甜土植物根部的钠离子应对策略研究进展

土壤盐渍化严重影响了甜土植物（特别是农作物）的生长速率和产量。植物根部是与土壤中Na^＋接触的重要界面,也是吸收Na^＋的主要器官,正日益成为甜土植物耐盐研究靶标。本文概述近10年来对Na^＋进入甜土植物根部的2种途径（共质体和质外体）以及根部维持离子稳态的3种应对方式（Na^＋的细胞外排、液泡区隔化和地上部分转运）新的认识和观点。通过阐述Na^＋在甜土植物根部的转运机制,以期为提高农作物抗盐性以及在盐渍环境中的产量提供理论基础。     

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.     

植物钙素吸收和运转

近年来,钙素在植物体内的吸收和运输研究主要集中在细胞和分子水平,但整株水平上的研究也同样重要.整株水平上的钙吸收和运输包括根细胞的钙吸收、钙离子横向穿过根系并进入木质部、在木质部运输、从木质部移出并进入叶片或果实及在叶片或果实中运转分配等环节,既经过质外体也穿越共质体.钙离子通道、Ca2 -ATP酶和Ca2 /H 反向转运器等参与根细胞的钙吸收.在钙离子横向穿根进入木质部的过程中,需要穿越内皮层和木质部薄壁细胞组织.根系内皮层凯氏带阻挡了Ca2 沿质外体途径由内皮层外侧向内侧的移动,部分Ca2 由此通过离子通道流进内皮层细胞而转入共质体并到达木质部薄壁细胞组织,而由木质部薄壁细胞组织进入中柱质外体可能需要Ca2 -ATP酶驱动;还有一些Ca2 由内皮层细胞运出,沿内皮层内侧的质外体途径进入木质部导管,并通过导管运向枝干.钙离子以螯合态的形式在枝干导管运输;水流速率是影响钙离子沿导管运输的关键因子.钙离子在果实和叶片中的运输和分配不仅通过质外体途径也通过共质体途径.     

植物体内光合同化物韧皮部装载和卸出研究进展

近年来研究表明,植物体内光合同化物的韧皮部装载和卸出均有其本途径和质外体途径,装载转运的糖类主要有：（２）棉子糖及其人类似物（以共质体方式装载）;（２）蔗糖（以质外体方式装载）。同化物的共质体卸出可通过扩散和集中作用实现,而质外体卸出则根据蔗糖在质外体是否水解而分为两种类型。卸出和装载的途径、机理因植物种类及库源关系而不同,也会受生长发育阶段及环境的变化而调整。深入研究韧皮部装载和帛出调控机制,对     

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。     

植物对重金属镉的耐受机制

镉离子（Cd^2＋）具有强植物毒性,抑制植物生长,甚至使植物死亡。由于长期的环境选择和适应进化,植物发展出耐受机制,可减轻或避免Cd^2＋的毒害。硫转运蛋白、硫还原相关酶类以及半胱氨酸、谷胱甘肽和植物螯合肽合成基因的表达受Cd^2＋调控。同时这些基因的过表达也能提高植物对Cd^2＋的耐性。植物抗氧化系统对Cd^2＋胁迫诱发的活性氧的清除作用,具转运Cd^2＋活性的质膜转运蛋白促进Cd^2＋经共质体途径向木质部运输、装载,而后随蒸腾流向地上部迁移,具转运Cd^2＋活性的液泡膜转运蛋白促进Cd^2＋进入液泡的隔离作用,都在植物对Cd^2＋的耐性中起作用。     

水稻土施硅对土壤-水稻系统中镉的降低效果

水稻中镉的积累造成人类健康的风险,增加水稻硅素能减轻镉中毒症状,降低稻米镉积累,但是硅对重金属的作用机理尚不清楚。主要研究了在中度和高度镉污染的土壤中,通过施用固态和液态的富硅物质对土壤-水稻系统中镉的吸收和转运的影响,探明决定镉和硅在根与芽的质外体和共质体中的作用机理。试验结果表明:(1)在中度和高度污染的土壤中,镉在土壤-作物系统中的转移和积累情况是不同的,可以通过富硅物质中的单硅酸与镉离子的相互作用,增加镉在硅物质表面的吸附来减少镉在土壤中的流动;(2)富硅物质可以降低水稻根和芽中镉的积累,在高度镉污染的情况下,施用硅可以使镉大量积累在水稻根及其共质体中,并降低根及其共质体中镉的转换和积累;(3)新鲜土壤中水萃取态的单硅酸含量与镉在土壤-作物系统中的流动性、转运以及积累等主要参数密切相关。     

植物防御素调控水稻镉积累的新机制

镉是我国农产品的主要重金属污染物之一。随着我国土壤重金属污染问题日益突出,包括稻米在内的农产品重金属超标时常发生。如何防控重金属在作物可食部位的积累,在保证农产品安全的同时将农田重金属进行移除修复,已成为我国农业生产急需解决的问题。最近,中科院上海生命科学院植物生理生态所龚继明研究组和中国水稻所钱前研究组克隆到1个特异调控镉在水稻(Oryza sativa)叶片中积累的主效QTL基因CAL1。CAL1编码1个植物防御素类似蛋白,通过与镉进行螯合,将镉从维管束木质部薄壁细胞中分泌出来,进入木质部参与长距离转运,从而定向调控镉在水稻叶片等营养器官的积累而不影响籽粒镉的积累。该研究加深了人们对重金属镉在植物体内的转运和再分配机理的认识,同时也为培育秸秆镉高积累而籽粒镉含量达标的"修复型"水稻品种提供有价值的新基因。研究成果具有重要的理论意义和应用价值。     

葡萄果实中的糖分积累和调控

文章介绍葡萄果实不同发育期糖分积累的特点.糖分积累的细胞学途径、共质体到质外体的转变过程和这两种途径的调控机制,以及根域限制栽培措施对葡萄果实糖分积累的影响和机制的研究进展.     

香根草对镉毒害的生理响应——采用傅里叶变换红外光谱法(FTIR)

为阐明香根草(Vetiveria zizanioides)对镉(Cd~(2+))胁迫的耐性机理及其对重金属Cd~(2+)的积累特征,通过水培试验,采用傅里叶变换红外光谱法(FTIR)研究在不同Cd~(2+)浓度处理时香根草根、茎、叶化学组分的变化,同时测定香根草叶Cd~(2+)的亚细胞分布和其重金属Cd~(2+)含量。结果表明,其根组织在2927 cm~(-1)处峰高先下降后上升,表明在低Cd~(2+)(Cd~(2+)3 mg/L)处理条件下香根草分泌的有机酸不断螯合Cd~(2+),造成羧酸O—H的减少,但随着Cd~(2+)含量的升高,其羧酸螯合力变弱,有机酸含量渐渐升高;茎组织在1631 cm~(-1)峰高处先上升后下降,表明在低Cd~(2+)(Cd~(2+)3 mg/L)处理条件下香根草产生氨基酸、多肽和蛋白质等物质,通过渗透调节来增强抗逆性,但随着Cd~(2+)含量的升高,蛋白质二级结构中肽键间氢键的结合力受影响较大。当Cd~(2+)处理浓度为7 mg/L时,香根草生长10 d后,地上部分及根组织富集Cd~(2+)量分别高达212.49 mg/kg和290.59 mg/kg。香根草地上部分的Cd~(2+)含量随Cd~(2+)处理浓度的增加而增加。香根草叶片富集的Cd~(2+)主要分布于细胞质中,其次为细胞壁,而在线粒体和叶绿体中含量最低。     

Effect of cadmium and calcium treatments on phytochelatin and glutathione levels in citrus plants

Industry residues, phosphate fertilisers and wastewater as a source of irrigation have considerably increased levels of heavy metals in the soil, mainly cadmium (Cd²⁺). To test the effects of a calcium (Ca²⁺) treatment on Cd²⁺ accumulation and plant tolerance to this heavy metal, plants of two citrus genotypes, Cleopatra mandarin (CM) and Carrizo citrange (CC), were watered with increasing concentrations of Cd²⁺, and phytochelatin (PC) and glutathione (GSH) content were measured. Both genotypes were able to synthesise PCs in response to heavy metal intoxication, although CM seems to be a better Cd²⁺ excluder than CC. However, data indicate that CC plants had a higher capacity for regenerating GSH than CM plants. In this context, the effects of Ca²⁺ treatment on Cd²⁺ accumulation, plant survival and PC, GSH and oxidised glutathione (GSSG) content were assessed. Data indicate that treatment with Ca²⁺ had two positive effects on citrus physiology: it reduced Cd⁺² uptake into roots and also increased GSH content (even in the absence of Cd²⁺). Overall, the data indicate that although Cd²⁺ exclusion is a powerful mechanism to avoid heavy metal build‐up into photosynthetic organs, the capacity to maintain optimum GSH levels to feed PC biosynthesis could also be an important factor in stress tolerance.     

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.     

黄连体内黄连素的组织器官定位和根尖屏障结构特征研究

黄连(Coptis chinensis)是毛茛科著名药材,该文研究了黄连体内黄连素在组织器官中的分布规律和根尖屏障结构特征。在白光和荧光显微镜下,组织器官中黄连素在蓝色激发光下自发黄色荧光,黄连素-苯胺兰对染研究细胞壁凯氏带和木质化,苏丹7B染色栓质层,间苯三酚-盐酸染色木质化。结果表明:黄连不定根初生结构为维管柱、内皮层、皮层、外皮层和表皮组成;次生结构以次生木质部为主、次生韧皮部和木栓层组成。黄连根茎初生结构由角质层,皮层和维管柱组成;次生结构由木栓层、皮层和维管柱组成,以皮层和维管柱为主。叶柄结构为髓、含维管束的厚壁组织层、皮层和角质层。黄连不定根的屏障结构初生结构时期由栓质化和木质化的内皮层、外皮层;次生结构时期为木栓层组成;根状茎的为角质层和木栓层。黄连素主要沉积分布在不定根和茎的木质部,叶柄的厚壁组织层,木质部和厚壁组织是鉴别黄连品质的重要部位。黄连根尖外皮层及早发育,同时初生木质部有黄连素沉积结合,可能造成水和矿质吸收和运输的阻碍,也是黄连适应阴生环境的重要原因。     

Cadmium absorption and transportation pathways in plants

Controlling the uptake, transport, translocation, and accumulation of excessive amounts of cadmium from polluted environments is critical for plants and, consequently, humans with regard to food safety. Plants adopt various cellular and molecular mechanisms to minimize Cd toxicity. Upon exposure to Cd, plants initially implement avoidance strategies, such as production of organic acids, chelation, and sequestration, to prevent metal access to root cells. Nevertheless, Cd can be transported through the roots, stems, and leaves via apoplastic and symplastic pathways. These processes have been controlled by specific sites at the root surface and root cortex, in cells responsible for loading the root xylem, at the transition between the vascular systems of the root and the shoot, and in connecting tissues and cells at the stem. Although resistance to heavy metal cadmium can be achieved by either avoidance or tolerance, genetic basis to tolerance is therefore implied, in that these mechanisms are heritable attributes of tolerant mutants or genotypes.     

Anatomical differences of poplar (<Emphasis Type="Italic">Populus</Emphasis> × <Emphasis Type="Italic">euramericana</Emphasis> clone I-214) roots exposed to zinc excess

Poplar is one of the suitable candidates for phytoremediation due to extensive root system, fast growth rate, easy propagation and high biomass production. Zinc (Zn) is an essential element, but at high concentration becomes toxic to plants, similarly like cadmium (Cd). In order to evaluate the effect of Zn on root tissue development we conducted experiments with poplar (Populus × euramericana clone I-214) grown in hydroponics. Plants were treated with low (control) and excess level of Zn (1 mM). Changes in the development of apoplasmic barriers — Casparian bands and suberin lamellae in endodermis, as well as lignification of xylem vessels have been investigated. We found that both apoplasmic barriers developed closer to the root apex in higher Zn-treated root when compared with control root. Similar changes were observed in lignification of xylem vessels. For localization of Zn within root tissues, cryo-SEM/EDXMA analyses were used. Most of Zn was localized in the cortical tissues and four-time less Zn was determined in the inner part of the root below the endodermis. This indicates that endodermis serves as efficient barrier of apoplasmic Zn transport across the poplar root.     

Effects of cadmium and lead on the accumulation of Ca2+ and K+ and on the influx and translocation of K+ in wheat of low and high K+ status

The effects of cadmium and lead on the internal concentrations of Ca²⁺ and K⁺, as well as on the uptake and translocation of K(⁸⁶Rb⁺) were studied in winter wheat (Triticum aestivum L. a. MV-8) grown hydroponically at 2 levels of K⁺ (100 uM and 10 mM). Cd²⁺ and Pb²⁺ were applied in the nutrient solution in the range of 0.3 to 1000 u.M. Growth was more severely inhibited by Cd²⁺ and in the high-K⁺ plants as compared to Pb^z+ and low-K⁺ plants. Ions of both heavy metals accumulated in the roots and shoots, but the K⁺ status influenced their levels. Ca²⁺ accumulation was increased by low concentrations of Cd²⁺ mainly in low-K⁺ shoots, whereas it was less influenced by Pb²⁺. The distribution of Cd²⁺ and Ca²⁺ in the plant and in the growth media indicated high selectivity for Cd²⁺ in the root uptake, while Ca²⁺ was preferred in the radial and/or xylem transport. Cd²⁺ strongly inhibited net K⁺ accumulation in high-K⁺ plants but caused stimulation at low K⁺ supply. In contrast, the metabolis-dependent influx of K⁺(⁸⁶Rb⁺) was inhibited in low-K⁺ plants, while the passive influx in high-K⁺ plants was stimulated. Translocation of K⁺ from the roots to the shoots was inhibited by Cd²⁺ but less influenced in Pb²⁺-treated plants. It is concluded that the effects of heavy metals depend upon the K⁺-status of the plants.     

Net sodium fluxes change significantly at anatomically distinct root zones of rice (Oryza sativa L.) seedlings

Casparian bands of endodermis and exodermis play crucial roles in blocking apoplastic movement of ions and water into the stele of roots through the cortex. These apoplastic barriers differ considerably in structure and function along the developing root. The present study assessed net Na⁺ fluxes in anatomically distinct root zones of rice seedlings and analyzed parts of individual roots showing different Na⁺ uptake. The results indicated that anatomically distinct root zones contributed differently to the overall uptake of Na⁺. The average Na⁺ uptake in root zones in which Casparian bands of the endo- and exo-dermis were interrupted by initiating lateral root primordia (root zone III) was significantly greater than that at the root apex, where Casparian bands were not yet formed (root zone I), or in the region where endo- and exo-dermis with Casparian bands were well developed (root zone II). The measurement of net Na⁺ fluxes using a non-invasive scanning ion-selective electrode technique (SIET) demonstrated that net Na⁺ flux varied significantly in different positions along developing rice roots, and a net Na⁺ influx was obvious at the base of young lateral root primordia. Since sodium fluxes changed significantly along developing roots of rice seedlings, we suggest that the significantly distinct net Na⁺ flux profile may be attributed to different apoplastic permeability due to lateral root primordia development for non-selective apoplastic bypass of ions along the apoplast.     

Heavy-metal ion uptake by plants from nutrient solutions with metal ion,plant species and growth period variations

Summary Rape, cucumber, wheat, oats and tomato were grown for one to two weeks in nutrient solutions with heavy metals added. Of the metal ions tested (Cr³⁺, Cu²⁺, Co²⁺, CrO₄ ^2-, Ni²⁺, Cd²⁺, Pb²⁺, Mn²⁺, Zn²⁺ and Ag⁺), manganese, nickel and lead exhibited the greatest mobility in cucumber plants, which resulted in the highest shoot/root concentration ratio. Silver was not translocated to the shoots of cucumber plants in measurable amounts.When the plants were grown with 1.0, 10 and 100 M cadmium or nickel in the solution, the shoot and root concentration increased 5–10 times if the metal ion concentration of the solution was increased 10 times.The plants showed great differences in cadmium and nickel uptake. In the shoot, the cadmium concentration increased in the order: oats = wheat < cucumber = rape < tomato, and in the root in the order: oats = wheat < cucumber = rape < tomato. The great uptake of cadmium and nickel by tomato is notable and agrees with other reports.The nickel, and especially the cadmium, concentration in roots and shoots increases with the age of the plant.The results are discussed and related to other investigations. The need for research on the uptake mechanisms of non-essential heavy metals is emphasized. re]19750415