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Single-cell profiling of histone marks and transcription factors via DeChIC-seq

July 13, 2026
in Medicine
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Single-cell profiling of histone marks and transcription factors via DeChIC-seq

Single-cell profiling of histone marks and transcription factors via DeChIC-seq

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A groundbreaking advancement in epigenomic profiling has emerged with the development of DeChIC-seq, a novel technique enabling genome-wide mapping of protein-DNA interactions at unprecedented single-cell resolution. Researchers have long sought effective methods to capture transcription factor (TF) binding sites, given their typically sparse distribution and the technical difficulties in detecting them with high sensitivity. DeChIC-seq presents a solution by leveraging a DNA deaminase-based chromatin immuno-conversion strategy, marking a significant breakthrough in chromatin biology.

Unlike traditional immunoprecipitation-dependent methods, DeChIC-seq circumvents the need for chromatin enrichment steps, instead using a fusion protein composed of Protein A linked to DddAtox, a bacterial DNA cytosine deaminase. This innovative fusion protein, guided by antibodies specific to chromatin-associated proteins, induces localized cytosine-to-uracil (C-to-U) conversions directly at the antibody-bound DNA sites. These base modifications serve as molecular footprints, allowing researchers to infer protein-DNA interactions by sequencing the converted DNA, effectively converting binding events into detectable genetic signatures without perturbing the chromatin landscape.

An exceptional feature of DeChIC-seq is its retention of genome-wide background sequence information. This capability not only facilitates the profiling of diverse histone modifications but also significantly enhances the sensitivity of transcription factor binding site detection. The method’s adaptability is further demonstrated by its integration with single-cell whole-genome amplification, yielding scDeChIC-seq—a powerful tool that profiles chromatin states at the resolution of individual cells. This is particularly valuable when sample biomass is limited, such as in early embryonic stages or rare cell populations.

Applying scDeChIC-seq to mouse embryogenesis, the researchers successfully characterized lineage-specific chromatin landscapes through comprehensive profiling of key histone marks such as H3K4me3, and architectural proteins including CTCF and RAD21. Remarkably, the technique sensitively identified TF binding events relevant to early development, highlighting factors such as NR5A2, TFAP2C, and KLF5 from minute numbers of blastomeres. This sensitivity underscores the technology’s robustness in detecting critical regulatory proteins that guide cell fate decisions.

The underlying technology exploits the natural enzymatic activity of DddAtox, which introduces targeted base conversions upon antibody-mediated recruitment, effectively translating protein occupancy into a genetic readout. This direct conversion-based approach enables simultaneous mapping of histone modifications and transcription factor binding within the same assay, a feat rarely achievable by conventional methods. The resulting chromatin maps are both highly specific and quantitatively reliable.

This work stands to revolutionize studies of gene regulation by providing a scalable, precise, and minimally invasive tool for charting the dynamic interplay between chromatin architecture and protein regulators. Beyond developmental contexts, the ability of DeChIC-seq to function in scarce biological samples heralds new possibilities for investigating epigenomic states in rare cell types, disease models, and clinical specimens.

As epigenomics continues to push the boundaries of resolution and sensitivity, DeChIC-seq offers a promising avenue to translate molecular interactions into high-definition chromatin landscapes. This evolution in technology not only advances fundamental biological understanding but also holds potential for novel diagnostic and therapeutic applications, emphasizing the intricate orchestration of gene regulation at the single-cell level.


Subject of Research: Epigenomics, Chromatin Profiling, Transcription Factor Binding, Single-Cell Genomics

Article Title: Genome-wide profiling of histone modifications and transcription factor binding at single-cell resolution by DeChIC-seq

Article References:
Shi, Z., Chen, X., Yang, Y. et al. Genome-wide profiling of histone modifications and transcription factor binding at single-cell resolution by DeChIC-seq. Cell Res (2026). https://doi.org/10.1038/s41422-026-01275-z

DOI: https://doi.org/10.1038/s41422-026-01275-z

Tags: antibody-guided DNA cytosine deaminationchromatin biology advancementsDeChIC-seq chromatin mappingDNA deaminase-based chromatin immuno-conversiongenome-wide chromatin profiling techniqueshigh-sensitivity transcription factor footprintinghistone modification mappingmethods for detecting sparse transcription factor binding sitesprotein-DNA interaction detectionsingle-cell epigenomic profilingsingle-cell epigenomics innovationsingle-cell transcription factor profiling
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