ATAC-seq Assay with Low Mitochondrial DNA Contamination from Primary Human CD4+ T Lymphocytes

Summary

Here, we present a protocol to perform an assay for transposase-accessible chromatin sequencing (ATAC-seq) on activated CD4+ human lymphocytes. The protocol has been modified to minimize contaminating mitochondrial DNA reads from 50% to 3% through the introduction of a new lysis buffer.

Abstract

ATAC-seq has become a widely used methodology in the study of epigenetics due to its rapid and simple approach to mapping genome-wide accessible chromatin. In this paper we present an improved ATAC-seq protocol that reduces contaminating mitochondrial DNA reads. While previous ATAC-seq protocols have struggled with an average of 50% contaminating mitochondrial DNA reads, the optimized lysis buffer introduced in this protocol reduces mitochondrial DNA contamination to an average of 3%. This improved ATAC-seq protocol allows for a near 50% reduction in the sequencing cost. We demonstrate how these high-quality ATAC-seq libraries can be prepared from activated CD4+ lymphocytes, providing step-by-step instructions from CD4+ lymphocyte isolation from whole blood through data analysis. This improved ATAC-seq protocol has been validated in a wide range of cell types and will be of immediate use to researchers studying chromatin accessibility.

Introduction

The assay for transposase-accessible chromatin sequencing (ATAC-seq) has rapidly become the leading method for interrogating chromatin architecture. ATAC-seq can identify regions of accessible chromatin through the process of tagmentation, the fragmenting and tagging of DNA by the same enzyme, to produce libraries with which sequencing can determine chromatin accessibility across an entire genome. This tagmentation process is mediated by the hyperactive Tn5 transposase, which only cuts open regions of chromatin due to nucleosomic steric hindrance. As it cuts, the Tn5 transposase also inserts sequencing adapters that allow for rapid library construction by PCR and next-generation sequencing of genome-wide accessible chromatin^1,2.

ATAC-seq has become the preferred method to determine regions of chromatin accessibility due to the relatively simple and fast protocol, quality and range of information that can be determined from its results, and small amount of starting material required. Compared to DNase-seq³ (which also measures genome-wide chromatin accessibility), MNase-seq⁴ (which determines nucleosome positions in open genome regions), and the formaldehyde-mediated FAIRE-seq⁵, ATAC-seq is faster, cheaper, and more reproducible¹. It is also more sensitive, working with starting material of as few as 500 nuclei, compared to the 50 million nuclei required for DNase-seq³. ATAC-seq also has the ability to provide more information about chromatin architecture than other methods, including regions of transcription factor binding, nucleosome positioning, and open chromatin regions¹. Effective, single-cell ATAC-seq protocols have been validated, providing information on chromatin architecture at the single-cell level^6,7.

ATAC-seq has been used to characterize chromatin architecture across a wide spectrum of research and cells types, including plants⁸, humans⁹, and many other organisms. It has also been critical in identifying epigenetic regulation of disease states⁷. However, the most widely used ATAC-seq protocol includes the major drawback of contamination sequencing reads from mitochondrial DNA. In some data sets, this contamination level can be as high as 60% of sequencing results¹. There is a concerted effort in the field to reduce these contaminating mitochondrial reads in order to allow for the more efficient application of ATAC-seq^7,10,11. Here we present an improved ATAC-seq protocol that reduces the mitochondrial DNA contamination rate to just 3%, allowing reduction of around 50% in sequencing costs¹⁰. This is made possible by a streamlined process of CD4+ lymphocyte isolation and activation and an improved lysis buffer that is critical in minimizing mitochondrial DNA contamination.

This modifiedATAC-seq protocol has been validated with a wide range of primary cells, including human primary peripheral blood mononuclear cells (PBMCs)¹⁰, human primary monocytes, and mouse dendritic cells (unpublished). It has also been used successfully to interrogate melanoma cell lines in a clustered regularly interspaced short palindromic repeats (CRISPR) screen of non-coding elements¹¹. Additionally, the data analysis package described in this protocol and provided on GitHub provides new and experienced researchers with tools to analyze ATAC-seq data. ATAC-seq is the most effective assay to map chromatin accessibility across an entire genome, and modifications to the existing protocol that are introduced here will allow researchers to produce high-quality data with low mitochondrial DNA contamination, reducing sequencing costs and improving ATAC-seq throughput.

Protocol

This improved protocol provides step-by-step instructions for performing ATAC-seq of CD4+ lymphocytes, from the starting material of whole blood through data analysis (Figure 1).

1. Isolation of CD4+ T Cells from Whole Blood

NOTE: The starting material for this protocol is 15 mL of fresh whole blood collected using standard procedures, allowing the source of the starting material to be selected based on research requirements. Scale the protocol as needed. Pre-warm phosphate buffered saline (PBS) + 2% fetal calf serum (FCS) to room temperature (RT) and adjust the centrifuge to RT before starting the CD4+ T cell enrichment procedure.

1. Add 750 µL of human CD4+ T cell enrichment cocktail to 15 mL of whole blood in a 50 mL conical tube and mix gently by inversion. Incubate at RT for 20 min. When incubation is complete, add 15 mL of PBS + 2% FCS to the tube and mix gently by inversion.
2. Prepare a fresh 50 mL conical tube with 15 mL of density medium. Carefully layer the diluted blood sample onto the top of the density medium, being sure not to disrupt the density medium/blood interface that forms. Centrifuge for 20 min at 1,200 x g and RT with acceleration set to 1 and the descending brake OFF.
   NOTE: It is critical to set the acceleration to 1 and descending brake OFF on the centrifuge to avoid disruption of the cell layer in the density medium.
3. Collect the enriched CD4+ T cells from the density medium/plasma interface using a narrow stem transfer pipette. Transfer the collected cells to a fresh 50 mL conical tube. Centrifuge the collected CD4+ T cells for 8 min at 423 x g and RT.
   NOTE: Make sure to return the centrifuge acceleration to 9 and descending brake to ON for step 1.3 and all of the following steps.
4. Discard the supernatant and wash the cell pellet twice with 50 mL of PBS + 2% FCS, centrifuging for 8 min at 423 x g and RT. Discard the final supernatant wash and suspend the washed cell pellet in 2 mL of PBS + 2% FCS.
5. Count cells using a hemocytometer. To continue with ATAC-seq, proceed to step 2.3. To freeze cells for later processing, proceed to step 1.6.
6. Add 1 mL of fresh freezing medium (90% FCS + 10% dimethyl sulfoxide) per 1 million cells. Aliquot 1 mL of cells in freezing medium in cryogenic safe tubes. Place tubes at -80 °C overnight in a slow-freezing container. The next day, transfer tubes to liquid nitrogen for long-term storage.
   NOTE: 1 million CD4+ T cells will be isolated per 2 mL of original volume of whole blood. Freeze 500,000 cells in 1 mL aliquots of freezing medium. Make fresh freezing medium at every use.

2. Activate and Purify CD4+ T Cells

NOTE: This rapid protocol for activating and purifying CD4+ T cells only requires 48 h and results in 95% viable, activated CD4+ T cells. Cool the centrifuge to 4 °C before beginning the protocol.

1. Thaw 1 vial (500,000) of CD4+ T cells in a 37 °C water bath until the ice has just melted. Gently transfer cells to a 15 mL conical tube containing 9 mL of pre-warmed Roswell Park Memorial Institute-1640 (RPMI-1640) media supplemented with 10% FCS, hereafter referred to as complete RPMI.
   NOTE: Do not let cells thaw completely to avoid exposure to DMSO.
2. Centrifuge for 6 min at 1500 x g and 4 °C. Discard the supernatant and gently suspend the pellet in 2 mL of complete RPMI. Repeat the spin down, discard the supernatant, and gently suspend cells in 0.5 mL of complete RPMI.
3. Count the cells using a hemocytometer. Adjust the density of the cell suspension with complete RPMI to plate 50,000 cells in 200 µL per well of a 96-well round bottom plate.
   NOTE: From one frozen tube of 500K CD4+ T cells, plate 10 wells of 50,000 CD4+ T cells in 200 µL per well.
4. Prepare magnetic beads conjugated with human T-activator anti-CD3 and anti-CD28 antibodies.
   1. Aliquot 12.5 µL of human T-activator CD3/CD28 beads per ATAC-seq sample to a 1.5 mL tube. Wash the beads with 1 mL of 1x PBS and place the tube on a magnet for 1 min.
   2. Carefully remove and discard the clear supernatant, remove the tube from magnet, and suspend the beads in 13 µL complete RPMI per ATAC-seq sample.
      NOTE: Calculate the amount of beads necessary based on the number of ATAC-seq samples being processed. This protocol requires 12.5 µL of CD3/CD28 beads per 500,000 cells, which constitutes one ATAC-seq sample.
5. Activate the CD4+ T cells. Collect 500,000 cells in 2.1 mL of complete RPMI medium in a 15 mL conical tube and add 12.5 µL of pre-washed human T-activator beads. Mix gently by inverting the tube.
6. Gently transfer the cells with beads to a sterile reservoir and plate 200 µL of cells with beads per well of round bottom 96-well plate using a multi-channel pipette. Incubate for 48 h in a 37 °C, 5% CO₂ incubator.
7. Post incubation, centrifuge the 96-well plate for 8 min at 423 x g and RT. Remove 100 µL of medium per well from the 96-well plate, collecting it to a conical tube before discarding to ensure no bead loss. Resuspend the cell pellet in the remaining 100 µL and collect all in a 1.5 mL tube.
   NOTE: 10 wells of activated T cells will be collected in a 1 mL volume.
8. Perform CD4+ isolation. Add 50 µL of pre-washed CD4 conjugated beads to 500,000 cells in 1 mL of complete RPMI. Combine beads and cells by pipette. Incubate for 20 min at 4 °C in the fridge. Agitate beads and cell mixture every 6 min.
   NOTE: This protocol is to be used for one sample of 500,000 cells. Adjust as necessary for two or more samples of 500,000.
9. When the incubation is complete, place the tube on the magnet for 2 min. Remove and discard the supernatant when clear. Wash the bead-bound cells by removing the tube from the magnet, suspending the bead-bound cells in 1 mL of PBS + 2% FCS, replacing the tube on the magnet for 1 min, and discarding the clear supernatant. Repeat this process for a total of 3 washes.
   NOTE: Be careful not to discard any beads during washes.
10. After the final wash, place the tube on the magnet for 1 min. Remove and discard the supernatant and place the pellet on ice. Proceed to section 3 (ATAC-seq).

3. ATAC-seq

NOTE: In this step, nuclei are isolated from activated CD4+ T cells for ATAC-seq. The lysis buffer used in this protocol has been improved to be gentler on the nuclei, resulting in more efficient digestion and higher quality results. All centrifugation steps in section 3 are performed with a fixed-angle centrifuge maintained at 4 °C. Cool the centrifuge before beginning protocol.

1. Perform nuclei isolation. Resuspend beads and cells with cold lysis buffer (10 mM Tris-HCl, pH 7.4, 10 mM NaCl, 3 mM MgCl2, 0.03% polysorbate 20). Centrifuge immediately at 500 x g for 10 min at 4 °C. Remove and discard the supernatant.
2. Perform the transposase reaction. Suspend the isolated nuclei pellet with 50 µL of Tn5 transposase mix (Table 1). Incubate in a thermocycler for 30 min at 37 °C with a 40 °C lid, holding at 4 °C when complete.
3. After thermocycling, immediately perform a quick benchtop centrifuge spin down and place the tube on the magnet for 1 min to remove the beads from the product.
4. Transfer the clear supernatant from the tube on the magnet to a DNA purification column. Wash the column once with 250 µL of Buffer PB and twice with 750 µL of Buffer PE. Elute the sample in 10 µL of elution buffer. Proceed directly to step 3.5.
   NOTE: This step amplifies the DNA fragments with the ligated adaptors, here referred to as the ATAC-seq library. In order to multiplex several ATAC-seq libraries to be run on one NGS lane, use unindexed Primer 1 for all samples and a different indexed Primer 2 for individual samples (Table 2). Primers are used at working concentrations of 1.25 µM.
5. Set up the initial PCR amplification reaction in a nuclease-free PCR tube, combining the components in the order and volume specified in Table 3. Place the PCR tube into the thermocycler and run the PCR amplification program with cycling conditions as specified in Table 4.
6. Monitor the reaction by qPCR. Set up the qPCR reaction in a nuclease-free PCR tube, combining the components in the order and amount specified in Table 5. Place in qPCR machine and cycle as specified in Table 6.
   1. To determine the optimal number of additional amplification cycles for the remaining 45 µL reaction, create a plot with cycle number on the x-axis and relative fluorescence (RFU) on the y-axis. The optimal number of additional amplification cycles is one-third the number of cycles it takes for the qPCR reaction to reach plateau.
      NOTE: Monitoring the reaction by qPCR allows for determination of the optimal number of PCR cycles desired to obtain optimal library fragment amplification while minimizing GC content and size bias.
7. Complete the final PCR amplification of the remaining 45 µL of PCR reaction. Place the PCR tube with the amplification reaction from step 3.5 back in the thermocycler and run the program as described in Table 7.
   NOTE: For samples processed as described in this protocol, the optimal total number of PCR amplification cycles was determined to be 12.
8. After the amplification is complete, purify the libraries using a PCR cleanup kit following the manufacturer’s protocol, eluting in 25 µL of the elution buffer.
   NOTE: Amplified libraries can be stored at 4 °C for up to 48 h or frozen at -20 °C for long-term storage.

4. ATAC-seq Library Quality Analysis

NOTE: It is important to validate the quality and quantity of ATAC-seq libraries before next-generation sequencing. The quality and quantity of the libraries should be assessed using commercially available kits (see Table of Materials).

1. Assess the quality and quantity of the ATAC-seq libraries using a microfluidics-based platform for sizing, quantification and quality control of DNA. See Figure 2 for representative quality assessment results.
   NOTE: The concentration of the ATAC-seq libraries must be >1 ng/µL to obtain quality sequencing results. On average, 30 nM in 25 µL was obtained.

5. Sequencing and Data Analysis

NOTE: This analysis pipeline allows users to control the quality of reads mapping procedure, adjust coordinates for experimental design, and call peaks for downstream analysis. The following are the commands lines and explanation of execution. The data analysis package is available at (https://github.com/s18692001/bulk_ATAC_seq).

1. Sequence the prepared libraries on a next generation sequencer to an average read depth of 42 million reads per sample.
2. Estimate the quality of sequencing reads by checking files generated by FastQC¹² software package using the command:
   fastqc -o <output_directory> <fastq_file>
3. Trim the bases of reads by Trimmomatic¹³ software, if needed, as determined by the FastQC quality check, using the command (for pair-ended):
   java -jar <path to trimmomatic jar file> PE <input1> <input2> <paired output1> <unpaired output1> <paired output2> <unpaired output2> HEADCROP:<crop bases>
4. Align reads to human reference genome (hg38) by Bowtie2¹⁴ software:
   bowtie2 -x <reference genome> -1 <input pair 1> <input pair 2> -S <output SAM file>
   NOTE: The argument -x is for the basename of the index for the reference genome, and -S is for the SAM format output.
5. Check thequality of mapped reads using Samtools¹⁵ flagstat package:
   samtools flagstat <BAM file>
6. Sort the mapped reads file and remove duplicates using Picard¹⁶ tool:
   java -jar picard.jar SortSam INPUT=<input SAM file name> OUTPUT=<output sorted BAM file name> SORT_ORDER=coordinate” and “java -jar picard.jar MarkDuplicates INPUT=<sorted BAM file> OUTPUT=<output BAM file without duplicates> REMOVE_DUPLICATES=TRUE
7. Index BAM file, trim the unused chromosome reads and shift the coordinates for the experimental reason of ATAC-seq¹⁷:
   java -jar picard.jar BuildBamIndex INPUT=<BAM file>
   samtools idxstats <Input BAM file> | cut -f 1 | grep -v chrY | grep -v chrM | grep -v chrUn | xargs samtools view -b <Input BAM file> > <Output trimmed BAM file>
   bedtools bamtobed -i <Input trimmed BAM file> > <Output trimmed BED file>
   awk 'BEGIN {OFS = "\t"} ; {if ($6 == "+") print $1, $2 + 4, $3 + 4, $4, $5, $6; else print $1, $2 - 5, $3 - 5, $4, $5, $6}' <Input trimmed BED file> <Trimmed shifted BED file>
8. Delete the reads that are shifted to negative coordination:
   awk '{if ($2 > 0) print $1 "\t" $2 "\t" $3 "\t" $4 "\t" $5 "\t" $6 }' <Input BED file> <Output non-negative coordination BED file>.
9. Convert the BED file to BAM file for following DiffBind¹⁸ analysis:
   bedtools bedtobam -i <Input BED file> -g <reference genome> <Output BAM file>
10. Perform peak calling by DiffBind¹⁸ software package:
    macs2 callpeak -t <Input BAM file> -f BAM -g hs -nomodel --nolambda --keep-dup all --call-summits --outdir <Output directory path> -n <Output name> -B -q 0.01 --bdg --shift -100 --extsize 200
    NOTE: After filtering, expect a median of 37 million reads per sample. Mitochondrial DNA contamination will range from 0.30%–5.39% (1.96% on average). There will be a low rate of multiply mapped reads (6.7%–56%, 19% on average) and a relatively high percentage of usable nuclear reads (60%–92%, 79% on average).

Results

From 15 mL of fresh whole blood, this protocol generates an average of 1 million CD4+ T cells. These can be frozen for later processing or used immediately. Viability of the CD4+ T cells, fresh or thawed, was consistently >95%. This method of CD4+ T cell isolation allows for flexibility in source material and collection time. This improved ATAC-seq protocol produces a final library of greater than 1 ng/µL for sequencing. Quality control performed using commercially available syst...

Discussion

The modified ATAC-seq protocol presented in this article provides reproducible results with minimal mitochondrial DNA contamination. The protocol has been used to successfully characterize chromatin architecture of human primary PBMCs¹⁰, human monocytes, mouse dendritic cells (unpublished), and cultured melanoma cell lines¹¹. We anticipate this improved lysis condition has the potential to work for other cell types as well. It is also anticipated that this nuclei isolation ...

Materials

Name	Company	Catalog Number	Comments
1x PBS, Sterile	Gibco	10010023	Can use other comparable products.
5810/5810 R Swing Bucket Refrigerated Centrifuge with 50 mL, 15 mL, and 1.5 mL Tube Buckets	Eppendorf	22625501	Can use other comparable products.
96 Well Round Bottom Plate	Thermo Scientific	163320	Can use other comparable products.
Agilent 4200 Tape Station System	Agilent	G2991AA	Suggested for quality assessment.
Cryotubes	Thermo Scientific	374081	Can use other comparable products.
DMSO	Sigma	D8418	Can use other comparable products.
Dynabeads Human T-Activator CD3/CD28	Invitrogen Life Technologies	11131D	Critical Component
Dynabeads Untouched Human CD4 T Cells Kit	Invitrogen Life Technologies	11346D	Critical Component
Dynamagnet	Invitrogen Life Technologies	12321D	Critical Component
FCS	Gemini Bio Products	100-500	Can use other comparable products.
High Sensitivity DNA Kit	Agilent	50674626	Suggested for quality assessment.
Magnesium Chloride, Hexahydrate, Molecular Biology Grade	Sigma	M2393	Can use other comparable products.
MinElute PCR Purification Kit (Buffer PB, Buffer PE, Elution Buffer)	Qiagen	28004	Critical Component
Mr. Frosty	Thermo Scientific	5100-0001	Can use other comparable products.
NaCl, Molecular Biology Grade	Sigma	S3014	Can use other comparable products.
NEBNext High Fidelity 2x PCR Master Mix	New England BioLabs	M0541	Critical Component
Nextera DNA Library Preparation Kit (2x TD Buffer, Tn5 Enzyme)	Illumina	FC1211030	Critical Component
Nuclease Free Sterile dH20	Gibco	10977015	Can use other comparable products.
Polysorbate 20 (Tween20)	Sigma	P9416	Can use other comparable products.
PowerUp SYBR Green Master Mix	Applied Biosystems	A25780	Critical Component
Precision Water Bath	Thermo Scientific	TSGP02	Can use other comparable products.
QIAquick PCR Purification Kit	Qiagen	28104	Critical Component
Qubit dsDNA HS Assay Kit	Invitrogen Life Technologies	Q32851	Suggested for quality assessment.
Qubit FlouroMeter	Invitrogen Life Technologies	Q33226	Suggested for quality assessment.
Rosette Sep Human CD4+ Density Medium	Stem Cell Technologies	15705	Critical Component
Rosette Sep Human CD4+ Enrichment Cocktail	Stem Cell Technologies	15022	Critical Component
RPMI-1640	Gibco	11875093	Can use other comparable products.
Sterile Resevoir	Thermo Scientific	8096-11	Can use other comparable products.
T100 Thermocycler with Heated Lid	BioRad	1861096	Can use other comparable products.
Tris-HCL	Sigma	T5941	Can use other comparable products.