scholarly journals Dispersal syndromes affect ecosystem functioning in ciliate microcosms

2021 ◽  
Author(s):  
Allan Raffard ◽  
Julie Campana ◽  
Delphine Legrand ◽  
Nicolas Schtickzelle ◽  
Staffan Jacob
Keyword(s):  
Ecosystem Functioning ◽  
Evolutionary Dynamics ◽  
Phenotypic Variability ◽  
Intraspecific Variability ◽  
Biomass Productivity ◽  
Ecosystem Functions ◽  
Genotypic Effect ◽  
Phenotypic Differences ◽  
Dispersal Syndromes ◽  
Lower Biomass

AbstractDispersal is a key process mediating ecological and evolutionary dynamics. Its effects on metapopulations dynamics, population genetics or species range distribution can depend on phenotypic differences between dispersing and non-dispersing individuals (i.e., dispersal syndromes). However, scaling up to the importance of dispersal syndromes for meta-ecosystems have rarely been considered, despite intraspecific phenotypic variability is now recognised as an important factor mediating ecosystem functioning. In this study, we characterised the intraspecific variability of dispersal syndromes in twenty isolated genotypes of the ciliate Tetrahymena thermophila to test their consequences for biomass productivity in communities composed of five Tetrahymena species. To do so, dispersers and residents of each genotype were introduced, each separately, in ciliate communities composed of four other competing species of the genus Tetrahymena to investigate the effects of dispersal syndromes. We found that introducing dispersers led to a lower biomass compared to introducing residents. This effect was highly consistent across the twenty T. thermophila genotypes despite their marked differences of dispersal syndromes. Finally, we found a strong genotypic effect on biomass production, confirming that intraspecific variability in general affected ecosystem functions in our system. Our study shows that intraspecific variability and the existence of dispersal syndromes can impact the functioning of spatially structured ecosystems in a consistent and therefore predictable way.

scholarly journals Dispersal syndromes can impact ecosystem functioning in spatially structured freshwater populations

2019 ◽  
Vol 15 (3) ◽  
pp. 20180865 ◽  
Author(s):  
Chelsea J. Little ◽  
Emanuel A. Fronhofer ◽  
Florian Altermatt
Keyword(s):  
Leaf Litter ◽  
Ecosystem Functioning ◽  
Native Species ◽  
Evolutionary Dynamics ◽  
Species Turnover ◽  
Freshwater Ecosystems ◽  
Dispersal Syndromes ◽  
Leaf Consumption ◽  
Litter Processing ◽  
Freshwater Habitats

Dispersal can strongly influence ecological and evolutionary dynamics. Besides the direct contribution of dispersal to population dynamics, dispersers often differ in their phenotypic attributes from non-dispersers, which leads to dispersal syndromes. The consequences of such dispersal syndromes have been widely explored at the population and community level; however, to date, ecosystem-level effects remain unclear. Here, we examine whether dispersing and resident individuals of two different aquatic keystone invertebrate species have different contributions to detrital processing, a key function in freshwater ecosystems. Using experimental two-patch systems, we found no difference in leaf consumption rates with dispersal status of the common native species Gammarus fossarum . In Dikerogammarus villosus , however, a Ponto-Caspian species now expanding throughout Europe, dispersers consumed leaf litter at roughly three times the rate of non-dispersers. Furthermore, this put the contribution of dispersing D. villosus to leaf litter processing on par with native G. fossarum, after adjusting for differences in organismal size. Given that leaf litter decomposition is a key function in aquatic ecosystems, and the rapid species turnover in freshwater habitats with range expansions of non-native species, this finding suggests that dispersal syndromes may have important consequences for ecosystem functioning.

scholarly journals Dispersal syndromes can impact ecosystem functioning in spatially structured freshwater populations

2018 ◽  
Author(s):  
Chelsea J. Little ◽  
Emanuel A. Fronhofer ◽  
Florian Altermatt
Keyword(s):  
Leaf Litter ◽  
Ecosystem Functioning ◽  
Native Species ◽  
Evolutionary Dynamics ◽  
Species Turnover ◽  
Freshwater Ecosystems ◽  
Dispersal Syndromes ◽  
Leaf Consumption ◽  
Litter Processing ◽  
Freshwater Habitats

Dispersal can strongly influence ecological and evolutionary dynamics. Besides the direct contribution of dispersal to population dynamics, dispersers often differ in their phenotypic attributes from non-dispersers, which leads to dispersal syndromes. The consequences of such dispersal syndromes have been widely explored at the population and community level, however, to date, ecosystem-level effects remain unclear. Here, we examine whether dispersing and resident individuals of two different aquatic keystone invertebrate species have different contributions to detrital processing, a key function in freshwater ecosystems. Using experimental two-patch systems, we found no difference in leaf consumption rates with dispersal status of the common native species Gammarus fossarum. In Dikerogammarus villosus, however, a Ponto-Caspian species now expanding throughout Europe, dispersers consumed leaf litter at roughly three times the rate of non-dispersers. Furthermore, this put the contribution of dispersing D. villosus to leaf litter processing on par with native G. fossarum, after adjusting for differences in organismal size. Given that leaf litter decomposition is a key function in aquatic ecosystems, and the rapid species turnover in freshwater habitats with range expansions of non-native species, this finding suggests that dispersal syndromes may have important consequences for ecosystem functioning.

The future of research with carnivorous plants

2018 ◽  
Author(s):  
Aaron M. Ellison ◽  
Lubomír Adamec
Keyword(s):  
Natural Selection ◽  
Population Biology ◽  
Field Experiments ◽  
Evolutionary Dynamics ◽  
Species Concept ◽  
Intraspecific Variability ◽  
Carnivorous Plants ◽  
Assisted Migration ◽  
Transcriptomic Data ◽  
Phylogenetic Framework

The material presented in the chapters of Carnivorous Plants: Physiology, Ecology, and Evolution together provide a suite of common themes that could provide a framework for increasing progress in understanding carnivorous plants. All speciose genera would benefit from more robust, intra-generic classifications in a phylogenetic framework that uses a unified species concept. As more genomic, proteomic, and transcriptomic data accrue, new insights will emerge regarding trap biochemistry and regulation; interactions with commensals; and the importance of intraspecific variability on which natural selection works. Continued elaboration of field experiments will provide new insights into basic physiology; population biology; plant-animal and plant-microbe relationships; and evolutionary dynamics, all of which will aid conservation efforts and contribute to discussions of assisted migration as the climate continues to change.

scholarly journals Plant traits are poor predictors of long-term ecosystem functioning

2019 ◽  
Author(s):  
Fons van der Plas ◽  
Thomas Schröder-Georgi ◽  
Alexandra Weigelt ◽  
Kathryn Barry ◽  
Sebastian Meyer ◽  
...  
Keyword(s):  
Plant Species ◽  
Ecosystem Functioning ◽  
Plant Traits ◽  
Vascular Plant ◽  
Plant Performance ◽  
Ecosystem Functions ◽  
Average Percentage ◽  
Functional Consequences ◽  
Small Set

ABSTRACTEarth is home to over 350,000 vascular plant species1 that differ in their traits in innumerable ways. Yet, a handful of functional traits can help explaining major differences among species in photosynthetic rate, growth rate, reproductive output and other aspects of plant performance2–6. A key challenge, coined “the Holy Grail” in ecology, is to upscale this understanding in order to predict how natural or anthropogenically driven changes in the identity and diversity of co-occurring plant species drive the functioning of ecosystems7, 8. Here, we analyze the extent to which 42 different ecosystem functions can be predicted by 41 plant traits in 78 experimentally manipulated grassland plots over 10 years. Despite the unprecedented number of traits analyzed, the average percentage of variation in ecosystem functioning that they jointly explained was only moderate (32.6%) within individual years, and even much lower (12.7%) across years. Most other studies linking ecosystem functioning to plant traits analyzed no more than six traits, and when including either only six random or the six most frequently studied traits in our analysis, the average percentage of explained variation in across-year ecosystem functioning dropped to 4.8%. Furthermore, different ecosystem functions were driven by different traits, with on average only 12.2% overlap in significant predictors. Thus, we did not find evidence for the existence of a small set of key traits able to explain variation in multiple ecosystem functions across years. Our results therefore suggest that there are strong limits in the extent to which we can predict the long-term functional consequences of the ongoing, rapid changes in the composition and diversity of plant communities that humanity is currently facing.

scholarly journals Phenotypic plasticity can reverse the relative extent of intra- and interspecific variability across a thermal gradient

2021 ◽  
Vol 288 (1953) ◽  
pp. 20210428
Author(s):  
Staffan Jacob ◽  
Delphine Legrand
Keyword(s):  
Phenotypic Plasticity ◽  
Thermal Gradient ◽  
Environmental Gradients ◽  
Intraspecific Variability ◽  
Functional Trait ◽  
Ecosystem Functions ◽  
Interspecific Variability ◽  
Ciliate Species ◽  
Relative Extent ◽  
Trait Variability

Intra- and interspecific variability can both ensure ecosystem functions. Generalizing the effects of individual and species assemblages requires understanding how much within and between species trait variation is genetically based or results from phenotypic plasticity. Phenotypic plasticity can indeed lead to rapid and important changes of trait distributions, and in turn community functionality, depending on environmental conditions, which raises a crucial question: could phenotypic plasticity modify the relative importance of intra- and interspecific variability along environmental gradients? We quantified the fundamental niche of five genotypes in monocultures for each of five ciliate species along a wide thermal gradient in standardized conditions to assess the importance of phenotypic plasticity for the level of intraspecific variability compared to differences between species. We showed that phenotypic plasticity strongly influences trait variability and reverses the relative extent of intra- and interspecific variability along the thermal gradient. Our results show that phenotypic plasticity may lead to either increase or decrease of functional trait variability along environmental gradients, making intra- and interspecific variability highly dynamic components of ecological systems.

scholarly journals Morphological variability of Quercus robur L. leaf in Serbia

Genetika ◽  
2017 ◽  
Vol 49 (2) ◽  
pp. 529-541
Author(s):  
Branislava Batos ◽  
Danijela Miljkovic ◽  
Marko Perovic ◽  
Sasa Orlovic
Keyword(s):  
Leaf Area ◽  
Analysis Of Variance ◽  
Population Differentiation ◽  
Quercus Robur ◽  
Phenotypic Variability ◽  
Morphological Variability ◽  
Intraspecific Variability ◽  
Morphological Characters ◽  
Interpopulation Variability ◽  
Intrapopulation Variability

This paper presents the results of a study dealing with leaf morphological variability of Quercus robur L. 148 trees were sampled from 5 population across Serbia and 17 morphological traits were assessed. Interpopulation variability was confirmed by the results of the analysis of variance (ANOVA). A statistically significant (p <0.05) effect of population was obtained for most of the studied morphological characters. Intrapopulation variability was confirmed by statistically significant tree effects for all of the studied leaf characters (all p < 0.05). The results of the multivariate analysis of variance (MANOVA) confirmed a significant population and tree share in the total phenotypic variability (all p <0.05). By applying the canonical discriminant analysis (CDA), the first discriminant function accounted for 63% of the variability between populations and the second accounted for 20% of the population variability. The leaf area (AREA), specific leaf area (SLA) and surface area to perimeter ratio (ARPE) had the greatest effect on population differentiation (CDA). It is assumed that different environmental conditions affect population differentiation and that high intrapopulation variability is due to intraspecific variability.

Predicting evolution in diverse communities

2019 ◽  
pp. 167-188
Author(s):  
Timothy G. Barraclough
Keyword(s):  
Microbial Community ◽  
Ecosystem Functioning ◽  
Evolutionary Dynamics ◽  
Control Measures ◽  
Living Systems ◽  
Human Populations ◽  
Focal Species ◽  
Diverse Communities ◽  
Challenges And Opportunities ◽  
Disease Agent

Following the outline of basic theory and evidence in chapters 7 and 8, this chapter sets the challenge of attempting to predict evolutionary dynamics in realistically diverse communities. Many challenges and opportunities facing human populations rely on being able to predict living systems. Even when a single focal species such as a pest or disease agent is of particular concern, its dynamics and responses to control measures always depend on interactions with a diverse set of other species. Even when the focus is on whole-ecosystem functioning, that depends on trait responses of constituent species. The chapter outlines several case studies where a multispecies evolutionary approach is required, including managing marine fisheries, controlling crop pests, and managing human microbiomes for improved health. To illustrate possible ways forwards, a model of evolution in a microbial community is presented, and possible methods for tracking evolution in diverse communities are discussed.

scholarly journals Diversity of parental environments increases phenotypic variation in Arabidopsis populations more than genetic diversity but similarly affects productivity

2020 ◽  
Author(s):  
Javier Puy ◽  
Carlos P Carmona ◽  
Hana Dvořáková ◽  
Vít Latzel ◽  
Francesco de Bello
Keyword(s):  
Genetic Diversity ◽  
Environmental Conditions ◽  
Phenotypic Variation ◽  
Ecosystem Functioning ◽  
Phenotypic Variability ◽  
Population Type ◽  
Diversity Effect ◽  
Environmental Fluctuations ◽  
Intraspecific Trait Variability ◽  
Trait Variability

Abstract Background and Aims The observed positive diversity effect on ecosystem functioning has rarely been assessed in terms of intraspecific trait variability within populations. Intraspecific phenotypic variability could stem both from underlying genetic diversity and from plasticity in response to environmental cues. The latter might derive from modifications to a plant’s epigenome and potentially last multiple generations in response to previous environmental conditions. We experimentally disentangled the role of genetic diversity and diversity of parental environments on population productivity, resistance against environmental fluctuations and intraspecific phenotypic variation. Methods A glasshouse experiment was conducted in which different types of Arabidopsis thaliana populations were established: one population type with differing levels of genetic diversity and another type, genetically identical, but with varying diversity levels of the parental environments (parents grown in the same or different environments). The latter population type was further combined, or not, with experimental demethylation to reduce the potential epigenetic diversity produced by the diversity of parental environments. Furthermore, all populations were each grown under different environmental conditions (control, fertilization and waterlogging). Mortality, productivity and trait variability were measured in each population. Key Results Parental environments triggered phenotypic modifications in the offspring, which translated into more functionally diverse populations when offspring from parents grown under different conditions were brought together in mixtures. In general, neither the increase in genetic diversity nor the increase in diversity of parental environments had a remarkable effect on productivity or resistance to environmental fluctuations. However, when the epigenetic variation was reduced via demethylation, mixtures were less productive than monocultures (i.e. negative net diversity effect), caused by the reduction of phenotypic differences between different parental origins. Conclusions A diversity of environmental parental origins within a population could ameliorate the negative effect of competition between coexisting individuals by increasing intraspecific phenotypic variation. A diversity of parental environments could thus have comparable effects to genetic diversity. Disentangling the effect of genetic diversity and that of parental environments appears to be an important step in understanding the effect of intraspecific trait variability on coexistence and ecosystem functioning.

scholarly journals Impairment of microbial and meiofaunal ecosystem functions linked to algal forest loss

2020 ◽  
Vol 10 (1) ◽  
Author(s):  
Silvia Bianchelli ◽  
Roberto Danovaro
Keyword(s):  
Habitat Loss ◽  
Ecosystem Functioning ◽  
Negative Impact ◽  
Ecosystem Functions ◽  
Marine Biodiversity ◽  
Forest Loss ◽  
Higher Taxa ◽  
Vulnerable Habitats ◽  
Nematode Biodiversity ◽  
Barren Grounds

AbstractHabitat loss is jeopardizing marine biodiversity. In the Mediterranean Sea, the algal forests of Cystoseira spp. form one of the most complex, productive and vulnerable shallow-water habitats. These forests are rapidly regressing with negative impact on the associated biodiversity, and potential consequences in terms of ecosystem functioning. Here, by comparing healthy Cystoseira forests and barren grounds (i.e., habitats where the macroalgal forests disappeared), we assessed the effects of habitat loss on meiofaunal and nematode biodiversity, and on some ecosystem functions (here measured in terms of prokaryotic and meiofaunal biomass). Overall, our results suggest that the loss of Cystoseira forests and the consequent barren formation is associated with the loss of meiofaunal higher taxa and a decrease of nematode biodiversity, leading to the collapse of the microbial and meiofaunal variables of ecosystem functions. We conclude that, given the very limited resilience of these ecosystems, active restoration of these vulnerable habitats is needed, in order to recover their biodiversity, ecosystem functions and associated services.

scholarly journals Linking community size structure and ecosystem functioning using metabolic theory

2012 ◽  
Vol 367 (1605) ◽  
pp. 2998-3007 ◽  
Author(s):  
Gabriel Yvon-Durocher ◽  
Andrew P. Allen
Keyword(s):  
Ecosystem Functioning ◽  
Size Structure ◽  
Ecosystem Respiration ◽  
Gross Primary Production ◽  
Research Question ◽  
Biogeochemical Cycles ◽  
Ecosystem Functions ◽  
Central Research ◽  
Metabolic Theory ◽  
Community Size

Understanding how biogeochemical cycles relate to the structure of ecological communities is a central research question in ecology. Here we approach this problem by focusing on body size, which is an easily measured species trait that has a pervasive influence on multiple aspects of community structure and ecosystem functioning. We test the predictions of a model derived from metabolic theory using data on ecosystem metabolism and community size structure. These data were collected as part of an aquatic mesocosm experiment that was designed to simulate future environmental warming. Our analyses demonstrate significant linkages between community size structure and ecosystem functioning, and the effects of warming on these links. Specifically, we show that carbon fluxes were significantly influenced by seasonal variation in temperature, and yielded activation energies remarkably similar to those predicted based on the temperature dependencies of individual-level photosynthesis and respiration. We also show that community size structure significantly influenced fluxes of ecosystem respiration and gross primary production, particularly at the annual time-scale. Assessing size structure and the factors that control it, both empirically and theoretically, therefore promises to aid in understanding links between individual organisms and biogeochemical cycles, and in predicting the responses of key ecosystem functions to future environmental change.

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