Integrin-αvß3 regulates thrombopoietin-mediated maintenance of hematopoietic stem cells.

Throughout life, one's blood supply depends on sustained division of hematopoietic stem cells (HSCs) for self-renewal and differentiation. Within the bone marrow microenvironment, an adhesion-dependent or -independent niche system regulates HSC function. Here we show that a novel adhesion-dependent mechanism via integrin-ß3 signaling contributes to HSC maintenance. Specific ligation of ß3-integrin on HSCs using an antibody or extracellular matrix protein prevented loss of long-term repopulating (LTR) activity during ex vivo culture. The actions required activation of αvß3-integrin "inside-out" signaling, which is dependent on thrombopoietin (TPO), an essential cytokine for activation of dormant HSCs. Subsequent "outside-in" signaling via phosphorylation of Tyr747 in the ß3-subunit cytoplasmic domain was indispensable for TPO-dependent, but not stem cell factor-dependent, LTR activity in HSCs in vivo. This was accompanied with enhanced expression of Vps72, Mll1, and Runx1, 3 factors known to be critical for maintaining HSC activity. Thus, our findings demonstrate a mechanistic link between ß3-integrin and TPO in HSCs, which may contribute to maintenance of LTR activity in vivo as well as during ex vivo culture.

Structural characterization of bioengineered human corneal endothelial cell sheets fabricated on temperature-responsive culture dishes.

For the purpose of corneal regenerative medicine, we fabricated human corneal endothelial cell sheets on temperature-responsive dishes, which could be non-invasively harvested as intact, transplantable sheets by simply reducing the culture temperature. Cells demonstrated hexagonal cell shape with numerous microvilli and cilia, and also exhibited abundant cytoplasmic organelles similar to these cells in vivo. Immunofluorescence for type IV collagen and fibronectin revealed that abundant extracellular matrix (ECM) was deposited on the basal surface throughout culture, and the deposited ECM was harvested along with the cell sheets by reducing culture temperature to 20 degrees C. Faint ECM remnants were observed on the dish surfaces after cell sheet detachment. Immunofluorescence for ZO-1 showed that tight junctions were established between cells, and immunoblotting indicated that intact ZO-1 was maintained during cell sheet harvest, while conventional proteolytic cell harvest methods resulted in the degradation of ZO-1. These results suggest that these transplantable corneal endothelial cell sheets can be applied to treat patients with damaged corneas.

Thermally responsive polymer-grafted surfaces facilitate patterned cell seeding and co-culture.

Tissue engineering constructs that effectively duplicate natural tissue function must also maintain tissue architectural and organization features, particularly the integration of multiple cell types preserving distinct, integrated phenotypes. Cell-cell communication and biochemical cross-talk have been shown to be essential for the maintenance of differentiated cell functions in tissues and organs. Current limitations of cell-culture hinder progress in understanding the features and dynamics of heterotypic cell communication pathways critical to developing more sophisticated or effective tissue-engineered devices. We describe a method to conveniently electron-beam pattern cell culture surfaces with thermo-responsive polymer chemistry that exploits changes in cell-polymer adhesive interactions over a temperature window amenable for high-throughput cell culture. Cells seeded on these patterned surfaces at 20 degrees C adhere only to surface areas lacking thermo-responsive grafting chemistry; grafted domains at 20 degrees C are hydrophilic and non-cell adhesive. The culture temperature is then increased to 37 degrees C collapsing the hydrated grafted chemistry. A second cell type is added to the culture and adheres only to these exposed relatively hydrophobic grafted patterns. Both cell types can then be effectively co-cultured at 37 degrees C under multiple conditions. Long-term cell pattern fidelity and differentiated cell functions characteristic of each co-planar cell type are observed. This method is simple and has few limitations, compared with other existing co-culture methods.