Evolution of avian olfaction

Steiger, Silke S. Fidler, Andrew Eric, Kempenaers, B. Mueller, Jakob C.

January 2008

Thesis (doctoral)--Ludwig-Maximilians-Universität München, 2008. / Title from PDF t.p. (viewed on Jan. 8, 2009). Some chapters co-authored with others. Includes bibliographical references (p. 117-127).

Kandidátní geny pro behaviorální adaptace u tropických a temperátních ptáků / Candidate genes for behavioural adaptations in tropical and temperate birds

Křístková, Barbora

January 2019

The use of candidate genes has become a widespread approach in the study of behavioral adaptations. Gene function is often maintained in very distant evolutionary lines. This approach allows us to extend knowledge about non-model species. I studied the influence of selection on candidate behavioral adaptation genes associated mainly with biorhythms. I was interested in comparing genetic variability between closely related species of songbirds from tropical and temperate zones. These environments differ mainly in the conditions stability. Tropical species live in very stable conditions with generally low seasonality, unlike temperate species. Timing of events of cirkanual cycle of temperate birds is essential because of the alternating of conditions of the environment. I therefore assumed a reduction in genetic variability in migrating temperate zone species compared to tropical species due to stabilizing selection. The study is based on analyzes of microsatellite loci in the exon region. I involved analysis of neutral microsatellites as a control for possible genetic variability reduction coming from different reasons than selection. Neutral microsatellites are expected to not be influenced by selection. In tropical species I found reduced genetic variability of neutral microsatellites. That might...

Tests of community assembly across spatial scales in Neotropical birds

Trisos, Christopher Harry

January 2014

Species diversity varies dramatically across the surface of the Earth. A key step in the accumulation of species diversity is the ability of species to coexist in biological communities. Thus, identifying the mechanisms underlying community assembly is a major challenge for ecologists seeking to explain patterns in species diversity and composition. Recently some consensus has been reached on the set of processes that influence community assembly: speciation, demographic stochasticity, niche-based fitness trade-offs among species and dispersal. However, it is unclear how the importance of a particular process changes with spatial scale, which interactions exist among processes at large spatial scales and the extent to which niche-based resource partitioning among species explains differences in diversity among communities. Neotropical birds offer an ideal opportunity to address these uncertainties because of their high diversity and the existence of detailed information on their evolutionary history and ecology. In this thesis, I first use trait and phylogenetic metrics of community structure to show that both habitat filtering and interspecific competition shape community composition at the scale of individual bird territories (~1-2 ha). Second, I use simulations of community assembly to show that trait-based metrics of community structure outperform phylogenetic metrics for detecting niche-based community assembly, and that both sets of metrics often have low power when multiple processes influence community composition. Third, taking a trait-based, species-level approach, I show that both habitat filtering and interspecific competition influence species occurrence at regional scales (~75000 km²), and interact with dispersal ability so that their effect on species occurrence is increased for species with greater dispersal ability. Finally, using a combination of trait- and isotope-based methods to quantify resource partitioning, I show that species' niche widths do not change and niche overlap is reduced at high compared to low species richness. Taken together, these results suggest that both habitat filtering and interspecific competition (i.e. niche-based processes) influence community assembly from local to regional scales. However, at least at regional scales, the degree to which these processes are important for determining the occurrence of any given species depends on that species's dispersal ability. They also suggest, based on niche-based interspecific competition influencing community composition, that differences in species richness among communities are in part explained by differences among sites in the breadth of available niche space, not by increased ecological specialisation or niche overlap.

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Birds in a tree : a journey through avian phylogeny, with particular emphasis on the birds of New Zealand : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Genetics

Gibb, Gillian Claire

January 2010

Two main themes to the avian research presented in this thesis are, 1. Deep resolution of birds generally, and 2. Investigation of specific aspects of the New Zealand avifauna. More specifically, this thesis covers phylogeny, and predictions about palaeognaths, pigeons, pelecaniforms and passerines. Significant progress is made in resolving the basal branches of Neoaves. This thesis examines whether the six-way basal Neoavian split of Cracraft (2001) is, in principle, resolvable. New mitochondrial genomes are added to improve taxon sampling, break up long branches, and allow testing of the prior assumptions of six Neoavian groups. This research shows the six-way split is resolvable, although more work is required for specific details. From a life-history perspective, it is interesting that the two bird-of-prey groups (falcons and buzzards) are very divergent, and may not be sister groups. Molecular dating supports major diversification of at least 12 Neoavian lineages in the Late Cretaceous. Additionally, novel avian mitochondrial gene orders are investigated and a hypothesis put forward suggesting gene conversion and stable intermediate forms allows an apparently rare event (gene rearrangement) to occur multiple times within Neoaves. One of Cracraft’s six groups, informally called the ‘Conglomerati’, is particularly difficult to resolve. The pigeons (Columbiformes) lie within the ‘Conglomerati’, and this chapter examines two aspects along the continuum of pigeon evolution. Firstly the large South Pacific fruit pigeon radiation is examined with mid-length mitochondrial sequences. This clade contains a third of all pigeon species, and has been very successful in island colonisation throughout South East Asia and the Pacific. Secondly, candidates for the closest relative of pigeons are tested using analysis of whole mitochondrial genomes. Highest support was found for the grouping of sandgrouse and pigeon, although they are clearly very divergent. Also within the ‘Conglomerati’ is the traditional order Pelecaniformes, and their close allies the Ciconiiformes. These orders (the P&C) are part of an adaptive radiation of seabird water-carnivores, including loons, penguins, petrels and albatrosses. This group is separate from the large shorebird water-carnivore group; although both appear to have begun radiating abut 70 million years ago. The tropicbird represents a separate, convergent life history and is not part of the Pelecaniformes, nor within the larger seabird water-carnivore group. Resolution of the basal phylogeny of oscine passerines is important for interpreting the radiation of this group out of the Australasian region. Many endemic New Zealand oscine passerines belong to ‘basal corvid’ lineages, but have not previously been investigated with mitochondrial DNA. This chapter shows that many ‘basal corvid’ lineages are actually ‘basal passerine’ lineages, and there is a discrepancy between nuclear Rag-1 phylogenies (the most commonly used gene in passerine phylogenetics) and other phylogenies, including mitochondrial, that requires further investigation. Taken as a whole, this thesis adds significantly to our understanding of the evolution of birds, and provides a foundation for future research, not only of phylogenetic relationships, but also of avian life history, long-term niche stability and macroevolution.

Neoavian genetics

Evolution of birds

Phylogenetic relationships

Mitochondrial DNA