Project description:We hypothesize that the combination of mechanical loading with hypoxia culture and TGF-β3 growth factor withdrawal will promote stable, non-hypertrophic chondrogenesis of hBM-MSC embedded in an HA-hydrogel. To this end, we first assessed static hypoxia culture with growth factor withdrawal against static normoxia (20% O2) culture at the global transcriptome and tissue matrix level. We then assess two modalities of mechanical loading (dynamic compression, DC and cyclic hydrostatic pressure, CHP) with growth factor withdrawal against static culture, all under hypoxia. Results showed that Mechanical stimulation and TGF-β3 withdrawal under hypoxia promoted a strong chondrogenic and non-hypertrophic phenotype of hBM-MSC.

Project description:The epigenetic roles in trigeminal neuralgia (TN) still remain unclear. H3K9ac alteration in neuralgia is obscure and controversy. In this study, we established TN rat model via chronic compression, and further treated with 100 mg/kg/d carbamazepine (CBZ). RNA-seq were conducted to investigate the transcriptional profilings in control, TN and TN+CBZ.

Project description:The epigenetic roles in trigeminal neuralgia (TN) still remain unclear. H3K9ac alteration in neuralgia is obscure and controversy. In this study, we established TN rat model via chronic compression, and further treated with 100 mg/kg/d carbamazepine (CBZ). ChIP-seq were conducted to investigate the genome-wide distribution of H3K9ac and HDAC3 in control, TN and TN+CBZ.

Project description:Physical constraints like compression influence cancer cell invasion and transcriptional dynamics in various tumors. Liver cancer is characterized by the rapid proliferation of tumor cells within a densely packed tissue matrix, subjecting the cancer cells to crowding and compression. The highly dysregulated mechanical environment highlights the need to elucidate the broader impact of compression on liver cancer development and evolution. In this study, we investigated and described a unique adaptive response of liver cells to prolonged compression. Liver cells presented significant transcriptional changes due to compression, including the loss of liver-specific markers and enrichment of epithelial-to-mesenchymal transition genes. Compression elevated Rac1 activity, which promoted cellular protrusions and YAP nuclear translocation and maintained cell viability under mechanical stress. Furthermore, compression disrupted intracellular calcium signaling, leading to resistance to apoptosis. Counteracting the effects of compression by inhibiting Rac1 or manipulating intracellular calcium facilitated death of compression-adapted cells. This study highlights compression as a critical biophysical signal in the tissue microenvironment that can induce cell state transitions and disease-driving phenotypes in the liver.

Project description:Human induced neurons and primary murine glia were subjected to a controlled in vitro model of mechanical compression to determine how solid stress—similar to forces present in glioblastoma—directly alters neuronal and glial transcriptional programs. RNA sequencing was performed after 24 hours of compression, with species-specific alignment enabling independent analysis of neuronal and glial responses. Compressed human neurons showed strong activation of hypoxia-responsive metabolic genes, pro-inflammatory signaling pathways, and intrinsic apoptotic programs. Murine glia exhibited parallel induction of hypoxia and apoptotic pathways, accompanied by robust NF-κB/AP-1-driven inflammatory cytokine expression characteristic of astrocytic and microglial activation. These data define the conserved transcriptional responses by which neurons and glia detect and respond to solid stress, providing a resource for understanding mechanotransduction and neuroinflammatory signaling in diseases characterized by mass effect, including glioblastoma.

Project description:To describe the long non-coding RNA (lncRNA) expression profile of cementoblasts under mechanical compression

Project description:We discovered mechanical compression is able to bring activated MuSCs back to their quiescent stem cell state.

Project description:Osteoarthritis is a multifactorial disease in which not only physical tissue damage but also persistent inflammation is thought to be one of the main causes. The qualitative differences between mechanical and inflammatory cytokine stimulation in the production of OA-related molecules are not fully understood, and the biological events that occur in cells when the two stimuli are applied simultaneously remain unresolved. 　Articular cartilage tissue is formed by relatively sparse cells surrounded by a rich extracellular matrix composed mainly of collagen and proteoglycans, and three-dimensional culture using hydrogels such as collagen gel has been frequently used to reproduce chondrocytes that are three-dimensionally bound to the surrounding extracellular matrix and to evaluate physiological responses. 　In this study, we aimed to compare the responses of 3D cultured articular chondrocytes to mechanical stimuli and inflammatory cytokine stimuli, to analyze the responses to the two stimuli when they occur simultaneously, and to gain insight into the molecular mechanisms involved. Three-dimensional culture of human articular chondrocytes was performed using a stiff atelocollagen sponge and atelocollagen gel, and analysis focused on changes in gene expression due to cyclic compression stimulation.

Project description:Immortalized human astrocytes were subjected to a controlled in vitro model of chronic mechanical compression to investigate how solid stress—similar to that exerted by growing brain tumors—directly affects astrocyte transcriptional programs. RNA sequencing was performed after 24 hours of compression to measure sustained mechanotransductive responses. Compressed astrocytes showed robust induction of AP-1-associated immediate-early genes and activation of NF-κB–dependent inflammatory pathways. These data define the transcriptional signatures by which human astrocytes detect and respond to mechanical stress, providing a resource for understanding mechanobiology and neuroinflammatory signaling in diseases featuring mass effect, including glioblastoma and traumatic brain injury.

Project description:Mechanical forces are essential for organ function, but excessive or dysregulated forces can promote pathologic conditions. In asthma, bronchoconstriction narrows the airway, compressing the airway epithelium and activating mechanotransduction, yet key regulators of mechanotransduction remain unclear. Here we show that Hic-5, a focal adhesion adaptor, is a key regulator of epithelial mechanotransduction. In human airway epithelial cells at air–liquid interface exposed to mechanical compression that mimics bronchoconstriction, we find that compression induces Hic-5 expression in airway basal cells. We further validated these in vitro findings by reanalyzing single-cell RNA-seq data from patients with asthma undergoing bronchoconstriction after allergen challenge, which revealed increased Hic-5 expression in airway basal cells. Hic-5 knockdown in human airway epithelial cells markedly attenuates mechanoresponses to compression, including stress fiber formation, differential gene expression, and increased secretion of endothelin-1 (ET-1). Through secretion of ET-1, a potent bronchoconstrictor, Hic-5 drives epithelial mechanotransduction and promotes a feed-forward cycle of bronchoconstriction, thereby highlighting dysregulated mechanical forces as active drivers of human disease.