Protein labeling

2022
Jun Xu, Ah-Ram Kim, Ross W Cheloha, Fabian A Fischer, Joshua Shing Shun Li, Yuan Feng, Emily Stoneburner, Richard Binari, Stephanie E Mohr, Jonathan Zirin, Hidde L Ploegh, and Norbert Perrimon. 2022. “Protein visualization and manipulation in through the use of epitope tags recognized by nanobodies.” Elife, 11.Abstract
Expansion of the available repertoire of reagents for visualization and manipulation of proteins will help understand their function. Short epitope tags linked to proteins of interest and recognized by existing binders such as nanobodies facilitate protein studies by obviating the need to isolate new antibodies directed against them. Nanobodies have several advantages over conventional antibodies, as they can be expressed and used as tools for visualization and manipulation of proteins in vivo. Here, we characterize two short (<15 aa) NanoTag epitopes, 127D01 and VHH05, and their corresponding high-affinity nanobodies. We demonstrate their use in Drosophila for in vivo protein detection and re-localization, direct and indirect immunofluorescence, immunoblotting, and immunoprecipitation. We further show that CRISPR-mediated gene targeting provides a straightforward approach to tagging endogenous proteins with the NanoTags. Single copies of the NanoTags, regardless of their location, suffice for detection. This versatile and validated toolbox of tags and nanobodies will serve as a resource for a wide array of applications, including functional studies in Drosophila and beyond.
2021
Ilia A Droujinine, Amanda S Meyer, Dan Wang, Namrata D Udeshi, Yanhui Hu, David Rocco, Jill A McMahon, Rui Yang, JinJin Guo, Luye Mu, Dominique K Carey, Tanya Svinkina, Rebecca Zeng, Tess Branon, Areya Tabatabai, Justin A Bosch, John M Asara, Alice Y Ting, Steven A Carr, Andrew P McMahon, and Norbert Perrimon. 2021. “Proteomics of protein trafficking by in vivo tissue-specific labeling.” Nat Commun, 12, 1, Pp. 2382.Abstract
Conventional approaches to identify secreted factors that regulate homeostasis are limited in their abilities to identify the tissues/cells of origin and destination. We established a platform to identify secreted protein trafficking between organs using an engineered biotin ligase (BirA*G3) that biotinylates, promiscuously, proteins in a subcellular compartment of one tissue. Subsequently, biotinylated proteins are affinity-enriched and identified from distal organs using quantitative mass spectrometry. Applying this approach in Drosophila, we identify 51 muscle-secreted proteins from heads and 269 fat body-secreted proteins from legs/muscles, including CG2145 (human ortholog ENDOU) that binds directly to muscles and promotes activity. In addition, in mice, we identify 291 serum proteins secreted from conditional BirA*G3 embryo stem cell-derived teratomas, including low-abundance proteins with hormonal properties. Our findings indicate that the communication network of secreted proteins is vast. This approach has broad potential across different model systems to identify cell-specific secretomes and mediators of interorgan communication in health or disease.