仙鹤藓属（Atrichum）藓类植物组织培养再生体系的建立

报道了仙鹤藓（Atrichum undulatum(Hedw.)P.Beauv.)和仙鹤藓小形变种（Atrichum undulatum var.minus(Hedw.)Par.)的组织培养再生体系的建立。为研究仙鹤藓属（Atrichum)藓类愈伤组织的诱导和再分化,将仙鹤藓和仙鹤藓小形变种原丝体接种在含有4%葡萄糖和0.2-2.0mg/L 6-BA的MS培养基上,培养一个月后,成功地诱导出疏松、易碎的绿色愈伤组织。愈伤组织诱导和常规继代培养较适合的培养基为含4%葡萄糖和1-2mg/L 6-BA的MS培养基。当将继代培养5次的脱分化藓类愈伤组织转移到含4%葡萄糖但无任何激素的MS培养基上时,能再分化形成原丝体,而在无任何碳源的Benecke培养基土培养时,能再分化形成经原丝体阶段发育来的直立配子体。     

石生南亚毛灰藓在不同温度和干旱条件下的生理生化特性

通过模拟高温和干旱处理,对喀斯特石漠化生境中南亚毛灰藓(Homomallium simlaense(Mitt.)Broth.Mitt)在胁迫条件下生理特征的变化进行了研究。结果表明,南亚毛灰藓在高温和干旱条件下,各项生理指标均与相对含水量呈显著正相关;丙二醛、渗透调节物质和叶绿素含量均随处理时间的增加和含水量的降低而减少,但植株仍保持较高的可溶性糖含量以维持渗透压的平衡。在极端干旱和高温的条件下,南亚毛灰藓可通过降低生理活性,保持一定的可溶性糖含量度过胁迫期,同时丙二醛含量保持最低状态。高温和干旱处理结束后,进行复水处理,植株的渗透调节物质和丙二醛含量显著升高,光合作用迅速恢复。研究结果表明,南亚毛灰藓适应干旱和高温的极端条件可能与丙二醛含量有关,但复水结束后丙二醛含量升高,胁迫反而增强,说明南亚毛灰藓对高温和干旱具有一定耐受性,原因可能与其长期生存于喀斯特的石生环境有关。     

仙鹤藓属(Atrichum)藓类植物组织培养再生体系的建立

报道了仙鹤藓(Atrichum undulatum(Hedw.)P.Beauv.)和仙鹤藓小形变种(Atrichum undulatum var.minus(Hedw.)Par.)的组织培养再生体系的建立.为研究仙鹤藓属(Atrichum)藓类愈伤组织的诱导和再分化,将仙鹤鲜和仙鹤藓小形变种原丝体接种在含有4%葡萄糖和0.2～2.0 mg/L 6-BA的MS培养基上,培养一个月后,成功地诱导出疏松、易碎的绿色愈伤组织.愈伤组织诱导和常规继代培养较适合的培养基为含4%葡萄糖和1～2 mg/L6-BA的MS培养基.当将继代培养5次的脱分化藓类愈伤组织转移到含4%葡萄糖但无任何激素的MS培养基上时,能再分化形成原丝体,而在无任何碳源的Benecke培养基上培养时,能再分化形成经原丝体阶段发育来的直立配子体.     

Bacillus subtilis fmbJ脂肽类抗菌物质的分离和鉴定

对Bacillus subtilis fmbJ脂肽类抗菌物质的分离和鉴定进行了系统研究。通过HPLC层析确定Bacillus subtilis fmbJ抗菌物质由多种组分构成,其中含有保留时间与surfactin相似的成分。通过TLC层析和原位酸解确定Bacillus subtilis fmbJ抗菌物质含有两个具有闭合肽键类的物质,其中之一为迁移率Rf与标样surfactin非常相近的组分。通过 ESIMS分析检测到Bacillus subtilis fmbJ抗菌物质含有分子量与fengicin相同的m/z1449.9、m/z1463.8、m/z1477.8、m/z1491.9和m/z1505.9五种同系物,和分子量与surfactin相同的m/z1008.8、m/z1022.8和m/z1036.8三种同系物。     

绵羊胎儿成纤维细胞不同处理对核移植重构胚发育的影响

研究供体细胞代数、大小、周期以及基因转染处理对重构胚发育的影响. 结果如下: (i)体外培养5~7代细胞做供体核, 重构胚的桑椹/囊胚率显著高于16~18代细胞的桑椹/囊胚率(17.3% vs. 4.9%, P < 0.05); (ii) 15~25 μm细胞做供体核, 重构胚的桑椹/囊胚率为20.0%, 高于8~15 mm细胞、25~33 μm细胞桑椹/囊胚率(8.0%, 9.7%), 但效果不显著(P > 0.05); (iii) 血清饥饿与非血清饥饿的细胞做供体核, 重构胚的桑椹/囊胚发育率没有显著性差异(11.8% vs. 18.6%, P > 0.05), 但非血清饥饿的效果要好于血清饥饿; (iv) 用0.05 μmol/L秋水仙素处理供体细胞效果最好, 重构胚的桑椹/囊胚率可达27.5%, 而未处理或用0.1 μmol/L秋水仙素处理供体细胞, 重构胚的桑椹/囊胚率分别为17.1%和12.1%, 但三者之间差异不显著(P > 0.05); (v) 以转染绿色荧光蛋白基因(GFP)细胞做供体核, 重构胚的桑椹/囊胚率显著低于非转基因细胞做供体核的桑椹/囊胚率(3.1% vs. 20.4%, P < 0.05). 上述结果表明, 传代少、中等大小的细胞更适合做供体核; 血清饥饿没有必要; 用0.05 μmol/L秋水仙素处理供体细胞有利于重构胚的发育; 转基因供体细胞对重构胚发育有影响.     

干旱胁迫与复水过程中遮光对细叶小羽藓的生理生化影响

以细叶小羽藓为试材,分别设置全光照、遮光30％、遮光50％和遮光70％条件,采用人工控水方法研究了干旱胁迫与复水过程中细叶小羽藓的质膜透性、渗透调节能力及抗氧化酶系统的变化.结果表明:于旱胁迫过程中,细叶小羽藓的相对含水量呈下降趋势,而相对电导率在干旱21 d时达到最大值,且全光照下的相对电导率最高(58.0％);可溶性糖和游离脯氨酸含量均先上升后下降;超氧化物歧化酶(SOD)和过氧化物酶(POD)活性先持续上升而后下降.在复水过程中,细叶小羽藓的相对含水量与干旱胁迫时相反;相对电导率、可溶性糖含量、游离脯氨酸含量、SOD和POD活性先小幅回升后逐渐下降,但SOD和POD活性仍较高;复水后大部分指标都恢复到干旱胁迫前水平.细叶小羽藓具备复苏植物的典型特征,在变水过程中有较强的抗旱能力.     

一氧化氮对增强的UV_B胁迫下螺旋藻生物损伤的减缓作用

为了探讨一氧化氮对增强的UV_B胁迫下螺旋藻生物学特性的影响,通过色素含量、蛋白质含量和生物量3个方面的变化证实了05mmol/L的一氧化氮(Nitric oxide, NO)供体硝普钠(Sodium nitroprusside, SNP)对增强UV_B胁迫下的螺旋藻(Spirulina platensis)794细胞生物损伤有明显的减缓作用。实验结果显示,NO能够显著诱导增强的UV_B胁迫下螺旋藻细胞内蛋白质含量、脯氨酸含量的提高,促进正常生长条件下螺旋藻(Spirulina platensis)794细胞内抗氧化物质GSH含量的增多,但外源NO又可以降低增强UV_B胁迫下螺旋藻细胞中GSH含量的增加。说明NO对增强UV_B胁迫下的螺旋藻794细胞有保护作用,可以减轻UV_B胁迫对螺旋藻(S. platensis)细胞引起的生物损伤。首次研究报道了增强UV_B胁迫下NO信号分子对蓝细菌——螺旋藻细胞生物损伤调节能力的影响,为进一步探讨NO信号及其与其它信号分子之间相互作用、相互关联来调节细胞的生理生化过程,以减缓UV_B胁迫下的生物损伤机理奠定了基础。     

极端干旱条件下杠柳的落叶相对休眠-复水复苏型生存策略

以3种梯度恒定干旱胁迫(土壤水分分别控制在最大田间持水量的80%、55%和35%)为对照,人工模拟持续自然干旱(干旱15~54 d后复水),研究黄土丘陵区广泛分布的乡土灌木杠柳(Periploca sepium)的形态、耗水、生长、生理在持续干旱、极端干旱以及旱后复水时的变化,探讨长期恒定胁迫及极端干旱下植物的适应性策略。结果表明:(1)在恒定干旱胁迫下,杠柳可调整生长和生理状况使其达到适应有限水分供应的新稳定状态;植株冠层减小,叶片可溶性糖积累以及过氧化物酶活性升高是杠柳适应长期恒定干旱胁迫的重要机制。(2)在长期自然干旱胁迫下,杠柳的形态与生理状况均持续变化。在叶片死亡脱落前,叶片中大量积累的脯氨酸、游离氨基酸和可溶性糖提高了杠柳对干旱胁迫的耐受性;随着干旱胁迫的加剧,杠柳叶片加速衰老死亡、以休眠芽形式进入相对休眠状态。(3)复水后根系和茎复苏长出新芽并补偿生长,新芽中高含量的脯氨酸和游离氨基酸以及高活性状态的SOD和POD表明新芽活跃的生理状态是其补偿生长的重要机制,即杠柳在极端干旱条件下具有落叶相对休眠-复水后复苏型生存策略。     

转修饰cry1Ac基因籼稻明恢81经花药培养获得抗虫DH系

对基因枪法获得的明恢81转修饰的cry1Ac基因当代植株进行花药培养,共接种花药2600枚,获得83份花培植株,其中双倍体植株43份,单倍体植株40份。 PCR结果表明含有cry1Ac基因的植株55份,花培植株群体中转基因与非转基因植株的比值为2∶1（55/28）。进一步结合Southern blot和ELISA分析,于花培植株当代筛选到转基因纯合株系36份。外源蛋白表达量上,花药来源于同一克隆的DH系的不同植株之间基本一致,最高的Cry1Ac含量达0.25%。田间抗虫性试验表明,经花药培养纯合获得的部分转基因纯合系植株对二化螟(Chilo suppressalis)表现出高抗,而且主要农艺性状保持不变。以上结果表明水稻花药培养可以加速转基因的纯合与育种利用。     

旱后复水对东亚砂藓生理生化指标的影响

对经长期干旱的东亚砂藓（Racomitrium japonicum）材料按不同时间梯度复水处理,并测定游离脯氨酸含量、可溶性蛋白含量、超氧化物歧化酶（SOD）活性和过氧化物酶（POD）活性等4项生理指标。结果表明,经长期干旱的东亚砂藓4项生理指标在复水后2d内恢复到对照水平,而在复水过程中变化趋势有所不同：可溶性蛋白含量经长期干旱后在植物体内积累,SOD活性较高,在复水过程中与游离脯氨酸含量变化趋势一致,呈现升高后降低的波动状态恢复到对照水平;而游离脯氨酸含量和POD活性经长期干旱后和对照一致,在复水过程中POD活性迅速升高而后很快恢复到对照水平。这4种生理指标从一定程度上反应了耐旱东亚砂藓具有不同于其它植物的旱后复水的特殊生理机制。     

Heat stress affects the organization of microtubules and cell division in Nicotiana tabacum cells

To investigate the effects of heat stress on the plant cytoskeleton, the structure of microtubule arrays in N. tabacum suspension cells incubated at 38 or 42°C was analysed. Whilst incubation at 42 °C resulted in the disruption of the majority of cellular microtubules after 30 min, in cells exposed to 38 °C all the microtubule arrays were preserved even after 12 h of incubation, although their organization was altered. The most susceptible were the microtubules of the mitotic spindle and the phragmoplast. Several abnormalities were observed: (i) splitting of the spindle into several parts; (ii) elongation of the spindles; (iii) formation of microtubule asters in mitotic cells, and (iv) elongation of phragmoplast microtubules. Exposure of cells to 38 °C caused a decrease in the mitotic index but an accumulation of telophase cells. The recovery of normal microtubule organization occurred after 12 h. Treatment of the cells subjected to heat stress conditions with an inhibitor of protein synthesis, cycloheximide, did not prevent either the alterations of microtubule organization or accumulation of cells containing phragmoplasts. Therefore, heat shock proteins do not seem to be directly responsible for the microtubule disorganization induced by heat stress.     

Effects of de- and rehydration on food-conducting cells in the moss Polytrichum formosum: a cytological study

BACKGROUND AND AIMS: Moss food-conducting cells (leptoids and specialized parenchyma cells) have a highly distinctive cytology characterized by a polarized cytoplasmic organization and longitudinal alignment of plastids, mitochondria, endoplasmic reticulum and vesicles along endoplasmic microtubules. Previous studies on the desiccation biology of mosses have focused almost exclusively on photosynthetic tissues; the effects of desiccation on food-conducting cells are unknown. Reported here is a cytological study of the effects of de- and rehydration on food-conducting cells in the desiccation-tolerant moss Polytrichum formosum aimed at exploring whether the remarkable subcellular organization of these cells is related to the ability of mosses to survive desiccation. METHODS: Shoots of Polytrichum formosum were dehydrated under natural conditions and prepared for transmission and scanning electron microscopy using both standard and anhydrous chemical fixation protocols. Replicate samples were then fixed at intervals over a 24-h period following rehydration in either water or in a 10 microM solution of the microtubule-disrupting drug oryzalin. KEY RESULTS: Desiccation causes dramatic changes; the endoplasmic microtubules disappear; the nucleus, mitochondria and plastids become rounded and the longitudinal alignment of the organelles is lost, though cytoplasmic polarity is in part retained. Prominent stacks of endoplasmic reticulum, typical of the hydrated condition, are replaced with membranous tubules arranged at right angles to the main cellular axis. The internal cytoplasm becomes filled with small vacuoles and the plasmalemma forms labyrinthine tubular extensions outlining newly deposited ingrowths of cell wall material. Whereas plasmodesmata in meristematic cells at the shoot apex and in stem parenchyma cells appear to be unaffected by dehydration, those in leptoids become plugged with electron-opaque material. Starch deposits in parenchyma cells adjoining leptoids are depleted in desiccated plants. Rehydration sees complete reestablishment over a 12- to 24-h period of the cytology seen in the control plants. Oryzalin effectively prevents leptoid recovery. CONCLUSIONS: The results point to a key role of the microtubular cytoskeleton in the rapid re-establishment of the elaborate cytoplasmic architecture of leptoids during rehydration. The reassembly of the endoplasmic microtubule system appears to dictate the time frame for the recovery process. The failure of leptoids to recover normal cytology in the presence of oryzalin further underlines the key role of the microtubules in the control of leptoid cytological organization.     

Effect of microtubule stabilization on the freezing tolerance of mesophyll cells of spinach

Freezing, dehydration, and supercooling cause microtubules in mesophyll cells of spinach (Spinacia oleracea L. cv Bloomsdale) to depolymerize (ME Bartolo, JV Carter, Plant Physiol [1991] 97: 175-181). The objective of this study was to determine whether the LT₅₀ (lethal temperature: the freezing temperature at which 50% of the tissue is killed) of spinach leaf tissue can be changed by diminishing the extent of microtubule depolymerization in response to freezing. Also examined was how tolerance to the components of extracellular freezing, low temperature and dehydration, is affected by microtubule stabilization. Leaf sections of nonacclimated and cold-acclimated spinach were treated with 20 micromolar taxol, a microtubule-stabilizing compound, prior to freezing, supercooling, or dehydration. Taxol stabilized microtubules against depolymerization in cells subjected to these stresses. When pretreated with taxol both nonacclimated and cold-acclimated cells exhibited increased injury during freezing and dehydration. In contrast, supercooling did not injure cells with taxol-stabilized microtubules. Electrolyte leakage, visual appearance of the cells, or a microtubule repolymerization assay were used to assess injury. As leaves were cold-acclimated beyond the normal period of 2 weeks taxol had less of an effect on cell survival during freezing. In leaves acclimated for up to 2 weeks, stabilizing microtubules with taxol resulted in death at a higher freezing temperature. At certain stages of cold acclimation, it appears that if microtubule depolymerization does not occur during a freeze-thaw cycle the plant cell will be killed at a higher temperature than if microtubule depolymerization proceeds normally. An alternative explanation of these results is that taxol may generate abnormal microtubules, and connections between microtubules and the plasma membrane, such that normal cellular responses to freeze-induced dehydration and subsequent rehydration are blocked, with resultant enhanced freezing injury.     

Effects of colchicine and amiprophos-methyl on microfibril arrangement and cell shape inAdiantum protonemal cells

Summary 5 mM colchicine and 1 g/ml amiprophos-methyl, known antimicrotubule agents, were applied to fernAdiantum protonemata under red light. Both drugs caused microtubule disruption and subsequent apical swelling of protonemal cells after certain lag periods. While the lag periods for the onset of microtubule disruption after application of the two drugs were different (within 15 minutes in amiprophos-methyl, 1 hour in colchicine), the lag periods of apical swelling after microtubule disruption were nearly the same (approx. 70 minutes). The results suggest that the apical swelling is a consequence of microtubule disruption.In cells examined 1 hour after microtubule disruption by either drug, the microfibril arrangement of the innermost layer of the cell wall was random at the tip, transverse in the subapical region, and roughly longitudinal in the cylindrical region. This pattern of microfibrils was similar to that of untreated cells in which the microtubules show a similar arrangement (Murata and Wada 1989). Surprisingly, even after approx. 4 hours of microtubule disruption, when apical swelling had occurred in most cells, the pattern of microfibril deposition was not altered. The role of microtubules in oriented microfibril deposition and the mechanism of control of cell shape are discussed.Abbreviations APM amiprophos-methyl - DMSO dimethylsulfoxide - MT(s) microtubule(s) - PBS phosphate buffered saline     

Visualization of assembled and disassembled microtubule protein by double label fluorescence microscopy

Indirect immunofluorescence with rhodamine labelled antibodies and fluoresceinated colchicine (FC) are used to simultaneously localize microtubules and soluble tubulin in cultured ovarian granulosa cells. FC labelled tubulin is most concentrated in regions of the cell occupied by antitubulin stained microtubule bundles. Pretreatment of granulosa cells with colchicine results in a central accumulation of FC and antibody labelled tubulin that coincides with the disposition of 10-nm filament cables. In contrast, the microtubule disrupting agent nocodazole produces a diffuse tubulin distribution as detected with both FC and antibody probes. Taxol treatment, which enhances microtubule assembly, results in a striking concentration of microtubule bundles associated with the nucleus that avidly bind FC. These results suggest that disassembled tubulin is preferentially associated with cytoplasmic microtubules and possibly other formed elements of the cytoskeleton.     

Membrane Organization of the Desiccation-Tolerant Moss Tortula ruralis in Dehydrated States

Membrane organization of the desiccation tolerant moss Tortula ruralis was studied in several intensely dehydrated states (75% relative humidity [RH], 90% RH, plasmolysis in molar salt, freezing to −20°C) by ³¹P nuclear magnetic resonance and ultrastructural analyses. Both methods revealed that even at 75% RH (−400 bars), the moss cellular membranes retained extended phospholipid bilayers. Ultrastructural analyses of the fully hydrated moss showed an extensive proliferation of membrane vesicles in the endoplasmic reticulum. During dehydration, these vesicles form layers of membrane under the plasmalemma and in some cases appear to fuse with the surface membrane. This suggests that these vesicles may serve as a reservoir of membranes to accommodate for membrane surface area changes during desiccation and subsequent rehydration.     

Circular arrangement of cortical microtubules around the subapical part of a tip-growing fern protonema

Summary Cortical microtubule arrays in tip-growing protonemal and rhizoid cells of the fernAdiantum gametophytes were observed by immunofluorescence microscopy. A circular arrangement of cortical microtubules was demonstrated around the subapical part of protonemal cells growing under red light conditions. However, such an arrangement was not found in growing rhizoids either by immunofluorescence microscopy or by electron microscopy. The different patterns of microtubule arrays around the apices of tip-growing protonemal and rhizoid cells suggest the possible existence of different mechanisms in regulating the cell diameter in the two types of cylindrical cell.     

Desiccation sensitivity and tolerance in the moss <Emphasis Type="Italic">Physcomitrella patens</Emphasis>: assessing limits and damage

The moss Physcomitrella patens is becoming the model of choice for functional genomic studies at the cellular level. Studies report that Physcomitrella survives moderate osmotic and salt stress, and that desiccation tolerance can be induced by exogenous ABA. Our goal was to quantify the extent of dehydration tolerance in wild type moss and to examine the nature of cellular damage caused by desiccation. We exposed Physcomitrella to humidities that generate water potentials from −4 (97% RH) to −273 MPa (13% RH) and monitored water loss until equilibrium. Water contents were measured on a dry matter basis to determine the extent of dehydration because fresh weights (FW) were found to be variable and, therefore, unreliable. We measured electrolyte leakage from rehydrating moss, assessed overall regrowth, and imaged cells to evaluate their response to drying and rehydration. Physcomitrella did not routinely survive water potentials <−13 MPa. Upon rehydration, moss dried to water contents >0.4 g g dm⁻¹ maintained levels of leakage similar to those of hydrated controls. Moss dried to lower water contents leaked extensively, suggesting that plasma membranes were damaged. Moss protonemal cells were shrunken and their walls twisted, even at −13 MPa. Moss cells rehydrated after drying to −273 MPa failed to re-expand completely, again indicating membrane damage. ABA treatment elicited tolerance of desiccation to at least −273 MPa and limited membrane damage. Results of this work will form the basis for ongoing studies on the functional genomics of desiccation tolerance at the cellular level.     

Modulation of the expression of connective tissue growth factor by alterations of the cytoskeleton

Modulation of the cytoskeletal architecture was shown to regulate the expression of CTGF (connective tissue growth factor, CCN2). The microtubule disrupting agents nocodazole and colchicine strongly up-regulated CTGF expression, which was prevented upon stabilization of the microtubules by paclitaxel. As a consequence of microtubule disruption, RhoA was activated and the actin stress fibers were stabilized. Both effects were related to CTGF induction. Overexpression of constitutively active RhoA induced CTGF synthesis. Interference with RhoA signaling by simvastatin, toxinB, C3 toxin, and Y27632 prevented up-regulation of CTGF. Likewise, direct disintegration of the actin cytoskeleton by latrunculin B interfered with nocodazole-mediated up-regulation of CTGF expression. Disassembly of actin fibers by cytochalasin D, however, unexpectedly increased CTGF expression indicating that the content of F-actin per se was not the major determinant for CTGF gene expression. Given the fact that cytochalasin D sequesters G-actin, a decrease in G-actin increased CTGF, while increased levels of G-actin corresponded to reduced CTGF expression. These data link alterations in the microtubule and actin cytoskeleton to the expression of CTGF and provide a molecular basis for the observation that CTGF is up-regulated in cells exposed to mechanical stress.