-PDF Download- The Next Step Disentangling The Role Of Plant Soil Feedbacks In Plant Performance And Species Coexistence Under Natural Conditions EBOOK

The Next Step: Disentangling the Role of Plant-Soil Feedbacks in Plant Performance and Species Coexistence Under Natural Conditions

Author: Johannes Heinze

Publisher: Frontiers Media SA

Published: 2020-09-17

Total Pages: 163

ISBN-13: 2889660230

This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact.

Plant Species Coexistence

Author: Chelsea Cunard

Publisher:

Published: 2016

Total Pages: 230

ISBN-13:

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Plant soil feedbacks, specifically soil microbial communities, have been proposed to affect plant species' relative abundances and stabilize coexistence within a community. Negative plant soil feedbacks, where plant species condition microbial communities detrimental to conspecifics, may promote coexistence and plant diversity within a community both by lowering overall fitness and creating negative frequency dependence, i.e. stabilizing niche differences. Positive plant soil feedbacks, where plant species condition communities beneficial to conspecifics, may promote the dominance of a species through increased overall fitness and reduced negative frequency dependence. Invasive species can disrupt coexistence and reduce resident species abundance and diversity in its invaded range, potentially due to a more neutral to positive interaction with the soil microbial community resulting from an escape from specialized pests and pathogens in its native range. However, a more antagonistic soil community could accumulate through time to reduce the dominance of the invader and promote coexistence between it and native plant species. We explored whether the propensity to coexist increased due to the presence of soil biota, as well as whether the likelihood of coexistence increased across invasion history for invasive Microstegium vimineum and native plants due to changes in the soil community. In an observational study across M. vimineum's invasive range in the eastern United States, we found a decline in M. vimineum's survival at low frequency and changes in its soil/root fungal community across invasion history. In a 2-year field experiment negative frequency dependence increased for M. vimineum across invasion history in conspecific conditioned soil. Finally, in a greenhouse experiment we found that the soil community promoted coexistence of M. vimineum and native Pilea pumila through increased stabilizing niche differences. These results combined show that the soil community promotes coexistence through stabilizing interactions and that the likelihood of coexistence between invasive M. vimineum and native plants is potentially increasing through invasion time due to an accumulation of an antagonistic soil community.

Quantifying the Effects of Spatial Environmental Variation and Soil Microbes on Plant Community Dynamics

Author: Gaurav Sunil Kandlikar

Publisher:

Published: 2020

Total Pages: 181

ISBN-13:

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Understanding the processes that determine the diversity and dynamics of plant communities is a longstanding challenge in ecology. Many studies have inferred the role of demographic processes by studying patterns of functional trait variation in natural communities, but studies explicitly linking such functional trait differences to demographic processes are lacking. There has also been a growing realization that the dynamics of plant communities are also influenced by the composition of the soil microbial community, but despite hundreds of empirical studies, predicting the influence of soil microbes on the diversity and dynamics of natural plant communities remains a challenge. In my dissertation I couple ecological theory with field and greenhouse experiments to build a more complete and generalizable understanding of the processes that control plant biodiversity. In Chapter One, I ask whether community-wide shifts in three key plant functional traits across an environmental gradient reflect variation in the trait-performance relationship across the landscape. To address this question I coupled observational data of variation in plant composition and functional with experimental data on species performance across the same landscape. I asked whether observed trait-environment interactions in the experimental data match observed patterns of trait variation. I found that shifts in community-weighted mean traits generally reflect the direction of trait-environment interactions. But on the whole, the interactions we found were weak, and by themselves might not be sufficient to explain community-wide shifts. This supports the value of plant functional traits for predicting species responses to environmental variation, and highlights a need for more detailed evaluation of how trait-performance relationships change across environments to improve such predictions. Chapters Two and Three focus on how soil microbes can influence diversity in plant communities. Chapter Two begins with a re-analysis of a classic framework that has been extensively used to study how feedbacks between plants and soil microbes can influence species coexistence. A great deal of existing theoretical and empirical work has shown that soil microbes can promote plant coexistence when they generate stabilizing feedback loops, or can drive exclusion when they generate destabilizing feedback loops. I applied insights from modern coexistence theory to show that existing work has largely neglected another avenue by which plant-soil feedbacks can mediate plant coexistence, by driving average fitness differences between plants. This chapter also extends classic models of plant-soil feedback to include more biological detail to show how the effects of plant-soil feedback on plant coexistence depends critically on how plants interact with each other through other processes like resource competition. In the final chapter of my dissertation, I applied the insights from Chapter Two to ask how plant-soil feedbacks influence diversity in southern California annual grassland communities. I conducted a greenhouse experiment to quantify microbially mediated stabilization and fitness differences among fifteen pairs of annual plants. We found that soil microbes frequently generate negative frequency-dependent dynamics that stabilize plant interactions, but they simultaneously generate large average fitness differences between species. The net result is that if the plant species are otherwise competitively equivalent, soil microbes would often drive exclusion among the focal species. This work illustrates the importance of quantifying microbially mediated fitness differences, and points to important avenues for future studies on how soil microbes shape plant diversity.

Plant-induced soil changes: Processes and feedbacks

Author: Nico van Breemen

Publisher: Springer Science & Business Media

Published: 2013-03-09

Total Pages: 255

ISBN-13: 9401726914

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This book by soil scientists and ecologists reviews how and why plants influence soils. Topics include effects on mineral weathering, soil structure, and soil organic matter and nutrient dynamics, case studies of soil-plant interactions in specific biomes and of secondary chemicals influencing nutrient cycling, the rhizosphere, and potential evolutionary consequences of plant-induced soil changes. This is the first volume that specifically highlights the effects of plants on soils and their feedbacks to plants. By contrast, other texts on soil-plant relationships emphasize effects of soil fertility on plants, following the strongly agronomic character of most research in this area. The aspects discussed in this volume are crucial for understanding terrestrial ecosystems, biogeochemistry and soil genesis. The book is directed to terrestrial ecologists, foresters, soil scientists, environmental scientists and biogeochemists, and to students following specialist courses in these fields.

Negative Mycorrhizal Feedback and Plant Species Coexistence in a Serpentine Grassland

Author: Jeffrey Paul Castelli

Publisher:

Published: 2001

Total Pages: 107

ISBN-13:

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Plant-Soil Negative Feedbacks as Drivers of Spatial Patterns of Abundance in a Successional Landscape

Author: Lucy D. Christiana

Publisher:

Published: 2019

Total Pages: 0

ISBN-13:

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Negative plant-soil feedbacks describe a phenomenon-resulting from interactions between plants and their soil biota, particularly fungal pathogens. These highly dynamic local above- and below-ground interactions may be a way that biodiversity levels are maintained: even if one plant species is a strong competitor, its pathogens suppress its dominance, allowing for the coexistence of multiple plant species. I am interested in how negative feedbacks play a role in determining plant community assembly patterns in a landscape-scale fragmentation field site (Lawrence, Kansas) for which I have over 30 years of historical vegetation data. I built a spatially-explicit cellular automata model of the spatial dynamics of one species, Ambrosia artemisiifolia (common ragweed) over time, across both continuous and fragmented landscapes. Using empirical data from 1985 to set initial conditions, I simulated 32 years of vegetation change and compared the spatial distribution of ragweed in the model to the actual spatial organization of plants from the field site vegetation surveys in 2017. Exploring the spread of ragweed over space and time I asked: as plant communities undergo succession, what spatial patterns of abundance will I observe if negative plant-soil feedbacks are a key driver of plant community composition? Further, how does fragmentation affect these patterns? The model shows that there is a wide range of negative feedback strengths that allow for percent cover levels that resemble the historical data. On the other hand, occupancy, the proportion of samples in which a species is present, requires a much more sensitive range of feedback strengths in order to resemble historical data. In order to yield realistic historical species abundance patterns in the absence of feedbacks, there must be high levels of generalized seed mortality due to other processes. While this model a step towards a more integrated above- and below-ground analysis of spatiotemporal patterns of plant community assembly dynamics, more variables such as abiotic factors, and temporal changes in feedback strength and direction throughout succession must be accounted for, as well as response variables that more accurately represent these patterns.

Interactions in Soil: Promoting Plant Growth

Author: John Dighton

Publisher: Springer

Published: 2014-05-23

Total Pages: 231

ISBN-13: 9789401788915

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This book investigates soil ecology and biodiversity for its ability to maintain a balance of beneficial organisms to support plant growth. This subject is discussed by a group of international authors in natural, agricultural and urban systems. The importance of biodiversity per se and, specifically, the feedbacks between the plant and soil biota in mediating soil function are emphasized. Examples are selected from allelopathy and invasive plant species along with the, hitherto overlooked, role of viruses in soil. The book is intended to provide a framework for a holistic understanding of the essential role of soil organisms in promoting plant growth.

Ecological and Evolutionary Dynamics of Plant-soil Feedbacks

Author: Michael E. Van Nuland

Publisher:

Published: 2017

Total Pages: 111

ISBN-13:

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Plants interact with, modify, and are affected by their soil environments. Though plant-soil interactions are well known to be important and active regulators of ecosystem function and community structure, much less is known about how these interactions affect plant evolution. The primary goal of my dissertation was to examine plant-soil interactions under a range of ecological and evolutionary contexts to better understand patterns of biodiversity, ecosystem function, and whole system responses to environmental change. Taking such an eco-evolutionary perspective allows for a holistic understanding of the causes and consequences of complex abiotic and biotic interactions that link ecosystem ecology and evolution. In my first chapter, I reviewed what is known about genetic interactions between plants, soils, and soil communities, and in doing so, identified a new mechanism for how genetically based plant-soil feedbacks might emerge at large scales. In my second chapter, I used field observations and multiple experimental approaches to test whether soil N acts as a selective gradient on plant phenotypes, if soil microbial communities mediate the selective pressure, and whether plant genetic variation impacts soil N pools. In my third chapter, I developed climate and soil ecological niche models, combined with a new double quantile regression approach, to tests how traits are adapted or plastic at critical environmental limits. Finally, my fourth chapter examined how plant-soil interactions and feedbacks at landscape scales may influence range dynamics and associated ecosystem processes as species move upwards towards higher elevations with rising temperatures. Overall, my dissertation sought to bring an evolutionary perspective to ecosystem ecology research by investigating the genetic mechanisms and outcomes of plant-soil interactions.

Plant-soil Feedbacks in a Grassland Ecosystem

Author: Kobe N. Luu

Publisher:

Published: 2022

Total Pages: 66

ISBN-13:

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Plant-soil feedbacks (PSFs) occur when plants alter soil conditions, subsequently affecting plant success. This process may play a key role in maintaining biodiversity and ecosystem functioning. Many PSF experiments have reported species-specific responses and there is growing interest in determining whether the response of plant functional groups (PFGs), in which species are grouped by similar plant functional traits, can be used to predict the likelihood of PSFs. One reason for the variable responses reported is that PSFs can be dependent on soil fertility, which can serve as a general indicator of succession and ecosystem development. To test how plant functional groups and soil fertility relate to PSF, we grew 19 grassland species from 3 functional groups (graminoids, forbs, legumes) in 3 levels of soil fertility for 4 years. We used this field conditioned soil to conduct greenhouse assays of plant growth rates for species representing each PFG. We found that on average, forbs exhibited positive PSF in the most-developed soil, while the graminoids and legumes exhibited negative PSFs regardless of soil fertility. Despite these trends, we found strong species-specific and soil fertility effects on PSF. These results most likely emerged due to the species-specific soil biota that accumulates over time during the conditioning phase, which includes both harmful and beneficial biota, with the net PSF effect determined by the dominant influence. Generally, we found that PSFs became more positive/less negative as soil fertility increased, most likely due to the increased nutrient concentrations and beneficial soil biota outweighing the effects of the harmful soil biota and lack of soil nutrients. These findings help to understand that different species have unique roles in plant community dynamics, and that their roles within the community are going to change over time, as is total ecosystem productivity.

Plant Evolution, Soil Ecosystems, and Feedback

Author: Connor Fitzpatrick

Publisher:

Published: 2018

Total Pages:

ISBN-13:

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Plants are inextricably linked to their environment. They can alter biotic and abiotic properties of soil ecosystems, which in turn can feed back to affect plant performance. My thesis explores this dynamic link between plants and soil at microevolutionary (within plant species) and macroevolutionary (between plant species) scales. In the microevolutionary half of my thesis I first test whether genetic variation, range-wide geographic trait clines and contemporary evolution in the focal plant species Oenothera biennis (Onagraceae) influence soil ecosystems. I found strong effects of plant genetic variation and evolution, but not geographic origin, on the structure of soil invertebrate communities and ecosystem processes such as soil respiration, litter decay and N mineralization rates. Finally, to understand how soil may be influencing plant evolution, I test whether variation in soil microbial communities can alter plant evolution across two common environmental stressors, competition and drought. I found that soil microbes drastically modify plant fitness, the expression of, and natural selection on flowering time. In the macroevolutionary half of my thesis I use a set of co-occurring plant species to investigate how evolutionary divergence over longer timescales influences plant-soil interactions. First, I conducted a multi-generational experiment to understand the drivers of plant-soil feedback (PSF) across 50 plant species. I found that evolutionary divergence and overall phenotypic similarity were poor predictors of soil feedback, however individual plant traits were strongly related to PSF. Next, I characterized the assembly and ecological function of the root microbiome across 30 plant species. Close plant relative exhibited high similarity in the diversity and composition of their root microbiota. Furthermore, patterns of root microbial recruitment among host plant species were related to PSF and plant drought tolerance. My thesis provides a unique evolutionary perspective on the reciprocal interactions between plants and soil.