Protein-Nucleic Acid Interactions Support—Troubleshooting

Here are possible causes and solutions:

The shift may be caused by non-specific binding or a DNA binding protein different than the one being tested.

Non-specific bands may be reduced or eliminated by optimizing the binding reactions. Strong non-specific bands can often be mistaken for a positive result but will not be blocked by the addition of cold competitor probe. The following are examples of changes that may help reduce non-specific bands:

• Reduce the amount of protein extract in the binding reaction.
• Increase the amount of non-specific competitor DNA [i.e., poly(dI-dC)A·poly(dI-dC)].
• Use a different non-specific competitor DNA [i.e., sonicated salmon sperm DNA or poly(dA-dT)A·poly(dA-dT)].
• Preincubate the protein extract with non-specific competitor DNA before adding the biotinylated probe.
• Shorten or redesign the probe used in the experiment.

The Lightshift™ Chemiluminescent EMSA Kit is used to detect a biotinylated probe in an EMSA. The binding conditions for each experiment must be optimized for the proteins tested. If an experiment was working when ³²P labeled probes were used, the same binding conditions from those previous experiments should be used, with the biotinylated probe to be substituted in place of the ³²P labeled probe. While commonly used reaction components are provided with the Lightshift™ Chemiluminescent EMSA Kit, these reagents may not be applicable in all situations.

Here are possible causes and solutions:

Speckling/spots can be caused by precipitate in the HRP conjugate or by air bubbles. Precipitate in the HRP conjugate can be removed by filtering the conjugate through a 0.2 μm filter or by centrifugation for 1 minute at maximum speed while air bubbles between the gel and the membrane should be removed before transfer.

Use a non-specific competitor DNA such as poly(dI.dC).

Here are some suggestions to improve the results:

• Make sure that the target DNA used is end-labeled with biotin.
• Increase target DNA concentration.
• Check integrity of target DNA to make sure it is not degraded.
• Check the transfer protocol to make sure that the transfer is efficient.
• Use the right type of membrane such as Biodyne™ B Nylon Membrane (Cat. No. 88518).
• Cover the membrane completely during incubations to make sure it doesn’t dry out during the detection steps.
• Make sure that the crosslinking is efficient.
• Make sure that the 4X wash buffer is diluted to 1X.
• Increase film exposure time during detection.

Here are possible causes and solutions:

Here are possible causes and solutions:

Speckling/spots can be caused by precipitate in the HRP conjugate or by air bubbles. Precipitate in the HRP conjugate can be removed by filtering the conjugate through a 0.2 μm filter or by centrifugation for 1 minute at maximum speed while air bubbles between the gel and the membrane should be removed before transfer.

Use a nonspecific competitor RNA such as tRNA or heparin.

Here are some suggestions to improve the results:

• Make sure that the target RNA used is end-labeled with biotin. Optimize labeling method and test for biotin labeling efficiency before assay. 
• Increase target RNA concentration.
• Check integrity of target RNA to make sure it is not degraded.
• Check the transfer protocol to make sure that the transfer is efficient.
• Use the right type of membrane (Biodyne™ B Nylon Membrane, Cat. No. 88518).
• Cover the membrane completely during incubations to make sure it doesn’t dry out during the detection steps.
• Make sure that the crosslinking is efficient.
• Make sure that the 4X wash buffer is diluted to 1X.
• Increase film exposure time during detection.

• Work in a clean nuclease-free environment.
• Ensure that all plastics are nuclease-free. 
• After in vitro transcription, check RNA integrity by gel electrophoresis.

RNA up to 450 nucleotides has been tested, but with optimization, labeling of longer RNA may be achievable. The RNA must have an accessible 3’-OH for the ligation reaction. 

Ensure that the control reaction in the kit is run to confirm that the labeling reaction is efficient. If the control RNA labels well, but the test RNA does not, optimization is required. Addition of DMSO or heat may help to relax the structure. Additionally, ensure that there are no traces of organic reagent in the reaction (if RNA was extracted before labeling). Ensure that 70% ethanol wash was utilized after precipitation. Ensure that the RNA concentration is sufficient for the labeling reaction.

Here are possible causes and solutions:

Here are possible causes and solutions:

Here are possible causes and solutions:

The elution fraction is compatible with preparation of peptides. Samples may be processed using the Mass Spec Sample Prep Kit for Cultured Cells (Cat. No. 89840). Alternatively, the elution fraction may be separated by denaturing PAGE. Bands of interest can be excised, and digested using the In-Gel Tryptic Digestion Kit (Cat. No. 89871).

These kits were designed using formaldehyde as a crosslinker. The lysing, washing, and elution conditions have all been optimized for formaldehyde crosslinking. These steps are not optimal for native ChIP (no crosslinking,) or for other crosslinkers, such as EGS.

Chromatin immunoprecipitation (ChIP) assays identify links between the genome and the proteome by monitoring transcription regulation through histone modification (epigenetics) or transcription factor:DNA binding interactions. The strength of ChIP assays is their ability to capture a snapshot of specific protein: DNA interactions occurring in a system and to quantitate the interactions using quantitative polymerase chain reaction (qPCR). Chromatin IP experiments require a variety of proteomics and molecular biology methods including crosslinking, cell lysis (protein-DNA extraction), nucleic acid shearing, antibody-based immunoprecipitation, DNA sample clean-up and PCR. Additional techniques such as gel electrophoresis are usually used during optimization experiments to validate specific steps. See here for more details.

Here are possible causes and solutions:

This indicates that the cell to Micrococcal Nuclease (MNase) ratio was too high. Decrease the amount of MNase or increase the cell number (refer to the MNase digestion optimization protocol in Appendix A of the manual).

This could be because your cell type requires more stringent handling to better lyse and release chromatin from the nucleus. Here are some suggestions:

• Increase incubation with nuclei lysis buffer to 30 minutes and vortex for 30 seconds every 5 minutes.
• Following the nuclear lysis step, sonicate the sample for 60 seconds using a 1/8 probe. Perform on wet ice in 3 pulses of 20 seconds with 30 second pauses between.
• Following the nuclear lysis step, dounce the sample 20 times in a glass dounce homogenizer.

Here are possible causes and solutions:

Here are possible causes and solutions:

Note: Increasing the stringency of the nuclear lysis is not recommended unless there is no signal or low signal-to-noise in the IP. Excess sample can result in high background, decreasing the signal of the specific signal.

Here are possible causes and solutions:

Here are possible causes and solutions:

Note: Increasing the stringency of the nuclear lysis is not recommended unless there is no signal or low signal-to-noise in the IP. Excess sample can result in high background, decreasing the signal of the specific signal.

Here are possible causes and solutions:

Here are possible causes and solutions:

Note: Increasing the stringency of the nuclear lysis is not recommended unless there is no signal or low signal-to-noise in the IP. Excess sample can result in high background, decreasing the signal of the specific signal.

Here are possible causes and solutions:

Here are possible causes and solutions:

Note: Increasing the stringency of the nuclear lysis is not recommended unless there is no signal or low signal-to-noise in the IP. Excess sample can result in high background, decreasing the signal of the specific signal.

• Verify that your specific antibody (if not using the kit-provided RNA polymerase II antibody) is validated for IP. Ideally, a ChIP validated antibody is the best, but an antibody for IP has a good chance of working in ChIP.
• Ensure that your chromatin is properly digested (see Appendix A in the manual). Too much digestion as well as too little digestion will affect the success of the ChIP reaction.
• Ensure that all the chromatin has been released from the nuclei. When following the Magnetic ChIP kit instructions, MNase digestion of 4x10⁶ cells followed by sonication to lyse the nuclei, yields about 20-50 µg for the IP. This same sequence can be used with the Agarose ChIP Kit as well. It is recommended that you start with 2–4 x 10⁶ cells per ChIP reaction. Once a successful ChIP has been run at this cell number, it is possible to decrease the cell amount empirically. We have seen good results using as little at 10,000 cells, but this entirely depends on the cell line, target, and antibody.
• Ensure that enough DNA was used for qPCR. Typically, 30-80 ng of DNA is a good range.