Investigating the nature of active forces in tissues reveals how contractile cells can form extensile monolayers.

Actomyosin machinery endows cells with contractility at a single-cell level. However, within a monolayer, cells can be contractile or extensile based on the direction of pushing or pulling forces exerted by their neighbours or on the substrate. It has been shown that a monolayer of fibroblasts behaves as a contractile system while epithelial or neural progentior monolayers behave as an extensile system. Through a combination of cell culture experiments and in silico modelling, we reveal the mechanism behind this switch in extensile to contractile as the weakening of intercellular contacts. This switch promotes the build-up of tension at the cell-substrate interface through an increase in actin stress fibres and traction forces. This is accompanied by mechanotransductive changes in vinculin and YAP activation. We further show that contractile and extensile differences in cell activity sort cells in mixtures, uncovering a generic mechanism for pattern formation during cell competition, and morphogenesis.

Desmosomal Junctions Govern Tissue Integrity and Actomyosin Contractility in Apoptotic Cell Extrusion.

During apoptosis, or programmed cell death, a dead cell could be expelled from the tissue by coordinated processes between the dying cell and its neighbors. Apoptotic cell extrusion is driven by actomyosin cable formation and its contraction and lamellipodial crawling of the neighboring cells [1-4]. Throughout cell extrusion, the mechanical coupling of epithelia needs to be maintained in order to preserve tissue homeostasis [1]. Although much is known about the regulation of adherens junctions (AJs) in apoptotic cell extrusion [4-7], the role and dynamics of desmosomal junctions (DJs) during this process remain poorly understood. Here, we show that DJs stay intact throughout and are crucial for cell extrusion. Pre-existing DJs between the apoptotic cell and neighboring cells remain intact, even during the formation of de novo DJs between non-dying cells, suggesting the neighboring cells possess two DJs in the middle of apoptotic cell extrusion. We further found that an actomyosin cable formed in the vicinity of DJs upon apoptosis and subsequently deviated from DJs during its constriction. Interestingly, the departure of the actomyosin cable from DJs coincided with the timing when DJs lost their straightness, suggesting a release of junctional tension at DJs and a mechanical coupling between DJs and actomyosin contractility. The depletion of desmoplakin resulted in defective contractility and an inability to form de novo DJs, leading to a failure of apoptotic cell extrusion. Our study provides a framework to explain how desmosomes play pivotal roles in maintaining epithelial sheet integrity during apoptotic cell extrusion.

Surface hydrophilicity of PLGA fibers governs in vitro mineralization and osteogenic differentiation.

Interfacial properties of biomaterials play an important role in governing their interaction with biological microenvironments. This work investigates the role of surface hydrophilicity of electrospun poly(lactide-co-glycolide) (PLGA) fibers in determining their biological response. For this, PLGA is blended with varying amounts of Pluronic®F-108 and electrospun to fabricate microfibers with varying surface hydrophilicity. The results of mineralization study in simulated body fluid (SBF) demonstrate a significant enhancement in mineralization with an increase in surface hydrophilicity. While presence of serum proteins in SBF reduces absolute mineral content, mineralization continues to be higher on samples with higher surface hydrophilicity. The results from in vitro cell culture studies demonstrate a marked improvement in mesenchymal stem cell-adhesion, elongation, proliferation, infiltration, osteogenic differentiation and matrix mineralization on hydrophilized fibers. Therefore, hydrophilized PLGA fibers are advantageous both in terms of mineralization and elicitation of favorable cell response. Since most of the polymeric materials being used in orthopedics are hydrophobic in nature, the results from this study have strong implications in the future design of interfaces of such hydrophobic materials. In addition, the work proposes a facile method for the modification of electrospun fibers of hydrophobic polymers by blending with a poloxamer for improved bone tissue regeneration.