腐解6个月后杉木枯枝落叶及腐殖土中的化感成分对杉木种子的化感效应

对腐解6个月后杉木[Cunninghamia lanceolata（Lamb．）Hook．]枯枝落叶及腐殖土中的化感成分进行了提取分离及生物检测。结果表明,枯枝落叶及腐殖土中的极性和弱极性化感成分对杉木种子的绝对发芽率、绝对发芽势、胚根长和胚轴长均有一定的抑制作用。随浓度的提高,枯枝落叶中的弱极性化感成分对绝对发芽率、胚轴长及幼苗干质量的抑制作用及极性化感成分对绝对发芽势、胚轴长的抑制作用均逐渐增强;腐殖土中的弱极性化感成分对绝对发芽率、绝对发芽势、胚根长及胚轴长的抑制作用及极性化感成分对胚轴长的抑制作用也逐渐增强。枯枝落叶中的化感成分对绝对发芽率、绝对发芽势及幼苗干质量的抑制效应高于腐殖土中的化感成分。     

沉水植物化感作用控藻能力评述

沉水植物所释放的化学物质对藻类的抑制作用是浅水湖泊维持清水状态的机制之一.本文从具有化感活性的沉水植物在湖泊中出现的频度、盖度、化感物质的种类、抑藻效应等方面对化感控藻进行了评述.已有研究结果表明：穗花狐尾藻、金鱼藻、伊乐藻等是具有很高活性的沉水植物,尤其是在其生物量达到一定程度,且湖泊中的优势藻为较敏感的种类时,沉水植物分泌的化感物质对浮游藻类的抑制作用更强;沉水植物释放的多酚类等化感物质具有控藻能力;化感物质对于不同种类藻的抑制作用具有选择性,蓝藻和硅藻比绿藻更为敏感,附生藻类通常比浮游藻类具有更高的耐受性;环境因素如光照、营养限制、温度等会显著影响沉水植物化感作用效果.沉水植物的化感控藻研究尚处于初始阶段,关于环境因素对化感作用的影响、化感物质的分离鉴定、选择性抑藻机理以及化感物质代谢途径等方面还有待深入、全面的研究.     

红树植物干粉和新鲜组织水提物对两种赤潮藻的化感抑制效应

通过测定藻细胞密度,研究了5种红树植物木榄、秋茄、海漆、海芒果、小花老鼠簕水提物对赤潮藻球形棕囊藻和赤潮异弯藻的化感抑制效应,探讨了高温处理对化感抑藻效应的影响.研究结果表明,红树植物干粉水提物和新鲜组织水提物对两种赤潮藻均显示出显著的化感抑制作用.第5 d,红树植物干粉水提物对2种赤潮藻的抑制效果依次为:海漆>秋茄>小花老鼠簕>木榄>海芒果.新鲜组织水提物抑藻效果最强的红树植物是木榄和秋茄.秋茄和海漆水提物中的抑藻化感物质对高温相对不稳定,木榄和小花老鼠簕水提物中的抑藻化感物质对高温相对比较稳定.     

化感作用水稻对无芒稗及相关田间杂草的抑制作用评价

对从500份水稻种质资源中用差时播种共培法的改进方法初步筛选出10份水稻化感抑稗材料进行了田间化感抑草评价研究.结果表明,在直播条件下,化感材料谷梅2号、吓一跳、鸡早籼、赣早籼和商糯1号等对无芒稗的抑制作用显著优于水稻无化感作用材料秀水63和春江11.化感材料Milyang54对田间总量杂草的抑制作用最强.在移栽条件下,化感材料谷梅2号、青困2号、吓一跳和鸡早籼对无芒稗的抑制作用与无化感作用材料秀水63和春江11差异及显著性水平.水稻材料间部分农艺性状差异及显著性水平,化感材料吓一跳和鸡早籼的株高较高,分蘖力较强,但顶三叶叶面积较小.     

小麦根系分泌物对黄瓜生长及土壤真菌群落结构的影响

以黄瓜为受体,以不同化感效应(促进/抑制)小麦品种为供体,采用PCR-DGGE技术,研究了小麦根系分泌物及伴生小麦对黄瓜生长及土壤真菌群落结构的影响.结果表明： 在处理第6天和第12天,化感促进效应小麦根系分泌物分别显著提高了黄瓜幼苗株高和茎粗;在处理第18天,化感促进和抑制效应小麦根系分泌物均显著提高了黄瓜幼苗株高;在处理第6天,不同化感效应小麦根系分泌物均显著降低了黄瓜幼苗根际土壤真菌群落条带数、Shannon指数及均匀度指数,有苗对照(W)显著高于无苗对照(Wn);在处理第18天,各处理的真菌群落结构条带数、Shannon指数及均匀度指数均显著高于无苗对照(Wn).伴生化感抑制效应小麦显著降低了黄瓜根际土壤真菌群落Shannon指数和均匀度指数,说明小麦根系分泌物及伴生小麦改变了土壤真菌群落结构.DGGE图谱及其主成分分析结果表明,伴生不同化感效应小麦对土壤真菌群落结构影响较大.     

三七自毒与化感作用初步研究

采用生物测定方法,对三七的自毒与化感作用进行初步研究。结果表明:(1)三七种子萌发过程中的自毒作用随其播种密度不同而有一定差异,但无明显规律性。三七种子萌发过程中的分泌物对油菜生长具有化感作用,主要表现为对油菜种子发芽率、发芽指数及苗高的抑制效应;(2)三七水浸液对不同受体植物的化感作用不尽相同,对小麦主要表现为对苗鲜重、苗干重、根鲜重、苗高及须根数有不同程度的促进或抑制作用;对油菜则表现为对其种子发芽率具有抑制作用,而对苗鲜重、苗干重、根鲜重、最长根长具有促进作用;(3)三七存在明显的化感自毒作用,其自毒物质可能为影响其连作的一个重要因素。     

化感作用抑制有害藻类生长的研究进展

利用植物化感作用抑制有害藻类生长的方法具有生态安全性好、快速高效等优点, 为有效控制有害藻类的爆发提供了新思路。论文从化感作用的概念、化感抑藻机理、陆生植物对藻类的化感抑制作用、水生植物对藻类的化感抑制作用等方面进行了论述, 并对植物化感作用抑藻技术的研究方向进行了展望, 提出对化感物质在环境中的降解特性、化感物质选择性抑藻机理及具有活性的化感物质的人工合成等方面需要做更深入的研究。     

本氏针茅根际土提取物对本氏针茅及其优势种种子萌发的影响

以本氏针茅及其优势种大针茅和百里香种子为受体,采用生物检测的方法研究了0(对照)、0.1、0.2和0.5g/mL本氏针茅根际土甲醇浸提液和水浸提液对3种受体种子萌发的影响,以探究草地演替过程中物种间的生态关系和化感作用的表现形式。结果显示:(1)甲醇浸提液对3种受体种子的发芽均有抑制作用;水浸提液对本氏针茅发芽有促进作用,对百里香有部分促进作用,而对大针茅有抑制作用。(2)甲醇浸提液对本氏针茅和大针茅胚根和胚芽生长无显著影响,而抑制百里香胚根和胚芽的生长;水浸提液对本氏针茅胚根生长无显著影响,对本氏针茅胚芽生长具有显著促进作用,而对其它两种受体胚根和胚芽均无显著影响。(3)各种浓度甲醇浸提液对大针茅和百里香生长表现出了化感综合抑制效应,对本氏针茅生长于0.2g/mL时表现出化感综合抑制效应,其它2种浓度(0.1、0.5g/mL)表现为化感综合促进效应;水浸提液对本氏针茅和百里香表现为化感综合促进效应,而对大针茅表现为化感综合抑制效应。研究表明,本氏针茅根际土甲醇浸提液和水浸提液的化感物质存在差异;不同受体对同一浸提液反应不同,同一受体对不同浸提液的反应也不同。     

化感物质对植物根系形态属性影响的meta分析

植物化感作用是通过释放到环境中的化感物质直接或间接影响受试植物生长而实现的。化感物质主要作用于根系,所以植物根系属性是化感作用研究的重要指标之一。目前,关于受试植物形态属性对外源化感物质的响应模式尚缺乏整体的认识。为此,本文对61篇有关纯化感物质(包括酚类、萜类和含氮化合物等)对植物根系形态属性(尤其是根长)影响的文献进行整合分析。结果发现: 整体上化感物质处理显著抑制根长,而对根生物量、根表面积和根体积等形态属性影响较小;酚类对根长的抑制效应最大,且化感物质对草本植物根长的抑制率高于木本、作物和其他植物;酚类与根长抑制效应呈显著的线性相关。进一步量化了4种典型酚酸——阿魏酸、对羟基苯甲酸、香草酸和肉桂酸的浓度-效应关系,证实了黄酮对受试植物根长的抑制效应显著高于酚酸类化感物质。受试植物根系属性对化感物质的响应主要受化感物质类型和添加浓度、植物种类与培养条件等多因素影响,建议未来研究在土壤环境条件下综合评价化感物质对受试植物根系形态和生理属性以及根系构型等参数的影响机制。     

腐解3个月后杉木枯枝落叶及腐殖土中的化感成分对杉木种子的化感效应

对腐解3个月后杉木〔Cunninghamia lanceolata(Lamb.) Hook.〕枯枝落叶及腐殖土中的化感成分进行了提取分离,并用杉木种子进行了生物检测。结果表明,与对照相比,杉木枯枝落叶中的极性和弱极性化感成分以及腐殖土中的弱极性化感成分对杉木种子的绝对发芽率、绝对发芽势、胚根长和胚轴长均有一定的抑制作用,但对幼苗干质量的抑制作用不明显。随浓度的提高,杉木枯枝落叶中的弱极性化感成分对杉木种子的绝对发芽势和胚轴长的抑制作用明显提高,极性化感成分对胚根长的抑制作用不断减小。随腐殖土中弱极性化感成分浓度的提高,对杉木种子绝对发芽率的抑制作用增加;腐殖土中的极性化感成分对杉木种子的绝对发芽率、绝对发芽势及胚轴长的抑制作用均随着浓度的升高而逐渐增强。     

Allelopathy of Aquatic Autotrophs

Allelopathy in aquatic environments may provide a competitive advantage to angiosperms, algae, or cyanobacteria in their interaction with other primary producers. Allelopathy can influence the competition between different photoautotrophs for resources and change the succession of species, for example, in phytoplankton communities. Field evidence and laboratory studies indicate that allelopathy occurs in all aquatic habitats (marine and freshwater), and that all primary producing organisms (cyanobacteria, micro- and macroalgae as well as angiosperms) are capable of producing and releasing allelopathically active compounds. Although allelopathy also includes positive (stimulating) interactions, the majority of studies describe the inhibitory activity of allelopathically active compounds. Different mechanisms operate depending on whether allelopathy takes place in the open water (pelagic zone) or is substrate associated (benthic habitats). Allelopathical interactions are especially common in fully aquatic species, such as submersed macrophytes or benthic algae and cyanobacteria. The prevention of shading by epiphytic and planktonic primary producers and the competition for space may be the ultimate cause for allelopathical interactions. Aquatic allelochemicals often target multiple physiological processes. The inhibition of photosynthesis of competing primary producers seems to be a frequent mode of action. Multiple biotic and abiotic factors determine the strength of allelopathic interactions. Bacteria associated with the donor or target organism can metabolize excreted allelochemicals. Frequently, the impact of surplus or limiting nutrients has been shown to affect the overall production of allelochemicals and their effect on target species. Similarities and differences of allelopathic interactions in marine and freshwater habitats as well as between the different types of producing organisms are discussed. Referee: Dr. Friedrich Jüttner, Universität Zürich-Limnologische Station, Institut für Pflanzen biologie, Universität Zürich, Seestrasse 187, Ch-8802 Klichberg ZH, Switzerland     

Algal allelopathy

The comprehensive review on allelopathy (Rice, 1979, 1984) has been largely responsible for the evolution of allelopathy as an independent branch of chemical/ physiological ecology. The allelopathic research during the last four decades drew attention to different facets of the interactions among the constituents of habitat, calling for an understanding of the role of allelopathy under different habitat conditions. In view of this, we have reviewed the existing information on allelopathic interactions in aquatic habitats with special reference to algal allelopathy. This review has been mainly confined, therefore, to different aspects of algal allelopathy such as allelopathic interactions in algae, algal toxins, bioassays, and implications of algal allelopathy. In spite of the large number of reviews on allelopathy (see section III), no independent review appears on algal allelopathy. Although there were reports of toxins from cyanobacteria and other algae, no appreciable attempt was made to implicate algal toxins in allelopathy under field conditions. Knowledge of chemistry and biology of allelochemical can help in their potential use in controlling plant diseases and weeds. Therefore, it is urgent to study algal toxins for their involvement in ecological phenomena such as succession, for their uses as herbicides, weedicides, and pesticides, for their uses in solving some of the problems of algal ecology, and for their involvement in applied aspects.     

Microbial Community Changes Elicited by Exposure to Cyanobacterial Allelochemicals

An increasing body of evidence points out that allelopathy may be an important process shaping microbial communities in aquatic ecosystems. Cyanobacteria have well-documented allelopathic properties, mainly derived from the evaluation of the activity of allelopathic extracts or pure compounds towards monocultures of selected target microorganisms. Consequently, little is known regarding the community dynamics of microorganisms associated with allelopathic interactions. In this laboratory-based study, a Microcystis spp.-dominated microbial community from a freshwater lake was exposed, for 15 days, to exudates from the cyanobacterium Oscillatoria sp. strain LEGE 05292 in laboratory conditions. This cyanobacterium is known to produce the allelochemicals portoamides, which were among the exuded compounds. The community composition was followed (by means of polymerase chain reaction followed by denaturing gradient gel electrophoresis and microscopic analyses) and compared to that of a non-exposed situation. Following exposure, clear differences in the community structure were observed, in particular for cyanobacteria and unicellular eukaryotic taxa. Interestingly, distinct Microcystis genotypes present in the community were differentially impacted by the exposure, highlighting the fine-scale dynamics elicited by the exudates. These results support a role for cyanobacterial allelochemicals in the structuring of aquatic microbial communities.     

An ecological perspective of allelochemical interference in land–water interface communities

Allelochemical interactions among aquatic macrophytes and between macrophytes and attached microbial assemblages (epiphyton) influence a number of ecological processes. The ecological importance of these interactions, however, is poorly understood; we hypothesize that paucity has resulted, in part, from (1) a narrow focus on exploration for herbicidal plant products from aquatic macrophytes, (2) the difficulties in distinguishing resource competition from allelopathic interference, and (3) a predominance of approaching aquatic allelopathy from a terrestrial perspective. Based upon recent thorough investigations of allelopathy among aquatic vascular plants, chemical compounds that influence competitive interactions among littoral organisms are amphiphilic compounds that tend to remain near the producing organism (e.g., polyphenolic compounds and volatile fatty acids). Production of these compounds may be influenced by relative availability of nutrients (particularly phosphorus and nitrogen), inorganic carbon, and light. Macrophyte strategies of clonal reproduction, in an effort to persist in these highly productive and competitive habitats, have contributed to reduced reliance upon sexual reproduction that is correlated with allelopathic autotoxicity among several dominant wetland plant species. Although few studies document the importance of allelochemical interactions in the wetland and littoral zones of aquatic ecosystems, abundant evidence supports the potential for significant effects on competition and community structure; effects of altered nutrient ratios and availability on plant chemical composition; and resultant effects on trophic interactions, particularly suppression of herbivory, competitive attached algae and cyanobacteria, and heterotrophic utilization of organic matter by bacteria and fungi.     

Allelopathic effect of Microcystis aeruginosa on Microcystis wesenbergii: microcystin-LR as a potential allelochemical

Microcystis aeruginosa and Microcystis wesenbergii are two cyanobacteria commonly found in eutrophic shallow lakes. Previous studies reported that microcystin-producing M. aeruginosa could have an increased competitive potential on other algae and aquatic plants, and microcystin-LR (MC-LR) was regarded as an allelochemical. Based on this hypothesis, the allelopathic interaction between these two cyanobacteria was studied for the first time under laboratory conditions, and potential allelochemicals were screened. Cyanobacteria biomass and microcystin-LR (MC-LR) concentration were monitored under different culture conditions. The potential allelochemicals from M. aeruginosa were investigated by extract fractionation and GC(LC)/MS analysis. The growth of M. wesenbergii was inhibited by the addition of cell-free filtrates of M. aeruginosa whereas M. aeruginosa was promoted by the addition of cell-free filtrates of M. wesenbergii. The higher polarity the extract of M. aeruginosa is, the stronger the inhibition effect of the extract on M. wesenbergii will be. According to our results, M. aeruginosa has a significant allelopathic inhibition effect on M. wesenbergii. Allelopathic compounds from M. aeruginosa have synergistic effects on inhibition of M. wesenbergii. Besides microcystin, there may be other allelopathic compounds in M. aeruginosa.     

Allelopathic activity of Elodea canadensis and Elodea nuttallii against epiphytes and phytoplankton

Elodea nuttallii and Elodea canadensis have both been introduced from North America to Europe. They are now common in many water bodies where they often form dominating stands. It was suggested that negative relationships between Elodea and phytoplankton or epiphytic covers exist, probably due to the release of growth inhibiting allelochemicals. This would be an effective strategy to avoid light limitation caused by algae and cyanobacteria. We investigated the allelopathic potential of both E. nuttallii and E. canadensis against different photoautotrophs, focussing on epiphytic algae and cyanobacteria isolated from different submersed macrophytes and culture strains. Methanolic extracts of both species inhibited the growth of most of these organisms. Only a culture strain of Scenedesmus brevispina was stimulated. Further separation of extracts yielded several active fractions, indicating that hydrophilic and slightly lipophilic compounds were responsible for growth reduction. At least some of the activity seems to be related to phenolic substances, but flavonoids in these species are inactive. Since growth declined also in a moderately lipophilic fraction of culture filtrate of E. nuttallii, we assume that active compounds were exuded in the water. Allelopathy might thus be relevant in situ and suppress cyanobacteria and algae. We furthermore found differences in the susceptibility of target organisms, which could (1) at least partly be a result of adaptation to the respective host plants and (2) indicate that allelopathic interference might reduce the abundance of some species, especially cyanobacteria, in epiphytic biofilms.     

Inhibitory metabolites production by the cyanobacterium Fischerella muscicola

Broad-spectrum inhibitory metabolites were produced by a benthic cyanobacterium Fischerella muscicola (UTEX 1829) in batch culture. These metabolites inhibited the growth of eukaryotic algae, cyanobacteria and eubacteria. The effect of culture age on the production and leakage of these inhibitory metabolites from the cyanobacterium was studied. Confirmation of the presence of an allelochemical, possibly fischerellin was achieved using high performance liquid chromatography (HPLC). The cyanobacterium produced inhibitory metabolites intracellularly at all stages of its growth cycle.     

Activity of the natural algicide, cyanobacterin, on eukaryotic microorganisms

Abstract The natural product cyanobacterin has been shown to be toxic to most cyanobacteria at a concentration of approx. 5 μM. We demonstrate here that cyanobacterin will also inhibit the growth of most eukaryotic algae at a similar concentration. Some algae, such as Euglena gracilis , are resistant because they are able to maintain themselves by heterotrophic nutrition. Others, such as Chlamydomonas reinhardtii , can apparently induce a detoxification mechanism to maintain photosynthesis in the presence of low concentrations of the inhibitor. Non-photosynthetic microorganisms are not affected by cyanobacterin.     

The Impact of Microbial Biotransformation of Catechin in Enhancing the Allelopathic Effects of Rhododendron formosanum

Rhododendron formosanum is distributed widely in the central mountains in Taiwan and the major allelopathic compound in the leaves has been identified as (-)-catechin, which is also a major allelochemical of an invasive spotted knapweed in North America. Soil microorganisms play key roles in ecosystems and influence various important processes, including allelopathy. However, no microorganism has been identified as an allelochemical mediator. This study focused on the role of microorganisms in the allelopathic effects of R. formosanum. The microorganism population in the rhizosphere of R. formosanum was investigated and genetic analysis revealed that the predominant genera of microorganisms in the rhizosphere of R. formosanum were Pseudomonas, Herbaspirillum, and Burkholderia. The dominant genera Pseudomonas utilized (-)-catechin as the carbon source and catalyzed the conversion of (-)-catechin into protocatechuic acid in vitro. The concentrations of allelochemicals in the soil were quantified by liquid chromatography-electrospray ionization/tandem mass spectrometry. The concentration of (-)-catechin in the soil increased significantly during the extreme rainfall in the summer season and suppressed total bacterial populations. Protocatechuic acid accumulation was observed while total bacterial populations increased abundantly in both laboratory and field studies. Allelopathic interactions were tested by evaluating the effects of different allelochemicals on the seed germination, radicle growth, and photosynthesis system II of lettuce. Protocatechuic acid exhibited higher phytotoxicity than (-)-catechin did and the effect of (-)-catechin on the inhibition of seed germination was enhanced by combining it with protocatechuic acid at a low concentration. This study revealed the significance of the allelopathic interactions between R. formosanum and microorganisms in the rhizosphere. These findings demonstrate that knowledge regarding the precise biotransformation process of (-)-catechin by microorganisms in the environment is necessary to increase our understanding of allelopathy.