We describe the short- and long-term dynamics of a phenotypic polymorphism that arose in a population of Escherichia coli while it was serially propagated for almost 20,000 generations in a glucose-limited minimal medium. The two types, designated L and S, differ conspicuously in the size of the colonies they form on agar plates as well as the size of their individual cells, and these differences are heritable. The S type reached a detectable frequency (>1%) at generation 6,000, and it remained above that frequency throughout the subsequent generations. In addition to morphological differences, L and S diverged in important ecological properties. With clones isolated at 18,000 generations, L has a maximal growth rate in fresh medium that is ∼20% higher than that of S. However, experiments with conditioned media demonstrate that L and S secrete one or more metabolites that promote the growth of S but not of L. The death rate of L during stationary phase also increases when S is abundant, which suggests that S may either secrete a metabolite that is toxic to L or remove some factor that enables the survival of L. One-day competition experiments with the clones isolated at generation 18,000 show that their relative fitness is frequency dependent, with each type having an advantage when rare. When these two types are grown together for a period of several weeks, they converge on an equilibrium frequency that is consistent with the 1-d competition experiments. Over the entire 14,000-generation period of coexistence, however, the frequency of the S type fluctuated between approximately 10% and 85%. We offer several hypotheses that may explain the fluctuations in this balanced polymorphism, including the possibility of coevolution between the two types.
Theoretical studies have predicted a trade-off between growth rate and yield in heterotrophic organisms. Here we test for the existence of this trade-off by analyzing the growth characteristics of 12 E. coli B populations that evolved for 20,000 generations under a constant selection regime. We performed three different tests. First, we analyzed changes in growth rate and yield over evolutionary time for each population. Second, we tested for a negative correlation between rate and yield across the 12 populations. Finally, we isolated clones from four selected populations and tested for a negative correlation between rate and yield within these populations. We did not find evidence for a trade-off based on the first two tests. However, we did observe a trade-off based on the within-population correlation of yield and rate. Our results indicate that, at least for the populations studied here, an analysis of the within-population diversity might be the most sensitive test for the existence of a trade-off. The observation of a trade-off within, but not between, populations suggests that the populations evolved different genetic solutions for growth in the selective environment, which in turn led to different physiological constraints.
A major focus of research on the dynamics of host-pathogen interactions has been the evolution of pathogen virulence, which is defined as the loss in host fitness due to infection. It is usually assumed that changes in pathogen virulence are the result of selection to increase pathogen fitness. However, in some cases, pathogens have acquired hypovirulence by themselves becoming infected with hyperparasites. For example, the chestnut blight fungus Cryphonectria parasitica has become hypovirulent in some areas by acquiring a double-stranded RNA hyperparasite that debilitates the pathogen, thereby reducing its virulence to the host. In this article, we develop and analyze a mathematical model of the dynamics of host-pathogen interactions with three trophic levels. The system may be dominated by either uninfected (virulent) or hyperparasitized (hypovirulent) pathogens, or by a mixture of the two. Hypovirulence may allow some recovery of the host population, but it can also harm the host population if the hyperparasite moves the transmission rate of the pathogen closer to its evolutionarily stable strategy. In the latter case, the hyperparasite is effectively a mutualist of the pathogen. Selection among hyperparasites will often minimize the deleterious effects, or maximize the beneficial effects, of the hyperparasite on the pathogen. Increasing the frequency of multiple infections of the same host individual promotes the acquisition of hypovirulence by increasing the opportunity for horizontal transmission of the hyperparasite. This effect opposes the usual theoretical expectation that multiple infections promote the evolution of more virulent pathogens via selection for rapid growth within hosts.
In nature, a large number of species can coexist on a small number of shared resources; however, resource-competition models predict that the number of species in steady coexistence cannot exceed the number of resources. Motivated by recent studies of phytoplankton, we introduce trade-offs into a resourcecompetition model and find that an unlimited number of species can coexist. Our model spontaneously reproduces several notable features of natural ecosystems, including keystone species and population dynamics and abundances characteristic of neutral theory, despite an underlying non-neutral competition for resources.
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