Your search keyword '"dispersal network"' showing total 11 results

1. Evolution reverses the effect of network structure on metapopulation persistence.

Author

McManus, Lisa, Tekwa, Edward, Schindler, Daniel, Walsworth, Timothy, Colton, Madhavi, Webster, Michael, Essington, Timothy, Forrest, Daniel, Palumbi, Stephen, Mumby, Peter, and Pinsky, Malin

Subjects

adaptation, climate change, dispersal network, eco-evolutionary dynamics, environmental heterogeneity, metapopulations, population persistence, random network, regular network, Biological Evolution, Ecosystem, Models, Biological, Phenotype, Population Dynamics

Abstract

Global environmental change is challenging species with novel conditions, such that demographic and evolutionary trajectories of populations are often shaped by the exchange of organisms and alleles across landscapes. Current ecological theory predicts that random networks with dispersal shortcuts connecting distant sites can promote persistence when there is no capacity for evolution. Here, we show with an eco-evolutionary model that dispersal shortcuts across environmental gradients instead hinder persistence for populations that can evolve because long-distance migrants bring extreme trait values that are often maladaptive, short-circuiting the adaptive response of populations to directional change. Our results demonstrate that incorporating evolution and environmental heterogeneity fundamentally alters theoretical predictions regarding persistence in ecological networks.

Published

2021

2. Chimera and cluster collective states in a dispersal ecological network under state-dependent feedback control and complex habitat structure

Author

Yi Yang, Lirong Liu, Changcheng Xiang, and Wenjie Qin

Subjects

chimera state, cluster solution, dispersal network, state-dependent feedback control, integrated pest management, Environmental sciences, GE1-350, Biology (General), QH301-705.5

Abstract

Pest control based on an economic threshold (ET) can effectively prevent excessive pest control measures such as pesticide abuse and overharvesting. The instinctive dispersal of pest populations in biological network patches for better survival poses challenges for pest management. As long as the pest density is controlled below the economic threshold and no pest outbreak occurs, the aim of pest management can be achieved and it is not necessary to completely remove the pests. This study focuses on the issues of chimera states and cluster solutions in regular bidirectional biological networks with state-dependent impulsive pest management. We consider the influence of two different control modes on the system states, namely global control and local control. Local control is found to be more likely to induce the chimera state. In addition, in the local coupling mode, a higher coupling strength is more likely to generate a coherent state, whereas a lower coupling strength is more likely to generate chimera and incoherent states. Furthermore, the cluster size is inversely related to the coupling strength under local coupling and global control.

Published

2021

3. Chimera and cluster collective states in a dispersal ecological network under state-dependent feedback control and complex habitat structure.

Author

Yang, Yi, Liu, Lirong, Xiang, Changcheng, and Qin, Wenjie

Subjects

*PEST control, *COHERENT states, *PESTS, *PESTICIDES, *BIOLOGICAL networks

Abstract

Pest control based on an economic threshold (ET) can effectively prevent excessive pest control measures such as pesticide abuse and overharvesting. The instinctive dispersal of pest populations in biological network patches for better survival poses challenges for pest management. As long as the pest density is controlled below the economic threshold and no pest outbreak occurs, the aim of pest management can be achieved and it is not necessary to completely remove the pests. This study focuses on the issues of chimera states and cluster solutions in regular bidirectional biological networks with state-dependent impulsive pest management. We consider the influence of two different control modes on the system states, namely global control and local control. Local control is found to be more likely to induce the chimera state. In addition, in the local coupling mode, a higher coupling strength is more likely to generate a coherent state, whereas a lower coupling strength is more likely to generate chimera and incoherent states. Furthermore, the cluster size is inversely related to the coupling strength under local coupling and global control. [ABSTRACT FROM AUTHOR]

Published

2021

4. Differences among avian frugivores in seed dispersal to degraded habitats.

Author

Rehm, Evan M., Chojnacki, Janelle, Rogers, Haldre S., and Savidge, Julie A.

Subjects

*FRUGIVORES, *SEED dispersal by birds, *FOREST regeneration, *TROPICAL forests, *DEFORESTATION

Abstract

Vertebrate frugivores enhance tropical forest regeneration by dispersing seeds into degraded areas. However, the importance of individual species as dispersers may vary within a community. Management and restoration would benefit from understanding which species are critical in moving native seeds into degraded habitats. We compared habitat composition of bird start and end locations for movement intervals based on mean gut passage times for the avian frugivore community on the island of Saipan. The proportion of movement intervals that began in intact, native forest varied among species, with Golden White‐eyes having the highest proportion. However, this species tended to remain in intact forest and only rarely crossed into degraded habitats. Bridled White‐eyes and Mariana Fruit Doves exhibited slightly higher rates of crossing from intact forest to degraded habitats, suggesting an ability to disperse native seeds to degraded areas. White‐throated Ground Doves were never recorded crossing from intact forest to degraded habitats. Despite having a low proportion of movement intervals beginning in intact forest, Micronesian Starlings showed a higher proportion and absolute number of movements from intact forest to degraded habitats, due to their propensity to move frequently, across long distances, and across habitat types. In this species‐poor frugivore network, seed dispersal into degraded habitats appears highly dependent on one species within the community. Regeneration of degraded lands may be severely hindered if this key disperser is lost. [ABSTRACT FROM AUTHOR]

Published

2018

5. Chimera and cluster collective states in a dispersal ecological network under state-dependent feedback control and complex habitat structure

Author

Changcheng Xiang, Wenjie Qin, Yi Yang, and Li Rong Liu

Subjects

Integrated pest management, QH301-705.5, Computer science, Models, Biological, Feedback, cluster solution, GE1-350, Biology (General), Pest Control, Biological, Ecosystem, Ecology, Evolution, Behavior and Systematics, integrated pest management, Ecology, business.industry, Economic threshold, fungi, Environmental resource management, state-dependent feedback control, Pest control, food and beverages, dispersal network, Ecological network, Environmental sciences, Coupling (computer programming), Biological dispersal, PEST analysis, chimera state, business, Biological network

Abstract

Pest control based on an economic threshold (ET) can effectively prevent excessive pest control measures such as pesticide abuse and overharvesting. The instinctive dispersal of pest populations in biological network patches for better survival poses challenges for pest management. As long as the pest density is controlled below the economic threshold and no pest outbreak occurs, the aim of pest management can be achieved and it is not necessary to completely remove the pests. This study focuses on the issues of chimera states and cluster solutions in regular bidirectional biological networks with state-dependent impulsive pest management. We consider the influence of two different control modes on the system states, namely global control and local control. Local control is found to be more likely to induce the chimera state. In addition, in the local coupling mode, a higher coupling strength is more likely to generate a coherent state, whereas a lower coupling strength is more likely to generate chimera and incoherent states. Furthermore, the cluster size is inversely related to the coupling strength under local coupling and global control.

Published

2021

6. Evolution reverses the effect of network structure on metapopulation persistence

Author

Lisa C. McManus, Edward W. Tekwa, Daniel E. Schindler, Daniel L. Forrest, Michael M. Webster, Malin L. Pinsky, Peter J. Mumby, Madhavi A. Colton, Stephen R. Palumbi, Timothy E. Walsworth, and Timothy E. Essington

Subjects

0106 biological sciences, Persistence (psychology), eco‐evolutionary dynamics, Environmental change, Population Dynamics, Metapopulation, adaptation, Biology, Ecological systems theory, Models, Biological, 010603 evolutionary biology, 01 natural sciences, Article, regular network, Ecosystem, Ecology, Evolution, Behavior and Systematics, Ecology, 010604 marine biology & hydrobiology, Articles, environmental heterogeneity, Biological Evolution, dispersal network, Ecological network, Phenotype, climate change, random network, Trait, Biological dispersal, Erratum, Adaptation, population persistence, metapopulations

Abstract

Global environmental change is challenging species with novel conditions, such that demographic and evolutionary trajectories of populations are often shaped by the exchange of organisms and alleles across landscapes. Current ecological theory predicts that random networks with dispersal shortcuts connecting distant sites can promote persistence when there is no capacity for evolution. Here, we show with an eco‐evolutionary model that dispersal shortcuts across environmental gradients instead hinder persistence for populations that can evolve because long‐distance migrants bring extreme trait values that are often maladaptive, short‐circuiting the adaptive response of populations to directional change. Our results demonstrate that incorporating evolution and environmental heterogeneity fundamentally alters theoretical predictions regarding persistence in ecological networks.

Published

2021

7. Using directed phylogenetic networks to retrace species dispersal history

Author

Layeghifard, Mehdi, Peres-Neto, Pedro R., and Makarenkov, Vladimir

Subjects

*GENETIC transformation, *PHYLOGENY, *DISPERSAL (Ecology), *BIOGEOGRAPHY, *ROBUST control, *CASE studies

Abstract

Abstract: Methods designed for inferring phylogenetic trees have been widely applied to reconstruct biogeographic history. Because traditional phylogenetic methods used in biogeographic reconstruction are based on trees rather than networks, they follow the strict assumption in which dispersal among geographical units have occurred on the basis of single dispersal routes across regions and are, therefore, incapable of modelling multiple alternative dispersal scenarios. The goal of this study is to describe a new method that allows for retracing species dispersal by means of directed phylogenetic networks obtained using a horizontal gene transfer (HGT) detection method as well as to draw parallels between the processes of HGT and biogeographic reconstruction. In our case study, we reconstructed the biogeographic history of the postglacial dispersal of freshwater fishes in the Ontario province of Canada. This case study demonstrated the utility and robustness of the new method, indicating that the most important events were south-to-north dispersal patterns, as one would expect, with secondary faunal interchange among regions. Finally, we showed how our method can be used to explore additional questions regarding the commonalities in dispersal history patterns and phylogenetic similarities among species. [Copyright &y& Elsevier]

Published

2012

8. On the impact of dispersal asymmetry on metapopulation persistence

Author

Kleinhans, David and Jonsson, Per R.

Subjects

*METAPOPULATION (Ecology), *SYMMETRY (Biology), *BIOGEOGRAPHY, *OCEAN currents, *LARVAE

Abstract

Abstract: Metapopulation theory for a long time has assumed dispersal to be symmetric, i.e. patches are connected through migrants dispersing bi-directionally without a preferred direction. However, for natural populations symmetry is often broken, e.g. for species in the marine environment dispersing through the transport of pelagic larvae with ocean currents. The few recent studies of asymmetric dispersal concluded that asymmetry has a distinct negative impact on the persistence of metapopulations. Detailed analysis, however, revealed that these previous studies might have been unable to properly disentangle the effect of symmetry from other potentially confounding properties of dispersal patterns. We resolve this issue by systematically investigating the symmetry of dispersal patterns and its impact on metapopulation persistence. Our main analysis based on a metapopulation model equivalent to previous studies but now applied on regular dispersal patterns aims to isolate the effect of dispersal symmetry on metapopulation persistence. Our results suggest that asymmetry in itself does not imply negative effects on metapopulation persistence. For this reason we recommend to investigate it in connection with other properties of dispersal instead of in isolation. [Copyright &y& Elsevier]

Published

2011

9. Effects of predation and dispersal on bacterial abundance and contaminant biodegradation

Author

Otto, Sally, Harms, Hauke, Wick, Lukas, Otto, Sally, Harms, Hauke, and Wick, Lukas

Abstract

Research into the biodegradation of soil contaminants has rarely addressed the consequences of predator–prey interactions. Here, we investigated the joint effect of predation and dispersal networks on contaminant degradation by linking spatial abundances of degrader (Pseudomonas fluorescens LP6a) and predator (Bdellovibrio bacteriovorus) bacteria to the degradation of the major soil contaminant phenanthrene (PHE). We used a laboratory microcosm with a PHE passive dosing system and a glass fiber network to facilitate bacterial dispersal. Different predator-to-prey ratios and spatial arrangements of prey and predator inoculation were used to study predation pressure effects on PHE degradation. We observed that predation resulted in (i) enhanced PHE-degradation at low predator counts (PC) compared to controls lacking predation, (ii) reduced PHE-degradation at elevated PC relative to low PC, and (iii) significant effects of the spatial arrangement of prey and predator inoculation on PHE degradation. Our data suggest that predation facilitated by dispersal networks (such as fungal mycelia) may support the build-up of an effective bacterial biomass and, hence, contaminant biodegradation in heterogeneous systems such as soil.

Published

2016

10. Effects of predation and dispersal on bacterial abundance and contaminant biodegradation.

Author

Otto S, Harms H, and Wick LY

Subjects

Bdellovibrio growth & development, Bdellovibrio physiology, Biomass, Food Chain, Pseudomonas fluorescens metabolism, Soil Pollutants analysis, Biodegradation, Environmental, Pseudomonas fluorescens physiology, Soil Pollutants metabolism

Abstract

Research into the biodegradation of soil contaminants has rarely addressed the consequences of predator-prey interactions. Here, we investigated the joint effect of predation and dispersal networks on contaminant degradation by linking spatial abundances of degrader (Pseudomonas fluorescens LP6a) and predator (Bdellovibrio bacteriovorus) bacteria to the degradation of the major soil contaminant phenanthrene (PHE). We used a laboratory microcosm with a PHE passive dosing system and a glass fiber network to facilitate bacterial dispersal. Different predator-to-prey ratios and spatial arrangements of prey and predator inoculation were used to study predation pressure effects on PHE degradation. We observed that predation resulted in (i) enhanced PHE-degradation at low predator counts (PC) compared to controls lacking predation, (ii) reduced PHE-degradation at elevated PC relative to low PC, and (iii) significant effects of the spatial arrangement of prey and predator inoculation on PHE degradation. Our data suggest that predation facilitated by dispersal networks (such as fungal mycelia) may support the build-up of an effective bacterial biomass and, hence, contaminant biodegradation in heterogeneous systems such as soil., (© FEMS 2016. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2017

11. The effects of connectivity on metapopulation persistence: network symmetry and degree correlations.

Author

Shtilerman, Elad and Stone, Lewi

Subjects

*METAPOPULATION (Ecology), *PATCH dynamics, *COLONIZATION (Ecology), *SYMMETRY (Biology), *DISPERSAL (Ecology)

Abstract

A spatial metapopulation is a mosaic of interconnected patch populations. The complex routes of colonization between the patches are governed by the metapopulation's dispersal network. Over the past two decades, there has been considerable interest in uncovering the effects of dispersal network topology and its symmetry on metapopulation persistence. While most studies find that the level of symmetry in dispersal pattern enhances persistence, some have reached the conclusion that symmetry has at most a minor effect. In this work, we present a new perspective on the debate. We study properties of the in- and out-degree distribution of patches in the metapopulation which define the number of dispersal routes into and out of a particular patch, respectively. By analysing the spectral radius of the dispersal matrices, we confirm that a higher level of symmetry has only a marginal impact on persistence. We continue to analyse different properties of the in-out degree distribution, namely the 'in-out degree correlation' (IODC) and degree heterogeneity, and find their relationship to metapopulation persistence. Our analysis shows that, in contrast to symmetry, the in-out degree distribution and particularly, the IODC are dominant factors controlling persistence. [ABSTRACT FROM AUTHOR]

Published

2015