Structured silicon for revealing transient and integrated signal transductions in microbial systems.
Xiang GaoYuanwen JiangYiliang LinKyoung-Ho KimYin FangJaeseok YiLingyuan MengHoo-Cheol LeeZhiyue LuOwen LeddyRui ZhangQing TuWei FengVishnu NairPhilip J GriffinFengyuan ShiGajendra S ShekhawatAaron R DinnerHong-Gyu ParkBozhi TianPublished in: Science advances (2020)
Bacterial response to transient physical stress is critical to their homeostasis and survival in the dynamic natural environment. Because of the lack of biophysical tools capable of delivering precise and localized physical perturbations to a bacterial community, the underlying mechanism of microbial signal transduction has remained unexplored. Here, we developed multiscale and structured silicon (Si) materials as nongenetic optical transducers capable of modulating the activities of both single bacterial cells and biofilms at high spatiotemporal resolution. Upon optical stimulation, we capture a previously unidentified form of rapid, photothermal gradient-dependent, intercellular calcium signaling within the biofilm. We also found an unexpected coupling between calcium dynamics and biofilm mechanics, which could be of importance for biofilm resistance. Our results suggest that functional integration of Si materials and bacteria, and associated control of signal transduction, may lead to hybrid living matter toward future synthetic biology and adaptable materials.
Keyphrases
- candida albicans
- pseudomonas aeruginosa
- staphylococcus aureus
- biofilm formation
- room temperature
- microbial community
- physical activity
- induced apoptosis
- high resolution
- mental health
- cerebral ischemia
- high speed
- cystic fibrosis
- signaling pathway
- cell cycle arrest
- photodynamic therapy
- current status
- drug delivery
- cancer therapy
- cell adhesion
- mass spectrometry
- oxidative stress
- brain injury
- drug release
- subarachnoid hemorrhage
- cell death
- loop mediated isothermal amplification
- quantum dots
- free survival