Project description:To investigate the relevant biological mechanism involved in the inhibition of 143B cells when cultured with injectable magnetothermal bioactive systems (IMBSs) under alternating magnetic field (AMF), the high-throughput RNA sequencing was conducted.

Project description:14 ChIP-Seq datasets of H3K27ac in human pancreatic islets from 14 donors, where islets were treated in high (11mM) glucose conditions. Samples IDs HI-129, HI-130, HI-131, HI-132, HI-135, HI-137 and HI-152 were also cultured in low glucose conditions.

Project description:Polymethoxylated flavones (PMFs) are a group of natural compounds known to display a wide array of beneficial effects to promote physiological fitness. Recent studies revealed circadian clocks as an important cellular mechanism mediating the preventive efficacy of the major PMF Nobiletin against metabolic disorders. Sudachitin is a PMF enriched in Citrus sudachi, and its functions and mechanism of action are poorly understood. Using circadian reporter cells, we showed that Sudachitin modulated circadian amplitude and period of Bmal1 promoter-driven reporter rhythms, and real-time qPCR analysis showed that Sudachitin altered expression of core clock genes, notably Bmal1, at both transcript and protein levels. Mass-spec analysis revealed systemic exposure in vivo. In mice fed with high-fat diet with or without Sudachitin, we observed increased nighttime activity and daytime sleep, accompanied by significant metabolic improvements in a circadian time-dependent manner, including respiratory quotient, blood lipid and glucose profiles and liver physiology. Focusing on the liver, RNA-sequencing and metabolomic analyses revealed prevalent diurnal remodeling in both gene expression and metabolite accumulation. Taken together, our study elucidates Sudachitin as a new clock-modulating PMF with hepatic remodeling functions to improve systemic metabolic homeostasis, and highlights the circadian clock as a fundamental mechanism to safeguard physiological well-being.

Project description:Primary myelofibrosis (PMF) together with polycythemia vera (PV) and essential thrombocythemia (ET) belongs to the classic Philadelphia-negative myeloproliferative neoplasms (MPNs). PV and ET can evolve to secondary myelofibrosis (SMF) giving rise to post-PV (PPV) and post-ET (PET) myelofibrosis (MF). PMF and SMF patients are currently managed in the same way and prediction of survival is based on the same prognostic models, even if it has been demonstrated that they can’t accurately distinguish different risk categories in SMF. In the last few years interest grew concerning the ability of gene expression profiling (GEP) to provide valuable prognostic information for clinical decision making. To construct a molecular signature that can predict survival according to gene expression we studied GEP of granulocytes from 114 MF patients, including 35 prefibrotic/early PMF (Pre-PMF), 37 overt PMF (Overt-PMF), 26 PET and 16 PPV, using microarray platform.

Project description:To explore the effect of magnetic mechanical forces mediated by magnetic nanoparticles on the repair phenotype of Schwann cells in a gradient magnetic field environment, we co-cultured magnetic nanoparticles with RSC96 cells.

Project description:Using diamagnetic levitation, we have exposed A. thaliana in vitro callus cultures to five environments with different levels of effective gravity (from levitation i.e. simulated mg* to 2g*) and magnetic fields (10.1 to 16.5 Tesla) and we have compared the results with those of similar experiments done in a Random Position Machine (simulated micro g) and a Large Diameter Centrifuge (2g) free of high magnetic fields. Microarray analysis indicates that there are changes in overall gene expression of the cultured cells exposed to these unusual environments but also that gravitational and magnetic field produce synergic variations in the steady state of the transcriptional profile of A. thaliana. Significant changes in the expression of structural, abiotic stress and secondary metabolism genes were observed into the magnet field. These results confirm that the strong magnetic field, both at micro g* or 2g*, has a significant effect on the expression of these genes but subtle gravitational effects are still observable. These subtle responses to microgravity environments are opposite to the ones observed in a hypergravity one.

Project description:Using diamagnetic levitation, we have exposed A. thaliana in vitro callus cultures to five environments with different levels of effective gravity (from levitation i.e. simulated mg* to 2g*) and magnetic fields (10.1 to 16.5 Tesla) and we have compared the results with those of similar experiments done in a Random Position Machine (simulated micro g) and a Large Diameter Centrifuge (2g) free of high magnetic fields. Microarray analysis indicates that there are changes in overall gene expression of the cultured cells exposed to these unusual environments but also that gravitational and magnetic field produce synergic variations in the steady state of the transcriptional profile of A. thaliana. Significant changes in the expression of structural, abiotic stress and secondary metabolism genes were observed into the magnet field. These results confirm that the strong magnetic field, both at micro g* or 2g*, has a significant effect on the expression of these genes but subtle gravitational effects are still observable. These subtle responses to microgravity environments are opposite to the ones observed in a hypergravity one. seven-condition experiment, MM2D Arabidopsis culture callus control vs. Treatment (altered gravity simulation, GBF). Three GBF were used (LDC (2g) + control, RPM (mg) + control and Magnet (mg*, 0.1g*, 1g*, 1.9g*, 2g*) + control). Biological replicates: 3 replicates in all conditions and controls except 1.9g* (2 replicates)

Project description:Genome-wide transcriptional profiling shows that reducing gravity levels in the International Space Station (ISS) causes important alterations in Drosophila gene expression. However, simulation experiments on ground, without space constraints, show weaker effects than space environment. A global and integrative analysis using the M-bM-^@M-^\gene expression dynamics inspectorM-bM-^@M-^] (GEDI) self-organizing maps, reveals a subtle response of the transcriptome using different populations and microgravity and hypergravity simulation devices. These results suggest that, in addition to behavioural responses that can be detected also at the gene expression level, the transcriptome is finely tuned to normal gravity. The alteration of this constant parameter on Earth can have effects on gene expression that depends both on the environmental conditions and the ground based facility used to compensate the gravity vector. Alternative and commons effects of mechanical facilities, like the Random Positioning Machine and a centrifuge, and strong magnetic field ones, like a cryogenically cooled superconductive magnet, are discussed. We compare the effects over the gene expression profile of different gender/age Drosophila imagoes in 3-4 days-long experiments under altered gravity conditions into three GBF ("Ground Based Facilities" for micro/hyper- gravity simulation) using whole genome microarray platforms. Descriptions of different GBFs ("treatments"): LDC means "Large Diameter Centrifuge". Samples can be placed under three conditions: inside LDC (at certain g level), at the LDC rotational control and at external 1g control (outside the LDC). RPM means "Random Positioning Machine". Samples can be placed under two conditions: inside RPM (at nearly 0g, Microgravity level) and at external 1g control (outside the RPM). At the magnet, means INSIDE the Magnetic levitator (another GBF). Samples can be placed under four conditions: inside Magnet 0g* (at microgravity with magnetic field), inside Magnet at 1g* (internal control with magnetic field) or inside the magnet 2g* (at hypergravity with magnetic field) and at external 1g control (outside the magnet)

Project description:Primary myelofibrosis (PMF) is a clonal blood disorder linked to mutually exclusive mutations in JAK2, CALR, or MPL genes. To understand the epigenetic effects of these mutations, we analyzed DNA methylation (DNAm) profiles of PMF patients. Notably, no differences were found between JAK2 and CALR mutated cases, whereas MPL mutations showed distinct DNAm patterns. Further investigation in induced pluripotent stem cell (iPSC) models with JAK2 mutations revealed only a moderate link to PMF-related epigenetic changes, suggesting these alterations are not directly caused by the mutations. Additionally, PMF-associated epigenetic changes showed minimal correlation with allele burden and were largely evoked by changes in the cellular composition. When comparing PMF DNAm profiles with those from other myeloid malignancies, such as acute myeloid leukemia, juvenile myelomonocytic leukemia, and myelodysplastic syndrome, many overlapping changes were found, making it difficult to distinguish PMF based on individual CpGs. However, a PMF score created by combining five CpGs successfully differentiated PMF from other diseases in training and validation datasets. These findings demonstrate that PMF driver mutations do not directly evoke epigenetic changes. While PMF shares epigenetic changes with other myeloid malignancies, epigenetic signatures can effectively differentiate PMF from related diseases.

Project description:Primary myelofibrosis (PMF) is a clonal blood disorder linked to mutually exclusive mutations in JAK2, CALR, or MPL genes. To understand the epigenetic effects of these mutations, we analyzed DNA methylation (DNAm) profiles of PMF patients. Notably, no differences were found between JAK2 and CALR mutated cases, whereas MPL mutations showed distinct DNAm patterns. Further investigation in induced pluripotent stem cell (iPSC) models with JAK2 mutations revealed only a moderate link to PMF-related epigenetic changes, suggesting these alterations are not directly caused by the mutations. Additionally, PMF-associated epigenetic changes showed minimal correlation with allele burden and were largely evoked by changes in the cellular composition. When comparing PMF DNAm profiles with those from other myeloid malignancies, such as acute myeloid leukemia, juvenile myelomonocytic leukemia, and myelodysplastic syndrome, many overlapping changes were found, making it difficult to distinguish PMF based on individual CpGs. However, a PMF score created by combining five CpGs successfully differentiated PMF from other diseases in training and validation datasets. These findings demonstrate that PMF driver mutations do not directly evoke epigenetic changes. While PMF shares epigenetic changes with other myeloid malignancies, epigenetic signatures can effectively differentiate PMF from related diseases.