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     

异质性生境中匍匐茎草本野草莓(Fragaria vesca)的克隆内资源共享

研究了不同海拔高度(1800和3900m)的匍匐茎克隆植物野草莓(Fragaria vesca)种群对光照和养分资源斑块性分布生境的响应。结果表明: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2个种群的野草莓的近端、远端分株部分和整个克隆片段的生物量和分株数均明显增加。当近端分株部分经历低光高养,而与其相连的远端分株部分经历高光低养时,相比于整个克隆片段都处于低光高养的同质性生境,来自2个海拔的种群的近端分株部分都会增加对根的生物量分配;当近端分株部分经历高光低养,而与其相连的远端分株部分经历低光高养时,相比于整个克隆片段都处于低光高养的同质性生境,来自2个海拔的种群的近端分株部分都会减少对根的生物量分配,远端分株部分也被观察到类似的生物量分配格局。相比于高光低养的同质性生境,当与低光高养的远端分株部分相连时,经历高光低养的近端分株部分有更大的叶面积;相比于低光高养的同质性生境,当与低光高养近端分株部分相连时,经历高光低养的远端分株部分有更大的叶面积。结果表明,野草莓在资源交互斑块性生境中发生了克隆内分工,克隆内分工有利于克隆植物对异质性资源的利用,对克隆植物在资源斑块性分布生境中的生存和生长具有重要的意义。     

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。     

克隆整合对异质性盐分胁迫下积雪草生长的影响

以匍匐茎草本克隆植物积雪草(Centella asiatica)为材料进行盆栽试验,研究了克隆整合特性对异质性盐分胁迫条件下植物生长的影响。试验中将远端分株(较幼分株)分别处于盐分胁迫或正常土壤条件下,切断或保持其与近端分株(较老分株)间的匍匐茎连接。结果表明：盐分胁迫下,克隆整合提高了受胁迫远端分株和整个克隆片断的叶面积和生物量等生长指标;与未遭受盐分胁迫处理相比,匍匐茎连接处理导致远端分株的根冠比显著降低。克隆整合还减轻了盐分胁迫对分株的叶绿素含量和光化学效率的影响,但盐分胁迫下,匍匐茎连接处理远端分株的净光合速率与匍匐茎切断处理远端分株并无显著差异,连接受胁迫的远端分株并没有引起近端分株生物量的明显损耗以及光合速率的补偿性提高。总之,克隆整合促进了积雪草遭受盐分胁迫的分株和整个克隆片段的生长,这对于丰富和发展异质性环境胁迫下克隆植物的生态适应对策具有重要意义。     

异质性重金属镉胁迫下克隆整合对匍匐茎草本植物积雪草生长的影响

 采用盆栽试验研究了异质性重金属镉胁迫下, 克隆整合对匍匐茎草本植物积雪草(Centella asiatica)生长的影响。将远端分株(相对年幼的分株)分别置于对照和镉胁迫处理下, 并对远端分株与近端分株(相对年长的分株)之间的匍匐茎进行切断或保持连接处理。研究结果显示: 镉胁迫处理显著降低了积雪草远端分株的净光合速率(P_n)、最大光量子产量(F_v/F_m)、叶绿素含量、叶面积、分株数和生物量; 克隆整合缓解了镉胁迫对远端分株生长的不利影响; 克隆整合不仅未导致相连近端分株的损耗, 而且相连近端分株的光合效率也没有表现出补偿性增加; 克隆整合降低了远端受胁迫分株的根冠比, 从而使之减少了对土壤中重金属镉的吸收; 匍匐茎切断和镉胁迫处理对近端分株、远端分株的叶柄长没有显著的影响。结果表明: 克隆整合提高了积雪草遭受镉胁迫的远端分株的生长, 改变了其生物量分配格局, 并有助于整个克隆片段在异质性重金属胁迫下的生长。该研究对于丰富和发展异质性环境胁迫下克隆整合的生态适应对策具有重要意义。     

异质性光照下匍匐茎草本狗牙根克隆整合的耗益

在一盆栽实验中,将匍匐茎草本植物狗牙根克隆分株对进行异质性光照处理,对远端分株(幼年)分别进行不同程度的遮荫,并对分株对之间的匍匐茎进行保持连接或是切断处理。结果显示:在中度遮荫时,切断匍匐茎连接显著降低了远端分株的生物量和净光合速率(Pn);在重度遮荫时,切断匍匐茎连接显著降低了远端分株的分株数、叶片数、生物量、净光合速率(Pn)、最大光量子产量(Fv/Fm)和实际光量子产量(ФPSⅡ),克隆整合缓解了遮荫胁迫对远端分株生长的影响。在中度遮荫时,保持匍匐茎连接显著提高了近端分株的净光合速率(Pn);在重度遮荫时,保持匍匐茎连接显著提高了近端分株的最大光量子产量(Fv/Fm)、实际光量子产量(ФPSⅡ)和净光合速率(Pn),克隆整合使得相连未受胁迫近端分株的光合效率表现出补偿性增加。相比于匍匐茎切断处理,当远端分株遭受重度遮荫胁迫时,克隆整合引起近端未受胁迫分株生物量显著降低,而整个克隆片段生物量没有显著变化。因此,当远端分株遭受重度遮荫胁迫时,匍匐茎草本狗牙根可能采取一种风险分摊策略以降低基株死亡风险,这样一种策略对于维持克隆植物在异质性生境中基株适合度具有重要意义。     

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。     

异质性光照生境下克隆整合对外来入侵植物薇甘菊生长的影响

薇甘菊(Mikania micrantha)原产中、南美洲,1919年薇甘菊作为杂草在中国香港出现,目前已广泛侵入中国广东、海南、云南等省区,是世界上最有害的100种外来入侵物种之一。本文以海南重要外来入侵植物薇甘菊(Mikania micrantha)为实验材料,通过温室盆栽实验,研究了克隆整合对异质性光照生境下薇甘菊克隆片段生长的影响。结果表明:在异质性光照下,克隆整合显著提高了低光斑块分株的生物量,但同时降低了高光斑块分株的生物量,对克隆片段总体的生物量积累无显著影响,且这一结果不受资源输送方向的影响;克隆整合降低了异质性光照下克隆分株间根冠比的差异,加大了克隆分株间净光合速率的差异,且倾向于提高生长在高光斑块分株的比叶面积;克隆整合虽然并不能促进薇甘菊匍匐茎克隆片段在异质性光照生境下总体的生长,但可以促进低光斑块下分株的生长,因而,克隆整合可促进薇甘菊从开阔生境向低光生境(森林、杂草群落等)的入侵能力,因此,克隆整合特性是薇甘菊对异质性光照环境的重要适应对策之一。     

光照强度和基质养分对匍匐茎草本金戴戴克隆生长和克隆形态的影响

在深度遮光 (光照强度为高光条件的 6 .2 5% ,约为自然光照的 5.3% )或低养分条件下 ,金戴戴 (HalerpestesruthenicaOvcz.)生物量、初级分株叶面积、分株总数、匍匐茎总数和总长度均显著减小 ,而比节间长和比叶柄长显著增加。在低养分条件下 ,金戴戴匍匐茎平均节间长显著增加 ,而匍匐茎分枝强度和分株数显著减小。这些结果与克隆植物觅食模型相符合 ,表明当生长于异质性生境中 ,金戴戴可能通过以克隆生长和克隆形态的可塑性实现的觅养行为来增加对养分资源的摄取。在深度遮光条件下 ,金戴戴平均间隔子长度 (即平均节间长和平均叶柄长 )均显著减小。这一结果与以往实验中匍匐茎草本间隔子对中度和轻度遮光 (光照强度为高光条件的 1 3%～ 75% ,>1 0 %的自然光照 )的反应不同。这表明 ,在深度遮光条件下匍匐茎克隆植物可能不发生通过间隔子可塑性实现的觅光行为。光照强度和基质养分条件的交互作用对许多性状如总生物量、匍匐茎总数和总长度、二级和三级分株数、分株总数、初级分株叶面积以及分枝强度均有十分显著的效应。在高光条件下 ,基质养分对这些性状有十分显著的影响 ;而在低光条件下 ,基质养分条件对这些性状不产生影响或影响较小。这表明 ,光照强度影响金戴戴对基质养分的可塑性反应。在深度遮光     

克隆整合对异质性土壤养分生境下薇甘菊生长的影响

环境资源的异质性在自然界中普遍存在。克隆植物能通过克隆整合较好地适应异质性生境。本文以海南外来强入侵性植物薇甘菊为材料,通过温室盆栽试验,研究克隆整合对异质性土壤养分生境下薇甘菊克隆片段生长的影响。结果表明:在养分异质下,克隆整合显著提高了低养分斑块分株的生物量,但同时降低了高养分斑块分株的生物量,对克隆片段总体的生长无显著影响,且这一结果不受资源输送方向的影响。克隆整合对薇甘菊克隆分株的光合速率和比叶面积影响较小,但当近端分株处于高养分条件时,其改变了克隆分株的根冠比。这些结果指示:克隆整合有利于异质性土壤养分条件下薇甘菊对低养分斑块的占领。因此,克隆整合可影响薇甘菊对资源异质性生境的入侵能力,它使薇甘菊能够扩展到低养分斑块,从而提高其入侵扩散能力。     

Clonal Integration of Fragaria orientalis in Reciprocal and Coincident Patchiness Resources: Cost-Benefit Analysis

Clonal growth allows plants to spread horizontally and to experience different levels of resources. If ramets remain physiologically integrated, clonal plants can reciprocally translocate resources between ramets in heterogeneous environments. But little is known about the interaction between benefits of clonal integration and patterns of resource heterogeneity in different patches, i.e., coincident patchiness or reciprocal patchiness. We hypothesized that clonal integration will show different effects on ramets in different patches and more benefit to ramets under reciprocal patchiness than to those under coincident patchiness, as well as that the benefit from clonal integration is affected by the position of proximal and distal ramets under reciprocal or coincident patchiness. A pot experiment was conducted with clonal fragments consisting of two interconnected ramets (proximal and distal ramet) of Fragaria orientalis. In the experiment, proximal and distal ramets were grown in high or low availability of resources, i.e., light and water. Resource limitation was applied either simultaneously to both ramets of a clonal fragment (coincident resource limitation) or separately to different ramets of the same clonal fragment (reciprocal resource limitation). Half of the clonal fragments were connected while the other half were severed. From the experiment, clonal fragments growing under coincident resource limitation accumulated more biomass than those under reciprocal resource limitation. Based on a cost-benefit analysis, the support from proximal ramets to distal ramets was stronger than that from distal ramets to proximal ramets. Through division of labour, clonal fragments of F. orientalis benefited more in reciprocal patchiness than in coincident patchiness. While considering biomass accumulation and ramets production, coincident patchiness were more favourable to clonal plant F. orientalis.     

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.     

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     

Nutrient addition does not increase the benefits of clonal integration in an invasive plant spreading from open patches into plant communities

• One benefit of clonal integration is that resource translocation between connected ramets enhances the growth of the ramets grown under stressful conditions, but whether such resource translocation reduces the performance of the ramets grown under favourable conditions has not produced consistent results. In this study, we tested the hypothesis that resource translocation to recipient ramets may reduce the performance of donor ramets when resources are limiting but not when resources are abundant.
• We grew Mikania micrantha stolon fragments (each consisting of two ramets, either connected or not connected) under spatially heterogeneous competition conditions such that the developmentally younger, distal ramets were grown in competition with a plant community and the developmentally older, proximal ramets were grown without competition. For half of the stolon fragments, slow‐release fertiliser pellets were applied to both the distal and proximal ramets.
• Under both the low and increased soil nutrient conditions, the biomass, leaf number and stolon length of the distal ramets were higher, and those of the proximal ramets were lower when the stolon internode was intact than when it was severed. For the whole clone, the biomass, leaf number and stolon length did not differ between the two connection treatments. Connection did not change the biomass of the plant communities competing with distal ramets of M. micrantha.
• Although clonal integration may promote the invasion of M. micrantha into plant communities, resource translocation to recipient ramets of M. micrantha will induce a cost to the donor ramets, even when resources are relatively abundant.

     

Spatial division of labour of Schoenoplectus americanus

If connected ramets are growing in heterogeneous environments, Division of Labour (DoL) among ramets potentially will result in more efficient sharing of resources and an overall benefit to the plants. As a result of DoL, connected ramets growing in a heterogeneous environment might achieve more biomass than ramets growing in a homogeneous environment. DoL has been demonstrated to occur in a few clonal plant species, although most studies simply focussed on biomass allocation, not on actual resource capturing such as water and nutrient consumption. The model system for our study is one in which two connected ramet groups of Schoenoplectus americanus were placed into contrasting environments. In one treatment, the connected ramets grew in heterogeneous environments and in the other treatment, the connected ramets grew in the same (i.e. homogeneous) environment. We manipulated two variables (light and salinity) in the experiment. We hypothesized that ramets growing in a shaded and fresh water condition in a heterogeneous environment would use more water than ramets growing in a similar condition but in a homogeneous environment. We further hypothesized that ramets growing in a light and saline condition in a heterogeneous environment would assimilate less water than ramets growing in a similar condition but in a homogeneous environment. These hypotheses are based on the assumption that ramets in a heterogeneous environment would translocate water from ramets growing in a shaded and fresh water condition to ramets growing in a light and saline water condition. We also hypothesized that ramets growing in heterogeneous environments achieve larger biomass than ramets in homogeneous environments. Ramets grown in light and saline conditions in heterogeneous environments allocated more biomass to aboveground parts, had taller shoots, larger Specific Green (leaf) Area and consumed less water than ramets grown in similar conditions but in a homogeneous environment. Results confirm the hypothesis that connected ramets in heterogeneous environments are specialised to capture locally abundant resources and share these with connected ramets growing in other habitats. The result of DoL is that the entire connected ramet system benefits and achieves higher biomass.     

根茎型植物扁秆荆三棱对光照强度和养分水平的生长响应及资源分配策略

自然界中光照和养分因子常存在时空变化,对植物造成选择压力。克隆植物可通过克隆生长和生物量分配的可塑性来适应环境变化。尽管一些研究关注了克隆植物对光照和养分因子的生长响应,但尚未深入全面了解克隆植物对光照和养分资源投资的分配策略。以根茎型草本克隆植物扁秆荆三棱(Bolboschoenus planiculmis)为研究对象,在温室实验中,将其独立分株种植于由2种光照强度(光照和遮阴)和4种养分水平(对照、低养分、中养分和高养分)交叉组成的8种处理组合中,研究了光照和养分对其生长繁殖及资源贮存策略的影响。结果表明,扁秆荆三棱的生长、无性繁殖及资源贮存性状均受到光照强度的显著影响,在遮阴条件下各生长繁殖性状指标被抑制。且构件的数目、长度等特征对养分差异的可塑性响应先于其生物量积累特征。在光照条件下,高养分处理的总生物量、叶片数、总根茎分株数、长根茎分株数、总根茎长、芽长度、芽数量等指标大于其他养分处理,而在遮阴条件下,其在不同养分处理间无显著差异,表明光照条件可影响养分对扁秆荆三棱可塑性的作用,且高营养水平不能补偿由于光照不足而导致的生长能力下降。光照强度显著影响了总根茎、总球茎及大、中、小球茎的生物量分配,遮阴条件下,总生物量减少了对地下部分根茎和球茎的分配,并将有限的生物量优先分配给小球茎。总根茎的生物量分配未对养分发生可塑性反应,而随着养分增加,总球茎分配下降,说明在养分受限的环境中球茎的贮存功能可缓冲资源缺乏对植物生长的影响。在相同条件下,根茎生物量对长根茎的分配显著大于短根茎,以保持较高的繁殖能力;而总球茎对有分株球茎的生物量分配小于无分株球茎,表明扁秆荆三棱总球茎对贮存功能的分配优先于繁殖功能。研究为进一步理解根茎型克隆植物对光强及基质养分环境变化的生态适应提供了依据。     

Integration in the clonal plant <Emphasis Type="Italic">Eriophorum angustifolium</Emphasis>: an experiment with a three-member-clonal system in a patchy environment

A clonal plant in heterogeneous environments is usually expected to profit from resource exchange via a clonal network where ramets placed in contrasting environments can specialise so to acquire the most abundant resources. An experiment was designed using the three member clonal system of Eriophorum angustifolium, which consisted of one parent ramet growing in a resource poor environment and two offspring: one was limited in growth by nutrients while the other was light limited; the contrast in availability of limited resources between the offspring ramets was high, medium or none, with the system either connected or severed. The total resource availability was the same in all treatments. We proposed four possible scenarios for the system: offspring ramets will share resources via the deficient parent ramet, and the whole clone will profit from the contrasting environment (scenario 1); offspring ramets will support exclusively the parent ramet, and the whole clone will profit from a homogeneous environment (scenario 2); offspring ramets will stop the export of the limiting resource to the parent ramet, with split and connected treatments not differing (scenario 3); and offspring ramets will exhaust the carbon stored in the biomass of the parental ramet; offspring ramet will profit from connection (scenario 4). In the experiment, the limiting resources were sent to the strongest sink (scenario 2). The parent ramet growing in a deficient environment received the highest support in the treatment where both offspring ramets were growing in the same conditions (no-contrast treatment). Production of new shoots, but not biomass of whole clone, was supported in a homogenous environment. The experiment revealed that multiple stresses might prohibit free exchange of limiting resources via the clonal network and supports the idea that experimental studies on more complex clones are essential for understanding the costs and benefits of clonal growth.     

Partial mechanical stimulation facilitates the growth of the rhizomatous plant Leymus secalinus: modulation by clonal integration

Background and Aims

Mechanical stimulation (MS) often induces plants to undergo thigmomorphogenesis and to synthesize an array of signalling substances. In clonal plants, connected ramets often share resources and hormones. However, little is known about whether and how clonal integration influences the ability of clonal plants to withstand MS. We hypothesized that the effects of MS may be modulated by clonal integration.

Methods

We conducted an experiment in which ramet pairs of Leymus secalinus were subjected to three treatments: (1) connected ramet pairs under a homogeneous condition [i.e. the proximal (relatively old) and distal (relatively young) ramets were not mechanically stressed]; (2) connected ramet pairs under a heterogeneous condition (i.e. the proximal ramet was mechanically stressed but the distal ramet was not); and (3) disconnected ramet pairs under the same condition as in treatment 2. At the end of the experiment, we harvested all plants and determined their biomass and allocation.

Key Results

Clonal integration had no significant influence on measured traits of distal L. secalinus ramets without MS. However, under MS, plants with distal ramets that were connected to a mother ramet produced more total plant biomass, below-ground biomass, ramets and total rhizome length than those that were not connected. Partial MS exerted local effects on stimulated ramets and remote effects on connected unstimulated ramets. Partial MS increased total biomass, root/shoot ratio, number of ramets and total rhizome length of stimulated proximal ramets, and increased total biomass, root weight ratio, number of ramets and total rhizome length of connected unstimulated ramets due to clonal integration.

Conclusions

These findings suggest that thigmomorphogenesis may protect plants from the stresses caused by high winds or trampling and that thigmomorphogenesis can be strongly modulated by the degree of clonal integration.     

The effects of physiological integration on biomass partitioning in plant modules: an experimental study with the stoloniferous herb Glechoma hederacea

Morphological and physiological plasticity are crucial attributes enabling plants to acquire resources from heterogeneous habitats. Although physiological integration can modify biomass partitioning in modules, especially when connected modules experience different conditions, its ecological importance has been largely overlooked. This experiment examined its effects on above- and belowground biomass partitioning by modules in the stoloniferous herb Glechoma hederacea. We studied how biomass allocation to roots by younger ramets was affected by connection to older ramets, and by nutrient conditions. A lower proportion of biomass was allocated to roots by younger ramets growing under low nutrient (LN) conditions when connected to older ramets in high nutrient (HN) conditions than when they were isolated, demonstrating localised modification of biomass partitioning due to physiological integration. The proportion of biomass allocated to roots by younger ramets was also lower when connected to older ramets in HN conditions than when connected to older ramets in LN conditions. Thus, the effect of integration on biomass partitioning depended on the nutrient conditions experienced by connected ramets. Such changes in biomass partitioning would result in more extensive stolon growth, and greater lateral displacement of new ramets. Understanding the ecological implications of phenotypic plasticity in plants will require further examination of the effects of physiological integration when connected modules experience contrasting growing conditions. This study demonstrates that such integration affects the biomass allocation strategy of connected ramets, enhancing resource acquisition in heterogeneous habitats. The widespread success of clonality in many communities is likely to be strongly promoted by this characteristic.     

Environmentally-induced functional specialization for locally abundant resources in the stoloniferous herb Duchesnea indica

Reciprocally patchy environments, where the availability of two resources are patchily distributed and negatively correlated in each patch, are common in many ecosystems. Interconnected ramets of clonal plants can specialize in the uptake of locally abundant resources. Ramet pairs of the stoloniferous herb Duchesnea indica were grown in reciprocally patchy environments i.e., one ramet of a pair was grown in the high light but low water patch (high light patch) and the other in the low light but high water patch (high water patch). Biomass allocation pattern (root-shoot ratio), morphological traits (leaf area and root length) and physiological traits (photosynthetic rate and chlorophyll content) were altered in a way that potentially enables ramets to enhance the capture of the locally abundant resource (i.e., increase the capture of light resource in the high light patch and of water in the high water patch). As a result,biomass and number of ramets in the connected ramet pairs were greatly improved. Functional specialization of ramets, modified by clonal integration, may have contributed greatly to the growth increase of D. indica in the reciprocally patchy environment.