植物对硅的吸收转运机制研究进展

硅(Si)能缓解生物与非生物胁迫对植物的毒害作用,Si的吸收转运是由Si转运蛋白介导的.最近,多个Si转运蛋白(Lsi)基因相继在水稻、大麦和玉米中被克隆出来,并在Si的吸收转运机制方面取得了很大进展.水稻OsLsi在根组织中呈极性分布,OsLsi1定位在根外皮层和内皮层凯氏带细胞外侧质膜,负责将外部溶液中的单硅酸转运到皮层细胞内.OsLsi2定位在凯氏带细胞内侧质膜,在外皮层中负责将Si输出到通气组织质外体中,在内皮层与OsLsi1协同作用将Si转运到中柱中.导管中的Si通过蒸腾流转运到地上部,再由定位在叶鞘和叶片木质部薄壁细胞靠近导管一侧的OsLsi6负责木质部Si的卸载和分配.在大麦和玉米中,ZmLsi1/HvLsi1定位在根表皮和皮层细胞外侧质膜负责Si的吸收,然后Si通过共质体途径被转运到内皮层凯氏带细胞中,再由ZmLsi2/HvLsi2输出转运到中柱中.ZmLsi6在细胞中的定位和活性与OsLsi6相似,推测其可能具有类似的功能,但大麦Lsi6至今未见报道.所以,Si转运机制仍需要进一步研究.     

植物钙吸收、转运及代谢的生理和分子机制

钙是植物必需的营养元素。酸性砂质土壤中含钙较少,导致在其土壤上生长的作物容易缺钙。另外由于果树果实、果菜类和包心叶菜类的蒸腾作用弱,导致果树和蔬菜普遍生理缺钙。根系维管束组织可能通过共质体和质外体两种途径进行钙素吸收,而果实则可通过非维管束组织直接吸收钙素。Ca2 通过Ca2 通道内流进入胞质,并通过Ca2 -ATPase和Ca2 /H 反向转运蛋白外流以保持胞质内低Ca2 浓度。为了应对植物发育和环境胁迫信号,Ca2 由质膜、液泡膜和内质网膜的Ca2 通道内流进入胞质,导致胞质Ca2 浓度迅速增加,产生钙瞬变和钙振荡,传递到钙信号靶蛋白,如钙调素、钙依赖型蛋白激酶及钙调磷酸酶B类蛋白,引起特异的生理生化反应。本文综述了植物钙素吸收、转运以及代谢研究的最新进展,包括植物对钙的需求和作物缺钙的原因,根系维管束组织及果实钙素吸收机理,Ca2 跨膜运输特性,钙的信使作用以及钙信号靶蛋白等方面内容。     

灵武长枣果实同化物韧皮部卸载和运输途径研究

韧皮部卸载和韧皮部后运输在调节同化物在果实中的分配和积累方面起着至关重要的作用,而且很大程度上决定着果实的产量和质量。为探讨灵武长枣果实同化物韧皮部卸载和运输途径,以4个时期灵武长枣果实为实验材料,对各个发育时期果实维管束的显微结构进行观察,并综合运用荧光染料活细胞示踪与激光共聚焦扫描显微镜技术实时观察果实内韧皮部同化物卸载路径的变化,为灵武长枣果实同化物积累和品质调控奠定基础。结果显示：(1)膨大前期不仅果实的韧皮部中具有明显的CF绿色荧光,同时在周围薄壁细胞中也分布着CF绿色荧光,筛管伴胞复合体和周围薄壁细胞之间存在着共质体联系。(2)快速膨大期,CF绿色荧光主要局限于果实的韧皮部中,在韧皮部周围薄壁细胞中分布较少,筛管伴胞复合体与周围薄壁细胞之间主要以共质体隔离为主,但也存在着一定的共质体联系。(3)着色期和完熟期,CF绿色荧光局限于果实的韧皮部中,在韧皮部周围薄壁细胞中基本没有CF绿色荧光,果实筛管伴胞复合体与周围薄壁细胞之间是共质体隔离状态,但引入CFDA的同时引入具有质膜通透作用的洋地黄皂苷时,周围薄壁细胞中CF绿色荧光分布明显增加。研究认为,灵武长枣在膨大前期果实韧皮部同化物为共质体卸载途径,快速膨大期果实主要以质外体途径运输同化物,但也通过共质体卸出同化物,着色期和完熟期果实通过质外体途径运输同化物。     

植物钙吸收、转运及代谢的生理和分子机制

钙是植物必需的营养元素。酸性砂质土壤中含钙较少, 导致在其土壤上生长的作物容易缺钙。另外由于果树果实、果菜类和包心叶菜类的蒸腾作用弱, 导致果树和蔬菜普遍生理缺钙。根系维管束组织可能通过共质体和质外体两种途径进行钙素吸收, 而果实则可通过非维管束组织直接吸收钙素。Ca2+通过Ca2+通道内流进入胞质, 并通过Ca2+-ATPase 和Ca2+/H+反向转运蛋白外流以保持胞质内低Ca2+浓度。为了应对植物发育和环境胁迫信号, Ca2+由质膜、液泡膜和内质网膜的Ca2+通道内流进入胞质, 导致胞质Ca2+浓度迅速增加, 产生钙瞬变和钙振荡, 传递到钙信号靶蛋白, 如钙调素、钙依赖型蛋白激酶及钙调磷酸酶B类蛋白, 引起特异的生理生化反应。本文综述了植物钙素吸收、转运以及代谢研究的最新进展, 包括植物对钙的需求和作物缺钙的原因, 根系维管束组织及果实钙素吸收机理, Ca2+跨膜运输特性, 钙的信使作用以及钙信号靶蛋白等方面内容。     

重金属镉(Cd)在植物体内的转运途径及其调控机制

重金属镉(Cd)的毒害效应与其由土壤向植物地上部分运输有关,揭示Cd~(2+)转运途径及其调控机制可为提高植物抗镉性以及镉污染的植物修复提供依据。对Cd~(2+)在植物体内的转运途径,特别是限制Cd~(2+)移动的细胞结构和分子调控机制研究进展进行了回顾。Cd~(2+)通过共质体和质外体途径穿过根部皮层进入木质部的过程中,大部分在皮层细胞间沉积,少部分抵达中柱后转移到地上部分。为了免受Cd~(2+)的危害,植物体产生了多种限制Cd~(2+)吸收和转移的生理生化机制:1)环绕在内皮层径向壁和横向壁上的凯氏带阻止Cd~(2+)以质外体途径进入木质部;2)螯合剂与进入根的Cd~(2+)螯合形成稳定化合物并区隔在液泡中;3)通过H+/Cd~(2+)离子通道等将Cd~(2+)逆向转运出根部。植物共质体和质外体途径转运重金属镉的能力以及两条途径的串扰尚待进一步明晰和阐明。     

宁夏枸杞果实韧皮部及其周围细胞超微结构研究

应用透射电镜技术研究了宁夏枸杞果实韧皮部细胞的超微结构变化。结果表明:(1)随着枸杞果实的发育成熟,果实维管组织中的韧皮部筛分子筛域逐渐变宽,筛孔大而多,通过筛孔的物质运输十分活跃;筛分子和伴胞间有胞间连丝联系,伴胞属传递细胞类型,与其相邻韧皮薄壁细胞和果肉薄壁细胞连接处的细胞界面发生质膜内突,整个筛分子/伴胞复合体与韧皮薄壁细胞之间形成共质体隔离,韧皮部糖分的卸载方式主要以质外体途径进行。(2)韧皮薄壁细胞间的胞间连丝较多,而韧皮薄壁细胞与果肉薄壁细胞的胞间连丝相对较少,但果肉薄壁细胞间几乎无胞间连丝;果肉薄壁细胞之间胞间隙较大,细胞壁和质膜内突间形成较大的质外体空间,为质外体的糖分运输创造了条件。(3)筛管、伴胞、韧皮薄壁细胞和果肉薄壁细胞中丰富的囊泡以及活跃的囊泡运输现象,暗示囊泡也参与了果实糖分的运输过程。研究推测,枸杞果实韧皮部同化物的卸载方式以及卸载后的同化物运输主要以质外体途径为主。     

灵武长枣果实ATPase超微细胞化学定位和功能研究

采用ATPase超微细胞化学定位技术,研究灵武长枣果实不同发育阶段韧皮部和果肉库薄壁细胞ATPase分布特征,以明确灵武长枣果实ATPase超微细胞化学定位特征和功能。结果显示:(1)第一次快速生长期SE/CC复合体与周围的薄壁细胞有丰富的胞间连丝,形成共质体连续,韧皮部薄壁细胞之间有丰富的胞间连丝,ATPase反应物在韧皮部各细胞分布较少。(2)缓慢生长期ATPase反应物在韧皮部各细胞分布逐渐增加。(3)第二次快速生长期SE/CC复合体与周围的薄壁细胞缺乏胞间连丝,形成共质体隔离,韧皮薄壁细胞及果肉库薄壁细胞的胞间连丝较少,囊泡和膜泡在筛管、韧皮薄壁细胞和库薄壁细胞中很丰富,质膜、液泡膜、囊泡膜、细胞壁和胞间隙的ATPase活性较高。研究表明,果实在第一次快速生长期同化物从筛分子的卸出主要采取共质体途径,缓慢生长期同化物卸出时可能为共质体和质外体途径共存,第二次快速生长期则主要以质外体途径为主,证明果实不同发育阶段韧皮部同化物卸出路径存在差异。     

枸杞果实ATP酶超微细胞化学定位研究

运用常规ATP酶超微细胞化学定位技术,对宁夏枸杞果实发育不同阶段的韧皮部和果肉库薄壁细胞ATP酶分布进行了观察研究.结果显示,在果实发育过程中SE/CC复合体与周围韧皮薄壁细胞间存在共质体隔离,韧皮薄壁细胞及果肉库薄壁细胞的胞间连丝较少,但是与果肉库薄壁细胞相邻的韧皮薄壁细胞的胞间连丝较多.囊泡和膜泡在筛管、韧皮薄壁细胞和库薄壁细胞中很丰富,并且质膜、囊泡膜、液泡膜上ATP酶沉淀物在韧皮部各细胞分布较少,在果肉库薄壁细胞分布较多,特别是在果实第二次快速生长期,果肉库薄壁细胞膜系统、细胞壁和胞间隙的ATP酶活性剧烈增强.此外,果肉库薄壁细胞的质膜ATP酶具极性分布特点.由此得出,枸杞果实韧皮部卸载是一种需要能量驱动的过程,其卸载途径主要以质外体途径为主,在从韧皮部向果肉库薄壁细胞卸出时可能为共质体和质外体途径共存.膜泡运输是枸杞果实同化物卸出和转运的重要方式,而韧皮薄壁细胞在同化物卸出和转运过程中承担了主要转运角色;果肉库薄壁细胞进行主动和定向卸载、积累同化物的能力很强.     

菜豆茎韧皮部卸出的细胞途径以及激素的促进作用(英文)

通过缩小叶面积和去茎尖改变源库比率,以调节韧皮部卸出的途径,证明了韧皮部卸出的共质体与质外体途径的季节变化,和由对氯高汞苯磺酸所诱发的从质外体向共质体途径的转变,是与光合产物的输入有关。缩小叶面积而降低源库比率,能增加夏季生长植株茎韧皮部的质外体卸出,但对冬季生长植株无影响。去尖而增加源库比率,则促进共质体卸出。赤霉酸和激动素能促进共质体的横向转运,但对质外体转运无作用。当质外体为主要运输途径时,赤霉酸和激动素开启共质体途径。赤霉酸和激动素刺激光合产物,通过共质体从筛管一伴胞复合体向韧皮部薄壁纽胞输送,并可能在韧皮部薄壁细胞被动扩散到自由空间。由此可进一步说明蔗糖在激素处理部位自由空间的增加。     

文冠果果实韧皮部及其周围薄壁细胞的超微结构观察及功能分析

该研究应用透射电镜技术,对生长发育过程中的文冠果果实的韧皮部及其周围薄壁细胞的超微结构进行了观察,以探讨文冠果果实同化物韧皮部卸载的细胞学路径及其机理。结果显示:(1)文冠果果实发育过程中,筛分子细胞胞腔较空,几乎没有细胞器,但有类似于囊泡的丝状不定型物存在;伴胞胞质浓密且细胞器丰富,液泡化程度不一,大多数存在多个小液泡;薄壁细胞具有中央大液泡,发育中期富含线粒体、高尔基体、内质网等细胞器,并存在囊泡运输现象,发育后期细胞器发生降解,说明随着果实生长发育,果实内物质代谢和转运活跃程度逐渐下降。(2)果实发育过程中筛分子和伴胞之间始终有胞间连丝,薄壁细胞之间也一直存在大量的胞间连丝,而筛分子-伴胞复合体与薄壁细胞之间只有在果实发育前期和后期存在一定数量的胞间连丝,发育中期却几乎没有胞间连丝。研究结果表明,文冠果果实发育过程中同化物韧皮部卸载路径可能发生了共质体途径-质外体途径-共质体途径的转变。     

The pathways of calcium movement to the xylem.

Calcium is an essential plant nutrient. It is acquired from the soil solution by the root system and translocated to the shoot via the xylem. The root must balance the delivery of calcium to the xylem with the need for individual root cells to use [Ca2+]cyt for intracellular signalling. Here the evidence for the current hypothesis, that Ca2+ travels apoplastically across the root to the Casparian band which it then circumvents via the cytoplasm of the endodermal cell, is critically reviewed. It is noted that, although Ca2+ channels and Ca2+-ATPases are present and could catalyse Ca2+ influx and efflux across the plasma membrane of endodermal cells, their transport capacity is unlikely to be sufficient for xylem loading. Furthermore, there seems to be no competition, or interactions, between Ca2+, Ba2+ and Sr2+ for transport to the shoot. This seems incompatible with a symplastic pathway involving at least two protein-catalysed transport steps. Thus, a quantity of purely apoplastic Ca2+ transport to the xylem is indicated. The relative contributions of these two pathways to the delivery of Ca2+ to the xylem are unknown. However, the functional separation of symplastic Ca2+ fluxes (for root nutrition and cell signalling) and apoplastic Ca2+ fluxes (for transfer to the shoot) would enable the root to fulfil the demand of the shoot for calcium without compromising intracellular [Ca2+]cyt signals. This is also compatible with the observed correlation between transpiration rate and calcium delivery to the shoot.     

Ion distribution measured by electron probe X-ray microanalysis in apoplastic and symplastic pathways in root cells in sunflower plants grown in saline medium

Little is known about how salinity affects ions distribution in root apoplast and symplast. Using x-ray microanalysis, ions distribution and the relative contribution of apoplastic and symplastic pathways for delivery of ions to root xylem were studied in sunflower plants exposed to moderate salinity (EC=6). Cortical cells provided a considerably extended Na+ and Cl- storage facility. Their contents are greater in cytoplasm (root symplast) as compared to those in intercellular spaces (root apoplast). Hence, in this level of salinity, salt damage in sunflower is not dehydration due to extracellular accumulation of sodium and chloride ions, as suggested in the Oertli hypothesis. On the other hand, reduction in calcium content due to salinity in intercellular space is less than reduction in the cytoplasm of cortical cells. It seems that sodium inhibits the radial movement of calcium in symplastic pathway more than in the apoplastic pathway. The cell wall seems to have an important role in providing calcium for the apoplastic pathway. Redistribution of calcium from the cell wall to intercellular space is because of its tendency towards xylem through the apoplastic pathway. This might be a strategy to enhance loading of calcium to xylem elements and to reduce calcium deficiency in young leaves under salinity. This phenomenon may be able to increase salt tolerance in sunflower plants. Supplemental calcium has been found to be effective in reducing radial transport of Na+ across the root cells and their loading into the xylem, but not sodium absorption. Supplemental calcium enhanced Ca2+ uptake and influx into roots and transport to stele.     

Can Ca2+ Fluxes to the Root Xylem Be Sustained by Ca2+-ATPases in Exodermal and Endodermal Plasma Membranes?

The pathway of Ca2+ movement from the soil solution into the root stele has been a subject of controversy. If transport through the endodermis is assumed to be through the cytoplasm, the limiting factor is believed to be the active pumping of Ca2+ from the cytoplasm into the stele apoplast through the plasma membrane lying on the stele side of the Casparian band. By analogy, for similar transport through the exodermis, the limiting step would be the active pumping into the apoplast on the central cortical side of the layer. Such effluxes are mediated by Ca2+-ATPases. To assess whether or not known Ca2+ fluxes to the stele in onion (Allium cepa) roots could be supported by Ca2+-ATPases, the percentages of total membrane protein particles required to effect the transport were calculated using measured values of membrane surface areas, an animal literature value for Ca2+-ATPase V(max), plant literature values for Ca2+-ATPase K(m), and protein densities of relevant membranes. Effects of a putative symplastic movement of Ca2+ from the exo- or endodermis into the next cell layer, which would increase the surface areas available for pumping, were also considered. Depending on the assumptions applied, densities of Ca2+ pumps, calculated as a percentage of total membrane protein particles, varied tremendously between three and 1,600 for the endodermis, and between 0.94 and 1,900 for the exodermis. On the basis of the data, the possibility of Ca2+ transport through the cytoplasm and membranes of the exodermis and endodermis cannot be discounted. Thus, it is premature to assign an entirely apoplastic pathway for Ca2+ movement from the soil solution to the tracheary elements of the xylem. To verify any conclusion with certainty, more detailed data are required for the characteristics of exo- and endodermal Ca2+-ATPases.     

Abscisic acid in the xylem: where does it come from, where does it go to?

Abscisic acid is a hormonal stress signal that moves in the xylem from the root to the different parts of the shoot where it regulates transpirational water loss and leaf growth. The factors that modify the intensity of the ABA signal in the xylem are of particular interest because target cells recognize concentrations. ABA(xyl), will be decreased as radial water flow through the roots is increased, assuming that radial ABA transport occurs in the symplast only. Such dilutions of the plant hormone concentration can be compensated in different ways, which help to keep the ABA-concentrations in the xylem constant: (i) apoplastic bypass flows of ABA, (ii) ABA flows between the stem parenchyma and the xylem during transport and (iii) the action of beta-D-glucosidases that release free ABA from its conjugates to the root cortex and the leaf apoplast. The significance of reflection coefficients (sigma(ABA)), permeability coefficients of membranes (P(S)(ABA)) and apoplastic barriers for ABA is discussed.     

pH, abscisic acid and the integration of metabolism in plants under stressed and non-stressed conditions: cellular responses to stress and their implication for plant water relations

A paradigm for the response of plants to stress is presented which suggests that plants move towards a state of minimal metabolic activity as a stress intensifies and remain in that state until that stress is relieved. The paradigm is based on the proposition that cells that interface with the transpiration stream employ variations on the following theme to move towards that state. Tension on the apoplastic water opens a mechanosensitive Ca2+ channel, a response that is augmented by apoplastic ABA. The resulting elevated cytoplasmic Ca2+ deactivates a plasmalemma H+/ATPase and also activates a K(+)-H+ symport. The inflow of K+ and H+ depolarizes the membrane and renders the apoplast less acidic, the protons being removed to the vacuole and the K+ ions being re-exported via the K+ outward rectifying channel. The onset of darkness in guard and mesophyll cells deactivates the plasmalemma H+/ATPase and then the events outlined above ensue except that these cells do not appear to utilize either Ca2+ or ABA during these changes. In stressed cells it is proposed that elevated cytoplasmic Ca2+ activates the release of an ABA precursor from a stored form. ABA is then released in the apoplast after export of the precursor if the activity of the K(+)-H+ symport has brought the apoplastic pH close to 7.0. It is proposed that aquaporins in the xylem parenchyma and mesophyll cells are opened by elevated cytoplasmic Ca2+ when the water potential of the transpiration stream is high so that water can be stored in the 'xylem parenchyma reservoir'. The water in this reservoir is then used to increase the water potential in the transpiration stream when the water column is under tension and to help repair embolisms by a mechanism that resembles stomatal closure.     

The apoplastic continuum,nutrient absorption and plasmatubules in the dwarf mistletoeKorthalsella lindsayi (Viscaceae)

Summary The transfer of nutrients between host and parasite in mistletoes has generally been considered to occur via the xylem to xylem contacts at the host-parasite interface in the haustorial organ of attachment. A few workers, however, have recently begun to question this assumption and have suggested an alternative pathway of transport involving the intervening parenchyma cells which are often abundant in the parasite at the interface. But no morphological experimental evidence has yet been forthcoming in support of an apoplastic continuum across this interface between parasite and host.Our observations on the dwarf mistletoeKorthalsella lindsayi first indicate an absence of plasmodesmata at the interface, with the conclusion that symplastic transport between the two plants is not involved. However, application of apoplastic markers, such as Calcofluor white and lanthanum and uranyl ions, to the stem of the host results in the transfer of these tracers across the interface and into the tissues of the parasite. This demonstrates the existence of an apoplastic continuum between the two plants, and a pathway that is probably used in the normal transfer of water and other nutrients from host to parasite.From the apoplastic continuum provided by the walls of the haustorial parenchyma tissue, nutrients are transferred to the symplast for eventual distribution to other parts of the plant. Evidence for the active uptake of substances from the apoplast by the protoplasts of the parenchyma cells is shown by the convoluted appearance of the plasmalemma and its differentiation often into plasmatubules.     

A possible stress physiological role of abscisic acid conjugates in root-to-shoot signalling

Abscisic acid (ABA) conjugates, predominantly their glucose esters, have recently been shown to occur in the xylem sap of different plants. Under stress conditions, their concentration can rise substantially to levels that are higher than the concentration of free ABA. External ABA conjugates cannot penetrate apoplastic barriers in the root. They have to be hydrolysed by apoplastic enzymes in the root cortex. Liberated free ABA can then be redistributed to the root symplast and dragged directly across the endodermis to the stele. Endogenous ABA conjugates are formed in the cytosol of root cells, transported symplastically to the xylem parenchyma cells and released to the xylem vessels. The mechanism of release is unknown; it may include the action of ABC-transporters. Because of its extremely hydrophilic properties, ABA-GE is translocated in the xylem of the stem without any loss to the surrounding parenchyma. After arrival in the leaf apoplast, transporters for ABA-GE in the plasmalemma have to be postulated to redistribute the conjugates to the mesophyll cells. Additionally, apoplastic esterases can cleave the conjugate and release free ABA to the target cells and tissues. The activity of these esterases is increased when barley plants are subjected to salt stress.     

Calcium transport between tissues and its distribution in the plant

Abstract. The low cytosol concentration of free Ca²⁺ makes the symplast of roots an ineffective pathway for the supply of the calcium needed for healthy growth in the aerial parts of plants. Ca²⁺ moves rapidly across the cortical apoplast by diffusion and mass flow but is probably diverted across the plasmamembranes of endodermal cells by Casparian bands. A proposal is made to account for the movement of calcium across the endodermis and it is estimated that Ca-fluxes are likely to be appreciably greater than in the regulation of cell Ca level by cortical cells.
Ca transport in the xylem occurs by mass flow of free Ca²⁺, and some organically complexed Ca, and by chromatographic movement along Ca-exchange sites in the xylem walls. Delivery of Ca to transpiring leaves and to weakly transpiring meristematic zones is discussed in relation to the two modes of Ca movement in the xylem. Competition between sinks is intensified when [Ca²⁺] in xylem is low and transpiration is great.
Tropic growth responses involve pumping of vacuolar calcium into the apoplast followed by its migration along gradients of electrical potential which develop in the apoplast after geo-stimulation. An attempt is made to estimate plasmalemma efflux during this process.
Redistribution from mature tissues to meristems in the pholem is likely to be small, if it occurs at all, since sieve tubes cannot have more than micro-molar concentrations of free-Ca²⁺ in them.