Project description:To gain new insights into the genetic networks regulating hair cell development, we developed a new transcriptional programming strategy to promote in vitro hair cell differentiation, starting from mouse embryonic stem cells (mESCs). In vivo, Atoh1 is the only transcription factor (TF) known to be necessary and sufficient for HC differentiation, but in vitro its overexpression induces neuronal rather than hair cell differentiation. We discovered that Atoh1 expression combined with two other TFs (Pou4f3, Gfi1) resulted in efficient hair cell generation. This work offers a new paradigm to understand the molecular mechanisms governing transcription factor specificity. For example, how do Pou4f3-Gfi1 modulate Atoh1 activity to orchestrate a HC differentiation program? To address this question, we have engineered several mESCs lines containing Atoh1, Gfi1 and/or Pou4f3 in a doxycycline-inducible locus to allow a controllable overexpression of every combination of these 3 transcriptional factors either using a polycistronic approach (mESCs lines: iG+A, iG+P, iP+A and iGPA) or by promoting their individual overexpression (mESCs lines: iAtoh1, iGfi1 and iPou4f3). These findings highlight the diversity of mechanisms by which one TF can redirect the activity of another to enable combinatorial control of cell identity.

Project description:Mechanosensory hair cells (HCs) are the primary receptors of our senses of hearing and balance. However, very little is known about the transcriptional regulators involved in HC fate determination and differentiation. In this paper, we show that expression of three HC lineage-specific transcription factors: Gfi1, Pou4f3 and Atoh1, can induce a direct commitment towards HC fate during in vitro embryonic stem cell (ESC) differentiation. Induced HCs (iHCs) express numerous HC-specific genes and exhibit polarized membrane protusions reminiscent of stereociliary bundles. The ability to obtain purified populations of iHCs by virtue of the Myo7:mVenus reporter line (iGPA-Myo7a:mVenus) allowed us to generate highly reproducible gene expression profiles for these cells, at various phases of their development (day 8 and day 12 of cell culture).

Project description:We purified seven different cell populations and performed RNA sequencing to profile transcriptional similarities and differences between them. The seven cell types were 1) Atoh1-GFP positive cochlear hair cells from the organ of Corti of postnatal day one mice, 2) Atoh1-GFP negative cells from the organ of Corti of postnatal day one mice, 3) Atoh1-GFP positive induced hair cells generated by overexpression of Six1, Atoh1, Pou4f3, and Gfi1, 4) dsRed transduced control mouse embryonic fibroblasts, 5) Atoh1-GFP positive Merkel cells from postnatal day 1 mice, 6) Atoh1-GFP positive Cerebellar granule precursor cells from postnatal day 1 mice, and 7) Atoh1-GFP positive Gut secretory cells from postnatal day one mice.

Project description:We purified seven different cell populations and performed RNA sequencing to profile transcriptional similarities and differences between them. The seven cell types were 1) Atoh1-GFP positive cochlear hair cells from the organ of Corti of postnatal day one mice, 2) Atoh1-GFP negative cells from the organ of Corti of postnatal day one mice, 3) Atoh1-GFP positive induced hair cells generated by overexpression of Six1, Atoh1, Pou4f3, and Gfi1, 4) dsRed transduced control mouse embryonic fibroblasts, 5) Atoh1-GFP positive Merkel cells from postnatal day 1 mice, 6) Atoh1-GFP positive Cerebellar granule precursor cells from postnatal day 1 mice, and 7) Atoh1-GFP positive Gut secretory cells from postnatal day one mice.

Project description:We purified seven different cell populations and performed RNA sequencing to profile transcriptional similarities and differences between them. The seven cell types were 1) Atoh1-GFP positive cochlear hair cells from the organ of Corti of postnatal day one mice, 2) Atoh1-GFP negative cells from the organ of Corti of postnatal day one mice, 3) Atoh1-GFP positive induced hair cells generated by overexpression of Six1, Atoh1, Pou4f3, and Gfi1, 4) dsRed transduced control mouse embryonic fibroblasts, 5) Atoh1-GFP positive Merkel cells from postnatal day 1 mice, 6) Atoh1-GFP positive Cerebellar granule precursor cells from postnatal day 1 mice, and 7) Atoh1-GFP positive Gut secretory cells from postnatal day one mice.

Project description:Hearing and balance are mediated in vertebrates by inner ear mechanosensory hair cells. Hair cell development, maturation and survival require POU4F3, a class IV POU domain transcription factor that is expressed in hair cells shortly after they start to differentiate. Here, we show that POU4F3 has pioneer factor activity, and is necessary to promote chromatin accessibility at approximately half of the distal regulatory elements that appear as hair cells differentiate. Pou4f3 expression in the inner ear is initiated by ATOH1, a bHLH transcription factor that is also necessary for hair cell differentiation and survival. We show that ATOH1 also binds a large number of POU4F3-dependent distal regulatory elements, suggesting a synergistic feed-forward model in which ATOH1 induces POU4F3, which then acts to promote ATOH1-dependent hair cell differentiation.

Project description:The role of POU4F3 in Merkel cell maturation, but not induction, is similar to its role in hair cells. This prompted us to investigate whether POU4F3 also regulates the accessibility of ATOH1 targets in a feed-forward manner during the maturation of Merkel cells. Our results suggest that, just as in hair cells, the pioneer factor activity of POU4F3 is also required for ATOH1 to correctly coordinate mechanosensory differentiation in Merkel cells.

Project description:Hair cells (HCs) are the mechanoreceptors responsible for hearing and balance in the inner ear. Multiple factors cause HC loss including aging, noise exposure and genetic predisposition. A barrier to hearing restoration after HC loss is the inability of mammalian auditory HCs to spontaneously regenerate. Multiple factors are shown to be crucial for HC development and represent good candidates for regenerative studies. Atoh1 is widely accepted to be necessary and contextually sufficient for driving HC fate. Furthermore, the miRNA-183 family is known to be expressed at the time of HC differentiation, and mutations in miR-96 (one member of the family) can cause deafness both in mouse and human. Our goal is to identify and compare the impact of Atoh1/miR-183 family alone and in combination on the transcriptome of two different developmental cell models; mouse embryonic stem cells (mESCs) and immortalized multipotent otic progenitors (iMOPs)

Project description:During embryonic development, hierarchical cascades of transcription factors interact with lineage specific chromatin structures to control the sequential steps in the differentiation of specialized cell types. While examples of transcription factor cascades have been well documented, the mechanisms underlying developmental changes in accessibility of cell type-specific enhancers remain poorly understood. Here we show that the transcriptional ‘master regulator’, ATOH1 – which is necessary for the differentiation of two distinct mechanoreceptor cell types, hair cells in the inner ear, and Merkel cells of the epidermis – is unable to access much of its target enhancer network in the progenitor populations of either cell type when it first appears, imposing a block to further differentiation. This block is overcome by a feed-forward mechanism in which ATOH1 first stimulates expression of POU4F3, which subsequently acts as a pioneer factor to provide access to closed ATOH1 enhancers, allowing hair cell and Merkel cell differentiation to proceed. Our analysis also indicates the presence of both shared and divergent ATOH1/POU4F3-dependent, enhancer networks in hair cells and Merkel cells. These cells share a deep developmental lineage relationship, deriving from their common epidermal origin, and suggesting that this feed-forward mechanism preceded the evolutionary divergence of these very different mechanoreceptive cell types.

Project description:Mutations in the gene for Norrie disease protein (Ndp) cause syndromic deafness and blindness. We show that cochlear function in an Ndp knockout (KO) mouse deteriorated with age: at P3-P4, hair cells (HCs) showed progressive loss of Pou4f3 and Gfi1, key transcription factors for HC maturation, and Myo7a, a specialized myosin required for normal function of HC stereocilia. Loss of expression of these genes correlated to increasing HC loss and profound hearing loss by 2 months of age. We show that overexpression of the Ndp gene in neonatal supporting cells or, remarkably, upregulation of canonical Wnt signaling in HCs rescued HCs and cochlear function. We conclude that Ndp secreted from supporting cells orchestrates a transcription factor network for the maintenance and survival of HCs and that increasing the level of b-catenin, the intracellular effector of Wnt signaling, is sufficient to replace the functional requirement for Ndp in the cochlea.