Abstract Introduction and aims Wound healing is a complex process essential for tissue restoration, where the extracellular matrix (ECM) plays a crucial role by providing structural and biochemical support to cells. Laminin 332, a key ECM component, is a promising target for protein-based therapeutics in view of its pathogenic role in junctional epidermolysis bullosa (JEB). Bioengineered capsular antigen F1 protein (Caf1) has emerged as a potential candidate molecule. We have developed the technology to enable bacteria to produce Caf1 polymers with multiple tailored bioactive motifs. Additionally, the unique properties of Caf1 minimize the potential for a host immune response. In this study, we engineered Caf1 proteins to express specific synthetic basement membrane components related to laminin 332 with the aim of restoring ECM equilibrium and achieving effective wound healing. Methods To evaluate Caf1 construct effects on human epidermal keratinocytes (HEKs) (CCD 1106) and human dermal fibroblasts (HDFs), scratch assays were performed under different treatment with Caf constructs. The Incucyte® ZOOM system (Sartorius AG, Göttingen, Germany) automated scratch wound and Live-Cell Analysis System screened constructs enhancing wound healing, capturing images every 2 h. Analysis involved quantifying the area under the curve of wound confluence (%) over 72 h to assess wound closure. Results The migration of HDFs was enhanced by 10.4% ± 0.95% (P < 0.05 Anova, n = 9 independent experiments) when there was interaction with Caf1-CTB4 (PMQKMRGDVFSP). The migration of CCDs was enhanced by 12.7% ± 1.03% when interacting with Caf1-J3 (KNSFMALYLSKGR) and by 14.4% ± 1.11% when interacting with Caf1-J4 (TALIRATYGEYSTGYI) (P < 0.05 Anova; n = 3 independent experiments). Combining Caf1-J3 and Caf1-J4 synergistically boosts CCD migration by 19.1% ± 1.42% (P < 0.05 Anova; n = 3 independent experiments), yielding better Results compared with individual treatments. Conclusions Caf1 exhibits promise as a platform for motif delivery, and the incorporation of cell migration motifs into Caf1 holds the potential to enhance wound healing.
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