Sonogenetics-controlled synthetic designer cells for cancer therapy in tumor mouse models.

Bacteria-based therapies are powerful strategies for cancer therapy, yet their clinical application is limited by a lack of tunable genetic switches to safely regulate the local expression and release of therapeutic cargoes. Rapid advances in remote-control technologies have enabled precise control of biological processes in time and space. We developed therapeutically active engineered bacteria mediated by a sono-activatable integrated gene circuit based on the thermosensitive transcriptional repressor TlpA39. Through promoter engineering and ribosome binding site screening, we achieved ultrasound (US)-induced protein expression and secretion in engineered bacteria with minimal noise and high induction efficiency. Specifically, delivered either intratumorally or intravenously, engineered bacteria colonizing tumors suppressed tumor growth through US-irradiation-induced release of the apoptotic protein azurin and an immune checkpoint inhibitor, a nanobody targeting programmed death-ligand 1, in different tumor mouse models. Beyond developing safe and high-performance designer bacteria for tumor therapy, our study illustrates a sonogenetics-controlled therapeutic platform that can be harnessed for bacteria-based precision medicine.

AAV-delivered muscone-induced transgene system for treating chronic diseases in mice via inhalation.

Gene therapies provide treatment options for many diseases, but the safe and long-term control of therapeutic transgene expression remains a primary issue for clinical applications. Here, we develop a muscone-induced transgene system packaged into adeno-associated virus (AAV) vectors (AAVMUSE) based on a G protein-coupled murine olfactory receptor (MOR215-1) and a synthetic cAMP-responsive promoter (PCRE). Upon exposure to the trigger, muscone binds to MOR215-1 and activates the cAMP signaling pathway to initiate transgene expression. AAVMUSE enables remote, muscone dose- and exposure-time-dependent control of luciferase expression in the livers or lungs of mice for at least 20 weeks. Moreover, we apply this AAVMUSE to treat two chronic inflammatory diseases: nonalcoholic fatty liver disease (NAFLD) and allergic asthma, showing that inhalation of muscone-after only one injection of AAVMUSE-can achieve long-term controllable expression of therapeutic proteins (ΔhFGF21 or ΔmIL-4). Our odorant-molecule-controlled system can advance gene-based precision therapies for human diseases.

A small and highly sensitive red/far-red optogenetic switch for applications in mammals.

Optogenetic technologies have transformed our ability to precisely control biological processes in time and space. Yet, current eukaryotic optogenetic systems are limited by large or complex optogenetic modules, long illumination times, low tissue penetration or slow activation and deactivation kinetics. Here, we report a red/far-red light-mediated and miniaturized Δphytochrome A (ΔPhyA)-based photoswitch (REDMAP) system based on the plant photoreceptor PhyA, which rapidly binds the shuttle protein far-red elongated hypocotyl 1 (FHY1) under illumination with 660-nm light with dissociation occurring at 730 nm. We demonstrate multiple applications of REDMAP, including dynamic on/off control of the endogenous Ras/Erk mitogen-activated protein kinase (MAPK) cascade and control of epigenetic remodeling using a REDMAP-mediated CRISPR-nuclease-deactivated Cas9 (CRISPR-dCas9) (REDMAPcas) system in mice. We also demonstrate the utility of REDMAP tools for in vivo applications by activating the expression of transgenes delivered by adeno-associated viruses (AAVs) or incorporated into cells in microcapsules implanted into mice, rats and rabbits illuminated by light-emitting diodes (LEDs). Further, we controlled glucose homeostasis in type 1 diabetic (T1D) mice and rats using REDMAP to trigger insulin expression. REDMAP is a compact and sensitive tool for the precise spatiotemporal control of biological activities in animals with applications in basic biology and potentially therapy.

Engineering of optogenetic devices for biomedical applications in mammalian synthetic biology.

Gene- and cell-based therapies are the next frontiers in the field of medicine. Both are transformative and innovative therapies; however, a lack of safety data limits the translation of such promising technologies to the clinic. Improving the safety and promoting the clinical translation of these therapies can be achieved by tightly regulating the release and delivery of therapeutic outputs. In recent years, the rapid development of optogenetic technology has provided opportunities to develop precision-controlled gene- and cell-based therapies, in which light is introduced to precisely and spatiotemporally manipulate the behaviour of genes and cells. This review focuses on the development of optogenetic tools and their applications in biomedicine, including photoactivated genome engineering and phototherapy for diabetes and tumours. The prospects and challenges of optogenetic tools for future clinical applications are also discussed.

Engineering a far-red light-activated split-Cas9 system for remote-controlled genome editing of internal organs and tumors.

It is widely understood that CRISPR-Cas9 technology is revolutionary, with well-recognized issues including the potential for off-target edits and the attendant need for spatiotemporal control of editing. Here, we describe a far-red light (FRL)-activated split-Cas9 (FAST) system that can robustly induce gene editing in both mammalian cells and mice. Through light-emitting diode-based FRL illumination, the FAST system can efficiently edit genes, including nonhomologous end joining and homology-directed repair, for multiple loci in human cells. Further, we show that FAST readily achieves FRL-induced editing of internal organs in tdTomato reporter mice. Finally, FAST was demonstrated to achieve FRL-triggered editing of the PLK1 oncogene in a mouse xenograft tumor model. Beyond extending the spectrum of light energies in optogenetic toolbox for CRISPR-Cas9 technologies, this study demonstrates how FAST system can be deployed for programmable deep tissue gene editing in both biological and biomedical contexts toward high precision and spatial specificity.

Systems-level understanding of how Propionibacterium acidipropionici respond to propionic acid stress at the microenvironment levels: mechanism and application.

In previous work, three evolved Propionibacterium acidipropionici mutants with higher tolerant capacity of propionic acid (PA) were obtained by genome shuffling. Here, we attempted to unravel the acid-tolerant mechanism of P. acidipropionici by comparing the physiological changes between P. acidipropionici and three mutants. The parameters used for comparison included intracellular pH (pHi), NAD⁺/NADH ratio, H⁺-ATPase activity, and the intracellular amino acids concentrations. It was indicated that the acid tolerance of P. acidipropionici was systematically regulated. Specifically, low pHi promoted the P. acidipropionici to biosynthesize more H⁺-ATPase to pump the protons out of the cells, and as a result, the NAD⁺/NADH ratio increased due to the decreased protons concentration. The increased arginine, aspartic acid, and glutamic acid concentrations helped to resist the acidic environment by consuming more H⁺ and generating more ATP and NH3. Based on what was analyzed above, 20 mM arginine and aspartic acid were added during the shaker culture of P. acidipropionici, and the maximal PA titer reached 14.38 g/L, which was increased by 39.9% compared with the control.