Cell kinetics, stomatal differentiation, and diurnal rhythm in Allium cepa

Cell kinetics parameters were obtained for the three mitotic divisions leading to formation of stomata in the epidermis of the cotyledon of Allium cepa seedlings. Analysis of mitotic frequencies throughout the course of development showed that the asymmetrical divisions started at about 50 hr after germination, and the symmetrical divisions were first seen a few hours later. Guard mother cell divisions started around 70 hr after germination. The maximal frequency of both symmetrical and asymmetrical division was found between 3 and 5 days after germination, and the highest frequencies of GMC divisions were observed between 6 and 8.5 days. All divisions ceased after 11 days. The three cell populations analyzed displayed diurnal fluctuations of their mitotic frequencies which were characteristic of the type of cell division measured and seemed independent of the region of the cotyledon in which they took place. The symmetrical divisions displayed two diurnal peaks—one at about 0400 and the other at 1600 hr—and the asymmetrical mitoses showed a single peak at about 2200 hr. Atypical asymmetrical divisions were observed in some guard mother cells, suggesting a different developmental sequence for some of the stomatal complexes.     

The development of stomata and other epidermal cells on the rice leaves

In the leaves of rice (Oryza sativa), stomatal initials arose from two asymmetric cell divisions and a symmetric division. Guard mother cells (GMCs) and long cells in stomatal files (LCSs) were formed through the first asymmetric division of the precursor cell of GMCs. Subsidiary cells (SCs) were produced by the second asymmetric division of subsidiary mother cells or LCSs. Following SC formation, GMCs divided once symmetrically to generate guard cells and then differentiated terminally to form mature stomata. The developmental patterns of long cells, prickle hairs and short cells (phellem cells and silica cells) were also examined. Interestingly, we found that the different developmental stages of stomata and epidermal cells occurred in the similar location of immature leaves of the same phyllotaxis. In addition, two spacing patterns (“one stoma, one long cell” and “one short cell row”) probably exist in rice leaves.     

The SCARECROW gene's role in asymmetric cell divisions in rice plants

Asymmetric cell division is one of the most important mechanisms in the diversification of cell function and fate. In Arabidopsis, SCARECROW (SCR) is essential for the asymmetric division of the cortex/endodermis progenitor cell in the root. To learn more about how SCR is involved in asymmetric division, we analyzed the rice SCR (OsSCR) expression. In the root tip, OsSCR expression was observed in the endodermal cell layer and downregulated in the daughter cortex cell after asymmetric division, just as with Arabidopsis SCR. In leaf primordia, expression of OsSCR was observed in stomatal and ligule formation. In stomatal development, OsSCR was specifically expressed in the stomatal cell files before formation of guard mother cells (GMCs), and then, its expression was localized in GMCs, when the first asymmetric division occurred to generate the GMCs. Before the second asymmetric division of subsidiary mother cells (SMCs), localized OsSCR expression was observed in SMCs in the area close to the GMCs. Before these asymmetric divisions, the localization of OsSCR mRNA in GMC-forming cells and SMCs was observed in the area of the daughter GMC and subsidiary cells. OsSCR expression was also observed in the initiation area of ligule formation, and its downregulation occurred in the inner L2 cells generated by asymmetric division. Based on these observations, we proposed that OsSCR is involved not only in the asymmetric division of the cortex/endodermis progenitor cell but also during stomata and ligule formation by establishing the polarization of cytoplasm.     

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     

Roles for polarity and nuclear determinants in specifying daughter cell fates after an asymmetric cell division in the maize leaf

Asymmetric cell divisions occur repeatedly during plant development, but the mechanisms by which daughter cells are directed to adopt different fates are not well understood [1,2]. Previous studies have demonstrated roles for positional information in specification of daughter cell fates following asymmetric divisions in the embryo [3] and root [4]. Unequally inherited cytoplasmic determinants have also been proposed to specify daughter cell fates after some asymmetric cell divisions in plants [1,2,5], but direct evidence is lacking. Here we investigate the requirements for specification of stomatal subsidiary cell fate in the maize leaf by analyzing four mutants disrupting the asymmetric divisions of subsidiary mother cells (SMCs). We show that subsidiary cell fate does not depend on proper localization of the new cell wall during the SMC division, and is not specified by positional information acting on daughter cells after completion of the division. Instead, our data suggest that specification of subsidiary cell fate depends on polarization of SMCs and on inheritance of the appropriate daughter nucleus. We thus provide evidence of a role for unequal inheritance of an intracellular determinant in specification of cell fate after an asymmetric plant cell division.     

The involvement of phospholipases C and D in the asymmetric division of subsidiary cell mother cells of Zea mays

In the present study, the involvement of phospholipase C and D (PLC and PLD) pathways in the asymmetric divisions that produce the stomatal complexes of Zea mays was investigated. In particular, the polar organization of microtubules (MTs) and actin filaments (AFs) and the process of asymmetric division were studied in subsidiary cell mother cells (SMCs) treated with PLC and PLD modulators. In SMCs treated with butanol-1 (but-1), which blocks phosphatidic acid (PA) production via PLDs, AF-patch formation laterally to the inducing guard cell mother cell (GMC) and the subsequent asymmetric division were inhibited. In these SMCs, cell division plane determination, as expressed by MT preprophase band (MT-PPB) formation, was not disturbed. Exogenously applied PA partially relieved the but-1 effects on SMCs. In contrast to SMCs, but-1 did not affect the symmetric GMC division. Inhibition of the PLC catalytic activity by neomycin or U73122 resulted in inhibition of asymmetric SMC division, while AF-patch and MT-PPB were organized as in control SMCs. These data show that the PLC and PLD signaling pathways are involved in the transduction and/or perception of the inductive stimulus that is emitted by the GMCs and induces the polar AF organization and asymmetric SMC division. In contrast, division plane determination in SMCs, as expressed by MT-PPB formation, does not depend on PLC and PLD signaling pathways.     

Cell kinetics,development of stomata and some effects of colchicine in barley

Summary The developmental sequence of the formation of stomatal complexes in the leaf epidermis of barley was studied. Cell-kinetic parameters were obtained from two genotypes — Early Bonus and eceriferum-g, a mutant with an abnormal stomatal pattern. The distribution of mitotic frequencies as a function of position in the stomatal rows was analyzed at each stage of development leading to mature stomata. Regression curves obtained for each stage showed that the distributions were stage-specific. Thus, the mitotic frequencies presented similar values throughout the portion of the file where the first asymmetrical divisions take place, had a parabolic distribution for the stage of subsidiary formation, and showed a linear shape, with a negative slope, for the stage of guard-mother-cell divisions. The mutant genotype differed from the normal by having a faster rate of ordinary guard-mother-cell divisions as a function of position in the row. The higher level of subsidiary cell formation in the mutant was interpreted as a consequence of a displacement of the used markers, suggesting a precocious initiation of subsidiary-cell formation in eceriferum-g. Time estimations of the length of the cell cycles were obtained by cell-population studies after a pulse with colchicine. Eceriferum-g appeared to have slower cell cycles. The leaves treated with colchicine showed a shift in the elongation axis of the cells. Autoradiography after treatment with ³H-thymidine showed ineorporation of the label in the portions of the row proximal to all three peaks of divisions indicating that all mitoses were preceded by the usual period of DNA synthesis. Labelling of lateral cells at a mature stage suggested DNA synthesis leading to endoploidy.     

Clonal analysis of stomatal development and patterning in Arabidopsis leaves.

Cell lineage has been used to explain the stomatal distribution in several plant species. We have used transgenic plants carrying a 35SGUS::Ac construct that produces clonal sectors to analyze the possible role of cell lineage during the establishment of stomatal patterning in Arabidopsis leaves. The analysis of sectors ranging from two to eighteen cells supports the conclusion that most stomatal complexes derive from a single and immediate precursor cell through a stereotyped pattern of three unequal cell divisions followed by a final equal one. In addition, it shows that the successive cell divisions take place at a constant angle (approximately 60 degrees ) with respect to the previous one. Interestingly, this angular dimension shifts from 60 degrees to 0 degrees in the last cell division that gives rise to the stoma. These sectors also reveal the development of both clockwise and counterclockwise patterns of cell divisions during stomatal development in approximately equal numbers. Our clonal analysis indicates that cell divisions involved in the development of stomatal complexes are probably the last ones contributing to epidermal growth and development. Finally, the stereotyped pattern of cell divisions that culminates in the formation of stomatal complexes indicates that cell lineage plays a very important role during stomatal pattern establishment.     

Stomatal development and patterning in Arabidopsis leaves

The functional unit for gas exchange between plants and the atmosphere is the stomatal complex, an epidermal structure composed of two guard cells, which delimit a stomatal pore, and their subsidiary cells. In the present work, we define the basic structural unit formed in Arabidopsis thaliana during leaf development, the anisocytic stomatal complex. We perform a cell lineage analysis by transposon excision founding that at least a small percentage of stomatal complexes are unequivocally non-clonal. We also describe the three-dimensional pattern of stomata in the Arabidopsis leaf. In the epidermal plane, subsidiary cells of most stomatal complexes contact the subsidiary cells of immediately adjacent complexes. This minimal distance between stomatal complexes allows each stoma to be circled by a full complement of subsidiary cells, with which guard cells can exchange water and ions in order to open or to close the pore. In the radial plane, stomata (and their precursors, the meristemoids) are located at the junctions of several mesophyll cells. This meristemoid patterning may be a consequence of signals that operate along the radial axis of the leaf, which establish meristemoid differentiation precisely at these places. Since stomatal development is basipetal, these radially propagated signals may be transmitted in the axial direction, thus guiding stomatal development through the basal end of the leaf.     

Stomatal neighbor cell polarity and division in <Emphasis Type="Italic">Arabidopsis</Emphasis>

Asymmetric divisions are key to regulating the number and patterning of stomata in Arabidopsis thaliana (L.) Heynh. Many formative asymmetric divisions take place in neighbor cells (NCs), cells adjacent to a stoma or stomatal precursor. TOO MANY MOUTHS is a receptor-like protein required for the correct plane of NC division, resulting in the placement of the new precursor distal to the pre-existing stoma. Because plant cells usually become polarized before asymmetric division, we studied whether NCs display a cytological asymmetry as a function of cell stage and of possible division behavior. Cells that divided in the developing leaf epidermis were smaller than 400 micro m(-2) in area and included NCs as well as isolated cells. All NCs in the youngest complexes divided with comparable frequencies, but divisions became restricted to the smaller and most recently produced NCs as the stomatal complex matured. The majority of developing NCs had distally located nuclei, suggesting that nuclear position is actively regulated in NCs. NC stages exhibiting distally located nuclei were the likeliest to divide asymmetrically. However, a distal nucleus did not necessarily predict an asymmetric division, because more NCs had distal nuclei than were likely to divide. No defect was detected in nuclear distribution in tmm NCs. These data suggest that TMM uses intercellular signals to control the plane of asymmetric division after or independently of nuclear positioning.     

Transient exposure to ethylene stimulates cell division and alters the fate and polarity of hypocotyl epidermal cells

After transient exposure to the gaseous hormone ethylene, dark-grown cucumber (Cucumis sativus) hypocotyls developed unusual features. Upon ethylene's removal, the developing epidermis showed significant increases in cell division rates, producing an abundance of guard cells and trichomes. These responses to ethylene depended on the stage of development at the time of ethylene exposure. In the upper region of the hypocotyl, where cells were least differentiated at the onset of ethylene treatment, complex, multicellular protuberances formed. Further down the hypocotyl, where stomata and trichomes were beginning to develop at the onset of ethylene exposure, an increase in the number of stomata and trichomes was observed. Stomatal complexes developing after the ethylene treatment had a significant increase in the number of stomatal subsidiary cells and the number of cells per trichome increased. Analysis of division patterns in stomatal complexes indicated that exposure to ethylene either suspended or altered cell fate. Ethylene also altered cell division polarity, resulting in aberrant stomatal complexes and branched trichomes. To our knowledge, the results of this study demonstrate for the first time that transient treatment with physiological concentrations of ethylene can alter cell fate and increase the propensity of cells to divide.     

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     

Three Brick genes have distinct functions in a common pathway promoting polarized cell division and cell morphogenesis in the maize leaf epidermis

We have taken a genetic approach to investigating cytoskeleton-dependent mechanisms governing cell morphogenesis in the maize leaf epidermis. Previously, we showed that the Brick1 (Brk1) gene is required for the formation of epidermal cell lobes as well as for properly polarized divisions of stomatal subsidiary mother cells, and encodes an 8 kDa protein highly conserved in plants and animals. Here, we show that two additional Brick genes, Brk2 and Brk3, are involved in the same aspects of epidermal cell morphogenesis and division. As shown previously for Brk1, analysis of the cytoskeleton shows that Brk2 and Brk3 are required for the formation of local F-actin enrichments associated with lobe outgrowth in wild-type cells. Analysis of brk1;brk2, brk1;brk3 and brk2;brk3 double mutants shows that their phenotypes are the same as those of brk single mutants. Mosaic analysis shows that Brk1 acts non cell-autonomously over a short distance. By contrast, Brk2 and Brk3 act cell-autonomously to promote pavement cell lobe formation, but Brk3 acts non cell-autonomously, and Brk2 partially non cell-autonomously, to promote polarized subsidiary mother cell divisions. Together, these observations indicate that all three Brk genes act in a common pathway in which each Brk gene has a distinct function. Recent work demonstrating a function for the mammalian homolog of BRK1 (HSPC300) in activation of Arp2/3-dependent actin polymerization implicates the Brk pathway in local regulation of actin polymerization in plant cells.     

THE CUTICULAR ANATOMY OF FRENELOPSIS VARIANS FROM THE LOWER CRETACEOUS OF CENTRAL TEXAS

Stem fragments identified as Frenelopsis varions Fontaine have been found in the Lower Cretaceous (Albian) of central Texas. The cuticle is extremely thick and characterized by 5–6 subsidiary cells with papillae overarching the stomatal chamber. Guard cells are deeply sunken below the epidermis. Stomatal complexes are arranged in axial rows extending from the base of an internode to its apex. The rows of stomata continue into the sheathing leaf where the rows curve towards the leaf apex. The epidermis of F. varions was apparently long persistent and underwent prolonged growth. Axial rows of stomata are frequently disrupted resulting in a random pattern of stomata. A single, highly reduced, sheathing leaf is present at each node. The margin of the leaf has numerous unicellular trichomes and extends to form a slightly triangular blade.     

Cellulose Synthase-Like D1 is integral to normal cell division, expansion, and leaf development in maize

The Cellulose Synthase-Like D (CslD) genes have important, although still poorly defined, roles in cell wall formation. Here, we show an unexpected involvement of CslD1 from maize (Zea mays) in cell division. Both division and expansion were altered in the narrow-organ and warty phenotypes of the csld1 mutants. Leaf width was reduced by 35%, due mainly to a 47% drop in the number of cell files across the blade. Width of other organs was also proportionally reduced. In leaf epidermis, the deficiency in lateral divisions was only partially compensated by a modest, uniform increase in cell width. Localized clusters of misdivided epidermal cells also led to the formation of warty lesions, with cell clusters bulging from the epidermal layer, and some cells expanding to volumes 75-fold greater than normal. The decreased cell divisions and localized epidermal expansions were not associated with detectable changes in the cell wall composition of csld1 leaf blades or epidermal peels, yet a greater abundance of thin, dense walls was indicated by high-resolution x-ray tomography of stems. Cell-level defects leading to wart formation were traced to sites of active cell division and expansion at the bases of leaf blades, where cytokinesis and cross-wall formation were disrupted. Flow cytometry confirmed a greater frequency of polyploid cells in basal zones of leaf blades, consistent with the disruption of cytokinesis and/or the cell cycle in csld1 mutants. Collectively, these data indicate a previously unrecognized role for CSLD activity in plant cell division, especially during early phases of cross-wall formation.     

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.     

BASL and EPF2 act independently to regulate asymmetric divisions during stomatal development

The initiation of stomatal development in the developing Arabidopsis epidermis is characterized by an asymmetric ‘entry’ division in which a small cell, known as a meristemoid, and a larger daughter cell is formed. The meristemoid may undergo further asymmetric divisions, regenerating a meristemoid each time, before differentiating into a guard mother cell which divides symmetrically to form a pair of guard cells surrounding a stomatal pore. Recently EPF2 and BASL have emerged as regulators of these asymmetric divisions and here we present results indicating that these two factors operate independently to control stomatal developmentKey words: stomata, development, meristemoids, asymmetric cell division, leaf epidermis, cell polarity, peptide signal     

PHOTOCONTROL OF THE ORIENTATION OF CELL DIVISION IN ADIANTUM. I. EFFECTS OF THE DARK AND RED PERIODS IN THE APICAL CELL OF GAMETOPHYTES

When protonemata of Adiantum capillus-veneris L. which had been grown filamentously under continuous red light were transferred to continuous white light, the apical cell divided transversely twice, but the 3rd division was longitudinal. An intervening period of darkness lasting from 0 to 90 hr either between the 1st and the 2nd cell division or between the 2nd and the 3rd one did not affect the number of protonemata in which the 3rd cell division was longitudinal. The insertion of red light instead of darkness greatly decreased the percentage of 1st longitudinal divisions occurring at the 3rd division, and increased the number of transverse divisions. Fifty percent reduction of induction of 1st longitudinal division was caused by ca. 50 hr exposure to red light between 1st and 2nd division and by ca. 20 hr between 2nd and 3rd division, and total loss was induced by an exposure of ca. 100 hr or longer to red light in the former and by ca. 40 hr longer in the latter. Thus, by using an appropriate intervening dark period or exposure to red light, the orientation and timing of cell division could be controlled in apical cell of the fern protonemata.     

The Arabidopsis D-type cyclin CYCD4 controls cell division in the stomatal lineage of the hypocotyl epidermis

Cyclin D (CYCD) plays an important role in cell cycle progression and reentry in response to external signals. Here, we demonstrate that Arabidopsis thaliana CYCD4 is associated with specific cell divisions in the hypocotyl. We observed that cycd4 T-DNA insertion mutants had a reduced number of nonprotruding cells and stomata in the hypocotyl epidermis. Conversely, CYCD4 overexpression enhanced cell division in nonprotruding cell files in the upper region of the hypocotyls, where stomata are usually formed in wild-type plants. The overproliferative cells were of stomatal lineage, which is marked by the expression of the TOO MANY MOUTHS gene, but unlike the meristemoids, most of them were not triangular. Although the phytohormone gibberellin promoted stomatal differentiation in the hypocotyl, inhibition of gibberellin biosynthesis did not prevent CYCD4 from inducing cell division. These results suggested that CYCD4 has a specialized function in the proliferation of stomatal lineage progenitors rather than in stomatal differentiation. We propose that CYCD4 controls cell division in the initial step of stomata formation in the hypocotyl.     

Cell division cycle of cultured neural precursor cells from Drosophila

In Drosophila neuroblast cells, which give rise to the embryonic nervous system, undergo a limited number of asymmetric cell divisions. These cell lineages result in the formation of clusters of neurons when neuroblasts are isolated and cultured. A significant proportion of these neural cell clusters (NCC) arise from individual precursor cells. The formation of NCC containing more than two neurons is repressed when DNA synthesis is inhibited. Cell division during NCC development was examined by [3H]thymidine autoradiography. The pattern of DNA synthesis by neural cells was that expected based on observations in situ. The pattern in individual NCC was consistent with single precursor origins for more than 80% of NCC, under our conditions of culture. Based on this, we show that the largest neural precursors at gastrulation undergo the most cell divisions in culture. The neuroblast cell division cycle averages approximately 1.5 hr, and is similar to that of blastoderm cells.