Physiological integration ameliorates effects of serpentine soils in the clonal herb Fragaria vesca

Small-scale heterogeneity in soil characteristics and the facility of clonal systems to spread may lead to situations where parent ramets in favourable microhabitats are connected to offspring in stressful conditions. Clonal plants are physiologically integrated if connections among ramets allow transport of resources. Thus, ramets in favourable habitats may provide support to developing or stressed ramets. We examined effects of integration in Fragaria vesca growing in patches of contrasting quality (potting compost vs serpentine soil). Serpentine soil was used to create unfavourable growing conditions. We assessed whether survival, biomass and photosynthetic efficiency (estimated by fluorescence and reflectance) of parents and offspring were affected by integration and soil quality. Integration increased photochemical efficiencies of parents but more consistently in parents with offspring growing in serpentine soils. We suggest that the assimilate demand from offspring enhanced the photosynthetic efficiency of parents by a mechanism of feedback regulation. This result extends the concept of physiological integration in clonal plants to include photochemical responses. Connected parents also showed significantly higher biomass than disconnected parents. In our system, integration did not entail costs for the whole clone in terms of biomass. Integration also improves the survival, growth and photochemical efficiency of developing ramets, suggesting that integration represents a mechanism for increasing survival in stressful habitats, as the serpentine soils.     

Clonal integration facilitates spread of Paspalum paspaloides from terrestrial to cadmium‐contaminated aquatic habitats

• Cadmium (Cd) is a hazardous environmental pollutant with high toxicity to plants, which has been detected in many wetlands. Clonal integration (resource translocation) between connected ramets of clonal plants can increase their tolerance to stress. We hypothesised that clonal integration facilitates spread of amphibious clonal plants from terrestrial to Cd‐contaminated aquatic habitats.
• The spread of an amphibious grass Paspalum paspaloides was simulated by growing basal older ramets in uncontaminated soil connected (allowing integration) or not connected (preventing integration) to apical younger ramets of the same fragments in Cd‐contaminated water.
• Cd contamination of apical ramets of P. paspaloides markedly decreased growth and photosynthetic capacity of the apical ramets without connection to the basal ramets, but did not decrease these properties with connection. Cd contamination did not affect growth of the basal ramets without connection to the apical ramets, but Cd contamination of 4 and 12 mg·l^?1 significantly increased growth with connection. Consequently, clonal integration increased growth of the apical ramets, basal ramets and whole clones when the apical ramets were grown in Cd‐contaminated water of 4 and 12 mg·l^?1. Cd was detected in the basal ramets with connection to the apical ramets, suggesting Cd could be translocated due to clonal integration. Clonal integration, most likely through translocation of photosynthates, can support P. paspaloides to spread from terrestrial to Cd‐contaminated aquatic habitats.
• Amphibious clonal plants with a high ability for clonal integration are particularly useful for re‐vegetation of degraded aquatic habitats caused by Cd contamination.

     

Differential Effects of Ammonium and Nitrate on Growth Performance of <i>Glechoma longituba</i> under Heterogeneous Cd Stress

Water, minerals, nutrients, etc., can be shared by physiological integration among inter-connected ramets of clonal plants. Nitrogen plays an important role in alleviating cadmium (Cd) stress for clonal plants. But how different forms of nitrogen affect growth performance of clonal plants subjected to heterogeneous Cd stress still remains poorly understood. A pot experiment was conducted to investigate the differential effects of ammonium and nitrate on growth performance of Glechoma longituba under heterogeneous Cd stress. In the experiment, parent ramets of Glechoma longituba clonal fragments were respectively supplied with modified Hoagland solution containing 7.5 mM ammonium, 7.5 mM nitrate or the same volume of nutrient solution without nitrogen. Cd solution with different concentrations (0, 0.1 or 2.0 mM) was applied to offspring ramets of the clonal fragments. Compared with control (N-free), nitrogen addition to parent ramets, especially ammonium, significantly improved antioxidant capacity [glutathione (GSH), proline (Pro), peroxidase (POD,) superoxide dismutase (SOD) and catalase (CAT)], PSII activity [maximum quantum yield of PSII (F_v/F_m) and effective quantum yield of PSII (ΦPSII)], chlorophyll content and biomass accumulation of the offspring ramets suffering from Cd stress. In addition, negative effects of nitrate on growth performance of whole clonal fragments were observed under Cd stress with high concentration (2.0 mM). Transportation or sharing of nitrogen, especially ammonium, can improve growth performance of clonal plants under heterogeneous Cd stress. The experiment provides insight into transmission mechanism of nitrogen among ramets of clonal plants suffering from heterogeneous nutrient supply. Physiological integration might be an important ecological strategy for clonal plants adapting to heterogeneous environment stress conditions.     

Photosynthetic response of <Emphasis Type="Italic">Fragaria orientalis</Emphasis> in different water contrast clonal integration

The capacity to exchange resources and non-resource agents is one of the most outstanding features of clonal plants. Contrast between patches in a heterogeneous environment is the main external driving force behind integration effects. It was hypothesized, on the basis of the source–sink hypothesis, that assimilate demand from drought-stressed ramets will result in enhancement of the photosynthesis of well-watered ramets by a mechanism of feedback regulation, that the negative effect of drought on the photosynthesis of drought-stressed ramets will be ameliorated by physiological integration, and that these effects will be enhanced by increasing contrast. A pot experiment was conducted with clonal fragments consisting of two interconnected ramets of Fragaria orientalis. In the experiment, both the connected and the disconnected clonal fragments were divided into three water contrast groups: (1) homogeneous (no contrast) group; (2) low-contrast group; (3) high-contrast group. The photosynthesis and stress tolerance of drought-stressed ramets did not decrease under the support of well-watered ramets when they were connected, allowing clones to maintain their performance in less favorable environments. But the photosynthesis and stress tolerance of drought-stressed ramets decreased with increasing drought-stress when stolons were disconnected. With a feedback regulation process, the photosynthesis of well-watered ramets connected to drought-stressed ramets was enhanced by the latter, which can compensate, at least partially, for the cost of maintaining the stressed ramets. Drought-stressed ramets gained more benefits in a high-contrast environment than in a lower-contrast environment; this can enhance the survival of drought-stressed ramets in unfavorable habitats, especially stressed patches that would otherwise be unexploitable by independent ramets. But photosynthesis of well-watered ramets did not increase with increasing water availability contrast. It can be concluded that photosynthesis and stress tolerance of F. orientalis was affected by clonal integration and by contrasts of water availability.     

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.     

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。     

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.     

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 modifies δ15N in the clonal plant Fragaria vesca,suggesting preferential transport of nitrogen to water-stressed offspring

Background and Aims

One of the most striking attributes of clonal plants is their capacity for physiological integration, which enables movement of essential resources between connected ramets. This study investigated the capacity of physiological integration to buffer differences in resource availability experienced by ramets of the clonal wild strawberry plant, Fragaria vesca. Specifically, a study was made of the responses of connected and severed offspring ramets growing in environments with different water availability conditions (well watered or water stressed) and nitrogen forms (nitrate or ammonium).

Methods

The experimental design consisted of three factors, ‘integration’ (connected, severed) ‘water status’ (well watered, water stressed) and ‘nitrogen form’ (nitrate, ammonium), applied in a pot experiment. The effects of physiological integration were studied by analysing photochemical efficiency, leaf spectral reflectance, photosynthesis and carbon and nitrogen isotope discrimination, the last of which has been neglected in previous studies.

Key Results

Physiological integration buffered the stress caused by water deprivation. As a consequence, survival was improved in water-stressed offspring ramets that remained connected to their parent plants. The nitrogen isotope composition (δ¹⁵N) values in the connected water-stressed ramets were similar to those in ramets in the ammonium treatment; however, δ¹⁵N values in connected well-watered ramets were similar to those in the nitrate treatment. The results also demonstrated the benefit of integration for offspring ramets in terms of photochemical activity and photosynthesis.

Conclusions

This is the first study in which carbon and nitrogen isotopic discrimination has been used to detect physiological integration in clonal plants. The results for nitrogen isotope composition represent the first evidence of preferential transport of a specific form of nitrogen to compensate for stressful conditions experienced by a member clone. Water consumption was lower in plants supplied with ammonium than in plants supplied with nitrate, and therefore preferential transport of ammonium from parents to water-stressed offspring could potentially optimize the water use of the whole clone.     

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。     

Difference in capacity of physiological integration between two ecotypes of Leymus chinensis underlies their different performance

Background and aims

Physiological integration can enhance the performance of clonal plants, but whether this differs between ecotypes and whether such difference is underlying their distribution have scarcely been addressed. We aimed to determine whether physiological integration differs between ecotypes and whether an ecotype with a wider distribution shows a greater capacity of physiological integration.

Methods

A garden experiment was conducted with ramet pairs of both ecotypes (grey-green and yellow-green ecotype) of a typical rhizomatous clonal plant, Leymus chinensis, using rhizome connection (connected vs. disconnected) and ecotype as factors. Physiological and biomass features were measured and compared to assess the effects of physiological integration for both ecotypes.

Results

Physiological integration enhanced the maximum net photosynthetic rate, apparent quantum efficiency, respiration rate, water use efficiency, and chlorophyll content of ramets no matter whether they were subject to nutrient-poor or -rich soil, as long as they were connected to other ramets. Moreover, such an effect on photosynthetic capacity and water use efficiency was larger for the grey-green ecotype than for the yellow-green ecotype.

Conclusions

The results suggested that grey-green ecotype has significantly greater capacity of physiological integration than yellow-green ecotype, which was assumed to be one of the underlying mechanisms of the wider distribution of the former in nature.     

Clonal integration enhances survival and performance of Potentilla anserina, suffering from partial sand burial on Ordos plateau, China

On Ordos plateau, a semi-arid, desertified area in China, sand burial is a common stress factor for plants. The extent to which sand burial occurs is heterogeneous and unpredictable in space and in time. Therefore, clonal fragments (i.e., interconnected ramets of a clonal plant) often experience partial sand burial, with some ramets buried in sand while the rest may remain unburied. It was hypothesized that clonal fragments are able to benefit from clonal integration, in case they experience partial sand burial. A pot experiment was conducted with Potentilla anserina, a stoloniferous herb often found on Ordos plateau. We used clonal fragments consisting of four interconnected ramets. In the experiment, the two proximal (older) ramets were unburied while the two distal (younger) ramets were either unburied (control) or buried with a 2, 4 or 6 cm deep layer of sand (burial treatments). The stolon connection between the proximal and the distal ramets was either severed or left intact. Stolon severing dramatically decreased the survival of buried ramets. Stolon severing and sand burial had significant effects on plant performance in terms of biomass production, number of leaves and leaf area. A cost–benefit analysis based on performance measures shows that the proximal ramets supported their connected distal ramets and did not incur any cost from this resource export. These results suggest that clonal integration, which is one of the functionally most important consequences of clonal growth, contributes significantly to our test species' capacity to withstand partial sand burial on Ordos plateau, a semi-arid and desertified area of China.     

克隆整合对无芒雀麦在异质性盐分环境中存活和生长的影响

无芒雀麦是浑善达克沙地植物群落中占优势的多年生根茎禾草.研究了克隆整合特性对无芒雀麦在异质性盐分环境中存活和生长的影响.结果表明,克隆整合显著提高了无芒雀麦分株在高盐环境中的存活能力,耗-益分析表明无芒雀麦在高盐斑块中分株的生物量、分株数、根茎节数和根茎总长显著受益于克隆整合,而与之相连的非盐分斑块中的分株却没有产生显著的损耗.因而,克隆整合特性是无芒雀麦对异质性环境形成的重要适应对策,它使无芒雀麦能够扩展到不适合植物生长的高盐分斑块中,从而增加了无芒雀麦在浑善达克沙地中的存活和生长,提高了其在半干旱沙化地区的适合度.     

Clonal integration in Fragaria vesca growing in metal-polluted soils: parents face penalties for establishing their offspring in unsuitable environments

Clonal plants often establish descendent ramets in sites with contrasting presence of favourable and unfavourable factors. Connections between ramets allow translocation of essential resources from established ramets to developing ramets and, as consequence, integration confers net benefits to ramets growing under unfavourable conditions. Therefore, integrated ramets may survive in habitat patches that would be lethal to independent ramets or non-clonal plants. This experiment aimed to investigate the physiological and morphological responses of the clonal plant Fragaria vesca growing in heterogeneous substrate with patches of contrasting quality (i.e. uncontaminated or heavy-metal-contaminated). We observed that parents reduced their photosynthetic efficiencies and growth as consequence of maintaining their offspring. This cost did not affect survival of the parents. Physiological integration brings about benefits to offspring ramets growing both at uncontaminated and heavy-metal-contaminated soils. The benefits of integration were detected in both physiological and morphological traits, enhancing the survivorship of offspring ramets in the Cu-polluted soils. We conclude that integration improves the performance of developing ramets of F. vesca growing in heavy-metal-contaminated habitats, allowing clone systems to overcome the establishment risks and maintain their presence in these less favourable sites.     

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。     

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.     

Effects of resource sharing directionality on physiologically integrated clones of the invasive Carpobrotus edulis

资源共享的方向性对入侵植物海榕菜生理整合的影响 与植物克隆生长相关的一个关键性状是生理整合能力,它允许在一个克隆内相连接的分株之间共享资源。资源传输遵循源-汇关系：从生长在资源丰富斑块上的分株到生长在贫瘠斑块上的分株。然而,一些实验结果表明,向顶运输(从后端到前端)通常超过基部运输(从前端到后端)。在本研究中, 我们旨在确定入侵植物海榕菜(Carpobrotus edulis)生理整合模块的资源运输方向。我们开展了两个模拟实 验,研究了在不同位置(后端、中部、前端)的不同营养水平对海榕菜连接和断开克隆系统的影响。比较了分株生物量分配模式和最终生物量,以阐明生理整合的作用是否受资源运输方向性的影响。研究结果表明,海榕菜资源的向顶运输是普遍存在的,其发育分工是后端分株专注于获取土壤资源,前端分株专注于地上生长。虽然在最严酷的生长条件下的前端分株所获得的效益最高,但这种生物量分配模式不受后端或前端分株生长的营养条件的影响。这种发育程序化的分工被认为可以促进海榕菜的横向生长,从而对这种入侵物种的扩展具有重要意义。     

Physiological Integration among Clonal Ramets during Invasion of Disturbance Patches in a New England Salt Marsh

Resource sharing between ramets growing across environmentalresource gradients may have important consequences for clonalplant populations and community dynamics. As the clonal saltmarsh grasses, Spartina patens and Distichlis spicata, vegetativelycolonize disturbance-generated bare patches, they span steepgradients in soil salinity and available sunlight. Examinationof water relations and carbon translocation in the field andgreenhouse revealed that connected ramets of these marsh grassesshare water and carbon in response to gradients in resourceavailability. Ramets colonizing disturbance patches rely uponphysiological integration with connected parent ramets to overcomewater stress associated with hypersaline patch environments.In addition, upon establishment inside a bare patch, daughterramets may translocate carbon back to shaded parent ramets inthe surrounding vegetation outside of patches. Physiological integration of ramets colonizing disturbance-generatedbare patches and parent ramets outside of patches may explainthe predominance of vegetative invasion over sexual recruitmentin marsh succession. Hypersaline soil conditions, which inhibitseedling recruitment into patches, have little effect on thesuccess of clonal colonizers that can import water from parentramets. This success appears to be due to the ability of clonalmarsh grasses to translocate water and carbon products betweenramets growing across opposing gradients in resource availability.Copyright1995, 1999 Academic Press Clonal integration, Distichlis spicata, halophytes, salt marsh ecology, secondary succession, Spartina patens