CRISPR-Cas systems enable powerful gene editing and regulation, yet single-modality control often fails to achieve orthogonal, spatiotemporally precise regulation of multiple endogenous genes. We engineered OREC, an orthogonal platform integrating chemogenetic and optogenetic modalities for precise, reversible, multiplex gene control. OREC comprises two components: ORECC regulated by doxycycline (Dox) and ORECo controlled by light. By assembling catalytically dead Cpf1 (dCpf1), gene regulatory elements, and crRNA arrays on single transcripts, OREC enables robust simultaneous manipulation of multiple genes. We demonstrated OREC's therapeutic potential in vitro for osteoblast function modulation and in vivo for o... More
CRISPR-Cas systems enable powerful gene editing and regulation, yet single-modality control often fails to achieve orthogonal, spatiotemporally precise regulation of multiple endogenous genes. We engineered OREC, an orthogonal platform integrating chemogenetic and optogenetic modalities for precise, reversible, multiplex gene control. OREC comprises two components: ORECC regulated by doxycycline (Dox) and ORECo controlled by light. By assembling catalytically dead Cpf1 (dCpf1), gene regulatory elements, and crRNA arrays on single transcripts, OREC enables robust simultaneous manipulation of multiple genes. We demonstrated OREC's therapeutic potential in vitro for osteoblast function modulation and in vivo for osteoporotic fracture repair. OREC effectively activated Bmp2 while inhibiting Dkk1, significantly enhancing bone formation and fracture healing in mouse models. These results establish OREC as a versatile platform for precise multiplex gene regulation, offering significant advancement for CRISPR-based gene therapy applications in complex tissues where coordinated control of multiple therapeutic targets is essential.
