Laura Kvist

Structure and evolution of the avian mitochondrial control region

The structural and evolutionary characteristics of the mitochondrial control region were studied by using control region sequences of 68 avian species. The distribution of the variable nucleotide positions within the control region was found to be genus specific and not dependant on the level of divergence, as suggested before. Saturation was shown to occur at the level of divergence of 10% in pairwise comparisons of the control region sequences, as has also been reported for the third codon positions in ND2 and cytochrome b genes of mtDNA. The ratio of control region vs cytochrome b divergence in pairwise comparisons of the sequences was shown to vary from 0.13 to 21.65, indicating that the control region is not always the most variable region of the mtDNA, but also that there are differences in the rate of divergence among the lineages. Only two of the conserved sequence blocks localized earlier for other species, D box and CSB-1, were found to show a considerable amount of sequence conservation across the avian and mammalian sequences. Additionally, a novel avian-specific sequence block was found.

Conflicting patterns of mitochondrial and nuclear DNA diversity in Phylloscopus warblers

Molecular variation is often used to infer the demographic history of species, but sometimes the complexity of species history can make such inference difficult. The willow warbler, Phylloscopus trochilus, shows substantially less geographical variation than the chiffchaff, Phylloscopus collybita, both in morphology and in mitochondrial DNA (mtDNA) divergence. We therefore predicted that the willow warbler should harbour less nuclear DNA diversity than the chiffchaff. We analysed sequence data obtained from multiple samples of willow warblers and chiffchaffs for the mtDNA cytochrome b gene and four nuclear genes. We confirmed that the mtDNA diversity among willow warblers is low (π = 0.0021). Sequence data from three nuclear genes (CHD‐Z, AFLP‐WW1 and MC1R) not linked to the mitochondria demonstrated unexpectedly high nucleotide diversity (π values of 0.0172, 0.0141 and 0.0038) in the willow warbler, on average higher than the nucleotide diversity for the chiffchaff (π values of 0.0025, 0.0017 and 0.0139). In willow warblers, Tajimas D analyses showed that the mtDNA diversity, but not the nuclear DNA diversity, has been reduced relative to the neutral expectation of molecular evolution, suggesting the action of a selective sweep affecting the maternally inherited genes. The large nuclear diversity seen within willow warblers is not compatible with processes of neutral evolution occurring in a population with a constant population size, unless the long‐term effective population size has been very large (Ne > 106). We suggest that the contrasting patterns of genetic diversity in the willow warbler may reflect a more complex evolutionary history, possibly including historical demographic fluctuations or historical male‐biased introgression of nuclear genes from a differentiated population of Phylloscopus warblers.

Evolution and genetic structure of the great tit (Parus major) complex

The great tit complex is divided into four groups, each containing several subspecies. Even though the groups are known to differ markedly on morphological, vocal and behavioural characters, some hybridization occurs in the regions where they meet. The great tit has often been referred to as an example of a ring species, although this has later been questioned. Here, we have studied the genetic structure and phylogenetic relationships of the subspecies groups to clarify the evolutionary history of the complex using control region sequences of the mitochondrial DNA. The subspecies groups were found to be monophyletic and clearly distinct in mitochondrial haplotypes, and therefore must have had long-independent evolutionary histories. This conflicts with the ring species assignment and supports the formation of secondary contact zones of previously temporarily isolated groups. According to the phylogenetic species concept, all the subspecies groups could be considered as separate species, but if the definition of the biological species concept is followed, none of the subspecies groups is a true species because hybridization still occurs.

Phylogeography of a Palaearctic sedentary passerine, the willow tit (Parus montanus)

We analysed variation of the mitochondrial control region from willow tits through its Palaearctic distribution range. Although we found high amount of genetic variation (π=1.114%), there was almost no differentiation between subspecies or geographical localities. This may be because of a combination of several ecological and genetic factors, including a relatively homogenic habitat through the distribution range, lack of geographical barriers, high gene flow and a large long‐term effective population size. On the contrary, in the songar tit, which is sometimes considered to be conspecific with the willow tit, the mitochondrial lineages seem to correlate with the geographical locality and are clearly distinct from the willow tit. We concluded that the common ancestors of willow and songar tits existed some 1.5–2 Myr ago in the south‐eastern Asia. After the last Ice Ages, the willow tit expanded all through the Palaearctic, whereas the songar tit remained in eastern Asia.

The colonization history and present-day population structure of the european great tit (Parus major major)

The colonization history and present-day population structure of the European subspecies of the great tit Parus major major were studied using mitochondrial control region sequences. One major haplotype was found in all but one of the eight sampled populations from Spain to northern Finland. The other haplotypes differed from the common one by just a few substitutions; the overall nucleotide diversity was 0.00187 and haplotype diversity 0.8633. No population structuring was detected. The mismatch distribution followed the expected distribution of an expanding population. The estimated time to the most recent common ancestor coincides with the last glacial period. The results suggest that P. m. major survived the last glacial period in a single isolated refuge probably by the Mediterranean Sea. This was followed by rapid colonization of the European continent and population growth. The most recent range expansion northwards is still occurring. Gene flow between the sampled populations is extensive. It is aided by juvenile dispersal, long-distance movements of juvenile flocks and partial migration in the northern parts of the great tit’s range.

A multi-gene approach reveals a complex evolutionary history in the Cyanistes species group

Quaternary climatic oscillations have been considered decisive in shaping much of the phylogeographic structure around the Mediterranean Basin. Within this paradigm, peripheral islands are usually considered as the endpoints of the colonization processes. Here, we use nuclear and mitochondrial markers to investigate the phylogeography of the blue tit complex (blue tit Cyanistes caeruleus, Canary blue tit C. teneriffae and azure tit C. cyanus), and assess the role of the Canary Islands for the geographic structuring of genetic variation. The Canary blue tit exhibits strong genetic differentiation within the Canary Islands and, in combination with other related continental species, provides an ideal model in which to examine recent differentiation within a closely related group of continental and oceanic island avian species. We analysed DNA sequences from 51 breeding populations and more than 400 individuals in the blue tit complex. Discrepancies in the nuclear and mitochondrial gene trees provided evidence of a complex evolutionary process around the Mediterranean Basin. Coalescent analyses revealed gene flow between C. caeruleus and C. teneriffae suggesting a dynamic process with multiple phases of colonization and geographic overlapping ranges. Microsatellite data indicated strong genetic differentiation among the Canary Islands and between the Canary archipelago and the close continental areas, indicating limited contemporary gene flow. Diversification of the blue tit complex is estimated to have started during the early Pliocene (≈ 5 Ma), coincident with the end of Messinian salinity crisis. Phylogenetic analyses indicated that the North African blue tit is derived from the Canary blue tits, a pattern is avian ‘back colonization’ that contrasts with more traditionally held views of islands being sinks rather than sources.

Population Genetic Structure and Conservation of the Lesser White-Fronted GooseAnser erythropus

The lesser white-fronted goose is a sub-Arctic species with a currently fragmented breeding range, which extends from Fennoscandia to easternmost Siberia. The population started to decline at the beginning of the last century and, with a current world population estimate of 25,000 individuals, it is the most threatened of the Palearctic goose species. Of these, only 30–50 pairs breed in Fennoscandia. A fragment of the control region of mtDNA was sequenced from 110 individuals from four breeding, one staging and two wintering areas to study geographic subdivisions and gene flow. Sequences defined 15 mtDNA haplotypes that were assigned to two mtDNA lineages. Both the mtDNA lineages were found from all sampled localities indicating a common ancestry and/or some level of gene flow. Analyses of molecular variance showed significant structuring among populations (φST 0.220, P < 0.001). The results presented here together with ecological data indicate that the lesser white-fronted goose is fragmented into three distinctive subpopulations, and thus, the conservation status of the species should be reconsidered.

Genomic organization of the human COL3A1 and COL5A2 genes : COL5A2 has evolved differently than the other minor fibrillar collagen genes

We report here on the complete structure of the human COL3A1 and COL5A2 genes. Collagens III and V, together with collagens I, II and XI make up the group of fibrillar collagens, all of which share a similar structure and function; however, despite the similar size of the major triple-helical domain, the number of exons coding for the domain differs between the genes for the major fibrillar collagens characterized so far (I, II, and III) and the minor ones (V and XI). The main triple-helical domain being encoded by 49-50 exons, including the junction exons, in the COL5A1, COL11A1 and COL11A2 genes, but by 43-44 exons in the genes for the major fibrillar collagens. Characterization of the genomic structure of the COL3A1 gene confirmed its association with the major fibrillar collagen genes, but surprisingly, the genomic organization of the COL5A2 gene was found to be similar to that of the COL3A1 gene. We also confirmed that the two genes are located in tail-to-tail orientation with an intergenic distance of approximately 22 kb. Phylogenetic analysis suggested that they have evolved from a common ancestor gene. Analysis of the genomic sequences identified a novel single nucleotide polymorphism and a novel dinucleotide repeat. These polymorphisms should be useful for linkage analysis of the Ehlers-Danlos syndrome and related disorders.

Disentangling the complex evolutionary history of the Western Palearctic blue tits (Cyanistes spp.) – phylogenomic analyses suggest radiation by multiple colonization events and subsequent isolation

Isolated islands and their often unique biota continue to play key roles for understanding the importance of drift, genetic variation and adaptation in the process of population differentiation and speciation. One island system that has inspired and intrigued evolutionary biologists is the blue tit complex (Cyanistes spp.) in Europe and Africa, in particular the complex evolutionary history of the multiple genetically distinct taxa of the Canary Islands. Understanding Afrocanarian colonization events is of particular importance because of recent unconventional suggestions that these island populations acted as source of the widespread population in mainland Africa. We investigated the relationship between mainland and island blue tits using a combination of Sanger sequencing at a population level (20 loci; 12 500 nucleotides) and next‐generation sequencing of single population representatives (>3 200 000 nucleotides), analysed in coalescence and phylogenetic frameworks. We found (i) that Afrocanarian blue tits are monophyletic and represent four major clades, (ii) that the blue tit complex has a continental origin and that the Canary Islands were colonized three times, (iii) that all island populations have low genetic variation, indicating low long‐term effective population sizes and (iv) that populations on La Palma and in Libya represent relicts of an ancestral North African population. Further, demographic reconstructions revealed (v) that the Canary Islands, conforming to traditional views, hold sink populations, which have not served as source for back colonization of the African mainland. Our study demonstrates the importance of complete taxon sampling and an extensive multimarker study design to obtain robust phylogeographical inferences.

Endangered subspecies of the Reed Bunting (Emberiza schoeniclus witherbyi and E. s. lusitanica) in Iberian Peninsula have different genetic structures

In the Iberian Peninsula, populations of two subspecies of the Reed Bunting Emberiza schoeniclus have become increasingly fragmented during the last decades when suitable habitats have been lost and/or the populations have gone extinct. Presently, both subspecies are endangered. We estimated the amount of genetic variation and population structure in order to define conservation units and management practices for these populations. We found that the subspecies lusitanica has clearly reduced genetic variation in nuclear and mitochondrial markers, has a drastically small effective population size and no genetic differentiation between populations. In contrast, the subspecies witherbyi is significantly structured, but the populations still hold large amounts of variation even though the effective population sizes are smaller than in the non-endangered subspecies schoeniclus. We suggest several management units for the Iberian populations. One unit includes subspecies lusitanica as a whole; the other three units are based on genetically differentiated populations of witherbyi. The most important genetic conservation measure in the case of lusitanica is to preserve the remaining habitats in order to at least maintain the present levels of gene flow. In the case of the three management units within witherbyi, the most urgent conservation measure is to improve the habitat quality to increase the population sizes.ZusammenfassungAuf der Iberischen Halbinsel wurden die Populationen von zwei Rohrammer-Unterarten Emberiza schoeniclus in den letzten Jahrzehnten, als geeignete Habitate verloren gingen und/oder Populationen ausstarben, zunehmend fragmentiert. Derzeitig sind beide Unterarten gefährdet. Wir schätzten die Höhe der genetischen Variation und die Populationsstruktur um daraus Einheiten für den Schutz und Managementpraktiken für diese Populationen zu bestimmen. Wir fanden heraus, dass die Unterart lusitanica eine deutlich reduzierte genetische Variation in nukleären wie mitochondrialen Markern, eine dramatisch geringe effektive Populationsgröße und keine genetische Differenzierung zwischen Populationen aufweist. Im Gegensatz dazu ist die Unterart witherbyi deutlich strukturiert, aber die einzelnen Populationen beinhalten immer noch große Anteile der Gesamtvariation, wenngleich die effektiven Populationsgrößen kleiner sind als die der nicht gefährdeten Unterart schoeniclus. Wir schlagen mehrere Management-Einheiten für die Iberischen Populationen vor. Eine Einheit beinhaltet die Unterart lusitanica als Ganzes; die anderen drei Einheiten basieren auf den genetisch differenzierten Populationen der Unterart witherbyi. Die allerwichtigste Schutzmaßnahme aus genetischer Sicht im Falle der Unterart lusitanica ist die Bewahrung der verbleibenden Habitate um zumindest das derzeitige Maß an Genfluss zu erhalten. Im Falle der drei Management-Einheiten der Unterart witherbyi ist die dringlichste Schutzmaßnahme die Verbesserung der Habitate um die Populationsgrößen zu erhöhen.