Home โ€บ Cell Biology โ€บ How CUT&RUN Profiles Chromatin | Cell Signaling Technology
Steps
  1. 1 Introduce protein-DNA interactions and experimental context 00:06
  2. 2 Compare ChIP-seq to CUT&RUN methodology 00:29
  3. 3 Prepare cells and permeabilize with digitonin 00:57
  4. 4 Add antibody and recruit micrococcal nuclease 01:18
  5. 5 Perform targeted DNA cleavage with calcium 01:35
  6. 6 Isolate digested DNA in supernatant 01:46
  7. 7 Add spike-in controls and compare advantages 02:07
  8. 8 Select appropriate CUT&RUN kit and reagents 02:37
Cell Biology Cell Signaling Technology

How CUT&RUN Profiles Chromatin | Cell Signaling Technology

Protocol
Difficulty
intermediate

Steps

1
Introduce protein-DNA interactions and experimental context

The narrator explains that protein-DNA interactions drive biological processes like gene expression and cell differentiation. Understanding when and where these interactions occur is essential for studying epigenetics in normal development and disease.

โ–ถ 00:06
2
Compare ChIP-seq to CUT&RUN methodology

Traditional ChIP-seq requires three days of work including chromatin crosslinking, fragmentation, immunoprecipitation, and DNA purification. CUT&RUN offers a faster alternative method with distinct advantages over the conventional approach.

โ–ถ 00:29
3
Prepare cells and permeabilize with digitonin

Harvest cells and bind them to magnetic beads to simplify handling and minimize sample loss. Permeabilize the cells with digitoninโ€”no crosslinking fixative is needed, allowing chromatin to remain in its native state.

โ–ถ 00:57
4
Add antibody and recruit micrococcal nuclease

Add antibodies targeting your protein of interest (transcription factors, cofactors, or histone modifications) to the permeabilized cells. Then add the enzyme Protein A-Protein G-Micrococcal Nuclease complex, which binds to the antibody through protein A or G interactions.

โ–ถ 01:18
5
Perform targeted DNA cleavage with calcium

Add calcium to activate the micrococcal nuclease enzyme, which cuts DNA at sites where proteins interact with chromatin. This design provides precise targeting and effective control of nuclease activity.

โ–ถ 01:35
6
Isolate digested DNA in supernatant

The DNA-containing complexes diffuse freely into the supernatant, while remaining chromatin is retained in the cell nucleus. This separation greatly simplifies subsequent DNA purification steps.

โ–ถ 01:46
7
Add spike-in controls and compare advantages

Add spike-in control DNA to ensure experimental reproducibility. CUT&RUN generates lower background with less starting material compared to ChIP-seq and requires fewer sequencing reads, completing analysis in just one to two days.

โ–ถ 02:07
8
Select appropriate CUT&RUN kit and reagents

Choose from Cell Signaling Technology's flexible CUT&RUN options: complete detection kits with all buffers and controls, or individual reagents and enzymes. Add validated primary antibodies specific to your target protein to complete the experiment.

โ–ถ 02:37

๐Ÿšจ Failure Case Library (27) + Submit your own case

critical
Loss of Phosphorylated Protein Signal
Phospho-specific antibody shows no or weak signal in IP experiment, while total protein antibody works. Basal phosphorylation levels appear insufficient for detection.
๐Ÿ’ก 4 ยท โœ“ 4
severe
Low Signal from Using N-ChIP for Weak DNA-Binding Proteins
Consistently low or absent signal when studying transcription factors or chromatin-associated proteins using native ChIP (N-ChIP). Histone ChIP experiments work well in the same laboratory.
๐Ÿ’ก 4 ยท โœ“ 4
severe
High Background from Insufficient Antibody Specificity
High background signal observed in immunoprecipitation experiments where multiple non-target protein bands appear in the eluate, indicating poor antibody specificity.
๐Ÿ’ก 4 ยท โœ“ 4
severe
High Background from Antigen Degradation During IP
High background with smeared or degraded protein bands in IP eluate, often accompanied by loss of target protein signal. Multiple lower molecular weight bands appear below the expected target band.
๐Ÿ’ก 4 ยท โœ“ 4
severe
Non-specific Protein Binding to Antibody
Multiple protein bands appear in IP eluate that are not related to the target antigen, indicating proteins binding non-specifically to the antibody Fc region or other antibody domains.
๐Ÿ’ก 4 ยท โœ“ 4
severe
No Protein Detected: Insufficient Antibody Capture
No target protein is detected in the elution fraction after immunoprecipitation procedure is completed. Western blot or other detection methods show no signal for the target protein.
๐Ÿ’ก 3 ยท โœ“ 3
severe
No Protein Detected: Elution Buffer Inadequacy
Target protein is not detected in elution fraction despite successful capture on beads. Protein may remain bound to beads or antibody after elution attempt.
๐Ÿ’ก 4 ยท โœ“ 4
severe
No Protein Detected: Antibody-Bead Binding Failure
No target protein recovered after IP procedure. Antibody may not be properly immobilized on beads, resulting in loss during washing steps.
๐Ÿ’ก 4 ยท โœ“ 5
severe
No Signal in Co-IP Due to Stringent Lysis Buffer
No signal detected in co-immunoprecipitation experiment despite adequate protein expression confirmed by input lysate control. Western blot shows no target protein bands after IP.
๐Ÿ’ก 4 ยท โœ“ 4
severe
Low/No IP Signal from Insufficient Target Expression
IP experiment yields no detectable signal on western blot. Input lysate control shows weak or absent target protein bands, indicating expression below detection threshold.
๐Ÿ’ก 3 ยท โœ“ 4
severe
Low Signal for Phosphorylated or Modified Proteins
IP of post-translationally modified proteins yields weak or no signal. Input lysate shows low basal levels of phosphorylated or modified target protein despite total protein presence.
๐Ÿ’ก 4 ยท โœ“ 5
severe
No Signal Due to Stringent Lysis Buffer
No signal detected in co-immunoprecipitation experiment. Target protein appears absent despite expected expression.
๐Ÿ’ก 4 ยท โœ“ 4
severe
Low Enrichment Due to Insufficient Starting Material
ChIP-seq exhibits low resolution with high background across large genomic regions. Signal-to-noise ratio is poor, with diffuse peaks and elevated baseline signal throughout the genome.
๐Ÿ’ก 4 ยท โœ“ 4
severe
No Protein Detected: Lysis Buffer Incompatibility
Target protein not detected in IP despite using sufficient antibody and confirmed protein expression. Antibody may fail to recognize target due to protein denaturation or improper folding.
๐Ÿ’ก 4 ยท โœ“ 4
severe
Fragmented Chromatin Concentration Below Required Threshold
DNA concentration of chromatin preparation is insufficient for ChIP, falling below the recommended 50 ยตg/ml or unable to provide 5-10 ยตg per IP reaction.
๐Ÿ’ก 4 ยท โœ“ 4
severe
Low/No Signal from Insufficient Protein Expression
No detectable signal in IP experiment. Input lysate control shows weak or absent target protein band on western blot.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Excessive Antibody Co-Elution with Target Protein
During the final elution step of immunoprecipitation, an unexpectedly high amount of antibody is released along with the target protein, contaminating the eluate and interfering with downstream analysis such as Western blot or mass spectrometry.
๐Ÿ’ก 4 ยท โœ“ 6
moderate
High Background from Incomplete Wash Steps
Persistent high background with many non-specific protein bands in IP eluate despite following standard protocol, indicating residual unbound proteins remain on beads.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Insufficient Bead Blocking Leading to Background
High background caused by non-specific proteins binding directly to the bead matrix surface rather than the antibody, appearing as multiple bands in negative controls with beads alone.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Sample Overload Causing Non-specific Background
Excessive background signal with numerous protein bands in eluate due to using too many cells or too much lysate protein, overwhelming the antibody-bead binding capacity.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Low IP Efficiency from Suboptimal IgG-Bead Binding
IP shows weak target protein recovery despite adequate antibody concentration and protein expression. Bead pellet appears smaller than expected or shows poor antibody capture.
๐Ÿ’ก 3 ยท โœ“ 4
moderate
Non-Specific Protein Binding to Beads or IgG
Multiple non-specific bands appear on western blot after IP. Background signal present in bead-only or isotype control lanes, indicating off-target protein capture.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Epitope Masking Prevents Antibody Binding
No IP signal despite confirmed protein expression in input control. Antibody works in western blot of denatured lysate but fails in native IP conditions.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Low IP Efficiency from Incorrect Bead Selection
Weak IP signal despite good input control. Low recovery of target protein compared to expected levels based on antibody quality.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Excessive Antibody Causing Non-specific Binding
High background observed when using too much antibody in the IP reaction, leading to increased non-specific protein interactions and higher background in the eluate.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Background from Insoluble Protein Carryover
High background in IP eluate with particulate matter visible, caused by insoluble proteins or cellular debris contaminating the soluble lysate supernatant.
๐Ÿ’ก 4 ยท โœ“ 4
moderate
Multiple Bands from Non-Specific Protein Binding
Multiple bands appear on western blot after IP. Background bands present in bead-only or IgG control lanes indicate non-specific binding.
๐Ÿ’ก 4 ยท โœ“ 4
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