Mechanically induced formation and maturation of 3D-matrix adhesions (3DMAs) in human mesenchymal stem cells.

Mechanical signal is important for regulating stem cell fate, but the molecular mechanisms involved are unclear. Cell-matrix adhesions are important molecular mechanosensors that their formation and maturation are force-dependent processes. However, most studies focused on the role of cell contractility or substrate stiffness in these processes. How external mechanical force stimulates the formation and maturation of cell-matrix adhesions is largely unknown. Here, by using human mesenchymal stem cells (hMSCs)-collagen microtissues as a 3D model, we found that upon short-term dynamic compression, integrin αV binding, focal adhesion formation, and subsequent FAK activation, are stimulated. This compression-stimulated FAK signaling also leads to YAP activation, suggesting crosstalk between integrin-based signaling and mechanosensing. More importantly, long-term compression induces maturation of α5-integrin based adhesions to form long, slender 3D-matrix adhesions (3DMAs), which are distinct from 2D focal adhesions in composition and morphology and previously found only in cell-derived matrices and native tissues. Mechanical preconditioning hMSCs with long-term compression loading induces the formation of mature integrin α5-dependent 3DMAs and potentiates their osteogenesis. Collectively, this work shows that active mechanical stimulation can modulate cell-matrix interactions significantly at the cell-material interfaces in a dynamic manner, and affects cell fate decisions, demonstrating the significance of loading-based functional tissue engineering.

Collagen microencapsulation recapitulates mesenchymal condensation and potentiates chondrogenesis of human mesenchymal stem cells - A matrix-driven in vitro model of early skeletogenesis.

Mesenchymal condensation is a critical transitional stage that precedes cartilage or bone formation. A microencapsulation technique was previously established to entrap mesenchymal stem cells (MSC) in nanofibrous collagen meshwork. We hypothesize that collagen microencapsulation of MSCs mimics the mesenchymal cell condensation process. Specifically, human MSCs at different concentrations were microencapsulated in collagen for different time points before evaluation for early skeletogenesis markers. A transient upregulation of mesenchymal condensation markers including peanut agglutinin, fibronectin, integrins α5 and αv, an enhanced nuclear localization of SOX9 and binding interactions with COL2A1, and other changes in chondrogenic, hypertropic and osteogenic marker were demonstrated. Collagen microencapsulation upregulated both the chondrogenic and the osteogenic transcription factors and the encapsulated hMSCs hold the potential to differentiate towards both chondrogenic and osteogenic lineages. We also hypothesize that collagen microencapsulation potentiates MSC chondrogenesis. Particularly, chondrogenic differentiation of hMSCs were induced at different time post-encapsulation before evaluation for chondrogenesis outcomes. Sustained SOX9, ACAN and COL2A1 expression were noted and the timing to induce supplement chondro-inductive factors matters. This study reports an extracellular matrix-based in vitro model of mesenchymal condensation, an early stage in skeletogenesis, contributing to rationalizing development-inspired tissue engineering.

Common carp metallothionein-1 gene: cDNA cloning, gene structure and expression studies.

Metallothionein-1 (MT-1) cDNA clones were isolated from a common carp (Cyprinus carpio) uninduced hepatopancreas cDNA library. Northern blot assay using the common carp (cc) MT-1 cDNA as a probe showed high fold induction of ccMT mRNA levels in the intestine and kidney following exposure to Cd2+ and Zn2+. Using polymerase chain reaction (PCR), primers designed from the cDNA sequences allowed the isolation of ccMT-1 gene fragments including the 5'-flanking region. The 600 bp 5'-flanking region of ccMT-1 gene carries four putative metal regulatory regions, one AP1, two SP1, one c-Jun site, and a TATA box. The 5'-flanking region of the ccMT-1 gene obtained was a functional promoter responding to the administration of various metal ions as well as hydrogen peroxide (H2O2) and lipopolysaccharide (LPS). When tested in primary cultures of cc hepatocytes, Zn2+ had the highest fold (20 times) induction of the 600 bp cloned ccMT-1 gene promoter, followed by Cu2+, Hg2+, Ni2+ and Pb2+ (4-5-fold inductions); H2O2 and LPS had a 6-7-fold induction. In conclusion, the ccMT-1 is a constitutively expressed MT and its gene promoter is inducible by various metal ions and chemical agents.