Project description:The subject of the current study is the finding of possible molecular partners of Drosophila EcR receptor. Two labelling enzymes (BioID2 and APEX2) were fused to EcR or Usp to biotin label the surrounding proteins. All fused proteins were expressed using the Act5C promoter in Drosophila S2 cells. To ensure functionality of the generated proteins, we verified their ability to bind EcR and Usp sites in the Drosophila genome with the ChIP-Seq. Our results demonstrate that EcR and Usp fusions can be recruited to genomic sites endogenous for the EcR/Usp proteins. Conversely, unfused BioID2 and APEX2 enzymes do not bind to EcR/Usp sites. A more in-depth study was conducted to clarify the association of EcR/Usp with one of the detected proteins, CP190, a well-described cofactor of Drosophila insulators. ChIP-Seq experiments revealed an enrichment of CP190 binding on transcription start and end sites of 20E-dependent genes but not at EcR/Usp-bound enhancers.

Project description:Our study focuses on understanding how Rbf impacts the formation of flight muscles in Drosophila. We analyzed by RNA-seq the transcriptional changes dependent on Rbf in proliferating adult muscle precursors and in mature flight muscles at two different stages of Drosophila development

Project description:About one third of all angiosperm species produce flowers with petals fused into a corolla tube. As an important element of the tremendous diversity of flower morphology, the corolla tube plays a critical role in many specialized interactions between plants and animal pollinators (e.g., beeflies, hawkmoths, hummingbirds, nectar bats), which in turn drives rapid plant speciation. Despite its clear significance in plant reproduction and evolution, the corolla tube remains one of the least understood plant structures from a developmental genetics perspective. Through mutant analyses and transgenic experiments, here we show that the tasiRNA-ARF pathway is required for corolla tube formation in the monkeyflower species Mimulus lewisii. Loss-of-function mutations in the M. lewisii orthologs of ARGONAUTE7 and SUPRESSOR OF GENE SILENCING 3 cause a dramatic decrease in tasiARF abundance and a moderate up-regulation of Auxin Response Factor 3 (ARF3) and ARF4, which lead to inhibition of lateral expansion of the bases of petal primordia and complete arrest of the upward growth of the inter-primordial regions, resulting in unfused corollas. Integrating our molecular and phenotypic analyses of the tasiRNA-ARF pathway in Mimulus with historical insights from morphological and anatomical studies in various sympetalous species, we propose a new conceptual model for the developmental genetic control of corolla tube formation.

Project description:Synovial and bone marrow mesenchymal stem cells after intradiscally injection show regenerative effects of nucleus pulposus. Microarray analyses of rats were performed to investigate the closeness of the gene profiles between the nucleus pulposus cells and the synovial or bone marrow mesenchymal stem cells. To investigate interaction between synovial mesenchymal stem cells and nucleus pulposus cells, human synovial mesenchymal stem cells and rat nucleus pulposus cells were co-cultured, and species specific microarray were performed. Synovium of knee joints, bone marrow and nucleus pulposus were harvested from rat or human, and cells were isolated for RNA extraction and hybridization on Affymetrix microarrays. To compare the gene profiles each other, isolated cells were mono-cultured respectively, and human synovial mesenchymal stem cells and rat nucleus pulposus cells were co-cultured.

Project description:The evolutionary origin of powered flight was fundamental to the establishment and radiation of the avian clade, and it remains a salient feature of modern birds. However, flight has been lost multiple times throughout the evolution of the avian lineage. Ratites (flightless palaeognaths, including the emu, ostrich and other well-known groups) are perhaps the most notable flightless birds, and their convergent losses of flight often coincide with adaptations to a cursorial lifestyle, including robust legs, digit loss, and reduced wings. Although there is a wealth of comparative anatomical knowledge for several ratites, the underlying genetic mechanisms producing these changes remain debated. Here we use a multidisciplinary approach employing embryological, genetic, and genomic techniques to interrogate the mechanisms underlying the delay in forelimb development contributing to the diminution of the forelimb in emu embryos. We show that the epithelial to mesenchymal transition (EMT) in the lateral plate mesoderm (LPM) and muscle precursor migration, the initiating events of limb formation, occur at equivalent stages in the emu and chick. However, the early emu forelimb fails to proliferate at HH18. The unique emu forelimb expression of Nkx2.5, previously associated with diminished wing development, does not initiate until after this stage, concomitant with migration of myoblasts into the limb bud, and hence would not appear to be the proximal cause of limb reduction in this species. In contrast, RNA-sequencing of HH18 limb tissues reveals significantly lower Fgf10 expression in the emu forelimb. Artificially increasing mesenchymal Fgf10 expression to the nascent emu wing induces ectodermal Fgf8 expression and results in a proliferative limb bud. Analyzing open chromatin reveals differentially active regulatory elements near Fgf10 and Sall-1 in the emu wing compared to emu hindlimb and both chicken limbs. Additionally, we show that the Sall-1 enhancer activity is dependent on an Ets transcription factor-binding site likely mediated by Fgf-signaling. Taken together, our results support a model where regulatory changes result in lower expression of Fgf10 and a concomitant failure to induce the genes required for limb proliferation in the early emu wing bud at HH18.

Project description:The evolutionary origin of powered flight was fundamental to the establishment and radiation of the avian clade, and it remains a salient feature of modern birds. However, flight has been lost multiple times throughout the evolution of the avian lineage. Ratites (flightless palaeognaths, including the emu, ostrich and other well-known groups) are perhaps the most notable flightless birds, and their convergent losses of flight often coincide with adaptations to a cursorial lifestyle, including robust legs, digit loss, and reduced wings. Although there is a wealth of comparative anatomical knowledge for several ratites, the underlying genetic mechanisms producing these changes remain debated. Here we use a multidisciplinary approach employing embryological, genetic, and genomic techniques to interrogate the mechanisms underlying the delay in forelimb development contributing to the diminution of the forelimb in emu embryos. We show that the epithelial to mesenchymal transition (EMT) in the lateral plate mesoderm (LPM) and muscle precursor migration, the initiating events of limb formation, occur at equivalent stages in the emu and chick. However, the early emu forelimb fails to proliferate at HH18. The unique emu forelimb expression of Nkx2.5, previously associated with diminished wing development, does not initiate until after this stage, concomitant with migration of myoblasts into the limb bud, and hence would not appear to be the proximal cause of limb reduction in this species. In contrast, RNA-sequencing of HH18 limb tissues reveals significantly lower Fgf10 expression in the emu forelimb. Artificially increasing mesenchymal Fgf10 expression to the nascent emu wing induces ectodermal Fgf8 expression and results in a proliferative limb bud. Analyzing open chromatin reveals differentially active regulatory elements near Fgf10 and Sall-1 in the emu wing compared to emu hindlimb and both chicken limbs. Additionally, we show that the Sall-1 enhancer activity is dependent on an Ets transcription factor-binding site likely mediated by Fgf-signaling. Taken together, our results support a model where regulatory changes result in lower expression of Fgf10 and a concomitant failure to induce the genes required for limb proliferation in the early emu wing bud at HH18.

Project description:MicroRNA expression profiling of human nucleus pulposus derived from patients with IDD in comparison with those derived from cadaveric disc as normal control. We have identified the expression profiles of miRNAs in IDD using scoliotic nucleus pulposus as controls (GSE19943). It is noteworthy that scoliotic discs are not strictly normal discs. Therefore, the microRNA expression profiles were revisited using normal discs as control. Two-condition experiment: control nucleus pulposus vs. degenerative nucleus pulposus. Biological replicates: 5 control, 5 degenerated, independently harvested (the same samples as in GSE56081). Four replicates per array.

Project description:MicroRNAs expression profiling of human nucleus pulposus cells derived from patients with disc degeneration in comparison with those derived from patients with scoliosis as control. Two-condition experiment: control nucleus pulposus cells vs. degenerative nucleus pulposus cells. Biological replicates: 3 control, 3 degenerated, independently harvested. Four replicates per array. The supplementary file 'GSE19943_fold_pvalue.txt' contains fold-changes and p-values.

Project description:Analyze the mechanism of short tail formation

Project description:Craniosynostosis (CS) is the congenital premature fusion of one or more cranial sutures and represents the more prevalent craniofacial malformation in humans, with an overall incidence of 1 out of 2000-3000 live births. Non-syndromic craniosynostoses (NSC) are believed to be multifactorial disorders, with a strong genetic component, due to possible gene–gene or gene–environment interactions that remain to be clearly identified. In this study we delved into the molecular signaling acting in calvarial tissue and cells from patients affected by nonsynodromic midline craniosynostosis, using a comparative analysis between fused and unfused sutures of each affected individuals. Using comparative microarray tissue gene expression profiling we have identified a subset of genes involved in the structure and function of the primary cilium, including the Bardet-Biedl syndrome 9 (BBS9) gene, which was recently associated to sagittal synostosis in a GWAS study. We therefore characterized BBS9 expression and cilium-related signaling in cells isolated from patients’ calvarial bone.