Nanobody-tethered transposition enables multifactorial chromatin profiling at single-cell resolution.
Tim StuartStephanie HaoBingjie ZhangLevan MekerishviliDan A LandauSilas ManiatisRahul SatijaIvan RaimondiPublished in: Nature biotechnology (2022)
Chromatin states are functionally defined by a complex combination of histone modifications, transcription factor binding, DNA accessibility and other factors. Current methods for defining chromatin states cannot measure more than one aspect in a single experiment at single-cell resolution. Here we introduce nanobody-tethered transposition followed by sequencing (NTT-seq), an assay capable of measuring the genome-wide presence of up to three histone modifications and protein-DNA binding sites at single-cell resolution. NTT-seq uses recombinant Tn5 transposase fused to a set of secondary nanobodies (nb). Each nb-Tn5 fusion protein specifically binds to different immunoglobulin-G antibodies, enabling a mixture of primary antibodies binding different epitopes to be used in a single experiment. We apply bulk-cell and single-cell NTT-seq to generate high-resolution multimodal maps of chromatin states in cell culture and in human immune cells. We also extend NTT-seq to enable simultaneous profiling of cell surface protein expression and multimodal chromatin states to study cells of the immune system.
Keyphrases
- single cell
- genome wide
- transcription factor
- rna seq
- dna methylation
- high throughput
- single molecule
- gene expression
- dna damage
- dna binding
- high resolution
- cell surface
- cell free
- copy number
- circulating tumor
- induced apoptosis
- pain management
- endothelial cells
- binding protein
- stem cells
- amino acid
- cell cycle arrest
- cell therapy
- genome wide identification