Evolutionary Feedback Mediated through Population Density, Illustrated with Viruses in Chemostats

Bull, James J.; Millstein, Jack; Orcutt, John D.; Wichman, Holly A.

doi:10.1086/499374

Cited by 75 publications

(90 citation statements)

References 51 publications

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“…This was observed by the fine-grained recA analyses showing rapid change at the level of microbial strains. These conclusions are consistent with many other studies (Middelboe, 2000;Middelboe et al, 2001;Zhong et al, 2002;Bull et al, 2006;Holmfeldt et al, 2007;Stoddard et al, 2007). Our conclusions are also supported by a recent study linking phage predation to the persistence of microbial diversity at the strain level .…”

Section: Fine-grained Analyses Of Microbial Strains and Viral Genotypessupporting

confidence: 94%

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Viral and microbial community dynamics in four aquatic environments

et al. 2010

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The species composition and metabolic potential of microbial and viral communities are predictable and stable for most ecosystems. This apparent stability contradicts theoretical models as well as the viral-microbial dynamics observed in simple ecosystems, both of which show Kill-the-Winner behavior causing cycling of the dominant taxa. Microbial and viral metagenomes were obtained from four human-controlled aquatic environments at various time points separated by one day to 41 year. These environments were maintained within narrow geochemical bounds and had characteristic species composition and metabolic potentials at all time points. However, underlying this stability were rapid changes at the fine-grained level of viral genotypes and microbial strains. These results suggest a model wherein functionally redundant microbial and viral taxa are cycling at the level of viral genotypes and virus-sensitive microbial strains. Microbial taxa, viral taxa, and metabolic function persist over time in stable ecosystems and both communities fluctuate in a Kill-the-Winner manner at the level of viral genotypes and microbial strains.

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Section: Fine-grained Analyses Of Microbial Strains and Viral Genotypessupporting

confidence: 94%

“…Likewise, recA-based TaxiF analysis of the microbiomes showed a corresponding rapid change in the microbial strains present. These results are consistent with previous chemostat studies observing limited numbers of viral and microbial pairs (Bull et al, 2006;Lennon and Martiny, 2008).…”

Section: Fine-grained Analyses Of Microbial Strains and Viral Genotypessupporting

confidence: 93%

Viral and microbial community dynamics in four aquatic environments

et al. 2010

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“…Maximization of m is through optimization of t L . The other approach is derived from comprehensive phage population dynamics in a chemostat culture (Bull 2006;Bull et al 2006). The phage growth rate is found to be m ¼ Às 1 rN ðbe ÀtLðd1mÞ À 1Þ, where s is the free phage death rate, r the adsorption rate, N the host concentration, and d the washout rate of the chemostat (Bull 2006, Equation 2b).…”

Section: Discussionmentioning

confidence: 99%

“…Nevertheless, it is an interesting and important topic worthy of further study. Using a population dynamics model that is based on chemostat culture condition, Bull (2006;Bull et al 2006) derived the optimal lysis time ast L ¼ e 1 ð1=mÞ, where t L is the lysis time, e the eclipse period, and m the phage growth rate, with the circumflexes indicating values at optimum. However, this relationship can also be derived using phage growth rate expressed as m ¼ lnðbÞ=ðt S 1 t L Þ, where t S is the search time for the bacterial host and b is the burst size, which can be expressed as b ¼ m(t L À e), where m is the maturation rate.…”

Section: Discussionmentioning

confidence: 99%

Bacteriophage Adsorption Rate and Optimal Lysis Time

2008

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The first step of bacteriophage (phage) infection is the attachment of the phage virion onto a susceptible host cell. This adsorption process is usually described by mass-action kinetics, which implicitly assume an equal influence of host density and adsorption rate on the adsorption process. Therefore, an environment with high host density can be considered as equivalent to a phage endowed with a high adsorption rate, and vice versa. On the basis of this assumption, the effect of adsorption rate on the evolution of phage optimal lysis time can be reinterpreted from previous optimality models on the evolution of optimal lysis time. That is, phage strains with a higher adsorption rate would have a shorter optimal lysis time and vice versa. Isogenic phage l-strains with different combinations of six different lysis times (ranging from 29.3 to 68 min), two adsorption rates (9.9 3 10 À9 and 1.3 3 10 À9 phage À1 cell À1 ml À1 min À1), and two markers (resulting in ''blue'' or ''white'' plaques) were constructed. Various pairwise competitions among these strains were conducted to test the model prediction. As predicted by the reinterpreted model, the results showed that the optimal lysis time is shorter for phage strains with a high adsorption rate and vice versa. Competition between high-and low-adsorption strains also showed that, under current conditions and phenotype configurations, the adsorption rate has a much larger impact on phage relative fitness than the lysis time.

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“…In contrast, the fixation probability does approach one in the burst-death model when the burst rate, l, is increased and s is very large. Recent work by Bull et al (2006) has elucidated the dynamics of adaptation when changes in both burst size and lysis time are possible.…”

Section: Discussionmentioning

confidence: 99%

Fixation Probabilities When Generation Times Are Variable: The Burst–Death Model

2007

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Estimating the fixation probability of a beneficial mutation has a rich history in theoretical population genetics. Typically, to attain mathematical tractability, we assume that generation times are fixed, while the number of offspring per individual is stochastic. However, fixation probabilities are extremely sensitive to these assumptions regarding life history. In this article, we compute the fixation probability for a ''burstdeath'' life-history model. The model assumes that generation times are exponentially distributed, but the number of offspring per individual is constant. We estimate the fixation probability for populations of constant size and for populations that grow exponentially between periodic population bottlenecks. We find that the fixation probability is, in general, substantially lower in the burst-death model than in classical models. We also note striking qualitative differences between the fates of beneficial mutations that increase burst size and mutations that increase the burst rate. In particular, once the burst size is sufficiently large relative to the wild type, the burst-death model predicts that fixation probability depends only on burst rate.

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Evolutionary Feedback Mediated through Population Density, Illustrated with Viruses in Chemostats

Cited by 75 publications

References 51 publications

Viral and microbial community dynamics in four aquatic environments

Viral and microbial community dynamics in four aquatic environments

Bacteriophage Adsorption Rate and Optimal Lysis Time

Fixation Probabilities When Generation Times Are Variable: The Burst–Death Model

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