Cheating is evolutionarily assimilated with cooperation in the continuous snowdrift game

Sasaki, Tatsuya, Okada, Isamu

11 April 2015

It is well known that in contrast to the Prisoner's Dilemma, the snowdrift game can lead to a stable coexistence of cooperators and cheaters. Recent theoretical evidence on the snowdrift game suggests that gradual evolution for individuals choosing to contribute in continuous degrees can result in the social diversification to a 100% contribution and 0% contribution through so-called evolutionary branching. Until now, however, game-theoretical studies have shed little light on the evolutionary dynamics and consequences of the loss of diversity in strategy. Here, we analyze continuous snowdrift games with quadratic payoff functions in dimorphic populations. Subsequently, conditions are clarified under which gradual evolution can lead a population consisting of those with 100% contribution and those with 0% contribution to merge into one species with an intermediate contribution level. The key finding is that the continuous snowdrift game is more likely to lead to assimilation of different cooperation levels rather than maintenance of diversity. Importantly, this implies that allowing the gradual evolution of cooperative behavior can facilitate social inequity aversion in joint ventures that otherwise could cause conflicts that are based on commonly accepted notions of fairness. (authors' abstract)

The assembly of protist communities: Understanding drivers of historical contingency and causes and consequences of biodiversity

Pu, Zhichao

27 May 2016

Understanding mechanisms regulating the assembly of ecological communities is a major goal of community ecology. I combined experimental and theoretical approaches to investigate the influences of various ecological factors on the assembly of protist communities. My research included three experimental studies and one theoretical study. Two experimental studies used freshwater heterotrophic ciliated protists as model organisms to examine how species dispersal across local communities and functional and phylogenetic diversity of the species pool influence historical contingency of the assembled communities, respectively. The results of the first experiment showed that the differences in species colonization history led to alternative community states that substantially differed in species composition and abundances, regardless of the level of species dispersal. The results of the second experiment showed that historical contingency, measured by beta diversity and the strength of inhibitive priority effects decreased as phylogenetic and functional diversity of the species pool increased. In the third experimental study, I used the same model system and observed positive relationships between phylogenetic diversity and temporal stability of community biomass. These positive relationships are likely due to the reduced competition among species and increased asynchronous species responses to environmental changes under higher phylogenetic diversity. The theoretical study explored how phytoplankton and zooplankton coevolution drives species diversity patterns along productivity gradients in a mathematical model system. I explored the conditions for evolutionary divergence in phytoplankton and zooplankton and the consequent productivity-diversity relationships (PDR) using the theory of adaptive dynamics and numerical simulations. The results of numerical simulations showed that the coevolutionary dynamics of phytoplankton and zooplankton can generate transient unimodal or positive PDRs, and positive PDRs when the systems reach steady states. The findings of my research suggest an important role of traits and species ecological difference in understanding causes and consequences of biodiversity in community ecology.

Adaptive dynamics

Community assembly

Dispersal

Environmental fluctuation

Evolutionary branching

Functional diversity

Metacommunity

Phylogenetic diversity

Priority effects

Temporal stability

Traits

The Impact of Dormancy on the Ecological, Evolutionary and Pathogenic Properties of Microbial Populations

Paul, Tobias

18 June 2024

Die vorliegende Arbeit behandelt das biologische Phänomen der Dormanz mit Hilfe mathematischer Modellierung. Dormanz beschreibt dabei einen reversiblen Zustand von Individuen, in dem die metabolische Aktivität reduziert wird und die Resistenz gegen Natureinflüsse erhöht ist. Der erste Teil der Arbeit widmet sich den ökologischen Eigenschaften. Hier wird zunächst ein Moranmodell vorgestellt, welches verschiedene Modellierungsarten von Dormanz aus der Populationsgenetik vereint und unter verschiedenen Skalierungen den schwachen seed-bank Koaleszenten und den starken seed-bank Koaleszenten als anzestralen Prozess innehat. Dadurch werden die Parameter der Koaleszenten vergleichbar. Als Anwendung betrachten wir die sogenannte species abundance distribution, welche mithilfe von Koaleszenten beschrieben werden kann. Der zweite Teil beschäftigt sich mit den Auswirkungen von Dormanz auf evolutionäre Eigenschaften und beginnt mit einer Einführung in die Theorie von adaptive dynamics. Dort werden auch verschiedene Möglichkeiten der Modellierung von Dormanz in individuenbasierten Modellen besprochen. Danach befassen wir uns mit der Erweiterung eines Modells für sympatrische Speziation um den Aspekt der Dormanz. Die canonical equation of adaptive dynamics wird - motiviert durch ein Modell mit Dormanz - für schnellere Mutationsraten aus dem sogenannten power-law Mutationsregime für einen Grenzfall hergeleitet. Die Arbeit schließt mit dem dritten Teil, in welchem ein individuenbasiertes Modell für die Entwicklung von Krebs unter dem Einfluss von Chemotherapie und unter Berücksichtigung von Dormanz vorgestellt wird. In Simulationsstudien wird untersucht, inwiefern Dormanz zu Misserfolg einer Therapie beiträgt. Ein weiteres Ziel ist die Analyse von Kombinationsbehandlung mit einem Medikament welches mit dormanten Zellen interagieren kann insbesondere unter Betrachtung verschiedener Therapieansätze zur Behandlung von dormanten Krebszellen. / The present thesis uses mathematical modelling to investigate the consequences of dormancy. Dormancy describes a reversible and protected state of reduced metabolic activity which enhances an individual's resilience to hazardous conditions. In this sense, dormancy acts as a protection mechanism against habitats with unfavourable environments. The thesis considers the impact of dormancy on ecological, evolutionary and in its broadest sense pathogenic properties of microbial populations. The first part is concerned with studying the impact of dormancy on ecology. For this, a Moran model is presented which unifies different models of dormancy from population genetics and exhibits the weak seed-bank coalescent and the strong seed-bank coalescent as the scaling limit of the ancestral process. As an application we consider the species abundance distribution which can be described using coalescent theory. In the second part we consider the influence of dormancy on evolutionary properties. The modelling framework for this is the theory of adaptive dynamics. We then show that competition-induced dormancy may favour sympatric speciation. A key aspect in the derivation of this result is the canonical equation of adaptive dynamics. We extend this equation - motivated by a model including dormancy - to power-law mutations in a limiting case. We conclude the thesis with the third part where we provide an individual-based model for the treatment of cancer with chemotherapy under consideration of dormant cancer cells. Using simulation studies, we investigate how dormancy may contribute to treatment failure. Another goal of this chapter is to analyse combination treatment with a drug which directly targets dormant cancer cells and to formulate general observations regarding various strategies to counter cancer cell dormancy.

Dormanz

Koaleszenten

Evolutionäre Verzweigung

Krebstherapie

Dormancy

Adaptive dynamics

Evolutionary branching

seed bank

coalescent

cancer therapy

ddc:519