Silver Mineralized Protein Hydrogel with Intrinsic Cell Proliferation Promotion and Broad-Spectrum Antimicrobial Properties for Accelerated Infected Wound Healing.

The presence of multidrug-resistant bacteria has challenged the clinical treatment of bacterial infection. There is a real need for the development of novel biocompatible materials with broad-spectrum antimicrobial activities. Antimicrobial hydrogels show great potential in infected wound healing but are still being challenged. Herein, broad-spectrum antibacterial and mechanically tunable amyloid-based hydrogels based on self-assembly and local mineralization of silver nanoparticles are reported. The mineralized hydrogels are biocompatible and have the advantages of sustained release of silver, prolonged antimicrobial effect, and improved adhesion capacity. Moreover, the mineralized hydrogels display a significant antimicrobial effect against both Gram-positive and Gram-negative bacteria in cells and mice by inducing membrane damage and reactive oxygen species toxicity in bacteria. In addition, the mineralized hydrogels can rapidly accelerate wound healing by the synergy between their antibacterial activity and intrinsic improvement for cell proliferation and migration. This study provides a modular approach to developing a multifunctional protein hydrogel platform based on biomolecule-coordinated self-assembly for a wide range of biomedical applications.

Molecular determinants and evolutionary dynamics of wobble splicing.

Alternative splicing at tandem splice sites (wobble splicing) is widespread in many species, but the mechanisms specifying the tandem sites remain poorly understood. Here, we used synaptotagmin I as a model to analyze the phylogeny of wobble splicing spanning more than 300 My of insect evolution. Phylogenetic analysis indicated that the occurrence of species-specific wobble splicing was related to synonymous variation at tandem splice sites. Further mutagenesis experiments demonstrated that wobble splicing could be lost by artificially induced synonymous point mutations due to destruction of splice acceptor sites. In contrast, wobble splicing could not be correctly restored through mimicking an ancestral tandem acceptor by artificial synonymous mutation in in vivo splicing assays, which suggests that artificial tandem splice sites might be incompatible with normal wobble splicing. Moreover, combining comparative genomics with hybrid minigene analysis revealed that alternative splicing has evolved from the 3' tandem donor to the 5' tandem acceptor in Culex pipiens, as a result of an evolutionary shift of cis element sequences from 3' to 5' splice sites. These data collectively suggest that the selection of tandem splice sites might not simply be an accident of history but rather in large part the result of coevolution between splice site and cis element sequences as a basis for wobble splicing. An evolutionary model of wobble splicing is proposed.