Antibody-trapping presents a widespread pitfall for microscopy and genomics in the nucleus
Authors
- Konrad Chudzik
- Yuko Sato
- Xingchi Yan
- Simon Ullrich
- Watanya Trakarnphornsombat
- Lothar Schermelleh
- Geoffrey Fudenberg
- Hiroshi Kimura
- Michael I. Robson
- Irina Solovei
Journal
- Nucleic Acids Research
Citation
- Nucleic Acids Res 54 (12): gkag615
Abstract
Chromatin has a complex 3D structure and diverse binding proteins that coordinate the genome’s most essential functions. Many microscopy and genomics technologies that map chromatin proteins and modifications rely on the diffusion of antibodies (Abs) to target epitopes within whole nuclei. Here, we reveal a critical flaw in such methods that arises when Abs become trapped at the edge of nuclear structures and fail to reach internally positioned epitopes. This “Ab-trapping” results in artifactual peripheral signal that fundamentally distorts the apparent positions of chromatin features across the genome and nucleus. Using computational modeling and experimental validation, we demonstrate that Ab-trapping is caused by a combination of three compounding factors—high epitope abundance, high Ab affinity, and low Ab diffusion rates. Ab-trapping can thus systematically misrepresent the localization of many prevalent chromatin features like histone modifications, transcription factors, nucleolar proteins, and protein tags. We also show that this artifact manifests in multiple technologies, including immunofluorescence microscopy, more recent CUT&Tag-seq, and likely any method relying on Ab diffusion. Finally, we outline readily implementable strategies to identify and mitigate Ab-trapping. Combined, our work presents a previously unrecognized yet prevalent artifact in Ab-based chromatin mapping methods and the means to resolve it.