Single-Cell Factor Localization on Chromatin using Ultra-Low Input Cleavage Under Targets and Release using Nuclease

Summary

CUT&RUN and its variants can be used to determine protein occupancy on chromatin. This protocol describes how to determine protein localization on chromatin using single-cell uliCUT&RUN.

Abstract

Determining the binding locations of a protein on chromatin is essential for understanding its function and potential regulatory targets. Chromatin Immunoprecipitation (ChIP) has been the gold standard for determining protein localization for over 30 years and is defined by the use of an antibody to pull out the protein of interest from sonicated or enzymatically digested chromatin. More recently, antibody tethering techniques have become popular for assessing protein localization on chromatin due to their increased sensitivity. Cleavage Under Targets & Release Under Nuclease (CUT&RUN) is the genome-wide derivative of Chromatin Immunocleavage (ChIC) and utilizes recombinant Protein A tethered to micrococcal nuclease (pA-MNase) to identify the IgG constant region of the antibody targeting a protein of interest, therefore enabling site-specific cleavage of the DNA flanking the protein of interest. CUT&RUN can be used to profile histone modifications, transcription factors, and other chromatin-binding proteins such as nucleosome remodeling factors. Importantly, CUT&RUN can be used to assess the localization of either euchromatic- or heterochromatic-associated proteins and histone modifications. For these reasons, CUT&RUN is a powerful method for determining the binding profiles of a wide range of proteins. Recently, CUT&RUN has been optimized for transcription factor profiling in low populations of cells and single cells and the optimized protocol has been termed ultra-low input CUT&RUN (uliCUT&RUN). Here, a detailed protocol is presented for single-cell factor profiling using uliCUT&RUN in a manual 96-well format.

Introduction

Many nuclear proteins function by interacting with chromatin to promote or prevent DNA-templated activities. To determine the function of these chromatin-interacting proteins, it is important to identify the genomic locations at which these proteins are bound. Since its development in 1985, Chromatin Immunoprecipitation (ChIP) has been the gold standard for identifying where a protein binds to chromatin^1,2. The traditional ChIP technique has the following basic workflow: cells are harvested and crosslinked (usually with formaldehyde), chromatin is sheared (usually with harsh sonication methods, necessitating crosslinking), the protein of interest is immunoprecipitated using an antibody that targets the protein (or tagged protein) followed by a secondary antibody (coupled to agarose or magnetic beads), crosslinking is reversed, protein and RNA are digested to purify DNA, and this ChIP enriched-DNA is used as the template for analysis (using radiolabeled probes^1,2, qPCR³, microarrays^5,6, or sequencing⁴). With the advent of microarrays and massively parallel deep sequencing, ChIP-chip^5,6 and ChIP-seq⁴ have more recently been developed and allow for genome-wide identification of protein localization on chromatin. Crosslinking ChIP has been a powerful and reliable technique since its advent with major advances in resolution by ChIP-exo⁷ and ChIP-nexus⁸. In parallel to the development of ChIP-seq, native (non-crosslinking) protocols for ChIP (N-ChIP) have been established, which utilize nuclease digestion (often using micrococcal nuclease or MNase) to fragment the chromatin, as opposed to sonication performed in traditional crosslinking ChIP techniques⁹. However, one major drawback to both crosslinking ChIP and N-ChIP technologies has been the requirement for high cell numbers due to low DNA yield following the experimental manipulation. Therefore, in more recent years, many efforts have been toward optimizing ChIP technologies for low cell input. These efforts have resulted in the development of many powerful ChIP-based technologies that vary in their applicability and input requirements^{10,11,12,13,14,15,16,17,18}. However, single-cell ChIP-seq based technologies have been lacking, especially for non-histone proteins.

In 2004, an alternative technology was developed to determine protein occupancy on chromatin termed Chromatin Endogenous Cleavage (ChEC) and Chromatin Immunocleavage (ChIC)¹⁹. These single-locus techniques utilize a fusion of MNase to either the protein of interest (ChEC) or to protein A (ChIC) for direct cutting of DNA adjacent to the protein of interest. In more recent years, both ChEC and ChIC have been optimized for genome-wide protein profiling on chromatin (ChEC-seq and CUT&RUN, respectively)^20,21. While ChEC-seq is a powerful technique for determining factor localization, it requires developing MNase-fusion proteins for each target, whereas ChIC and its genome-wide variation, CUT&RUN, rely on an antibody directed toward the protein of interest (as with ChIP) and recombinant Protein A-MNase, where the Protein A can recognize the IgG constant region of the antibody. As an alternative, a fusion Protein A/Protein G-MNase (pA/G-MNase) has been developed that can recognize a broader range of antibody constant regions²². CUT&RUN has rapidly become a popular alternative to ChIP-seq for determining protein localization on chromatin genome-wide.

Ultra-low input CUT&RUN (uliCUT&RUN), a variation of CUT&RUN that enables the use of low and single-cell inputs, was described in 2019²³. Here, the methodology for a manual 96-well format single-cell application is described. It is important to note that since the development of uliCUT&RUN, two alternatives for histone profiling, CUT&Tag and iACT-seq have been developed, providing robust and highly parallel profiling of histone proteins^24,25. Furthermore, scCUT&Tag has been optimized for profiling multiple factors in a single cell (multiCUT&Tag) and for application to non-histone proteins²⁶. Together, CUT&RUN provides an attractive alternative to low input ChIP-seq where uliCUT&RUN can be performed in any molecular biology lab that has access to a cell sorter and standard equipment.

Protocol

Ethics statement: All studies were approved by the Institutional Biosafety Office of Research Protections at the University of Pittsburgh.

1. Prepare magnetic beads

NOTE: Perform prior to cell sorting and hold on ice until use.

1. Pipette 30 µL of ConA-conjugated paramagnetic microspheres bead slurry mix per reaction to a fresh 1.5 mL microfuge tube and add 850 µL of Binding Buffer, pipetting gently to mix.
   NOTE: ConA-conjugated paramagnetic microspheres are lectin-coated magnetic beads that permit lipid membrane binding.
2. Place the tube on a magnetic rack and allow the beads to magnetize for 1-2 min. Once the supernatant has cleared, remove and discard the supernatant without disturbing the beads.
3. Remove the tube from the magnetic rack and wash the beads by resuspending in 1 mL of Binding Buffer.
4. Repeat steps 1.2 and 1.3.
5. Magnetize the beads for 2 min and remove the supernatant to discard.
6. Remove the tube from the magnetic rack and resuspend the beads in 30 µL of Binding Buffer per reaction.
7. Hold the washed bead mix on ice until cells are sorted.

2. Harvest cells

NOTE: This step is written for adhered cells and optimized for murine E14 embryonic stem cells. Culturing and harvesting the cells depend on the cell type.

1. Remove the cells from the 37 °C incubator and examine them under a microscope to assure quality.
2. Aspirate the media from the cell plate and rinse with 5 mL of 1x PBS.
3. Aspirate PBS from the plate and harvest the cells (using traditional cell harvesting methods which will differ by cell type). Obtain single-cell suspension by gently pipetting up and down with a serological pipette against the culture dish, if necessary.
4. Transfer the cell suspension to a 15 mL conical tube and spin down at 200 x g for 5 min.
5. Aspirate off the media to discard and wash the cell pellet with 5 mL of PBS + 1% FBS.
6. Spin down the cells at 200 x g for 5 min, discard the supernatant, and resuspend the cell pellet in 5 mL of PBS + 1% FBS.
7. Count the cells and transfer 1 mL of 1 x 10⁶ cells into a fresh 1.5 mL microfuge tube.
8. Add 5 µL of 7-Amino-Actinomycin D (7-AAD), invert the tube well to mix, and then apply the sample to the cell sorter to sort live single cells into individual wells of a 96-well plate.
   NOTE: 7-AAD dye is excluded from live cells, and therefore can be used in live-cell sorting.

3. Cell sorting and lysis

1. Prepare a cell sorter-compatible 96-well plate with 100 µL of Nuclear Extraction (NE) Buffer in each well prior to cell sorting.
2. Sort the cells into 96-well plates following the manufacturer's instructions.
3. Quickly spin the plate (600 x g for 30 s) to assure cells are in the buffer within the wells.
   NOTE: It is worth testing in a preliminary experiment whether the cells being used are reliably brought to the bottom of the wells.
4. Hold the samples on ice for 15 min.
5. Spin down the samples at 600 x g for 5 min at 4 °C and carefully pipette to remove the supernatant (leaving behind 5 µL).
6. Resuspend each sample in 55 µL of NE buffer and add 30 µL of the prewashed ConA-conjugated paramagnetic microspheres (from step 1.7; in Binding Buffer) to each reaction.
7. Incubate at room temperature for 10 min.

4. Pre-block samples to prevent early digestion by MNase

1. Place the plate on a 96-well magnetic rack, allow the beads to bind for a minimum of 5 min, and then remove and discard the supernatant.
2. Add 100 µL of Blocking Buffer to the nucleus-bound beads and mix with gentle pipetting.
3. Incubate for 5 min at room temperature.

5. Addition of primary antibody

1. Place the plate on a 96-well magnetic rack, allow the supernatant to clear for a minimum of 5 min, and then remove and discard the supernatant without disturbing the beads.
2. Remove the plate from the magnetic rack and resuspend the beads in 100 µL of Wash Buffer per reaction with gentle pipetting.
3. Place the plate back on the 96-well magnetic rack, allow the supernatant to clear, and then remove and discard the supernatant.
4. Resuspend the beads in 25 µL of Wash Buffer per reaction with gentle pipetting.
5. Make a primary antibody master mix: 25 µL of Wash Buffer + 0.5 µL of antibody per reaction.
6. While gently vortexing the nuclei-bound beads, add 25 µL of the primary antibody master mix to each sample being treated with an antibody targeting the protein of interest (typically 1:100 final dilution). Add 25 µL of Wash Buffer with no antibody, if performing a control.
7. Incubate for 1 h at room temperature.
8. Place the samples on a 96-well magnetic rack, allow the supernatant to clear for a minimum of 5 min, and then remove and discard the supernatant without disturbing the beads.
9. Remove the plate from the magnetic rack and wash the beads with 100 µL of Wash Buffer, resuspending by pipetting.

6. Addition of pA-MNase or pA/G-MNase

NOTE: Protein A has a high affinity for IgG molecules from certain species such as rabbits but is not suitable for IgGs from other species such as mice or rats. Alternatively, Protein A/G-MNase can be used. This hybrid binds rabbit, mouse, and rat IgGs, avoiding the need for secondary antibodies when mouse or rat primary antibodies are used.

1. Place the plate back on a 96-well magnetic rack, allow the supernatant to clear for a minimum of 5 min, and then remove and discard the supernatant without disturbing the beads.
2. Remove the plate from the magnetic rack and resuspend each sample in 25 µL of Wash Buffer.
3. Make a pA-MNase master mix (25 µL of Wash Buffer + optimized amount of pA-MNase per reaction).
4. While gently vortexing, add 25 µL of the pA-MNase master mix to each sample, including the control samples.
   NOTE: The concentration of pA-MNase varies upon preparation, if homemade, and should be tested prior to use upon each independent purification. For pA/G-MNase, 2.5 µL of the 20x stock should be used.
5. Incubate the samples for 30 min at room temperature.
6. Place the plate on a 96-well magnetic rack, allow the supernatant to clear for a minimum of 5 min, and then remove and discard the supernatant without disturbing the beads.
7. Remove the plate from the magnetic rack and wash the beads with 100 µL of Wash Buffer, resuspending by gentle pipetting.

7. Directed DNA digestion

1. Place the plate on a 96-well magnetic rack, allow the supernatant to clear for a minimum of 5 min, and then remove and discard the supernatant.
2. Remove the samples from the magnetic rack and resuspend the beads in 50 µL of Wash Buffer by gentle pipetting.
3. Equilibrate the samples to 0 °C in an ice/water mixture for 5 min.
4. Remove the samples from the 0 °C ice/water bath and add 1 µL of 100 mM CaCl₂ using a multichannel pipette. Mix well (3-5 times) with gentle pipetting using a larger volume multichannel pipette, and then return the samples to 0 °C.
   NOTE: Mixing well here is essential. CaCl₂ is added to activate MNase digestion of DNA flanking the protein of interest.
5. Start a 10 min timer as soon as the plate is back in the ice/water bath.
6. Stop the reaction by pipetting 50 µL of 2XRSTOP+ Buffer into each well, in the same order as the CaCl₂ was added.
   NOTE: Make 2XRSTOP+ Buffer before the 10 min digestion is over to prevent over digestion.

8. Sample fractionation

1. Incubate the samples for 20 min at 37 °C.
2. Spin the plate at 16,000 x g for 5 min at 4 °C.
3. Place the plate on a 96-well magnetic rack, allow the supernatant to clear for a minimum of 5 min, and transfer supernatants to a fresh 96-well plate. Discard the beads.

9. DNA extraction

1. Add 1 µL of 10% Sodium Dodecyl Sulfate (SDS) and 0.83 µL of 20 mg/mL Proteinase K to each sample.
   CAUTION: SDS powder is harmful if inhaled. Users should use in well-ventilated spaces wearing goggles, gloves, and an N95-grade respirator, handling with care.
2. Mix the samples by gentle pipetting.
3. Incubate the samples for 10 min at 70 °C.
4. Return the plate to room temperature and add 46.6 µL of 5 M NaCl and 90 µL of 50% PEG 4000. Mix by gentle pipetting.
5. Add 33 µL of polystyrene-magnetite beads to each sample and incubate for 10 min at room temperature.
   NOTE: Be sure to bring polystyrene-magnetite beads to room temperature (~30 min) and mix well before using.
6. Place the plate on a magnetic rack and allow the supernatant to clear for ~5 min, and then carefully discard the supernatant without disturbing the beads.
7. Rinse 2x with 150 µL of 80% ethanol without disturbing the beads.
   CAUTION: Ethanol is highly flammable and causes skin, eye, and lung irritation. Perform this step with appropriate laboratory clothing and in a vented hood.
8. Spin the plate briefly at 1000 x g for 30 s. Place the plate back on a 96-well magnetic rack and remove all residual EtOH without disturbing the beads.
9. Air-dry the samples for ~2-5 min.
   NOTE: Do not dry the beads for longer than 5 min. If diligent about removing the EtOH, 2-3 min of drying is sufficient.
10. Resuspend the beads with 37.5 µL of 10 mM Tris-HCl (pH 8) and incubate for 5 min at room temperature.
11. Place the plate on a magnetic rack and allow the beads to bind for 5 min.
12. Transfer 36.5 µL of the supernatant to a fresh thermocycler compatible 96-well plate. Discard the beads.
    NOTE: The experiment can be stopped here by storing samples at -20 °C or can continue with the library build (steps 10-15).

10. End repair, phosphorylation, adenylation

NOTE: The reagents are sourced as referenced in the Table of Materials. The below protocol follows a similar method to the commercial kit such as NEBNext Ultra DNA II kit.

1. Dilute 5 U/µL of T4 DNA polymerase 1:20 in 1x T4 DNA ligase buffer.
2. Prepare an end-repair/3'A master mix: 2 µL of 10x T4 DNA ligase buffer, 2.5 µL of 10 mM dNTPs, 1.25 µL of 10 mM ATP, 3.13 µL of 40% PEG 4000, 0.63 µL of 10 U/µL T4 PNK, 0.5 µL of diluted T4 DNA polymerase, 0.5 µL of 5U/µL Taq DNA polymerase, with a total volume of 13.5 µL per reaction.
   NOTE: Be sure to bring 40% PEG 4000 to room temperature before pipetting.
3. Add 13.5 µL of end-repair/3'A master mix to 36.5 µL of DNA.
4. Mix the reaction by quick vortex, and then a quick spin (500 x g for 10 s).
5. Incubate using the following reaction conditions in a pre-cooled thermocycler with a heated lid for temperatures >20 °C. Use the reaction conditions: 12 °C for 15 min, 37 °C for 15 min, 72 °C for 20 min, hold at 4 °C.

11. Adapter ligation

NOTE: Keep the samples on ice while setting up the following reaction. Allow ligase buffer to come to room temperature before pipetting. Dilute the Adaptor (see Table of Materials) in a solution of 10 mM Tris-HCl containing 10 mM NaCl (pH 7.5). Due to the low yield, do not pre-quantify the CUT&RUN-enriched DNA. Rather, generate 25-fold dilutions of the adaptor, using a final working adaptor concentration of 0.6 µM.

1. Make a ligation master mix: 55 µL of ligase buffer (2x), 5 µL of T4 DNA ligase, and 5 µL of diluted Adaptor, with a total volume of 65 µL per reaction.
2. Add 65 µL of the master ligation mix to 50 µL of DNA from step 10.5.
3. Mix by quick vortexing, followed by quick spinning (500 x g for 10 s).
4. Incubate at 20 °C in a thermocycler (without a heated lid) for 15 min.
   NOTE: Proceed immediately to the following step.

12. USER digestion

1. Add 3 µL of USER enzyme to each sample, vortex, and spin (500 x g for 10 s).
2. Incubate in thermal cycler at 37 °C for 15 min (heated lid set to 50 °C).

13. Polystyrene-magnetite bead clean-up following ligation reaction

NOTE: Allow polystyrene-magnetite beads to equilibrate at room temperature (~30 min). Vortex to homogenize the bead solution before using. Perform the following steps at room temperature.

1. Add 39 µL (0.33x) of polystyrene-magnetite bead solution to each well containing adaptor-ligated DNA.
2. Mix thoroughly by pipetting, and then incubate the samples at room temperature for 15 min to allow DNA to bind to the beads.
3. Place the samples on a 96-well magnetic rack and incubate for 5 min until the supernatant is clear.
4. Keep the plate on the magnetic rack and carefully remove and discard the supernatant without disturbing the beads.
5. Rinse the beads with 200 µL of 80% EtOH without disturbing the beads.
6. Incubate for 30 s on a 96-well magnetic rack to allow the solution to clear.
7. Remove and discard the supernatant without disturbing the beads.
8. Repeat steps 13.5-13.7 for a total of two washes.
9. Spin the plate briefly at 500 x g for 10 s, place the plate back on a 96-well magnetic rack, and remove residual EtOH without disturbing the beads.
10. Keep the plate on the magnetic rack and air-dry the samples for 2 min.
    NOTE: Do not over-dry the beads.
11. Remove the plate from the magnetic rack and resuspend the beads in 28.5 µL of 10 mM Tris-HCl (pH 8).
    CAUTION: Hydrochloric acid is very corrosive. Users should handle it with care in a chemical fume hood wearing goggles, gloves, and a lab coat.
12. Thoroughly resuspend beads by pipetting, taking care to not produce bubbles.
13. Incubate for 5 min at room temperature.
14. Place the plate on a 96-well magnetic rack and allow the solution to clear for 5 min.
15. Transfer 27.5 µL of supernatant to a new PCR plate and discard the beads.

14. Library enrichment

NOTE: Primers are diluted with the same solution as the adaptor. For this library build, use a final working primer concentration of 0.6 µM.

1. Add 5 µL of diluted indexed primer (see Table of Materials) to each sample.
   NOTE: Each sample needs a different index to be identified after sequencing.
2. Prepare a PCR master mix: 10 µL of 5x high fidelity PCR buffer, 1.5 µL of 10 mM dNTPs, 5 µL of diluted Universal primer, 1 µL of 1 U hot start high fidelity polymerase, with a total master mix volume of 17.5 µL per sample.
3. Add 17.5 µL pf PCR mix to 32.5 µL of purified adaptor-ligated DNA (5 µL of indexed primer is included in this volume).
4. Mix the solution by pipetting.
5. Incubate in a thermocycler using the following reaction conditions with a maximum ramp rate of 3 °C/s: 98 °C for 45 s, 98 °C for 45 s, 60 °C for 10 s, repeat the second and third steps 21 times, 72 °C for 1 min, hold at 4 °C.
   NOTE: The samples can be kept at 4 °C for short-term storage or -20 °C for long-term storage.

15. Polystyrene-magnetite bead clean-up

1. Add 60 µL (1.2x) of polystyrene-magnetite beads to each sample.
2. Resuspend the beads by pipetting and incubate for 15 min at room temperature.
3. Place the plate on a magnetic rack for 5 min until the solution is clear.
4. Discard the supernatant and rinse the beads with 200 µL of 80% EtOH without disturbing the beads.
5. Repeat the wash step for a total of two 80% EtOH washes.
6. Spin the plate at 500 x g for 10 s, place the plate on a 96-well magnetic rack, and allow the beads to bind for 5 min.
7. Pipette to remove excess EtOH without disturbing the beads and allow the beads to air-dry for 2 min.
   NOTE: Do not over-dry the beads.
8. Resuspend the beads in 21 µL of nuclease-free water and incubate for 5 min at room temperature.
9. Place the plate on a magnetic rack and allow the solution to clear for 5 min.
10. Transfer 20 µL of the supernatant to a new plate.
    NOTE: The experiment can be stopped here by storing the sample at -20 °C.
11. Quantify library concentrations with a fluorometer (see Table of Materials), using a 1x HS reagent.
12. If the concentration allows, run 30 ng of sample on 1.5% agarose gel with a low molecular weight ladder to visualize. Alternatively, visualize on a Fragment Analyzer or related instrument.
13. Sequence libraries on an Illumina platform to obtain ~50,000-100,000 uniquely mapped reads.

Results

Here, a detailed protocol is presented for single-cell protein profiling on chromatin using a 96-well manual format uliCUT&RUN. While results will vary based on the protein being profiled (due to protein abundance and antibody quality), cell type, and other contributing factors, anticipated results for this technique are discussed here. Cell quality (cell appearance and percent of viable cells) and single-cell sorting should be assessed prior to or at the time of live-cell sorting into the NE buffer. An example of ES...

Discussion

CUT&RUN is an effective protocol to determine protein localization on chromatin. It has many advantages relative to other protocols, including: 1) high signal-to-noise ratio, 2) rapid protocol, and 3) low sequencing read coverage required thus leading to cost savings. The use of Protein A- or Protein A/G-MNase enables CUT&RUN to be applied with any available antibody; therefore, it has the potential to quickly and easily profile many proteins. However, adaptation to single-cell for any protein profiling on chroma...

Materials

Name	Company	Catalog Number	Comments
1.5 mL clear microfuge tubes	ThermoFisher Scientific	90410
1.5 mL tube magnetic rack	ThermoFisher Scientific	12321D
1.5 mL tube-compatible cold centrifuge	Eppendorf	5404000537
10 cm sterile tissue culture plates	ThermoFisher Scientific	150464
10X T4 DNA Ligase buffer	New England Biolabs	B0202S
15 mL conical tubes	VWR	89039-656
1X TE buffer	ThermoFisher Scientific	12090015
200 µL PCR tubes	Eppendorf	951010022
2X quick ligase buffer	New England Biolabs	M2200	Ligase Buffer
5X KAPA HiFi buffer	Roche	7958889001	5X high fidelity PCR buffer
7-Amino-Actinomycin D (7-AAD)	Fisher Scientific	BDB559925
96-well magnetic rack	ThermoFisher Scientific	12027 or 12331D
96-well plate	VWR	82006-636
AMPure XP beads	Beckman Coulter	A63881	polystyrene-magnetite beads; Due to potential variability between AMPure XP bead lots, it is recommended that your AMPure bead solution be calibrated. See manufacturer’s instructions
Antibody to protein of interest	varies
ATP	ThermoFisher Scientific	R0441
BioMag Plus Concanavalin A beads	Polysciences	86057-10	ConA-conjugated paramagnetic microspheres
BSA
Calcium Chloride (CaCl2)	Fisher Scientific	AAJ62905AP
Cell sorter	BD FACSAria II cell sorter		Requires training
Cell-specific media for cell culture	Varies
Chloroform	ThermoFisher Scientific	C298-500	Chloroform is a skin irritant and harmful if swallowed; handle in a chemical fume hood using gloves, a lab coat, and goggles
Computer with 64-bit processer and access to a super computing cluster			For computational analyses of resulting sequencing datasets
DNA spin columns	Epoch Life Sciences	1920-250
dNTP set	New England Biolabs	N0446S
EGTA	Sigma Aldrich	E3889
Electrophoresis equipment	varies
Ethanol	Fisher Scientific	22032601	100% vol/vol ethanol is highly flammable; handle in a chemical fume hood using gloves, a lab coat, and goggles
Ethylenediaminetetraacetic acid  (EDTA)	Fisher Scientific	BP2482100
FBS	Sigma Aldrich	F2442
Glycerol	Fisher Scientific	BP229-1
Glycogen	VWR	97063-256
HEPES	Fisher Scientific	BP310-500
Heterologous S. cerevisiae DNA spike-in	homemade		Prepared from crosslinked, MNase-digested, and agarose gel extracted genomic DNA purified of protein/RNA and diluted to 10 ng/mL. We recommend yeast genomic DNA, but other organisms can be used if needed.
Hydrochloric Acid  (HCl)	Fisher Scientific	A144-212	Hydrochloric Acid is very corrosive; handle in a chemical fume hood using gloves, a lab coat, and goggles
Ice Bucket	varies
Illumina Sequencing platform (e.g., NextSeq500)	Illumina
Incubator with temperature and atmosphere control	ThermoFisher Scientific	51030284
KAPA HotStart HiFi DNA Polymerase with 5X KAPA HiFi buffer	Roche	7958889001	hotstart high fidelity polymerase
Laminar flow hood	Bakery Company	SG404
Manganese Chloride (MnCl2)	Sigma Aldrich	244589
Micropipette set	Rainin	30386597
Minifuge	Benchmark Scientific	C1012
NEB Adaptor	New England Biolabs	E6612AVIAL	Adaptor
NEB Universal primer	New England Biolabs	E6611AVIAL	Universal Primer
NEBNext Multiplex Oligos for Illumina kit	New England Biolabs	E7335S/L, E7500S/L, E7710S/L, E7730S/L	Indexed Primers
Negative control antibody	Antibodies-Online	ABIN101961
Nuclease Free water	New England Biolabs	B1500S
PCR thermocycler	Eppendorf	2231000666
Phase lock tubes	Qiagen	129046
Phenol/Chloroform/Isoamyl Alcohol (PCI)	ThermoFisher Scientific	15593049	Phenol is harmful if swallowed or upon skin contact; handle in a chemical fume hood using gloves, a lab coat, and goggles
Phsophate buffered saline (PBS)	ThermoFisher Scientific	10814010
Pipette aid	Drummond Scientific	# 4-000-100
Polyethylene glycol (PEG) 4000	VWR	A16151
Potassium Chloride (KCl)	Sigma Aldrich	P3911
Potassium Hydroxide (KOH)	Fisher Scientific	P250-1	CAUTION KOH is an eye/skin irritant as a solid and corrosive in solution. Handle in a chemical fume hood using gloves, a lab coat, and goggles
Protease Inhibitors	ThermoFisher Scientific	78430
ProteinA/G-MNase	Epicypher	15-1016	pA/G-MNase
ProteinA-MNase, purified from pK19pA-MN	Addgene	86973
Proteinase K	New England Biolabs	P8107S
Qubit 1X dsDNA HS Assay Kit	ThermoFisher Scientific	Q33230
Qubit Assay tubes	ThermoFisher Scientific	Q32856
Qubit Fluorometer	ThermoFisher Scientific	Q33238
Quick Ligase with 2X Quick Ligase buffer	New England Biolabs	M2200S
RNase A	New England Biolabs	T3010
Sodium Acetate  (NaOAc)	ThermoFisher Scientific	BP333-500
Sodium Chloride (NaCl)	Sigma Aldrich	S5150-1L
Sodium dodecyl sulfate (SDS)	ThermoFisher Scientific	BP166-500	SDS is poisonous if inhaled; handle with care in well ventilated spaces using gloves, eye protection, and an N95-grade respirator when handling
Sodium Hydroxide (NaOH)	Fisher Scientific	S318-1	NaOH is an eye/skin irritant as a solid and corrosive in solution. Handle in a chemical fume hood using gloves, a lab coat, and goggles
Spermidine	Sigma Aldrich	S2626
Standard Inverted Light Microscope	Leica	11526213
Standard lab agarose gel materials	Varies
Standard lab materials such as serological pipettes and pipette tips	Varies
T4 DNA Ligase	New England Biolabs	M0202S
T4 DNA Polymerase	New England Biolabs	M0203S
T4 PNK	New England Biolabs	M0201S
Tabletop vortexer	Fisher Scientific	2215414
Taq DNA Polymerase	New England Biolabs	M0273S
Thermomixer	Eppendorf	5384000020	Alternatively, can use a waterbath
Tris base	Fisher Scientific	BP152-5
Triton X-100	Sigma Aldrich	9002-93-1	Triton X-100 is hazardous; use a lab coat, gloves, and goggles when handling
Trypsin	Fisher Scientific	MT25052
Tube rotator	VWR	10136084
USER enzyme	New England Biolabs	M5505S