Abstract
Abstract. Populations can respond to environmental change over tens or hundreds of generations by shifts in phenotype that can be the result of a sustained physiological response, evolutionary (genetic) change, shifts in community composition, or some combination of these factors. Microbes evolve on human timescales, and evolution may contribute to marine phytoplankton responses to global change over the coming decades. However, it is still unknown whether evolutionary responses are likely to contribute significantly to phenotypic change in marine microbial communities under high pCO2 regimes or other aspects of global change. Recent work by Müller et al. (2010) highlights that long-term responses of marine microbes to global change must be empirically measured and the underlying cause of changes in phenotype explained. Here, I briefly discuss how tools from experimental microbial evolution may be used to detect and measure evolutionary responses in marine phytoplankton grown in high CO2 environments and other environments of interest. I outline why the particular biology of marine microbes makes conventional experimental evolution challenging right now and make a case that marine microbes are good candidates for the development of new model systems in experimental evolution. I suggest that "black box" frameworks that focus on partitioning phenotypic change, such as the Price equation, may be useful in cases where direct measurements of evolutionary responses alone are difficult, and that such approaches could be used to test hypotheses about the underlying causes of phenotypic shifts in marine microbe communities responding to global change.
Highlights
One of the major tasks faced by biologists today is to understand how future populations of marine phytoplankton may differ from contemporary ones
That genetic change will occur is inevitable; the question is whether evolutionary change will be an important contributor to phenotypic shifts that arise in marine algae during long-term responses to ocean acidification
This question is being addressed by at least two separate groups of researchers working in two separate paradigms, with surprisingly little dialogue between them: biological oceanographers and microbial experimental evolutionary biologists
Summary
One of the major tasks faced by biologists today is to understand how future populations of marine phytoplankton may differ from contemporary ones. Since Muller and colleagues set up their cultures as a mini selection experiment (long term growth of replicate populations that were initially genetically identical under novel and control environmental conditions), I read it looking for indications of evolutionary change after a few dozen generations of growth under rising pCO2.
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