植物种间和种内的化学作用

植物间相互作用是生态学基础科学问题之一,植物能感受和识别共存同种或异种植物,进而调整生长、繁殖和防御策略。植物种间和种内的感受和识别大多是由植物产生释放的次生物质所介导,这类化学识别通讯可以启动相应的植物化感作用机制。近年发现,植物亲属间也存在着化学识别、地下根系通讯调控地上开花繁殖等植物种间和种内的化学作用关系。目前植物通过地上挥发物介导的植物化学作用已基本澄清,但根分泌物介导的植物地下化学作用机制及其信号物质还所知甚少。地下化学作用不仅决定根系侵入(接近)和躲避(排斥)行为,也能调控地上开花时间和花期。这样,植物间的化学作用还涉及植物地下和地上的协调互作。本文以植物化感作用和植物化学识别通讯及相应的化感物质和信号物质为基点,从植物亲属识别、根系化学识别和行为模式、地下化学作用调控地上开花繁殖3个方面综述植物种间和种内化学作用的研究进展,为全面理解植物间相互作用提供新视野。     

动物尿液化学通讯的研究进展

动物通讯是动物个体通过不同的信息交流方式实现信息传递及共享的过程。尿液是动物化学通讯中传递和分享信息的重要信号来源,尿液化学通讯是动物种内乃至种间信息交流的重要途径之一。本文阐述了不同物种之间信息交流和相同物种不同个体之间的尿液化学通讯,对于了解动物个体尿液化学成分组成、繁殖、行为以及社会识别等具有重要的生物学意义。     

21世纪植物化学生态学前沿领域

植物和其它有机体通过次生物质为媒介的化学作用关系近年引入注目,其中植物的诱导化学防御,植物的化学通讯,植物次生物质和进化的关系,植物与人类的化学关系和海洋植物化学生态学是21世纪植物化学生态学值得关注的前沿领域。植物化学生态学前沿领域的进展将为实现21世纪的持续,发展是在生态安全条件下提高农业产量并达到对病虫草害的有效控制方面具有重要意义。     

转基因抗虫植物-植食性昆虫-天敌间化学通讯的研究进展

植物或昆虫释放的化学信息物质在植物-植食性昆虫-天敌三级营养层信息通讯中发挥重要作用.这种生物间的信息交流形成信息网,调节生物种内和种间行为,支撑和维持植物和昆虫群落的组成和结构.转基因抗虫植物的应用可能会影响三级营养层间的化学信息通讯,进而干扰生物群落结构和农田生态系统稳定性.该方面已在全球范围内引起了转基因抗虫作物环境安全研究者的关注.本文对植物-植食性昆虫-天敌间化学信息通讯进行了简要概括;分析和归纳了转基因抗虫作物的种植对植物和节肢动物间化学通讯的潜在影响及相关机制;讨论了该领域当前的研究进展和未来研究前景.以期促进我国科学家在该领域的研究,加深对转基因抗虫作物群落结构动态潜在影响的理解.     

植物次生物质对于植物生存的重要作用

植物次生物质在植物生存中抵御动物和微生物的侵害,参与同其他植物的生存竞争以及进行植物间化学通讯等方面具有重要的作用。植物次生物质的产生是植物化学保护的必然结果。简要介绍植物次生物质的合成途径。     

蜜蜂的行为

简要介绍了蜜蜂的生活方式（独栖性,社会性和盗寄生性）,全年的生活周期;筑巢地点的选择和建造巢房的工艺,采食花粉,花蜜的习性和酿蜜的过程,蜜蜂种群内部及与植物间的信息传递方式,化学通讯是主要藉化学信息物质保持蜂群的内在联系,行为和物理通讯,主要是通过蜜蜂的“舞蹈”和光,声等因素传递蜜源植物的方位及距离等。     

转录因子的胞间移动在植物生长发育中的作用

多细胞生物体的生长发育依赖于细胞和细胞之间物质的交流和信号的传递。细胞命运的特化受到来自旁临细胞信息的调控。作为细胞-细胞通讯方式之一的蛋白质胞间运输广泛的存在于植物各种发育过程中。本文总结了近年来有关植物重要发育调控转录因子在细胞间移动的研究进展,综述了这些因子移动的细胞学基础和分子调控模型,并对今后蛋白胞间移动研究面临的挑战和需引入的新技术手段进行了展望。     

蝗虫化学信息物质研究进展

详述了蝗虫主要化学信息物质的种类、功能及主要成分等研究进展。蝗虫化学信息物质包括种内通讯的化学信息素和种间通讯的化学信息物质。其中种内通讯的化学信息素主要有群居信息素、成熟信息素、产卵信息素(含促产卵化学信息素和群集产卵化学信息素)、性信息素、聚集信息素等;种间通讯的化学信息物质主要介绍用于防卫的化学信息物质,包括卵分泌的信息物质、特定腺体分泌的信息物质、粪便挥发的信息物质、口腔分泌物和内部毒素等,对其天敌均有一定的防卫作用。化学通讯是蝗虫种内和种间通讯联系的普遍方式。     

植物挥发性信号物质介导抗性的生态功能

植物产生的挥发性化合物能够作为媒介参与植物与周围环境之间的信息交流及相互作用。植物挥发性物质在吸引传粉者、促进种子传播、抑制其它植物种子萌发等方面具有重要的作用。近年来,关于植物挥发性物质在生态系统中的信号作用研究已经成为国内外的研究热点,受到广泛关注。总结了植物挥发性物质作为信号物质在提高植物抗性方面的国内外研究成果,阐述了植物挥发性物质不仅能够直接提高植物的抗性,而且可以作为信号物质在同株、同种异株和不同种植物之间进行传递,进而间接提高目标植物的抗性。最后,还对植物挥发性物质的研究方法和潜在的生态功能进行了探讨。     

植物抗逆性与水杨酸介导的信号传导途径的关系

基因表达既受发育过程的调控又受外界环境的影响。无论是内因还是外因诱发一组基因表达时都涉及信号传导(signal transduction)问题。局部器官和组织所发生的生理变化的信息要传递到远处的组织,引起基因表达时间和空间上的协调。信号传导途径的研究是当今分子生物学的研究热点之一。 作为信号传递的分子主要是小分子物质,属于次生代谢产物。也发现某些小肽具有信号分子的功能。信号分子可以在胞间扩散,亦可通过输导组织传送到远处的器官。近年来研究甚多的一种信号     

Impact of fertilizer type and rate on carbon and nitrogen pools in a sandy Cambisol

Diversity, structure and productivity of above-ground compartment of terrestrial ecosystems have been generally considered as the main drivers of the relationships between diversity and ecosystem functioning. More recently it has been suggested that plant population dynamics may be linked with the development of the below-ground community. The biologically active soil zone where root-root and root-microbe communications occur is named “Rhizosphere” where root exudates play active roles in regulating rhizosphere interactions. Root exudation can regulate the soil microbial community, withstand herbivory, facilitate beneficial symbioses, modify the chemical and physical soil properties and inhibit the growth of competing plant species. In this review, we explore the current knowledge assessing the importance of root exudates in plant interactions, in communications between parasitic plants and their hosts and how some soil microbial components could regulate plant species coexistence and change relationships between plants. This review will be focussed on several well documented biological processes regulating plant-plant communications such as exotic plant species invasions, negative root-root communication (allelopathy) and parasitic plant / host plant interactions and how some soil microbial components can interfere with signal traffic between roots. The reported data show that the overall effect of one plant to another results from multiple interacting mechanisms where soil microbiota can be considered as a key component.     

Plant-nematode interactions: environmental signals detected by the nematode's chemosensory organs control changes in the surface cuticle and behaviour

Plant parasitic nematodes have developed the capacity to sense and respond to chemical signals of host origin and the ability to orientate towards plant roots enhances the nematode's chance of survival. Root exudates contain a range of compounds which mediate belowground interactions with pathogenic and beneficial soil organisms. Chemical components of root exudates may deter one organism while attracting another and these compounds alter nematode behaviour and can either attract nematodes to the roots or result in repellence, motility inhibition or even death. In vitro, plant signals present in root exudates, trigger a rapid alteration of the surface cuticle of Meloidogyne incognita and the same changes were also induced by indole-acetic acid (IAA). IAA binds to the chemosensory organs of M. incognito and it is possible that IAA acts as a signal that orientates the nematode on the root surface in the rhizosphere and/or inside the root tissue and thereby promotes nematode infection.     

植物的环境信号分子茉莉酸及其生物学功能

茉莉酸信号分子参与植物生长发育众多生理过程的调控,尤其是作为环境信号分子能有效地介导植物对生物及非生物胁迫的防御反应。迄今已知具有信号分子生理功能的至少包括茉莉酸(jasmonic acid,JA)以及茉莉酸甲酯(methyl jasmonate,Me JA)和茉莉酸-异亮氨酸复合物(jasmonoyl-isoleucine,JA-Ile)等茉莉酸衍生物,统称为茉莉酸类化合物(jasmonates,JAs)。从环境信号分子角度介绍了茉莉酸信号的启动(环境信号感知与转导、茉莉酸类化合物合成)、传递(局部传递、维管束传输、空气传播)和生物学功能(茉莉酸信号受体、调控的转录因子、参与的生物学过程)。     

植物间挥发物信号的研究进展

植物VOCs信号是植物间进行信息交流的“语言”, 可由多种生物和非生物因素诱导产生。非寄生植物释放的VOCs信号可影响其所在群落中其它植物的种子萌发与幼苗生长; 而寄主植物释放的VOCs信号却是诱导寄生植物种子萌发和幼苗生长的信号物质。VOCs作为植物间的伤害信息可以诱导临近的同种或异种植物做好防御准备, 从而通过主动或间接防御以减少外界的伤害。植物间通过VOCs信号进行信息交流, 从而实现其繁衍与防御。该文通过对VOCs信号的种类、诱导产生因素、传递及作用进行综述, 以期对VOCs信号的研究有所帮助。     

Increasing flavonoid concentrations in root exudates enhance associations between arbuscular mycorrhizal fungi and an invasive plant

Many invasive plants have enhanced mutualistic arbuscular mycorrhizal (AM) fungal associations, however, mechanisms underlying differences in AM fungal associations between introduced and native populations of invasive plants have not been explored. Here we test the hypothesis that variation in root exudate chemicals in invasive populations affects AM fungal colonization and then impacts plant performance. We examined flavonoids (quercetin and quercitrin) in root exudates of native and introduced populations of the invasive plant Triadica sebifera and tested their effects on AM fungi and plant performance. We found that plants from introduced populations had higher concentrations of quercetin in root exudates, greater AM fungal colonization and higher biomass. Applying root exudates more strongly increased AM fungal colonization of target plants and AM fungal spore germination when exudate donors were from introduced populations. The role of root exudate chemicals was further confirmed by decreased AM fungal colonization when activated charcoal was added into soil. Moreover, addition of quercetin into soil increased AM fungal colonization, indicating quercetin might be a key chemical signal stimulating AM fungal associations. Together these results suggest genetic differences in root exudate flavonoids play an important role in enhancing AM fungal associations and invasive plants’ performance, thus considering root exudate chemicals is critical to unveiling mechanisms governing shifting plant-soil microbe interactions during plant invasions.Subject terms: Population dynamics, Community ecology, Plant ecology     

Plant age and genotype impact the progression of bacterial community succession in the Arabidopsis rhizosphere

The rhizosphere is strongly influenced by plant-derived phytochemicals exuded by roots and plant species exert a major selective force for bacteria colonizing the root-soil interface. We have previously shown that rhizobacterial recruitment is tightly regulated by plant genetics, by showing that natural variants of Arabidopsis thaliana support genotype-specific rhizobacterial communities while also releasing a unique blend of exudates at six weeks post-germination. To further understand how exudate release is controlled by plants, changes in rhizobacterial assemblages of two Arabidopsis accessions, Cvi and Ler where monitored throughout the plants'' life cycle. Denaturing gradient gel electrophoresis (DGGE) fingerprints revealed that bacterial communities respond to plant derived factors immediately upon germination in an accession-specific manner. Rhizobacterial succession progresses differently in the two accessions in a reproducible manner. However, as plants age, rhizobacterial and control bulk soil communities converge, indicative of an attenuated rhizosphere effect, which coincides with the expected slow down in the active release of root exudates as plants reach the end of their life cycle. These data strongly suggest that exudation changes during plant development are highly genotype-specific, possibly reflecting the unique, local co-evolutionary communication processes that developed between Arabidopsis accessions and their indigenous microbiota.Key words: rhizobacterial succession, rhizobacterial communities, natural variation, root exudates, Arabidopsis accessions     

Jasmonates promote cabbage (Brassica oleracea L. var Capitata L.) root and shoot development

Jasmonates are a new group of plant hormones; their roles on plant development are still little known. The aim of this work is to determine the action of jasmonates on cabbage, Brassica oleracea L. var Capitata, development both in in vitro cultured explants and in whole plants. Jasmonic acid (JA) enhanced nodal explant development when applied at 2–50 nM and inhibited it when supplied at 1250 and 6000 nM JA. Overall plant development was enhanced most under the 10 nM JA treatment; which significantly increased the explant shoot, leaf, and root dry weight. The root system of the explants cultured under the lower JA concentrations appeared more vigorous. Jasmonic acid also promoted the development of isolated in vitro cultured roots when applied at 2 and 10 nM. Root length and weight significantly increased, while concentrations 250 nM JA and over were detrimental. Isolated roots were progressively thicker as the JA concentration increased. Methyl jasmonate promoted both the below- and above-ground cabbage plant development when applied in a confined atmosphere at a concentration of only 1.225 nl.l^–1 MJ: plants were higher and heavier, and showed an improved root system development. On the other hand, the 2.43 nl.l^–1 MJ treatment decreased plant growth. The present work reveals a role for jasmonates as enhancers of in vitro and in vivo cabbage plant development. To our knowledge, no corresponding studies on the effects of jasmonates on whole plants have been previously published.     

植物-昆虫间的化学通讯及其行为控制

在植物与昆虫间的化学通讯中植物气味物质起着决定性的作用,它调控着昆虫的多种行为,诸如引诱昆虫趋向寄主植物,刺激昆虫取食,引导昆虫选择产卵场所,进行传粉和防御昆虫等。有些植物则当受到食植性昆虫危害时会释出一些引诱害虫天敌的化学信号。这些化学信号是一些挥发性萜类混合物,天敌昆虫就以此来区分受害和未受害植株。尽管目前在害虫综合治理中,昆虫信息素的应用越来越显得比天然植物气味源更受重视,但是必须指出的是,昆虫信息化合物首次成功地使用于植物保护的却是天然植物气味源。在利用植物气味源作害虫测报和防治中,近年来一种简单价廉的粘胶诱捕器己成为多种害虫的标准测报工具。在害虫综合治理中利用植物气味源的技术显然是具有不可估量的潜力。文中提出了利用基因工程技术来改造植物,使植物能释放特定的驱避剂或其它控制昆虫行为的特殊气味物质的新概念。     

Methyl jasmonate increases reported alkamides and ketoalkene/ynes in Echinacea pallida (Asteraceae)

Methyl jasmonate (MJ), a naturally-occurring plant cellular signal molecule, was found to induce production of lipophilic secondary metabolites in Echinacea pallida seedlings. Seedling aerial parts were sprayed with 100 ppm MJ, and roots were harvested and extracted 24 h later. Lipophilic root extracts, separated by HPLC, revealed significant increases (P< 0.05) in six alkamides or related ketoalkene/ynes produced by 34 day-old plants and in seven compounds produced by 58 day-old plants.