The tuning of DNA mutability via codon context and usage bias : identifying predispositions to nonneutral evolution within human genes

Horvath, Monica Marie.

January 2004

Thesis (Ph. D.) -- University of Texas Southwestern Medical Center at Dallas, 2004. / Vita. Bibliography: 291-299.

Poxvirus evolution the role of horizontal gene transfer /

Odom, Mary Rebecca.

January 2010

Thesis (Ph.D.)--University of Alabama at Birmingham, 2010. / Title from PDF title page (viewed on July 7, 2010). Includes bibliographical references.

Novel genetic and molecular properties of meiotic recombination protein PRDM9

Altemose, Nicolas Frank

January 2015

Meiotic recombination is a fundamental biological process in sexually reproducing organisms, enabling offspring to inherit novel combinations of mutations, and ensuring even segregation of chromosomes into gametes. Recombination is initiated by programmed Double Strand Breaks (DSBs), the genomic locations of which are determined in most mammals by PRDM9, a rapidly evolving DNA-binding protein. In crosses between different mouse subspecies, certain Prdm9 alleles cause infertility in hybrid males, implying a critical role in fertility and speciation. Upon binding to DNA, PRDM9 deposits a histone modification (H3K4me3) typically found in the promoters of expressed genes, suggesting that binding might alter the expression of nearby genes. Many other questions have remained about how PRDM9 initiates recombination, how it causes speciation, and why it evolves so rapidly. This body of work investigates these questions using complementary experimental and analytical methodologies. By generating a map of human PRDM9 binding sites and applying novel sequence analysis methods, I uncovered new DNA-binding modalities of PRDM9 and identified sequence-independent factors that predict binding and recombination outcomes. I also confirmed that PRDM9 can affect gene expression by binding to promoters, identifying candidate regulatory targets in meiosis. Furthermore, I showed that PRDM9’s DNA-binding domain also mediates strong protein-protein interactions that produce PRDM9 multimers, which may play an important functional role. Finally, by generating high-resolution maps of PRDM9 binding in hybrid mice, I provide evidence for a mechanism to explain PRDM9-mediated speciation as a consequence of the joint evolution of PRDM9 and its binding targets. This work reveals that PRDM9 binding on one chromosome strongly impacts DSB formation and/or repair on the homologue, suggesting a novel role for PRDM9 in promoting efficient homology search and DSB repair, both critical for meiotic progression and fertility. One consequence is that PRDM9 may play a wider role in mammalian speciation.

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Glycosylhydrolase genes control respiratory tubes sizes and airway stability

Behr, Matthias, Riedel, Dietmar

11 February 2022

Tight barriers are crucial for animals. Insect respiratory cells establish barriers through their extracellular matrices. These chitinous-matrices must be soft and flexible to provide ventilation, but also tight enough to allow oxygen flow and protection against dehydration, infections, and environmental stresses. However, genes that control soft, flexible chitin-matrices are poorly known. We investigated the genes of the chitinolytic glycosylhydrolase-family 18 in the tracheal system of Drosophila melanogaster. Our findings show that five chitinases and three chitinase-like genes organize the tracheal chitin-cuticles. Most of the chitinases degrade chitin from airway lumina to enable oxygen delivery. They further improve chitin-cuticles to enhance tube stability and integrity against stresses. Unexpectedly, some chitinases also support chitin assembly to expand the tube lumen properly. Moreover, Chitinase2 plays a decisive role in the chitin-cuticle formation that establishes taenidial folds to support tube stability. Chitinase2 is apically enriched on the surface of tracheal cells, where it controls the chitin-matrix architecture independently of other known cuticular proteins or chitinases. We suppose that the principle mechanisms of chitin-cuticle assembly and degradation require a set of critical glycosylhydrolases for flexible and not-flexible cuticles. The same glycosylhydrolases support thick laminar cuticle formation and are evolutionarily conserved among arthropods.

info:eu-repo/classification/ddc/570

ddc:570

The genetic and functional characterization the tumour suppressor ivp-3 in Caenorhabditis briggsae / The genetic and functional characterization of ivp-3

Pabla, Ramandeep

January 2017

A Thesis Submitted to the School of Graduate Studies in the Partial Fulfillment of the Requirements for the Degree Master of Science / Caenorhabditis elegans and one of its close relatives, Caenorhabditis briggsae, are animal models that are commonly used for comparative studies to understand the evolution of developmental mechanisms and gene function. Although the two species appear nearly identical morphologically, comparative genomic analyses have revealed interesting differences between the genomes. Whether such differ- ences contribute to changes in developmental mechanisms and signalling pathways is an active area of research. One of the most well studied phenotypes associated with C. elegans signalling pathways are those that affect the specification of vulval tissue. Within the system of vuval development, mutants that exhibit the Mul- tivulva (Muv) phenotype are important as they show inappropriate divisions of vulva cells, which model tumour formation. Comparing gene function in different species genetic backgrounds can lead to an understanding of how genetic differ- ences contribute to different responses in cancer development. Genetic screens, conducted in our laboratory, yielded several genes whose loss of function results in a Muv phenotype and identified a novel regulator of C. briggsae vulval devel- opment, Cbr-ivp-3. Using the nematode C. briggssae as experimental system, we have characterized the tumour suppressor gene, Cbr-ivp-3, which impacts cell sig- nalling and cell division. I have carried out molecular genetic analyses of ivp-3 in both C. briggsae and C. elegans and have begun to characterize the functional role of Cbr-ivp-3. The findings in this thesis suggest that Cbr-ivp-3 is functioning to negatively regulate EGF/Cbr-lin-3. / Thesis / Master of Science (MSc) / The nematodes Caenorhabditis elegans and Caenorhabditis briggsae, are commonly used for comparative studies to understand the evolution of developmental mechanisms and gene function. Although both species appear morphologically similar, comparative genomic analyses reveal differences between genomes. Comparing gene function in different genetic backgrounds can lead to an understanding of how genetic differences contribute to different responses in cancer development. Genetic screens have yielded several genes whose loss of function results in a Multivulva phenotype, showing inappropriate division of vulva cells, modeling tumor formation. We have carried out molecular genetic analyses of ivp-3, a novel regulator of C. briggsae vulval development, in both species and have found that Cbr-ivp-3 is regulating vulva development by negatively regulating EGF/Cbr-lin-3.

Genetic studies of the negative regulators of vulva development in C. elegans and C. briggsae / Negative regulators of vulva development in C. elegans and C. briggsae

Jain, Ish

January 2020

Caenorhabditis elegans and its congener, C. briggsae are excellent animal models for the comparative study of developmental mechanisms and gene function. Gupta lab is using the vulval tissue in these nematodes as a system to investigate conservation and divergence in signal transduction pathways. Genetic screens conducted earlier in our laboratory recovered several mutants that cause multivulva (Muv) phenotype. The Muv genes act as tumor suppressors and negatively regulate the proliferation of vulval precursors. Genetic and molecular work on these genes has revealed that C. briggsae vulva developmental utilizes novel genes representing a new phenotypic class termed ‘Inappropriate Vulva cell Proliferation (IVP)’ (Sharanya et al., 2015). This indicates that the signaling mechanism in C. briggsae specifies vulval cell fates differently from C. elegans. Interestingly, it has been found that Cbr-ivp mutants show higher levels of Cbr-lin-3 (EGF) transcript, indicating that these genes act genetically upstream of Cbr-lin-3, similar to SynMuv family members in C. elegans. Moreover, RNAi knockdown of the Cbr-lin-3 transcript resulted in the suppression of the multivulva phenotype in mutant animals. Similar suppression was also observed when a MAP kinase inhibitor was used in the previous study. In addition, the role of two other novel negative regulators of cell proliferation, Cbr-lin(bh1) and Cbr-lin(bh3) was also investigated. Preliminary findings on these regulators suggested that both Cbr-lin(bh1) and Cbr-lin(bh3) exhibiting a heritable Muv phenotype and are found to be located on Chromosome I and III respectively. Identification of novel genes and further characterization will help us understand the molecular function of genes and their involvement in the regulation of vulval cell differentiation. The findings of my research work will provide a background for future studies to understand the role of novel genes in reproductive system development. Overall, these results provide evidence that although the morphology of vulva is similar in the two nematode species, underlying mechanisms of development appear to have diverged. / Thesis / Master of Science (MSc)

Competition and cooperation in host-associated microbial communities : insights from computational and mathematical models

Schluter, Jonas

January 2014

Our bodies contain a vast number and diversity of microbes. These microbes interact, and these interactions can define how microbes affect us. Microbial ecology and evolution, therefore, are important for both microbiology and human health. However, our understanding of microbial communities remains limited. There is a need for theory that dissects the complexity and identifies the key factors and processes affecting microbial groups. Here I develop realistic computer simulations and population models of microbial communities. My first project seeks to explain microbial communication (quorum sensing) and argues that quorum sensing is a way to infer when competing genotypes are no longer a threat. The second project proposes an evolutionary explanation for another major microbial trait: adhesion. I argue that adhesion is a weapon allowing cells to compete within microbial groups and push competitors out, particularly when growing on a host epithelium. The third project moves from microbes to the host and asks whether a host can control which microbes grow and persist inside it. I develop a model of the human gut epithelium and show that the gut architecture amplifies the ability of hosts to select helpful microbes over harmful ones using nutrient secretion. In addition to selecting particular microbial strains, a host will also benefit from stable symbiotic communities that behave in a predictable manner. But what determines whether host-associated communities are ecologically stable? My final project uses ecological network theory to show that ecological stability is likely to be a problem for gut communities that are diverse and contain species that cooperate with each other. However, I argue that the host should function as an ecosystem engineer that increases ecological stability by weakening the strong dependence of cooperating species upon one another. While host-associated communities are complex ecological systems, my thesis identifies key factors that affect their form and function.

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The dynamical systems theory of natural selection

Bentley, Michael

January 2016

Darwin's (1859) theory of evolution by natural selection accounts for the adaptations of organisms, but, as Fisher (1930) famously said, 'natural selection is not evolution.' Evolutionary theory has two major components: i) natural selection, which involves the underlying dynamics of populations; and ii) adaptive evolutionary change, which involves the optimisation of phenotypes for fitness maximisation. Many of the traditional theoretical frameworks in evolutionary theory have focussed on studying optimisation processes that generate biological adaptations. In recent years, however, a number of evolutionary theorists have turned to using frameworks such as the 'replicator dynamics' or 'eco-evolutionary dynamics', to explore the dynamics of natural selection. There has, however, been little attempt to explore how these dynamical systems frameworks relate to more traditional frameworks in evolutionary theory or how they incorporate the principles that embody the process of evolution by natural selection, namely, phenotypic variation, differential reproductive success, and heritability. In this thesis, I use these principles to provide the formal foundations of a general framework - a mathematical synthesis - in which the future state of an evolutionary system can be predicted from its present state; what I will call a 'dynamical systems theory of natural selection.' Given the state of an existing biological system, and a set of assumptions about how individuals within the system interact, the job of the dynamical systems theory of natural selection is no less than to predict the future in its entirety.

The genome of Euglena gracilis : annotation, function and expression

Ebenezer, ThankGod Echezona

January 2018

Euglena gracilis is a species of unicellular photosynthetic flagellate that inhibits aquatic ecosystems. E. gracilis belongs to the supergroup Excavata, and are an important component of the global biosphere, have biotechnological potential and is useful biological model due to their evolutionary history and complex biology. Whilst the evolutionary position of E. gracilis is now clear, their relationship with other protists such as Naegleria, Giardia, and Kinetoplastids, remains to be investigated in detail. Investigating and understanding the biology of this complex organism is a promising way to approach many evolutionary puzzles, including secondary endosymbiotic events and the evolution of parasitism, due to their relationship with Kinetoplastids. Here, I report a draft genome for E. gracilis, together with a high quality transcriptome and proteomic analysis. The estimated genome size is ~ 2 Gbp, with a GC content of ~ 50 % and a protein coding potential predicted at 36,526 Open Reading Frames (ORFs). Less than 25% of the genome is single copy sequence, indicating extensive repeat structure. There are evidences for large number of paralogs amongst specific gene families, indicating expansions and possible polyploidy as well as extensive sharing of genes with other non photosynthetic and photosynthetic eukaryotes: red and green algael genes, together with trypanosomes and other members of the excavates. Functional resolution into several of the biological systems indicates multiple similarities with the trypanosomatids in terms of orthology, paralogy, relatedness and complexity. Several biological systems such as nuclear architecture (e.g. chromosome segregation, nuclear pore complex, nuclear lamins), protein trafficking, translation, surface, consist of conserved and divergent components. For instance, several gene families likely associated with the cell surface and signal transduction possess very large numbers of lineage-specific paralogs, suggesting great flexibility in environmental monitoring and, together with divergent mechanisms for metabolic control, novel solutions to adaptation to extreme environments. I also demonstrate that the majority of control of protein expression levels is post-transcriptional and absence of transcriptional regulation, despite the presence of conventional introns. These data are a major advance in the understanding of the nuclear genome of Euglenids and provide a platform for investigation of the contributions of E. gracilis and relatives to the biosphere.

Coevolutionary adaptation in mutualisms

Wyatt, Gregory Alan Kenneth

January 2014

Natural selection favours those individuals that respond best to novel features of their selective environment. For many, a critical challenge is responding to evolutionary change in mutualistic species. These responses create complex feedbacks, so only coevolutionary approaches are able to fully answer key questions about the maintenance or disruption of mutualistic behaviour, and explain the range of mechanisms that allow individuals to benefit from these associations. I first consider the hypothesis that economic models studying multiple classes of traders, where each trader seeks to optimise its own payoffs will yield insights into mutualistic systems. I show that individuals can be favoured to discriminate amongst potential partners based on the price for which they provide resources. Then, I show that market mechanisms can maintain cooperation and drive specialisation in mutualistic systems. I extend this market model to allow individuals to restrict a mutualistic partner's access to resources, and show that this strategy can stabilise cooperation and increase the fitness of both partners. I also explicitly incorporate relatedness in my market model. I show that high relatedness sometimes increases cooperativeness in members of a mutualistic species, but sometimes decreases cooperativeness as it narrow the scope for partner choice to maintain cooperation. Having studied market mechanisms, I consider indiscriminate costly help to members of another species. I discover that this trait can be favoured by natural selection and can be classified as either altruism between or altruism within species. Finally, I consider a framework for analysing coevolved phenotypic responses to a partner's cooperativeness, a challenging process to model. I demonstrate that this framework can yield firm predictions about behaviour whenever partners hold private information about their costs and benefits.

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