The predominant role of the pith in the Growth and development of internodes in Liquidambar styraciflua (Hamamelidaceae). I. Histological basis of compressive and tensile stresses in developing primary tissues

Quantitative changes in cell pattern in the pith, cortex, cortical collenchyma, and epidermis were followed in developing internodes of Liquidambar to examine the cellular basis of compressive and tensile stresses in organized shoot growth. Initially, the highest rates of cell multiplication occur in the pith, followed successively by the epidermis, cortex, and cortical collenchyma. As internodes enter the phase of maximum elongation growth, mitotic activity begins to shift acropetally, accompanied by pronounced changes in cell pattern. The highest rates of cell multiplication now occur in the pith and cortex and continue until the cessation of internode growth. Concomitantly, reduced rates of cell division in peripheral tissues result in rapid increases in rates of cell elongation in the cortical collenchyma and epidermis. Attention is focused on the role of continued cell division in developing internodes with emphasis on differences in rates of cell multiplication between inner and outer tissues affecting patterns of tissue stress. For example, rapid and sustained increases in cell number in the pith, accompanied by growth of readily extensible pith cells, result in the development of compressive forces driving the growth of internodes. Conversely, continuing divisions in less extensible collenchyma and epidermal cells can relieve threshold tensile stresses resulting from the continuous stretching of these tissues by the developing pith. The concept that the passive extension of peripheral tissues, especially the epidermis, control the rate of internode elongation is viewed as an oversimplification of the interacting role of compressive and tensile forces in organized growth and development.     

Sugar concentrations along and across the Ricinus communis L. hypocotyl measured by single cell sampling analysis

Single cell sap sampling and analysis were used to measure the longitudinal and radial distribution of sucrose, glucose and fructose in the apical cell division zone and in the basal, elongated zone of the Ricinus hypocotyl. Sucrose and hexose increased in concentration from the apex to the base of the seedling axis. In the cell division zone low hexose and sucrose concentrations prevailed in cortex and pith, with a slightly higher hexose concentration in pith cells. The sucrose concentrations in sieve tubes and in phloem were much higher than in the cortex and pith cells. In the basal zone of the hypocotyl high levels of sucrose in phloem, cortex and pith were found, therefore radial, diffusional sucrose flow away from the phloem was considered unlikely. It is proposed that radial flow of growth-water to the hypocotyl periphery together with the down-regulation of a sucrose transporter at the phloem leads to a preferential sucrose flow to the expanding cortex. The pith cells, which do not experience flow of growth-water, are probably insufficiently supplied with sucrose from the phloem resulting eventually in cell death as the plant grows. Shortage of sucrose supply, experimentally achieved by removal of the endosperm, led to sucrose hydrolysis in the pith. The sucrose levels in the other tissues decreased less. It appears that the hydrolysis to hexose was initiated to maintain the osmotic value in the pith cell sap. It is speculated that high hexose levels in the cells are indicative of insufficient sucrose supply via the phloem and that the pith cells are confronted with that situation during early seedling development.     

Cell cleavage : Ultrastructural evidence against equatorial stimulation by aster microtubules

Cell cleavage is spatially and temporally coordinated with karyokinesis. In astral division, as occurs in sea urchin eggs, coordination is accomplished by the mitotic asters. We have explored the following hypotheses:

1. 1. That microtubules of the two asters cross at the cell's equator.

2. 2. That because they cross, or by some other configuration, more microtubules interact with the equatorial cortex than with the polar cortex.

3. 3. That the microtubule component of astral rays differentially stimulates the equatorial cortex for cleavage contraction.

Using a fixation procedure which enhances visibility of microtubules, we have determined that aster microtubules do not cross at the equatorial cortex at any stage of mitosis relevant to cleavage stimulation, contrary to the first hypothesis. Aster microtubules extend progressively farther during anaphase, but the two arrays occupy mutually exclusive hemispheres in the egg. Using another fixation procedure which results in more conventional microtubule morphology, we have systematically counted microtubules penetrating the cortex at both the equator and the poles in sections cut parallel and perpendicular to the axis of the mitotic apparatus, respectively, at all stages of mitosis. We did not observe any microtubules in the cortex of the equator during prometaphase, metaphase, early anaphase or mid-anaphase. In comparison, small numbers of microtubules were observed in the polar cortex during this time. By late anaphase there are some microtubules in the equatorial cortex but many more are observed in the polar cortex. These findings are contrary to the second hypothesis and therefore do not establish the morphological basis for the third hypothesis. We conclude that there is no positive correlation between microtubule numbers at the egg equator and the timing of cleavage stimulation. Therefore, coordination between karyokinesis and cell cleavage is achieved by some process other than the simple numerical increase of microtubules at the equatorial cortex.     

Furrow Constriction in Animal Cell Cytokinesis

Cytokinesis is the process of physical cleavage at the end of cell division; it proceeds by ingression of an acto-myosin furrow at the equator of the cell. Its failure leads to multinucleated cells and is a possible cause of tumorigenesis. Here, we calculate the full dynamics of furrow ingression and predict cytokinesis completion above a well-defined threshold of equatorial contractility. The cortical acto-myosin is identified as the main source of mechanical dissipation and active forces. Thereupon, we propose a viscous active nonlinear membrane theory of the cortex that explicitly includes actin turnover and where the active RhoA signal leads to an equatorial band of myosin overactivity. The resulting cortex deformation is calculated numerically, and reproduces well the features of cytokinesis such as cell shape and cortical flows toward the equator. Our theory gives a physical explanation of the independence of cytokinesis duration on cell size in embryos. It also predicts a critical role of turnover on the rate and success of furrow constriction. Scaling arguments allow for a simple interpretation of the numerical results and unveil the key mechanism that generates the threshold for cytokinesis completion: cytoplasmic incompressibility results in a competition between the furrow line tension and the cell poles’ surface tension.     

Modification by ethylene of the cell growth pattern in different tissues of etiolated lupine hypocotyls

The influence of ethylene on growth in etiolated lupine (Lupinus albus L.) hypocotyls was studied in ethephon-treated plants. Ethephon reduced the length and increased the diameter of hypocotyls. At the end of the hypocotyl growth period (14 days), the fresh weight was reduced by 53%, and the dry weight was reduced by 16%. Thus, ethylene reduced water uptake in the tissues to a greater extent than the incorporation of new materials. Light microscopic measurements showed that the thickness of tissues was stimulated by ethylene, the vascular cylinder and cortex exhibiting greater increases (55 and 45%, respectively) than pith (26%) or epidermis (12%). Ethephon modified the cell growth pattern, stimulating lateral cell expansion and cell wall thickness, while reducing cell elongation. The response to ethylene varied in the different tissues and was higher in cortex and pith cells than in the epidermis cells. The ethylene-induced cell expansion in the cortex varied according to the localization of cells in the tissue: the central and subepidermal layers showed little change, whereas the innermost layers exhibited the greatest increase. Electron microscopy revealed that ethylene increased both the rough endoplasmic reticulum and dictyosomes, suggesting that ethylene stimulated the secretion of cell wall materials. In untreated seedlings, the pattern of cell growth was similar in cells from the epidermis, cortex, and pith. The final cell size varied along the hypocotyl, the cells becoming shorter and broader the closer to the basal zones of the organ.     

Furrow Constriction in Animal Cell Cytokinesis

Cytokinesis is the process of physical cleavage at the end of cell division; it proceeds by ingression of an acto-myosin furrow at the equator of the cell. Its failure leads to multinucleated cells and is a possible cause of tumorigenesis. Here, we calculate the full dynamics of furrow ingression and predict cytokinesis completion above a well-defined threshold of equatorial contractility. The cortical acto-myosin is identified as the main source of mechanical dissipation and active forces. Thereupon, we propose a viscous active nonlinear membrane theory of the cortex that explicitly includes actin turnover and where the active RhoA signal leads to an equatorial band of myosin overactivity. The resulting cortex deformation is calculated numerically, and reproduces well the features of cytokinesis such as cell shape and cortical flows toward the equator. Our theory gives a physical explanation of the independence of cytokinesis duration on cell size in embryos. It also predicts a critical role of turnover on the rate and success of furrow constriction. Scaling arguments allow for a simple interpretation of the numerical results and unveil the key mechanism that generates the threshold for cytokinesis completion: cytoplasmic incompressibility results in a competition between the furrow line tension and the cell poles’ surface tension.     

Bullwhip neurons in the retina regulate the size and shape of the eye

Bullwhip and mini-bullwhip cells are unconventional types of retinal neurons that utilize the neuropeptides glucagon, glucagon-like peptide 1 (GLP1) and substance P. These cells have been implicated in regulating the proliferation of neural progenitors in the circumferential marginal zone (CMZ) of the chicken retina. The purpose of this study was to investigate the roles of the bullwhip cells in regulating ocular size and shape. We found that intravitreal delivery of colchicine at postnatal day 7 destroys the vast majority (approximately 98%) of the bullwhip and mini-bullwhip cells and their peptidergic terminals that are concentrated in the CMZ near the equator of the eye. Interestingly, colchicine-treatment resulted in excessive ocular growth that involved the expansion of equatorial diameter, but not axial length. Intraocular injections of glucagon completely prevented the equatorial expansion that occurs with colchicine-treatment. In eyes with undamaged retinas, exogenous glucagon suppressed equatorial eye growth, whereas glucagon receptor antagonists caused excessive equatorial growth. Furthermore, visual stimuli that increase or decrease rates of ocular growth caused a down- or up-regulation, respectively, of the immediate early gene Egr1 in the bullwhip cells; indicating that the activity of the bullwhip cells is regulated by growth-guiding visual cues. We found that the glucagon receptor was expressed by cells in the fibrous and cartilaginous sclera in equatorial regions of the eye. Taken together, these findings suggest that glucagon peptide released from the terminals of the bullwhip and mini-bullwhip cells regulates the growth of the equatorial sclera in a vision-dependent manner. Although the bullwhip and mini-bullwhip cells are not abundant, less than 1000 cells per retina, their influence on the development of the eye is substantial and includes vision-guided ocular growth.     

A comparative karyological and cytophotometric study of normal and wounded stem tissues ofLathyrus odoratus L.

Wounding of stems ofLathyrus odoratus induced increased mitoses with polyploid in vascular and pith tissues, but not in cortex. Cell division area extended 200 μm from the wound edge. These facts confirm the previous observations inPisum sativum. DNA content of normal stem nuclei was high in vascular and pith tissues, but not in cortex.     

梨果实表面积新测算方法的建立

基于对梨果形的分析,提出用随圆及线性方程描述梨果实,由这些方程推导出测算梨果袂表面积的新公式的新方法,新方法测量简便快速,只需一把游标卡尺即可,测出果实横径、纵径、梗端果宽、萼洼深及最大横径与果项间的长度,即可用新公式计算出果实表面积,在两个品种上对新公式测算精度进行检验,其平均测算误差分别为１．８６％和２．５２％,说明用新方法可相当准确地测算梨果实表面积。     

Developmental Patterns of Phytohormone Content in the Cortex and Pith of Potato Tubers as Related to Their Growth and Starch Content

The contents of ABA, IAA, and cytokinins (zeatin + zeatin riboside) were determined in the cortex and pith of medium-sized (25 g) and large (120 g) tubers of potato (Solanum tuberosum L., cv. Malakhit) at the end of the flowering phase (48 days after sprouting) and related to plant growth (cell division and enlargement) and starch biosynthesis and deposition. The patterns of phytohormone distribution were different in the cortex and pith. In the latter, with most cells at the enlargement phase, the IAA content increased, as well as the ratios IAA/ABA and IAA/cytokinins. In the cortex dominated by the dividing cells, the ABA content declined, and the ratio cytokinins/ABA exceeded that in the pith. The enhancement of starch synthesis and accumulation in the pith and the retardation of these processes in the cortex followed the changes in the ABA content providing indirect support to the previously made observation that the exogenous ABA promoted starch biosynthesis. The data obtained are discussed in the context of the hormonal control of carbohydrate metabolism and starch deposition in growing tubers.     

Correlation of cell division and cell expansion to potato microtuber growth in vitro

The sink capacity of plant storage organs influences crop economic yield and relates to the number and volume of their cells. To obtain a better understanding of their contributions to the growth of potato microtubers produced in vitro, the number and volume of the cells in the tuber tissues were measured as tubers grew. Two potato cultivars, E-Potato 1 and Mira were employed and the results showed that cortex, perimedulla and pith tissue contributed for about 30, over 65 and up to 3% to the volume of the mature microtuber, respectively. The number of cells and cell volume increased simultaneously as the microtubers grew and the relationships could be described by a power function, Y = aW ^b. However, the rate of cell division was greater than the rate of cell expansion and the former contributed more than the latter to the increase in tuber size. The rate of cell division was greatest in the cortex and least in the pith, but, because the perimedulla forms the largest part of the tuber, cell division in this tissue was particularly important. The regulation of cell division to improve the production of usable microtubers is discussed.     

Dynamic changes in microtubule organization during division of the primitive dinoflagellate Oxyrrhis marina

The marine dinoflagellate Oxyrrhis marina has three major microtubular systems: the flagellar apparatus made of one transverse and one longitudinal flagella and their appendages, cortical microtubules, and intranuclear microtubules. We investigated the dynamic changes of these microtubular systems during cell division by transmission and scanning electron microscopy, and confocal fluorescent laser microscopy. During prophase, basal bodies, both flagella and their appendages were duplicated. In the round nucleus situated in the cell centre, intranuclear microtubules appeared radiating toward the centre of the nucleus from densities located in some nuclear pores. During metaphase, both daughter flagellar apparatus separated and moved apart along the main cell axis. Microtubules of ventral cortex were also duplicated and moved with the flagellar apparatus. The nucleus flattened in the longitudinal direction and became discoid-shaped close to the equatorial plane. Many bundles of microtubules ran parallel to the short axis of the nucleus (cell long axis), between which chromosomes were arranged in the same direction. During ana-telophase, the nucleus elongated along the longitudinal axis and took a dumbbell shape. At this stage a contractile ring containing actin was clearly observed in the equatorial cortex. The cortical microtubule network seemed to be cut into two halves at the position of the actin bundle. Shortly after, the nucleus divided into two nuclei, then the cell body was constricted at its equator and divided into one anterior and one posterior halves which were soon rebuilt to produce two cells with two full sets of cortical microtubules. From our observations, several mechanisms for the duplication of the microtubule networks during mitosis in O. marina are discussed.     

An Equatorial Contractile Mechanism Drives Cell Elongation but not Cell Division

Cell shape changes and proliferation are two fundamental strategies for morphogenesis in animal development. During embryogenesis of the simple chordate Ciona intestinalis, elongation of individual notochord cells constitutes a crucial stage of notochord growth, which contributes to the establishment of the larval body plan. The mechanism of cell elongation is elusive. Here we show that although notochord cells do not divide, they use a cytokinesis-like actomyosin mechanism to drive cell elongation. The actomyosin network forming at the equator of each notochord cell includes phosphorylated myosin regulatory light chain, α-actinin, cofilin, tropomyosin, and talin. We demonstrate that cofilin and α-actinin are two crucial components for cell elongation. Cortical flow contributes to the assembly of the actomyosin ring. Similar to cytokinetic cells, membrane blebs that cause local contractions form at the basal cortex next to the equator and participate in force generation. We present a model in which the cooperation of equatorial actomyosin ring-based constriction and bleb-associated contractions at the basal cortex promotes cell elongation. Our results demonstrate that a cytokinesis-like contractile mechanism is co-opted in a completely different developmental scenario to achieve cell shape change instead of cell division. We discuss the occurrences of actomyosin rings aside from cell division, suggesting that circumferential contraction is an evolutionally conserved mechanism to drive cell or tissue elongation.     

Cortical actin turnover during cytokinesis requires myosin II

The involvement of myosin II in cytokinesis has been demonstrated with microinjection, genetic, and pharmacological approaches; however, the exact role of myosin II in cell division remains poorly understood. To address this question, we treated dividing normal rat kidney (NRK) cells with blebbistatin, a potent inhibitor of the nonmuscle myosin II ATPase. Blebbistatin caused a strong inhibition of cytokinesis but no detectable effect on the equatorial localization of actin or myosin. However, whereas these filaments dissociated from the equator in control cells during late cytokinesis, they persisted in blebbistatin-treated cells over an extended period of time. The accumulation of equatorial actin was caused by the inhibition of actin filament turnover, as suggested by a 2-fold increase in recovery half-time after fluorescence photobleaching. Local release of blebbistatin at the equator caused localized accumulation of equatorial actin and inhibition of cytokinesis, consistent with the function of myosin II along the furrow. However, treatment of the polar region also caused a high frequency of abnormal cytokinesis, suggesting that myosin II may play a second, global role. Our observations indicate that myosin II ATPase is not required for the assembly of equatorial cortex during cytokinesis but is essential for its subsequent turnover and remodeling.     

落葵粘液细胞分布及发育的解剖学研究

采用石蜡切片法对落葵粘液细胞的分布及发育构造进行观察研究.结果表明:(1)除花药、子房及种子外,粘液细胞普遍存在于落葵植株的地上部分内.茎中的粘液细胞多单个散生分布于皮层、髓及髓射线;叶内的粘液细胞主要分布于海绵组织,栅栏组织中则很少见;叶柄中的粘液细胞主要沿叶柄"U"型皮层的两边分布;发育后期作为果实的花萼片中粘液细胞则散生分布很多.(2)根据发育过程的不同形态,可将粘液细胞的发育分为4个阶段:原始细胞阶段、液泡化阶段、成熟阶段和细胞质解体阶段;粘液细胞最早可见于第三叶原基,并且粘液细胞的发育与植株器官的发育不同步.     

Control of cell size at division in fission yeast by a growth-modulated size control over nuclear division

In the fission yeast Schizosaccharomyces pombe, nutritional reduction of growth rate by supplying poor nitrogen, carbon or phosphate sources causes a decrease in cell size. The effect on cell division following three different nutritional shifts-up has been investigated. In all cases, about 20% of the cells divide at the original cell length, and then cell division stops for a period. Cell division then resumes at the new faster rate, cell length at division being characteristic of the new medium. Further investigation reveals that the first effect of the shift is to inhibit nuclear division rapidly and completely. These results are strongly suggestive of the operation of a cell size requirement for entry into nuclear division. The cell size necessary for nuclear division is set, or modulated, by the prevailing growth conditions. This model is confirmed by a nutritional shift-down, where nuclear division and cell division are stimulated after the shift. Cell length at division falls rapidly until the new shorter length is attained, when a new steady state is assumed at a slower growth rate. The control system is compared with that in bacteria, and its implications for various models proposed for the control of timing of mitosis are discussed.     

Reduced Anthracnose Stalk Rot in Resistant Maize is Associated with Restricted Development of Colletotrichum graminicola in Pith Tissues

Resistance to anthracnose stalk rot (ASR) in maize was investigated for its effects on the development of Colletotrichum graminicola. ASR and fungal presence in pith tissues of resistant and susceptible genotypes, inoculated at time intervals after wounding in the first internodes, were assessed by rating tissue discoloration and by quantifying ergosterol production using high performance liquid chromatography (HPLC) and fungal recovery from tissues, respectively. Slices (30 μm thick) of pith cores (2 mm diam) of first internodes at late‐whorl and kernel blister stages were also inoculated with a suspension of fungal conidia immediately, 2 or 6 h after slicing. Fungal development was observed in tissues by light microscopy. ASR was markedly reduced in resistant genotypes when compared to susceptible genotypes and when inoculation was delayed after stalk wounding. Ergosterol content in tissues was associated with extent of discoloration due to ASR and fungal recovery. Conidial germination, germ tube elongation, appressorium formation and penetration of cortical cells were all markedly delayed in resistant genotypes, in both resistant and susceptible maize at vegetative stages, and by wound healing. C. graminicola macerated more rapidly and to a greater extent pith tissues of susceptible than resistant genotypes. Resistance mediated by maize genotype and ontogeny, and wound healing is expressed at early stages and subsequent events of host–pathogen interaction. Fungal structural development in detached pith tissues and the rapidity and extent of pith maceration in susceptible when compared to resistant genotypes was indicative of genotypic reaction to ASR in maize in the field. Laboratory inoculation and observation of detached pith tissues could be a useful and accurate tool for rapid screening of maize germplasm to identify ASR resistant genotypes that will function well in the field even where pathogen ingress occurs via wounds.     

Cell division and cell enlargement during potato tuber formation

Cell division and cell enlargement were studied to reveal the developmental mechanism of potato tuberization using both in vivo in vitro culture systems. Distribution of cells in S-phase was visualized by immunolabelling of incorporated bromodeoxyuridine (BrdU). Mitosis was detected in DAPI (4,6-di-amidino-2-phenylindole) or toluidine blue-stained sections. Timing and frequency of cell division were determined by daily cell counting, and cell enlargement was deduced from measurements of cell diameters.Under in vivo conditions, lateral underground buds developed into stolons due to transverse cell divisions and cell elongation in the apical region of the buds. At the onset of tuber formation, the elongation of stolons stopped and cells in pith and cortex enlarged and divided longitudinally, resulting in the swelling of the stolon tip. When tubers had a diameter of 0.8 cm, longitudinal divisions had stopped but randomly oriented division and cell enlargement occurred in the perimedullary region and continued until tubers reached their final diameter.In vitro tubers were formed by axillary buds on single node cuttings cultured under tuber-including conditions. They stopped growing at a diameter of 0.8 cm. Pith and cortex were involved in tuberization such as that found during the early stage of in vivo tuberization (<0.8 cm in diameter). The larger size of in vivo tubers is, however, due to further development of the perimedullary region, which is lacking in vitro conditions.Keywords: Cell division, cell enlargement, DNA synthesis, in vitro culture, potato, tuber formation.      

Distinct pathways for the early recruitment of myosin II and actin to the cytokinetic furrow

Equatorial organization of myosin II and actin has been recognized as a universal event in cytokinesis of animal cells. Current models for the formation of equatorial cortex favor either directional cortical transport toward the equator or localized de novo assembly. However, this process has never been analyzed directly in dividing mammalian cells at a high resolution. Here we applied total internal reflection fluorescence microscope (TIRF-M), coupled with spatial temporal image correlation spectroscopy (STICS) and a new analytical approach termed temporal differential microscopy (TDM), to image the dynamics of myosin II and actin during the assembly of equatorial cortex. Our results indicated distinct and at least partially independent mechanisms for the early equatorial recruitment of myosin and actin filaments. Cortical myosin showed no detectable directional flow during early cytokinesis. In addition to equatorial assembly, we showed that localized inhibition of disassembly contributed to the formation of the equatorial myosin band. In contrast to myosin, actin filaments underwent a striking flux toward the equator. Myosin motor activity was required for the actin flux, but not for actin concentration in the furrow, suggesting that there was a flux-independent, de novo mechanism for actin recruitment along the equator. Our results indicate that cytokinesis involves signals that regulate both assembly and disassembly activities and argue against mechanisms that are coupled to global cortical movements.     

Differential treatment ofAcetabularia with cytochalasin B and N-Ethylmaleimide with special reference to their effects on cytoplasmic streaming

Summary Cytoplasmic streaming in the stalk ofAcetabularia, ryukyuensis at the vegetative stage was reversibly inhibited by cytochalasin B (cB) of 50 g/ml and irreversibly by N-Ethylmaleimide (NEM) above concentrations of 0.25 mM.After the endoplasm and the chloroplasts were pushed forward one end of the stalk by gentle centrifugation at about 500 × g for 3 minutes, numerous ectoplasmic striations remainedin situ in the stalk cortex. The striations ran in parallel with the longitudinal axis of the stalk at unequal intervals. The endoplasm streamed back only along these striations.By combining centrifugation and a double chamber technique, the endoplasm and the cortex of the stalk were treated separately with CB or NEM. CB treatment of the cortex arrested streaming; when treatment was restricted to the endoplasm, streaming continued at an normal rate. NEM treatment restricted to the cortex permitted normal streaming rates. Treatment restricted to the moving endoplasm inhibited streaming.These results suggest that microfilaments and a moiety, possibly myosin, play an active role in the streaming. Microfilaments must reside in the cortex, especially in the ectoplasmic striations, while the putative myosin must reside in the moving endoplasm.