@article{LaisneyBraaschWalteretal.2010,
  author    = {Laisney, Juliette A. G. C. and Braasch, Ingo and Walter, Ronald B. and Meierjohann, Svenja and Schartl, Manfred},
  title     = {Lineage-specific co-evolution of the Egf receptor/ligand signaling system},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-67922},
  year      = {2010},
  abstract  = {Background: The epidermal growth factor receptor (Egfr) with its numerous ligands has fundamental roles in development, cell differentiation and physiology. Dysfunction of the receptor-ligand system contributes to many human malignancies. Consistent with such various tasks, the Egfr gene family has expanded during vertebrate evolution as a consequence of several rounds of whole genome duplication. Of particular interest is the effect of the fish-specific whole genome duplication (FSGD) on the ligand-receptor system, as it has supplied this largest group of vertebrates with additional opportunities for sub- and/or neofunctionalization in this signaling system. Results: We identified the predicted components of the Egf receptor-ligand signaling system in teleost fishes (medaka, platyfish, stickleback, pufferfishes and zebrafish). We found two duplicated egfr genes, egfra and egfrb, in all available teleost genomes. Surprisingly only one copy for each of the seven Egfr ligands could be identified in most fishes, with zebrafish hbegf being the only exception. Special focus was put on medaka, for which we more closely investigated all Egf receptors and Egfr ligands. The different expression patterns of egfra, egfrb and their ligands in medaka tissues and embryo stages suggest differences in role and function. Preferential co-expression of different subsets of Egfr ligands corroborates the possible subfunctionalization and specialization of the two receptors in adult tissues. Bioinformatic analyses of the ligand-receptor interface between Egfr and its ligands show a very weak evolutionary conservation within this region. Using in vitro analyses of medaka Egfra, we could show that this receptor is only activated by medaka ligands, but not by human EGF. Altogether, our data suggest a lineage-specific Egfr/Egfr ligand co-evolution. Conclusions: Our data indicate that medaka Egfr signaling occurs via its two copies, Egfra and Egfrb, each of them being preferentially coexpressed with different subsets of Egfr ligands. This fish-specific occurrence of Egf receptor specialization offers unique opportunities to study the functions of different Egf receptor-ligand combinations and their biological outputs in vertebrates. Furthermore, our results strongly support the use of homologous ligands in future studies, as sufficient cross-specificity is very unlikely for this ligand/receptor system.},
  subject      = {Epidermaler Wachstumsfaktor-Rezeptor},
  language  = {en}
}
@article{SchartlWalterShenetal.2013,
  author    = {Schartl, Manfred and Walter, Ronald B. and Shen, Yingjia and Garcia, Tzintzuni and Catchen, Julian and Amores, Angel and Braasch, Ingo and Chalopin, Domitille and Volff, Jean-Nicolas and Lesch, Klaus-Peter and Bisazza, Angelo and Minx, Pat and Hillier, LaDeana and Wilson, Richard K. and F{\"u}rstenberg, Susan and Boore, Jeffrey and Searle, Steve and Postlethwait, John H. and Warren, Wesley C.},
  title     = {The genome of the platyfish, Xiphophorus maculatus, provides insights into evolutionary adaptation and several complex traits},
  series = {Nature Genetics},
  volume    = {45},
  journal   = {Nature Genetics},
  number    = {5},
  doi       = {10.1038/ng.2604},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-132152},
  pages     = {567-572},
  year      = {2013},
  abstract  = {Several attributes intuitively considered to be typical mammalian features, such as complex behavior, live birth and malignant disease such as cancer, also appeared several times independently in lower vertebrates. The genetic mechanisms underlying the evolution of these elaborate traits are poorly understood. The platyfish, X. maculatus, offers a unique model to better understand the molecular biology of such traits. We report here the sequencing of the platyfish genome. Integrating genome assembly with extensive genetic maps identified an unexpected evolutionary stability of chromosomes in fish, in contrast to in mammals. Genes associated with viviparity show signatures of positive selection, identifying new putative functional domains and rare cases of parallel evolution. We also find that genes implicated in cognition show an unexpectedly high rate of duplicate gene retention after the teleost genome duplication event, suggesting a hypothesis for the evolution of the behavioral complexity in fish, which exceeds that found in amphibians and reptiles.},
  language  = {en}
}
@article{HerpinBraaschKraeusslingetal.2010,
  author    = {Herpin, Amaury and Braasch, Ingo and Kraeussling, Michael and Schmidt, Cornelia and Thoma, Eva C. and Nakamura, Shuhei and Tanaka, Minoru and Schartl, Manfred},
  title     = {Transcriptional Rewiring of the Sex Determining dmrt1 Gene Duplicate by Transposable Elements},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-68437},
  year      = {2010},
  abstract  = {Control and coordination of eukaryotic gene expression rely on transcriptional and posttranscriptional regulatory networks. Evolutionary innovations and adaptations often require rapid changes of such networks. It has long been hypothesized that transposable elements (TE) might contribute to the rewiring of regulatory interactions. More recently it emerged that TEs might bring in ready-to-use transcription factor binding sites to create alterations to the promoters by which they were captured. A process where the gene regulatory architecture is of remarkable plasticity is sex determination. While the more downstream components of the sex determination cascades are evolutionary conserved, the master regulators can switch between groups of organisms even on the interspecies level or between populations. In the medaka fish (Oryzias latipes) a duplicated copy of dmrt1, designated dmrt1bY or DMY, on the Y chromosome was shown to be the master regulator of male development, similar to Sry in mammals. We found that the dmrt1bY gene has acquired a new feedback downregulation of its expression. Additionally, the autosomal dmrt1a gene is also able to regulate transcription of its duplicated paralog by binding to a unique target Dmrt1 site nested within the dmrt1bY proximal promoter region. We could trace back this novel regulatory element to a highly conserved sequence within a new type of TE that inserted into the upstream region of dmrt1bY shortly after the duplication event. Our data provide functional evidence for a role of TEs in transcriptional network rewiring for sub- and/or neo-functionalization of duplicated genes. In the particular case of dmrt1bY, this contributed to create new hierarchies of sex-determining genes.},
  subject      = {Gen},
  language  = {en}
}