ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) kits enable rapid genome-wide profiling of chromatin accessibility by employing a hyperactive Tn5 transposase that simultaneously fragments DNA and inserts sequencing adapters into accessible chromatin regions. This approach generates sequencing-ready libraries from isolated nuclei or permeabilized cells, providing high-resolution maps of open chromatin, transcription start site (TSS) enrichment, and nucleosome positioning. Streamlined workflows support bulk, low-input, and single-cell applications.

Key Advantages

• Fast and Efficient Workflow: Transposition and adapter incorporation occur in a single reaction, significantly reducing library preparation time.
• High Sensitivity and Resolution: Enables the identification of promoters, enhancers, and regulatory elements while providing nucleosome-scale fragment-size information.
• Low-Input and Single-Cell Compatibility: Optimized protocols support applications ranging from a few hundred cells to advanced single-cell ATAC-seq workflows using droplet-based or combinatorial indexing technologies.
• Broad Sample Compatibility: Suitable for cultured cell lines, primary cells, sorted populations, frozen tissues, and other challenging biological specimens.
• Multi-Omics Integration: Easily combined with RNA-seq, CUT&Tag, and other epigenomic approaches to provide comprehensive insights into gene regulation.

Applications

• Bulk ATAC-seq: Identification of differentially accessible chromatin regions and regulatory elements across biological conditions.
• Low-Input and Rare-Cell Analysis: Profiling chromatin accessibility from limited cell numbers and valuable clinical specimens.
• Single-Cell ATAC-seq: Characterization of cell-type-specific chromatin landscapes, heterogeneity, and developmental trajectories.
• Multi-Omics Studies: Integration with CUT&Tag, RNA-seq, and Hi-C datasets to obtain deeper insights into gene regulatory networks.
• Chromatin Architecture Research: Investigation of nucleosome positioning, chromatin remodeling, and epigenetic regulation mechanisms.