism of cell secretion

Secretion occurs in all living cells and involves the delivery of intracellular products to the cell exterior. Secretory products are packaged and stored in membranous sacs or vesicles within the cell. When the cell needs to secrete these products, the secretory vesicles containing them dock and fuse at plasma membrane-associated supramolecular structures, called porosomes, to release their contents. Specialized cells for neurotransmission, enzyme secretion, or hormone release use a highly regulated secretory process. Similar to other fundamental cellular processes, cell secretion is precisely regulated. During secretion, swelling of secretory vesicles results in a build-up of intravesicular pressure, allowing expulsion of vesicular contents. The extent of vesicle swelling dictates the amount of vesicular contents expelled. The discovery of the porosome as the universal secretory machinery, its isolation, its structure and dynamics at nanometer resolution and in real time, and its biochemical composition and functional reconstitution into artificial lipid membrane have been determined. The molecular mechanism of secretory vesicle swelling and the fusion of opposing bilayers, that is, the fusion of secretory vesicle membrane at the base of the porosome membrane, have also been resolved. These findings reveal, for the first time, the universal molecular machinery and mechanism of secretion in cells.     

UPTAKE BY AND FATE OF LYSOZYME IN ROOTS OF IASIONE MONTANA (CAMPANULACEAE)

A basic protein, lysozyme, labeled with fluorescein isothiocyanate, is readily taken up by roots of lasione montana. Most of the protein taken up is tightly bound to cell walls of the roots. Fluorescent protein is diluted in the growing region of a root as cells elongate and divide. Fluorescence remains in mature nongrowing regions and root cap cells for one to two weeks. Redistribution and translocation of the protein within the root is minimal or nil. A layer of chloroform-soluble material that prevents lysozyme from interacting with stem cell walls exposed to fluorescent lysozyme was found on stems of germinating Iasione montana.     

Directional cell-to-cell communication in theArabidopsis root apical meristem III. Plasmodesmata turnover and apoptosis in meristem and root cap cells during four weeks after germination

Summary Plasmodesmata frequency and distribution in root cap cells ofArabidopsis thaliana root tips were characterized during four weeks after germination to understand the symplasmic control of apoptosis. Apoptotic cells in some of the root apical-meristem cells and in root cap cells were identified by the terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling reaction and characterized by electron microscopy. Starting at the second week after germination, cells in the outermost layers of the root cap showed typical apoptotic features, including nuclear DNA fragmentation, chromatin condensation, cytoplasmic vacuolation, and organelle destruction. Intercellular connections, indicated by the frequency and number of plasmodesmata per cell length, were significantly reduced in the walls of outer root cap cells. This shows that cells become symplasmically isolated during the apoptosis process. In apoptotic root cap cells, the majority of nonfunctional plasmodesmata were observed to be associated with degenerated endoplasmic reticulum; this state was prior to the detection of any nuclear DNA fragmentation. Other nonfunctional plasmodesmata were sealed by heterogeneous cell wall materials. However, in immature epidermal and cortical cells in 4-week-old arrested roots the endoplasmic reticulum associated with plasmodesmata became disconnected as a result of protoplast condensation and shrinkage. No degenerated endoplasmic reticulum was observed in these cells. These observations suggest that the apoptotic processes in the root body and the root cap are different.     

Fucose in the surface deposits of axenic and field grown roots ofZea mays L.

Summary The location of materials containing terminal fucose residues on the surface of axenic and field grown roots of corn has been determined.Binding patterns of FITC-labelled,Lotus purpureus Moench lectin indicate the presence of the fucose residues in the cell walls and mucilage of the peripheral region of the root cap. During development, fucose residues also appear in the outer periclinal walls and overlying mucilage of columnar epidermal cells. Surface material rich in these residues persists between the mature root hairs but is not found on their surface. Fucose-rich mucilage is present on the exposed surface of aerial roots and at the point where they enter the soil. No lectin binding residues are indicated elsewhere in the roots.     

A role for Ca in the cellular differentiation of root cap cells: A re-examination of root growth control mechanisms

Ultrastructural investigations of root caps (Zea mays) have shown a correlation between the depletion of extracellular Ca²⁺ resources by treatment of intact roots with 50 mM EGTA and changes in the activity of peripheral cap cells, involving reductions in the quantity and changes in the appearance of Golgi apparatus-derived material. In EGTA-treated roots the development of the Golgi apparatus of peripheral cap cells was severely altered and there was no evidence of a granular secretory product, which was encountered in the vesicles of dictyosomes of control roots. Vesicles of dictyosomes of EGTA-treated roots were small and the development of dictyosomes was reminiscent of that encountered in central cap cells of control roots. A decrease in amyloplast numbers brought about by EGTA was concomitant with reduced secretory activity. EGTA treatment was also associated with a redistribution of amyloplasts located in central cap cells. Decreased cap volume arising from EGTA treatment was considered indicative of a decline in overall cap activity. Proposals are made with regard to the integration of intercellular activities in the response of plant roots to stimulus-modulated signals. It is suggested that alterations in peripheral cap cell secretory activity arising from the redistribution of Ca²⁺ may account for the anisotropic growth response of gravireactive roots.     

An Electron Microscope Study of the Path of Water Movement in Transpiring Leaves of Cotton (Gossypium hirsulum L.)

Precipitation of ferrocyanide by ferric ions in cotton leavesproduced electron-opaque crystals visible with othe electronmicroscope and identifiable as Prussian blue by X-ray and electrondiffraction. These crystals were formed within the lumina andexposed primary walls of the tracheary elements but not withintheir secondary walls. The precipitation pattern indicated thatwater moved from the tracheary elements into the parenchymaof the bundle sheath and bundle sheath extensions. From thesecells water moved into the epidermis or through the mesophyllto the transpirational exits. Prussian blue accumulated in thewalls of cells lining the substomatal cavities and to a lesserextent between adjacent covering hairs. Ferrocyanide anionsdid not follow the water stream through the cuticle. In parenchymaand epidermal cells Prussian blue crystals were found withinthe primary wall, in the region between the plasma-lemma andthe cell wall, and within the protoplast.     

Plasmolysis as a Tool to Reveal Lead Localization in the Apoplast of Root Cells

In order to analyze the distribution of lead between cell walls and plasmalemma, two-day-old maize seedlings (Zea mays L.) were incubated for 24 h on a solution of lead nitrate at a concentration causing 50% inhibition of root growth (10^–5 M). Using the histochemical technique (precipitation of lead dithizonate), the distribution of lead in plasmolyzed and nonplasmolyzed cells of the root cortex was compared. This allowed us to separate the lead bound by cell walls from the lead located on the protoplast surface and in the periplasmic space. The plasmolysis was conducted prior to histochemical reaction by the incubation of seedling roots in 0.6 M sucrose solution for 30 min. The lead precipitates were located in cell walls and on the surface of protoplast. A small amount of lead was found in periplasmic space of some cells in root cortex. It is suggested that the lead is bound not only to the cell wall matrix but also to the plasmalemma.     

Golgi apparatus mediated polysaccharide secretion by outer root cap cells of Zea mays

Summary In the outer cap cells of roots of Zea mays, secretion is accompanied by hypertrophy of dictyosome cisternae with formation of large secretory vesicles. Vesicle contents are subsequently released from the protoplast by fusion of the vesicle membrane with the plasma membrane. The secreted material, a highly hydrated polysaccharide, was localized intracellularly by the periodic acid-Schiff reaction. Under appropriate conditions, the product moves outward through the cell wall after discharge from the protoplast, and appears as a droplet adhering to the root tip. Under conditions where the secretory product accumulates at the inner wall surfaces, no external droplet is formed.The secretory activity has an active phase that is sensitive to metabolic inhibitors and influenced by temperature (Q₁₀>2), and a passive phase that is independent of temperature, insensitive to metabolic inhibitors but sensitive to osmotic agents. The active phase is characterized by a temperature-independent periodicity (3 hours). Sucrose supplied to the growth medium increases the amount of polysaccharide secreted. Polysaccharide synthesis, segregation into vesicles, and discharge from the protoplast are assumed to require active metabolism; the step involving extrusion of polysaccharide through the cell wall region appears to be a passive process influenced by the degree of hydration of the polysaccharide and by cell turgor.Purdue University Agricultural Experiment Station Journal Paper No. 2967; Charles F. Kettering Research Laboratory Contribution No. 261.     

不同盐度下互花米草根结构的比较研究

以不同盐度下生长的互花米草(Spartina alterniflora)为材料,采用常规石蜡切片法对其根的横切结构进行显微观察,比较不同盐度下互花米草根结构的特点及变化规律,研究互花米草根对盐浸环境的适应性。观察结果显示:(1)互花米草根只有初生结构;(2)成熟根的表皮细胞基本毁坏、脱落;(3)互花米草根具有发达的外皮层和皮层通气组织,内皮层细胞壁五面加厚明显,且随盐度的升高呈先增大后减小的趋势;(4)维管柱中央被机械组织所填充,中柱鞘细胞壁也出现加厚现象。互花米草根的结构体现了其对盐浸环境的适应性特征。     

Secondary cell wall deposition causes radial growth of fibre cells in the maturation zone of elongating tall fescue leaf blades

A gradient of development consisting of successive zones of cell division, cell elongation and cell maturation occurs along the longitudinal axis of elongating leaf blades of tall fescue (Festuca arundinacea Schreb.), a C3 grass. An increase in specific leaf weight (SLW; dry weight per unit leaf area) in the maturation region has been hypothesized to result from deposition of secondary cell walls in structural tissues. Our objective was to measure the transverse cell wall area (CWA) associated with the increase in SLW, which occurs following the cessation of leaf blade elongation at about 25 mm distal to the ligule. Digital image analysis of transverse sections at 5, 15, 45, 75 and 105 mm distal to the ligule was used to determine cell number, cell area and protoplast area of structural tissues, namely fibre bundles, mestome sheaths and xylem vessel elements, along the developmental gradient. Cell diameter, protoplast diameter and area, and cell wall thickness and area of fibre bundle cells were calculated from these data. CWA of structural tissues increased in sections up to 75 mm distal to the ligule, confirming the role of cell wall deposition in the increase in SLW (r2 = 0.924; P < or = 0.01). However, protoplast diameter of fibre cells did not decrease significantly as CWA increased, although mean thickness of fibre cell walls increased by 95 % between 15 and 105 mm distal to the ligule. Therefore, secondary cell wall deposition in fibre bundles of tall fescue leaf blades resulted in continued radial expansion of fibre cells rather than in a decrease in protoplast diameter.     

Ultrastructure of acapsular mutant Cryptococcus neoformans cap 67 and monosaccharide composition of cell extracts

Acapsular mutant Cryptococcus neoformans cap 67 was grown in Pine's citrate broth medium for 3 days and the cells then transferred to a nitrogen-free medium for 6 days. The cells were subjected to a four stage extraction with buffered Triton-X1OO, cold dilute alkaline borohydride, hot dilute acetic acid, and a second alkaline extraction. Galactoxylomannan antigens were recovered from the culture supernates of both 3 day old and 9 day-old yeast cells. The alkaline extracts contained water-soluble galactoxylomannan and a water-insoluble glucan. Dilute acid treatment released a minor amount of carbohydrate from the cells. The second alkaline extraction yielded increased amounts of glucan and galactoxylomannan from the 9 day-old cells. Soluble non-dialyzable cell extracts were antigenically identical in immunodiffusion with the culture supernate antigens. After the extraction sequence, all of the galactose, xylose, and mannose were removed from the cells. The walls retained their shape after extraction but their layers were loosened. Cells resuspended in nitrogen-free medium for six days developed thickened walls with alternating electron-dense and electronlucent layers. The major constituent of the thickened 9 day-old cell walls was glucose, only 5% glucosamine was detected.     

ADVENTITIOUS ROOT DEVELOPMENT FROM THE COLEOPTILAR NODE IN ZEA MAYS L.

Department of Botany and Bacteriology, University of Arkansas, Fayetteville, Arkansas 72701 Zea mays L. root development from the coleoptilar node was observed by light and electron microscopy. Roots developed opposite collateral vascular bundles in the coleoptilar nodal region. Three distinct histogens (stelar, cortical-protoderm, and root cap) became evident in early development. In median sections of the young roots, root cap and cortical regions formed a “hat” configuration over the stelar region. As the root matured, this “hat” developed centripetally to encapsulate the stelar region. Central core cells of the root cap were characterized by having numerous dictyosomes, amyloplasts, vacuoles, and thin cell walls. As these cells matured into outer or peripheral cap cells, the Golgi vesicles became hypertrophied. These hypertrophied vesicles contained a granular PAS-positive material which accumulated between the plasma membrane and the cell wall and formed a thick layer. As the PAS-positive material passed through the cell wall, it changed to a fibrillar texture. A PAS-positive material similar to that in the outer root cap cells was found adjacent to the outer walls of the protodermal cells. In median sections, PAS-positive material was not present in the promeristem region. Root cap cells as well as parent cortical cells were crushed as the young root forced its way through the parent tissue.     

Fine-structural observations on necrotic adventitious root apices inGlechoma hederacea L.

Summary In certain adventitious roots ofGlechoma hederacea necrosis may already occur in the primordium before emergence from the parent shoot. In such roots the apical organization is lost and the root becomes dormant soon after emergence and covered by a brown mantle derived from the root cap and apical initials. The tangential walls of cells comprising the mantle are frequently conspiciously thickened and contain numerous flecks. The arrangement of the flecks resembles somewhat the suberin lamellae in other species but staining reactions failed to indicate the presence of suberin in the dormant root ofG. hederacea.     

Occurrence of secretory structures in underground systems of seven Asteraceae species

In contrast with the abundance of anatomical studies of secretory structures on aerial vegetative organs of Asteraceae species, the information about secretory structures on thickened subterranean organs is sparse. The aim of this study was to investigate the occurrence of secretory structures on thickened and nonthickened subterranean organs of seven Asteraceae species from three tribes: Eupatorieae (Chromolaena squalida and Gyptis lanigera), Vernonieae (Chresta sphaerocephala, Lessingianthus bardanoides, L. glabratus and Orthopappus angustifolius), and Plucheeae (Pterocaulon angustifolium). The specimens were collected in areas of cerrado from the State of São Paulo, Brazil. All species of the tribe Vernonieae studied exhibited endodermic cells, other than the epithelial cells of the canal, with secretory activity in the roots. In C. sphaerocephala roots, two types of endodermic cell were found, but only one had secretory activity. Secretory canals were found in the tuberous and nontuberous roots of all studied species. These data agree with the results from the literature for Asteraceae species. Here, we describe for the first time in Asteraceae the presence of secretory idioblasts in C. sphaerocephala. Secretory trichomes are present in the Orthopappus angustifolius rhizophore. Histochemical tests have shown that all types of secretory structure possess substances containing lipids. © 2008 The Linnean Society of London, Botanical Journal of the Linnean Society, 2008, 157 , 789–796.     

Some unusual staining properties of tannic acid in plants

Summary Maize root tips were fixed in glutaraldehyde fixatives containing tannic acid and then processed for electron microscopy. Under these conditions, tannic acid selectively stained the contents of the Golgi apparatus secretory vesicles of some outer root cap cells, the cell walls of all cells, and substances in, and adjacent to, intercellular connections of mature primary walls and of secondary walls. Intercellular connections of the young primary walls were not stained. Plasma membranes, and substances associated with the outer leaflets of the plasma membranes, were also stained. Tannic acid-positive material was associated with the cell plate vesicles of forming walls but very little, or none, was associated with the Golgi apparatus vesicles of dividing cells.