蓝藻对UV-B增强的响应及其紫外屏蔽物质的研究

紫外线辐射对生物体危害日趋严重,逐渐引起了人们的重视.由于蓝藻在生物进化中的特殊性和在生态系统中的重要性,用于研究UV-B对生物体的影响具有诸多优势,目前国内关于UV-B对蓝藻的影响相关报道较少.本文介绍了近年来国外该领域的相关研究,主要包括UV-B对蓝藻生物量、生理效应,特别是光合作用等方面的影响,同时着重介绍了蓝藻中的紫外吸收物质的研究现状,并进一步探讨了其应用情况.     

UV-B辐射增强对陆地生态系统碳循环的影响

作为全球变化的重要现象之一,紫外射线B(UV-B,波长280～320 nm)辐射增强对陆地生态系统碳循环具有重要影响.UV-B辐射增强主要通过改变植物的光合作用、凋落物分解以及土壤呼吸来影响陆地生态系统碳的输入和转化输出.其他气候因子(大气CO2浓度、温度和水分)可能会促进或减缓UV-B辐射对陆地生态系统碳循环的作用.本文介绍了UV-B辐射增强的背景,综述了国内外近年来UV-B辐射增强及与其他气候因子交互作用对陆地生态系统碳循环的影响,总结了目前研究存在的不足,讨论了未来的研究重点和方向.     

植物对UV-B辐射的响应与调控机制

UV-B(ultraviolet-B)辐射会在多个方面对植物产生影响,随着研究的不断深入,人们发现UV-B除了作为一个胁迫因子外,还会作为信号调节因子来调节植物的生长发育.本文把UV-B辐射对植物形态建成和生理代谢的影响、植物响应UV-B辐射的信号通路以及UV-B与其他因子复合作用对植物的影响等进行了论述,并对植物响应UV-B辐射的研究做了展望.     

UV-B辐射对仙客来的生理效应

通过室内模拟试验,研究了不同强度UV-B辐射(10μW/cm2和20μW/cm2)对仙客来(Cyclamen persicum Mill)生理的影响。结果表明:(1)UV-B辐射的增加对仙客来叶片光合色素的含量具有影响;(2)叶片质膜透性随UV-B辐射强度的增加而增加,随UV-B辐射时间的延长而增加;(3)叶片类黄酮含量随UV-B辐射强度的增加而增加,且在40d时达到最大值;(4)增强UV-B辐射下,仙客来花瓣中的花青素含量增加。     

紫外光源及太阳UV-B辐射的模拟实验

介绍了用于UV-B生物学效应研究的几种常见光源,对如何利用选择性薄膜获得理想的UV-B波段的光谱,进而能较真实模拟平流层O3耗损所导致的近地表面太阳UV-B辐射的增强,以及在野外进行UV-B模拟研究时,紫外荧光灯管的排列方式等进行了分析讨论。介绍并讨论了当前UV-B辐射实验的各种方法,并就各实验设计的注意事项和安全操作等提出了建议。     

螺旋藻对增强的UV-B胁迫的响应

本文研究了实验室条件下增强的uv-B（280-320nm）胁迫对一种蓝藻一钝顶螺旋藻（Spirulina platensis）794生物量、色素和蛋白、细胞内MDA含量及活性氧产生的影响。结果表明,在增强的uV-B胁迫下,螺旋藻的生物量减少,细胞内叶绿素a和类胡萝卜素含量降低,从而使螺旋藻的生长发育受到一定程度的抑制,而细胞浆蛋白质含量增加,这可能是螺旋藻对逆境胁迫的一种适应性反应。增强UV-B胁迫下,螺旋藻细胞内MDA含量增加,与之相对应,活性氧的产生速率也增加,进一步证实了逆境胁迫下,植物细胞内叶绿素含量的下降、MDA的积累主要与UV-B胁迫下活性氧的产生及其对细胞的氧化损伤有关。     

紫外线-B辐射对植物DNA及蛋白质的影响

大气平流层中的臭氧衰减,导致太阳辐射中的紫外辐射量有明显的增加,其中UV-B辐射对植物会产生不同程度的影响。分子生态学理论认为,UV-B辐射对植物造成的损伤,首先伤害植物的生物大分子,即进行光化学修饰。本文就臭氧衰减对生态环境和植物的影响途径进行了讨论,重点论述了UV-B辐射对植物蛋白质合成的抑制和DNA的损伤修复途径。并应用分子生物学技术研究植物对UV-B辐射的抗性机理和DNA修复技术的前景进行了展望。     

UV-B辐射增强对陆地植物次生代谢的影响

平流层臭氧的减薄已导致地表中波紫外辐射(UV-B,280～320nm)增强,由于UV-B能被许多生物大分子如蛋白质和核酸吸收并引起分子构象的变化,因此可对植物的各方面产生影响。本文将近年来特别是近5年的UV-B辐射增强对植物次生代谢物影响的研究工作进行了综述。主要包括：UV-B辐射增强对植物紫外吸收物的影响和可能的机制;环境因子的复合作用对植物紫外吸收物的影响和可能的机制;UV-B辐射增强对次生代谢物影响的生态学意义。并对该领域未来的研究作了展望。     

植物响应UV-B辐射的研究进展

地表UV-B辐射的增强对植物的生长生理产生了多方面影响。随着研究的不断深入, 人们认识到UV-B辐射不仅是一种胁迫因子, 而且是一个重要的信号调节分子。该文论述了近年来植物响应UV-B辐射研究的一系列成果, 包括UV-B辐射对植物形态建成、生理代谢、UV-B光受体UVR8蛋白、细胞程序性死亡、细胞骨架和细胞周期的影响, 及其它因素与UV-B复合处理对植物的作用; 并对植物响应UV-B辐射研究进行了望。     

UV-B辐射增强对植物影响的研究进展

UV-B辐射的增强对植物的影响是目前科学研究的热点之一。本文综述了国内外有关UV-B辐射增强对植物影响的研究现状与动态,讨论了在增强了UV-B辐射时,植物在生长发育、生理形态、光合作用、物质次生代谢、抗氧化系统和分子防御反应等多个层次的变化,同时还探讨了UV-B辐射与其它环境因素联合作用对植物的影响。并展望了UV-B辐射对植物的影响领域中值得深入探讨的问题。     

增强紫外B辐射对植物及生态系统影响研究的发展趋势

介绍了一些有关紫外B辐射增强对植物及生态系统影响研究的新进展：1．许多研究已深入到分子水平;2．注意到对植物生长调控的研究;3．更加重视对植物防御、修复的研究;4．有关信号传导的研究日渐增多;5．对植物群体及生态系统影响的研究在不断扩大与加深;6．复合效应研究正在升温。推断今后在一段时间内,有关UV－B辐射对植物和生态系统影响的研究不但不会削弱,可能还会加强,特别分子水平的研究会大大增加,今后对群体和生态系统的研究会重视野外和长期效应的观测。我国在这一领域的研究起步晚,但近些年发展得较快,有部分研究已赶上国际研究进展的步伐。     

UV-B辐射胁迫对杨桐幼苗生长及光合生理的影响

通过对UV-B辐射胁迫下亚热带典型木本杨桐幼苗的生长及光合生理的研究,探讨植物对于UV-B辐射胁迫的生理响应及适应性机理,进而揭示UV-B辐射变化对亚热带森林树种的影响.实验设置UV-B辐射滤光组、自然光对照组以及辐射增强组,选择亚热带典型树种杨桐(Cleyera japonica Thunb.)幼苗为实验材料.研究结果表明:(1)增强UV-B辐射会降低杨桐幼苗的叶绿素含量,而降低辐射则会显著促进叶绿素的增加,且这种胁迫在时间上具有积累性.(2)增强或降低辐射强度都会抑制杨桐地径的生长,增强辐射会产生更显著的抑制;降低辐射强度会对杨桐幼苗的株高生长产生促进作用,反之,则会抑制其生长.3个测定期数据综合分析显示随着处理时间的加长,这种胁迫作用有减小的趋势.(3)对光响应曲线的分析表明相对于自然光条件下的UV-B辐射,降低其强度对杨桐幼苗光合作用有显著的促进作用,反之则会抑制,不过抑制作用并不显著;对于光合特征参数的分析表明增强或降低UV-B辐射会显著降低杨桐幼苗的光饱和点(LSP)和光补偿点(LcP),而对最大净光合速率(Amax)、表观光合量子效率(AQY)、暗呼吸速率(Rd)影响均不显著,表明辐射胁迫对杨桐幼苗利用光能的效率影响不大,从而也并未对杨桐的光合作用产生显著性的伤害,但是由于森林树种的多年生特性,这种影响将是积累性的或延迟的,UV-B所造成的光合作用或光能利用率的微小变化都可能会积累成长期影响.因此,对森林树种进行长期研究是必要的.     

植物对增强UV-B辐射和SO2的响应(综述)

酸雨、温室效应和地球臭氧层的破坏是目前世界上最受关注的环境问题。由于臭氧层的破坏而导致的大气ＵＶ－Ｂ辐射的增加以及空气中ＳＯ２污染的加剧都会严重影响到植物和动物的生命活动。本文回顾和简述了近二十年来这两种环境胁迫因子对植物影响的研究概况。     

The effects of increased UV-B radiation on growth,pollination success,and lifetime female fitness in two Brassica species

The increasing levels of ultraviolet-B (UV-B) radiation reaching the earth's surface caused by ozone destruction have prompted many studies of UV-B effects on plants. Most of these studies have focused on physiological and growth responses of plants to increased UV-B, but these measures may not be closely related to future survival of plant populations. We examined the effects of two different levels of increased UV-B on total female fitness, including seed number and quality, in rapid-cycling strains of Brassica nigra and B. rapa (Brassicaceae). We also measured the effects of UV-B on fitness components, particularly those related to pollination success. Two separate experiments, examining two different levels of UV-B, were performed. Sixty plants of each species were grown under control and enhanced levels of UV-B for a total of 480 plants (60 plantsx2 speciesx2 UV-B levelsx2 experiments). Increased UV-B was generally detrimental to growth and flowering in both species; however, total seed production was actually greater at higher UV-B doses in three of four dose/plant species combinations examined. UV-B had little effect on pollination success or offspring quality in either species. Therefore, in spite of the detrimental effects of UV-B on growth and flowering that we found, there is little evidence that fitness of these plant species would suffer with increasing UV-B, and we caution against using solely physiological or growth measurements to infer effects of UV-B on plant population fitness.     

The role of interactions between trophic levels in determining the effects of UV-B on terrestrial ecosystems

Understanding the potential impact of ozone depletion on terrestrial ecosystems is constrained by lack of information on the effects of environmentally realistic UV-B doses on terrestrial organisms other than higher plants. Increasing UV-B may alter interactions between plants and consumers through direct effects on consumer organisms (herbivores, phytopathogens, decomposers, etc.). The effects of increasing UV-B on arthropods are not known. Significant UV-B effects on fungi have been reported, and may be either negative (inhibition of spore germination and mycelial growth) or positive (increased growth, induction of reproductive development and sporulation). However, in many cases consumers are unlikely to be directly exposed to UV-B in the field. In addition, UV action spectra for fungi suggest that this major group may be less sensitive to the effects of ozone depletion than higher plants. Host mediated effects of UV-B on consumers may include alterations in plant chemistry. While secondary metabolites such as phenolics may increase under increased UV-B, this is not invariably the case and evidence that such changes have significant effects on consumers is limited. In particular, there is no evidence that increased UV-B increases resistance of higher plants to fungal pathogens. Indeed, increased UV-B prior to inoculation results in no significant effect or increased disease. Such responses may be attributable to UV-B effects on host surface properties or on compounds other than phenolics. However, such changes are poorly known, and their potential effects on phytopathogens, herbivores or decomposers cannot be assessed. Understanding the effects of UV-B on terrestrial ecosystems is further limited since virtually nothing is known of possible impacts on higher trophic levels, i.e. predators, parasites or pathogens.     

The response of Vicia faba to enhanced UV-B radiation under low and near ambient PAR levels

The effects of enhanced UV-B are often overestimated in greenhouse studies due to low levels of photosynthetically active radiation (PAR). For this reason, we studied effects of enhanced UV-B (12 kJ m^–2 d^–1) at low and near ambient PAR levels on young vegetative plants of Vicia faba, in the greenhouse. It was hypothesized that near ambient PAR levels could reduce the negative UV-B effects on growth, due to higher amounts of UV-B absorbing compounds in the leaves and to morphological changes attenuating UV-B damage.We found that effects of enhanced UV-B on the growth were not negative. We found an increase in biomass in response to enhanced UV-B at low and near ambient PAR levels. The increase in biomass was related to increased branching, which leads to a higher interception of PAR. Enhanced irradiance of both PAR and UV-B had similar photomorphogenic effects: thicker and smaller leaves and reduced plant height and internode length. Moreover, the concentration of UV-B absorbing compounds was increased. We conclude that in this study effects of enhanced UV-B were mainly photomorphogenic effects, which were also induced by radiation in the PAR region.     

Outdoor Studies on the Effects of Solar UV-B on bryophytes: Overview and Methodology

In this review all recent field studies on the effects of UV-B radiation on bryophytes are discussed. In most of the studies fluorescent UV-B tubes are used to expose the vegetation to enhanced levels of UV-B radiation to simulate stratospheric ozone depletion. Other studies use screens to filter the UV-B part of the solar spectrum, thereby comparing ambient levels of UV-B with reduced UV-B levels, or analyse effects of natural variations in UV-B arising from stratospheric ozone depletion. Nearly all studies show that mosses are well adapted to ambient levels of UV-B radiation since UV-B hardly affects growth parameters. In contrast with outdoor studies on higher plants, soluble UV-B absorbing compounds in bryophytes are typically not induced by enhanced levels of UV-B radiation. A few studies have demonstrated that UV-B radiation can influence plant morphology, photosynthetic capacity, photosynthetic pigments or levels of DNA damage. However, there is only a limited number of outdoor studies presented in the literature. More additional, especially long-term, experiments are needed to provide better data for statistical meta-analyses. A mini UV-B supplementation system is described, especially designed to study effects of UV-B radiation at remote field locations under harsh conditions, and which is therefore suited to perform long-term studies in the Arctic or Antarctic. The first results are presented from a long-term UV-B supplementation experiment at Signy Island in the Maritime Antarctic.