植物对重金属的吸收和分布

植物修复是利用植物来清除污染土壤中重金属的一项技术。该技术成功与否取决于植 物从土壤中吸取金属以及向地上部运输金属的能力。植物对金属的吸收主要取决于自由态离子活度。许多螯合剂能诱导植物对重金属的吸收。金属离子在液泡中的区域化分布是植物耐 重金属的主要原因。同时,细胞内的金属硫蛋白、植物螯合肽等蛋白质以及有机酸、氨基酸等在金属贮存和解毒方面也起重要作用。本文还论述了重金属在植物体内运输的生理及分子 方面的研究进展。     

植物吸收利用铁的机理

根据植物铁营养的一些研究进展,论述了植物对铁的吸收和运输机理以及HCO3^-,N、P等因素对铁利用效率的影响。     

植物对重金属的吸收和分布

植物修复是利用植物来清除污染土壤中重金属的一项技术。该技术成功与否取决于植物从土壤中吸取金属以及向地上部运输金属的能力。植物对金属的吸收主要取决于自由态离子活度。许多螯合剂能诱导植物对重金属的吸收。金属离子在液泡中的区域化分布是植物耐重金属的主要原因。同时,细胞内的金属硫蛋白、植物螯合脓等蛋白质以及有机酸、氨基酸等在金属贮存和解毒方面也起重要作用。本文还论述了重金属在植物体内运输的生理及分子方面的研究进展。     

植物重金属镉(Cd2+)吸收、运输、积累及耐性机理研究进展

本文从植物对Cd2 吸收、运输及积累机制,以及Cd2 对植物的伤害、植物对Cd2 的耐性机制等三个层面对相关研究进展进行了综述,并对该研究领域的重点问题进行了展望。     

VA菌根降低植物对重金属镉的吸收

高等植物在漫长的进化过程中对环境产生种种适应机制。菌根的形成即是对自然土壤中有效磷不足的一种适应。菌根真菌与寄主根系共生形成菌根后,真菌的菌丝可以远远伸出根际范围从而扩大了植物对土壤中难以移动的磷元素的吸收范围而改善植物的磷素营养。因此,地球上90％的陆生植物都可形成菌根。菌根的形成,不仅促进了植物对磷的吸收,而且也影响到植物对其它元素包括重金属的吸收。在重金属污染的土壤中,菌根对植物重金属的吸收将影响到植物对重金属的抗性和农产品品质。本文拟研究在添加镉的土壤上菌根对植物吸收Cd的影响。     

植物对羰基化合物的排放与吸收研究进展

综述了植物排放、吸收羰基化合物的研究成果,讨论了植物与大气之间羰基化合物的交换补偿点问题.气孔和角质层的吸收是醛类被植物净化的重要途径.羰基化合物进入植物叶片后,在叶片体内酶的作用下绝大部分被代谢为有机酸、糖类、氨基酸、二氧化碳等产物.根据补偿点及周围大气中羰基化合物的浓度可初步推断出植物与大气之间羰基化合物的交换方向.简要叙述了目前植物排放羰基化合物以及植物叶片中羰基化合物的分析方法,如DNPH/HPLC/UV和PFPH/GC/MS法.最后指出未来的研究热点为:改进和优化植物排放羰基化合物的分析方法和研究体系(如植物-土壤体系)、扩大植物排放羰基化合物的检测种类范围、筛选净化污染能力强的植物物种,以及推广植物修复大气污染技术.     

植物铁吸收、转运和调控的分子机制研究进展

铁是植物正常生命活动所必需的微量矿质元素,铁离子的吸收、转运和利用是一个复杂的过程,很多基因参与了这一过程。本文对近10年来发现和分离的参与植物铁吸收、转运及调控的基因研究进展进行了综述。根据最近的研究结果,提出了植物控制铁吸收的分子调控模式(机理I)。     

植物铁吸收、转运和调控的分子机制研究进展

铁是植物正常生命活动所必需的微量矿质元素, 铁离子的吸收、转运和利用是一个复杂的过程, 很多基因参与了这一过程。本文对近10年来发现和分离的参与植物铁吸收、转运及调控的基因研究进展进行了综述。根据最近的研究结果, 提出了植物控制铁吸收的分子调控模式(机理I)。     

植物对水中菲和芘的吸收

以菲和芘为多环芳烃（PAHs）代表物,采用水培体系研究了黑麦草（Lolium multiflorum Lam）对水中PAHs的吸收作用,重点研究了植物吸收菲和芘的时间动态.水中菲和芘起始浓度分别为1.00mg/L和0.12mg/L.0～288h内,黑麦草根和茎叶中菲和芘含量均先快速增加而后降低,积累量不断增大,植物根系和茎叶富集系数则先快速升高而后趋于稳定.茎叶中菲和芘含量、茎叶对菲和芘的富集系数比根低1～3数量级,积累量也明显小于根系.黑麦草根系对水中芘有更强的富集能力,其根系富集系数比菲大85%～179%;而其茎叶对菲的富集作用则略强.菲和芘在植物体内有明显的传导作用.0～288h,传导系数（TF）先显著升高而后趋于恒定;但实验条件下,菲和芘的TF值均很小,分别不高于0.031和0.009,且芘的TF值明显小于菲,表明供试植物对芘的传导能力更弱.     

Absorption,Transport and Metabolism of Vitamin E

Vitamin E includes eight naturally occurring fat-soluble nutrients called tocopherols and dietary intake of vitamin E activity is essential in many species. α-Tocopherol has the highest biological activity and the highest molar concentration of lipid soluble antioxidant in man. Deficiency of vitamin E may cause neurological dysfunction, myopathies and diminished erythrocyte life span. α-Tocopherol is absorbed via the lymphatic pathway and transported in association with chylomicrons. In plasma α-tocopherol is found in all lipoprotein fractions, but mostly associated with apo B-containing lipoproteins in man. In rats approximately 50% of α-tocopherol is bound to high density lipoproteins (HDL). After intestinal absorption and transport with chylomicrons α-tocopherol is mostly transferred to parenchymal cells of the liver were most of the fat-soluble vitamin is stored. Little vitamin E is stored in the non-parenchymal cells (endothelial, stellate and Kupffer cells). α-Tocopherol is secreted in association with very low density lipoprotein (VLDL) from the liver. In the rat about 90% of total body mass of α-tocopherol is recovered in the liver, skeletal muscle and adipose tissue. Most α-tocopherol is located in the mitochondrial fractions and in the endoplasmic reticulum, whereas little is found in cytosol and peroxisomes. Clinical evidence from heavy drinkers and from experimental work in rats suggests that alcohol may increase oxidation of α-tocopherol, causing reduced tissue concentrations of α-tocopherol. Increased demand for vitamin E has also been observed in premature babies and patients with malabsorption, but there is little evidence that the well balanced diet of the healthy population would be improved by supplementation with vitamin E.     

Assimilate Transport and Partitioning in Plants: Approaches,Methods, and Facets of Research

This review, dedicated to the 100th anniversary of A.L. Kursanov's date of birth, considers the development of phloem transport studies since his book, Assimilate Transport in the Plant, was published in 1976. This book and several other fundamental publications on phloem structure and functions basically shaped this physiological issue; as a result, several international meetings by scientists working in the area were induced, and the proceedings of these meetings were published at regular intervals. Six conferences have been held to date, and six corresponding collections of papers have been published and are reviewed here along with other experimental communications and reviews. This review considers the following topics: (1) the phloem structure and the ultrastructure of specialized phloem cells, (2) the physiological functions of phloem and their regulation, (3) photosynthesis and phloem loading with assimilates, (4) phloem unloading and the related processes of plant growth and development, (5) the mechanisms of sugar and amino acid transport, (6) the levels of transport, (7) transport compartments; (8) xylem–phloem and symplast–apoplast communication; (9) phloem transport vs. the integral plant physiology, (10) transport of xenobiotics, and (11) the trophic transport networks in symbionts.     

夜间低温对番茄幼苗磷素吸收及转运的影响

以‘辽园多丽’番茄幼苗为试材,采用营养液栽培模式,以夜温15℃为对照,对夜间低温(6℃)影响番茄幼苗磷素吸收及转运过程的因素进行研究。结果显示:(1)夜间低温胁迫导致番茄幼苗根系活力受到显著抑制。(2)夜间低温条件下,番茄幼苗根系中酸性磷酸酶活性无明显变化,而其地上部酸性磷酸酶活性增强,且以叶片中活性增加较大。(3)夜间低温胁迫使根系中磷酸盐转运蛋白基因LePT1和LePT2的相对表达量较对照增加,地上部磷酸盐转运蛋白基因LePT1的表达受到抑制,且叶片中受到的抑制作用更显著。(4)夜间低温胁迫处理营养液中剩余磷素含量始终多于对照;其番茄幼苗地下部和地上部中磷素绝对含量均下降,且叶片比茎的下降幅度更大。(5)夜间低温胁迫使番茄幼苗伤流强度下降,伤流液中磷素含量随着处理天数的增加而增加,在处理第9天时极显著高于对照。研究表明,夜间低温导致番茄幼苗根系活力降低,诱导植株中磷酸盐转运蛋白基因LePT1的表达下调以及伤流强度降低,从而引起磷素由茎向叶片中的转运过程受到明显抑制。     

Defoliation,Photosynthetic Rates,and Assimilate Transport in Grapevine Plants

The source-sink relations in grapevine (Vitis vinifera L., var. Rkatsiteli) plants were disturbed by defoliation at different stages of vegetative growth in order to investigate changes in photosynthetic activity and assimilate partitioning. Defoliation was shown to stimulate photosynthesis in the remaining source leaves, enhance the assimilate export, and diminish the midday suppression of photosynthesis. Defoliation created a powerful sink for assimilates, and stimulated their delivery to the affected zone. It is hypothesized that defoliation-induced stress is accompanied by a substantial enhancement of photosynthetic activity and by redistribution of assimilate flows, which enables a sustained supply of assimilates to the sink organs of grapevine plants.__________Translated from Fiziologiya Rastenii, Vol. 52, No. 4, 2005, pp. 507–512.Original Russian Text Copyright © 2005 by Chanishvili, Badridze, Barblishvili, Dolidze.     

Transport Processes in Vacuoles of Higher Plants

The vacuole is the largest compartment of a mature plant cell and serves as an internal reservoir of metabolites and nutrients. In the last years transport of solutes across the tonoplast has been intensively investigated. It was shown that two different proton pumps reside in the tonoplast. These pumps generate an electrochemical gradient which can be used as an energy-source to accumulate solutes. Cation uptake is driven by an H⁺ antiport mechanism. Anions are accumulated in response to the inside positive membrane potential. In addition, the existence of ion channels was shown using the patch clamp technique. The aim of this review is to compare and to discuss the present state of our knowledge of solute transport across the tonoplast.     

Silicon Suppresses Fusarium Wilt Development in Banana Plants

This study aimed to determine the effect of silicon (Si) in reducing the symptoms of Fusarium wilt, caused by Fusarium oxysporum f. sp. cubense (Foc), on banana plants. Banana seedlings of Grand Nain (resistant) and Maçã (susceptible) were grown in plastic trays amended with 0 (?Si) or 0.39 g Si (+Si) per kg of soil and inoculated with Foc at 60 days after transplanting. The Si concentration in the roots and rhizome‐pseudostem significantly increased by 30.26 and 58.82%, respectively, for the +Si treatment compared with ?Si treatment. The Si concentration in the roots and rhizome‐pseudostem of Grand Nain plants was, respectively, 11.57 and 37.04% greater than that found in Maçã. The +Si plants showed a reduction of 12.37, 49.81, 51.87 and 20.39%, respectively, for the area under reflex leaf symptoms progress curve, the area under root symptoms progress curve, the area under disease progress curve and the area under asymptomatic fungal colonization of tissue progress curve compared with ‐Si plants. The area under darkening of rhizome‐pseudostem progress curve (AUDRPPC) of Maçã significantly increased by 15.98% for the ?Si treatment in comparison with the +Si treatment. For the +Si treatment, the AUDRPPC of the plants from the Maçã cultivar significantly decreased by 20.59% in comparison with the plants from the Grand Nain cultivar. The area under relative lesion length progress curve (AURLLPC) of the plants from the Maçã cultivar significantly decreased by 41.54% for the +Si treatment in comparison with the ?Si treatment. There was no significant difference between the ‐Si and +Si treatments in the AUDRPPC and AURLLPC of Grand Nain. For the +Si treatment, the AURLLPC of Grand Nain significantly decreased by 9.23% in comparison with Maçã. There was no significant difference between the Grand Nain and Maçã for the AUDRPPC and AURLLPC in the ?Si treatment. The findings of this study show that supplying Si to banana plants, especially to a susceptible cultivar to Foc, had a great potential in reducing the intensity of Fusarium wilt and may play a key role in disease management when banana plants are cultivated in Si‐deficient soils infested by this pathogen.     

细胞核质转运及其受体在植物抗病防御反应中的调控作用

植物病害严重威胁全球粮食生产,研究植物对病原菌防御机制和病原菌对寄主作物的侵染过程和分子机制,有助于改良植物种源使其获得持久抗性。近年来, 日渐增多的研究表明, 一些抗病蛋白需要转移到细胞核内才能启动免疫反应,进而发挥抗病防御作用,而细胞核质转运受体是实现这些抗病蛋白核质转运必不可少的“载体”。因此,细胞核质转运及转运...     

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.