Development and application of light-controlled inducible recombination systems.

The site-specific recombination systems are composed of recombinases and specific recognition sites, which are powerful tools for gene manipulation and have been extensively used in life sciences research. Inducible recombination systems have been developed to precisely regulate gene expression in a spatiotemporal manner in cells and animals for applications such as gene function research, cell lineage tracing and disease treatment. Based on different spatiotemporal expression methods of recombinases, inducible recombination systems can be divided into two categories: chemical- controlled and light-controlled inductions. Light-controlled inducible recombination systems that utilize light as inducer consist of photocage and optogenetics in accordance with optical control patterns and objects. Photocaged inducible recombination systems are using photosensitive groups to control chemical inducers or recombinases. Their activities are inhibited by photosensitive groups before light induction and recovered after specific light irradiation, leading to light-controlled inducible gene recombination. While optogenetic inducible recombination systems rely on reactivations of split recombinases that mediated by optogenetic switches. Optogenetic switches are composed of a series of gene-encoded photosensitive proteins, including cryptochromes, VIVID, phytochromes, etc. These types of light-controlled inducible recombination systems provide more possibilities for analyzing gene expression and function from the dimension of high spatiotemporal resolution to meet the increasingly complex demands of life science research. In this review, we summarize the developing principles and applications of different types of light-controlled inducible recombination systems, compare their advantages and disadvantages, and prospect the development of more light-controlled recombination systems in the future, with the aims to provide theoretical basis and guidance for system optimization and upgrade.

Pulmonary Staphylococcus aureus infection regulates breast cancer cell metastasis via neutrophil extracellular traps (NETs) formation.

The formation of neutrophil extracellular traps (NETs) was recently identified as one of the most important processes for the maintenance of host tissue homeostasis in bacterial infection. Meanwhile, pneumonia infection has a poor effect on cancer patients receiving immunotherapy. Whether pneumonia-mediated NETs increase lung metastasis remains unclear. In this study, we identified a critical role for multidrug-resistant Staphylococcus aureus infection-induced NETs in the regulation of cancer cell metastasis. Notably, S. aureus triggered autophagy-dependent NETs formation in vitro and in vivo and increased cancer cell metastasis. Targeting autophagy effectively regulated NETs formation, which contributed to the control of cancer metastasis in vivo. Moreover, the degradation of NETs by DNase I significantly suppresses metastasis in lung. Our work offers novel insight into the mechanisms of metastasis induced by bacterial pneumonia and provides a potential therapeutic strategy for pneumonia-related metastasis.