Project description:Similarities between speech and birdsong make songbirds advantageous for investigating the neurogenetics of learned vocal communication; a complex phenotype likely supported by ensembles of interacting genes in cortico-basal ganglia pathways of both species. To date, only FoxP2 has been identified as critical to both speech and birdsong. We performed weighted gene co-expression network analysis on microarray data from singing zebra finches to discover gene ensembles regulated during vocal behavior. We found ~2,000 singing- regulated genes comprising 3 co-expression groups unique to area X, the basal ganglia subregion dedicated to learned vocal-motor behavior. These contained known targets of human FOXP2 and potential avian targets. We validated novel biological pathways for vocalization. Our findings show that higher-order gene co-expression patterns, rather than expression levels, molecularly distinguish area X from the ventral striato-pallidum during singing. The previously unknown structure of singing-driven networks enables prioritization of molecular interactors that likely bear on human motor disorders, especially those affecting speech. Gene expression was measured in 2 basal ganglia sub-regions (area X & ventral striato-pallidum (VSP)) of 27 adult male zebra finches that sang different amounts of song over a 2hr period in the morning. 18 birds were allowed to sing freely, 9 birds were discouraged from singing by the presence of an investigator and those that sang fewer than 10 song motifs were considered “non-singers”.

Project description:Similarities between speech and birdsong make songbirds advantageous for investigating the neurogenetics of learned vocal communication; a complex phenotype likely supported by ensembles of interacting genes in cortico-basal ganglia pathways of both species. To date, only FoxP2 has been identified as critical to both speech and birdsong. We performed weighted gene co-expression network analysis on microarray data from singing zebra finches to discover gene ensembles regulated during vocal behavior. We found ~2,000 singing- regulated genes comprising 3 co-expression groups unique to area X, the basal ganglia subregion dedicated to learned vocal-motor behavior. These contained known targets of human FOXP2 and potential avian targets. We validated novel biological pathways for vocalization. Our findings show that higher-order gene co-expression patterns, rather than expression levels, molecularly distinguish area X from the ventral striato-pallidum during singing. The previously unknown structure of singing-driven networks enables prioritization of molecular interactors that likely bear on human motor disorders, especially those affecting speech.

Project description:Agilent custom zebra finch microarray

Project description:Validation of a genome-wide search for zebra finch epigenetically regulated genes using Zebra finch Exon Arrays

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.

Project description:Taeniopygia guttata (zebra finch) genome, bTaeGut1, alternate haplotype

Project description:Gut microbiome of nesting and non-nesting zebra finch

Project description:Taeniopygia guttata (zebra finch) genome sequencing and assembly, primary haplotype

Project description:Functional genomic analysis and neuroanatomical localization of miR-2954 in zebra finch cells

Project description:Transcriptics analysis of fovea and non-fovea in the P14 zebra finch retina