Aims

 相互连接的克隆植物分株分别处于资源互补性的不同斑块时, 将可能发生形态结构的特化, 以更有效地吸收利用所处斑块中丰富的资源, 形成分株的功能分化, 即克隆内分工。生境的斑块对比度, 作为资源或环境异质性的主要素, 在一定程度上决定克隆内分工的发生状况。该文以鹅绒委陵菜(Potentilla anserina)为材料, 在自然条件下将多组分株对置于不同的斑块对比度处理下, 比较了它们克隆内分工的发生状态, 试图发现分工与斑块对比度的关系, 同时考察在克隆分工过程中分株的可塑性变化及其与分工的关系。该实验的理论假设是: 分株发生分工的程度与分株所处斑块的资源对比度成正相关。研究结果表明, 鹅绒委陵菜分株的高度和叶面积对局部光照环境产生强烈的可塑性反应, 反应的结果是增加了对匮乏的光资源的获取。从分株根冠比和我们提出的分工指数来看, 分工的程度在一定的斑块对比度范围内随斑块对比度的增强而增强, 但到达一个最大值后又迅速降低。鹅绒委陵菜分株之间的分工和结构特化往往滞后于分株对所处局部环境的适应性可塑性变化, 而后者往往在分株之间具有独立性和局部特征。克隆内分工主要依赖于生物量分配的调节而实现, 其发生状态都是分株系统在分工收益、分工代价与分工风险之间权衡的结果, 而这种结果在很大程度上取决于分株所处的斑块对比度。     

资源交互斑块性生境中两种不同分枝型匍匐茎植物的克隆内分工

以青藏高原和四川盆地过渡带两种不同分枝型匍匐茎植物野草莓 (Fragaria vesca)和过路黄 (Lysimachia christinae)为对象 ,研究它们在高光照低养分斑块和低光照高养分斑块组成的资源交互斑块性生境中的克隆内分工。结果显示 ,与资源的空间同质性处理 (I)和 (II)相比 ,资源的空间异质性处理 (III)和 (IV)中野草莓和过落黄的近端、远端和整个克隆片段的生物量和分株数均获得显著增加。生长在低光高养条件下的远端分株 ,若与高光低养的近端分株相连 ,相比连接到低光高养的近端分株 ,它们分配更多的生物量到地下部分 ;生长在高光低养条件下的远端分株 ,若与低光高养的近端分株相连 ,相比连接到高光低养的近端分株 ,它们分配更多的生物量到地上部分 ;生长在高光低养条件下的近端分株 ,若与低光高养的远端分株相连 ,相比连接到高光低养的远端分株 ,它们分配更多的生物量到地上部分。实验结果表明 ,资源交互斑块性生境中野草莓和过路黄均发生了克隆内分工。通过克隆内分工 ,克隆植物能有效的利用异质性分布的资源 ,缓解资源交互斑块性分布对克隆植物生长的不利影响     

克隆整合提高异质性UV-B辐射下活血丹抗氧化酶活力

增强UV-B辐射会对植物生长和生理生化过程产生有害效应。克隆植物中,相连的克隆分株对经常共享资源和激素,然而鲜有关于异质性UV-B辐射下抗氧化酶活力变化的报道。本研究模拟同质(克隆分株片段均处于自然背景辐射)和异质(克隆分株一端处于自然背景辐射,另一端处于补加的UV-B辐射)UV-B辐射,以克隆植物活血丹为材料,进行连接和隔断处理,研究异质性UV-B辐射下,克隆整合对活血丹抗氧化酶(超氧化物歧化酶(SOD),过氧化物酶(POD)和过氧化氢酶(CAT))活力的影响。结果表明:与处于同质UV-B辐射环境相比,异质UV-B辐射下连接处理中的活血丹UV-B辐射端抗氧化酶活力显著增加,说明克隆植物生理整合存在,且克隆整合提高了活血丹抗氧化酶活力。表明异质UV-B辐射环境中,UV-B辐射胁迫端克隆分株通过生理整合从非胁迫端获益,最大化地利用资源。     

青藏高原东缘过路黄在资源交互斑块性生境中的克隆内资源共享

在青藏高原和四川盆地过渡带,分别于618m和1800m两个海拔高度上研究匍匐茎克隆植物过路黄(Lysimachia christinae)在资源交互斑块性生境中的克隆内资源共享及其对生长的影响.结果显示, 在海拔1800m处,与资源的空间同质性处理(Ⅰ) 和(Ⅱ)相比, 资源的空间异质性处理(Ⅲ)和(Ⅳ)下过路黄整个克隆片段的生物量和分株数均获得显著增加;在海拔618m处,与资源的空间同质性处理(Ⅰ) 和(Ⅱ)相比,资源的空间异质性处理(Ⅲ)和(Ⅳ)下过路黄整个克隆片段生物量显著增加.在海拔618m和1800m处,生长在低光高养条件下的远端分株, 若与高光低养的近端分株相连, 相比连接到低光高养的近端分株, 它们分配更多的生物量到地下部分;在海拔1800m处,生长在高光低养条件下的远端分株, 若与低光高养的近端分株相连, 相比连接到高光低养的近端分株, 它们分配更多的生物量到地上部分.在海拔618m和1800m处,生长在高光低养条件下的近端分株, 若与低光高养的远端分株相连, 相比连接到高光低养的远端分株, 它们分配更多的生物量到地上部分.处于资源交互斑块性生境中的过路黄发生了克隆内分工,依靠相连分株间的功能分化, 克隆植物能有效的利用异质性分布的资源, 缓解资源交互斑块性分布对克隆植物生长的不利影响.通过间隔子(匍匐茎或根状茎),相连分株间能够相互传递和共享由不同分株获得的资源,这种资源共享能够提高克隆植物在异质性生境中的存活与生长.同时,方差分析显示环境异质性和海拔的交互作用显著影响克隆片段的生物量和分株数.相比于海拔618m,在海拔1800m处克隆内资源共享对克隆植物生长表现的影响更大.     

基于根系形态可塑性的空心莲子草克隆分工特征

资源在空间和时间上不均匀分布现象往往形成资源异质性斑块,克隆植物凭借强大的侧向生长能力占据广阔空间,分株间的生理连接促进了其对异质性生境的适应。克隆分株首先通过资源获取结构的功能特化来提高从各种资源富养斑块中的养分获取,然后通过克隆整合作用实现分株间的养分传输,这种功能特化和资源共享模式被称为‘分工’。该文以入侵克隆植物空心莲子草(Alternanthera philoxeroides)为研究对象,研究其根系对资源异质性分布的形态可塑性响应;通过调节光照强度和土壤养分来实现资源的异质性分布,共设置4个处理:1近端分株高光低养—远端分株高光低养(HL-HL),2近端分株低光高养—远端分株低光高养(LH-LH),3近端分株高光低养—远端分株低光高养(HL-LH),4近端分株低光高养—远端分株高光低养(LH-HL);使用WinRHIZO Pro软件分析相关根系指标,SPSS 18.0单因素方差(one-way ANOVA)分析方法分析异质性条件对近、远端分株以及整个克隆片段的影响。结果表明:异质性斑块中经历高光低养的分株分配更多的生物量到地上部分,经历低光高养的分株分配更多的生物量到地下部分,空心莲子草通过调整对地上和地下部分的生物量分配比例实现了克隆分工;异质性斑块中,生长在富养斑块中的空心莲子草分株根系有更高的根生物量、根长、根表面积、根体积以及分枝系数等,表明空心莲子草分株根系通过对异质性斑块的形态可塑性变化提高了土壤养分的吸收能力。由此可见,空心莲子草通过对资源获取结构的功能特化提高了其资源吸收能力,这可能是其具强入侵能力的重要原因。     

克隆整合对天胡荽分株间有性和克隆繁殖策略的影响

研究了克隆整合特性对天胡荽在异质性土壤养分环境中繁殖策略的影响。结果表明: 克隆整合可显著提高相连分株中处于低资源条件下近端分株的结果数和坐果率、总种子数量, 及其单个克隆分株的平均结籽数, 但对各处理单果重量的无显著影响。克隆整合有利于促进资源缺乏端的有性繁殖; 促进生理顶端分株的克隆繁殖。在低资源条件下, 克隆整合促进近端分株的有性繁殖以及远端分株的克隆繁殖; 相反则促进远端分株的有性繁殖和克隆繁殖。因此, 克隆整合特性是天胡荽对异质性环境的重要适应对策, 它使天胡荽能够扩展到不适合植物生长的低养分斑块中, 从而增加了天胡荽对恶劣环境的繁殖适合度及适应能力。     

资源异质性环境中三种匍匐茎草本植物克隆内资源共享和分株功能特化(英文)

研究了 3种来自中国北方林下、草地和碱化草甸匍匐茎型克隆草本植物绢毛匍匐委陵菜 (PotentillareptansL .var.sericophyllaFranch .)、鹅绒委陵菜 (P .anserinaL .)和金戴戴 (Halerpestesruthenica (Jacq .)Qvcz .)对由高光照低养分斑块和低光照高养分斑块组成的资源交互斑块性生境的适应性对策。当生长于高光照低养分条件下分株(HL分株 )与生长于低光照高养分条件下分株 (LH分株 )之间的匍匐茎连接时 ,3种克隆植物HL分株、LH分株以及整个分株对系统 (HL分株 LH分株 )的生物量均得到显著提高。同时 ,LH分株根冠比显著增加 ,而HL分株根冠比显著下降。这表明 ,当互连分株置于由低光照高养分斑块和高光照低养分斑块组成的异质性环境中时 ,3种植物克隆分株均发生了环境诱导的功能特化。克隆内资源共享以及克隆内不同分株的功能特化有利于整个分株系统对局部丰富资源的获取 ,从而能够缓解资源交互斑块性生境对克隆植物的不利影响     

资源异质性环境中三种匍匐茎草本植物克隆内资源共享和分株功能特化

研究了3种来自中国北方林下、草地和碱化草甸匍匐茎型克隆草本植物绢毛匍匐委陵菜 (Potentilla reptans L. var. sericophylla Franch.)、鹅绒委陵菜 (P. anserina L.) 和金戴戴 (Halerpestes ruthenica (Jacq.) Qvcz.) 对由高光照低养分斑块和低光照高养分斑块组成的资源交互斑块性生境的适应性对策.当生长于高光照低养分条件下分株 (HL分株) 与生长于低光照高养分条件下分株 (LH分株) 之间的匍匐茎连接时, 3种克隆植物HL分株、LH分株以及整个分株对系统 (HL分株 + LH分株) 的生物量均得到显著提高.同时, LH分株根冠比显著增加, 而HL分株根冠比显著下降.这表明, 当互连分株置于由低光照高养分斑块和高光照低养分斑块组成的异质性环境中时, 3种植物克隆分株均发生了环境诱导的功能特化.克隆内资源共享以及克隆内不同分株的功能特化有利于整个分株系统对局部丰富资源的获取, 从而能够缓解资源交互斑块性生境对克隆植物的不利影响.     

UV-B辐射方向对白三叶克隆整合的影响

增强UV-B辐射会对植物生长和生理生化过程产生有害效应。克隆植物中,相连的克隆分株对经常共享资源和激素,然而鲜有关于异质性UV-B辐射下UV-B辐射方向对克隆整合的影响及克隆植物形态结构变化的报道。模拟同质(克隆分株片段均处于自然背景辐射)和异质(克隆分株一端处于自然背景辐射,另一端处于补加的UV-B辐射)UV-B辐射,以克隆植物白三叶为材料,进行连接和隔断处理,研究UV-B辐射方向对克隆整合强度变化、叶片形态结构特化及生理可塑性的影响。结果表明:异质性UV-B辐射下,15N同位素标记端保留的15N百分比高于同质UV-B辐射处理,转移到无标记相连端的15N含量则降低,紫外辐射处理和同位素标记是否处于同一分株端对结果无显著性影响,说明克隆植物白三叶生理整合存在但整合强度降低,辐射方向与克隆整合强度无关;隔断处理组气孔长度增加,栅栏组织增厚,但连接处理组却无此变化,表明生理整合在白三叶叶片形态结构特化中发挥作用。UV-B辐射下,最小荧光、电子传递速率及光化学淬灭系数降低但非光化学淬灭系数升高,而生理整合却使结果相反;叶绿素和紫外吸收物可在异质性UV-B辐射相连的两端运输分享。以上均表明异质UV-B辐射环境中,UV-B辐射胁迫端克隆分株通过生理整合从非胁迫端获益,并以此提高胁迫环境中克隆植物对资源的利用效率。     

资源异质性环境中三种葡匐茎草本植物克隆内资源共享和分株功能特化

研究了3种来自中国北方林下、草地和碱化草甸匍匐茎型克隆草本植物绢毛匍匐委陵菜（Potentilla reptans L.var.sericophylla Franch.)、鹅绒委陵菜（P.anserina L.)和金戴戴（Halerpestes ruthenica (Jacq.)Qvcz.)对由高光照低养分斑块和低光照高养分斑块组成的资源交互斑块性生境的适应性对策。当生长于高照低养分条件下分株（HL分株）与生长于低光照高养分条件下分株（LH分株）之间的匍匐茎连接时,3种克隆植物HL分株、LH分株以及整个分株对系统（HL分株＋LH分株）的生物量均得到显提高,同时,HL分株根冠比显增加,而HL分株根冠比显下降。这表明,当互连分株置于由低光照高养分斑块和高光照低养分斑块组成的异质性环境中时,3种植物克隆分株均发生了环境诱导的功能特化。克隆内资源共享以及克隆内不同分株的功能特化有利于整个分株系统对局部丰富资源的获取,从而能够缓解资源交互斑块性生境对克隆植物的不利影响。     

竹类植物对异质生境的适应——表型可塑性

竹类植物是一类以木本为主的克隆植物,凭借表型可塑性的优势,对异质生境具有很强适应能力。然而,目前对竹类植物表型可塑性的实现方式及其异质生境适应对策未见系统总结,从而在一定程度上限制了竹类生态学的发展。从形态可塑性、选择性放置、克隆整合和克隆分工等4个方面对竹类植物的表型可塑性研究进行分析和梳理,结果表明:竹类植物在异质生境中具有明显的表型可塑反应,主要采用形态可塑性、选择性放置和克隆整合来适应异质生境,而克隆分工的普遍性仍有待验证;目前侧重于研究构件形态和生物量分配格局,而很少深入探讨形态、生理和行为等可塑性机理。今后竹类植物表型可塑性研究重点在于:1)克隆整合的格局与机理;2)克隆整合对生态系统的影响;3)克隆分工的形成及其与环境关系;4)表型可塑性的等级性及环境影响;5)不同克隆构型的表型可塑性特征及其内在机制。     

克隆植物对异质生境的适应对策研究进展

生境异质性是自然生态系统的基本特征,植物生长的必需资源和环境胁迫因子均存在着复杂的时间和空间异质性。克隆植物是指在自然条件下具有克隆特性的植物,即可通过与母株相连的芽、根茎、分蘖或枝条等繁殖体产生无性繁殖的植物,这些繁殖体一旦定居便可成为潜在的独立个体。克隆植物具有独特的生境适应策略(如形态可塑性、克隆整合、克隆分工、觅食行为、风险分摊等),面对异质性的生境条件,它可以通过调整自身的生理和形态结构来适应异质生境。目前,对于克隆植物在异质生境适应行为的研究已有很多报道,然而系统性的归纳和总结尚有欠缺。综述了克隆植物在不同资源异质生境(光照、养分、水分)和不同胁迫生境(盐碱胁迫、风沙胁迫、重金属胁迫)下独特的适应对策。最后,针对克隆植物对异质生境的适应对策,进行了总结并对未来的重点研究方向提出建议：(1)时间异质性尺度上的考量;(2)异质性生境中生物因子的调控作用;(3)克隆植物入侵机制;(4)克隆植物在生态修复中的应用潜力。     

Two types of division of labour in clonal plants: benefits, costs and constraints

Clonal plants spread vegetatively within their habitats by forming rooted ramets on stolons or rhizomes. Each of these ramets is capable of an independent existence after establishment. Nevertheless, ramets remain physically connected by stolon or rhizome internodes for variable periods of time, thereby allowing for resource movement and signal transduction within clones.Interconnected ramets of clonal plants, though potentially independent and totipotent, can specialize functionally in the performance of limited numbers of tasks such as the uptake of resources from above- vs below-ground sources, carbohydrate storage, vegetative spread and sexual reproduction. Such specialization and cooperation is comparable to a division of labour in economic systems or in colonies of social animals. The ecological significance of division of labour in clonal plants may be found in the increased efficiency of entire clones in exploiting their environments.Two different types of division of labour in clonal plants will be discussed in this review. The first type is an environmentally-induced specialization of ramets in the uptake of locally abundant resources (plastic division of labour), which can be found in several stoloniferous species. Evidence exists that this response increases resource uptake in spatially heterogeneous environments. The second type of division of labour, which occurs mainly in rhizomatous species, relates to a developmentally-programmed specialization and cooperation between interconnected ramets. This response pattern is thought to enhance plant performance by restricting the number of tasks for individual ramets and thereby significantly increasing the efficiency of task performance. In some plants, such an inherent division of labour is likely to contribute to nutrient extraction from poor and unpredictably variable sources.In this article not only benefits but also potential costs and constraints on division of labour in clonal plants are shown. The aim is to provide a review of existing knowledge and to develop concepts and hypotheses for future research.     

Clonal plant <Emphasis Type="Italic">Duchesnea indica</Emphasis> Focke forms an effective survival strategy in different degrees of Pb-contaminated environments

Clonal plants in heterogeneous environments can benefit from habitat selection, giving them the ability to utilize patchily distributed resources efficiently. However, most research is conducted in a resource heterogeneous environment, and the study of heterogeneous environment of non-resource material (copper, cadmium, lead, and so on) is limited. Research into clonal plant growth under heterogeneous toxic conditions could contribute to our understanding of the strategy of the selective establishment pattern. Thus, we examined clonal growth in a heterogeneous lead environment to enhance understanding of habitat selection strategies. The growth indices (stolon-length, ramet number, biomass, and lead-concentrations) of Duchesnea indica were examined under three levels (low, moderate, and high were represented by 0, 50 and 100%) of lead contamination and two degrees of heterogeneity (low and high heterogeneity under moderate contamination) environments in a glasshouse study. Habitat selection strategy was analyzed by clone growth pattern, labor division, and risk-spreading. The clones under the moderate contamination level, especially with high heterogeneity, demonstrated the optimal growth. They expanded their growth-pattern to escape the toxic environment, and rooted more ramets in the unpolluted patches, allocating more aboveground biomass to these areas. Moreover, parent ramets transported their lead in the soil to the offspring. The offspring spread the toxic risk by accumulating lead in their roots and producing more ramets. Optimal growth of clonal plants occurred in environments moderately contaminated with lead, especially under higher heterogeneity, which performed effective survival strategy by expensive growth architecture, aboveground biomass increase and risk-spreading.     

Effects of soil heterogeneity and clonal integration on Alternanthera philoxeroides populations with a radial ramet aggregation

Some clonal plants can spread their ramet populations radially, and soil heterogeneity and clonal integration may greatly affect the establishment of these types of populations. We constructed Alternanthera philoxeroides populations with a radial ramet aggregation, allowing old ramets of clonal fragments to concentrate in central pots and younger ramets to root in peripheral pots. The peripheral pots were supplemented either with three different levels (high, medium and low) of soil nutrients to simulate a heterogeneous soil environment, or only one medium level of soil nutrients to simulate a homogeneous environment. Stolon connections between the central older ramets and the peripheral younger ramets were left intact or severed to test the effect of clonal integration. The maintenance of stolon connection could induce the division of labor between different‐aged ramets, by increasing the root investment in central ramets and the above‐ground growth in peripheral ramets. The maintenance of stolon connection could improve the growth of the central and peripheral ramets, clonal fragments and even the whole population. However, the positive consequence in peripheral ramets and whole fragments was only detected in the high‐nutrient patch of heterogeneous treatment. In sum, in the population with the radial ramet aggregation, clonal integration can play a key role in the rapid recruitment of young ramets of A. philoxeroides fragments, as well as the expansion of the whole population. The magnitude of clonal integration also became more obvious in the peripheral young ramets and whole fragments that experienced high‐nutrient patches.     

克隆和有性亲体效应及其调控机制

植物表型受自身基因型、所处环境及其亲体所经历环境的共同影响;其中,亲体环境对子代表型的影响被称为亲体效应。亲体效应不仅可通过有性繁殖产生的种子传递给后代（即有性亲体效应）,也可以通过克隆生长等无性繁殖产生的分株传递给后代（即克隆亲体效应）。亲体效应对植物种群,特别是对有性繁殖受限、缺乏遗传变异的克隆植物种群的长期进化可能发挥着极其重要的作用,因此,对亲体效应研究进展的梳理非常必要。对克隆亲体效应和有性亲体效应的内涵进行了阐释,并论述了克隆和有性亲体效应对子代表型、适合度、种内/种间竞争能力以及种群/群落结构和功能的潜在影响;阐述了亲体效应的潜在调控机制,包括供给机制、代谢物质调控机制、表观遗传机制等;论述了克隆亲体效应在克隆植物适应进化中的作用。未来可以就克隆亲体效应的遗传稳定性及其对克隆生活史性状变异的贡献程度,以及克隆和有性亲体效应引起的表型多样性对种内/种间关系、种群/群落多样性及生态系统结构、功能和稳定性的影响开展深入研究。     

Physical factors increased quantity and quality of micropropagated shoots of Cannabis sativa L. in a repeated harvest system with ex vitro rooting

In Vitro Cellular & Developmental Biology - Plant - Micropropagation is a preferred method to propagate clean, clonal stock plants. Subculture is labor intensive and costly. In vitro hedging...     

Developmentally-programmed division of labour in the clonal invader Carpobrotus edulis

Invasive species are one of the main causes for the loss of global biodiversity. However, the mechanisms that explain the success of invasive species remain unsolved. Clonal growth has been pointed out as an attribute that could contribute to the invasiveness of plants, however little research has been conducted to determine the importance of clonal traits in successful invaders. One of the most interesting attributes related to clonal growth is the capacity for division of labour. In this experiment we investigated the capacity for division of labour in the aggressive invader Carpobrotus edulis, and how clonal integration can contribute to the expansion of this species. Division of labour was determined by studying the degree of morphological and physiological specialization of individual ramets to a specific activity: acquisition of soil or aboveground resources and aboveground expansion. Our results showed that there is division of labour in the clonal fragments, with older ramets increasing the biomass allocated to roots (specialization in the uptake of belowground resources) and younger ramets increasing the chlorophyll content and aboveground biomass (specialization in the uptake of aboveground resources). Physiological integration allows division of labour, and as consequence the overall performance of the clonal fragment was enhanced, with connected clonal fragments showing a higher total biomass than severed clonal fragments. Division of labour increased the aboveground growth of apical ramets of C. edulis, and therefore could contribute to an effective colonization of the surrounding area by this aggressive invader. Our study is the first exploring the role of division of labour in the expansion of an invader, and supports the idea that clonal traits could increase the invasiveness of plant species.     

On the ecological and evolutionary significance of storage in clonal plants

Environmental heterogeneity has received wide attention in clonal plant research over the last decade. Most studies have focussed on the effects of spatial variation in environmental conditions on the performance of ramets and genets, while the effects of temporal heterogeneity have only occasionally been studied. As a consequence, our current knowledge about functional responses of clonal plants to habitat patchiness is biased towards spatial aspects of environmental heterogeneity. Nevertheless, temporal changes in biotic and abiotic conditions do occur in most natural habitats, and they are very likely to affect plant growth and performance, and to create positive selection pressures on traits that can buffer plants against unfavorable consequences of this variability. Storage of resources is a widespread phenomenon in clonal plant species. Typical clonal structures such as stolons, rhizomes and hibernacles serve as storage organs. However, the ecologic significance of storage in clonal plant structures remains partly unclear. We suggest that the lack of understanding with respect to resource storage in clonal plants be related to our poor knowledge of ecologic implications of temporal habitat heterogeneity in natural environments. Resource storage can be understood as a safety measure against temporal changes in the growing conditions of plants. This paper summarizes existing information about the ecologic relevance of storage in clonal plants and it tries to develop a framework for further investigation of resource storage as a strategy to enhance the performance of clonal plants in temporally variable environments.