Genome Evolution of Neurospora tetrasperma

Sun, Yu

January 2013

In this thesis work, I have used a comparative genomics approach to study a fungal model organism, Neurospora tetrasperma. My specific focus has been on genomic introgression, intron evolution, chromosomal structural rearrangements and codon usage. All of the studies are based on large-scale dataset generated by next-generation sequencing technology (NGS), combined with other techniques, such as Optical Mapping. In the introgression study, we detected large-scale introgression tracts in three N. tetrasperma lineages, and the introgression showed allele-specific and chromosomal-specific pattern. In the study of introns, we found indications of mRNA mediated intron loss and non-homologous end joining (NHEJ) mediated intron gains in N. tetrasperma. We found that selection is involved in shaping intron gains and losses, and associated with intron position, intron phase and GC content. In the study of chromosomal structural rearrangements, we found a lineage specific chromosomal inversion pattern in N. tetrasperma, which indicates that inversions are unlikely to associate with the origin of the suppressed recombination and the mating system transition in N. tetrasperma. The result suggests inversions are the consequences, rather than the causes, of suppressed recombination on the mating-type chromosome of N. tetrasperma. In the final study, analyses of codon usage indicated that the region of suppressed recombination in N. tetrasperma is subjected to genomic degeneration, and selection efficiency has been much reduced in this region.

Neurospora tetrasperma

next-generation sequencing

introgression

intron

chromosomal inversion

codon usage

Integrating genetics, geography, and local adaptation to understand ecotype formation in the yellow monkeyflower, Mimulus guttatus

Lowry, David Bryant

January 2010

<p>Speciation is a constantly ongoing process whereby reproductive isolating baririer build up over time until groups of organisms can no longer exchange genes with each other. Adaptation is thought to play a major role in the formation of these barriers, although the genetic mechanisms and geographic mode underlying the spread of barriers due to adaptive evolution is poorly understood. Critically, speciation may occur in stages through the formation of intermediate partially reproductively isolated groups. The idea of such widespread ecotypes has been the subject of great controversy over the last century. Even so, we have relatively little understanding about whether widespread ecotypes exist, wheather they are reproductively isolated, and how adaptive alleles are distributed among partially isolated groups. In this dissertation, I examined these issues in widespread coastal perennial and inland annual ecotypes of the yellow monkeyflower, Mimulus guttatus. First, I determined that coastal and inland populations comprise distinct ecotypic groups. I then determined that these ecotypes are adapted to their respective habitats through genetically based flowering time and salt tolerance differences. I assessed the genetic architecture of these adaptations through quantitative trait loci (QTL) analysis and determined the geographic distribution of the underlying alleles through latitudinally replicated mapping populations. I quantified the contribution of these loci to adaptation in the field through the incorporation of advance generation hybrids in reciprocal transplant experiments. In the process, I discovered a widespread chromosomal inversion to be involved in the adaptive flowering time and annual/perennial life-history shift among the ecotypes. Overall, the results of this study suggest that widespread reproductively isolated ecotypes can form through the spread adaptive standing genetic variation between habitats and that chromosomal rearrangements can integral to this process.</p> / Dissertation

Biology, Genetics

Biology, Ecology

Evolution and Development

adaptation

chromosomal inversion

ecotype

flowering time

salt tolerance

speciation

The Importance of Bacterial Replichore Balance

Cerit, Ender Efe

January 2021

In most bacterial pathogens, the genome is comprised within a single circular chromosome which is typically organized by the origin-to-terminus axis that divides the chromosome into equally-sized arms of replication (replichores). This similarity in length is presumed to be required for the synchronization of the two replication forks to meet at the terminus for efficient chromosome segregation. Transfer of genes between organisms, different from the route of parent to offspring, is called horizontal gene transfer (HGT). Acquiring foreign DNA through HGT is an important factor for the evolution of virulence in bacteria since it provides access to new features such as new toxins and antibiotic resistance genes. Chromosomes of many pathogenic bacteria such as Salmonella spp. carry such horizontally-transferred DNA fragments called pathogenicity islands. However, after such HGT events, the existing organization of chromosome can be disrupted and an imbalance between the two halves of the circular chromosome might occur. The predicted outcome of a replichore imbalance is the retardation of growth which in turn might result in the out-competition by other faster-growing bacteria in the environment. For that reason, we have investigated the association of the fitness cost and the replichore imbalance with isogenic strains with varying degrees of inter-replichore inversions. Our results showed that there is a correlation between the magnitude of replichore imbalance and fitness cost, for example 2.49-fold imbalance (one replichore 2.49-fold longer than the other) resulted in 11% reduction of fitness in comparison with balanced replichores. Therefore, our data suggest that the replichore imbalance could be utilized to predict the fitness cost of HGT events.

Salmonella

bacterial evolution

fitness cost

chromosome organization and structure

chromosomal inversion

replichore

horizontal gene transfer

Microbiology in the medical area