Differential Single Cell Responses of Embryonic Stem Cells Versus Embryoid Bodies to Gravity Mechanostimulation

Abstract: The forces generated by gravity have shaped life on Earth and impact gene expression and morphogenesis during early development. Conversely, disuse on Earth or during spaceflight, reduces normal mechanical loading of organisms, resulting in altered cell and tissue function. Although gravity mechanical loading in adult mammals is known to promote increased cell proliferation and differentiation, little is known about how distinct cell types respond to gravity mechanostimulation during early development. In this… Show more

“…An increase in external mechanical stress to 50 g /5kPa hydrostatic pressure for 1 h led to the activation of the transcription of population maintenance and angiogenesis genes in mESCs. At the same time, the expression of genes associated with multicellular development, mechanotransduction, and DNA repair increased in embryoid bodies [ 40 ]. Additionally, the application of additional shear stress to human embryonic stem cells hESC line H1 led to an increase in H2B histone acetylation and an increase in the nucleus as a result of cytoskeletal reorganization [ 41 ].…”

Single Cell in a Gravity Field

“…An increase in external mechanical stress to 50 g /5kPa hydrostatic pressure for 1 h led to the activation of the transcription of population maintenance and angiogenesis genes in mESCs. At the same time, the expression of genes associated with multicellular development, mechanotransduction, and DNA repair increased in embryoid bodies [ 40 ]. Additionally, the application of additional shear stress to human embryonic stem cells hESC line H1 led to an increase in H2B histone acetylation and an increase in the nucleus as a result of cytoskeletal reorganization [ 41 ].…”

Single Cell in a Gravity Field