Changes in metal-binding peptides due to acclimation to cadmium transferred between ramets of Salvinia minima

Summary Different ramets of a clonal plant exploiting a patchily metal-contaminated habitat may be exposed to different levels of toxic metals. This study investigated whether the exposure of older (parent) ramets to Cd affected the levels of metal-binding peptides and essential elements in younger (daughter) ramets which were not exposed to ambient Cd. Pre-treatment of parent ramets of Salvinia minima with 50 g Cd·l^–1 increased the levels of thiols and phytochelatins (PCs), decreased Mg and increased Cu, Zn and S in daughter ramets growing in a Cd-free medium. Acclimation of parents to lower Cd levels (10 and 25 g Cd·l^–1) increased thiols and decreased cysteine and glutathione in daughters, but did not increase PCs. Parental acclimation to all Cd concentrations tested reduced PC production in daughter ramets during subsequent Cd exposure. Daughter ramets from parents pre-treated with 25 g Cd·l^–1 were more Cd tolerant than controls. Although the tolerant daughters contained 35% more thiols than controls, fractionation of tissue Cd showed no difference between the control and tolerant ramets in the fraction of Cd bound by thiol compounds. Thus, while the acclimation of parent plants to Cd increased levels of metal-binding peptides and thiols in daughter ramets, the relationship between these compounds and the Cd tolerance of daughters is unclear.     

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.

     

Effects of the loss of clonal integration on four sedges that differ in ramet aggregation

Although clonal growth is a dominant mode of plant growth in wetlands, the importance of clonal integration, resource sharing among ramets, to individual ramet generations (mother and daughter) and entire clones of coexisting species has not been well investigated. This study evaluated the significance of clonal integration in four sedge species of varying ramet aggregations, from clump-forming species (Clumpers –Carex sterilis, Eleocharis rostellata), with tightly aggregated ramets (rhizomes<1cm), to runner species (Runners –Schoenoplectus acutus, Cladium mariscoides), with loosely aggregated ramets. We manipulated clonal integration by either severing connections between target mother and daughter ramets or leaving connections intact, and then planted them in an intact neighborhood of a fen in Michigan, USA. We measured growth parameters of original and newly produced ramets over two growing seasons and conducted a final biomass harvest, to address four hypotheses. First, we expected integrated clones to accumulate more biomass than severed clones. However, final clone-level biomass and ramet production were the same for both treatments in all species although severing initially stimulated ramet production by Schoenoplectus and produced a more compact ramet aggregation in Cladium. Second, we hypothesized that mother ramets would experience a cost of integration, through reduced ramet or biomass production, while daughters would experience a benefit, through increased resource availability from mothers. Mother ramets of Cladium suffered a cost from integration, while Schoenoplectus mothers suffered a slight cost and Carex daughters saw a slight benefit. Finally, we hypothesized that integration would be more active in runner species than in clumper species. Indeed, we documented more active integration in runners than clumpers, but none of the study species were dependent upon integration for growth or survival once daughter ramets were established with their own roots and shoots. This study demonstrates that integration between established ramets may not be the most important advantage to clonal growth in this wetland field site. The loss of integration elicited varied responses among coexisting species in their natural habitat, somewhat but not completely related to their growth form, suggesting that a combination of plant life history traits contributes to the dependence upon clonal integration among established ramets of clonal species.     

克隆整合提高淹水胁迫下狗牙根根部的活性氧清除能力

虽然国内外已开展大量关于克隆整合影响植物抗逆生理的研究,但迄今未见克隆整合是否会影响逆境下不同分株清除活性氧过程的报道。以河岸带适生克隆植物狗牙根(Cynodon dactylon)为例,研究克隆植物的抗氧化生理响应,检测了狗牙根在先端淹水/不淹水、先端与基端匍匐茎连接/切断两个因素的交互作用下的根部主要抗氧化酶:超氧化岐化酶(Superoxide dismutase, SOD)、抗坏血酸过氧化物酶(Ascorbate peroxidase, APX)、过氧化氢酶(Catalase, CAT)的活力以及生物量的变化。结果显示,淹水环境中狗牙根先端的生物量和根部SOD酶活力在匍匐茎连接处理下显著高于切断处理组,同一处理的生物量以及根部APX、CAT酶活力总体上表现出不同程度的提高趋势;与受淹先端连接的基端分株根部抗氧化酶活力均低于切断处理组,且SOD和CAT受连接处理影响显著;淹水和切断处理显著降低先端分株的生物量,但对基端和克隆片段影响不明显。这表明淹水胁迫下克隆整合提高了其根部活性氧清除能力,显著改善了先端分株的表现。     

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.     

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.     

Physiological integration increases the survival and growth of the clonal invader <Emphasis Type="Italic">Carpobrotus edulis</Emphasis>

Clonal growth seems to be a common trait for many of the most aggressive invasive plant species. However, little research has been conducted to determine the role of clonality in the successful invasion of new areas by exotic species. Carpobrotus edulis (L.) N.E. Br. is a mat-forming succulent plant, native to South Africa that is invasive in coastal dunes of Australia, New Zealand, USA and Southern Europe. Although Carpobrotus edulis is a clonal plant, there is no information on the role of clonality for the invasion by this species, therefore the objective of this study was to test whether or not physiological integration improves the performance of C. edulis invading coastal sand dunes. To do that, a 6-month field experiment was designed in which the stolon connections between the apical ramets and the C. edulis mats were severed to prevent physiological integration. This treatment was applied to ramets growing under high and low competition with the native species. Apical ramets with intact stolon connections were used as control. Integration improved the survivorship and growth of apical ramets, both in high and low competition. Connected ramets showed a more pronounced increase of clonal growth (estimated as stolon length) during the experimental period and a higher total biomass and number of ramets at the completion of the experiment. In terms of survivorship, the benefit of integration was greater under high competition. Physiological integration can therefore be considered an important factor in the invasiveness of C. edulis, both in open space and in direct competition with the native plants.     

Exploitation of patchy soil water resources by the clonal vine <Emphasis Type="Italic">Ficus tikoua</Emphasis> in karst habitats of southwestern China

The karst habitats of southwestern China are characterized by a highly heterogeneous distribution of water resources. We hypothesized that the clonal integration between connected ramets of the clonal vine Ficus tikoua was an important adaptive strategy to the patchy distribution of water resources in these habitats. We grew ramet pairs (each consisting of a parent and an offspring ramet) in both homogeneously and heterogeneously watered conditions. The offspring ramets were well-watered, whereas their connected parent ramets were randomly assigned to four water treatments: well-watered, mild water stress, moderate water stress, and severe water stress. Increasing water stress decreased leaf water potential, relative water content, net assimilation rate, maximum quantum yield of PSII (F _v/F _m), and biomass of the parent ramets. Subjecting the parents to water stress significantly increased root biomass and root mass ratio (RMR) of their offspring ramets. Exploitation of plentiful water resources through the increased adventitious roots connected to another soil patch permitted the complete restoration of water relations and photosynthetic capacity of offspring ramets after an initial depression. Water relations and gas exchange of the parents were not affected by the water supply to their connected offspring ramets, suggesting that offspring ramets hardly exported water to the stressed parents. However, net assimilation rate and proline content of the offspring ramets increased when they were connected to water-stressed parents. The compensatory photosynthetic responses of offspring ramets connected to stressed parents revealed an increasing trend as the experiment progressed. Morphological and physiological plasticity of F. tikoua in response to heterogeneous water resources allow them to adapt to karst habitats and be suitable candidates for vegetation restoration projects.     

Clonal integration and heavy-metal stress: responses of plants with contrasting evolutionary backgrounds

Physiological integration between ramets can ameliorate the growth and survival of clonal plants in spatially-heterogeneous environments, as ramets from favourable patches can provide support to those found in stressful patches. However, the advantage conferred by clonal integration might also depend on the evolutionary history of plants with regards to the presented stress. Here, we compared the benefit of clonal integration in response to the distribution of a heavy metal as a stress factor, and asked if this benefit would differ between ecotypes that have either undergone selection to tolerate heavy metals or not. In a greenhouse experiment, we grew pairs of connected and severed ramets of the metal hyperaccumulator Arabidopsis halleri, which originated from populations of either metalliferous or non-metalliferous soils. The ramets were grown in paired pots, which were contaminated with cadmium (Cd) either heterogeneously (100 or 0 ppm Cd per pot) or homogenously (50 ppm Cd per each pot). A. halleri ecotypes that originated from non-metalliferous soils performed better when ramets were connected and the distribution of Cd was heterogeneous. However, clonal integration had no effect on the performance of genotypes from metalliferous soils, regardless of the distribution of Cd. These results support the hypothesis that clonal integration is beneficial in stressful environments as long as the stress is patchily distributed, and particularly for plants that did not undergo selection to withstand it.     

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。     

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.     

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。     

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.     

Physiological integration enhanced the tolerance of Cynodon dactylon to flooding

Many flooding‐tolerant species are clonal plants; however, the effects of physiological integration on plant responses to flooding have received limited attention. We hypothesise that flooding can trigger changes in metabolism of carbohydrates and ROS (reactive oxygen species) in clonal plants, and that physiological integration can ameliorate the adverse effects of stress, subsequently restoring the growth of flooded ramets. In the present study, we conducted a factorial experiment combining flooding to apical ramets and stolon severing (preventing physiological integration) between apical and basal ramets of Cynodon dactylon, which is a stoloniferous perennial grass with considerable flooding tolerance. Flooding‐induced responses including decreased root biomass, accumulation of soluble sugar and starch, as well as increased activity of superoxide dismutase (SOD) and ascorbate peroxidase (APX) in apical ramets. Physiological integration relieved growth inhibition, carbohydrate accumulation and induction of antioxidant enzyme activity in stressed ramets, as expected, without any observable cost in unstressed ramets. We speculate that relief of flooding stress in clonal plants may rely on oxidising power and electron acceptors transferred between ramets through physiological integration.     

Evidence for unexpected higher benefits of clonal integration in nutrient-rich conditions

Physiologically integrated clonal plants cope better with spatial heterogeneity due to their ability to share resources among ramets. According to theoretical predictions and experimental evidence, such benefits of resource sharing should increase with higher patch quality of an exporting ramet and lower patch quality of an importing ramet. This study investigated the effect of spatial heterogeneity in nutrient availability on benefits of clonal integration under plausible scenarios of clonal spread, in which more developed ramets give rise to new ones. Pairs of mother and daughter ramets of a stoloniferous grass, Agrostis stolonifera, were grown in various nutrient conditions. Disconnected pairs of ramets were used as controls. Results showed considerable benefits of integration for developmentally younger daughters and no costs for older mothers in all treatments. Surprisingly, benefits of integration were more pronounced in nutrient-rich daughters, and allocation to integrated daughters decreased with increasing nutrient level of mothers. In addition, integration in general increased root-to-shoot ratio of daughters. One possible explanation of the observed patterns may be prevailing translocation of photosynthates rather than nutrients. Daughters also responded to nutrients by changes in clonal architecture. Number of stolons increased, and maximum stolon length decreased in high nutrient levels. Integration increased maximum stolon length in small daughters. The architectural responses are generally in accord with the foraging behaviour concept. Overall, our results suggest that resource translocation within a clonal fragment need not be easily predictable from a gradient of resource availability.     

养分异质条件下结缕草克隆分株生长、碳水化合物及可溶性蛋白的生理整合

通过对连接和断开的结缕草分株进行不同的养分处理,研究了养分异质条件下结缕草克隆分株生长、碳水化合物及可溶性蛋白含量的变化.结果表明: 在养分异质条件下,处于中、高养分水平的母株可以显著提高与其相连子株的地上、地下及总生物量,高养分下分别提高32.5%、22.1%和24.8%,降低根冠比、可溶性糖及非结构性碳水化合物(NSC)含量,高养分下分别降低7.7%、15.2%和13.1%,但是对淀粉、纤维素、可溶性蛋白含量无显著影响.处于中、高养分水平的子株对与其相连的母株生长、碳水化合物及可溶性蛋白含量没有显著影响.养分异质条件下结缕草母株对子株生物量、根冠比、可溶性糖及NSC含量有明显的生理整合,其整合强度与养分梯度呈正比,而对淀粉、纤维素及可溶性蛋白含量没有显现显著的生理整合效应.子株对母株各项指标都没有显著的生理整合,结缕草母株和子株间是一种单向的生理整合.     

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.     

Clonal integration affects allocation in the perennial herb <Emphasis Type="Italic">Alternanthera philoxeroides</Emphasis> in N-limited homogeneous environments

Most work on clonal growth in plants has focused on the advantages of clonality in heterogeneous habitats. We hypothesized (1) that physiological integration of connected ramets within a clone can also increase plant performance in homogeneous environments, (2) that this effect depends on whether ramets differ in ability to take up resources, and (3) that only ramets with relatively low uptake ability benefit. We tested these hypotheses using the perennial amphibious herb Alternanthera philoxeroides. We grew clonal fragments and varied numbers of rooted versus unrooted ramets, connection between the apical and basal parts of fragments, and availability of nitrogen. Patterns of final size and mass of fragments did not support these hypotheses. By some measures, severance did reduce the growth of more apical ramets and increase the growth of less apical ones, consistent with net apical transfer of resources. Rooting of individual ramets strongly influenced their growth: second and third most apical ramets each grew most when they were the most apical rooted ramet, and this pattern was more pronounced under higher nitrogen levels. This adds to the evidence that signalling between ramets is an important aspect of clonal integration. Overall, the results indicate that physiological integration between ramets within clones in homogeneous environments can alter the allocation of resources between connected ramets even when it does not affect the total growth of clonal fragments.     

Carbon Translocation Between Parents and Ramets of a Desert Perennial

Agave deserti, a semelparous, Crassulacean acid metabolism perennialoccurring in the northwestern Sonoran Desert, propagates primarilyvegetatively by ramets produced on rhizomes that extend lessthan 10 cm from the base of a parent plant. Carbon translocationfrom parents to ramets, measured after exposing leaves to ¹⁴CO₂,was essentially complete in 7 d, with parents exporting 3·3%of their assimilated carbon to ramets. Shading ramets belowlight compensation for 6 weeks more than doubled the amountof carbon exported from the parent to shaded ramets, comparedwith unshaded ramets. The total amount of carbon imported bya ramet from its parent was independent of the mass of the ramet.Although the net movement of carbon is expected to be towardsthe ramets, parents also received carbon from labelled ramets,indicating bidirectional translocation. The physiological integrationof parents and ramets allows ramets to draw upon the reservesof the parent for up to 14 years, a longer period than for mostother reported clonal species, thereby facilitating ramet growthand establishment in a resource-limited environment. Agave deserti Engelm., clonal, physiological integration, translocation, ¹⁴CO₂     

High levels of inter-ramet water translocation in two rhizomatous Carex species,as quantified by deuterium labelling

We studied water trnaslocation between interconnected mother and daughter ramets in two rhizomatous Carex species, using a newly developed quantitative method based on deuterium tracing. Under homogeneous conditions, in which both ramets were subjected either to wet or dry soil, little water was exchanged between the ramets. When the ramet pair was exposed to a heterogeneous water supply, water translocation became unidirectional and strongly increased to a level at which 30–60% of the water acquired by the wet ramet was exported towards the dry ramet. The quantity of water translocated was unrelated to the difference in water potential between the ramets, but highly correlated to the difference in leaf area. In both species, the transpiration of the entire plant was similar under heterogeneous and homogeneous wet conditions. This was a direct result of an increase in water uptake by the wet ramet in response to the dry conditions experienced by the interconnected ramet. In C. hirta, the costs and benefits of integration in terms of ramet biomass paralleled the responses of water consumption. This species achieved a similar whole-plant biomass in heterogeneous and homogeneous wet treatments, and water translocation was equally effective in the acropetal and basipetal directions. In C. flacca, responses of biomass and water consumption did not match and, under some conditions, water translocation imposed costs rather than benefits to the plants of this species. It is concluded that enhanced resource acquisition by donor ramets may be of critical importance for the net benefits of physiological integration in clonal plants.