Strong growth limitation of a floating plant (Lemna gibba) by the submerged macrophyte (Elodea nuttallii) under laboratory conditions

1. The asymmetric competition for light and nutrients between floating and submerged aquatic plants is thought to be key in explaining why dominance by either of these groups can be stable and difficult to change. 2. Although the shading effect of floating plants on submerged plants has been well documented, the impact of submerged plants on floating plants has been poorly explored hitherto. 3. Here, we used laboratory experiments to examine how submerged plant (Elodea nuttallii) alter nutrient conditions in the water column and how this affects the growth of floating plants (Lemna gibba). 4. We demonstrate that, at higher nutrient concentrations, Lemna is increasingly likely to outcompete Elodea. 5. Under low nutrient concentrations (0.1–2 mg N L^?1) Elodea can strongly reduce the growth of Lemna. Growth of floating plants virtually stopped in some of the experiments with Elodea. 6. Extremely reduced tissue N, Mn, chlorophyll and elongated roots indicated that the growth inhibition of Lemna by Elodea was predominantly caused by the latter’s impact on the nutrient conditions for floating plants. 7. These results strengthen the hypothesis that submerged plants can prevent colonization of a lake by floating plants.     

凤眼莲入侵程度对金鱼藻和黑藻生长及种间关系的影响

湿地生态系统中凤眼莲（Eichhornia crassipes）入侵造成湿地植物群落结构退化及功能崩溃,直接影响沉水植物的生长繁殖及初级生产力。目前关于凤眼莲的入侵机制有一定的研究,而关于凤眼莲入侵程度对沉水植物金鱼藻（Ceratophyllum demersum）和黑藻（Hydrilla verticillate）生长及种间关系的影响相对缺乏。以外来入侵植物凤眼莲,沉水植物金鱼藻和黑藻为研究对象,设计凤眼莲入侵程度（无入侵,轻度入侵对应盖度25%,重度入侵对应盖度75%）交叉定植方式（黑藻单种模式、金鱼藻单种模式,金鱼藻和黑藻混种模式）的控制实验,探究凤眼莲入侵强度对沉水植物金鱼藻和黑藻生长及种间关系的影响。结果表明,凤眼莲入侵程度显著降低了金鱼藻的生物量、分枝数;黑藻的株高、分枝数和分节数。无凤眼莲入侵时,两种沉水植物生物量均最大,两者种间竞争关系较强;随凤眼莲入侵盖度增加,两种沉水植物的生物量先急剧降低后略微增加,种间关系经过微弱促进后又变为竞争作用,其中黑藻表现出明显的竞争优势。此外,凤眼莲入侵略微降低了水体中的总氮、总磷含量。结构方程模型分析结果表明凤眼莲入侵以及水体总氮、总磷等水体理化性质对沉水植物生长均有显著负向影响（P<0.05）,且水体理化性质对沉水植物生长的影响强于凤眼莲入侵。总之,凤眼莲入侵显著降低了金鱼藻和黑藻生长繁殖,随着凤眼莲入侵程度增加,两种沉水植物种间关系由竞争转变为促进再转变为竞争。研究结果为凤眼莲入侵有效控制及湿地沉水植被的恢复与重建提供了一定的理论依据和技术支撑。     

Evaluating the necessity of additional aquatic plant testing by comparing the sensitivities of different species

At present, at least three and up to five plant species are required to assess the potential risks of herbicides to non-target aquatic plants. Several regulatory authorities are considering whether there should be further requirements based on concerns about the possible selectivity of herbicides (e.g., specific modes of action against dicotyledonous plants). The relative sensitivity of a range of aquatic plants is assessed in our work in order to evaluate the implications of differences in species sensitivity for aquatic risk assessment of herbicides. We therefore present results from ecotoxicological tests performed at Syngenta Crop Protection AG on various aquatic plants and compare them to available studies and results in literature. The criterion used for sensitivity ranking is the EC50 (median effect concentration) value, which allows a better comparison of values from different testing methods and conditions. The overall results obtained in the present work show that the aquatic risk assessment procedure for herbicides based on Lemna sp. and algae is sufficiently protective while identifying potential toxicity to non-target plants. Only few exceptions concerning herbicides with selective modes of action (e.g., auxin simulators) may require additional species testing for proper risk assessment.     

Receptor modifiers indicate that 4-aminobutyric acid (GABA) is a potential modulator of ion transport in plants

GABA (4-aminobutyric acid) is a ubiquitousnon-protein amino acid that accumulates rapidly inplants in response to stress. GABA was firstidentified in plants (potato tubers) and animals(brain tissue) 50 years ago. Although GABA is nowrecognized as the most important inhibitoryneurotransmitter in the mammalian central nervoussystem (CNS), the role of GABA in plants remainsunclear. Studies were performed using Lemna toinvestigate the possibility that GABA elicits aresponse in plants that may be related to that of asignaling molecule as described for GABA effects onthe CNS. Lemna growth was increased 2 to 3-foldby 5 mM GABA, but growth was strongly inhibited by 0.5mM of the isomers 3-aminobutyric acid and2-aminobutyric acid. Growth promotion by GABA wasrapidly terminated by addition of 2-aminobutyric acidto the culture medium, but inhibitory effects of2-aminobutyric acid were not reversed by GABAregardless of amounts added. Promotion of Lemnagrowth by GABA was associated with an increase inmineral content of treated plants in a dose dependentmanner. Results support the hypothesis that GABAactivity in plants involves an effect on ion transportand an interaction with a receptor. Evidence for GABAreceptors in Lemna was obtained from experimentswith pharmacological agents that have been used toidentify GABA receptors in animals. GABA mediatedpromotion of Lemna growth was inhibited bybicuculline and picrotoxin, which are respectivelycompetitive and non-competitive antagonists of GABAreceptors in the CNS. Growth inhibition bybicuculline was not relieved by increasing the amountsof GABA in the medium, indicating that the alkaloid isnot acting, as in the CNS, by competitive antagonismof GABA at GABA receptor sites. Baclofen, a GABAagonist that promotes GABA activity in animalssignificantly increased GABA mediated promotion ofLemna growth. These findings and the knownaction of GABA in regulating ion channels in animalssuggests a way that GABA could amplify the stressresponse in plants.     

Changes in carbon and nitrogen content during decomposition of three macrophytes in freshwater and marine environments

Three species of aquatic plants were analyzed for their ash, organic carbon and nitrogen content both fresh and after decomposition using the mesh bag method Chara contraria A. Br. ex Kütz in a small freshwater pond and Lemna minor L. in a shallow swamp were examined over a 70 day period of in situ decomposition. Fucus vesiculosus L. was examined over a 63 day period of decomposition in a rocky shore and a salt marsh environment.During decomposition Chara showed a decrease in carbon and an increase in nitrogen content while Lemna increased in carbon and decreased in nitrogen, all on an ash-free dry weight basis. Although the C : N ratio of Chara was high initially and that of Lemna relatively low, after decomposition the C : N ratio for the remains of the two plants was nearly the same. Fucus decomposing in the salt marsh showed no significant change in carbon but increased in nitrogen content while that at the rocky shore decreased in carbon and increased in nitrogen content. Much of the loss in total dry weight in the first few hours of submergence could be attributed to solubilization of ash and of some high C : N ratio organic material. Consistent and significant differences in the C : N ratio of decomposing Fucus at the two marine sites may be attributable to the nature of the decomposer organisms that inhabit these environments. The accumulation of a high proportion of autotrophic microbial biomass (such as purple sulfur bacteria) in the structural carbohydrates of the salt marsh Fucus may have caused these differences.This study suggests that initial differences in nutritional value of aquatic macrophytes diminish during decomposition and that the ultimate C : N ratio attained may be more dependent on the nature of the decomposer organisms present than on the nature of the organic material undergoing decomposition.     

Growth Cycles in Lemna gibba Cultures and Their Effects on Growth Rate and Ultrastructure

A long-established axenic culture of Lemna gibba G3 was maintained in exponential growth phase under controlled conditions. Weekly analyses for 2 years showed that the individual plants of the Lemna gibba clone fluctuated between two forms. One extreme consisted of plants light in weight, small in size, and with a high relative growth rate (RGR), the other of heavy, large, and more slowly growing plants. At intervals plants having intermediate characteristics dominated in the stock culture. Indication of an annual growth-cycle was also found. The magnitude of growth response (weight, RGR, area, and dry matter content) after treatment with abscisic acid (ABA), 6-benzylaminopurine (BAP), and a combination of the two was different for low-weight and heavy plants. The heavy plants were more sensitive to ABA and BAP treatment than the low-weight ones. The accumulation of starch was least in small untreated plants and greatest in ABA treated plants. Large electron transparent globules were found in the chloroplasts of the ABA treated plants and in heavy plants regardless of how they had been treated. The different physiological and ultrastructural characteristics of the two forms of Lemna plants probably reflect an ageing-rejuvenation cycle. Emphasis is placed on the importance of this cycle when Lemna is used as a model plant in physiological experiments.     

基于无人机SfM数据的挺水植物生物量反演

生物量是衡量挺水植物生长状况的重要参数,对湿地生态系统健康评价具有重要意义。利用无人机影像生成运动重建结构Sf M(Structure from Motion,Sf M)数据,结合野外实测生物量构建定量反演模型,并根据反演模型对生物量进行空间制图,最后分析了挺水植物类型对生物量空间分布的影响。结果表明,文中基于Sf M数据建立的逐步线性回归模型(Stepwise Linear(SWL)regression model)具有较好的反演精度及估测能力。其模型显著性为显著(P0.01),决定系数为0.86,相对均方根误差为6.1%。挺水植物类型对生物量空间分布影响显著(P0.05)。通过对研究区挺水植物的生物量进行估算,为利用无人机遥感监测挺水植物生物量提供了新思路。     

Trade-offs in plant responses to herbivory influence trophic routes of production in a freshwater wetland

Responses of aquatic macrophytes to leaf herbivory may differ from those documented for terrestrial plants, in part, because the potential to maximize growth following herbivory may be limited by the stress of being rooted in flooded, anaerobic sediments. Herbivory on aquatic macrophytes may have ecosystem consequences by altering the allocation of nutrients and production of biomass within individual plants and changing the quality and quantity of aboveground biomass available to consumers or decomposers. To test the effects of leaf herbivory on plant growth and production, herbivory of a dominant macrophyte, Nymphaea odorata, by chrysomelid beetles and crambid moths was controlled during a 2-year field experiment. Plants exposed to herbivory maintained, or tended to increase, biomass and aboveground net primary production relative to controls, which resulted in 1.5 times more aboveground primary production entering the detrital pathway of the wetland. In a complementary greenhouse experiment, the effects of simulated leaf herbivory on total plant responses, including biomass and nutrient allocation, were investigated. Plants in the greenhouse responded to moderate herbivory by maintaining aboveground biomass relative to controls, but this response occurred at the expense of belowground growth. Results of these studies suggest that N. odorata may tolerate moderate levels of herbivory by reallocating biomass and resources aboveground, which in turn influences the quantity, quality and fate of organic matter available to herbivores and decomposers.     

THE IN VITRO SECRETION OF GROWTH REGULATORS BY ISOLATED CALLUS TISSUES

Tissues from a wide variety of plants were surface sterilized, isolated, and grown on different media. These isolated tissues were bioassayed for growth regulatory activity. The secretions from four of the 20 callus tissues inhibited the growth of Bacillus subtilis. An aseptic method for measuring the growth of Lemna was developed and used to detect inhibitory materials in medium which had supported the growth of five isolated callus tissues. In the seed (Lycopersicon esculentum) germination test five callus tissues had an inhibitory influence while two callus tissues showed a stimulatory effect. The study also included expressed juices and extracts of callus tissues which secreted regulatory materials. The expressed juice of five callus tissues contained materials which inhibited the growth of Lemna. Two expressed juices inhibited the growth of Bacillus subtilis. The water extract of two callus tissues inhibited the growth of Lemna. Fifty percent of the plants which have been reported to produce growth regulatory materials in nature also produced callus tissue which was capable of regulating growth of assay organisms.     

Differentiating aquatic plant communities in a eutrophic river using hyperspectral and multispectral remote sensing

1. This study evaluates the efficacy of remote sensing technology to monitor species composition, areal extent and density of aquatic plants (macrophytes and filamentous algae) in impoundments where their presence may violate water‐quality standards. 2. Multispectral satellite (IKONOS) images and more than 500 in situ hyperspectral samples were acquired to map aquatic plant distributions. By analyzing field measurements, we created a library of hyperspectral signatures for a variety of aquatic plant species, associations and densities. We also used three vegetation indices. Normalized Difference Vegetation Index (NDVI), near‐infrared (NIR)‐Green Angle Index (NGAI) and normalized water absorption depth (D_H)_, at wavelengths 554, 680, 820 and 977 nm to differentiate among aquatic plant species composition, areal density and thickness in cases where hyperspectral analysis yielded potentially ambiguous interpretations. 3. We compared the NDVI derived from IKONOS imagery with the in situ, hyperspectral‐derived NDVI. The IKONOS‐based images were also compared to data obtained through routine visual observations. Our results confirmed that aquatic species composition alters spectral signatures and affects the accuracy of remote sensing of aquatic plant density. The results also demonstrated that the NGAI has apparent advantages in estimating density over the NDVI and the D_H. 4. In the feature space of the three indices, 3D scatter plot analysis revealed that hyperspectral data can differentiate several aquatic plant associations. High‐resolution multispectral imagery provided useful information to distinguish among biophysical aquatic plant characteristics. Classification analysis indicated that using satellite imagery to assess Lemna coverage yielded an overall agreement of 79% with visual observations and >90% agreement for the densest aquatic plant coverages. 5. Interpretation of biophysical parameters derived from high‐resolution satellite or airborne imagery should prove to be a valuable approach for assessing the effectiveness of management practices for controlling aquatic plant growth in inland waters, as well as for routine monitoring of aquatic plants in lakes and suitable lentic environments.     

Eutrophication and endangered aquatic plants: an experimental study on <Emphasis Type="Italic">Baldellia</Emphasis> <Emphasis Type="Italic">ranunculoides</Emphasis> (L.) Parl. (Alismataceae)

Anthropogenic enrichment of aquatic ecosystems is an increasingly common phenomenon, resulting from human population growth and the intensification of industrial and agricultural developments. Eutrophication has been considered to be one of the main causes of the decline of many aquatic plants. These observations, however, have rarely been supported by data or explored in detail using an experimental approach. Our experimental study demonstrates, for the first time, a strong direct negative influence of eutrophication on the performance of the endangered aquatic plant Baldellia ranunculoides s.str. (L.) Parl. (Alismataceae). Both morphological and reproductive traits were significantly affected by this phenomenon. Plants growing on eutrophic substrates were much smaller, possessed fewer and smaller leaves, and their biomass was on average half that of plants growing on a mesotrophic substrate. Additionally, plants growing on eutrophic substrates produced fewer inflorescences and flowers, and they had a smaller number of achenes per capitulum. Consequently, they produced only 15% of the seeds produced by plants growing in non-eutrophic conditions. Thus, the chance of long-term subsistence of B. ranunculoides populations in strongly eutrophic habitats will be significantly reduced, and at the same time, the success of any new establishment of viable B. ranunculoides populations in such habitats will be highly restricted. Conservation efforts for B. ranunculoides, either of existing populations or in newly selected re-introduction sites, should start, therefore, with an assessment of the trophic level of those sites. On the other hand, due to its sensitivity to eutrophication, the presence of viable populations of B. ranunculoides can be used as an indicator of valuable aquatic habitats for oligotrophy-dependent organisms.     

Toxicity of rhizomes of the invasive Hedychium coronarium (Zingiberaceae) on aquatic species

The production and release of chemical compounds by invasive plants can affect competitors and native species overall, destabilizing ecological interactions and harming ecosystem functioning. Hedychium coronarium is an invasive macrophyte common on Brazilian riparian areas that produces a wide variety of allelochemicals, but little is known about their effect on aquatic species. Here, we identified the major chemical compounds of the aqueous extract of H. coronarium rhizomes and assessed its toxicity, evaluating the growth inhibition of one alga (Raphidocelis subcapitata) and one macrophyte (Lemna minor), and the lethality of cladoceran (Ceriodaphnia silvestrii and Daphnia similis) and Chironomidae larvae (Chironomus sancticaroli). The majoritarian compounds of H. coronarium rhizomes were Coronarin D and Coronarin D Ethyl Ether. The aqueous extract was toxic for all tested species. We observed growth inhibition in R. subcapitata, as well as reduction in biomass in L. minor. Chironomus sancticaroli and cladoceran were the most sensible species. The aqueous extract of H. coronarium rhizomes was toxic on tested conditions, suggesting that the rhizome compounds may interfere on aquatic organisms and in the dynamic of trophic webs of aquatic ecosystems on invaded areas.

     

Beaver herbivory on aquatic plants

Herbivores have strong impacts on marine and terrestrial plant communities, but their impact is less well studied in benthic freshwater systems. For example, North American beavers (Castor canadensis) eat both woody and non-woody plants and focus almost exclusively on the latter in summer months, yet their impacts on non-woody plants are generally attributed to ecosystem engineering rather than herbivory. Here, we excluded beavers from areas of two beaver wetlands for over 2 years and demonstrated that beaver herbivory reduced aquatic plant biomass by 60%, plant litter by 75%, and dramatically shifted plant species composition. The perennial forb lizard’s tail (Saururus cernuus) comprised less than 5% of plant biomass in areas open to beaver grazing but greater than 50% of plant biomass in beaver exclusions. This shift was likely due to direct herbivory, as beavers preferentially consumed lizard’s tail over other plants in a field feeding assay. Beaver herbivory also reduced the abundance of the invasive aquatic plant Myriophyllum aquaticum by nearly 90%, consistent with recent evidence that native generalist herbivores provide biotic resistance against exotic plant invasions. Beaver herbivory also had indirect effects on plant interactions in this community. The palatable plant lizard’s tail was 3 times more frequent and 10 times more abundant inside woolgrass (Scirpus cyperinus) tussocks than in spatially paired locations lacking tussocks. When the protective foliage of the woolgrass was removed without exclusion cages, beavers consumed nearly half of the lizard’s tail leaves within 2 weeks. In contrast, leaf abundance increased by 73–93% in the treatments retaining woolgrass or protected by a cage. Thus, woolgrass tussocks were as effective as cages at excluding beaver foraging and provided lizard’s tail plants an associational refuge from beaver herbivory. These results suggest that beaver herbivory has strong direct and indirect impacts on populations and communities of herbaceous aquatic plants and extends the consequences of beaver activities beyond ecosystem engineering.     

Growth and nitrate uptake properties of plants grown at different relative rates of nitrogen supply. I. Growth of Pisum and Lemna in relation to nitrogen

Abstract The relations between growth and internal nitrogen concentrations were investigated in nonnodulated Pisum sativum L. cv. Marma and Lemna gibba L. grown at relative rates of nitrate-N additions (R_A) varying from 0.03 to 0.27 d ¹(Pisum) and 0.05 to 0.40 d ¹ (Lemna). At R_A≤0.21 d ¹(Pisum) and ≤0.30 d ¹ (Lemna), the relative growth rate (RGR) correlated well with R_A whereas higher R_A was not met by any further increawse in growth rate. The tissue nitrogen concentrations at growth-limiting R_A increased linearly with RGR. The slope of these lines indicate a maximum nitrogen productivity (amount of biomass formed per unit nitrogen and time) of 14.4 g DW g ¹ Nd ¹ for Pisum and 15.9 g DW g ¹ N d ¹ for Lemna. Extrapolation of the plots to RGR=0 yielded intercepts of 10–15 mg N g^?1 DW for Pisum tissue, whereas for Lemna the intercepts were closer to the origin than for Pisum. These intercepts formally define a fraction of the total plant nitrogen that appears not to be active in production of new biomass, her termed ‘non-growth nitrogen’. The partitioning of nitrogen as well as biomass to the roots increased at low R_A, and is discussed in relation to activity of shoots and roots, respectively.     

The distribution of lead in duckweed (Lemna minor L.) root tip

While considerable information on lead distribution in the cells of terrestrial plants has been collected, little is known about lead localization in the cells of the aquatic plant. Lemna minor L. (duckweed) roots were examined using X-ray microanalysis. After 1-h treatment with lead, its concentration was the highest in small vacuoles. After 6 and 12 h, the lead content of cell walls gradually increased. The changes of lead level between vacuoles and cell walls may result from redistribution of this metal from symplast to cell walls or it may reflect increased apoplastic transport. Lead was not found in the ground cytoplasm of any variants of the experiments. This fact and presence of lead in small vesicles suggests that endocytosis may play the role in lead uptake in Lemna.     

Effects of invasive species on plant communities: an example using submersed aquatic plants at the regional scale

Submersed aquatic plants have a key role in maintaining functioning aquatic ecosystems through their effects on the hydrological regime, sedimentation, nutrient cycling and habitat of associated fauna. Modifications of aquatic plant communities, for example through the introduction of invasive species, can alter these functions. In the Sacramento-San Joaquin River Delta, California, a major invasive submersed plant, Brazilian waterweed Egeria densa, has become widespread and greatly affected the functionality of the submersed aquatic plant community. Rapid assessments of the distribution and abundance of this species are therefore crucial to direct management actions early in the season. Given the E. densa bimodal growth pattern (late spring and fall growth peaks), summer assessments of this species may indicate which and where other submersed species may occur and fall assessments may indicate where this and other species may occur in the following spring, primarily because the Delta’s winter water temperatures are usually insufficient to kill submersed aquatic plant species. We assessed community composition and distribution in the fall of 2007 and summer of 2008 using geostatistical analysis; and measured summer biomass, temperature, pH, salinity, and turbidity. In the fall of 2007, submersed aquatic plants covered a much higher proportion of the waterways (60.7%) than in the summer of 2008 (37.4%), with a significant overlap between the seasonal distribution of native and non-native species. Most patches were monospecific, and multispecies patches had significantly higher dominance by E. densa, co-occurring especially with Ceratophyllum demersum. As species richness of non-natives increased there was a significant decrease in richness of natives, and of native biomass. Sustained E. densa summer biomass negatively affected the likelihood of presence of Myriophyllum spicatum, Potamogeton crispus, and Elodea canadensis but not their biomass within patches. Depth, temperature and salinity were associated with biomass; however, the direction of the effect was species specific. Our results suggest that despite native and invasive non-native submersed plant species sharing available niches in the Delta, E. densa affects aquatic plant community structure and composition by facilitating persistence of some species and reducing the likelihood of establishment of other species. Successful management of this species may therefore facilitate shifts in existing non-native or native plant species.     

Community collocation of four submerged macrophytes on two kinds of sediments in Lake Taihu, China

To explore a method for rapid restoration and artificial regulation of submerged macrophytes in large-scale restoration of eutrophic lakes, the succession and the biodiversity changes of four communities composed of four native, common submerged macrophytes, Hydrilla verticillata, Potamogeton malaianus, Vallisneria spiralis and Najas marina, on two kinds of sediments were investigated. Under low light intensity (reduced by 99%), the plant biomass changed with seasonal changes, plant competition, and environmental stress. The competitive capability for light differed in the four species due to different shoot height and tiller number. After 405 days of transplantation, H. verticillata became dominant in all communities. The biomass of H. verticillata, with strong ability to endure low water light environment, accounted for more than 90% of the total community biomass, and P. malaianus had only weak growth, while V. spiralis and N. marina almost disappeared. Based on livability and biomass of submerged macrophytes on two sediment types, brown clay sediment appeared to be more favorable for the settlement of the plants, while fertile sludge sediment was suitable for vegetative growth. In conclusion, the improvement of habitats and the selection of appropriate plant species are of the greatest importance for ecological restoration of the aquatic ecosystem.     

Spatial distribution and density dependent growth and flowering of Asphodelus aestivus Brot.

Distribution patterns of A. aestivus at four different sites of a degraded mediterranean-type ecosystem (asphodel desert), Thessally, Greece, have been studied. A first order spatial structure was identified at small block sizes and was related to asexual reproduction, a second order structure, at large block sizes, was related to sexual reproduction. Spatial distribution of A. aestivus was associated with soil depth while ecological neighbourhood was discussed in relation to degradation phenomena, especially erosion. Density dependent growth of aboveground biomass and flowering has also been explored. Self-thinning was not detected, whereas the percentage of plants flowering decreases linearly with density and this was attributed to competition for nutrients. A reciprocal equation describes the growth of the aboveground biomass with time. A two-sided competition was displayed by initial plant weight, while the rate of growth of the aboveground biomass was proved independent of density.     

Some analyses of aquatic plants and waters

Summary Results are given of some analyses of aquatic plants, chiefly nitrogen, copper, and chloride contents of Lemna species.

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Résumé Ci-inclus les résultats de quelques analyses de plantes aquatiques sont donnés dont les constituents sont pour la plupart du nitrogène, du cuivre, et du chlore des espèces Lemna.

     

The effect of allometric partitioning on herbivory tolerance in four species in South China

Herbivory tolerance can offset the negative effects of herbivory on plants and plays an important role in both immigration and population establishment. Biomass reallocation is an important potential mechanism of herbivory tolerance. To understand how biomass allocation affects plant herbivory tolerance, it is necessary to distinguish the biomass allocations resulting from environmental gradients or plant growth. There is generally a tight balance between the amounts of biomass invested in different organs, which must be analyzed by means of an allometric model. The allometric exponent is not affected by individual growth and can reflect the changes in biomass allocation patterns of different parts. Therefore, the allometric exponent was chosen to study the relationship between biomass allocation pattern and herbivory tolerance. We selected four species (Wedelia chinensis, Wedelia trilobata, Merremia hederacea, and Mikania micrantha), two of which are invasive species and two of which are accompanying native species, and established three herbivory levels (0%, 25% and 50%) to compare differences in allometry. The biomass allocation in stems was negatively correlated with herbivory tolerance, while that in leaves was positively correlated with herbivory tolerance. Furthermore, the stability of the allometric exponent was related to tolerance, indicating that plants with the ability to maintain their biomass allocation patterns are more tolerant than those without this ability, and the tendency to allocate biomass to leaves rather than to stems or roots helps increase this tolerance. The allometric exponent was used to remove the effects of individual development on allocation pattern, allowing the relationship between biomass allocation and herbivory tolerance to be more accurately explored. This research used an allometric model to fit the nonlinear process of biomass partitioning during the growth and development of plants and provides a new understanding of the relationship between biomass allocation and herbivory tolerance.