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Browsing by Author "Nie, Jing"
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Item CHD7 regulates otic lineage specification and hair cell differentiation in human inner ear organoid(Springer Nature, 2022-11-17) Nie, Jing; Ueda, Yoshitomo; Solivais, Alexander J.; Hashino, Eri; Otolaryngology -- Head and Neck Surgery, School of MedicineMutations in CHD7 cause CHARGE syndrome, affecting multiple organs including the inner ear in humans. We investigate how CHD7 mutations affect inner ear development using human pluripotent stem cell-derived organoids as a model system. We find that loss of CHD7 or its chromatin remodeling activity leads to complete absence of hair cells and supporting cells, which can be explained by dysregulation of key otic development-associated genes in mutant otic progenitors. Further analysis of the mutant otic progenitors suggests that CHD7 can regulate otic genes through a chromatin remodeling-independent mechanism. Results from transcriptome profiling of hair cells reveal disruption of deafness gene expression as a potential underlying mechanism of CHARGE-associated sensorineural hearing loss. Notably, co-differentiating CHD7 knockout and wild-type cells in chimeric organoids partially rescues mutant phenotypes by restoring otherwise severely dysregulated otic genes. Taken together, our results suggest that CHD7 plays a critical role in regulating human otic lineage specification and hair cell differentiation.Item Defective Tmprss3-Associated Hair Cell Degeneration in Inner Ear Organoids(Elsevier, 2019-07-09) Tang, Pei-Ciao; Alex, Alpha L.; Nie, Jing; Lee, Jiyoon; Roth, Adam A.; Booth, Kevin T.; Koehler, Karl R.; Hashino, Eri; Nelson, Rick F.; Otolaryngology, IU School of MedicineMutations in the gene encoding the type II transmembrane protease 3 (TMPRSS3) cause human hearing loss, although the underlying mechanisms that result in TMPRSS3-related hearing loss are still unclear. We combined the use of stem cell-derived inner ear organoids with single-cell RNA sequencing to investigate the role of TMPRSS3. Defective Tmprss3 leads to hair cell apoptosis without altering the development of hair cells and the formation of the mechanotransduction apparatus. Prior to degeneration, Tmprss3-KO hair cells demonstrate reduced numbers of BK channels and lower expressions of genes encoding calcium ion-binding proteins, suggesting a disruption in intracellular homeostasis. A proteolytically active TMPRSS3 was detected on cell membranes in addition to ER of cells in inner ear organoids. Our in vitro model recapitulated salient features of genetically associated inner ear abnormalities and will serve as a powerful tool for studying inner ear disorders.Item Defining developmental trajectories of prosensory cells in human inner ear organoids at single-cell resolution(The Company of Biologists, 2023) Ueda, Yoshitomo; Nakamura, Takashi; Nie, Jing; Solivais, Alexander J.; Hoffman, John R.; Daye, Becca J.; Hashino, Eri; Otolaryngology -- Head and Neck Surgery, School of MedicineThe inner ear sensory epithelia contain mechanosensitive hair cells and supporting cells. Both cell types arise from SOX2-expressing prosensory cells, but the mechanisms underlying the diversification of these cell lineages remain unclear. To determine the transcriptional trajectory of prosensory cells, we established a SOX2-2A-ntdTomato human embryonic stem cell line using CRISPR/Cas9, and performed single-cell RNA-sequencing analyses with SOX2-positive cells isolated from inner ear organoids at various time points between differentiation days 20 and 60. Our pseudotime analysis suggests that vestibular type II hair cells arise primarily from supporting cells, rather than bi-fated prosensory cells in organoids. Moreover, ion channel- and ion-transporter-related gene sets were enriched in supporting cells versus prosensory cells, whereas Wnt signaling-related gene sets were enriched in hair cells versus supporting cells. These findings provide valuable insights into how prosensory cells give rise to hair cells and supporting cells during human inner ear development, and may provide a clue to promote hair cell regeneration from resident supporting cells in individuals with hearing loss or balance disorders.Item Directed Differentiation of Mouse Embryonic Stem Cells Into Inner Ear Sensory Epithelia in 3D Culture(Springer Nature, 2017) Nie, Jing; Koehler, Karl R.; Hashino, Eri; Otolaryngology -- Head and Neck Surgery, School of MedicineThe inner ear sensory epithelium harbors mechanosensory hair cells responsible for detecting sound and maintaining balance. This protocol describes a three-dimensional (3D) culture system that efficiently generates inner ear sensory epithelia from aggregates of mouse embryonic stem (mES) cells. By mimicking the activations and repressions of key signaling pathways during in vivo inner ear development, mES cell aggregates are sequentially treated with recombinant proteins and small molecule inhibitors for activating or inhibiting the Bmp, TGFβ, Fgf, and Wnt signaling pathways. These stepwise treatments promote mES cells to sequentially differentiate into epithelia representing the non-neural ectoderm, preplacodal ectoderm, otic placodal ectoderm, and ultimately, the hair cell-containing sensory epithelia. The derived hair cells are surrounded by a layer of supporting cells and are innervated by sensory neurons. This in vitro inner ear organoid culture system may serve as a valuable tool in developmental and physiological research, disease modeling, drug testing, and potential cell-based therapies.Item Generation of inner ear organoids with functional hair cells from human pluripotent stem cells(Nature Publishing group, 2017-06) Koehler, Karl R.; Nie, Jing; Longworth-Mills, Emma; Liu, Xiao-Ping; Lee, Jiyoon; Holt, Jeffrey R.; Hashino, Eri; Otolaryngology -- Head and Neck Surgery, School of MedicineHuman inner ear tissue derived from pluripotent stem cells could provide a powerful platform for drug discovery or a source of sound- or motion-sensing cells for patients with hearing loss or balance dysfunction. Here we report a method for differentiating human pluripotent stem cells to inner ear organoids that harbor functional hair cells. Using a three-dimensional culture system, we modulate TGF, BMP, FGF, and Wnt signaling to generate multiple otic vesicle–like structures from a single stem-cell aggregate. Over two months, the vesicles develop into inner ear organoids with sensory epithelia that are innervated by sensory neurons. Additionally, using CRISPR/Cas9, we generate an ATOH1-2A-eGFP cell line to detect hair cell induction and demonstrate that derived hair cells exhibit electrophysiological properties similar to those of native sensory hair cells. Our culture system will be useful for elucidating mechanisms of human inner ear development and testing potential inner ear therapies.Item Imaging the Drosophila retina: zwitterionic buffers PIPES and HEPES induce morphological artifacts in tissue fixation(BioMed Central, 2015-02) Nie, Jing; Mahato, Simpla; Zelhof, Andrew C.; Department of Anatomy & Cell Biology, IU School of MedicineBackground Tissue fixation is crucial for preserving the morphology of biological structures and cytological details to prevent postmortem degradation and autolysis. Improper fixation conditions could lead to artifacts and thus incorrect conclusions in immunofluorescence or histology experiments. To resolve reported structural anomalies with respect to Drosophila photoreceptor cell organization we developed and utilized a combination of live imaging and fixed samples to investigate the exact biogenesis and to identify the underlying source for the reported discrepancies in structure. Results We found that piperazine-N,N’-bis(ethanesulfonic acid) (PIPES) and 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES), two zwitterionic buffers commonly used in tissue fixation, can cause severe lumen and cell morphological defects in Drosophila pupal and adult retina; the inter-rhabdomeral lumen becomes dilated and the photoreceptor cells are significantly reduced in size. Correspondingly, the localization pattern of Eyes shut (EYS), a luminal protein, is severely altered. In contrast, tissues fixed in the phosphate buffered saline (PBS) buffer results in lumen and cell morphologies that are consistent with live imaging. Conclusions We suggest that PIPES and HEPES buffers should be utilized with caution for fixation when examining the interplay between cells and their extracellular environment, especially in Drosophila pupal and adult retina research.Item A mosaic of independent innovations involving eyes shut are critical for the evolutionary transition from fused to open rhabdoms(Elsevier, 2018-11-15) Mahato, Simpla; Nie, Jing; Plachetzki, David C.; Zelhof, Andrew C.; Ophthalmology, School of MedicineA fundamental question in evolutionary biology is how developmental processes are modified to produce morphological innovations while abiding by functional constraints. Here we address this question by investigating the cellular mechanism responsible for the transition between fused and open rhabdoms in ommatidia of apposition compound eyes; a critical step required for the development of visual systems based on neural superposition. Utilizing Drosophila and Tribolium as representatives of fused and open rhabdom morphology in holometabolous insects respectively, we identified three changes required for this innovation to occur. First, the expression pattern of the extracellular matrix protein Eyes Shut (EYS) was co-opted and expanded from mechanosensory neurons to photoreceptor cells in taxa with open rhabdoms. Second, EYS homologs obtained a novel extension of the amino terminus leading to the internalization of a cleaved signal sequence. This amino terminus extension does not interfere with cleavage or function in mechanosensory neurons, but it does permit specific targeting of the EYS protein to the apical photoreceptor membrane. Finally, a specific interaction evolved between EYS and a subset of Prominin homologs that is required for the development of open, but not fused, rhabdoms. Together, our findings portray a case study wherein the evolution of a set of molecular novelties has precipitated the origin of an adaptive photoreceptor cell arrangement.