| 1. |
- Berg, Frida, 1975-
(författare)
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Genetic Analysis of Fat Metabolism in Domestic Pigs and their Wild Ancestor
- 2006
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- The domestication of the pig began about 9 000 years ago and many of the existing domestic breeds have been selected for phenotypic traits like lean meat and fast growth. Domestic pigs are phenotypically very different from the ancestral wild boar that has adapted to survive in their natural environment. Because of their divergence, crosses between domestic pigs and wild boars are suitable for constructing genetic maps and Quantitative trait locus (QTL) analyses. A cross between the Large White and the European wild boar was thus initiated in the late 1980s. A major QTL for fat deposition and growth, denoted FAT1, was found on chromosome 4. The aim of this thesis was to further characterise the FAT1 locus and to identify the causative gene(s) and mutation(s). We have identified new markers and constructed a high-resolution linkage and RH map of the FAT1 QTL interval. We also performed comparative mapping to the human genome and showed that the pig chromosome 4 is homologous to human chromosomes 1 and 8. The gene order is very well conserved between the two species. In parallel we have narrowed down the FAT1 QTL interval by repeated backcrossing to the domestic Large White breed for six generations. The QTL could be confirmed for fatness but not for growth. Furthermore, the data strongly suggested that there might be more than one gene underlying the FAT1 QTL. Depending on which hypothesis to consider, the one- or two-loci model, the FAT1 interval can be reduced to 3,3 or 20 centiMorgan (cM), respectively, based on the backcross experiments. In the last study we confirm the two-loci model with one locus primarily effecting abdominal fat and another locus primarily effecting subcutaneous fat. We have identified a missense mutation in the RXRG gene which is in strong association with the abdominal fat QTL and the mutation is a potential candidate for that locus.Brown adipose tissue (BAT) is a specific type of fat essential for non-shivering thermogenesis in mammals. Piglets appear to lack BAT and rely on shivering as the main mechanism for thermoregulation. Uncoupling protein 1 (UCP1) gene is exclusively expressed in BAT and its physiological role is to generate heat by uncoupling oxidative phosphorylation. We show that the UCP1 gene has been disrupted in the pig lineage about 20 years ago. The inactivation of UCP1 provides a genetic explanation for the poor thermoregulation in piglets.
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| 2. |
- Berglund, Jonas, 1983-
(författare)
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Meiotic Recombination in Human and Dog : Targets, Consequences and Implications for Genome Evolution
- 2014
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Understanding the mechanism of recombination has important implications for genome evolution and genomic variability. The work presented in this thesis studies the properties of recombination by investigating the effects it has on genome evolution in humans and dogs.Using alignments of human genes with chimpanzee and macaque orthologues we studied substitution patterns along the human lineage and scanned for evidence of positive selection. The properties mirror the situation in human non-coding sequences with the fixation bias ‘GC-biased gene conversion’ (gBGC) as a driving force in the most rapidly evolving regions. By assigning candidate genes to distinct classes of evolutionary forces we quantified the extent of those genes affected by gBGC to 20%. This suggests that human-specific characters can be prompted by the fixation bias of gBGC, which can be mistaken for selection.The gene PRDM9 controls recombination in most mammals, but is lacking in dogs. Using whole-genome alignments of dog with related species we examined the effects of PRDM9 inactivation. Additionally, we analyzed genomic variation in the genomes of several dog breeds. We identified that non-allelic homologous recombination (NAHR) via sequence identity, often GC-rich, creates structural variants of genomic regions. We show that these regions, which are also found in dog recombination hotspots, are a subset of unmethylated CpG-islands (CGIs). We inferred that CGIs have experienced a drastic increase in biased substitution rates, concurrent with a shift of recombination to target these regions. This enables recurrent episodes of gBGC to shape their distribution.The work presented in this thesis demonstrates the importance of meiotic recombination on patterns of molecular evolution and genomic variability in humans and dogs. Bioinformatic analyses identified mechanisms that regulate genome composition. gBGC is presented as an alternative to positive selection and is revealed as a major factor affecting allele configuration and the emergence of accelerated evolution on the human lineage. Characterization of recombination-induced sequence patterns highlights the potential of non-methylation and establishes unmethylated CGIs as targets of meiotic recombination in dogs. These observations describe recombination as an interesting process in genome evolution and provide further insights into the mechanisms of genomic variability.
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| 3. |
- Eriksson, Jonas
(författare)
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Genetic and Genomic Studies in Chicken : Assigning Function to Vertebrate Genes
- 2012
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- A major challenge in the post-genomic era is to understand how genome sequence variants (genotype) give rise to the enormous diversity observed in terms of morphology, physiology and behavior (phenotype) among living organisms. Domestic animals—with their tremendous phenotypic variation—are excellent model organisms for determining the relationships between genotype and phenotype. In this thesis, I describe the utilization of the chicken, in combination with modern genetic and genomic approaches, in developing our understanding of the genetic mechanisms underlying phenotypic variation. These studies provide novel information on the genetics behind variation in carotenoid- and melanin-based pigmentation—observed in many organisms—and also cast light on the genetic basis of chicken domestication. In paper I, we report that the yellow skin phenotype—observed in most commercial chickens—is caused by one or several tissue-specific mutations altering the expression of beta-carotene oxygenase 2 (BCO2 or BCDO2) in skin. In addition, we present the first conclusive evidence of a hybrid origin of the domestic chicken, since the allele causing yellow skin most likely originates from the grey jungle fowl (Gallus sonneratii) and not from the previously described sole ancestor, the red jungle fowl (Gallus gallus). In paper II, we detect a number of loci that were likely important during the domestication process of chicken and the later specialization into meat (broiler) and egg (layer) producing lines. One of the major findings was that worldwide, almost all domestic chickens carry a missense mutation in TSHR (thyroid stimulating hormone receptor) in a position that is completely conserved amongst vertebrates. We speculate that this “domestication-mutation” has played an important role in the transformation of the wild red jungle fowl ancestor into the modern domestic chicken. In paper III, we demonstrate that the dilution of red (pheomelanin) pigmentation—observed in the plumage of the Inhibitor of Gold chicken—is caused by a frame-shift mutation in the catechol-O-methyltransferase domain containing 1 (COMTD1) gene. The production and regulation of pheomelanin is poorly understood and this discovery advances our current knowledge of this pathway.
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| 4. |
- Fitzsimmons, Carolyn, 1975-
(författare)
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Exploring the Realm of Gene Expression Differences Between White Leghorn and Red Junglefowl Chickens
- 2006
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- In this thesis we attempted to elicit patterns of gene expression that influence phenotype, and that may also have been altered by thousands of years of domestication and selection, between red junglefowl and White Leghorn chickens. Red junglefowl are the wild ancestor to all domesticated chickens, and poultry in general are highly valued as a research animal and food resource. The project was also begun in order to complement an earlier study of an intercross between White Leghorn and red junglefowl, which identified several regions that were linked with phenotypic differences between the two birds.We began by creating our own cDNA microarray via generating four cDNA libraries from red junglefowl/White Leghorn brain and testis. We generated 12,549 unique transcripts. This included 400 new putative transcripts specific to chickens, and 180 transcripts that were not found in any other database. When investigating polymorphisms between White Leghorn and red junglefowl we found a SNP rate of 1.9/kb coding region, and a synonymous and non-synonymous percentage for these SNPs of 80 and 20% respectively.In the last two studies we used the cDNA microarray to measure gene expression differences between White Leghorn and red junglefowl in both hypothalamus/thalamus and liver. We found that there appears to be a significant number of genes down-regulated in White Leghorn hypothalamus/thalamus, plus an over-representation of up-regulated genes from well-known pathways, as compared with red junglefowl. We hypothesize that domestication/selection may be connected with this characteristic. We also found that the p-arm of chicken chromosome 4, which is an ancestral microchromosome, was over represented with differentially expressed genes in hypothalamus/thalamus. A number of differentially expressed genes are shared between the two tissues, and these genes are expressed in same manner between red junglefowl and White Leghorn.
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| 5. |
- Gunnarsson, Ulrika
(författare)
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Genetic Studies of Pigmentation in Chicken
- 2009
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Domestic animals have been selected by humans for thousands of years, which have drastically altered their genetic constitution and phenotypes. In this thesis, several of the most important genes causing pigmentation differences between the wild red junglefowl (Gallus gallus) and domestic chickens have been identified. Pigmentation phenotypes are easily scored, and the genes underlying these phenotypes are valuable models to study gene function and gene interaction. Dominant white colour is widespread among domestic chickens. The Dominant white allele specifically inhibits the expression of black (eumelanin) pigment and we identified several insertion/deletion mutations in the PMEL17 gene causing the different phenotypes controlled by this locus. The Silver allele on the other hand inhibits the expression of red (pheomelanin) colour and is a genetic variant of the SLC45A2 gene. Silver is the first pheomelanin-specific mutation(s) reported for this gene. An 8 kb deletion, including a conserved enhancer element, 14 kb upstream of the transcription factor SOX10 is causing the Dark brown phenotype. This phenotype restricts the expression of eumelanin and enhances red pheomelanin in specific parts of the plumage. These three gene identifications have extended the knowledge about genes affecting melanocyte function. Carotenoid-based pigmentation is of utmost importance in birds and other animals. The yellow skin allele in chicken allows deposition of carotenoids in skin and explains why most domestic chickens have yellow legs. We demonstrated that the yellow skin phenotype is caused by a tissue specific regulatory mutation in the gene for the enzyme beta-caroten dioxygenase 2 (BCDO2). This was the first identification of a specific gene underlying carotenoid-based pigmentation. Interestingly, the yellow skin haplotype was shown to originate from the grey junglefowl (Gallus sonneratii) and not the red junglefowl as expected, thus presenting the first conclusive evidence for a hybrid origin of the domestic chicken.
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| 6. |
- Han, Fan
(författare)
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Genetic Adaptation and Speciation in Darwin’s Finches and Atlantic Herring
- 2020
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Natural selection acts on existing genetic variation to drive genetic adaptation of organisms to various ecological niches. Interaction between closely related populations, through processes such as competition and hybridization, may either lead to their divergence or population fusion, which has consequences for adaptation and the formation of species. This thesis aims to use two natural populations, Darwin’s finches and Atlantic herring, as models to explore the genetic mechanisms underlying ecological adaptation and speciation.The ecological adaptation of Darwin’s finches across the Galápagos Islands is primarily reflected by variation in beak morphology. Using whole-genome re-sequencing of all Darwin’s finch species, we discover that a locus, HMGA2, is highly associated with variation in beak size. Data collected before and after a severe drought show that this locus plays a critical role for ecological character displacement in large ground finches Geospiza magnirostris and medium ground finches G. fortis.Genomic islands of divergence refer to genomic regions of elevated divergence when comparing the genomes of closely related taxa. Establishment of these genomic islands can reflect a role in reproductive isolation or be related to ecological adaptation or background selection. Investigating their properties can shed light on how new species evolve. We study the landscape of genomic islands in Darwin’s finches, and find that the most pronounced genomic islands are likely ancient balanced polymorphisms, which govern adaptive variation in beak morphology.Hybridization is increasingly recognized as an important evolutionary process which may lead to speciation. We study two cases of hybridization in Darwin’s finches. In the first case, a new lineage of Darwin’s finches was founded through hybridization between a resident medium ground finch G. fortis and an immigrant Española cactus finch G. conirostris. In the second case, female-biased introgression occurred predominantly from medium ground finches G. fortis to common cactus finches G. scandens. Our genetic analysis on the mosaic genomes of hybrid finches show that non-random mating and natural selection primarily determine the outcome of hybridization.We generate a chromosome-level assembly of the Atlantic herring with a total size of 726 Mb, which coincides with a high-resolution linkage map and an LD-based recombination map. This facilitates the identification of an ~8Mb inversion, which is likely to be associated with ecological adaptation in herring to differences in water temperature. The contiguity of the assembly sorts placement of loci under selection that were identified based on a previous, highly fragmented draft assembly of the herring genome.
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| 7. |
- Imsland, Freyja
(författare)
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Monogenic Traits Associated with Structural Variants in Chicken and Horse : Allelic and Phenotypic Diversity of Visually Appealing Traits
- 2015
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Domestic animals have rich phenotypic diversity that can be explored to advance our understanding of the relationship between molecular genetics and phenotypic variation. Since the advent of second generation sequencing, it has become easier to identify structural variants and associate them with phenotypic outcomes. This thesis details studies on three such variants associated with monogenic traits.The first studies on Rose-comb in the chicken were published over a century ago, seminally describing Mendelian inheritance and epistatic interaction in animals. Homozygosity for the otherwise dominant Rose-comb allele was later associated with reduced rooster fertility. We show that a 7.38 Mb inversion is causal for Rose-comb, and that two alleles exist for Rose-comb, R1 and R2. A novel genomic context for the gene MNR2 is causative for the comb phenotype, and the bisection of the gene CCDC108 is associated with fertility issues. The recombined R2 allele has intact CCDC108, and normal fertility.The dominant phenotype Greying with Age in horses was previously associated with an intronic duplication in STX17. By utilising second generation sequencing we have examined the genomic region surrounding the duplication in detail, and excluded all other discovered variants as causative for Grey.Dun is the ancestral coat colour of equids, where the individual is mostly pale in colour, but carries intensely pigmented primitive markings, most notably a dorsal stripe. Dun is a dominant trait, and yet most domestic horses are non-dun in colour and intensely pigmented. We show that Dun colour is established by radially asymmetric expression of the transcription factor TBX3 in hair follicles. This results in a microscopic spotting phenotype on the level of the individual hair, giving the impression of pigment dilution. Non-dun colour is caused by two different alleles, non-dun1 and non-dun2, both of which disrupt the TBX3-mediated regulation of pigmentation. Non-dun1 is associated with a SNP variant 5 kb downstream of TBX3, and non-dun2 with a 1.6 kb deletion that overlaps the non-dun1 SNP. Homozygotes for non-dun2 show a more intensely pigmented appearance than horses with one or two non-dun1 alleles. We have also shown by genotyping of ancient DNA that non-dun1 predates domestication.
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| 8. |
- Jiang, Lin
(författare)
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Functional Studies of Genes Associated with Muscle Growth in Pigs and Hair Greying in Horses
- 2012
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Domestic animals have become very different from their wild ancestors during domestication and animal breeding. This provides a good model to unravel the molecular mechanisms underlying phenotypic variation. In my thesis I have studied genes affecting two important traits, leanness in pigs and hair greying-associated melanoma in horses.In the first part of the thesis, I focused on an intronic mutation leading to more muscle growth and less fat deposition in domestic pigs to identify a transcription factor (TF) that binds to the regulatory element overlapping with the mutation. The aim has been to further study the function of the previously unknown TF in mouse myoblast cells and in insulin-producing cells (Paper I-III). We discovered a new TF ZBED6 binding to intron 3 of the IGF2 gene, in which a single nucleotide substitution in pigs abrogates the binding and causes increased leanness in domestic pigs. Silencing of ZBED6 expression in mouse myoblasts increased Igf2 expression, cell proliferation and migration, and myotube formation. This result is in line with the increased leanness phenotype in mutant pigs. Chromatin Immunoprecipitation-sequencing (ChIP-seq) using an anti-ZBED6 antibody identified 1200 ZBED6 target genes besides IGF2 and many are TFs controlling fundamental biological processes. In the first follow-up study we found ZBED6 mainly affected the expression of muscle protein genes by directly regulating Igf2 and Twist2 expression, in agreement with our previous observation of faster myotube formation in ZBED6-silenced cells. ChIP-seq with antibodies against six different histone modifications revealed that ZBED6 preferentially binds to active promoters and modulates transcriptional activity by a novel mechanism rather than by recruiting repressive histone modifications. The second follow-up study revealed that ZBED6 affects the morphology and insulin content and release in pancreatic ß cells.In the second part (Paper IV), we investigate the functional significance of an intronic duplication in the Syntaxin 17 (STX17) gene causing hair greying and melanoma in horses. We found two Microphtalmia-associated transcription factor (MITF) binding sites within the duplication and showed that the duplicated sequence up-regulates reporter gene expression in a melanocyte-specific manner both by reporter assays in mouse melanocytes and in transgenic zebrafish. These results established that the intronic duplication acts as a melanocyte-specific enhancer that becomes much stronger when it is duplicated.
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| 9. |
- Lamichhaney, Sangeet, 1984-
(författare)
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The genetic basis for adaptation in natural populations
- 2016
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Many previous studies in evolutionary genetics have been based on few model organisms that can be reared at ease in the laboratory. In contrast, genetic studies of non-model, natural populations are desirable as they provide a wider range of adaptive phenotypes throughout evolutionary timescales and allow a more realistic understanding of how natural selection drives adaptive evolution. This thesis represents an example of how modern genomic tools can be effectively used to study adaptation in natural populations.Atlantic herring is one of the world’s most numerous fish having multiple populations with phenotypic differences adapted to strikingly different environments. Our study demonstrated insignificant level of genetic drift in herring that resulted in minute genetic differences in the majority of the genome among these populations. In contrast, a small percentage of the loci showed striking genetic differentiation that were potentially under natural selection. We identified loci associated with adaptation to the Baltic Sea and with seasonal reproduction (spring- and autumn-spawning) and demonstrated that ecological adaptation in Atlantic herring is highly polygenic but controlled by a finite number of loci.The study of Darwin’s finches constitutes a breakthrough in characterizing their evolution. We identified two loci, ALX1 and HMGA2, which most likely are the two most prominent loci that contributed to beak diversification and thereby to expanded food utilization. These loci have played a key role in adaptive evolution of Darwin’s finches. Our study also demonstrated that interspecies gene flow played a significant role in the radiation of Darwin’s finches and some species have a mixed ancestry.This thesis also explored the genetic basis for the remarkable phenotypic differences between three male morphs in the ruff. Identification of two different versions of a 4.5 MB inversion in Satellites and Faeders that occurred about 4 million years ago revealed clues about the genetic foundation of male mating strategies in ruff. We highlighted two genes in the inverted region; HSD17B2 that affects metabolism of testosterone and MC1R that has a key role in regulating pigmentation, as the major loci associated with this adaptation.
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| 10. |
- Larhammar, Martin, 1985-
(författare)
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Neuronal Networks of Movement : Slc10a4 as a Modulator & Dmrt3 as a Gait-keeper
- 2014
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Nerve cells are organized into complex networks that comprise the building blocks of our nervous system. Neurons communicate by transmitting messenger molecules released from synaptic vesicles. Alterations in neuronal circuitry and synaptic signaling contribute to a wide range of neurological conditions, often with consequences for movement. Intrinsic neuronal networks in the spinal cord serve to coordinate vital rhythmic motor functions. In spite of extensive efforts to address the organization of these neural circuits, much remains to be revealed regarding the identity and function of specific interneuron cell types and how neuromodulation tune network activity. In this thesis, two novel genes initially identified as markers for spinal neuronal populations were investigated: Slc10a4 and Dmrt3.The orphan transporter SLC10A4 was found to be expressed on synaptic vesicles of the cholinergic system, including motor neurons, as well as in the monoaminergic system, including dopaminergic, serotonergic and noradrenergic nuclei. Thus, it constitutes a novel molecular denominator shared by these classic neuromodulatory systems. SLC10A4 was found to influence vesicular transport of dopamine and affect neuronal release and reuptake efficiency in the striatum. Mice lacking Slc10a4 displayed impaired monoamine homeostasis and were hypersensitive to the drugs amphetamine and tranylcypromine. These findings demonstrate that SLC10A4 is capable of modulating the modulatory systems of the brain with potential clinical relevance for neurological and mental disorders.The transcription factor encoded by Dmrt3 was found to be expressed in a population of inhibitory commissural interneurons originating from the dorsal interneuron 6 (dI6) domain in the spinal cord. In parallel, a genome-wide association study revealed that a non-sense mutation in horse DMRT3 is permissive for the ability to perform pace among other alternate gaits. Further analysis of Dmrt3 null mutant mice showed that Dmrt3 has a central role for spinal neuronal network development with consequences for locomotor behavior. The dI6 class has been suggested to take part in motor circuits but remains one of the least studied classes due to lack of molecular markers. To further investigate the Dmrt3-derived neurons, and the dI6 population in general, a Dmrt3Cre mouse line was generated which allowed for characterization on the molecular, cellular and behavioral level. It was found that Dmrt3 neurons synapse onto motor neurons, receive extensive synaptic inputs from various neuronal sources and are rhythmically active during fictive locomotion. Furthermore, silencing of Dmrt3 neurons in Dmrt3Cre;Viaatlx/lx mice led to impaired motor coordination and alterations in gait, together demonstrating the importance of this neuronal population in the control of movement.
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