Project description:Cells resident in tissues must be resilient to the physical demands of their surroundings. Our current understanding of cellular mechano-signalling is largely based on static systems, but these models do not reproduce the dynamic nature of living tissue. Here, we examined the time-resolved response of primary human mesenchymal stem cells (hMSCs) to periods of cyclic tensile strain (CTS). We observed parallels between morphological changes following low-intensity strain (1 hour, 4% CTS at 1 Hz) and responses to increased substrate stiffness. However, as the strain regime was intensified (CTS at ≥ 2 Hz), we characterised a broad, structured and reversible protein-level response, even as transcription was apparently shut down. Regulation of the linker of nucleo- and cytoskeleton (LINC) complex proteins, and specifically of SUN domain-containing protein 2 (SUN2), was found to decouple mechano-transmission within the cell and hence isolate the nucleus from cellular deformation.

Project description:Cells resident in tissues must be resilient to the physical demands of their surroundings. Our current understanding of cellular mechano-signalling is largely based on static systems, but these models do not reproduce the dynamic nature of living tissue. Here, we examined the time-resolved response of primary human mesenchymal stem cells (hMSCs) to periods of cyclic tensile strain (CTS). We observed parallels between morphological changes following low-intensity strain (1 hour, 4% CTS at 1 Hz) and responses to increased substrate stiffness. However, as the strain regime was intensified (CTS at ≥ 2 Hz), we characterised a broad, structured and reversible protein-level response, even as transcription was apparently shut down. Regulation of the linker of nucleo- and cytoskeleton (LINC) complex proteins, and specifically of SUN domain-containing protein 2 (SUN2), was found to decouple mechano-transmission within the cell and hence isolate the nucleus from cellular deformation.

Project description:Cells resident in tissues must be resilient to the physical demands of their surroundings. Our current understanding of cellular mechano-signalling is largely based on static systems, but these models do not reproduce the dynamic nature of living tissue. Here, we examined the time-resolved response of primary human mesenchymal stem cells (hMSCs) to periods of cyclic tensile strain (CTS). We observed parallels between morphological changes following low-intensity strain (1 hour, 4% CTS at 1 Hz) and responses to increased substrate stiffness. However, as the strain regime was intensified (CTS at ≥ 2 Hz), we characterised a broad, structured and reversible protein-level response, even as transcription was apparently shut down. Regulation of the linker of nucleo- and cytoskeleton (LINC) complex proteins, and specifically of SUN domain-containing protein 2 (SUN2), was found to decouple mechano-transmission within the cell and hence isolate the nucleus from cellular deformation.

Project description:Cells resident in tissues must be resilient to the physical demands of their surroundings. Our current understanding of cellular mechano-signalling is largely based on static systems, but these models do not reproduce the dynamic nature of living tissue. Here, we examined the time-resolved response of primary human mesenchymal stem cells (hMSCs) to periods of cyclic tensile strain (CTS). We observed parallels between morphological changes following low-intensity strain (1 hour, 4% CTS at 1 Hz) and responses to increased substrate stiffness. However, as the strain regime was intensified (CTS at ≥ 2 Hz), we characterised a broad, structured and reversible protein-level response, even as transcription was apparently shut down. Regulation of the linker of nucleo- and cytoskeleton (LINC) complex proteins, and specifically of SUN domain-containing protein 2 (SUN2), was found to decouple mechano-transmission within the cell and hence isolate the nucleus from cellular deformation.

Project description:The process of commercial catching, transport and slaughter (CTS) is known to be an acute stressful event in broiler chickens. Corticosteroid concentrations increase, impacting measures of IGF-1, growth hormone and metabolites of the immune system from blood plasma samples. We used ARK-Genomics chicken 20K oligo array, a two channel DNA microarray, to investigate the significantly differentially expressed genes in the livers of chickens during CTS. We investigate the differences of gene expression profiles in hepatic tissues between control birds (n=10) and birds experiencing CTS (n=10) using an ARK-Genomics chicken 20K oligo array, a two channel DNA array (http://www.ark-genomics.orgmicroarray) with full dye swap.

Project description:Understanding how cells respond to and cope with high levels of mechanical stress is important to gain a better understanding of mechano-biology, both in health and disease. The experiment was designed to assess the total mRNA levels in mechanically stimulated cells and was used, in conjunction with mass spectrometry data, to gain an insight into the systemic response to high-intensity mechanical strain. Here, total RNA was extracted from human mesenchymal stem cells (n=6) following 1 hour of cyclic tensile strain (2.6 – 6.2% strain, 5.0 Hz) using a Flexcell Tension Plus device. RNA from unstrained cells was used as control. The protein coding RNAs were then sequenced with Illumina HiSeq technology.

Project description:Analysis of the effect of electrical field stimulation frequency at the gene expression level. Electrical stimulation has been shown to mature nascent cardiomyocytes and alter their beating properties. The purpose of the array was to identify potential mediators of these effects. Total RNA was isolated from cardiomyocytes subjected to 0.5 Hz, 1 Hz, or 2 Hz continuous electrical stimulation for 7 days, compared to an unstimulated control. Three samples from each group were analyzed

Project description:The potential health hazard of exposures to electromagnetic fields (EMF) continues to cause much public concern. However, the biological and health effects of exposures to EMF remain controversial and their biophysical mechanisms are unclear. In the present study, we used Saccharomyces cerevisiae to identify genes responding to extremely low frequency magnetic fields (ELF-MF) and to radiofrequency (RF) EMF exposures. The expression of genes was analyzed by microarray screening and confirmed by real-time reverse transcription -polymerase chain reaction. In confirmation experiments, we found that there was no statistically significant change in three of the ELF-MF responsive candidate genes (P>0.05). On the other hand, out of the forty genes that responded to RF-EMF, the confirmation experiments found that only five were affected: structural maintenance of chromosomes 3-gene (SMC3), aquaporin 2 –gene (AQY2), halotolerance protein 9 –gene (HAL9), yet another kinase 1 -gene (YAK1) and one of unknown function gene (open reading frame: YJL171C) (P<0.05). Overall, this study has demonstrated that the yeast cells did not respond to 50 Hz ELF-MF and that the response to RF-EMF is limited to only five genes. The biological consequences of the observed gene expression changes induced by RF-EMF await further investigation. The yeast cells were exposed to 0.4 mT 50 Hz ELF-MF or 1800 MHz RF-EMF at a specific absorption rate of 3.5 W/kg for 6 hours.

Project description:To assess if human induced pluripotent stem cell-derived mesenchymal stem cells (hiPSC-MSCs) could be induce to acquire dermal papilla (DP) properties (especially hair inductive capacity), hiPSCs were initially programmed in serum-free MSC medium with FGF, TGFbeta and PDGF. Subsequently, hiMSCs were exposed to retinoic acid and activators of WNT, BMP and FGF signaling pathways. Global gene expression profiles were compared among primarily cultured human DP cells, hiPSC-MSCs before and after induction. Human dermal papillae were microdissected and cultured from different donors. Induction from hiPSCs to MSCs and subsequent sorting of CD271+CD90+ subpopulation and thier induction to DP was performed using WD39 hiPSC lines in two independent experimentations to generate hiPSC-MSC-1,hiPSC-MSC-2 ipDPSC-1 and ipDPSC-2. Funding: The Human Stem Cells Informatization Project of the Ministry of Health, Labour and Welfare, Japan

Project description:Type of experiment: <br> Our experiments examine gene expression profiles from untreated and mechanical stretching NIH 3T3 cells to gain new insights about the molecular and genetic basis of effect of mechanical stress. <br><br> Experimental factors: <br> We compared differences in gene expression profiles between 0.25% mechanical strain and control factor for NIH 3T3 cells. <br><br> The number of hybridizations performed in the experiment: <br> A total of 4 hybridizations were performed on Agilent One-color microarray platform. <br><br> Number of replicates (Biological or Technical)<br> 3 biological replicates for treated condition <br><br> Hybridization design: <br> All treated NIH 3T3 cells sample RNAs were hybridized against a pooling control RNA sample (see above). Cells were cultured in a humidifier incubator at 37 0C and 5% CO2. After cells were confluent, these cells were subjected to cyclic sinusoidal strain at 0.25 Hz for 60 minutes at a maximum membrane indentation of 1 mm., equal to 0.25% strain. Strain experiments were carried out in a humidified incubator with 5% CO2 at 37°C. Control cells were treated identical, however, not exposed to mechanical stress.