喜旱莲子草入侵群落土壤对植物生长的影响

分别以受喜旱莲子草(Alternanthera philoxeroides)入侵和未受喜旱莲子草入侵的当地植物群落土壤为生长基质,比较不同基质上入侵植物喜旱莲子草和同属的土著植物莲子草(A.sessilis)的生长指标,探讨喜旱莲子草入侵群落土壤对喜旱莲子草及莲子草生长的影响机制。结果表明,喜旱莲子草入侵群落土壤抑制了莲子草的生长,显著降低了根生物量、茎生物量和总生物;改变了形态特征,显著降低了分枝数量、茎长度、根长、根体积;减少了对根的生物量分配,显著抑制了根质量比与根冠比。喜旱莲子草入侵群落土壤对入侵植物喜旱莲子草的生物量、分枝数量、茎长度、根长、根体积没有显著的抑制作用,而显著增加了其叶片数量和叶质量比。这种效应将有利于喜旱莲子草在入侵地形成单优群落,表明土壤在喜旱莲子草成功入侵中起了重要作用。     

地上-地下植食性天敌对入侵植物空心莲子草与本地种莲子草种间关系的影响

生物入侵是全球生物多样性的主要威胁,外来种与本地种的种间竞争能力会影响其能否成功入侵。本研究选用入侵植物空心莲子草和其本地同属种莲子草为对象,探究其专食性天敌莲草直胸跳甲与南方根结线虫对空心莲子草与莲子草的生长及种间关系的影响。结果表明: 与无天敌胁迫相比,线虫处理显著降低了莲子草的株高(28.1%),但显著增加了空心莲子草的株高(52.8%)和莲子草的地上生物量(63.7%);跳甲处理显著降低了莲子草的株高(40.7%),对空心莲子草无显著影响;而跳甲与线虫的共同胁迫显著降低了莲子草的株高(35.3%)和空心莲子草的地下生物量(62.2%),显著增加了莲子草的地上生物量(69.1%);天敌胁迫对两种植物的茎粗、分枝数和根长均无显著影响。无天敌作用下,两种植物的相对邻体效应指数(RNE)均为正值,且空心莲子草的RNE比莲子草高21.3%;天敌胁迫下,空心莲子草的RNE均为负值,而莲子草的RNE在线虫或跳甲单独胁迫下为正值,在线虫和跳甲共同胁迫下为负值。表明地上-地下天敌互作可以使两种植物的种间关系发生改变,并可能促进空心莲子草的入侵。     

Relative abundance of invasive plants more effectively explains the response of wetland communities to different invasion degrees than phylogenetic evenness

入侵植物的相对多度比群落系统发育均匀度更能解释湿地群落对不同入侵程度的响应 本地植物群落普遍受到入侵植物不同程度的入侵。然而,入侵植物相对多度与群落系统发育均匀度对不同入侵程度下湿地植物群落响应入侵的相对贡献尚不明确。此外,这种贡献是否随淹水等环境 条件的变化而变化也不清楚。为了探讨这些问题,我们选择空心莲子草(Alternanthera philoxeroides)作为入侵植物,通过改变植物群落物种组成,构建了4个不同的入侵程度,并且设置了水淹和无水淹两种处理。 改变群落入侵程度的同时改变了空心莲子草的相对多度和群落的系统发育均匀度。研究结果表明,不同的入侵程度显著影响了空心莲子草和一些本地物种的单株生物量。变异分割结果表明,无论淹水情况结果如何,空心莲子草相对多度对植物群落指标变异的贡献都大于系统发育均匀度。斯皮尔曼等级相关检验结果表明,空心莲子草的相对多度与空心莲子草和部分本地物种的单株生物量显著负相关;群落系统发育均匀度仅与少数本地种性状显著正相关。其相关强度和显著性均受特定的物种和水淹环境的影响。总之,这些研究结果表明：无论淹水情况如何,入侵植物(空心莲子草)的相对多度都比群落的系统发育均匀度更能有效地解释湿地植物群落对不同入侵程度的响应。     

喜旱莲子草原产地和入侵地种群的植物-土壤反馈差异

植物-土壤反馈是植物通过生长改变根际土壤环境,从而影响后续植物生长发育的生态学过程。入侵植物从原产地扩散到入侵地后,可能会经历植物本身的适应性进化而对土壤环境产生不同影响,从而使负向植物-土壤反馈降低,甚至转为正反馈。以往对入侵植物的植物-土壤反馈研究多集中于比较其与本地种、其他入侵种之间的差异,而较少关注入侵植物的入侵地种群和原产地种群在入侵地的差异。本研究采用同质园实验比较了喜旱莲子草(Alternanthera philoxeroides)入侵地(中国)和原产地(阿根廷)种群是否存在对入侵地土壤的植物-土壤反馈差异以及如何通过土壤微生物群落来影响反馈结果。结果表明:(1)喜旱莲子草入侵地种群的反馈表现为正,原产地种群表现为中性。(2)入侵地种群显著增加了土壤的细菌和真菌群落多样性,原产地种群与对照土壤无显著差异。这些结果表明,喜旱莲子草入侵地种群在扩散过程中,对土壤微生物群落的调节作用发生了改变,从而产生正向的植物-土壤反馈效应。     

Effects of elevated temperature on chemistry of an invasive plant,its native congener and their herbivores

增温对莲子草属入侵植物与本地同属植物化学物质组成和天敌昆虫的影响 气候变暖影响植物生长和生理活动,然而气候变暖如何改变入侵植物化学物质组成并间接影响其与植食性昆虫互作还少有报道。本研究以入侵植物空心莲子草(Alternanthera philoxeroides)及其本地同属 植物莲子草(A. sessilis)为对象,探究增温对其叶片化学物质组成的影响并进一步检验这些变化如何影响两 种植食性昆虫虾钳菜披龟甲(Cassida piperata)和斜纹夜蛾(Spodoptera litura)的生长发育。通过模拟增温实验,探究增温对空心莲子草和莲子草13个叶片化学物质的影响,并用其饲养两种植食性昆虫,测量它们的生长和发育时间。研究结果显示,增温显著改变了空心莲子草和莲子草叶化学物质组成;增温降低了空心莲子草叶片氮浓度,增加了莲子草叶片总黄酮和总酚浓度;增温对其它营养物质(果糖、蔗糖、总可溶性糖和淀粉)随物种和具体物质发生改变;采用增温处理的莲子草饲养的虾钳菜披龟甲蛹重和斜纹夜蛾幼虫重量,以及增温处理的空心莲子草饲养的斜纹夜蛾幼虫重量,显著低于对照不增温处理;此外,采用增温处理的莲子草饲养的斜纹夜蛾幼虫发育时间显著延长。这些结果表明,增温对植物化学物质组成的影响随物种发生变化,增温对入侵植物和本地植物化学物质组成的影响间接改变了其与植食性昆虫的互作关系。     

不同生境下空心莲子草响应模拟昆虫采食的生长和化学防御策略

外来植物往往可以入侵多种生境并受到多种昆虫的采食,而不同生境条件将可能会影响这些入侵植物对昆虫采食的防御策略。以入侵我国的克隆植物——空心莲子草为研究对象,分别选择生长在水生生境、水陆两栖生境和陆生生境中的无性个体(分株),通过50%去叶处理模拟昆虫采食,分析不同生境下空心莲子草对模拟昆虫采食处理的生长及化学防御响应的差异。模拟昆虫采食处理显著抑制了陆生生境、水陆两栖生境以及水生生境下空心莲子草的根、茎、叶和总生物量,但对3种生境下空心莲子草的生物量分配(根冠比、根生物量分配、茎生物量分配和叶生物量分配)均无显著影响。陆生生境下空心莲子草根、茎和总生物量显著高于水陆两栖生境和水生生境,根冠比显著低于水陆两栖生境和水生生境。模拟昆虫采食处理显著降低了空心莲子草的木质素含量,而对单宁和总酚含量影响不显著。生境对木质素含量无显著影响,但陆生生境下空心莲子草单宁含量显著高于水陆两栖生境和水生生境,且总酚含量显著高于水陆两栖生境,表明陆生生境中空心莲子草具有更强的防御能力。空心莲子草木质素含量与总生物量无显著相关性,但在模拟采食情况下,其总酚含量与总生物量呈显著负相关,而无论模拟昆虫采食处理存在与否,空心莲子草单宁含量与总生物量均呈显著正相关。因此,空心莲子草存在昆虫介导的生长和化学防御之间的权衡,在昆虫采食的情况下可通过减少生长来增加对化学防御物质的投入,但生境对空心莲子草这种生长-防御权衡的影响十分有限。     

Opposing effects of plant growth regulators via clonal integration on apical and basal performance in alligator weed

植物生长调节剂通过克隆整合对空心莲子草顶端和基部生长的不同作用 入侵植物不仅对全球生物多样性造成了巨大的威胁,同时也严重影响了农业生产与粮食安全。克隆整合使得相连植株进行资源共享,能促进入侵植物的生长从而获得优势。然而,入侵杂草 在植物调节剂(plant growth regulators, PGRs)影响下的克隆整合作用则很少有报道。PGRs被广泛应用于 农作物生产上,并能通过土壤淋溶、侵蚀和径流作用,影响分布在作物附近的农田杂草的生长。本 研究采用两种PGRs赤霉素(gibberellins, GA)和多效唑(paclobutrazol,PAC)处理恶性入侵杂草空心莲子草 (Alternanthera philoxeroides)基端,并保持或者通过剪切达到控制基端与顶端的连通,从而探究克隆整合作用在空心莲子草响应两种农业常用PGRs中的作用。研究结果表明,GA和PAC对空心莲子草生长的作用相反。GA通过克隆整合作用显著促进顶端植株的地上生长。相反地,PAC显著抑制基端和顶端的地 上生长,但是能够通过克隆整合作用显著促进基端和顶端的地下生长。这些研究结果解释了克隆整合作用能促进PGRs对空心莲子草生长的促进作用,这很可能是外来杂草能够成功入侵人为干扰较多的农业生态系统的重要原因之一。     

Aboveground herbivory increases soil nematode abundance of an invasive plant

入侵植物往往可以影响土壤线虫的群落结构。然而,入侵植物在入侵地并未完全逃逸地上植食性昆虫的取食危害,而我们对昆虫取食是否会调节入侵植物对土壤线虫群落的影响还知之甚少。在本研究中,我们探讨了地上植食性昆虫取食危害如何调节入侵植物空心莲子草(Alternanthera philoxeroides)对土壤线虫群落的影响,并研究了昆虫调节作用的时间效应。我们开展温室实验,对盆栽的空心莲子草施加三种不同的昆虫取食处理[无昆虫取食、专食性昆虫莲草直胸跳甲(Agasicles hygrophila)取食、广食性昆虫虾钳菜披龟甲(Cassida piperata)取食],并在移除所有植食性昆虫后的第1、10和20天测定土壤线虫的群落结构。此外,我们还测定了空心莲子草根系及根系分泌物的碳含量。研究发现,在植食性昆虫被移除的第1天,昆虫取食处理显著提高了空心莲子草根围土壤线虫的丰度,特别是植食性线虫。然而,随着时间推移,这种影响逐渐减退,并在后期(第10和20天)完全消失。此外,专食性昆虫莲草直胸跳甲和广食性昆虫虾钳菜披龟甲的取食危害对土壤线虫丰度的影响并无显著性差异。综上所述,本研究表明地上植食性昆虫的取食危害可以改变入侵植物对土壤线虫群落的影响,但昆虫的调节作用是短暂的。此外,我们的研究强调了在评估入侵植物的影响时,需要同时考虑地上和地下生物群落。     

酸雨和采食模拟胁迫下克隆整合对空心莲子草生长的影响

研究表明克隆整合可以显著提升异质环境中克隆植物的生长,然而当克隆植物遭受均质环境压力时,整合对植物生长影响的研究相对较少。本文以典型入侵克隆植物空心莲子草（Alternanthera philoxeroides）为例,研究均质环境压力酸雨和采食模拟胁迫对空心莲子草生长的影响,以及克隆整合在空心莲子草适应不利环境过程中所起的作用。酸雨设3种浓度梯度：pH值3.5 、pH值4.5和 pH值6.5（对照）;采食设3种水平：不去叶、去叶50%和去叶90%;整合水平：匍匐茎切断和连接。结果表明：无论保持或切断匍匐茎的连接,酸雨处理都不影响空心莲子草生物量。当保持匍匐茎连接时,pH值4.5酸雨处理增加了空心莲子草匍匐茎长度和分株数目,因此,低度酸雨可能对空心莲子草生长有一定的促进作用。同样,无论匍匐茎是否被切断,采食处理都显著降低了空心莲子草克隆片段生物量,而显著增加了叶片数目。当切断匍匐茎连接时,采食处理使空心莲子草分株数目显著增加。本文得出的结论是：空心莲子草能较好地适应酸雨和采食的环境压力,当空心莲子草全部克隆分株遭受均质环境胁迫时,克隆整合并不能显著改善它的生长。     

三种增温情景对入侵植物空心莲子草形态可塑性的影响

虽然国内外已对克隆植物的表型可塑性开展了大量研究,但是气候变暖对克隆植物,尤其是入侵性克隆植物形态可塑性的影响及其可能的生态学意义研究仍然有限。通过设置白天增温、夜间增温和全天增温3种方式,通过切断或不切断匍匐茎处理,探讨入侵植物空心莲子草(Alternanthera philoxeroides)形态特征对不同气候变暖情景的响应。研究发现:夜间增温2℃条件下,切断匍匐茎连接显著降低空心莲子草匍匐茎总长度和平均分株长度;白天增温和全天增温2℃对匍匐茎切断和连接组的空心莲子草的匍匐茎总长和平均分株长影响不显著;3种增温方式对空心莲子草的分蘖数均无显著影响。这些结果表明:空心莲子草对增温具有较高的耐受性,并对不同增温方式采取不同的响应策略;夜间增温可能通过光合补偿效应增加其匍匐茎的长度和平均分株长从而促进其水平方向的扩展以占据更加有利的生境,增强其入侵能力;白天和全天增温对整个克隆片段匍匐茎形态几乎无影响。     

Decomposition dynamics of invasive alligator weed compared with native sedges in a Northland lake

Invasive weeds have been shown to alter ecosystem processes such as decomposition and nutrient cycling. However, little is known about the effects of introduced biocontrol agents on these processes. This study examined the effects of alligator weed (Alternanthera philoxeroides) and its biocontrol agent, the alligator weed flea beetle (Agasicles hygrophila), on nutrient cycling in a northern New Zealand lake. Alligator weed litter decomposed significantly faster than either of two native sedge species (Schoenoplectus tabernaemontani, Isolepis prolifer) in a litterbag experiment. In addition, the presence of the alligator weed flea beetle resulted in large amounts of decaying alligator weed litter entering the lake in early summer. Both the timing and magnitude of this litter input were uncharacteristic of seasonal biomass dynamics of the native sedges. Combined with alligator weed?s rapid decomposition, this indicates altered patterns of nutrient cycling at the lake, with potential flow-on effects including facilitation of further weed invasion.     

Disturbance-mediated competition: the interacting roles of inundation regime and mechanical and herbicidal control in determining native and invasive plant abundance

Disturbance is a key component of many successful plant invasions. However, interactions among natural and anthropogenic disturbances and effects of these interacting disturbances on invasive plants and desired vegetation are rarely examined. We investigated the effect of anthropogenic disturbance (herbicidal and mechanical) along a natural inundation gradient (20–282 days) on the biomass and resource allocation of the invasive wetland plant, alligator weed (Alternanthera philoxeroides), and two co-occurring competitor plants, the introduced grass, kikuyu (Pennisetum clandestinum), and the native grass, couch (Cynodon dactylon), over a 2-year period. In the absence of additional disturbance, kikuyu biomass was negatively affected, alligator weed biomass was positively affected, and couch biomass was not affected by inundation disturbance. In addition, kikuyu was not affected by the selective removal of alligator weed, while couch increased in wetter habitats where kikuyu was absent due to inundation stress. This suggests that kikuyu is a superior competitor in drier habitats and inundation facilitates the invasion of alligator weed, while couch is an inferior competitor to both kikuyu and alligator weed and is therefore suppressed across its entire niche by these two introduced species. Mowing alone had no effect on the biomass of the species, suggesting the plants are equally tolerant of shoot removal. Selective herbicide reduced alligator weed biomass by 97.5% and the combination of selective herbicide and mowing reduced the biomass of alligator weed significantly more than herbicide alone, by 98.6% compared with un-manipulated controls. To predict community change and prevent sequential exotic plant invasions after weed removal, it is necessary to consider the interacting effects of disturbance and the niche space of invasive species in the local propagule pool.     

不同土壤水分和养分条件下喜旱莲子草与同属种生长状况的比较研究

喜旱莲子草(Alternanthera philoxeroides)入侵已在中国造成巨大的生态和经济损失。为揭示喜旱莲子草成功入侵的生态机制并预测其种群扩张趋势及其与环境因子的关系, 作者比较了喜旱莲子草与其同属的外来弱入侵种刺花莲子草(A. pungens)以及土著种莲子草(A. sessilis)在不同土壤水分、养分条件下的生长状况。结果显示: 在高水高肥条件下, 喜旱莲子草的生物量要高于刺花莲子草和莲子草, 而在低水低肥条件下却不如这两个同属种; 弱入侵种刺花莲子草在低水条件下的生物量要高于强入侵种喜旱莲子草和土著种莲子草, 说明植物的入侵性受环境条件的影响。另外, 强入侵种喜旱莲子草形态学性状的可塑性较高, 在各种条件下都具有较高的比叶面积, 暗示这两个指标可作为莲子草属外来植物入侵性的预测指标。     

Effects of clonal integration on photosynthesis of the invasive clonal plant <Emphasis Type="Italic">Alternanthera philoxeroides</Emphasis>

A greenhouse experiment examined whether clonal integration improves photosynthesis of ramets of alligator weed [Alternanthera philoxeroides (Mart.) Griseb.], a widespread invasive clonal plant in China, in heterogeneous (He) nutrient habitats. The connected pairs of ramets experienced different nutrient levels [high homogeneous (Ho) nutrient, low Ho nutrient, and two He nutrient treatments]. Clonal integration significantly improved the net photosynthetic rate, stomatal conductance, transpiration rate, and minimal and maximal chlorophyll fluorescence of ramets of alligator weed in low nutrient condition. These characteristics may contribute to the success of the ramets of alligator weed in invading contrasting habitats. The clonal integration of the invasive clonal plants may contribute significantly to their invasiveness.     

Control and spread of Alligator Weed Alternanthera philoxeroides (Mart.) Griseb., in Australia: lessons for other regions

Biological control of alligator weed Alternanthera philoxeroides (Mart.) Griseb. has been successful in limiting growth in water in areas with mild or warm winters, but not on land. Until recently, herbicides have had very limited short term and no long term effectiveness. Several herbicides that now provide better control include: glyphosate over water, and metsulfuron and dichlobenil on land and in shallow water. The latter two are limited by lack of selectivity, contamination of water, and cost. Mechanical or manual control has provided local eradication of the weed at a few locations where infestations were small. Alligator weed is still spreading with new outbreaks on New South Wales, Australia (NSW) coastal beach areas and coastal river systems, and on inland waterbodies. Its use as a cultivated vegetable by some ethnic communities has resulted in many new locations in all eastern Australia states: Queensland to Tasmania. It is predicted that it will spread throughout much of coastal and inland southern Australia. The difficulties with management of this weed indicate that every effort should be made to prevent further invasion of wetlands and, in particular, its introduction to Africa, where it is predicted that all wetlands could support destructive levels of alligator weed growth.     

Effects of simulated herbivory and resource availability on the invasive plant, Alternanthera philoxeroides in different habitats

In biological control programs, the insect natural enemy’s ability to suppress the plant invader may be affected by abiotic factors, such as resource availability, that can influence plant growth and reproduction. Understanding plant tolerance to herbivory under different environmental conditions will help to improve biocontrol efficacy. The invasive alligator weed (Alternanthera philoxeroides) has been successfully controlled by natural enemies in many aquatic habitats but not in terrestrial environments worldwide. This study examined the effects of different levels of simulated leaf herbivory on the growth of alligator weed at two levels of fertilization and three levels of soil moisture (aquatic, semi-aquatic, and terrestrial habitats). Increasing levels of simulated (manual) defoliation generally caused decreases in total biomass in all habitats. However, the plant appeared to respond differently to high levels of herbivory in the three habitats. Terrestrial plants showed the highest below–above ground mass ratio (R/S), indicating the plant is more tolerant to herbivory in terrestrial habitats than in aquatic habitats. The unfertilized treatment exhibited greater tolerance than the fertilized treatment in the terrestrial habitat at the first stage of this experiment (day 15), but fertilizer appears not to have influenced tolerance at the middle and last stages of the experiment. No such difference was found in semi-aquatic and aquatic habitats. These findings suggest that plant tolerance is affected by habitats and soil nutrients and this relationship could influence the biological control outcome. Plant compensatory response to herbivory under different environmental conditions should, therefore, be carefully considered when planning to use biological control in management programs against invasive plants.     

Phenotypic plasticity rather than locally adapted ecotypes allows the invasive alligator weed to colonize a wide range of habitats

Both phenotypic plasticity and locally adapted ecotypes may contribute to the success of invasive species in a wide range of habitats. Here, we conducted common garden experiments and molecular marker analysis to test the two alternative hypotheses in invasive alligator weed (Alternanthera philoxeroides), which colonizes both aquatic and terrestrial habitats. Ninety individuals from three pairs of aquatic versus terrestrial populations across southern China were analyzed, using inter simple sequence repeat (ISSR) marker, to examine population differentiation in neutral loci. Two common gardens simulating aquatic and terrestrial habitats were set up to examine population differentiation in quantitative traits. We found no evidence of population differentiation in both neutral loci and quantitative traits. Most individuals shared the same ISSR genotype. Meanwhile, plants from different habitats showed similar reaction norms across the two common gardens. In particular, plants allocated much more biomass to the belowground roots in the terrestrial environment, where alligator weed may lose part or all of the aboveground shoots because of periodical or accidental disturbances, than those in the aquatic environment. The combined evidence from molecular marker analysis and common garden experiments support the plasticity hypothesis rather than the ecotype hypothesis in explaining the adaptation of alligator weed in a wide range of habitats.     

Biosorption of As(V) onto dried alligator weed root: role of metal (hydro) oxides

The present work investigates the adsorption of As(V) onto the dried powder of alligator weed root as bio-sorbent, using acid pre-treated alligator weed root powder as the reference. The isotherm study suggested there is a favorable As(V) adsorption happened on the AWR surface. The batch adsorption experimental results indicated that the ionic strength has little impact on the adsorption, while the solution pH has a significant effect on the adsorption with apparent inhibition appearing in both extreme acidic and alkaline pH region. In addition, the properties of the biosorbent were characterized by various techniques including SEM-EDS, FT-IR, and ICP detection. The analysis results suggested that the metals including Mn, Fe, and Al enrich over the alligator weed root surface in the morphology of metal (hydro) oxide. Based on the nature of the biosorbent and As(V) besides the adsorption performance, the metal (hydro) oxides over biosorbent surface is suggested as the essential role to drive the adsorption. With the metal (hydro) oxides denuded in the pre-treatment, the biosorbent loses its adsorption capability for As(V) totally.     

Genetic diversity of alligator weed in China by RAPD analysis

Random amplified polymorphic DNA (RAPD) was applied to analyze geneticdiversity of an invasive weedy species, alligator weed (Alternantheraphiloxeroides (Martius) Grisebach), collected from eight differentsites in southern China. Amplified by 108 RAPD primers, 391 bands wereidentified from samples collected from three of the eight sites withconsiderably large spatial intervals, but no genetic variation was detectedamong the samples. A total number of 196 RAPD fragments were amplified from allsamples collected in the eight sites by 31 primers that produced the mostconsistent results, but no genetic variation was detected within or betweenpopulations. The molecular data indicated extremely low genetic diversity in thealligator weed. Given the fact that the alligator weed is a serious invasiveweed, and widely found in China, we consider that the low genetic diversity ofthe alligator weed does not affect the success of its expansion in China, andlow genetic diversity does not necessarily lead to endangered status of a plantspecies. In addition, molecular evidence from this study suggests that thealligator weed in southern China might originate from a very few clones or evenonly from a single clone. Therefore, the rapid range expansion of the alligatorweed is most likely the result of a massive vegetative propagation since it wasintroduced in China.