Search for: All records

Myokines and exosomes, originating from skeletal muscle, are shown to play a significant role in maintaining brain homeostasis. While exercise has been reported to promote muscle secretion, little is known about the effects of neuronal innervation and activity on the yield and molecular composition of biologically active molecules from muscle. As neuromuscular diseases and disabilities associated with denervation impact muscle metabolism, we hypothesize that neuronal innervation and firing may play a pivotal role in regulating secretion activities of skeletal muscles. We examined this hypothesis using an engineered neuromuscular tissue model consisting of skeletal muscles innervated by motor neurons. The innervated muscles displayed elevated expression of mRNAs encoding neurotrophic myokines, such as interleukin-6, brain-derived neurotrophic factor, and FDNC5, as well as the mRNA of peroxisome-proliferator-activated receptor γ coactivator 1α, a key regulator of muscle metabolism. Upon glutamate stimulation, the innervated muscles secreted higher levels of irisin and exosomes containing more diverse neurotrophic microRNAs than neuron-free muscles. Consequently, biological factors secreted by innervated muscles enhanced branching, axonal transport, and, ultimately, spontaneous network activities of primary hippocampal neurons in vitro. Overall, these results reveal the importance of neuronal innervation in modulating muscle-derived factors that promote neuronal function and suggest that the engineered neuromuscular tissue model holds significant promise as a platform for producing neurotrophic molecules. 

Abstract Drug‐resistant microorganisms cause serious problems in human healthcare, leading to the persistence in infections and poor treatment outcomes from conventional therapy. In this study, a gene‐targeting strategy using microbubble‐controlled nanoparticles is introduced that can effectively eliminate biofilms of methicillin‐resistantStaphylococcus aureus(MRSA) in vivo. Biofilm‐targeting nanoparticles (BTN) capable of delivering oligonucleotides are developed that effectively remove biofilm‐associated bacteria upon controlled delivery with diatom‐based microbubblers (MB). The activity of BTN in silencing key bacterial genes related to MRSA biofilm formation (icaA), bacterial growth (ftsZ), and antimicrobial resistance (mecA), as well as their multi‐targeting ability in vitro is validated. The integration of BTN with MB is next examined, resulting in synergistic effects in biofilm removal and antimicrobial activity in an ex vivo porcine skin model. The therapeutic efficacy is further investigated in vivo in a mouse wound model infected with MRSA biofilm, which showed that MB‐controlled BTN delivery substantially reduced bacterial load and led to the effective elimination of the biofilm. This study underscores the potential of the gene silencing platform with physical enhancement as a promising strategy to combat problems related to biofilms and antibiotic resistance.