In Caenorhabditis nematodes, the androdioecious, self-fertilizing reproductive strategy has evolved relatively recently from gonochoristic, outcrossing ancestors. Transitions in mating system impact how genes are vertically transmitted between generations and horizontally between populations through gene flow. To date, species-wide studies have targeted selfing species, and we have limited understanding about how population genetic processes have shaped the genome structure and evolutionary history of outcrossing species of Caenorhabditis. To fill this gap, I investigate patterns of genetic variation and population genetic processes focusing on two outcrossing species in the genus, C. brenneri and C. remanei, using a survey of nucleotide polymorphisms in a multipopulation, multilocus context.
I discover extensive genetic diversity in Caenorhabditis brenneri, termed hyperdiversity, giving this species the highest known levels of nucleotide polymorphism for any multicellular eukaryote. Genetic crosses between populations, extensive intra-locus recombination, and evidence of weak selection on codon usage all suggest that this is due to a large effective population size in the species and not an artifact of cryptic species divergence.
I demonstrate that C. remanei also is characterised by high genetic variation globally, albeit not as extreme as in C. brenneri, and within each local population. Despite geographic barriers, considerable gene flow occurs between inter-continental locations. While exploring genetic diversity in C. remanei, I discovered C. sp. 23, a new, gonochoristic species reproductively isolated and highly divergent from it.
Subsequently, taking advantage of this newly discovered species pair, I explore the patterns of postzygotic reproductive isolation between C. remanei and C. sp. 23. I find evidence of partial F1 hybrid inviability, strong F1 hybrid male sterility (Haldaneās rule) and strong F2 hybrid breakdown between the two.
The findings from this thesis, especially the notion of hyperdiversity, can be taken advantage of to answer key questions on testing limits of natural selection, of evolution of genome complexity as well as identifying and characterising functional, non-coding regulatory elements. Discovery of a new species pair in Caenorhabditis helps establish an emerging age of speciation genetics in the worm.
| Identifer | oai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/43540 |
| Date | 08 January 2014 |
| Creators | Dey, Alivia |
| Contributors | Cutter, Asher |
| Source Sets | University of Toronto |
| Language | en_ca |
| Detected Language | English |
| Type | Thesis |
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