Effects of microfilament disrupters on microfilament distribution and morphology in maize root cells

Maize root tip cells were examined for the distribution of actin microfilaments in various cell types and to determine the effects of microfilament disrupters. Fluorescence microscopy on fixed, stabilized, squashed cells using the F-actin specific probe, rhodamine-labelled phalloidin, allowed for a three-dimensional visualization of actin microfilaments. Microfilaments were observed as long, meandering structures in root cap cells and meristematic cells, while those in immature vascular parenchyma were abundant in the thin band of cytoplasm and were long and less curved. By modifying standard electron microscopic fixation procedures, microfilaments in plant cells could be easily detected in all cell types. Treatment with cytochalasin B, cytochalasin D and lead acetate, compounds that interfere with microfilament related processes, re-organized the microfilaments into abnormal crossed and highly condensed masses. All the treatments affected not only the microfilaments but also the accumulation of secretory vesicles. The vivid demonstration of the effects of all of these microfilament disrupters on the number and size of Golgi vesicles indicates that these vesicles may depend on microfilaments for intracellular movement.     

Effects of bunaftine on morphology,microfilament integrity,and mitotic activity in cultured human fibroblasts and HeLa cells

Summary Human fibroblasts and HeLa cells were treated with bunaftine (N-butyl-N-/2-(diethylamino)ethyl/-1-naphthalenecarboxamide) in vitro. At concentrations of 0.5–2.0 mM, the drug caused contraction and rounding of the cells with loss of microvilli-like processes. Aggregates of dense, partly granular, partly fibrillar material formed in the cytoplasm and the rough endoplasmic reticulum became vesiculated. Immunofiuorescence microscopy with DNase I and anti-DNase I demonstrated that bundles of actin filaments were disrupted, forming rings, coils, and granules. Filaments stained with antibodies to vimentin (fibroblasts) and prekeratin (HeLa cells) showed less characteristic rearrangements, probably related to the rounding up of the cells. 0.4 mM bunaftine increased and 0.8–1.0 mM markedly decreased the percentage of mitotic cells, without accumulation of cells in any particular stage of mitosis. The drug may arrest the cell cycle at some point before mitosis; it may have a critical concentration above which the arrest becomes permanent.These results suggest that bunaftine interferes with the integrity of microfilament bundles in a different manner from that of cytochalasins. It does not cause any depletion of cellular ATP, indicating that its effect is not a result of inhibition of cell metabolism. It is proposed that bunaftine may be used as a complement to cytochalasins in studies of the microfilament system of the cell. The possible binding of bunaftine to actin or myosin and further details of its mechanism of action remain to be elucidated.     

玉米根分布模拟方法比较

根分布是陆面过程模型中模拟根系吸水过程的重要参数,对其准确表达将可改善水热通量的模拟。利用已有研究中玉米不同发育期根生物量实测资料,对常用于现有主流陆面过程模型中分别由Schenk、Zeng和Jackson建立的3种根分布参数化方案(被定义为M1、M2、M3)的模拟精度进行比较。结果表明:M2和M3模拟精度基本一致,仅在玉米吐丝期以后模拟精度较高,而M1能够对玉米不同发育期根分布进行较高精度的模拟,是3方案中的最优方案;通过对M1方案中玉米不同发育期d50和d95(累积根比例分别为50%和95%的土层深度)2个参数拟合值分析发现,d95值随玉米生育进程逐渐增大,变异性在拔节和成熟期最大,在吐丝期最小;d50值在大喇叭口期以前随生育进程增大,在吐丝期以后趋于稳定;d50和d95值在大喇叭口期以前与现有模型设定值差异最大,可引起陆面过程模拟的误差。     

水分胁迫下秸秆还田对玉米产量和根系空间分布的影响

为了探究水分胁迫条件下秸秆还田对玉米产量和根系空间分布的影响,自2016年起连续2年在沈阳农业大学试验田设置了秸秆还田控水试验.于大型遮雨棚内采用滴灌控水的方法,设置行间秸秆翻埋(T₁)与混拌(T₂)两种还田方式,15 cm (D₁)、30 cm (D₂)、45 cm (D₃) 3个还田深度,以秸秆不还田3个翻埋深度为对照,在玉米苗期和吐丝期分别进行旱、涝处理,分析水分胁迫条件下玉米产量和根系空间分布特征. 结果表明: 2016年S₁T₁D₂(秸秆翻埋还田30 cm)产量显著高于对照处理,增产幅度为5.7%～7.1%;侧根和深层根系根干质量较其他处理分别高67.3%～149.9%和17.9%～116.4%;植株地上部干物质积累量显著低于其他处理,降低幅度为2.1%～35.8%. S₁T₁D₂可以提高玉米根系生长量,扩展根长的空间分布范围,缓解了旱涝危害,实现降雨不均条件下的增产和稳产. 因此,在东北地区先旱后涝的气候条件下,春玉米生产推荐行间翻埋30 cm的秸秆还田方式.     

Endocytosis in maize root cap cells

Summary Primary roots of maize seedlings have been treated with solutions of lanthanum and lead salts in an attempt to demonstrate endocytosis. Subsurface cells in the root cap reveal deposits of these heavy metals in coated pits in the plasma membrane and in coated vesicles. In addition lead deposits were observed in coated evaginations (pits) on large (secretory) vesicles present at the trans-pole of the Golgi apparatus and on small vacuoles. Lead was also found in the peripheral regions of individual cisternae throughout the dictyosomal stack. We interpret our results as providing evidence for coated pit/coated vesicle-mediated endocytosis and for the direct recycling of plasma membrane to the Golgi apparatus.     

Cyclic amp and cell morphology in cultured fibroblasts. Effects on cell shape, microfilament and microtubule distribution, and orientation to substratum

The change in shape of 3T3 and L929 cells due to Bt2cAMP treatment is accompanied by altered intracellular distribution of microfilaments and microtubules. Bt2cAMP added to cells in low density culture causes (a) microfilaments to accumulate in bundles near the plasma membrane, mainly at the cell periphery, and (b) microtubules to accumulate beneath these microfilament bundles. In narrow cell processes that form characteristically in Bt2cAMP-treated L cells, microtubules accumulate in parallel arrays near the center of these processes. A new simple method for evaluating the relative distance of the cell from its underlying substratum is desribed. In normal medium, 3T3 cells attach to their substratum near the nucleus and at the tips of cell processes, bridging irregularities in the plastic surface. With Bt2cAMP treatment, attachment occurs at the cell edge and at many isolated points under the cytoplasm, and the cells conform more closely to irregularities of the underlying substratum. A model of the mechanism by which cAMP modulates cell shape is presented.     

Abscisic acid distribution in horizontal maize root segments

Using gas chromatography-mass spectrometry (GC/MS) techniques of analyses, it has been found that endogenous abscisic acid (ABA) becomes asymmetrically distributed in the elongation zone of horizontal Zea mays (cv. LG 11) roots which are showing a positive gravitropic response. There is a relative increase in the ABA content of the lower half and a concomitant decrease for the upper half in such roots. Asymmetric distribution of ABA is also detected in the elongation zone of half-decapped roots.Abbreviations IAA indoleacetic acid - ABA abscisic acid - GC/MS gas chromatography-mass spectrometry     

Localization of intracellular calcium in root meristematic cells and root cap cells of maize

The localization of Ca²⁺ in cells of the periblem and dermatogen in the root meristem and the columella and peripheral cells of the root cap of maize was examined by the precipitation method of potassium pyroantimonate and EGTA-treatment. In periblem and dermatogen cells, Ca²⁺ was found to be localized in the nucleoplasm and granular zone of the nucleolus. Ca²⁺ was also found in most cell organelles: in the matrix in mitochondria, on the thylakoid membrane in proplastids, in the vacuoles and on the plasma membranes. Ca²⁺ was also distributed throughout the cytoplasmic ground matrix. Much Ca²⁺ was present in the cell wall soon after its formation during the cell division. Ca²⁺ was also conspicuous in the vesicles of Golgi in the dermatogen cells. In columella and peripheral cells, there was less Ca²⁺ in the organelles and cytoplasmic ground matrix, but Ca²⁺ was present in Golgi vesicles in the peripheral cells. Electron microscopic and X-ray microanalysis showed that Ca²⁺ was also present in the mucilaginous layer, the outermost cell wall of the peripheral cells.     

Mastoparan alters subcellular distribution of profilin and remodels F-actin cytoskeleton in cells of maize root apices

Indirect immunofluorescence localization of profilin in cells of maize root apices revealed that this abundant protein was present both in the cytoplasm and within nuclei. Nucleo-cytoplasmic partitioning of profilin exhibits tissue-specific and developmental features. Mastoparan-mediated activation of heterotrimeric G-proteins, presumably through triggering a phosphoinositide-signaling pathway based on phosphatidylinositol-4,5-bisphosphate (PIP(2)), induced relocalization of profilin from nuclei into the cytoplasm of root apex cells. In contrast, PIP(2) accumulated within nuclei of mastoparan-treated root cells. Intriguingly, cytoplasmic accumulation of profilin was associated with remodeling of F-actin arrays in root apex cells. Specifically, dense F-actin networks were dismantled and distinct actin patches became associated with the periphery of small vacuoles. On the other hand, disruption of F-actin with the G-actin sequestering agent latrunculin B does not affect the subcellular distribution of profilin or PIP(2). These data suggest that nuclear profilin can mediate a stimulus-response action on the actin cytoskeleton which is somehow linked to a phosphoinositide-signaling cascade.     

Cadmium,nickel, copper,and zinc influence on microfilament organization in Arabidopsis root cells

The plant cytoskeleton orchestrates such fundamental processes in cells as division, growth and development, polymer cross-linking, membrane anchorage, etc. Here, we describe the influence of Cd²⁺, Ni²⁺, Zn²⁺, and Cu²⁺ on root development and vital organization of actin filaments into different cells of Arabidopsis thaliana line expressing GFP-FABD2. CdSO₄, NiSO₄, CuSO₄, and ZnSO₄ were used in concentrations of 5–20 µM in this study. It was found that Cd, Ni, and Cu cause dose-dependent primary root growth inhibition and alteration of the root morphology, whereas Zn slightly stimulates root growth and does not affect the morphology of Arabidopsis roots. This growth inhibition/stimulation correlated with the various sensitivities of microfilaments to Cd, Ni, Cu, and Zn action. It was established that Cd, Ni, and Cu affected predominantly the actin filaments of meristematic cells. Cells of transition and elongation zones demonstrated strong actin filament sensitivity to Cd and Cu. Microfilaments of elongating root cells were more sensitive to Ni and Cu. Although Cd, Ni, and Cu stimulated root hair growth after long-term treatment, actin filaments were destroyed after 1 h exposure with these metals. Zn did not disrupt native actin filament organization in root cells. Thus, our investigation shows that microfilaments act as sensitive cellular targets for Cd, Ni, and Cu. More data on effects on native actin filaments organization would contribute to a better understanding of plant tolerance mechanisms to the action of these metals.     

Cadmium induces acidosis in maize root cells

* Cadmium (Cd) stress increases cell metabolic demand for sulfur, reducing equivalents, and carbon skeletons, to sustain phytochelatin biosynthesis for Cd detoxification. In this condition the induction of potentially acidifying anaplerotic metabolism in root tissues may be expected. For these reasons the effects of Cd accumulation on anaplerotic metabolism, glycolysis, and cell pH control mechanisms were investigated in maize (Zea mays) roots. * The study compared root apical segments, excised from plants grown for 24 h in a nutrient solution supplemented, or not, with 10 microM CdCl(2), using physiological, biochemical and (31)P-nuclear magnetic resonance (NMR) approaches. * Cadmium exposure resulted in a significant decrease in both cytosolic and vacuolar pH of root cells and in a concomitant increase in the carbon fluxes through anaplerotic metabolism leading to malate biosynthesis, as suggested by changes in dark CO2 fixation, metabolite levels and enzyme activities along glycolysis, and mitochondrial alternative respiration capacity. This scenario was accompanied by a decrease in the net H(+) efflux from the roots, probably related to changes in plasma membrane permeability. * It is concluded that anaplerotic metabolism triggered by Cd detoxification processes might lead to an imbalance in H(+) production and consumption, and then to cell acidosis.     

玉米根系形态性状和空间分布对水分利用效率的调控

玉米根系形态性状(总根长、根系表面积和根系干物质重)与植物整体水分利用效率间具有显著或极显著的相关性,回归曲线趋势基本相同,均呈二次曲线关系,只是相关系数不同。说明从提高水分利用效率来说,根系需要维持适宜的大小。其中根长对水分利用效率的贡献是第一位的,而根系干物质重的贡献最小,根系表面积介于二者之间。从空间分布来说,玉米每层节根数、节根长度和直径在父母本和杂交种间也具有显著或极显著的差异。与中下层根量相比,母本与不抗旱的父本处于上层干土中的根系数量明显较多,且根系直径大,吸水困难。而杂交种在干旱条件下上层根重和数量维持不变,或略高于不抗旱品种,但中层和下层根系数量和长度明显高于不抗旱品种,且根系直径小于不抗旱品种,这样从多的有效根系数量和低的吸水阻力两方面保证了水分的吸收,从而使其产量和水分利用效率均最高,说明通过根系形态特性和空间分布的优化能够调节作物整体的水分利用效率。     

Altered cellular morphology and microfilament array in ataxia-telangiectasia fibroblasts

Cells derived from individuals with the ataxia-telangiectasia syndrome demonstrate a number of unusual properties. They are highly sensitive to the lethal effects of ionizing radiation and also fail to demonstrate the normal inhibition of DNA synthesis associated with this type of DNA-damaging agent. Additionally, a number of ataxia-telangiectasia lymphoblastoid lines have been shown to have an unusual regulation of the cellular actin levels. However, the primary lesion causing ataxia-telangiectasia is unknown. In this paper we report an altered cellular morphology in three ataxia-telangiectasia fibroblast lines, but not in a number of control fibroblast lines. Investigation of the cytoskeleton using antibodies against certain cytoskeletal proteins revealed a difference in the microfilament pattern from ataxia-telangiectasia fibroblasts compared to controls. Ataxia fibroblasts showed a microfilament stress fiber pattern that appeared to have a more well defined and abundant array of stress fibers than control fibroblasts. In contrast, no differences were observed in the microtubule array, nor in the vinculin patterns between any of the cell lines. In addition to the differences in the microfilament patterns, ataxia-telangiectasia fibroblasts differed in their ability to recover from microfilament disruption by dimethyl sulfoxide. Control fibroblasts returned to a normal cellular state in a shorter time compared to ataxia fibroblasts, as judged by indirect immunofluorescence using antiactin. These results provide further evidence for a cytoskeletal anomaly in ataxia-telangiectasia.     

Effects of fusaric acid on respiration in maize root mitochondria

The effects of fusaric acid, a phytotoxin produced byFusarium pathogens, on the metabolism of isolated maize root mitochondria and on maize seed germination and seedling growth were investigated. The phytotoxin inhibited basal and coupled respiration when succinate and α-ketoglutarate were the substrates. Coupled respiration dependent on NADH was inhibited, but basal respiration was not. Consistently, succinate cytochromec oxidoreductase activity was decreased whereas NADH cytochromec oxidoreductase was not affected. The ATPase activities of carbonyl cyanide p-trifluoro-methoxyphenyl hydrazone stimulated mitochondria and of freeze-thawing disrupted mitochondria were inhibited. These results indicate that the phytotoxin impairs the respiratory activity of maize mitochondria by at least three mechanisms: (1) it inhibits the flow of electrons between succinate dehydrogenase and coenzyme Q, (2) it inhibits ATPase/ATP-synthase activity and (3) it possibly inhibits α-ketoglutarate dehydrogenase. Seed germination and seedling growth were also affected by fusaric acid with the most pronounced effect on root development. These effects can possibly contribute to the diseases ofFusarium- infected plants     

Thyrotropin induces changes in the morphology and the organization of microfilament structures in cultured thyroid cells

Thyrotropin (TSH) induces morphological changes in cultures of normal rat thyroid cell lines and in primary bovine thyroid cells. It also induces a specific reorganization of the microfilaments of the thyroid cells. Both effects are fully reversible and are mimicked by 8-bromo-cAMP. These results indicate that the trophic response of TSH involves changes in the organization of the actin-containing filaments, probably mediated through cAMP, followed by changes in cell shape.     

The distribution of plasmodesmata in the root tip of maize

Summary The distribution of plasmodesmata in different regions of the root apex of Zea mays has been analysed from electron micrographs. There are many more plasmodesmata traversing transverse walls than across longitudinal walls in all the regions studied. When the number of plasmodesmata per unit cell volume is calculated, cells in non-dividing tissue have a considerably lower value than cells in dividing tissue. Evidence for the transport of materials between cells via plasmodesmata is summarised. If it is accepted that plasmodesmata do act as channels for intercellular communication then we believe that their pattern of distribution may be a contributory factor to the process of cell differentiation.     

Mapping genes controlling root morphology and root distribution in a doubled-haploid population of rice

 A deep thick root system has been demonstrated to have a positive effect on yield of upland rice under water stress conditions. Molecular-marker-aided selection could be helpful for the improvement of root morphological traits, which are otherwise difficult to score. We studied a doubled-haploid population of 105 lines derived from an indica×japonica cross and mapped the genes controlling root morphology and distribution (root thickness, maximum root length, total root weight, deep root weight, deep root weight per tiller, and deep root to shoot ratio). Most putative QTL activity was concentrated in fairly compact regions on chromosomes 1, 2, 3, 6, 7, 8 and 9, but was widely spread on chromosome 5 and largely absent on chromosomes 4, 10, 11 and 12. Between three and six QTLs were identified on different chromosomes for each trait. Individual QTLs accounted for between 4 and 22% of the variation in the traits. Multiple QTL models accounted for between 14 and 49%. The main QTLs were common between traits, showing that it should be possible to modify several aspects of root morphology simultaneously. There was evidence of interaction between marker locations in determining QTL expression. Interacting locations were mostly on different chromosomes and showed antagonistic effects with magnitudes large enough to mask QTL detection. The comparison of QTL locations with another population showed that one to three common QTLs per trait were recovered, among which the most significant was in one or other population. These results will allow the derivation of isogenic lines introgressed with these common segments, separately in the indica and japonica backgrounds. Received: 12 August 1996 / Accepted: 15 November 1996     

Mitochondrial morphology and distribution in mammalian cells

It is now appreciated that mitochondria form tubular networks that adapt to the requirements of the cell by undergoing changes in their shape through fission and fusion. Proper mitochondrial distribution also appears to be required for ATP delivery and calcium regulation, and, in some cases, for cell development. While we now realise the great importance of mitochondria for the cell, we are only beginning to work out how these organelles undergo the drastic morphological changes that are essential for cellular function. Of the few known components involved in shaping mitochondria, some have been found to be essential to life and their gene mutations are linked to neurological disorders, while others appear to be recruited in the activation of cell death pathways. Here we review our current understanding of the functions of the main players involved in mitochondrial fission, fusion and distribution in mammalian cells.