Single-Cell RNA Sequencing of Mutant Whole Mouse Embryos: From the Epiblast to the End of Gastrulation

Summary

This paper establishes a pipeline for high-quality single-cell and nuclei suspensions of gastrulating mouse embryos for sequencing of single cells and nuclei.

Abstract

Over the last decade, single-cell approaches have become the gold standard for studying gene expression dynamics, cell heterogeneity, and cell states within samples. Before single-cell advances, the feasibility of capturing the dynamic cellular landscape and rapid cell transitions during early development was limited. In this paper, a robust pipeline was designed to perform single-cell and nuclei analysis on mouse embryos from embryonic day E6.5 to E8, corresponding to the onset and completion of gastrulation. Gastrulation is a fundamental process during development that establishes the three germinal layers: mesoderm, ectoderm, and endoderm, which are essential for organogenesis. Extensive literature is available on single-cell omics applied to wild-type perigastrulating embryos. However, single-cell analysis of mutant embryos is still scarce and often limited to FACS-sorted populations. This is partially due to the technical constraints associated with the need for genotyping, timed pregnancies, the count of embryos with desired genotypes per pregnancy, and the number of cells per embryo at these stages. Here, a methodology is presented designed to overcome these limitations. This method establishes breeding and timed pregnancy guidelines to achieve a higher chance of synchronized pregnancies with desired genotypes. Optimization steps in the embryo isolation process coupled with a same-day genotyping protocol (3 h) allow for microdroplet-based single-cell to be performed on the same day, ensuring the high viability of cells and robust results. This method further includes guidelines for optimal nuclei isolations from embryos. Thus, these approaches increase the feasibility of single-cell approaches of mutant embryos at the gastrulation stage. We anticipate that this method will facilitate the analysis of how mutations shape the cellular landscape of the gastrula.

Introduction

Gastrulation is a fundamental process required for normal development. This rapid and dynamic process occurs when pluripotent cells transition into lineage-specific precursors that define how organs form. For years, gastrulation was long defined as the formation of three largely homogeneous populations: mesoderm, ectoderm, and endoderm. However, high-resolution technologies and an emerging number of embryonic stem cell models^1,2 unveil unprecedented heterogeneity among the early germ layers^3,4. This suggests that much more remains to be uncovered about the mechanisms regulating the distinct cell populations of the gastrula. Mouse embryonic development has been one of the best models to study early cell fate decisions during gastrulation^3,5. Gastrulation in mice is rapid, as the entire process of gastrulation occurs within 48 h, from embryonic day E6.5 to E8⁵.

Recent advancements in single-cell technologies have enabled detailed mapping of wild-type mouse embryonic development, providing a comprehensive overview of the cellular and molecular landscapes of embryos during gastrulation^3,4,6,7,8. However, the analysis of mutant embryos at these stages is less common and often limited to FACS-sorted populations^9,10. The scarce literature reflects the technical challenges associated with the manipulation and single-cell preparation of gastrulating embryos that require genotyping. Capturing the dynamic process of gastrulation can pose challenges due to its rapid nature, especially for understanding mutant embryos. The timing and synchronization of pregnancies are essential, as even slight differences between timed pregnancies can be misinterpreted as a developmental phenotype resulting from the mutant gene. This becomes particularly important when the mutant gene influences the process of gastrulation^13,14. In this study, guidelines are established to obtain synchronized pregnancies through visualization of vaginal plugs (i.e., the mass of coagulated seminal fluid formed in the female's vagina after mating). Additionally, a strategy is designed to obtain robust single-cell data from mutant gastrulating embryos from E6.5 to E8. This strategy is devised to overcome constraints associated with the low number of embryos with the desired genotype per pregnancy and the decrease in viability caused by freezing-thawing embryos or cells.

This paper describes an optimized methodology from the establishment of timed pregnancies via vaginal plugs to the final sequencing of single cells/nuclei. This method explains how to increase the number of synchronized pregnancies to obtain a higher number of embryos with desired genotype, cell/nuclei isolations to improve the viability of the cells, and a same-day genotyping protocol. This manuscript also describes the process of embryo isolation at different gastrulation time points. The methodology helps to increase the number of final viable embryo cells/nuclei for sequencing, ensuring high-quality sequencing data. Therefore, this method will open the doors for single-cell studies of gastrulating embryos that require genotyping.

Protocol

This protocol and all animal experiments described were formally approved and in accordance with institutional guidelines established by the Temple University Institutional Animal Care and Use Committee, which follows the Association for Assessment and Accreditation of Laboratory Animal Care international guidelines. All mice described were on the C57/BL6N background strain. No animal health concerns were observed in these studies.

1. Breeding colony and timed pregnancies

1. Time the pregnancies by the visualization of a vaginal plug. Noon on the day of the plug is considered E0.5.
2. House mice in cages with bedding material containing chipped hardwood bedding and paper nesting material.
   1. Each cage contains mouse chow, fresh water, and an enrichment item (e.g., tunnel and nesting material). Track and collect colony information daily during timed breeding.
   2. Log all information such as the age of the mouse, the number of pregnancies a female mouse has had, the number of plugs placed by a male mouse, and the stage of estrous (Figure 2) for female mice.
      NOTE: Females that have already given birth 1-2 times will deliver larger litter sizes in future pregnancies.
3. Before starting timed pregnancies, house the male mouse alone in a cage 1 week prior to breeding. During the week of breeding initiation, introduce at least 1 female per male in the cage.
   NOTE: Depending on the approved animal protocol, adding 2-3 females into a breeding cage may be allowed and is preferred to increase plug generation.
4. Set up at least 4 breeding trios (2 female mice to 1 male) to increase the chances of synchronized pregnancies across the cages (aka., multiple plugs in the same day). This will increase the number of embryos isolated at the same developmental stage.
5. Arrange ideal mating in the afternoon or evening before 5 PM, and females are placed into the male's cage or vice versa. If breeding does not occur in 4-5 days, consider switching mating partners every other day.
   NOTE: If unable to check for a vaginal plug the following morning, separate the breeding pair the night before (i.e., weekend/holidays).
6. Check for vaginal plugs every day in the early morning; before 9 AM is preferred.
   1. To check for vaginal plugs, gently lift the female mice by the base of the tail and observe the vaginal opening. Look for a white or cream-colored gelatinous mass. Often, the vaginal plug can be obvious, but if unclear, take tweezers and gently probe the vaginal opening. Consider only the more apparent plugs for isolation. Refer to Figure 2C.
      NOTE: It is critical to check for vaginal plugs as early as possible in the morning to avoid missing a potential pregnancy. Plugs can fall out or dissolve after 12 h.
      NOTE: Even if a plug is observed, it does not guarantee that the female mouse will be pregnant. If a partial or no plug is observed but there is redness near the vaginal opening of the female mice, do not consider these females for isolation as there is a less likely chance the plug will stick. The likelihood of pregnancy after mating varies among mouse strains and depends on the phase of the estrous cycle during mating (Figure 2).
7. Once a vaginal plug is observed, record the day. The noon of the same day that the vaginal plug is observed is considered E0.5. Separate the female mice from the breeding cage and isolate the embryos depending on the stage of gastrulation desired.
   NOTE: This method does not provide precise timing for mating. Conventionally, mating is assumed to occur around midnight the preceding night. Consequently, embryos are considered to be half a day old (E0.5) by noon on the day when the vaginal plug is observed.

2. Isolation of mouse embryos during gastrulation

1. Prior to starting the embryo isolation, prepare all required reagents and equipment.
   1. Clean the area thoroughly with 70% ethanol. Ensure all dissection tools (forceps and scissors) are washed and sterilized. Obtain sterile 5 mL of Dulbecco's Modified Eagle Medium (DMEM)/10% fetal bovine serum (FBS) and 20 mL DPBS^-/- and place on ice.
   2. Perform all isolations using a stereomicroscope with a transmitted light stage and camera to assist with gross developmental phenotyping.
2. Euthanize the pregnant mouse dam and start the isolation immediately.
   1. Place the pregnant dam in a CO₂ chamber with the CO₂ flow rate adjusted to displace 20% of the cage volume per minute. Monitor the mouse closely and confirm death by observing the absence of breathing movements.
   2. Maintain CO₂ flow for an additional 2 min after the absence of breathing movements. Confirm euthanasia by performing a cervical dislocation.
   3. Position the mice in a normal standing position on a firm, flat surface. Then, with the thumb and first finger of one hand against the back of the neck at the base of the skull, push forward and downward while pulling backward with the other hand holding the tail base.
   4. Verify the effectiveness of dislocation by feeling the separation of cervical vertebrae. When the spinal cord is severed, a 2-4 mm space will be palpable between the occipital condyles and the first cervical vertebra.
      NOTE: Do not euthanize multiple pregnant dams at once, as cell viability will be affected. Isofluorane can be used as an alternative anesthetic agent if approved by the Institutional Animal Care and Use Committee (IACUC) or equivalent body.
3. Place the pregnant dam on its back and sterilize the area near the vaginal opening with ethanol.
   1. Using dissection scissors and tweezers, lift the skin fold near the vaginal opening and make a small V-shaped cut, slowly revealing the uterus of the pregnant dam (Figure 3 [yellow arrow]).
   2. Dissect out the uterine horn of the pregnant dam by holding one end of it with tweezers and cutting along it, making sure to remove the cervix. Place the uterine horn into a 10 cm Petri dish containing DPBS^-/- on ice (Figure 3).
      NOTE: Depending on the embryo isolation stage, the uterus will resemble smaller or larger implantation sites (i.e., 'pearls' on a string).
4. With dissection scissors and tweezers, cut each implantation site ('pearls') containing the decidual swellings inside and place into fresh DPBS^-/- in a 6 cm Petri dish on ice (Figure 3).
   NOTE: An average pregnant dam will have around 6-8 implanted embryos.
5. Take one implantation site and place it on a new 6 cm Petri dish on top of the stereomicroscope stage and add 500 µL of DPBS^-/- on top of it. Adjust the focus of the microscope and the light source (Figure 3).
   NOTE: Depending on the size of the implantation site, the amount of DPBS might vary; the goal is to have enough DPBS that the implantation site is submerged.
6. Using fine-tipped dissection tweezers, remove the uterine muscle from the implantation site. Hold down the implantation site with one set of tweezers in one hand and slowly insert another pair of forceps with the other hand into the end of the implantation site cut from the uterine horn, slowly revealing the decidua swelling (Figure 3).
   NOTE: Do not pull or tug too hard on the uterine surface, as it can lead to the rupture of the decidual swelling or even the lysis of the embryo.
7. After the decidual swelling is isolated, proceed to reveal the embryo.
   1. Hold the anti-mesometrial end of the decidual swelling with one pair of forceps and, with the other pair, slowly make a horizontal cut about ¼ the size of the decidual swelling from the mesometrial end (i.e., often the more pointed end of the decidual swelling).
   2. Now, with both forceps, slowly push from the anti-mesometrial end of the decidual swelling, and the embryo will pop out from the freshly cut mesometrial end (Figure 3).
      NOTE: Do not tear into the decidual swelling, as this will break the embryo. If necessary, make smaller cuts along the mesometrial end of the decidual swelling.
8. Once the embryo is revealed, remove any extraembryonic tissues attached.
   1. The parietal endodermal sac and ectoplacental cone might spontaneously come off from the embryo during the revealing process, but if not, use a pair of forceps and remove them along with any associated maternal blood. Then, using two forceps, hold down the embryo with one pair and slowly peel the visceral yolk sac from the embryo using the other set.
   2. Using a P20 pipette, place the yolk sac with no more than 10 µL of DPBS^-/- from the dish into an 8-strip polymerase chain reaction (PCR) tube on ice, as this will be used for same-day genotyping.
      NOTE: It is critical that the yolk sac sample is not contaminated with tissue from the pregnant dam. Contamination may lead to incorrect genotype assignment of the embryo.
9. Take bright field pictures of freshly isolated embryos to ensure the staging of the littermates is similar. With a P200 pipette, slowly pipette up the embryo with 50 µL of DMEM/10% FBS and place it into a 1.5 mL tube on ice. Let the embryos remain on ice until genotypes have been confirmed.
   NOTE: Embryos were kept on ice for 3-4 h with no obvious degradation, but do not exceed this time, as a decrease in cell viability will occur. Label the embryos and genotyping tubes accordingly. Taking bright field images is encouraged to identify and annotate gross phenotypic differences among embryos.
10. Repeat these steps for all remaining decidual swellings. Clean all dissection tools and use new plastics for every isolation to ensure no contamination from previous isolations.
    NOTE: Ensure that the dissection procedures are limited to 1 h from the moment of collection of the implantation site from the pregnant dam.
11. Proceed to isolate embryos from the next pregnant dam (if multiple synchronized pregnancies were identified) before moving to the same-day genotyping step.

3. Same-day genotyping (Figure 4)

1. Digest each visceral yolk sac in an 8-strip PCR tube. Using a P20 pipette, add 19.3 µL of PCR template DNA lysis buffer and 0.7 µL of 0.2 µg/mL Proteinase K to each yolk sac sample.
2. Vortex the sample for 10 s and spin down to position the samples at the bottom of the tube using a mini centrifuge with a strip adaptor at 1,000 x g for 10 s. Place the 8-strip PCR tube in an 85 °C heat block for 45 min and vortex for 5 s every 5 min.
   NOTE: It is important to vortex samples while digesting to maximize cell lysis in 45 min.
3. After 45 min, spin the tube strip down using a mini centrifuge with a strip adaptor at 1,000 x g for 10 s, and proceed with PCR for desired genetic identification. For reference, a sample protocol for a Cre-lox system is provided. The following is an example of PCR conditions for Cre genotyping. Design primers to amplify the 5' and 3' regions of the targeted Cre site.
4. To perform the PCR reaction for Cre genotyping, prepare a PCR master mix per 8-strip PCR tube for each yolk sac containing 10 µL of Taq DNA polymerase mix, 0.5 µL of 0.5 µM forward Cre primer, 0.5 µL of 0.5 µM reverse Cre primer, 5 µL of PCR-certified water, and 4 µL of yolk sac genomic DNA.
   NOTE: If using a protocol that was optimized for mouse tail genotyping, add double the amount of DNA that is typically utilized for cleaner results.
5. Once the PCR master mix has been made, run the PCR thermal cycle amplification program. For Cre genotyping, the cycle is as follows: (1) 95 °C for 3 min, (2) 95 °C for 30 s, (3) 55 °C for 30 s, (4) 72 °C for 30 s, repeated step 2-4 for 34 cycles, (5) 72 °C for 10 min, (6) 4 °C hold. Run the PCR products on a 1% agarose gel to draw genotyping conclusions.
   NOTE: If more than one PCR is necessary for genetic identification, run the PCR reactions simultaneously to optimize timing. To expedite the process, prepare the agarose gel a day in advance on the day of the experiment and store it at 4 °C overnight. Do not consider any samples without clear genotypes. Take both the genotype and developmental stage into consideration for samples, as littermates could be at different stages of gastrulation and potentially skew results. When performing the genotyping of the LoxP alleles, the PCR bands expected in the gel may vary depending on the Cre-driver used. For instance, if the Cre driver is expressed in the visceral yolk sac, the Loxp band will appear shifted in the Cre-positive (Cre+) embryos, compared to the Cre-negative (Cre-). However, if the Cre is not expressed in the visceral yolk sac, the size of the Loxp band will be the same size in the Cre+ and the Cre- embryos (i.e., the Loxp alleles will not be floxed in the yolk sac lineage). An embryo carrying one Cre+ allele and two Loxp alleles is considered a conditional KO embryo. However, to confirm the deletion of the floxed gene, it is recommended to perform a confirmation of the knockout of the gene on the cells that express the Cre driver, either by repeating the genotyping protocol or by qPCR analysis of the mRNA levels of the floxed gene (Figure 4D, E).
6. Store the remaining digested yolk sac samples in the -20 °C freezer for long-term storage.

4. Cell dissociation of embryos and cell viability

1. Once the genotypes have been confirmed, take a P200 pipette and pipette 50 µL of DMEM/10% FBS. Pool embryos with the same genotype into a new 1.5 mL tube and place the tube on ice.
   NOTE: Do not proceed with the experiment if there are not at least 5 embryos per group (E7-E7.5) or 3 (E7.75-E8), as cell count and viability will decrease tremendously.
2. After embryos have been pooled based on genotypes, allow them to settle to the bottom of the tube. Wash the pooled embryos by adding 50 µL of DPBS^-/-, then wait for the embryos to settle before removing as much of DPBS^-/- as possible without removing the embryos from the tube. Repeat this step twice.
   NOTE: Holding the 1.5 mL tube up to a light source or towards a window will make it easier to see the embryos settling to the bottom of the tube.
3. Add 100 µL of trypsin to the pooled embryos and incubate at 37 °C in a heat block for 5 min. Gently flick the 1.5 mL tubes every 30 s to help the cells dissociate.
   NOTE: Do not use a vortex or a pipette during the trypsinization process, as it damages the cells. If more than 5 embryos (E7-E7.5) or 3 embryos (E7.75-E8) are pooled, perform trypsin digestion in another tube with an equivalent amount of trypsin (~20 µL per 1 embryo). Use ~20 µL of trypsin per embryo (E6.5-E7.5), 35 µL per embryo (E7.75), and 40 µL for embryo (E8).
4. After 5 min, neutralize the trypsin with 300 µL of DMEM/10% FBS. Centrifuge the pooled embryos at 100 x g for 4 min at room temperature (RT). After centrifugation, a small pellet will appear for all samples. Resuspend the pellets in 40 µL of DMEM/10% FBS and place them on ice.
   NOTE: The size of the pellet will vary depending on the number of embryos pooled. It is possible that the pellet is not visible but proceed with the next step.The amount of DMEM/10% FBS required to neutralize trypsin will depend on the amount of trypsin added. Add 3 times the amount of DMEM/10% to the trypsin amount.
5. Determine the concentration of the resuspended cells (40 µL) using an automated cell counter. Mix 5 µL of cells with 5 µL of trypan blue in a new 1.5 mL tube. Pipette mix thoroughly and pipette onto a slide to determine the cell number and cell viability. The optimal concentration of cells is 700-1200 cells/µL, and the cell viability is 90% or higher.
   NOTE: If the concentration is lower than 200 cells/µL and viability is lower than 50%, do not continue the experiment. If cell concentration is too high, dilute the cell suspension and recount cells again. If cell clumps are observed, use a cell strainer to ensure a single-cell suspension.
6. Proceed to single-cell partitioning using a microfluidic chip and follow the protocol from the microfluidic chip manufacturers¹¹.

5. Nuclei isolation mouse embryos (option for larger embryonic time points from E8 onward)

1. Prepare fresh lysis and wash buffers outlined in Table 1, and place them on ice.
   NOTE: Nuclei isolation can be performed on fresh or frozen samples. If samples are frozen, allow them to thaw for 2-5 min on ice.
2. Prior to starting the experiment, confirm all genotypes and pool only embryos with clear genotypes.
3. Using a P200 pipette, add 50 µL of nuclei lysis buffer to pooled embryos in a 1.5 mL tube, aiming for a minimum of 3 embryos per mutant group. Allow samples to sit on ice with lysis buffer for 5 min and vortex every 30 s.
4. After 5 min of incubation, centrifuge at 500 x g for 5 min at 4 °C. Using a P200 pipette, remove the supernatant and resuspend the pellet in 50 µL of wash buffer. Once resuspended, centrifuge at 500 x g for 5 min at 4 °C.
5. Remove the supernatant and resuspend in 40 µL of DPBS^-/-. Count the cells using an automated cell counter. Mix 5 µL of nuclei with 5 µL of trypan blue in a new 1.5 mL tube. Pipette the mixture thoroughly and load it onto a slide to determine the cell number and viability.
   NOTE: The nuclear membrane is permeable to trypan blue; therefore, the isolated nuclei stain is positive for trypan blue. In an automated cell counter, the percentage of dead cells is used to estimate the percentage of isolated nuclei (Figure 5A).
6. If the percentage of intact nuclei is greater than 90% (meaning that at least 90% of the nuclei are stained with trypan blue and exhibit a rounded shape and turgid aspect; refer to Figure 5B, C), proceed to utilize a microfluidic chip and follow protocol from the microfluidic chip manufacturers¹¹.

6. Single-cell partitioning (including cDNA amplification and library construction)

1. Proceed immediately with the single-cell RNA sequencing protocol following the microfluidic chip manufacturer's protocol¹¹ for the most optimal results. Set the target cell recovery to 6000 cells or greater.

7. Sequencing

1. After libraries are constructed, measure the fragment size distribution and concentrations of samples using an automated electrophoresis analyzer.
   NOTE: Optimal fragment size distributions are between 300-1000 bp.
2. Samples are ready to be loaded into the sequencer. Pool libraries from different samples together. The final loading concentration of pooled libraries is 750 pM in a total volume of 24 µL. Load the pooled libraries into the reagent cartridge, following the sequencing manufacturer's protocol¹².
3. Sequence the libraries loaded into the pre-assembled flow cell and cartridge according to the desired sequencing depth with pair-end, dual indexing. The sequencing reads adhered to the protocol outlined by microfluidic chip manufacturers is as follows¹¹: Read 1: 28 cycles, i7 Index: 10 cycles, i5 Index: 10 cycles, and Read 2: 90 cycles. Following the completion of sequencing, the data undergoes bioinformatics analysis.
4. Use bioinformatics methods to perform quality controls. This includes assessing the number of sequenced cells, reads per cell, and number of genes mapped per cell.
   NOTE: For optimal results, the number of sequenced cells is at least 80% of the targeted cells. It is recommended that the number of reads per cell is at least 30,000, and the number of genes detected higher than 3000 (for mouse samples).

Results

The methodology designed in this paper is specifically intended to enhance the preparation of embryo samples for single-cell omics from E6.5 to E8. This robust pipeline consists of five major steps: synchronized timed pregnancies, embryo isolations, same-day genotyping, cell dissociation, and assessment of cell viability (Figure 1A). While the presented data focuses on time points from E7 to E7.5, it can be applied to embryos up to E8 (Figure 1B) with small...

Discussion

A robust pipeline is presented in this paper for obtaining high-quality single-cell and nuclei suspensions from gastrulating mouse embryos, specifically designed to facilitate studies on mechanisms of cell-fate specification in early development. This method addresses a crucial gap in the field of gastrulation by optimizing the analysis of embryos requiring genotypes, such as sex or somatic genes. By utilizing genetic mutation mouse models and employing high-resolution single-cell sequencing on whole mouse embryos, this ...

Materials

Name	Company	Catalog Number	Comments
10 cm Petri dish	Genesee Scientific	25-202
1000 µL Reach Barrier Tip	Genesee Scientific	23-430
20 µL Reach Barrier Tip	Genesee Scientific	24-404
300 µL Reach Barrier Tip	Genesee Scientific	24-415
37 µm Reversible Strainer, small	Stem Cell	27215
6 cm Petri dish	Genesee Scientific	25-260
8-strip PCR tubes	Genesee Scientific	27-125U
Agarose	Apex Bioresearch Product	20-102
Benchmark Scientific BSH300 MyBlock Mini Dry Bath	Genesee	31-437
Benchmark Scientific Z216-MK Z216MK Hermle Refrigerated Microcentrifuge	Genesee	33-759R
Bovine Serum Albumin (BSA)	Sigma-Aldrich	A2153
Chromium Controller	10X	PN-1000127
Chromium Next GEM Single Cell 3' Reagent Kits v3.1	10X	PN-1000269
Countess 3 Automated Cell Counter	Invitrogen	AMQAX2000
Countess Cell Couning Chamber Slides	Invitrogen	C10283
D1000 Reagents	Agilent	5067-5583
D1000 ScreenTape	Agilent	5067-5582
Digitonin	ThermoFisher Scientific	BN2006
DirectPCR yolk sac	Viagen	201-Y
Dithiothreitol (DTT)	ThermoFisher Scientific	R0861
DNA LoBind Tube 1.5 mL	Eppendorf	22431021
Dubecco's Modificiation of Eagle's Medium (DMEM, 1x)	CORNING	10-013-CV
Dulbecco's PBS	GenClone	25-508
Dumont #5 Fine Forceps	Fine Science Tools	11254-20
Dumont #5SF Forceps	Fine Science Tools	11252-00
Ethanol	Koptec	V1401
EVOS M7000 Imaging System	Invitrogen	AMF7000
Fine Scissors - Sharp	Fine Science Tools	14060-11
GoTaq G2 Green Master Mix	Promega	M7823
Graefe Forceps	Fine Science Tools	11049-10
MgCl2	ThermoFisher Scientific	AC223211000
MiniAmp Thermal Cycler	Applied Biosystems	A37834
NaCl	Fisher Chemical	S271-500
NextSeq 1000/2000 P2 Reagents (100 Cycles) v3	Illumina	20046811
NextSeq2000	Illumina
Nikon SMZ 1000 Stereo Microscope	Nikon
Nondiedt P40	Sigma-Aldrich	74385
Nuclease-free Water	GenClone	25-511
Optical Tube 8x Strip (401428)	Agilent	401428
Optical Tube Cap 8x Strip (401425)	Agilent	401425
Poseidon 31-511, HS24 Microcentrifuge, with 24 x 1.5/2.0 mL rotor, 1 Centrifuge/Unit	Genesee	31-511
Proteinase K	Sigma-Aldrich	P6556
Qubit dsDNA Quantification Assay Kits	Invitrogen	Q32851
Qubit Flex 3	Invitrogen
RNase inhibitor	Fisher Scientific	12-141-368
Standard Pattern Forceps	Fine Science Tools	11000-12
Tape Station Loading tips	Agilent	5067-5598
Tapestation 4150	Agilent	G2992AA
Tris-HCL (Ph7)	Quality Biological	351-007-101
Trypan Blue Stain 0.4%	Theromo Fisher Scientific	T10282
Tryple Express	Gibco	12604-021
Tween-20	Bio-Rad	1662404
Vortex mixer IKA MS3 with 96-well sample plate adapter	IKA	3617000