Project description:Adipose derived stem cells (ASCs) were preconditioned with endothelial differentiation medium (EDM) for four days and then incubated in endothelial basal medium (EBM) supplemented with 1% microvesicle (MV)-free FBS for two days. The conditioned medium was harvested for MV isolation. The small RNA extracted from the MVs was used for microRNA array. qPCR gene expression profiling; Two equal-amount small RNA samples were from two independent experiments.

Project description:Recently, mesenchymal stem cells-derived microvesicles (MMVs) attract much attention as a strategy of cell-free treatment. In our study, we found that MMVs could improve the organ dysfunction during sepsis. To investigate the mechanism, we harvested MMVs from mesenchymal stem cells to perform proteomic analysis, and chondrocyte-derived microvesicles (CMVs) were used as a negative control, and PGC-1α overexpressed-MMVs were used as a positive control. A total of 5411 proteins were identified in this study, and differentially expressed (DE) proteins were further identified with a cut-off of absolute fold change >1.5 and a significance p-value <0.05. Compared with CMV group, 321 proteins were upregulated and 209 proteins were downregulated in MMVs. This study illustrated the differences between MMVs and CMVs, and provided a sight for investigating the protective effect of MMVs.

Project description:Evaluation of microRNA expression profile of microvesicles (MVs) derived from endothelial progenitor cells (EPCs) cultured in different oxygen concentrations (normoxic/hypoxic conditions)

Project description:Membrane vesicles (MVs) are produced by species across all domains of life and have diverse physiological functions and promising applications. While the mechanisms for vesiculation in Gram-negative bacteria are well-established, the genetic determinant and regulation of MVs biogenesis in Gram-positive bacteria remain still largely unknown. Here, we demonstrate that a Q225P substitution in the alternative sigma factor SigB greatly triggers MVs production in Staphylococcus aureus strain Newman by directly repressing expression of alkaline shock protein 23, wherein the Q225P mutation hinders the specific binding of SigB to the asp23 promoter. Isogenic deletion of asp23 consistently promotes MVs formation in Newman, highlighting the critical role of both sigB and asp23 in modulating S. aureus vesiculation. While bacterial growth and cytoplasmic membrane fluidity do not be impaired, mutation of asp23 elicits a weakened cell wall and enhanced autolysis that potentially involved in LrgAB-controlled hydrolases and PSMα-mediated activities, which ultimately leads to hypervesiculation in Newman. Furthermore, TEM and proteomic analysis suggest nearly identical morphology and composition, but virulence-associated factors are significantly enriched in MVs upon asp23 deletion. Overall, this study reveals novel genetic determinants and cues underlying S. aureus vesiculation, advancing the understanding of the physiology of MVs biogenesis in Gram-positive bacteria.

Project description:PBMC were exposed to Cell Free Nucleic Acids (CFNA) extracted from blood products eligible for transfusion: Red Blood Cell units (RBC), Fresh Frozen Plasma units (FFP). PBMC alone exposed to the same extract from PBS were used as a control (PBMC+control). PBMC alone were also used as control. The used positive control was PBMC exposed to Lipopolysaccharide (LPS)

Project description:Regular blood transfusion is the cornerstone of care for patients with red blood cell (RBC) disorders such as thalassemia or sickle cell disease. With repeated transfusion, alloimmunisation often occurs due to incompatibility at the level of minor blood group antigens. We use CRISPR-mediated genome editing of an immortalised human erythroblast cell line (BEL-A) to generate multiple enucleation competent cell lines deficient in individual blood groups. Edits are combined to generate a single cell line deficient in multiple antigens responsible for the most common transfusion incompatibilities: ABO (Bombay phenotype), Rh (Rhnull), Kell (K0), Duffy (Duffynull), GPB (S- s- U-). These cells can be differentiated to generate deformable reticulocytes, illustrating the capacity for coexistence of multiple rare blood group antigen null phenotypes. This study provides the first proof-of-principle demonstration of combinatorial CRISPR-mediated blood group gene editing to generate customisable or multi-compatible RBCs for diagnostic reagents or recipients with complicated matching requirements.

Project description:Cardiovascular events are the leading cause of death in patients with JAK2V617F myeloproliferative neoplasms. Their mechanisms are poorly understood. To investigate the role of microvesicles in these events, we performed a proteomic analysis of microvesicles derived from red blood cells from mice with a myeloproliferative neoplasms (Jak2V617F Flex/WT ;VE-cadherin-Cre) vs. littermate controls.

Project description:A proteomic analysis utilizing UDMSE was performed on exosomes and microvesicle fractions isolated from human urine. more than 2 unique peptides containing proteins were quantified (586). exosomes and microvesicles were compared to each other in a quantitative manner.

Project description:Identification of RNA Markers in Red Blood Cells for Doping Control in Autologous Blood Transfusion

Project description:Multipotent and pluripotent stem cells have significant potential as sources for cell replacement therapies. However, the low yield and quality of in vitro differentiated cells produced from various stem cell sources presents a significant limitation for therapeutic applications. The most mature use of these stem cell products is in the field of transfusion medicine, where stem cell-derived red blood cells (RBCs) have clinically-proven potential as alternative transfusion products. To improve upon current approaches for RBC production, we used insight from both common and rare human genetic variation of blood counts to focus on the SH2B3 gene. By producing loss of function of SH2B3 using targeted knockdown and genome editing approaches in human hematopoietic stem and progenitor cells, as well as human pluripotent stem cells, we are able to significantly improve both the quality and yield of in vitro derived RBCs. We illustrate how insight from human genetic variation can assist in the development of broadly applicable approaches that have tremendous value for regenerative medicine.