技术资料

Baculovirus,an insect virus commonly used for recombinant protein expression in insect cells and gene delivery in mammalian systems,is often generated through bacmid-based engineering. To enable flexible and programmable bacmid engineering,we developed SHOT 2.0,an optimized CRISPR-associated transposon platform that mediates RNA-guided and customized bacmid editing in Escherichia coli. The edited bacmid can be transfected into insect cells to produce recombinant baculoviruses. SHOT 2.0 supported site-specific integration of large DNA cargos (at least 14 kb) into defined loci such as v-cath and ODVe56,with integration at ODVe56 markedly improving transgene stability during serial virus passaging. The system is fully compatible with the Bac-to-Bac® workflow,enabling dual-gene insertion into the bacmid and derived baculovirus. Leveraging this platform,we constructed an all-in-one baculovirus encoding the PE5max prime editor. This vector-mediated prime editing achieves efficiencies up to 85.6% in HEK293T cells and achieves robust prime editing in hard-to-transfect cell types,including iPSCs and liver cancer cells,with efficiencies up to 37.1%. These results demonstrate that SHOT 2.0 substantially expands the baculovirus engineering toolbox,providing a flexible platform for genome editing and future gene delivery. View Publication

Cell surface proteins offer significant cancer therapeutic potential attributable to their accessible membrane localization and central roles in cellular signaling,yet their promise remains largely untapped due to technical challenges inherent to profiling them. Here,we employ N-glycoproteomics to analyze 85 patient-derived xenografts (PDXs),constructing Glyco PDXplorer—an in vivo pan-cancer atlas of cancer-derived surface proteins. We develop a target discovery pipeline to prioritize proteins with favorable expression profiles for immunotherapeutic targeting and validate FAT2 as a squamous-cancer-enriched surface protein minimally detected in normal tissue. Functional studies reveal that FAT2 is essential for head and neck squamous cancer (HNSC) cell growth and adhesion through regulation of surface architecture and integrin-PI3K signaling. Chimeric antigen receptor (CAR)-T cells targeting FAT2 demonstrate anti-tumor activity. This work lays the foundation for developing FAT2-targeted therapies and represents a pivotal platform to inform therapeutic target discovery across cancers. Graphical abstract Highlights•Pan-cancer landscape of cancer-derived cell surface proteins detected in vivo•Discovery pipeline to prioritize proteins as immunotherapy target candidates•Validation of FAT2 as an SCC surface protein with minimal normal tissue expression•FAT2 CAR-T cells demonstrate anti-tumor activity in pre-clinical models Govindarajan et al. leverage N-glycoproteomics and PDX models to decode the in vivo cancer cell surfaceome and establish Glyco PDXplorer—a target discovery platform. The identification and validation of FAT2 as a previously undescribed,actionable antigen demonstrates the utility of Glyco PDXplorer for uncovering therapeutic vulnerabilities. View Publication

Three-dimensional (3D) culture systems that recapitulate the tumor microenvironment are essential for studying cancer cell behavior,drug response,and cell–matrix interactions. Here,we present a detailed protocol for generating 3D spheroid cultures from murine breast cancer cells using methacrylated gelatin (GelMA)-based bioink and a CELLINK BioX bioprinter. This method enables precise deposition of spheroid-laden GelMA droplets into low-attachment plates,facilitating high-throughput and reproducible 3D culture formation. The protocol includes steps for spheroid formation,GelMA preparation,bioprinting,and post-printing analysis using a customized CellProfiler pipeline. The analysis pipeline takes advantage of the functionality of CellProfiler and ImageJ software (version 2.14.0) packages to create a versatile and accessible analysis tool. This approach provides a robust and adaptable platform for in vitro cancer research,including studies of metastasis,drug resistance,cancer cell lipid metabolism,and TME-associated hypoxia. View Publication