植物硒同化的研究进展及其耐硒突变体的筛选

简要叙述了高等植物对硒元素吸收、同化的过程和特点。对近年来植物硒蛋白存在状态、硒相关突变体的筛选和应用硒代谢关键酶基因的转基因植物研究等方面的最新进展怍了扼要综述。在此基础上对植物硒营养研究的发展提出了几点设想。     

植物硒同化的研究进展及其耐硒突变体的筛选

简要叙述了高等植物对硒元素吸收、同化的过程和特点。对近年来植物硒蛋白存在状态、硒相关突变体的筛选和应用硒代谢关键酶基因的转基因植物研究等方面的最新进展作了扼要综述。在此基础上对植物硒营养研究的发展提出了几点设想。     

烟草根际土壤硒、硫形态相互作用与烟草对硒、硫吸收的研究

通过烟草根际营养试验研究发现,烟草根际土壤Se总量及可溶态Se、交换态Se及有机Se均表现出明显的亏缺.而根际土中S总量及吸附性S、有机S则表现明显的富集.施S对根际土Se亏缺程度的影响与施Se处理有关,而施Se对根际土S富集程度的影响随施S的水平而有一定差异.未施Se处理时,施S降低了烟草根际土中相应几种Se形态的亏缺率,施Se处理时施S的影响则相反.不施S时,加入Se可以增加根际土全S量的富集程度;施S时,加入Se则减少根际全S量的富集程度.前期烟草的Se含量主要受根际土壤可溶态Se的影响,而Se积累量除受土壤可溶态Se的影响外,还受到根际土壤交换态Se、有机Se及酸溶态Se的影响.前期烟草地上部分中S含量主要受根际土壤可溶性S及有机S影响.     

菌根和植物相互作用的本质

介绍了菌根真菌在植物吸收、运输营养物质中的作用,宿主植物体内碳水化合物的流动,菌根真菌和其它根际微生物之间的相互作用。     

植物硒及其含硒蛋白的研究

硒是植物的有益元素,植物对硒的吸收与外源硒的有效性、硒的形态、植物的种类等有关;硒在植物中主要以有机硒形态存在,HPLC-ICP-MS联用已成为植物体内硒形态鉴定的最常用手段;含硒蛋白是植物体内最主要的有机大分子硒,具有抗肿瘤、抗氧化等多种生物活性。在环境安全和人类健康等方面,富硒植物具有很好的应用价值,所以利用分子生物学手段分析富硒植物的富硒机制,可以为富硒基因的筛选和利用提供理论依据。     

土壤硒及其与植物硒营养的关系

综述了土壤中Se的形态分布、有效性及其与植物关系研究方面的进展。论述了不同形态的Se在土壤中分布情况、对植物的有效性与土壤pH值、化学及矿物学组成、吸附表面、氧化还原状态等物理化学性质的关系;Se在植物中的富集、转化及其对植物的抗氧化、促进生长、提高产量和质量等各种生物学效应;并在此基础上对Se的应用前景做了展望。     

富硒植物与人体健康

硒是生态环境中的一个重要微量元素。1957年施瓦茨发现,硒有抗氧化作用,并首次提出硒是人体的必需元素。同年,谷跳甘肽过氧化物酶被发现。1971年,Rotz－uch证明,硒是该酶的组成成分。1973年,世界卫生组织宣布硒是人体生命的必需元素。近年,德国植物营养学家已将硒列于植物有益元素的行列。硒通过生物地球化学营养链：岩石一土壤和水一植物一动物和人给人和动物以影响。几十年来的研究结果表明,人和动物的四十多种疾病与体内硒缺乏有关,典型疾病如地方性克山病、大骨节病、牲畜的白肌病。禽类的渗出性素质等,而硒制剂对这些疾病均…     

植物的硫同化及其相关酶活性在镉胁迫下的调节

植物对土壤中硫的利用包括根系对硫酸盐的吸收、转运、同化、分配等过程,也是由一系列酶和蛋白质参与和调节的代谢过程。近年来的研究表明,在植物体内,硫同化与植物对镉等重金属元素的胁迫反应机制有着密切关系。镉胁迫能调节植物对硫酸盐的吸收、转运、同化,以及半胱氨酸、谷胱甘肽（glutathione,GSH）和植物螯合肽（Dhytochelatins,pc）的合成。植物在镉胁迫下通过多种调节机制,增强对硫酸盐的吸收和还原,迅速合成半胱氨酸和谷胱甘肽等代谢物,从而合成足够的PC,以满足植物生理的需要。     

植物硒生理及与重金属交互的研究进展

硒是一种重要的微量元素,在低浓度时对生物有益,但高浓度时呈现与重金属类似的毒性。植物作为人体硒摄入的主要来源,其硒代谢对于植物硒积累乃至人体硒营养水平十分重要。研究植物硒吸收、代谢和积累机理能指导富硒粮食的生产,是解决人体硒摄入不足/超量问题的有效途径。本文在阐述土壤硒含量、形态、生物有效性及分布的基础上,综述了植物对硒的吸收、代谢机理的研究进展,并讨论了农业生物强化以及遗传育种生物强化等两种硒生物强化的实践方法,以及利用硒生物强化缓解重金属毒性减少积累;最后,提出了植物硒代谢及硒生物强化研究的前沿问题,以期为改善人体硒营养水平提高人体健康状况提供理论和实践依据。     

Effects of Sulfur and Selenium on Glucosinolate Biosynthesis in Cabbage

Plant Molecular Biology Reporter - The effects of S and Se treatment on cabbage, especially the interactions of S and Se metabolism with the biosynthesis of glucosinolate (GSL), including...     

Effect of Sulfur Nutrition on the Redistribution of Sulfur in Vegetative Soybean Plants

Soybean (Glycine max L.) plants were grown with sulfate at 2 (S2) or 20 [mu]M (S20) and treated with [35S]sulfate between d 36 and 38. Growth was continued with or without 20 [mu]M sulfate (i.e. S2 -> S0, S2 -> S20, etc.). When the leaves of S20 -> S20 plants were 70% expanded, they exported S and 35S label from the soluble fraction, largely as sulfate, to new expanding leaves. However, 35S label in the insoluble fraction was not remobilized. Very little of the 35S label in the soluble fraction of the leaves of S20 -> S0 plants was redistributed; most was incorporated into the insoluble fraction. The low levels of S remobilization from the insoluble fraction were attributed to the high level of N in the nutrient solution (15 mM). Most of the 35S label in S2 plants at d 38 occurred in the soluble fraction of the roots. In S2 -> S0 plants the 35S label was incorporated into the insoluble fraction of the roots, but in S2 -> S20 plants 35S label was rapidly exported to leaves 3 to 6. It was concluded that the soluble fraction of roots contains a small metabolically active pool of S and another larger pool that is in slow equilibrium with the small pool.     

Quantification of Methylated Selenium,Sulfur, and Arsenic in the Environment

Biomethylation and volatilization of trace elements may contribute to their redistribution in the environment. However, quantification of volatile, methylated species in the environment is complicated by a lack of straightforward and field-deployable air sampling methods that preserve element speciation. This paper presents a robust and versatile gas trapping method for the simultaneous preconcentration of volatile selenium (Se), sulfur (S), and arsenic (As) species. Using HPLC-HR-ICP-MS and ESI-MS/MS analyses, we demonstrate that volatile Se and S species efficiently transform into specific non-volatile compounds during trapping, which enables the deduction of the original gaseous speciation. With minor adaptations, the presented HPLC-HR-ICP-MS method also allows for the quantification of 13 non-volatile methylated species and oxyanions of Se, S, and As in natural waters. Application of these methods in a peatland indicated that, at the selected sites, fluxes varied between 190–210 ng Se·m⁻²·d⁻¹, 90–270 ng As·m⁻²·d⁻¹, and 4–14 µg S·m⁻²·d⁻¹, and contained at least 70% methylated Se and S species. In the surface water, methylated species were particularly abundant for As (>50% of total As). Our results indicate that methylation plays a significant role in the biogeochemical cycles of these elements.     

植物硒代谢和积累及相关酶的研究进展

阐述了植物硒代谢的基本途径及其积累的分子机制,详细介绍了几种参与硒代谢的关键性酶的分子生物学特性。并展望了有关植物硒代谢的发展趋势。     

Ethylene and Ethane Production from Sulfur Dioxide-injured Plants

After alfalfa (Medicago sativa) seedlings were exposed to approximately 0.7 microliter per liter SO₂ for 8 hours, elevated ethylene and ethane production was observed. Ethylene production peaked about 6 hours and returned to control levels by about 24 hours following the fumigation, while ethane production peaked about 36 hours and was still above control levels 48 hours after the fumigation. Light had an opposite effect upon the production of the two gases: ethane production rates were higher from plants held in light, whereas ethylene production rates were higher from those held in the dark. Peak ethylene and ethane production rates from SO₂-treated plants were about 10 and 4 to 5 times greater, respectively, than those of the control plants. Ethylene appeared to be formed primarily from stressed yet viable leaves and ethane from visibly damaged leaves. The different time courses and light requirements for ethylene and ethane production suggest that these two gases were formed via different mechanisms. Light appears to have a dual role. It enhances SO₂-induced cellular damage and plays a role for repairs.     

Biotransfer Possibilities of Selenium from Plants Used in Phytoremediation

We are investigating the biotransfer of accumulated Se by the plant in several phytoremediation systems. In study I, we evaluated the biotransfer of Se from Indian mustard, a Brassica species, to the insect-cabbage looper (Trichoplusia ni); mortality, deterrence, and biomagnification of Se were examined. We determined that feeding behavior of food chain consumers was affected not only by the plant concentration of Se, but also by the mobility of the insects and choice of feed available. In study II, we examined the survival and development of beet army worm (Spodoptera exigua) fed Se-enriched plant tissues from different lines of saltbush (Atriplex spp.) After feeding on lines of saltbush that produced high biomass and accumulated high concentrations of Se, insect growth and survival was reduced. In studies III, IV, and V, lambs, dairy cows, and rabbits were fed Se-enriched Brassica and Medicago (alfalfa) plants as part of their feed ration. None of the tested animals exhibited any Se toxicity symptoms, but they had increased levels of Se in most tissues sampled (e.g., organs, blood, urine, feces), excluding milk. In study VI, we evaluated biotransfer of Se from broccoli to rats to determine efficacy of Se for reducing colon cancer. We found that Se-enriched plant material was more effective than inorganic sources of Se for preventing precancerous colon lesions. Results from all studies clearly show that Se absorbed by plants can be transferred biologically in an intentional or unintentional manner to insects and animals.