Tropoelastin modulates systemic and local tissue responses to enhance wound healing.

Wound healing is facilitated by biomaterials-based grafts and substantially impacted by orchestrated inflammatory responses that are essential to the normal repair process. Tropoelastin (TE) based materials are known to shorten the period for wound repair but the mechanism of anti-inflammatory performance is not known. To explore this, we compared the performance of the gold standard Integra Dermal Regeneration Template (Integra), polyglycerol sebacate (PGS), and TE blended with PGS, in a murine full-thickness cutaneous wound healing study. Systemically, blending with TE favorably increased the F4/80+ macrophage population by day 7 in the spleen and contemporaneously induced elevated plasma levels of anti-inflammatory IL-10. In contrast, the PGS graft without TE prompted prolonged inflammation, as evidenced by splenomegaly and greater splenic granulocyte and monocyte fractions at day 14. Locally, the inclusion of TE in the graft led to increased anti-inflammatory M2 macrophages and CD4+T cells at the wound site, and a rise in Foxp3+ regulatory T cells in the wound bed by day 7. We conclude that the TE-incorporated skin graft delivers a pro-healing environment by modulating systemic and local tissue responses. STATEMENT OF SIGNIFICANCE: Tropoelastin (TE) has shown significant benefits in promoting the repair and regeneration of damaged human tissues. In this study, we show that TE promotes an anti-inflammatory environment that facilitates cutaneous wound healing. In a mouse model, we find that inserting a TE-containing material into a full-thickness wound results in defined, pro-healing local and systemic tissue responses. These findings advance our understanding of TE's restorative value in tissue engineering and regenerative medicine, and pave the way for clinical applications.

Characterization of Single-Protein Dynamics in Polymer-Cushioned Lipid Bilayers Derived from Cell Plasma Membranes.

Native cell-membrane-derived supported lipid bilayers (SLBs) are an emerging platform with broad applications ranging from fundamental research to next-generation biosensors. Central to the success of the platform is the proper accommodation of membrane proteins so that their dynamics and functions are preserved. Polymer cushions have been commonly employed to avoid direct contact between the bilayer membrane and the supporting substrate, and thus, the mobility of the transmembrane proteins is maintained. However, little is known about how the polymer cushion affects the absolute mobility of membrane molecules. Here, we characterized the dynamics of single membrane proteins in polymer-cushioned lipid bilayers derived from cell plasma membranes and investigated the effects of polymer length. Three membrane proteins with distinct structures, i.e., a GPI-anchored protein, single-pass transmembrane protein CD98 heavy chain, and seven-pass transmembrane protein SSTR3, were fused with green fluorescent protein (GFP), and their dynamics were measured by fluorescent single-molecule tracking. An automated data acquisition was implemented to study the effects of PEG polymer length on protein dynamics with large statistics. Our data showed that increasing the PEG polymer length (molecular weight from 1000 to 5000) enhanced the mobile fraction of the membrane proteins. Moreover, the diffusion coefficients of transmembrane proteins were augmented with the polymer length, whereas the diffusion coefficient of the GPI-anchored protein remained almost identical for different polymer lengths. Importantly, the diffusion coefficients of the three membrane proteins became identical (2.5 µm2/s approximately) for the cushioned membrane with the longest polymer length (molecular weight of 5000), indicating that at the microscopic length scale, the SLBs were fully suspended from the substrate by the polymer cushion. Transient confinements were observed for all three proteins, and increasing the polymer length reduced the tendency of transient confinement. The measured dynamics of membrane proteins were found to be nearly unchanged after the depletion of cholesterol, suggesting that the observed immobilization and transient confinement were not due to cholesterol-enriched membrane nanodomains (lipid rafts). Our single-molecule dynamics elucidate the biophysical properties of polymer-cushioned plasma membrane bilayers that are potentially useful for the future developments of membrane-based biosensors and analytical assays.