Project description:The zebra finch is one of the most commonly studied songbirds in biology, particularly in genomics, neuroscience and vocal communication. However, this species lacks a robust cell line for molecular biology research and reagent optimization. We generated a cell line from zebra finch embryonic fibroblasts using the SV40 large and small T antigens, designated CFS414. This cell line demonstrates an improvement over previous songbird cell lines through continuous and density-independent growth, allowing for indefinite culture and monoclonal line derivation. Cytogenetic, genomic, and transcriptomic profiling established the provenance of this cell line and identified the expression of genes relevant to ongoing songbird research. This single-cell RNA sequencing experiment provided information on the gene expression landscape of the cell line, informing on its cell type, transcriptomic stability, and value to researchers utilizing the zebra finch as a model organism.
Project description:To investigate the cellular basis of parental species bias at birdsong, we performed single nuclei RNA-seq for six zebra finch and owl finch F1 hybrid juvenile birds.
Project description:To investigate the cellular basis of parental species bias at birdsong, we performed single nuclei RNA-seq for six zebra finch and owl finch F1 hybrid juvenile birds.
Project description:We applied single-cell RNA sequencing to investigate inter-species differences in germ cell development between chicken and zebra finch (Taeniopygia castanotis, formerly Taeniopygia guttata castanotis), a Neoaves songbird species and a common model of vocal learning.
Project description:DNA methylation is tightly linked with gene expression regulation and has long been regarded a stable epigenetic mark in postmitotic cells. However, it recently became clear that postnatal brains appear to show stimulus-induced de novo CpG methylation or active demethylation related to neuronal plasticity. Due to striking homologies between the brains of birds and mammals, songbirds, especially the zebra finch, propose an attractive model for investigating the genome-wide DNA methylation profile and DNA methylation reconfiguration during brain development. In order to obtain a first genome-wide compendium of genes under putative DNA methylation control, we performed MethyCap-seq experiments on two recently cultured zebra finch cell lines, G266 and ZFTMA, also upon AZA-induced demethylation. First, the MethylCap-seq methodology in zebra finch was validated by comparison with RRBS generated data. Subsequently, quantitative analysis identified 30,700 significantly demethylated loci upon AZA-treatment. Further examination revealed enrichment of these regions in exons and promoters. To assess the influence of methylation on gene expression, RNA-seq experiments were performed. Comparison of the RNA-seq and MethylCap-seq results showed that at least 357 of the 3,457 AZA-upregulated genes are putatively regulated by methylation in the promoter region, for which a pathway analysis showed obvious enrichment for neurological networks. The ZF exon-arrays analysis validated the RNA-seq expression result for 75% and 62%, of the down and up-regulated genes, respectively. A subset of genes was validated also using qPCR and CpG pyrosequencing. To our knowledge, this study provides the first genome-wide DNA methylation map of the zebra finch genome as well as a comprehensive set of genes of which transcription is under putative methylation control Within the overall project, we performed a set of microarrays to validate RNAseq data (Series accession number GSE61060) . DMSO- and AZA-treated zebra finch cell lines, i.e. G266 and ZFTMA. ChipInspector carries out significance analysis on the single probe level. Normalized probe set level data not provided for individual Sample records. Processed data is available on Series record.
Project description:DNA methylation is tightly linked with gene expression regulation and has long been regarded a stable epigenetic mark in postmitotic cells. However, it recently became clear that postnatal brains appear to show stimulus-induced de novo CpG methylation or active demethylation related to neuronal plasticity. Due to striking homologies between the brains of birds and mammals, songbirds, especially the zebra finch, propose an attractive model for investigating the genome-wide DNA methylation profile and DNA methylation reconfiguration during brain development. In order to obtain a first genome-wide compendium of genes under putative DNA methylation control, we performed MethyCap-seq experiments on two recently cultured zebra finch cell lines, G266 and ZFTMA, also upon AZA-induced demethylation. First, the MethylCap-seq methodology in zebra finch was validated by comparison with RRBS generated data. Subsequently, quantitative analysis identified 30,700 significantly demethylated loci upon AZA-treatment. Further examination revealed enrichment of these regions in exons and promoters. To assess the influence of methylation on gene expression, RNA-seq experiments were performed. Comparison of the RNA-seq and MethylCap-seq results showed that at least 357 of the 3,457 AZA-upregulated genes are putatively regulated by methylation in the promoter region, for which a pathway analysis showed obvious enrichment for neurological networks. The ZF exon-arrays analysis validated the RNA-seq expression result for 75% and 62%, of the down and up-regulated genes, respectively. A subset of genes was validated also using qPCR and CpG pyrosequencing. To our knowledge, this study provides the first genome-wide DNA methylation map of the zebra finch genome as well as a comprehensive set of genes of which transcription is under putative methylation control
Project description:We have conducted a Cross-Species Microarray analysis by hybridizing genomic DNA from the common whitethroat (Sylivia communis) on a newly developed Affymetrix costum array designed for the zebra finch (Taeniopygia guttata), the Lund-zf array. We have also quality tested the Lund-zf array by hybridizing zebra finch genomic DNA to the platform.
Project description:DNA methylation is tightly linked with gene expression regulation and has long been regarded a stable epigenetic mark in postmitotic cells. However, it recently became clear that postnatal brains appear to show stimulus-induced de novo CpG methylation or active demethylation related to neuronal plasticity. Due to striking homologies between the brains of birds and mammals, songbirds, especially the zebra finch, propose an attractive model for investigating the genome-wide DNA methylation profile and DNA methylation reconfiguration during brain development. In order to obtain a first genome-wide compendium of genes under putative DNA methylation control, we performed MethyCap-seq experiments on two recently cultured zebra finch cell lines, G266 and ZFTMA, also upon AZA-induced demethylation. First, the MethylCap-seq methodology in zebra finch was validated by comparison with RRBS generated data. Subsequently, quantitative analysis identified 30,700 significantly demethylated loci upon AZA-treatment. Further examination revealed enrichment of these regions in exons and promoters. To assess the influence of methylation on gene expression, RNA-seq experiments were performed. Comparison of the RNA-seq and MethylCap-seq results showed that at least 357 of the 3,457 AZA-upregulated genes are putatively regulated by methylation in the promoter region, for which a pathway analysis showed obvious enrichment for neurological networks. A subset of genes was validated using qPCR and CpG pyrosequencing. To our knowledge, this study provides the first genome-wide DNA methylation map of the zebra finch genome as well as a comprehensive set of genes of which transcription is under putative methylation control.
Project description:Primordial germ cells (PGCs), major cell resource used in the production of germline chimeras in birds, have been used in conservation of avian genetic resources and production of transgenic animals. Numerous bird species have been put on the brink of extinction due to habitat loss and degradation caused by environmental destruction and climate change, but research on PGCs is limited to specific poultry, such as chickens. Although it has recently been expanding to various bird species, it is still difficult to utilize PGCs due to biological differences and difficulties in in vitro long-term culture. Here, we constructed a single-cell landscape of chicken gonadal PGCs with established long-term culture systems of PGCs and compared them with those of the vocal learning wild bird, the zebra finches. Our results identified the interspecific differences in signaling pathways in gonadal PGCs and somatic cells, respectively. In particular, the NODAL and insulin signaling pathways were more active in zebra finch than in chickens, whereas the FGF downstream signaling pathway known to be important for the proliferation of chicken PGCs, was more active in chickens. These differences may contribute to optimizing the in vitro culture conditions of zebra finch PGCs. This study is the first cross-species single-cell transcriptomic analysis targeting birds, and laid an essential groundwork to contribute to the restoration of endangered birds and the production of transgenic birds by securing sufficient PGCs from various bird species in the future.