ChIP-exo Kit. (version A4) Catalog No

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1 ChIP-exo Kit (version A4) Catalog No Active Motif North America 1914 Palomar Oaks Way, Suite 150 Carlsbad, California 92008, USA Toll free: Telephone: Fax: Active Motif Europe Avenue Reine Astrid, 92 B-1310 La Hulpe, Belgium UK Free Phone: France Free Phone: Germany Free Phone: Telephone: +32 (0) Fax: +32 (0) Active Motif Japan Azuma Bldg, 7th Floor 2-21 Ageba-Cho, Shinjuku-Ku Tokyo, , Japan Telephone: Fax: Active Motif China 787 Kangqiao Road Building 10, Suite 202, Pudong District Shanghai, , China Telephone: (86) Hotline: Copyright 2015 Active Motif, Inc.

2 Information in this manual is subject to change without notice and does not constitute a commitment on the part of Active Motif, Inc. It is supplied on an as is basis without any warranty of any kind, either explicit or implied. Information may be changed or updated in this manual at any time. This documentation may not be copied, transferred, reproduced, disclosed, or duplicated, in whole or in part, without the prior written consent of Active Motif, Inc. This documentation is proprietary information and protected by the copyright laws of the United States and international treaties. The manufacturer of this documentation is Active Motif, Inc Active Motif, Inc., 1914 Palomar Oaks Way, Suite 150; Carlsbad, CA All rights reserved. All trademarks, trade names, service marks or logos referenced herein belong to their respective companies.

3 TABLE OF CONTENTS Overview Flow Chart of Process...2 Introduction References Kit Performance and Benefits...4 Protocol Overview and Time Table...5 Kit Components and Storage ChIP-exo Kit....6 Additional Materials Required...7 Protocols Experimental Set Up Cell Growth and Recommendations...9 Buffer Preparation...10 Recommendations Protocols Section A. Cell Fixation Starting with Cultured Cells...13 Section B. Chromatin Sonication of Cultured Cells...14 Section C. Cell Fixation Starting with Fresh or Frozen Tissue...17 Section D. Chromatin Sonication of Tissue...18 Section E. Antibody Conjugation to Protein G Beads...21 Section F. Chromatin Immunoprecipitation...22 Section G. Perform End Repair...22 Section H. Ligation of P7 Exo-Adapter...23 Section I. Nick Repair...24 Section J. Lambda Exonuclease Digestion...25 Section K. RecJf Exonuclease Digestion...25 Section L. Reversal of Cross-links and Elution from Beads...26 Section M. DNA Purification...27 Section N. P7 Primer Extension...28 Section O. Ligation of P5 Exo-Adapter...29 Section P. PCR Amplification of DNA Library...30 Section Q. Size Select the Library...31 Section R. Recommendations for Data Analysis...32 Appendix Section S. Use of Magnetic Beads and Included Bar Magnet...35 Section T. Walking Primer Design...38 Section U. Troubleshooting Guide Technical Services...42 Page

4 Overview Transcriptional regulation is a highly complex mechanism that involves changes in epigenetic modifications, transcription factors and cofactors, and chromatin structure. Because aberrations in transcription are often associated with disease states, including cancer, gaining further insight into the mechanisms regulating gene expression is crucial to understanding disease susceptibility, initiation and progression. Chromatin Immunoprecipitation (ChIP) is a powerful tool for studying protein/dna interactions because it enables identification of the localization of proteins bound to specific DNA loci. However, traditional ChIP-sequencing (ChIP-seq) and ChIP-chip methods provide limited resolution for transcription factors and often produce high background which limits sequencing coverage and increases noise. Active Motif s ChIP-exo* (ChIP-exonuclease) Kit overcomes these limitations by providing a high resolution method for mapping protein binding sites genome-wide. ChIP-exo utilizes exonucleasemediated digestion of DNA during the immunoprecipitation protocol to eliminate extraneous DNA and increase binding site resolution to within bp reads making it easier to more accurately define sequences representing protein/dna binding motifs. This makes ChIP-exo ideal for mapping transcription factor binding sites, performing discovery-based studies, or evaluation of mutation and SNP effects. The ChIP-exo Kit contains sufficient reagents to prepare chromatin and perform 12 immunoprecipitation reactions. Reagents are also provided for preparation of sequencing libraries for use on Illumina sequencing platforms. product format catalog no. ChIP-exo Kit 12 rxns *Technology covered under U.S. Patent No b2 1

5 Flow Chart of Process Flow chart of ChIP-exo method. Cells are fixed with formaldehyde to cross-link protein-dna binding interactions. Cells are then lysed and chromatin is fragmented by sonication. An antibody directed against the protein of interest is conjugated to protein G magnetic beads for immunoprecipitation of the DNA of interest. With the chromatin still bound by the beads, the DNA is end-polished and P7-exo adapters are ligated onto the blunt ends. The nicked DNA is repaired and then digested by lambda and RecJf exonulceases to excise DNA in a 5 to 3 direction, trimming up to the site of the cross-linking and selectively eliminating the P7 adapter at the 5 end. Following cross-link reversal and elution from the beads, the DNA is made double-stranded by P7 primer extension and a P5-exo adapter is added to the exonuclease-treated ends. The DNA library is PCR amplified and size selected before it is subjected to high-throughput sequencing. The sequence of the DNA is mapped back to the reference genome to determine the binding locations of the protein of interest. The 5 ends of the DNA fragments on the forward strand indicate the left border of a DNA-protein interaction, while the 5 ends of DNA fragments on the reverse strand indicate the right border of a DNA-protein interaction. These borders demarcate the precise site of the protein-dna cross-linking, providing high resolution (20-95 base pairs) identification of genomic binding locations. 2

6 Introduction Chromatin immunoprecipitation technologies (ChIP-seq and ChIP-chip) have provided valuable information regarding protein-dna localization, which has increased our understanding of the functional organization of the genome 1. However, these methods have their limitations with regards to mapping transcription factor binding sites and resolution of positional information. Transcription factors often bind DNA in a sequence dependent manner as monomers, homodimers or heterodimers, but only a fraction of a given transcription factor will be bound to the chromatin at any specific time 2. Current ChIP methods aim to identify protein binding sites in the presence of several hundred base pairs of non-specific DNA that result from random chromatin fragmentation. Given the relatively low abundance of chromatin-associated transcription factors, and the relatively high level of background noise in the IP reaction, accurate identification of precise binding sequences, or resolution of positional information about binding complexes are not possible with these methods. ChIP-exonuclease (ChIP-exo) is a technology that was developed in the laboratory of B. Franklin Pugh 3-5. This technology modifies the traditional ChIP-seq method by including an exonuclease digestion step to trim the immunoprecipitated DNA to a precise distance from the cross-linking site. By removing the excess DNA that is not bound by the protein of interest, background signal is reduced such that fewer sequencing reads map to non-specific genomic regions enabling the identification of weak peaks which would be indistinguishable from noise in a traditional ChIP-seq. The high resolution of ChIP-exo facilitates the identification of consensus sequences for transcription factors that could lead to the discovery of new binding sequences to significantly improve our understanding of the impact that mutations or SNPs have on transcriptional regulation and disease. Active Motif s ChIP-exo Kit is a streamlined version of the original methodology that has adapted the assay for use on Illumina sequencing platforms 6. The Kit contains optimized buffers for chromatin preparation from cell or tissue samples. Chromatin is then captured and enzymatically treated while bound to Protein G magnetic beads for easy processing. Sequencing adapters are added and the library is amplified and size selected before it is subjected to high throughput sequencing. Guidelines are also provided for data analysis of the sequencing reads. References 1. Dunham, I. et al. (2012) Nature, 489: Bailey, T. et al. (2013) PLoS Comput Biol, 9(11): e Rhee H.S. and Pugh B.F. (2011) Cell, 147(6): Rhee H.S. and Pugh B.F. (2012) Nature, 483(7389): ; erratum 487(7405): Rhee H.S. and Pugh B.F. (2012) Curr Protoc Mol Biol., Chapter 21: Unit Serandour, A.A. et al. (2013) Genome Biology, 14(12): R147. 3

7 Kit Performance and Benefits ChIP-Exo Advantages: Enables high resolution genome-wide mapping of transcription factor binding locations Superior resolution maps protein binding sites within bp making it easy to study mutation or SNP effects Low background due to exonuclease-mediated degradation of non-specific DNA On-bead enzymatic reactions streamline sample processing Published (10x10 7 cells) Binding Site = 70 bp 6.3 { Fw Rv 10.1 FoxA1 ChIP-exo from MCF-7 Cells AM (2x10 7 cells) Binding Site = 14 bp 3.3 { Fw Rv Reported FoxA1 Binding Site (215 bp) 5.2 Figure 1: BigWig graphs comparing Active Motif s ChIP-exo data with published ChIP-exo data for FoxA1. To generate Active Motif s ChIP-exo results (AM) for FoxA1, 100 μg of chromatin obtained from 20 million MCF-7 cells was fragmented and ChIP was performed using the ChIP-exo Kit with antibodies against FoxA1. Results were compared with published results (Published) for FoxA1 obtained by performing ChIP-exo on fragmented chromatin generated from 100 million MCF-7 cells as described previously by Serandour et al. (Ref 6). Data was aligned to the hg19 human reference genome using Bowtie. The BigWig graphs were generated using the ChIP-exo-specific analysis software: MACE (Model based Analysis of ChIP-exo). These results demonstrate that Active Motif s ChIP-exo method achieves comparable resolution of binding motifs as the published data for FoxA1 using a fraction of the starting cell numbers used to obtain the published data. Results overlap with reported FoxA1 binding sites. 4

8 Protocol Overview and Time Table Below is an overview of the protocol steps and the required time to completion. Please read the entire assay protocol and plan your experimental design before starting the assay. Suggestions for dividing up the assay each day are provided below, but may be modified as needed to accommodate your experimental plan and time line. Day Protocol Required Time Day 1 Cell or Tissue Fixation and Lysis 1.5 hours Chromatin Sonication Assessment of Chromatin Size* 15 minutes per sample 4.5 hours for cell culture Overnight for tissue Day 2 Antibody Conjugation to Protein G Magnetic Beads 4 hours (or overnight) incubation Immunoprecipitation Overnight incubation Day 3 End Repair 30 minutes P7 Exo-Adapter Ligation Nick Repair Lambda Exonuclease Digestion RecJf Exonuclease Digestion Reversal of Cross-links DNA Purification 1 hour 20 minutes 30 minutes 30 minutes 2.5 hours Day 4 P7 Primer Extension 1.5 hours P5 Exo-Adapter Ligation PCR Amplification of the DNA Library Library Size Selection * The protocol varies between cell culture and tissue samples. 2 hours to overnight incubation 1.5 hours 1 hour 1.5 hours 5

9 Kit Components and Storage Please store each component at the temperature indicated in the table below. Do not re-freeze the Protein G Magnetic Beads. Once thawed, Protein G beads should be stored at 4 C. Reagents Quantity Storage T4 DNA Ligase (2000 U/µl) 25 µl -20 C DNA Polymerase I Klenow fragment (5 U/µl) 13 µl -20 C T4 Polynucleotide Kinase (10 U/µl) 65 µl -20 C T4 DNA Polymerase (3 U/µl) 65 µl -20 C Phi29 Polymerase (10 U/µl) 32 µl -20 C Lambda Exonuclease (5 U/µl) 25 µl -20 C RecJf Exonuclease (30 U/µl) 13 µl -20 C Q5 High-Fidelity DNA Polymerase (2 U/µl) 13 µl -20 C 5X Q5 Reaction Buffer 125 µl -20 C 1X Phi29 Reaction Buffer 1.6 ml -20 C 10X T4 DNA Ligase Buffer 65 µl -20 C 10X Lambda Exonuclease Buffer 125 µl -20 C 10X Reaction Buffer AM3 375 µl -20 C dntps (5 mm) 400 µl -20 C 100 mm ATP 25 µl -20 C Indexing Primer 2 13 µl -20 C Indexing Primer 4 13 µl -20 C P7 exo-adapter 125 µl -20 C P5 exo-adapter 13 µl -20 C P7 primer 13 µl -20 C RNase A (10 µg/µl) 40 µl -20 C Proteinase K (10 µg/µl) 180 µl -20 C 100 mm PMSF 500 µl -20 C Protease Inhibitor Cocktail (PIC) 500 µl -20 C Precipitation Buffer 1 ml -20 C Carrier 30 µl -20 C Glycogen 13 µl -20 C 10X PBS 120 ml -20 C 6

10 Fixation Buffer 2 x 1.5 ml 4 C Blocking Buffer AM3 52 ml 4 C Protein G Magnetic Beads* 600 µl 4 C AMPure Beads** 3.3 ml 4 C 5X Wash Buffer AM1 50 ml 4 C 10X Wash Buffer AM6 15 ml 4 C Stop Solution 20 ml RT Chromatin Prep Buffer 80 ml RT ChIP Buffer 30 ml RT Elution Buffer AM4 2 x 2 ml RT DNA Purification Elution Buffer 5 ml RT 5 M NaCl 400 µl RT TE ph x 1.5 ml RT Detergent 20 ml RT Bar magnet 1 ea RT Glue dots 2 ea RT * The Protein G Magnetic Beads are shipped on dry ice and can be stored frozen until their first use. Once thawed, the Protein G beads should not be re-frozen by the customer. Protein G Magnetic Beads should be stored at 4ºC. ** This product contains AMPure XP Reagent manufactured by Beckman Coulter, Inc. Additional materials required A ChIP-seq validated antibody directed against the protein of interest Dounce homogenizer with a small clearance pestle (e.g. Active Motif Catalog Nos & 40415) with the tight-fitting A pestle). Use of a homogenizer is necessary for shearing chromatin. 37% formaldehyde solution with 10-15% methyl alcohol to prevent polymerization. Do not use paraformaldehyde. Phenol Chloroform/isoamyl alcohol (24:1) 100% ethanol (absolute) 70% ethanol DNase-free H 2 O 7

11 Rocking platform for culture plates Apparatus to rotate tubes end-to-end at 4 C (e.g. a Labquake from Barnstead/Thermolyne with a tube holder for 1.5 ml microcentrifuge tubes) Thermal Mixer (Fisher Scientific ) or heat block Microcentrifuge (table top centrifuge 4 C) and microcentrifuge tubes 250 µl PCR tubes Thermal cycler 15 and 50 ml conical tubes Spectrophotometer for DNA quantitation Pipettors and tips (filter tips are recommended) Sonicator (e.g. Active Motif s EpiShear Sonicator with a 1/8 probe (Catalog No ) with the EpiShear Cooled Sonication Platform (Catalog No )) Agarose gel electrophoresis apparatus Razor blades (for tissue preparations) Hand-held homogenizer for tissue preparations (e.g. Biospec Products Tissue-Tearor) Cell scraper (rubber policeman) 8

12 Protocols Experimental Set Up PLEASE READ THE ENTIRE PROTOCOL BEFORE STARTING! Cell Growth Recommendations Successful ChIP-exonuclease (ChIP-exo) requires a large sample input, and is also dependent on the quality of the ChIP antibody and the abundance of the target protein. Lower binding affinity antibodies / low abundance transcription factors will require more input material than a highly abundant protein / high affinity ChIP antibody. The minimum recommended number of cells that should be used for the preparation of chromatin is 15 million cells (approximately one 150 mm plate), although significant improvements in sequencing coverage are observed if the cell number is increased to million cells per sample. In order to efficiently process the exonuclease reaction, each 15 million cell pellet is divided and processed as 3 independent IP reactions. If using 45 million cells, the chromatin will be divided into 9 independent IP reactions. Scaling quantities into a single tube will reduce the efficiency of the IP and is not recommended. Calculate the number of cell culture plates needed per sample based on the abundance of your target protein and/or affinity of the ChIP antibody to achieve the desired level of sequencing coverage. Note that if you wish to analyze the effect of particular compounds or culturing conditions on transcription factor/dna interactions, you should prepare chromatin from control (untreated) cells as a reference sample. Protein Abundance / Antibody Affinity High abundance / affinity Medium abundance / affinity Low abundance / affinity # Cell Culture Plates 1 x 150 mm 2 x 150 mm 3 x 150 mm Seeding Density 5.0 x x 5.0 x x 5.0 x 10 6 Total Cells at 70-80% Confluency* Growth Medium Volume 15.0 x x x ml 2 x 20 ml 3 x 20 ml Cell Fixative Solution 2 ml 2 x 2 ml 3 x 2 ml Stop Solution 1.1 ml 2 x 1.1 ml 3 x 1.1 ml PBS Wash Buffer 2 x 10 ml 4 x 10 ml 6 x 10 ml Chromatin Prep Buffer 5 ml 2 x 5 ml 3 x 5 ml ChIP Buffer 500 µl 2 x 500 µl 3 x 500 µl Expected chromatin yield 50 µg 100 µg 200 µg Required # IP rxns 3 IP rxns 6 IP rxns 9 IP rxns * The number of cells on a confluent plate or dish will vary with cell type. For this table, HeLa cells were used. Please adjust as needed based on your particular cell type. ** Please refer to the descriptions below for complete details on buffer preparations 9

13 Buffer Preparation Complete Cell Fixation Solution Buffer should be prepared fresh before each experiment. For every 20 ml of cell growth medium used, prepare 2.5 ml of Complete Cell Fixation Solution by adding 180 µl Fixation Buffer to 1.57 ml sterile water in a 15 ml conical tube. Using appropriate precautions (i.e. safety glasses, gloves and lab coat), add 750 µl 37% formaldehyde to the tube and vortex to mix. Use 1/10 growth medium volume per plate. Complete cell fixation solution can be added to the growth medium in the presence or absence of serum. Complete Tissue Fixation Solution Buffer should be prepared fresh before each experiment. Prepare 10 ml of Tissue Fixation Solution for each tissue sample to be processed by adding 1 ml 10X PBS to 8.7 ml sterile water in a 15 ml conical tube. Using appropriate precautions (i.e. safety glasses, gloves and lab coat), add 280 µl 37% formaldehyde to the tube and vortex to mix. Stop Solution Is provided ready to use. Use 1/20 media volume per cell culture plate or 515 µl per 10 ml Complete Tissue Fixation Solution. PBS Wash Buffer Prepare 25 ml PBS Wash Buffer for every 15 cm plate or tissue sample. To a 50 ml conical tube add ml sterile water, 2.5 ml 10X PBS and 1.25 ml Detergent. Mix by inverting. Place PBS Wash Buffer on ice to chill. PBS Wash Buffer can be prepared in large quantities and stored at 4ºC for 6 months. 100 mm PMSF and Protease Inhibitor Cocktail (PIC) Thaw PMSF and PIC at room temperature until fully dissolved, which takes about 30 minutes. Vortex gently and spin down briefly before use, then add to the buffers immediately before use. Chromatin Prep Buffer Is supplied ready to use. ChIP Buffer Is supplied ready to use. Protein G Magnetic Beads Follow the instructions in the manual to conjugate antibody to the beads for use in the IP reactions. For best results, gently shake and invert the tube to resuspend the magnetic beads. The beads settle quickly, and therefore should be resuspended just before pipetting. We recommend cutting 2 mm from the end of a pipet tip prior to pipetting to prevent the tip from becoming clogged. Protein G Magnetic Beads are shipped on dry ice and can be stored frozen until their first use. Once thawed, beads should not be re-frozen by the customer. Protein G Magnetic Beads should be stored at 4ºC. 10

14 Blocking Buffer AM3 Is supplied ready to use. The BSA contained in the Blocking Buffer AM3 may form clumps, therefore it is necessary to completely resuspend the buffer by warming to room temperature and vortexing for 1 minute prior to use. Preparation of 1X Wash Buffer AM1 Prepare the amount of 1X Wash Buffer AM1 required for the assay as follows: For every IP reaction prepare 20 ml of 1X Wash Buffer AM1 by diluting 4 ml 5X Wash Buffer AM1 with 16 ml distilled water. Vortex to mix. This includes excess for pipetting errors. Please scale volumes as needed based on the number of IP reactions per experiment. Preparation of 1X Wash Buffer AM6 Prepare the amount of 1X Wash Buffer AM6 required for the assay as follows: For every IP reaction prepare 15 ml of 1X Wash Buffer AM6 by diluting 1.5 ml 10X Wash Buffer AM6 with 13.5 ml distilled water. Vortex to mix. This includes excess for pipetting errors. Please scale volumes as needed based on the number of IP reactions per experiment. Elution Buffer AM4 Is supplied ready to use. AMPure Beads Is supplied ready to use. Ensure that the beads are fully resuspended prior to use. Just before removing an aliquot of beads, vortex for 30 seconds. Repeat each time you remove beads. Enzymes, Adapters, Primers and Cofactors This kit contains multiple enzymes, adapters, primers and cofactors needed to perform end repair, adapter ligation, nick repair, exonuclease digestion, primer extension and PCR amplification. Each tube contains a small quantity of the necessary reagent. All reagents should be kept on ice when not in use. Centrifuge each tube prior to opening to ensure that the contents are collected at the bottom so that material is not lost when removing the caps. Use the recommended tables provided throughout the manual to determine the volumes needed based on the number of IP reactions. Do not prepare excess volumes above the suggested amounts. 11

15 Recommendations ChIP-seq validated Antibody We recommend conjugating 10 µg antibody per 50 µl Protein G magnetic beads. If the concentration of the antibody is unknown, use 15 µl antibody per 50 µl Protein G magnetic beads. However, this will vary according to the affinity of the antibody and the quality of the chromatin; you may need to use more of a particular antibody. ChIP performed with an antibody that has not been ChIP-seq validated must include appropriate controls (such as Active Motif s ChIP-IT Control qpcr Kits, Catalog Nos , and 53028) to validate the chromatin preparation and the ChIP methodology. To see a list of available ChIP-seq validated antibodies available from Active Motif, please visit /chipabs. Chromatin Shearing Tips We suggest using a probe sonicator (i.e. Active Motif s EpiShear Probe Sonicator) which employs a direct sonication method to prepare chromatin for use in the ChIP-IT Exonuclease Kit. Indirect sonication systems may require longer sonication times to achieve optimal chromatin shearing. ChIP experiments usually require chromatin that has been sheared to a size of bp. In general, shearing efficiency is improved through the use of a small shearing volume and a V-bottom tube rather than a round-bottom tube. Also, note that shearing is inefficient if the chromatin sample becomes emulsified with air bubbles. To determine the appropriate shearing level for your sample, set up a practice tube containing only ChIP Buffer. Slowly increase the sonication amplitude until foaming starts to occur. Reduce the amplitude setting down slightly and mark this as the highest possible intensity to use without foaming. If a chromatin preparation becomes emulsified inadvertently, discontinue shearing and centrifuge the sample at maximum speed for 4 minutes at 4ºC in a microcentrifuge to remove trapped air. Finally, to prevent overheating and denaturation of chromatin, samples should be kept on ice as much as possible during shearing, and shearing should be performed discontinuously (i.e. sonicate for 20 seconds, then place on ice/water for 30 seconds, sonicate again for 20 seconds, etc.). If possible, shear while on ice or use Active Motif s EpiShear Cooled Sonication Platform (Catalog No ) to help regulate sample temperature. Thermal Mixer The use of a thermal mixer (e.g. Fisher Scientific ) is highly recommended to improve the efficiency of the enzymatic reactions during the ChIP-exo protocol. If a thermal mixer is not available, use a heat block with intermittent mixing by hand throughout the incubation steps. Safety Precautions Formaldehyde and PMSF are highly toxic chemicals. Appropriate safety precautions (i.e. safety glasses, gloves and lab coat) should be used. Also, formaldehyde is highly toxic by inhalation and should be used only in a ventilated hood. Finally, chromatin sonication should be performed in a biosafety hood if the chromatin is extracted from biohazardous or infectious materials. 12

16 Protocols Section A: Cell Fixation Starting with Cultured Cells This protocol describes cell fixation and chromatin preparation from one 15 cm plate (approximately 1.5 x 10 7 cells). We recommend using 20 ml growth medium per 15 cm plate. The minimum cell number to be used for the preparation of chromatin is 15 million (1.5 x 10 7 ) cells. If using multiple plates we recommend processing each plate separately. Do not pool samples together. 1. Prepare 15 cm plates for each cell line to be tested. Grow the cells to 70-80% confluency. Stimulate cells as desired to activate the pathway of interest. 2. Freshly prepare Complete Cell Fixation Solution for each 15 cm plate. The volumes listed below are enough to process one 15 cm plate. 3. To fix cells, add 1/10 growth medium volume of freshly prepared Complete Cell Fixative Solution to the existing culture media for the cells (e.g. 20 ml growth medium would get 2 ml Complete Cell Fixation Solution). Shake gently at room temperature for 15 minutes. 4. Stop the fixation reaction by adding 1/20 media volume of Stop Solution to the existing culture media for the cells (e.g. 20 ml growth medium would get 1.1 ml Stop Solution). Swirl to mix and incubate at room temperature for 5 minutes. 5. Following the incubation, hold the plate at an angle and using a rubber policeman scrape cells down to collect them at the bottom edge of the plate. Use a pipette to transfer the cells to a 50 ml conical tube on ice. 6. Pellet the cells from step 5 by centrifugation for 3 minutes at 1,250 x g at 4 C. 7. Remove the supernatant and discard. Resuspend the pellet(s) in 10 ml ice-cold PBS Wash Buffer by pipetting up and down. Keep samples ice-cold for the remainder of the procedure. 8. Centrifuge for 3 minutes at 1,250 x g at 4 C. Remove the supernatant and discard. Wash the pellet(s) a second time in 10 ml ice-cold PBS Wash Buffer by pipetting up and down. Centrifuge for 3 minutes at 1,250 x g at 4 C. Remove the supernatant and discard. (Cell pellets may be stored at -80 C at this stage). 9. Resuspend each pellet(s) in 5 ml Chromatin Prep Buffer supplemented with 5 µl PIC and 5 µl 100 mm PMSF. Pipet up and down to mix. 10. Incubate on ice for 10 minutes. 11. Transfer the resuspended pellets individually to a chilled dounce homogenizer on ice. Use the tight fitting pestle (Type A) to homogenize the sample for 30 strokes. Transfer the contents to a new 15 ml conical tube and centrifuge for 3 minutes at 1,250 x g at 4 C. Monitor Cell Lysis: To ensure cell lysis, take 10 µl of the cell lysate from the dounce and look at it under a phase contrast microscope using a hemocytometer to verify that the nuclei have been released. It is often helpful to look at the cells before and after the lysis step as this makes it easier to identify the nuclei versus whole cells. Intact cells should have a dark central region (nucleus) surrounded by a halo of less dense cytoplasm. In lysed cells, the nuclei will appear as dots surrounded by asymmetric debris. If the cells are not lysed, then 13

17 dounce on ice with an additional 10 strokes, or until the cells are lysed. 12. Remove the supernatant and discard. Resuspend each pellet in 500 µl ChIP Buffer supplemented with 5 µl PIC and 5 µl 100 mm PMSF. Transfer the contents to a new 2 ml microcentrifuge tube. 13. Incubate on ice for 10 minutes. Proceed to Step B: Chromatin Sonication of Cultured Cells. Section B. Chromatin Sonication of Cultured Cells The section below describes the fragmentation of chromatin using sonication. Sonication results may vary depending on cell type and sonication device being used. This protocol has been validated using Active Motif s EpiShear Probe Sonicator in combination with an EpiShear Cooled Sonication Platform to maintain probe height and temperature consistency between samples. We do not recommend sonication of samples containing less than 350 µl volume or more than 15 million cells. If using multiple plates, each cell pellet should be sonicated independently using identical sonication conditions. The ChIP Buffer has been optimized for immunoprecipitation performance, however, due to its unique composition optimization of sonication conditions may be required. To maintain the high sensitivity of the assay, we recommend using our buffer system and altering the sonication time and/or amplitude of your sonication system to achieve the desired fragmentation (e.g. some systems may require as much as a three-fold increase in sonication time to improve chromatin shearing). Please pay particular attention to our protocol regarding the processing of input chromatin for agarose gel analysis prior to the chromatin immunoprecipitation reaction as many steps may differ from traditional ChIP protocols and failure to follow the outlined procedure may lead to artifacts in the gel images as shown in Figure 2 on page Place the 2 ml microcentrifuge tube containing the chromatin into the tube cooler or packed ice. Open cap and submerge the microtip into the liquid until the microtip is approximately 5 mm from the bottom of the tube. Sonicate according to optimized settings for the cell type being used (see Recommendations on page 12). A recommended starting range for cultured cells is: 25% amplitude, pulse for 30 seconds on and 30 seconds off for a total sonication on time of 10 minutes (or 20 minutes elapsed time). 2. Spin tubes at 4 C in a microcentrifuge at maximum speed for 2 minutes to pellet the cellular debris. 3. Transfer 25 µl of each chromatin preparation into a 250 µl PCR tube for analysis of shearing efficiency and chromatin quantification. This sample will be used to generate the Input DNA. 4. Aliquot the remainder of each chromatin preparation into 1.5 ml microcentrifuge tubes. We recommend making 3 aliquots of 150 µl volume from each cell pellet and storing at -80 C. Note: The size of the chromatin sonication should be verified before proceeding to the immunoprecipitation step. 14

18 Input Preparation 5. To each 25 µl chromatin preparation from Step 3 above, add 175 µl TE ph 8.0 and 1 µl RNAse A. Cap the PCR tubes and vortex to mix 6. Incubate in a thermocycler at 37 C for 30 minutes. 7. Add 2 µl Proteinase K to each tube and vortex. Incubate tubes in a thermocycler at 55 C for 30 minutes and then increase the temperature to 80 C for 2 hours. 8. Transfer each chromatin input to a 1.5 ml microcentrifuge tube. Add 83 µl Precipitation Buffer, 2 µl Carrier and 750 µl absolute ethanol. Vortex to mix and chill at -80 C for 30 minutes to overnight. 9. Spin tubes at 4 C in a microcentrifuge at maximum speed for 15 minutes. 10. Carefully remove the supernatant taking care not to disturb the pellet. Wash the pellet with 500 µl 70% ethanol and spin at 4 C in a microcentrifuge at maximum speed for 5 minutes. 11. Carefully remove the supernatant taking care not to disturb the pellet. Remove residual ethanol with a pipet tip. Leave the tubes uncapped and air dry for minutes. 12. When the pellets are dry, add 25 µl DNA Purification Elution Buffer to each tube. Incubate at room temperature for 10 minutes. Then vortex to ensure the pellet is completely resuspended. This solution contains your Input DNA. 13. Read the absorbance of each sample on a NanoDrop or other spectrophotometer at 260 nm to determine the DNA concentration of each chromatin preparation. Set aside 500 ng of DNA for analysis as described in Step 14. Store the remaining Input DNA at -20 C. 14. Analyze each chromatin preparation on an agarose gel by following the instructions below. a. Prepare 500 mm NaCl by adding 2 µl 5M NaCl to 18 µl sterile water. Vortex to mix. b. Transfer 500 ng of Input DNA to a 250 µl PCR tube and add 1 µl 500 mm NaCl. Adjust the final volume to 10 µl with sterile water if needed. c. Heat samples in a thermocycler at 100 C for 20 minutes followed by ramping the temperature down to 50 C. d. Remove tubes from the thermocycler and incubate at room temperature for 5 minutes. e. Add gel loading buffer to each sample and run on a 1.5% agarose gel. Include 100 bp and 1 kb DNA ladders to analyze chromatin size. DNA should appear as a smear anywhere between bp. Note: Chromatin prepared using the ChIP-IT Exonuclease protocol may look different on an agarose gel compared to chromatin prepared using traditional ChIP methods. However, this will not affect the sensitivity of the assay or increase background signal. Please follow the protocol as listed above for preparing Input DNA. Use of an alternative reverse cross-linking method or omitting the 20 minute incubation at 100 C in NaCl is not recommended as this will cause artifacts that make the DNA appear larger. As long as the chromatin falls within the recommended bp range, proceed with the ChIP reaction. If fragments do not fall within this range sonication conditions should be further optimized. 15

19 15. If chromatin preparations were successful, the aliquots stored at -80 C from Section B, Step 4 can be used to perform the ChIP reactions in Section F. Figure 2: Validation of chromatin shearing efficiency following reversal of cross-links at 80 C for 2 hours. Chromatin preparations of MCF-7 cells were fixed and sonicated using the EpiShear Probe Sonicator and EpiShear Cooled Sonication Platform from Active Motif. Input DNA was prepared in duplicate according to Section B, Steps 5-13 in the manual. In Sample 1, Step 14 was not performed and 500 ng of input DNA was loaded directly onto a 1.5% agarose gel without receiving the addition of NaCl and incubation at 100 C. The omission of Step 14 has caused a buffer artifact that makes the DNA appear larger on a gel. The duplicate sample, Sample 2, was processed according to the manual instructions and included the addition of NaCl and incubation at 100 C as stated in Step 14. Analysis of 500 ng of this input DNA on a 1.5% agarose gel shows the expected fragmentation between bp. The difference in DNA sizing on the gel between the two samples illustrates the importance of following the protocol recommendations regarding the processing of input chromatin for agarose gel analysis prior to chromatin immunoprecipitation. Omission of key steps can lead to inaccurate analysis of chromatin shearing efficiency. If the protocol steps were followed and the DNA fragments fall outside of the recommended range, sonication conditions should be further optimized. 16

20 Section C: Cell Fixation Starting with Fresh or Frozen Tissue This protocol describes cell fixation and chromatin preparation from mg fresh or frozen animal tissue. If performing chromatin preparation on multiple tissue samples, we recommend completing Steps 1-7 for each sample before processing the next sample. 1. For tissue fixation, transfer 10 ml Complete Tissue Fixation Solution (see Buffer Preparation on page 7) to a 60 mm petri dish. Place the dish on ice. 2. Add mg fresh or frozen tissue sample to the petri dish and ensure that the sample is fully immersed. Cut the tissue sample into small pieces (approximately 1 mm cubes) using a razor blade. 3. Transfer the sample plus the Complete Tissue Fixation Solution to a 15 ml conical tube and rotate at room temperature for 15 minutes. 4. Stop the fixation reaction by adding 515 µl Stop Solution to the conical tube and rotate at room temperature for 5 minutes. 5. Place the conical tube on ice and homogenize the contents with a hand-held tissue homogenizer set at 30,000 rpm for 45 seconds. 6. Pellet the cells from step 5 by centrifugation for 3 minutes at 1,250 x g at 4 C. 7. Remove the supernatant and discard. Resuspend the pellet in 10 ml ice-cold PBS Wash Buffer by pipetting up and down. Keep samples ice-cold for the remainder of the procedure. 8. Centrifuge for 3 minutes at 1,250 x g at 4 C. Remove the supernatant and discard. Wash the pellet(s) a second time in 10 ml ice-cold PBS Wash Buffer by pipetting up and down. Centrifuge for 3 minutes at 1,250 x g at 4 C. Remove the supernatant and discard. (Cell pellets may be stored at -80 C at this stage). 9. Resuspend each pellet in 5 ml Chromatin Prep Buffer supplemented with 5 µl PIC and 5 µl 100 mm PMSF. 10. Incubate on ice for 10 minutes. 11. Transfer the resuspended pellet(s) individually to a chilled dounce homogenizer on ice. Use the tight fitting pestle (Type A) to homogenize the sample for 30 strokes. Once finished, transfer the contents to a new 15 ml conical tube. Monitor Cell Lysis: To ensure cell lysis, take 10 µl of the cell lysate from the dounce and look at it under a phase contrast microscope using a hemocytometer to verify that the nuclei have been released. It is often helpful to look at the cells before and after the lysis step as this makes it easier to identify the nuclei versus whole cells. Intact cells should have a dark central region (nucleus) surrounded by a halo of less dense cytoplasm. In lysed cells, the nuclei will appear as dots surrounded by asymmetric debris. If the cells are not lysed, then dounce on ice with an additional 10 strokes, or until the cells are lysed. 12. Centrifuge for 3 minutes at 1,250 x g at 4 C. 13. Remove the supernatant and discard. Resuspend each pellet in 500 µl - 1 ml ChIP Buffer supplemented with PIC and 100 mm PMSF. (For 500 µl add 5 µl PIC and 5 µl PMSF. For 1 ml 17

21 add 10 µl PIC and 10 µl PMSF) Transfer the contents to a new 2 ml microcentrifuge tube. 14. Incubate on ice for 10 minutes. Proceed to Section D: Chromatin Sonication of Tissue. Section D. Chromatin Sonication of Tissue The section below describes the fragmentation of chromatin using sonication. Due to the increased concentration of protein and cellular debris present in animal tissue, we recommend following this protocol for the preparation of chromatin and input DNA from tissue. Sonication results may vary depending on tissue type and sonication device being used. This protocol has been validated using Active Motifs EpiShear Probe Sonicator in combination with the EpiShear Cooled Sonication Platform to maintain probe height and temperature consistency between samples. We do not recommend sonication of samples containing less than 350 µl volume. If the total sample volume is 1 ml, split the sample into two 500 µl aliquots for sonication. Each 500 µl tube should be sonicated independently using identical sonication conditions The Chromatin Prep Buffer has been optimized for immunoprecipitation performance, however, due to its unique composition optimization of sonication conditions may be required. To maintain the high sensitivity of the assay, we recommend using our buffer system and altering the sonication time and/or amplitude of your sonication system to achieve the desired fragmentation (e.g. some systems may require as much as a three-fold increase in sonication time to improve chromatin shearing). Please pay particular attention to our protocol regarding the processing of input chromatin for agarose gel analysis prior to the chromatin immunoprecipitation reaction as many steps may differ from traditional ChIP protocols and failure to follow the outlined procedure may lead to artifacts in the gel images as shown in Figure 3 on page Place the 2 ml microcentrifuge tube containing the chromatin into the tube cooler or packed ice. Open cap and submerge the microtip into the liquid until the microtip is approximately 5 mm from the bottom of the tube. Sonicate according to optimized settings for the tissue type being used (see Recommendations on page 12). A recommended starting range for tissue samples is: 25% amplitude, pulse for 30 seconds on and 30 seconds off for a total sonication on time of 10 minutes (or 20 minutes elapsed time). 2. Spin tubes at 4 C in a microcentrifuge at maximum speed for 2 minutes to pellet the cellular debris. 3. Transfer 25 µl of each chromatin preparation into a 250 µl PCR tube for analysis of shearing efficiency and chromatin quantification. This sample will be used to generate the Input DNA. 4. Aliquot the remainder of each chromatin preparation into 1.5 ml microcentrifuge tubes. We recommend making 3 aliquots of 150 µl volume from each sonication and storing at -80 C. Note: The size of the chromatin sonication should be verified before proceeding to the immunoprecipitation step. 18

22 Input Preparation 5. To each 25 µl chromatin preparation from Step 3 above, add 175 µl TE ph 8.0 and 2 µl RNAse A. Cap the PCR tubes and vortex to mix. 6. Incubate in a thermocycler at 37 C for 1 hour. 7. Add 5 µl Proteinase K to each tube, vortex and incubate in a thermocycler at 37 C for 3 hours. 8. Add 10 µl 5 M NaCl, vortex and incubate at 65 C for 6-16 hours to reverse cross-links. 9. Remove tubes from the thermocycler and add 250 µl phenol and 125 µl chloroform:isoamyl alcohol (24:1). Vortex vigorously and spin tubes in a room temperature microcentrifuge at maximum speed for 2 minutes. 10. Transfer each upper aqueous layer to a new 1.5 ml microcentrifuge tube and add 250 µl chloroform:isoamyl alcohol (24:1). Vortex vigorously and spin tubes in a room temperature microcentrifuge at maximum speed for 2 minutes. 11. Transfer the upper aqueous layer to a new 1.5 ml microcentrifuge tube. Add 83 µl Precipitation Buffer, 2 µl Carrier and 900 µl absolute ethanol. Vortex to mix and chill at -80 C for 30 minutes to overnight. 12. Spin at 4 C in a microcentrifuge at maximum speed for 15 minutes. 13. Carefully remove the supernatant taking care not to disturb the pellet. Wash the pellet with 500 µl 70% ethanol and spin at 4 C in a microcentrifuge at maximum speed for 5 minutes. 14. Carefully remove the supernatant taking care not to disturb the pellet. Remove residual ethanol with a pipet tip. Leave the tubes uncapped and air dry for minutes. 15. When the pellets are dry, add 25 µl DNA Purification Elution Buffer to each tube. Incubate at room temperature for 10 minutes. Then vortex to ensure the pellet is completely resuspended. This solution contains your Input DNA. 16. Read the absorbance of each sample on a NanoDrop or other spectrophotometer at 260 nm to determine the DNA concentration of each chromatin preparation. Set aside 500 ng of DNA for analysis as described in Step 17. Store the remaining Input DNA at -20 C. 17. Analyze each chromatin preparation on an agarose gel by following the instructions below. a. Prepare 500 mm NaCl by adding 2 µl 5M NaCl to 18 µl sterile water. Vortex to mix. b. Transfer 500 ng of Input DNA to a 250 µl PCR tube and add 1 µl 500 mm NaCl. Adjust the final volume to between 10 µl with sterile water if needed. c. Heat samples in a thermocycler at 100 C for 20 minutes followed by ramping the temperature down to 50 C. d. Remove tubes from the thermocycler and incubate at room temperature for 5 minutes. e. Add gel loading buffer to each sample and run on a 1.5% agarose gel. Include 100 bp and 1 kb DNA ladders to analyze chromatin size. DNA should appear as a smear anywhere between bp. Note: Chromatin prepared using the ChIP-IT Exonuclease protocol may look different on an agarose gel than chromatin prepared using traditional ChIP methods. 19

23 However, this will not affect the sensitivity of the assay or increase background signal. Please follow the protocol as listed above for preparing Input DNA. Use of an alternative reverse cross-linking method or omitting the 20 minute incubation at 100 C in NaCl is not recommended as this will cause artifacts that make the DNA appear larger. As long as the chromatin falls within the recommended bp range, proceed with the ChIP reaction. If fragments do not fall within this range sonication conditions should be further optimized. 18. If chromatin preparations were successful, the aliquots stored at -80 C from Section D, Step 4 can be used to perform the ChIP reactions in Section F. Figure 3: Validation of chromatin shearing efficiency following reversal of cross-links overnight at 65 C. Chromatin preparations were fixed and sonicated using the EpiShear Probe Sonicator and EpiShear Cooled Sonication Platform from Active Motif. Input DNA was prepared in duplicate according to Section D, Steps 5-16 in the manual. In Sample 1, Step 17 was not performed and 500 ng of input DNA was loaded directly onto a 1.5% agarose gel without receiving the addition of NaCl and incubation at 100 C. The omission of Step 17 has caused a buffer artifact that makes the DNA appear larger on a gel. The duplicate sample, Sample 2, was processed according to the manual instructions and included the addition of NaCl and incubation at 100 C as stated in Step 17. Analysis of 500 ng of this input DNA on a 1.5% agarose gel shows the expected fragmentation between bp. The difference in DNA sizing on the gel between the two samples illustrates the importance of following the protocol recommendations regarding the processing of input chromatin for agarose gel analysis prior to chromatin immunoprecipitation. Omission of key steps can lead to inaccurate analysis of chromatin shearing efficiency. If the protocol steps were followed and the DNA fragments fall outside of the recommended range, sonication conditions should be further optimized. 20

24 Section E. Antibody Conjugation to Protein G Beads Successful chromatin immunoprecipitation depends on the quality of the ChIP antibody and the abundance of the target protein. ChIP antibodies must recognize fixed, native protein that is bound to DNA and/or complexed with other proteins. Many antibodies that perform well in other applications do not perform in ChIP. Therefore, we recommend using a ChIP-validated antibody for conjugation to the Protein G beads. For information regarding the use of the magnetic beads and the included bar magnet and glue dots, please refer to Appendix Section S. 1. Determine the number of immunoprecipitation reactions needed using the table below as a guide. We recommend using the chromatin extracted from 15 million cells in 3 independent IP reactions. These IP reactions will be pooled at the end of the protocol to produce a single sample for sequencing. Scaling quantities into a single tube will reduce the efficiency of the IP and is not recommended. Prepare labeled tubes based on the number of reactions. 15 million cells 30 million cells 45 million cells Tissue Small Vol. Tissue Large Vol. # Cell Culture Plates 1 x 150 mm 2 x 150 mm 3 x 150 mm N/A N/A Sonication Volume 1 x 500 µl 2 x 500 µl 3 x 500 µl 1 x 500 µl 2 x 500 µl # Chromatin Tubes Section B.4 or D.4 3 x 150 µl 6 x 150 µl 9 x 150 µl 3 x 150 µl 6 x 150 µl Required # IP rxns 3 IP rxns 6 IP rxns 9 IP rxns 3 IP rxns 6 IP rxns 2. Resuspend the Protein G magnetic bead vial by end-to-end rotation for 5 minutes at room temperature. Magnetic beads have a tendency to settle to the bottom of the tube and it is important to resuspend the contents completely before use. Following resuspension, use a wrist flick to collect beads out of the cap prior to opening the vial. 3. Aliquot 50 µl Protein G magnetic beads to each labeled tube prepared in Step Add 1 ml Blocking Buffer AM3 to each tube. Gently flick to mix. Place beads against the magnet and allow beads to collect to the side of the tube. Carefully remove and discard the supernatant without disturbing the beads. 5. Repeat Step 4 two more times for a total of 3 Blocking Buffer washes. 6. Resuspend the beads in 250 µl Blocking Buffer AM3. 7. Add 10 µg antibody (15 µl antibody if the concentration is unknown) per IP tube. Incubate the reactions for 4 hours to overnight at 4 C with end-to-end rotation. 8. Centrifuge the tubes at 8,150 x g for 20 seconds to collect the contents to the bottom. 9. Place the tubes on the magnet to separate. Remove and discard the supernatant. Add 1 ml ice-cold Blocking Buffer AM3 and gently flick to mix. 10. Place the tubes on the magnet to separate. Remove and discard the supernatant. Add 1 ml room temperature ChIP Buffer and gently flick to mix. 11. Using the magnet, remove and discard the supernatant. Resuspend the beads in 150 µl ChIP Buffer supplemented with 5 µl Protease Inhibitor Cocktail. 21

25 Section F. Chromatin Immunoprecipitation Chromatin is added to the antibody-conjugated Protein G beads for capture of the protein/dna binding interactions of interest. 1. Thaw the 3 x 150 µl aliquots of sonicated chromatin per sample (from Section B.4 or Section D.4) on ice. Spin chromatin at 4 C in a microcentrifuge at maximum speed for 2 minutes. 2. Add 150 µl of chromatin per tube of antibody-conjugated beads. The total volume of the IP is 305 µl per tube. 3. Incubate on an end-to-end rotator overnight at 4 C. 4. Quick spin the tubes to collect the liquid to the bottom. Using the magnetic stand, remove and discard the supernatant. 5. Wash each reaction with 1 ml Wash Buffer AM1 supplemented with 5 µl PIC. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. 6. Repeat this wash five more times. 7. Wash each reaction with 1 ml of Wash Buffer AM6. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. 8. Add 1 ml Wash Buffer AM6 to each tube. Allow reactions to sit in wash buffer while preparing the reaction mix needed for End Repair in Section G below. Section G: Perform End Repair This section is designed to perform end repair of the immunoprecipitated samples while they are bound to the Protein G magnetic beads. End repair creates blunt ends for adapter ligation. 1. In a new microcentrifuge tube, prepare the End Repair master mix. Reagents Per rxn 3 rxns 6 rxns 9 rxns 12 rxns dh 2 O 76 µl µl µl µl µl 10X Reaction Buffer AM3 10 µl 31 µl 61 µl 91.5 µl 122 µl 100 mm ATP 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl dntp Mix, X(5) mm each 2 µl 6.2 µl 12.2 µl 18.3 µl 24.4 µl T4 DNA Polymerase (3 U/µl) 5 µl 15.5 µl 30.5 µl 45.8 µl 61 µl DNA Polymerase I Klenow (5 U/µl) 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl T4 Polynucleotide Kinase (10 U/µl) 5 µl 15.5 µl 30.5 µl 45.8 µl 61 µl Total Volume 100 µl 310 µl 610 µl 915 µl 1220 µl 2. Once the End Repair reaction mixture is ready, place the IP samples from Section F.8 on a magnetic stand. Remove and discard the supernatant. Immediately add 100 µl per tube of the End Repair reaction and pipette up and down to mix. 22

26 3. Place the tubes in a thermal mixer set to shake at 960 rpm with a set temperature of 30 C. Incubate for 30 minutes. Note: The use of a thermal mixer greatly enhances the efficiency of the reaction. If a thermal mixer is not available, place tubes in a heat block or water bath set to 30 C. Flick the tubes with your fingers every 5 minutes during the 30 minute incubation to ensure proper mixing. 4. Place the tubes on the magnet to separate. Remove and discard the supernatant. Add 1 ml Wash Buffer AM1 and pipette up and down to mix. 5. Repeat Step 4 one more time. 6. Wash each reaction with 1 ml of Wash Buffer AM6. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. 7. Add 1 ml Wash Buffer AM6 to each tube. Allow reactions to sit in wash buffer while preparing the reaction mix needed for Ligation of Adapters in Section H below. Section H: Ligation of P7 Exo-Adapter This protocol is for ligation of P7 exo-adapters to the ends of the immunoprecipitated chromatin. 1. In a new microcentrifuge tube, set up the Adapter Ligation master mix as follows: Reagents Per rxn 3 rxns 6 rxns 9 rxns 12 rxns dh 2 O 78 µl µl µl µl µl 10X Reaction Buffer AM3 10 µl 31 µl 61 µl 91.5 µl 122 µl 15 µm P7 exo-adapter 10 µl 31 µl 61 µl 91.5 µl 122 µl 100 mm ATP 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl T4 DNA Ligase (2000 U/µl) 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl Total Volume 100 µl 310 µl 610 µl 915 µl 1220 µl 2. Once the Adapter reaction mixture is ready, place the IP samples from Section G.7 on a magnetic stand. Remove and discard the supernatant. Immediately add 100 µl per tube of the Adapter Ligation mixture and pipette up and down to mix. 3. Place the tubes in a thermal mixer set to shake at 960 rpm with a set temperature of 25 C. Incubate for 1 hour. Note: The use of a thermal mixer greatly enhances the efficiency of the reaction. If a thermal mixer is not available, place tubes in a heat block or water bath set to 25 C. Flick the tubes with your fingers every 5 minutes during the 1 hour incubation to ensure proper mixing. 4. Place the tubes on the magnet to separate. Remove and discard the supernatant. Add 1 ml Wash Buffer AM1 and pipette up and down to mix. 23

27 5. Repeat Step 4 one more time. 6. Wash each reaction with 1 ml of Wash Buffer AM6. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. 7. Add 1 ml Wash Buffer AM6 to each tube. Allow reactions to sit in wash buffer while preparing the reaction mix needed for Nick Repair in Section I below. Section I: Nick Repair This protocol is used to fill in overhangs and repair DNA nicks following P7 exo-adapter ligation. 1. In a new microcentrifuge tube, set up the Nick Repair master mix as follows: Reagents Per rxn 3 rxns 6 rxns 9 rxns 12 rxns 1X Phi29 Reaction Buffer 95.5 µl 296 µl µl µl µl dntp Mix, 5 mm each 3 µl 9.3 µl 18.3 µl 27.5 µl 36.6 µl Phi29 DNA polymerase (10 U/µl) 1.5 µl 4.7 µl 9.2 µl 13.7 µl 18.3 µl Total Volume 100 µl 310 µl 610 µl 915 µl 1220 µl 2. Once the Nick Repair mixture is ready, place the IP samples from Section H.7 on a magnetic stand. Remove and discard the supernatant. Immediately add 100 µl per tube of the Nick Repair mixture and pipette up and down to mix. 3. Place the tubes in a thermal mixer set to shake at 960 rpm with a set temperature of 30 C. Incubate for 20 minutes. Note: The use of a thermal mixer greatly enhances the efficiency of the reaction. If a thermal mixer is not available, place tubes in a heat block or water bath set to 30 C. Flick the tubes with your fingers every 5 minutes during the 20 minute incubation to ensure proper mixing. 4. Place the tubes on the magnet to separate. Remove and discard the supernatant. Add 1 ml Wash Buffer AM1 and pipette up and down to mix. 5. Repeat Step 4 one more time. 6. Wash each reaction with 1 ml of Wash Buffer AM6. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. 7. Add 1 ml Wash Buffer AM6 to each tube. Allow reactions to sit in wash buffer while preparing the reaction mix needed for the Lambda Exonuclease Digestion reaction in Section J below. 24

28 Section J: Lambda Exonuclease Digestion This protocol is to perform 5 to 3 exonuclease digestion of the double-stranded DNA. Digestion occurs along the 5 to 3 strands and trims away DNA that is not protected by binding of the target protein to the chromatin. 1. In a new microcentrifuge tube, set up the Lambda Exonuclease master mix as follows: Reagents Per rxn 3 rxns 6 rxns 9 rxns 12 rxns dh 2 O 88 µl µl µl µl µl 10X Lambda Exonuclease Buffer 10 µl 31 µl 61 µl 91.5 µl 122 µl Lambda exonuclease (5 U/µl) 2 µl 6.2 µl 12.2 µl 18.3 µl 24.4 µl Total Volume 100 µl 310 µl 610 µl 915 µl 1220 µl 2. Once the Lambda Exonuclease mixture is ready, place the IP samples from Section I.7 on a magnetic stand. Remove and discard the supernatant. Immediately add 100 µl per tube of the Lambda Exonuclease mixture and pipette up and down to mix. 3. Place the tubes in a thermal mixer set to shake at 960 rpm with a set temperature of 37 C. Incubate for 30 minutes. Note: The use of a thermal mixer greatly enhances the efficiency of the reaction. If a thermal mixer is not available, place tubes in a heat block or water bath set to 37 C. Flick the tubes with your fingers every 5 minutes during the 30 minute incubation to ensure proper mixing. 4. Place the tubes on the magnet to separate. Remove and discard the supernatant. Add 1 ml Wash Buffer AM1 and pipette up and down to mix. 5. Repeat Step 4 one more time. 6. Wash each reaction with 1 ml of Wash Buffer AM6. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. 7. Add 1 ml Wash Buffer AM6 to each tube. Allow reactions to sit in wash buffer while preparing the reaction mix needed for the RecJf Exonuclease Reaction in Section K below. Section K: RecJf Exonuclease Digestion This protocol is to remove the deoxynucleotide monophosphates from single-stranded DNA following the lambda exonuclease digestion. 1. In a new microcentrifuge tube, set up the RecJf Exonuclease master mix as follows: Reagents Per rxn 3 rxns 6 rxns 9 rxns 12 rxns dh 2 O 89 µl µl 543 µl µl 1086 µl 10X Reaction Buffer AM3 10 µl 31 µl 61 µl 91.5 µl 122 µl 25

29 RecJf exonuclease (30 U/µl) 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl Total Volume 100 µl 310 µl 610 µl 915 µl 1220 µl 2. Once the RecJf Exonuclease mixture is ready, place the IP samples from Section J.7 on a magnetic stand. Remove and discard the supernatant. Immediately add 100 µl per tube of the RecJf Exonuclease mixture and pipette up and down to mix. 3. Place the tubes in a thermal mixer set to shake at 960 rpm with a set temperature of 37 C. Incubate for 30 minutes. Note: The use of a thermal mixer greatly enhances the efficiency of the reaction. If a thermal mixer is not available, place tubes in a heat block or water bath set to 37 C. Flick the tubes with your fingers every 5 minutes during the 30 minute incubation to ensure proper mixing. 4. Place the tubes on the magnet to separate. Remove and discard the supernatant. Add 1 ml Wash Buffer AM1 and pipette up and down to mix. 5. Repeat Step 4 one more time. 6. Wash each reaction with 1 ml of Wash Buffer AM6. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. 7. Add 1 ml Wash Buffer AM6 to each tube. Pipette up and down three times to mix. Using the magnetic stand, remove and discard the supernatant. Proceed immediately to Section L: Reversal of Cross-links and Elution from the Beads below. Section L. Reversal of Cross-links and Elution from the Beads This section is designed to reverse the protein cross-links and elute the ChIP-enriched DNA from the Protein G magnetic beads. 1. Add 200 µl Elution Buffer AM4 to each reaction tube. 2. Add 10 µl Proteinase K to each reaction tube. 3. Place the tubes in a thermal mixer set to shake at 960 rpm with a set temperature of 55 C. Incubate for 30 minutes. Note: The use of a thermal mixer greatly enhances the efficiency of the reaction. If a thermal mixer is not available, place tubes in a heat block or water bath set to 55 C. Flick the tubes with your fingers every 5 minutes during the 30 minute incubation to ensure proper mixing. 4. Following the incubation, increase the temperature of the thermal mixer/heat block to 80 C to heat inactivate the Proteinase K. Incubate samples at 80 C for 2 hours. Mixing is not required during this step. 26

30 Section M. DNA Purification This protocol is for the removal of the inactive Proteinase K and purification of the DNA. 1. Remove the tubes from the thermal mixer/heat block and allow to cool to room temperature. 2. Place tubes on the magnet to separate. Transfer the supernatant into a new microcentrifuge tube. This contains the eluted ChIP DNA. 3. Add 250 µl Phenol and 125 µl chloroform/isoamyl alcohol (25:1) to each reaction tube. Vortex 1 minute to mix. 4. Centrifuge at 14,000 rpm for 5 minutes. 5. Collect the aqueous (top) phase and transfer to a new microcentrifuge tube. Determine the volume of the aqueous phase (~200 µl). 6. Add 5 M NaCl to achieve a final concentration of 0.2 M. (For 200 µl volume you will need to add 8 µl 5M NaCl.) 7. Add 1 µl Glycogen to each tube and vortex to mix. 8. Add 650 µl of 100% ethanol to each reaction. Vortex to mix and place at -80 C to precipitate for 1 hour to overnight. 9. Following the incubation, centrifuge the tubes at 14,000 rpm for 20 minutes in a refrigerated microcentrifuge set to 4 C. There should be a visible pellet of precipitated DNA following the centrifugation. Note: If there is no visible pellet following centrifugation, there is a very high probability that the ChIP-exo reaction has failed. We recommend that you repeat the experiment from the beginning. 10. Carefully remove and discard the supernatant without disturbing the pellet. Add 500 µl icecold 70% ethanol to each tube. Centrifuge at 14,000 rpm for 10 minutes. 11. Carefully remove and discard the supernatant without disturbing the pellet. Allow the pellet to air dry for minutes. Drying time depends on how efficiently the liquid was removed following centrifugation. Make sure the traces of ethanol have evaporated and the pellet is dry, but do not extend drying time for prolonged periods beyond what is needed as this makes it more difficult to resuspend the pellet. 12. Resuspend the pellet in 20 µl sterile water. Vortex the sample for 10 seconds to aid in resuspension of the DNA pellet. Quick spin the tubes to collect the liquid. The DNA can be stored at -20 C at this stage. If the DNA is stored, we recommend heating the samples at 37 C for 10 minutes prior to use to ensure the DNA is fully dissolved. 27

31 Section N. P7 Primer Extension In this section, the P7 primer anneals to the P7 exo-adapter sequence that was added in Section H, and the Phi29 Polymerase extends the DNA sequence to create double-stranded DNA. 1. Transfer 20 µl of each ChIP-exo DNA into a 200 µl PCR tube. 2. Heat the samples for 5 minutes at 95 C. While the samples are incubating, prepare the Primer Extension Reaction mixture below. Reagents Per rxn 3 rxns 6 rxns 9 rxns 12 rxns Phi29 Reaction Buffer 29 µl 89.9 µl µl µl µl 5 µm P7 primer 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl Total Volume 30 µl 93 µl 183 µl µl 366 µl 3. Add 30 µl Primer Extension mixture to each tube and pipette up and down to mix. 4. Place tubes in a PCR instrument and program as below. Please note that additional components need to be added to the reactions within 7 minutes of starting the PCR program. Have these reagents on ice and ready for addition into the tubes in advance of starting the program. There is an additional 10 minutes built into the program to accommodate the addition of reagents without the need to pause the machine. 65 C for 5 minutes 30 C for 30 minutes* 65 C for 10 minutes 4 C Hold * Once the PCR program has completed the first 2 minutes of the 30 C cycle, remove the samples and add 1 µl Phi29 Polymerase and 2.1 µl dntps (5 mm each) to each tube. Mix by pipetting up and down and return the samples back to the PCR instrument. Allow the program to continue to completion with the 4 C hold. 5. Once the PCR is finished, place the samples at room temperature. 6. Add 90 µl AMPure beads to each reaction. Pipette up and down repeatedly (~10 times) to ensure a homogenous mixture. 7. Place the tubes on the magnet to separate. Remove and discard the supernatant. 8. Without removing the tubes from the magnet, add 200 µl ice-cold 70% ethanol to wash the beads. Allow beads to sit in the ethanol wash for 30 seconds before removing and discarding the supernatant. 9. Repeat Step 8 one more time. 10. Without removing the tubes from the magnet, allow the beads to air dry for 20 minutes. 11. Remove the tubes from the magnet and resuspend the beads in 20 µl DNA Purification Elution buffer. Pipette up and to mix. 12. Place the tubes on the magnetic stand to separate. Transfer supernatant to a new PCR tube. 28

32 Section O. Ligation of P5 Exo-Adapter In this section the P5 exo-adapters are added to the DNA. These adapters will serve as binding sites for the indexing primers during PCR amplification. 1. In a new microcentrifuge tube set up the P5 Adapter master mix as follows: Reagents Per rxn 3 rxns 6 rxns 9 rxns 12 rxns dh 2 O 23 µl 71.3 µl µl µl µl 10X T4 DNA Ligase Buffer 5 µl 15.5 µl 30.5 µl 45.8 µl 61 µl 15 µm P5 adapter 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl T4 DNA Ligase (2000 U/µl) 1 µl 3.1 µl 6.1 µl 9.2 µl 12.2 µl Total Volume 30 µl 93 µl 183 µl µl 366 µl 2. Add 30 µl of the P5 Adapter Mix to each PCR tube. Pipette up and down to mix. 3. Place reactions in a PCR instrument set to 25 C for 1 hour. 4. Following the incubation, remove the samples and add 90 µl AMPure beads to each tube. Pipette up and down repeatedly (~10 times) to ensure a homogenous mixture. 5. Place the tubes on the magnet to separate. Remove and discard the supernatant. 6. Without removing the tubes from the magnet, add 200 µl ice-cold 70% ethanol to wash the beads. Allow beads to sit in the ethanol wash for 30 seconds before removing and discarding the supernatant. 7. Repeat Step 6 one more time. 8. Without removing the tubes from the magnet, allow the beads to air dry for 20 minutes. 9. Remove the tubes from the magnet and resuspend the beads in 20 µl DNA Purification Elution buffer. Pipette up and down to mix. 10. Place the tubes on the magnetic stand to separate. Transfer the supernatant to a new 200 µl PCR tube. 29

33 Section P: PCR Amplification of the DNA Library In this section, the DNA library is PCR amplified. Each Indexing primer included in the kit can be used to process 6 reactions. If your experiment requires more than 6 reactions you will need to use both Indexing primers. If needed, the sequencing information generated from the different primers can be merged together during bioinformatic analysis. Additional Indexing primers are available at /chipexo. The barcode sequence for the Indexing primers included in the kit are listed below. The index barcode is the reverse complement of the Illumina adapter sequence. Please refer to the corresponding Illumina adapter sequence to confirm the compatiblity of your sample when multiplexing your sequencing run. Indexing primer 2 = ACATCG corresponds to Illumina adapter barcode CGATGT Indexing primer 4 = TGGTCA corresponds to Illumina adapter barcode TGACCA 1. In a new microcentrifuge tube, set up the PCR Amplification master mix as follows: Reagents Per rxn 3 rxns 6 rxns dh 2 O 14 µl 43.4 µl 85.4 µl 5X Q5 Reaction Buffer 10 µl 31 µl 61 µl dntps, 5 µm each 3 µl 9.3 µl 18.3 µl Indexing primer 2 or Indexing primer 4** 2 µl 6.2 µl 12.2 µl Q5 High-Fidelity Polymerase 1 µl 3.1 µl 6.1 µl Total Volume 30 µl 93 µl 183 µl ** Indexing primers are specific for working with the Illumina sequencing platforms. These index primers contain a short barcode sequence that allows for individual identification of samples within a mixed population. Two index primers are included in the assay kit that may be used to combine two samples together within a single sequencing lane. 2. Add 30 µl of the PCR amplification mix to each DNA sample. 3. Place tubes in a PCR instrument and program as follows: 95 C for 90 seconds (98 C for 10 seconds, 65 C for 30 seconds, 72 C for 30 seconds) for 14 cycles 72 C for 5 minutes 4 C Hold 4. Once the PCR is finished, remove the samples from the machine and place at room temperature. 5. Add 90 µl AMPure beads to each reaction. Pipette up and down repeatedly (~10 times) to ensure a homogenous mixture. 6. Place the tubes on the magnet to separate. Remove and discard the supernatant. 7. Without removing the tubes from the magnet, add 200 µl ice-cold 70% ethanol to wash the beads. Allow beads to sit in the ethanol wash for 30 seconds before removing and discarding the supernatant. 30

34 8. Repeat Step 7 one more time. 9. Without removing the tubes from the magnet, allow the beads to air dry for 20 minutes. 10. At this stage, the three IP reactions that were set up from one 15 million cell pellet will be recombined into a single tube. Remove the tubes from the magnet and add 30 µl DNA Purification Elution buffer to the first tube of beads. Pipette up and to mix. Once these beads are fully resuspended, transfer the solution to the second tube of beads. Pipette up and to mix. Once these beads are fully resuspended, transfer the solution to the third tube of beads. Pipette up and to mix. This tube should now contain all the beads from the 3 IP reactions in approximately 30 µl volume. 11. Place the tubes on the magnetic stand to separate. Transfer the supernatant to a new PCR tube. This contains the eluted DNA library. Section Q: Size Select the Library This process selects a size range of DNA templates. 1. Prepare a 1.5% agarose TAE gel with 400 ng/ml ethidium bromide using a large-well comb. Note: Ethidium bromide is a mutagen. Use appropriate precaution when handling. 2. Add 5X loading dye to each DNA sample so that the final concentration is 1X. 3. Run the entire PCR amplified DNA Library from Step P.11 and 500 ng of 100 bp DNA ladder on a 1.5% agarose gel for size selection of the DNA library. To avoid potential cross contamination of adjacent wells, leave at least one empty lane between DNA ladder and sample wells. 4. Run the gel at 120V for ~1 hour or until the tracking dye is 2/3 down the length of the gel. 5. Visualize the DNA using a Dark Reader transilluminator to avoid exposure to UV light. If using a UV light, work quickly when excising the band to minimize direct exposure to UV. Prolonged exposure to UV light can damage DNA. 6. Using a clean razor blade, excise a gel slice in the bp range. We recommend to photograph the gel before and after the band is excised. 7. Use a QIAquick Gel Extraction Kit (QIAGEN Cat. No ) to purify the DNA from the agarose. Make the following protocol modifications to the QIAquick Gel Extraction Kit protocol: a. QIAquick columns can handle a maximum of 400 mg agarose. If using a larger quantity of agarose, you will need to split your sample across multiple columns. 31

35 b. Incubate the gel slice in 3 volumes Buffer QG at 37 C for 30 minutes instead of the suggested 50 C for 10 minutes. Buffer volumes and incubation times are dependent upon the thickness of the gel and may need to be adjusted based on your sample. If necessary, add additional Buffer OG and increase the duration of the 37 C incubation. c. Add the recommended extra 0.5 ml Buffer QG to the QIAquick column. d. During the wash steps, incubate 2-5 minutes in Buffer PE before centrifugation. e. Elute the DNA in 20 µl Buffer EB. 8. The size selected DNA library is now ready for downstream analysis. For sequencing, we recommend 40 million reads. This generally returns results between million read counts. If the numbers fall below this range the samples may need to be resubmitted for another sequencing run. Alternatively, PCR walking primers can be developed to confirm the exonuclease digestion of the ChIP DNA prior to sequencing (see Appendix Section T). Section R: Recommendations for Data Analysis The following information is included to provide guidance for data analysis of sequencing results and represents one program we have successfully utilized for analysis of ChIP-exo sequencing reads. Alternative programs are available and may be used for analysis. Please note that data output from other programs will use different algorithms and result in different border length values. Therefore, results should not be compared across programs. Active Motif is not responsible for analysis of the sequencing data or for tracking modifications or changes that are made to the software program over time. Recommendations are provided as guidelines only. Specific inquiries regarding analysis programs and files should be directed towards your bioinformatics provider. 1. When your sequencing files are returned, we suggest running a filter step. 2. Align the sequences to the human genome. 3. Covert the.sam files to.bam files. (A.BAM file is a.sam file but stored in binary. Conversion will save storage space and make it faster to manipulate files.) 4. Sort your.bam files 5. Index your.bam files 6..BAM files can be used in your analysis software. We recommend using a program designed for analysis of ChIP-exo data called MACE (Model-Based Analysis of ChIP-exo). MACE will look at the border peaks on either side of the transcription factor/protein binding site and will give very concise sequence information. More traditional analysis programs, such as MACS, may also be used. These programs may require additional manipulations to generate summit length values which represent the range between the two peaks of the forward and reverse peak strands. This range will be broader than the range defined by MACE and therefore will have lower resolution of binding site identification. Because of the decrease in resolution, we suggest using MACE for analysis and have guidelines to run the program below. For any MACE-specific questions, or to download the software, please visit: 32

36 Move to directory containing your.bam files. The program may take 4 hours or more to run. The data output will be in the form of.bw (BigWiggle) files and.bed files. These files can be loaded into the UCSC genome browser to examine binding sites by looking at either the elite_border_pairs or the Gale-Sharpley Paired Border, GSB border_pairs. You will also have SFB and SRB borders, which are single direction binding events (forward or reverse) that do not have a pair. These may or may not represent true binding sites and should be evaluated further. ChIP-seq Cells Reads Alignments Total Peaks Avg. Binding Site Length FoxA1 MCF-7 95, bp MACS Cells Reads Alignments Total Peaks Avg. Binding Site Length AM 2x ,044,067 41,028, , bp Published 10x ,348,662 13,465,289 78, bp MACE Cells Reads Alignments Total Peaks Avg. Binding Site Length AM 2x ,044,067 41,028,096 3, bp Published 10x ,793,798 26,985,549 6, bp Figure 4: Example of data analysis from ChIP-exo with transcription factor FoxA1. Active Motif s ChIP-exo Kit was used to analyze transcription factor FoxA1 for comparison to published data. Bioinformatic analysis was performed using both MACS and MACE programs. The data displays comparable results between the kit and published results. The identified FoxA1 binding sites are significantly smaller for ChIP-exo than traditional ChIP-seq results. This data shows the reproducibility of the assay for binding site identification. 33

37 { Published (10x10 7 cells) Binding Site = 70 bp { AM (2x10 7 cells) Binding Site = 14 bp Fw Rv Fw Rv FoxA1 ChIP-exo from MCF-7 Cells Reported FoxA1 Binding Site (215 bp) Figure 5: BigWig graphs comparing Active Motif s ChIP-exo data with published ChIP-exo data for FoxA1. To generate Active Motif s ChIP-exo results (AM) for FoxA1, 100 μg of chromatin obtained from 20 million MCF-7 cells was fragmented and ChIP was performed using the ChIP-exo Kit with antibodies against FoxA1. Results were compared with published results (Published) for FoxA1 obtained by performing ChIP-exo on fragmented chromatin generated from 100 million MCF-7 cells as described previously by Serandour et al. (Ref 6). Data was aligned to the hg19 human reference genome using Bowtie. The BigWig graphs were generated using the ChIP-exo-specific analysis software: MACE (Model based Analysis of ChIP-exo). These results demonstrate that Active Motif s ChIP-exo method achieves comparable resolution of binding motifs as the published data for FoxA1 using a fraction of the starting cell numbers used to obtain the published data. Results overlap with reported FoxA1 binding sites. 34

38 Appendix Section S. Use of Magnetic Beads and Included Bar Magnet The magnet should be stored in the provided tube. Be careful when working near metal objects or surfaces. A free magnet will jump great distances onto nearby metal surfaces with surprising speed. This can break the magnet. Use the provided Mini Glue Dots to attach the bar magnet to an empty pipette tip box to create an effective magnetic stand for use with either PCR strips or microcentrifuge tubes. If the magnet becomes attached to a flat metal surface, it should be removed by sliding it off the edge of the surface. The magnet may break if you attempt to pull one end or pry it away from the metal. Caution: The included neodymium bar magnet is extremely powerful and is easily broken if handled incorrectly. Creating a magnetic stand for 8-well PCR strips: Note: 8-well strip tubes for use with standard 96-well PCR cyclers are recommended (e.g. Thermo Fisher AB-0451). 1. Place a strip of PCR tubes in the wells of an empty tip box (200 µl tips) and place the magnet directly against the tubes. This is the way the magnet will be positioned when the glue dots are used to affix it to the box. 2. Remove the covering tape from one side of two glue dots and attach the glue dots on the bar magnet (the uncovered face of the dot is placed on the magnet) as shown below. 3. Remove the covering tape from the exposed side of the glue dots. Fix the magnet to the tip box so that it is against the PCR tubes. The magnetic stand is now ready for use. Note: Familiarize yourself with using the magnetic stand before performing with PCR tubes for the first time. Add 5 µl of magnetic beads to 100 µl ChIP Buffer in one tube of an 8-well strip of PCR tubes. Use this tube with the assembled bar magnet stand to become familiar with use of the beads and magnet. It is difficult to re-suspend the beads if the tubes are directly adjacent to the magnet, so it is best to move the tubes away from the magnet for resuspension steps. 35

39 Washing should be performed as follows: a. Place the tubes in the rack against the magnet and allow the beads to be pinned to the side of the tube, as shown below. b. Remove supernatant with a 200 µl pipetteman or a 200 µl eight-channel pipetteman. c. Move the tube strip into a row that is not adjacent to the magnet. d. Add wash buffer and pipet up and down to fully re-suspend the beads. Ensure that a minimal amount of beads cling to the tips when the re-suspension is complete. e. Repeat steps a-d until desired washing steps are complete. Centrifugation of 8-well PCR strip tubes: When working with 8-well PCR strip tubes, it may be desirable to centrifuge the tubes to collect the liquid and beads from the insides of the caps. This is easily accomplished in a centrifuge fitted with adaptors for spinning microtiter plates. Place a standard 96-well plate in the adaptor to hold the tubes in place. Be sure to balance the rotor (i.e. place a microtiter plate and tubes of appropriate mass in the rotor s opposing 96-well plate adaptor). Spin the plates briefly to let the rotor reach a speed of 1000 x g before allowing the rotor to stop. Creating a magnetic stand for 1.7 ml microcentrifuge tubes: 1. Remove the covering tape from one side of two glue dots. 2. Place two 1.7 ml microcentrifuge tubes in the wells of an empty tip box (1000 µl) and place the magnet directly against the tubes. This is the way the magnet will be positioned when the glue dots are used to affix it to the box. 36

40 3. Attach the glue dots on the bar magnet (the uncovered face of the dot is placed on the magnet) as shown above. 4. Remove the covering tape from the exposed side of the glue dot. Fix the magnet to the tip box so that it is against the tubes. The magnetic stand is now ready for use. Note: 1.7 ml microcentrifuge tubes are held less securely in this assembled tube stand than in a typical commercial magnetic stand. This is not a problem if the below washing protocol is followed. Work with 1 tube at a time, and keep the tubes in the standard tube rack unless you are holding the tube next to the magnet. Washing is best performed one tube at a time, as follows: 1. Place the tube in a standard 1.7 ml microcentrifuge tube rack and open the cap. 2. Place the opened tube in the assembled magnetic stand. The beads will pellet more rapidly if the bottom of the tube is held against the magnet, as shown below, and then slowly lowered into the well. This will pellet the beads up onto the side of the tube. 3. Allow the beads to pellet completely and remove supernatant with a 1000 µl pipetteman. You can either leave the tube in the rack or pull it out when you remove the buffer. The beads will remain on the side of the tube, even when not next to the magnet. 4. Return the tube to the standard microcentrifuge tube rack, add wash buffer and fully resuspend the beads by pipetting up and down. 5. After the final wash has been removed, the last traces of wash buffer should be removed with a 200 µl pipetteman. 37

41 Section T: Walking Primer Design Walking primers can be utilized to confirm the success of the ChIP-exo efficiency prior to submitting samples for sequencing. Primers are designed to a known protein binding site based on ENCODE data sets. A series of primers are created which will cover the binding site and 400 bp upstream and 400 bp downstream of the binding site. If the ChIP-exo reaction was successful, the exonuclease digestion should trim away the DNA sequence that was not associated directly with the protein binding site. As a result, primers designed to DNA sequences far away from the binding site will not generate a PCR amplicon, while primers in the immediate vicinity of the binding site should generate a PCR amplicon. This provides a quick, visual assessment of the efficiency of the exonuclease reaction. Samples that are successful should then be submitted for sequencing. A. Design of the primers Design and analyze your potential primer pairs using the ENCODE information on the UCSC Genome Browser at Select the genome and assembly to search. Under Regulation, ensure that the Encode Transcription Factor Binding (ENC TF Binding) is showing. Refresh if necessary. Click the link for the ENC TF BInding and select the track to display. As a default you can use Uniform TFBS. Search for the protein of interest and the cell line that you will be using. Please note that EN- CODE does not contain data for all transcription factors, cell lines or combinations thereof. For simplicity, it is best to remove any unrelated transcription factors and cell lines from the search. Submit the search. Under Mapping and Sequencing, ensure that Assembly is showing. Go to a known binding site of interest and zoom in. Select a known binding site sequence which covers ~200 bp. The goal is to capture the DNA sequence that lies 400 bp upstream and 400 bp downstream of your desired binding site for primer design. Once you have identified your region of interest, right click on the Assembly track and select Get DNA for. Then, input the range of interest and get DNA. Obtain the DNA sequence that lies ~400 bp upstream and ~400 bp downstream of your desired binding site. Within the sequence identified as a binding site for your protein, try and determine the binding motif using Factorbook ( If the motif cannot be determined, use the absolute center of the binding site sequence. Using the identified motif or center of binding sequence, design a collection of primers that will cover 100 bp, 200 bp, 300 bp and 400 bp in each direction from the center. Primers designed on the forward strand should have a universal reverse primer imbedded in the binding site and different forward primers that cover the various DNA lengths upstream of the binding site. Primers designed on the reverse strand should have a universal forward primer imbedded in the binding site and different reverse primers that cover the various DNA lengths downstream of the binding site. 38

42 Use a program such as Primer3plus ( primer3plus.cgi/) to design the primer collection. Try and maintain a constant annealing temperature across the primer pairs to enable all reactions to be performed in the same PCR run. Perform PCR using a 1:20 dilution of the isolated DNA. We recommend 1 µl of diluted DNA per 20 µl PCR reaction according to the manufacturer s instruction for your PCR master mix. An example of primer design strategy and PCR results are shown below. Example of walking primer design. PCR primers are designed using a known protein binding sequence as the center of the binding site. Additional primers are designed at increasing intervals both upstream and downstream of the binding site to determine the efficiency of the exonuclease digestion. Example of ChIP-exo walking primer analysis. PCR primers were designed around a known CTCF binding site. A universal reverse primer was designed using the center of the CTCF binding motif and forward primers were designed to detect DNA sequences at 75 bp, 150 bp, 200 bp, 300 bp and 400 bp upstream of the binding site. The image on the left shows the walking primer results from a successful exonuclease reaction. The primer sets closest to the CTCF binding site amplify readily, while the distant DNA sequences that were targeted by exonuclease digestion show little to no amplification. The image on the right shows a no exonuclease control reaction. In this case a PCR product was produced from all primer sets, indicating that DNA was not digested during ChIP-exo. 39

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