Project description:Engineering functional tissues for transplantation requires insight into epigenetic mechanisms that regulate stem cell fate. We have developed the Wnt-induced osteogenic tissue model (WIOTM), a platform that recapitulates human osteogenesis, and identified acetylation of histone H3 at lysine 14 (H3K14ac) as a critical epigenetic regulator in human skeletal stem cells (hSSCs). In WIOTM, localized Wnt signals drive asymmetric cell division (ACD), yielding a proximal hSSC with high H3K14ac and a distal daughter with reduced H3K14ac that migrates into the 3D collagen matrix and initiate osteogenic differentiation. Disrupting H3K14ac in hSSCs abrogates ACD and WIOTM formation. To test whether hSSCs maintain H3K14ac in vivo, we formed the WIOTM on Wnt-functionalized polymer bandages and transplanted them into calvarial defects. The WIOTM contributed to bone repair, and human cells adjacent to the bandages retained high H3K14ac despite the injury environment. These findings establish WIOTM as both a mechanistic and translational platform for regenerative medicine.

Project description:Engineering functional tissues for transplantation requires insight into epigenetic mechanisms that regulate stem cell fate. We have developed the Wnt-induced osteogenic tissue model (WIOTM), a platform that recapitulates human osteogenesis, and identified acetylation of histone H3 at lysine 14 (H3K14ac) as a critical epigenetic regulator in human skeletal stem cells (hSSCs). In WIOTM, localized Wnt signals drive asymmetric cell division (ACD), yielding a proximal hSSC with high H3K14ac and a distal daughter with reduced H3K14ac that migrates into the 3D collagen matrix and initiate osteogenic differentiation. Disrupting H3K14ac in hSSCs abrogates ACD and WIOTM formation. To test whether hSSCs maintain H3K14ac in vivo, we formed the WIOTM on Wnt-functionalized polymer bandages and transplanted them into calvarial defects. The WIOTM contributed to bone repair, and human cells adjacent to the bandages retained high H3K14ac despite the injury environment. These findings establish WIOTM as both a mechanistic and translational platform for regenerative medicine.

Project description:<p>Bone regeneration requires spatiotemporal coordination of immune modulation, stem cell recruitment, angiogenesis, and osteogenesis, yet most scaffolds lack sequential control across healing phases. We develop a near-infrared (NIR)-responsive therapeutic&nbsp;platform that integrates clinically available irradiation with an engineered 3D radially aligned nanofiber scaffold functionalized with black phosphorus (BP) and a bone marrow mesenchymal stem cell (BMSC)-targeting aptamer (Apt19S). NIR photothermal stimulation accelerates BP degradation, releasing phosphate ions and activating a heat-shock program to promote macrophage polarization, endogenous MSC homing, neovascularization, and osteogenic differentiation. Metabolomics reveals cooperative regulation of HSP-linked signaling and lipid metabolism. In a rat critical-size calvarial defect, the platform achieves robust bone regeneration without exogenous cells or growth factors. The system is simple, structurally tunable, and shape-customizable, providing a clinically translatable and modular framework for spatiotemporal microenvironment programming in bone and other regenerative settings.</p>

Project description:Transcription regulation in pluripotent embryonic stem (ES) cells is a complex process that involves multitude of regulatory layers, one of which is post-translational modification of histones. Here we have investigated the genome-wide occurrence of two histone marks, acetylation of histone H3K9 and K14 (H3K9ac and H3K14ac), in mouse ES cells. We demonstrate genome-wide that H3K9ac and H3K14ac show very high correlation. Examination of H3K9ac and H3K14ac in mES cells

Project description:Histone acetylation and deacetylation is important for gene regulation. The histone acetyltransferase, Gcn5, is a known activator of transcriptional initiation that is recruited to gene promoters. Here we map genome-wide levels of Gcn5 occupancy and histone H3K14ac at high resolution. Gcn5 is predominantly localized to coding regions of highly transcribed genes where it antagonistically collaborates with the class II histone deacetylase, Clr3, to regulate histone H3K14ac levels. Regulation of histone H3k14ac levels is critical for regulation of many genes during stress adaptation. Our findings suggest a novel role for Gcn5 during transcriptional elongation in addition to its known role in transcriptional initiation. The data in this series showed Gcn5 occupancy and H3K14 acetylation levels in wild type, gcn5- and gcn5-/clr3- cells under KCl stress condition. Related expression data are GSE5227 and GSE13817 Keywords: Chip-chip

Project description:SETDB1 is a major H3K9 methyltransferase. It contains a unique Triple Tudor Domain (3TD) which specifically bind the dual modification of H3K14ac in the presence of H3K9me1/2/3. In this study, we explored the role of the 3TD H3K14ac interaction in the H3K9 methylation activity by SETDB1. We generated the 3TD binding reduced F332A mutant and demonstrate in biochemical methylation assays on recombinant nucleosomes containing H3K14ac analogs, that H3K14 acetylation is crucial for the 3TD mediated recruitment of SETDB1. We also see this effect in the cells where SETDB1 binding and activity was globally correlated with H3K14ac, and knock-out (KO) of the H3K14 acetyltransferase HBO1 caused a drastic reduction in the H3K9me3 levels at SETDB1 dependent sites. Further analyses revealed that 3TD was not required for SETDB1 recruitment for regions targeted by KAP1, but at specific target regions, SETDB1 KO could not be efficiently reconstituted by a 3TD mutant of SETDB1 as shown by the finding that H3K9 methylation of L1M repeat elements is highly dependent on an intact 3TD. In summary, our data demonstrate an important role of the 3TD interaction with H3 tails containing K14ac and K9 methylation in the recruitment of SETDB1 to chromatin which is particularly relevant at L1M repeats.

Project description:In the conventional model of transcriptional activation, transcription factors bind to response elements and recruit co-factors, including histone acetyltransferases. Contrary to this model, we show that the histone acetyltransferase KAT7 (HBO1/MYST2) is required genome-wide for histone H3 lysine 14 acetylation (H3K14ac). Examining neural stem cells, we found that KAT7 and H3K14ac were present not only at transcribed genes, but also at inactive genes, intergenic regions and in heterochromatin. KAT7 and H3K14ac were not required for the continued transcription of genes that were actively transcribed at the time of loss of KAT7, but indispensable for the activation of repressed genes. The absence of KAT7 abrogated neural stem cell plasticity, diverse differentiation pathways and cerebral cortex development. Reexpression of KAT7 restored stem cell developmental potential. Overexpression of KAT7 enhanced neuron and oligodendrocyte differentiation. Our data suggest that KAT7 prepares chromatin for transcriptional activation and is a prerequisite for gene activation.

Project description:While cellular energy metabolism regulates tissue regeneration, it remains as a challenge with its limited understanding of activation by engineered scaffolds to regenerate tissue or organ for therapeutic purpose. This study presents a biosynthesized poly(3-hydroxybutyrate-co-4-hydroxybutyrate) [abbreviated as P(3HB-co-4HB)] and its major degradation product, 3-hydroxybutyrate (3HB), functioning as an endogenous bioenergetic molecule to facilitate bone regeneration and promote cellular anabolism via generations of adenosine triphosphate (ATP) and citrate that enhance the progression of human bone marrow mesenchymal stem cells (hBMSCs) towards osteoblastogenesis. Our studies demonstrate that 3HB not only significantly enhances in vitro ATP generation to elevate mitochondrial membrane potential (ΔΨm) and capillary-like tube formation, but also increases the content of intermediate metabolite, namely, citrate, in tricarboxylic acid (TCA) cycle, and ultimately promotes the formation of citrate-containing apatite during osteogenesis of hBMSCs. Furthermore, 3HB administration increases the bone mass in rats with ovariectomy (OVX)-induced osteoporosis. Results also show that the P(3HB-co-4HB) scaffold significantly enhances long-term induced bone repair in a rat model with critical-sized calvarial defects, compared to the commercialized available poly-L-lactic acid (PLLA) scaffold. Collectively, these findings uncover a previously undefined role of 3HB in promoting osteogenic differentiation of hBMSCs and highlight that the P(3HB-co-4HB) scaffold functions as a metabolically activated energetic material for bone regeneration.

Project description:The calvarial bones of the infant skull are linked by transient fibrous joints known as sutures and fontanelles, which are essential for skull compression during birth and expansion during postnatal brain growth. Genetic conditions caused by pathogenic variants in FGFR2, such as Apert, Pfeiffer, Crouzon syndromes, result in calvarial deformities due to premature suture fusion and a persistently open anterior fontanelle (AF). In this study we investigated how Fgfr2 regulates AF closure by leveraging mouse genetics and single-cell transcriptomics. We find that AF cells, marked by the tendon/ligament factor SCX, are spatially organized into ecto- and endocranial domains that selectively differentiate into ligament, bone, and cartilage to form the posterior frontal suture. We show that AF cell differentiation is non-autonomously regulated by FGFR2 signaling in osteogenic front cells of the frontal bones, which regulate WNT signaling in neighboring AF cells by expressing the secreted WNT inhibitor Wif1. Upon loss of Fgfr2, Wif1 expression is downregulated, and AF cells fail to form the posterior frontal suture. This study identifies an FGF-WNT signaling circuit that that directs suture formation within the AF during postnatal development.

Project description:Zinc is an indispensable micronutrient for optimal physiological functions, and zinc deficiency has been implicated in the pathogenesis of various human diseases. One potential mechanism underlying such pathogenic effects is the alteration of gene expression caused by zinc deficiency; however, the details of this process remain largely unexplored. Here, we show that during zinc deficiency, the histone acetyltransferase KAT7 loses its enzymatic activity, leading to the attenuated acetylation of histone H3 at Lys14 (H3K14ac) at enhancer regions. Physiologically, the decrease in H3K14ac leads to the upregulation of the expression of ZIP10, a plasma membrane-localized zinc transporter, thereby facilitating the import of extracellular zinc to maintain cellular zinc homeostasis. Moreover, prolonged zinc deficiency in mice induced by a zinc-deficient diet or high-fat diet, accompanied by decreased H3K14ac levels in the liver, upregulated the expression of genes associated with intracellular lipid droplet formation, leading to the accumulation of lipids within liver tissue. Our findings demonstrate that cells respond to zinc deficiency by converting it into an epigenetic signal that drives physiological or pathophysiological biological processes.