Andere Kunden interessierten sich auch für
![Communities and Ecosystems]( "Communities and Ecosystems")
Communities and Ecosystems69,99 €![Computational Protein-Protein Interactions]( "Computational Protein-Protein Interactions")
Computational Protein-Protein Interactions119,99 €![The Geometry of Ecological Interactions]( "The Geometry of Ecological Interactions")
The Geometry of Ecological Interactions70,99 €![Mechanisms of Evolution]( "Mechanisms of Evolution")
Mechanisms of Evolution57,99 €![Evolution and Origin of Cells]( "Evolution and Origin of Cells")
Evolution and Origin of Cells55,99 €![Cellular Consequences of Evolution]( "Cellular Consequences of Evolution")
Cellular Consequences of Evolution53,99 €![Evolution of Eukaryotes]( "Evolution of Eukaryotes")
Evolution of Eukaryotes56,99 €
Pairwise and diffuse coevolution are defined, with examples that include mutualisms and predator-prey interactions. In any example of coevolution, the costs and benefits to both species involved in the interaction must be assessed in order to understand evolution of the interaction. Models to explain coral bleaching are examined in the context of a coevolutionary mutualism, as are the implications for the possible extinction of coral reefs. Data are examined in order to determine which model is best supported. Other examples of how evolution affects interactions and communities of organisms include adaptation to living in particular habitats and evolution to frequent and somewhat predictable disturbances. For the former, physiological adaptations possessed by some plants to live in low light conditions are described and assessed. Ecological disturbances are defined, and the role of disturbance on evolution of ecological systems is assessed through the use of data. Finally, how time and spatial scales affect disturbances and the evolutionary responses of organisms to disturbances are also examined.