两种践踏胁迫下克隆整合对入侵植物空心莲子草生长的影响

研究了两种践踏胁迫下克隆整合对入侵植物空心莲子草生长的影响.结果表明:(1)切断分株间的匍匐茎连接,会降低先端分株的生物量、分株数、总匍匐茎长度和总叶片数,但会显著增强基端分株的生物量.(2)对先端分株的践踏胁迫会显著降低先端分株叶片的叶绿素相对含量,对基端分株的践踏胁迫会显著降低基端分株的生物量和总匍匐茎长度.(3)对于基端分株的分株数、总匍匐茎长度和总叶片数来说,当进行基端分株践踏胁迫时,匍匐茎连接对其影响不大,而当进行先端分株践踏胁迫时,则明显对其不利.(4)对于整个克隆片段,践踏胁迫的差异和匍匐茎是否切断对其生长没有显著影响.     

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。     

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。     

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。     

莲草直胸跳甲取食对空心莲子草和莲子草克隆整合的影响

很多外来入侵植物都具有克隆生长习性,探究克隆整合特性与外来克隆植物入侵性间的关系对阐明其生态适应性及入侵机制具有重要的意义。本研究以入侵植物空心莲子草及其本地同属种莲子草为研究对象,比较在生防昆虫莲草直胸跳甲的取食下,克隆整合对两种植物先端分株、基端分株及整个克隆片段生长和生物量分配的影响。结果表明: 在莲草直胸跳甲取食下,有克隆整合的空心莲子草先端分株的叶片数、茎长、分株数及整个克隆片段的地径均显著高于无克隆整合植株,其基端分株及整个克隆片段的地下生物量和总生物量相较于无克隆整合植株分别降低了78.2%、60.9%和48.7%、37.2%;有克隆整合的莲子草先端分株的地径及整个克隆片段的叶片数与无克隆整合植株相比显著增加,其基端分株数显著降低了21.7%,而其先端分株、基端分株及整个克隆片段的生物量均无显著差异。耗益分析表明,在莲草直胸跳甲取食下,空心莲子草先端分株的分株数与生物量及莲子草先端分株的分株数均能通过克隆整合显著受益,而两种植物基端的分株数、生物量的耗益则不受克隆整合处理的影响。这些结果表明,克隆整合虽能在一定程度缓解莲草直胸跳甲对于两种植物先端分株的取食压力,且空心莲子草的克隆整合作用要强于莲子草,但在整个克隆片段水平上,两种植物并不能通过克隆整合显著获益。     

克隆整合有助于狗牙根抵御水淹

尽管国内外开展了大量的克隆整合对克隆植物抵御逆境能力影响的研究, 但整合对植物抵御水淹能力的影响研究仍比较缺乏。该文从克隆整合的角度探讨多年生草本植物狗牙根(Cynodon dactylon)对水淹胁迫的响应。试验模拟了先端分株(相对年幼的分株)分别处于0、5和15 cm三种水淹胁迫环境, 并在每个水淹梯度下实施先端分株与基端分株(相对年长的分株)之间匍匐茎连接或切断处理, 调查水淹一个月后基端分株和先端分株以及整个克隆片段在形态和生理上的表现。研究发现: 切断匍匐茎连接显著降低了狗牙根先端分株的生长, 表现在生物量下降、匍匐茎长度减短和分株数减少等方面; 水淹显著抑制了先端分株的生长, 但对基端分株的生长并未造成显著影响; 在5 cm水淹处理下, 匍匐茎保持连接时, 先端分株和整个克隆片段的生长显著增加; 连接或切断处理在不同水淹梯度下对匍匐茎平均节间长没有显著影响, 对先端分株或基端分株在光化学转化效率上也未表现显著性差异。结果表明: 克隆整合效应促进了狗牙根在水淹胁迫下分株的生长, 并有助于整个克隆片段抵御水淹胁迫。     

克隆整合是否有助于空心莲子草抵抗菟丝子的短期寄生?

关于克隆植物通过克隆整合抵御逆境能力影响的研究已有很多,但克隆整合是否能抵御植物寄生的研究还比较缺乏。本文利用匍匐茎克隆植物空心莲子草和1年生寄生植物菟丝子作为研究系统,检验假说"克隆整合有助于克隆植物抵抗寄生植物的寄生胁迫"。在实验中,相连分株分别经历了以下处理:M+-D-(分株对中母株被寄生,子株不被寄生),M--D+(母株不被寄生,子株被寄生),M+-D+(母株、子株均被寄生),M--D-(母株、子株均不被寄生)。研究发现,菟丝子寄生显著影响了空心莲子草的叶绿素相对含量、最大光量子产量等生理指标,以及叶片数、匍匐茎长度、分株数等生长指标,但不同处理间的生物量没有显著差异。本实验的结果没有支持实验假说。这样的结果可能是由于本实验时间较短所引起的,表明克隆整合适应性的表达不是无条件的。进一步实验应该既能够检验短期效应也能够检验长期效应。     

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。     

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。     

Clonal integration affects growth and sediment properties of the first ramet generation,but not later ramet generations under severe light stress

克隆整合影响严重光胁迫下第一分株世代的生长和沉积物特征但不影响 后续分株世代的生长和沉积物特征 克隆整合通过缓冲环境压力和提高资源获取效率使克隆植物受益。然而,在一个克隆系统中,受益于克隆整合的连接分株世代的数量很少受到关注。我们进行了一个盆栽实验来评估沉水植物苦草 (Vallisneria natans)克隆系统内的生理整合程度,该克隆系统由一个母株和3个依次连接的后代分株组成。 母株生长在正常光照下,而后代分株被严重遮荫。母株与后代分株间的匍匐茎被切断或保持连接,但3个后代分株之间的连接仍然存在。与遮荫的后代分株连接时,苦草未遮荫的母株的光合能力显著增强,但其生物量积累大大减少。克隆整合显著增加了第一分株世代(相邻分株)的生物量积累和土壤的碳氮可用性、胞外酶活性和微生物生物量,但没有增加后续分株世代的这些特征。我们的结果表明,在严重光胁迫下,来自苦草母株的支持可能仅限于克隆系统中相邻的后代分株,这暗示着一个分株世代的效应。我们的结果有助于更好地理解克隆植物的层次结构和分段化。这些发现表明克隆整合程度在分株种群的生态相互作用中起着至关重要的作用。     

Effects of stolon severing on the expansion of Alternanthera philoxeroides from terrestrial to contaminated aquatic habitats

Few studies have examined the effects of clonal integration (translocation of resources between interconnected ramets) during the expansion of amphibious clonal plants from terrestrial to aquatic habitats. We conducted a greenhouse experiment to simulate the expansion of plants from terrestrial to contaminated aquatic habitats in the amphibious stoloniferous herb Alternanthera philoxeroides (alligator weed). The proximal ramets (i.e. relatively old) of clonal fragments grown in uncontaminated soils were connected to (allowing clonal integration) or disconnected from (preventing clonal integration) distal ramets (i.e. relatively young) grown either in uncontaminated water (control, no CuSO₄) or in four copper‐contaminated water treatments containing 31.25, 62.5, 125 and 250 mg/L CuSO₄, respectively. When a stolon connection was severed, all distal ramets grown in the contaminated water died. When the stolon connection was intact, however, the survival rate of the distal ramets was 85–100% when they were grown at the three lower levels of contamination and 43.75% at the highest level. Moreover, the survival rate and growth of the distal ramets grown in the three lower levels of contamination treatments did not differ from those in the control (uncontaminated water). These results suggest that clonal integration could greatly improve the survival and growth of alligator weed subjected to moderate levels of copper stress. Although clonal integration could also increase the survival rate of the connected distal ramets subjected to the highest level of copper stress (250 mg/L CuSO₄) compared with that of disconnected distal ramets, the survival rate and growth measures were still significantly lower than those in the control. This suggests that clonal integration plays a limited role in the survival and growth of alligator weed when it is subjected to severe stress by high levels of copper contamination.     

Physiological integration helps a clonal macrophyte spread into competitive environments and coexist with other species

Physiological integration may help clonal macrophytes invade or escape from existing communities. No studies have tested the above hypothesis in aquatic plants. In an outdoor pond experiment, we subjected clonal fragments of the submerged macrophyte Vallisneria spiralis L. to heterogeneous environments in which V. spiralis spread from bare habitats towards vegetated habitats occupied by Myriophyllum spicatum L. or V. spiralis spread from vegetated habitats towards bare habitats. V. spiralis stolons between ramets in bare habitats and in vegetated habitats were either intact or severed. We investigated the habitat selection of V. spiralis by examining the allocation of biomass and ramets to heterogeneous habitats during its vegetative spread phase. Results showed that the stolon connection had different effects on the habitat selection of V. spiralis with regard to invasion and escape. When V. spiralis spread from bare to vegetated habitats, in comparison to severing the stolon, the stolon connection eventually facilitated a 49% increase in biomass and a 27% increase in number of ramets allocated to vegetated habitats. However, when V. spiralis spread from vegetated to bare habitats, biomass and ramets allocated to bare habitats were not significantly changed by the stolon connection (only a 5% increase in biomass and a 6% increase in number of ramets). These results indicate that clonal integration facilitated V. spiralis not to escape from but invade into vegetated habitats. The study provides evidence that physiological integration is important for survival and tolerance of ramets in competitively stressful environments and can help clonal macrophytes coexist with other species.     

Relative costs and benefits of clonal integration of Zoysia japonica under various N:P ratios

Clonal plants adaptively respond to abiotic stress, but to date little is known about under what circumstanses clonal integration is beneficial, or costly. To study the costs and benefits of clonal integration on clonal growth, we cultivated Zoysia japonica under three ratios of N:P (N:P ≈ 7, 14:1 and 21:1), and four types of stolon severing treatments (connected stolon CS, light severing LS, moderate severing MS, serious severing SS). The results showed that Z. japonica performed best at a low ratio of N:P (N:P ≈ 7:1). When the stolons were connected (CS), the growth of primary A‐ramets, multiple‐nodes and stolons benefited from clonal integration; however, the growth of primary B‐ramets on the primary stolons, A and B ramets was significantly reduced (p < 0.05). In the moderate stolon severing treatment MS_7:1 (N:P ≈ 7:1), clonal integration appeared more cost effective than in all other treatments. On the whole, with increasing stolon severing intensity, the cost of clonal integration increased and the clonal growth of Z. japonica declined significantly. The pattern of biomass allocation may be useful for Z. japonica to adapt to the various environments, and clonal integration plays a significant role under adverse environmental conditions.     

Clonal integration supports the expansion from terrestrial to aquatic environments of the amphibious stoloniferous herb Alternanthera philoxeroides

Effects of clonal integration on land plants have been extensively studied, but little is known about the role in amphibious plants that expand from terrestrial to aquatic conditions. We simulated expansion from terrestrial to aquatic habitats in the amphibious stoloniferous alien invasive alligator weed ( Alternanthera philoxeroides ) by growing basal ramets of clonal fragments in soils connected (allowing integration) or disconnected (preventing integration) to the apical ramets of the same fragments submerged in water to a depth of 0, 5, 10 or 15 cm. Clonal integration significantly increased growth and clonal reproduction of the apical ramets, but decreased both of these characteristics in basal ramets. Consequently, integration did not affect the performance of whole clonal fragments. We propose that alligator weed possesses a double-edged mechanism during population expansion: apical ramets in aquatic habitats can increase growth through connected basal parts in terrestrial habitats; however, once stolon connections with apical ramets are lost by external disturbance, the basal ramets in terrestrial habitats increase stolon and ramet production for rapid spreading. This may contribute greatly to the invasiveness of alligator weed and also make it very adaptable to habitats with heavy disturbance and/or highly heterogeneous resource supply.     

Combined effects of resource heterogeneity and simulated herbivory on plasticity of clonal integration in a rhizomatous perennial herb

Previous lines of investigation assuming potential advantage of clonal integration generally have neglected its plasticity in complex heterogeneous environments. Clonal plants adaptively respond to abiotic heterogeneity (patchy resource distribution) and herbivory‐induced heterogeneity (within‐clone heterogeneity in ramet performance), but to date little is known about how resource heterogeneity and simulated herbivory jointly affect the overall performance of clones. Partial damage within a clone caused by herbivory might create herbivory‐induced heterogeneity in a resource‐homogeneous environment, and might also decrease or increase the extent of heterogeneity under resource‐heterogeneous conditions. We conducted a greenhouse experiment in which target‐ramets of Leymus chinensis segments within homogeneous or heterogeneous nutrient treatments were subject to clipping (0% or 75% shoot removal). In homogeneous environments with high (9:9) nutrient availability, ramet biomass of L. chinensis with intact or severed rhizomes is 0.70 or 0.69 g. Conversely, target‐ramet biomass with intact rhizomes is obviously lower than that of the severed target‐ramets in the homogeneous environments with medium (5:5) and low (1:1) nutrient availability. High resource availability and the presence of herbivory can alleviate negative effects of rhizome connection under homogeneous conditions, by providing copious resource or creating herbivory‐induced heterogeneity respectively. Herbivory tolerance of clonal fragments with connected rhizomes was higher than that of fragments with severed rhizomes under heterogeneous conditions. These findings confirmed the unconditional advantage of clonal integration on reproduction under the combined influence of resource heterogeneity and simulated herbivory. Moreover, our results made clear the synergistically interactive effects of resource heterogeneity and simulated herbivory on costs and benefits of clonal integration. This will undoubtedly advance our understanding on the plasticity of clonal integration under complex environmental conditions.     

Physical connection decreases benefits of clonal integration in Alternanthera philoxeroides under three warming scenarios

Physical connection between ramets usually allows clonal plants to perform better but can have the opposite effects in some cases. Clonal integration and the effects of climate warming have been extensively studied, but to date little is known about how climate warming affects the benefits of clonal integration. We conducted a field experiment in which Alternanthera philoxeroides segments with connected and severed stolons were subject to four climate regimes (ambient, day warming, night warming and daily warming), and measured final biomass, number of ramets and total length of stolons. Across the three warming treatments, temperature rise suppressed growth of clonal fragments with connected stolons but increased growth of fragments with severed stolons; temperature rise affected the biomass of distal ramets but not proximal ramets, and had similar effects on the numbers of proximal and distal ramets. When the three warming treatments were considered separately, they had contrasting consequences for the benefits of clonal integration. Specifically, when fragments were exposed to day and night warming, physical connection evened out the advantages of clonal integration that occur under ambient conditions; when fragments were exposed to daily warming, physical connection led to smaller clonal plants. These findings suggest that physical connection between ramets may be disadvantageous to overall performance of A. philoxeroides fragments under climate warming, and also indicate that the net consequences of daily warming outweigh those of day or night warming.     

The effects of clonal integration on morphological plasticity and placement of daughter ramets in black locust (Robinia pseudoacacia)

We studied the field response of Robinia pseudoacacia L. to light, total soil nitrogen, available soil phosphorus and soil pH. Results indicated that there was very strong clonal integration between mother and daughter ramets. Mother ramets can provide nitrogen and phosphorus to daughter ramets sufficient for their continued growth through strong clonal integration, but cannot provide enough photosynthate. With clonal integration, soil nitrogen and phosphorus availability had no effect on biomass allocation to roots, number of ramets and length of connection roots. Biomass allocation to roots increased markedly and responded to nitrogen and phosphorus availability, when the connections were severed. Light had a significant effect on the percent of biomass allocation to leaves and number of ramets, but no effect on the length of connection roots. Daughter ramets allocated more resources to leaves, and clones placed more daughter ramets in high light patches than in low light patches. Soil pH had a significant effect on ramet number and connection root length. Clones concentrated in alkaline patches and escaped from acid patches through selective placement of daughter ramets and changing the length of connection roots. We suggest that the clonal integration may be very strong and provide sufficient soil resources to daughter ramets, then affect the daughter ramets’ morphology and placement, if the size of a specific ramet is significantly larger than the other ramets in an arbor clone.     

Clonal segmentation – The development of physiological independence within stolons of Glechoma hederacea L. (Lamiaceae)

The youngest parts of clonal plants benefit from substantial physiological support from older parts, but the extent to which this physiological dependence persists through time is poorly understood. The development of autonomy among connected subunits was therefore analysed in the clonal species Glechoma hederacea. The stolons of a series of clonal fragments with differing numbers of primary ramets were severed at a fixed point relative to the four oldest primary ramets. The subsequent growth of both parts of the severed fragments was compared with that of a series of intact fragments.The growth of apical stolon portions that included five or more rooted primary ramets at the time of severing was unaffected by severing. Apical portions with three or fewer rooted ramets at the time of severing produced fewer new primary ramets than equivalent parts of intact fragments, while apical portions with four or fewer rooted ramets produced less above-ground mass than equivalent apical portions of intact clonal fragments. Basal portions of clonal fragments severed when there were one or two rooted ramets in the apical portion produced more secondary ramet mass than equivalent parts of intact fragments. The gain in mass of secondary ramets in the basal portions of severed fragments matched the reduction in mass of secondary ramets in the apical portions. However, severing caused an overall loss of mass when apical portions had three or fewer rooted ramets at the time of severing, because the mass of primary ramets in basal portions did not increase following severing. Severing had little impact on the allometry of the apical portions. The relationship between mass in secondary ramets and mass in primary ramets was similar in the apical portions of severed and intact clonal fragments. None of the severing treatments increased the total mass of secondary ramets, suggesting that apical dominance in this species only affects branches very close to the apex.These observations, combined with existing knowledge of vascular architecture in G. hederacea, demonstrate that, whether or not physical connections persist between ramets, growing stolons rapidly develop into physiologically autonomous segments. This may be a characteristic of species that exploit disturbed, spatially heterogeneous habitats through rapid multiplication of ramets connected by long, aerial runners or stolons.     

Clonal Integration Enhances the Performance of a Clonal Plant Species under Soil Alkalinity Stress

Clonal plants have been shown to successfully survive in stressful environments, including salinity stress, drought and depleted nutrients through clonal integration between original and subsequent ramets. However, relatively little is known about whether clonal integration can enhance the performance of clonal plants under alkalinity stress. We investigated the effect of clonal integration on the performance of a typical rhizomatous clonal plant, Leymus chinensis, using a factorial experimental design with four levels of alkalinity and two levels of rhizome connection treatments, connected (allowing integration) and severed (preventing integration). Clonal integration was estimated by comparing physiological and biomass features between the rhizome-connected and rhizome-severed treatments. We found that rhizome-connected treatment increased the biomass, height and leaf water potential of subsequent ramets at highly alkalinity treatments but did not affect them at low alkalinity treatments. However, rhizome-connected treatment decreased the root biomass of subsequent ramets and did not influence the photosynthetic rates of subsequent ramets. The biomass of original ramets was reduced by rhizome-connected treatment at the highest alkalinity level. These results suggest that clonal integration can increase the performance of clonal plants under alkalinity stress. Rhizome-connected plants showed dramatically increased survival of buds with negative effects on root weight, indicating that clonal integration influenced the resource allocation pattern of clonal plants. A cost-benefit analysis based on biomass measures showed that original and subsequent ramets significantly benefited from clonal integration in highly alkalinity stress, indicating that clonal integration is an important adaptive strategy by which clonal plants could survive in local alkalinity soil.