Evercode WT Mega v2.2.1

Parse Biosciences; Elisabeth Rebboah

Nov 08, 2023

Evercode WT Mega v2.2.1

DOI

dx.doi.org/10.17504/protocols.io.8epv5xxrng1b/v1

Parse Biosciences¹,
Elisabeth Rebboah²

¹Parse Biosciences;
²University of California, Irvine

IGVF

Elisabeth Rebboah

University of California, Irvine

DOI: dx.doi.org/10.17504/protocols.io.8epv5xxrng1b/v1

External link: https://www.parsebiosciences.com/

Protocol Citation: Parse Biosciences, Elisabeth Rebboah 2023. Evercode WT Mega v2.2.1. protocols.io https://dx.doi.org/10.17504/protocols.io.8epv5xxrng1b/v1

Manuscript citation:

Rosenberg, A.B., Roco, C.M., Muscat, R.A., Kuchina, A., Sample, P., Yao, Z., Graybuck, L.T., Peeler, D.J., Mukherjee, S., Chen, W., Pun, S.H., Sellers, D.L., Tasic, B., and Seelig, Georg (2018). Single-cell profiling of the developing mouse brain and spinal cord with split-pool barcoding. Science, 360(6385), 176-182.

License: This is an open access protocol distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited

Protocol status: Working

We use this protocol and it's working

Created: August 17, 2023

Last Modified: November 08, 2023

Protocol Integer ID: 86577

Keywords: Parse Biosciences, snRNA-seq, Split-seq, Evercode WT Mega, Evercode, scRNA-seq, Single cell, Parse Bio, Parse, Mortazavi, UCI, IGVF, Mouse

Abstract

This protocol describes the original Parse Biosciences Evercode WT Mega v2 protocol for single-nucleus or single-cell RNA-seq of 1,000,000 nominal nuclei or cells. Unlike other scRNA-seq methods that physically separate individual cells into different compartments to label transcripts with cell-specific barcodes, Evercode WT Mega uses the cells (or nuclei) themselves as “containers” in which intracellular transcripts are labeled using combinatorial indexing. In practice, cells are split into different wells, a well-specific barcode is appended to intracellular transcripts, and cells are then pooled back together. Repeating this process several times ensures a high likelihood that each cell travels through a unique combination of wells. Consequently, the transcriptome of each individual cell is labeled with a unique combination of well-specific barcodes. Unlike previous methods that scale linearly with the number of available compartments and barcodes, this method scales exponentially with the number of barcoding rounds, enabling a massive increase in the number of cells that can be sequenced, while minimizing doublets.

The products of this protocol are up to 16 subpools of varying size, where each molecule has a cell/nucleus barcode and UMI, ready for Illumina short-read sequencing. The cell/nucleus barcode is unique within each subpool, so the subpol index acts as the fourth barcode to uniquely barcode all the cells/nuclei within an experiment. Please see the attachment for the original Parse Biosciences protocol. The main deviations from the original protocol are 1. loading 15 ul rather than 14 ul in the Round 1 barcoding plate and 2. saving all "leftover" barcoded nuclei or cells at -80C for potential repeats.

The first part of the protocol, Section 1, describes barcoding cells or nuclei. Briefly, fixed cells/nuclei are thawed and added to the Round 1 reverse transcription barcoding plate at 37,500 cells/nuclei per well across 96 wells. Individual samples from each tissue are distributed in the sample barcoding plate with at least 1 well per sample. Within the fixed cells/nuclei, RNA is reverse transcribed using oligodT and random hexamer primers and the first barcode is annealed. After RT, cells/nuclei are pooled and distributed in 96 wells of the Round 2 ligation barcoding plate for in situ barcode ligation. After Round 2, cells/nuclei are pooled and redistributed into 96 wells of the Round 3 ligation barcoding plate for barcode 3 and Illumina adapter ligation. Finally, cells/nuclei are counted using a hemocytometer, distributed into up to 16 subpools, and lysed. The second part, Section 2, describes template switching and amplification of the full-length cDNA. Importantly, full-length cDNA from Section 2 is the input for cDNA Exome Capture. For non-exome captured Illumina libraries, proceed to Section 3: Preparing Libraries for Sequencing. Section 3 describes Illumina library preparation with 100 ng of full-length cDNA per subpool. Subpool cDNA is fragmented and Illumina P5/P7 adapters are ligated during the final amplification. Importantly, if using single indices (WX100) please follow Appendix D: Single Indexing. If using dual indices (WX200) follow main protocol. Libraries with 5% PhiX spike-in are sequenced on an Illumina sequencer as paired-end, single-index (140/86/6/0) or dual-index reads (130/86/8/8).

Attachments

SO+10122022_+Evercod...

6.1MB

Materials

User Supplied Equipment and Consumables
The following materials and equipment are required to perform the protocol, but are not provided within the kit. Note that this list does not include standard laboratory equipment, such as freezers. Any questions regarding these items can be directed to support@parsebiosciences.com.

ItemSupplierPart NumberNotes
Centrifuge with Swinging Bucket RotorsVarious SuppliersVariesCapable of reaching 4°C. Compatible with 15 mL centrifuge tubes and 96-well plates.
MicrocentrifugeVarious SuppliersVariesCompatible with 1.5 mL and 0.2 mL tubes.
Heat BlockVarious SuppliersVariesOr equivalent water bath, bead bath, or thermomixer capable of holding temperature at 37°C.
HemocytometerSigma-AldrichZ359629Or other cell counting device. We recommend validating alternatives relative to a hemocytometer.
Single Channel Pipettes: P20, P200, P1000 12-channel: P20, P200Various SuppliersVariesOr 8-channel pipettes can be substituted for 12-channel.
T100 Thermal CyclerBio-Rad Laboratories1861096Or an equivalent thermocycler compatible with unskirted 96-well plates and a heated lid capable of 50-105°C.
Parse Biosciences Magnetic RackParse BiosciencesSB1004Magnetic strength is critical. If 3rd party magnetic racks are used, the number of transcripts and genes detected per cell will be compromised. This magnetic rack is compatible with most 0.2 mL PCR tubes.
6-Tube Magnetic Separation RackNew England BiolabsS1506SOr an equivalent magnetic rack for 1.5 mL tubes.
Vortex-Genie 2Scientific IndustriesSI-0236Compatible with a vortex adapter for 96-well plates. Or a shaker set to 800-1000 RPM. Part number varies with different lab voltage and frequency requirements.
6-inch PlatformScientific Industries146-6005-00Or an equivalent vortex adapter for 96-well plates.
Microplate Foam InsertScientific Industries504-0235-00Or an equivalent vortex adapter for 96-well plates.
Qubit Flex FluorometerThermo Fisher ScientificQ33327Or an equivalent fluorometer.
2100 BioanalyzerAgilentG2939BAChoose one.
4200 TapeStation SystemAgilentG2991BA
Equipment

ItemSupplierPart NumberNotes
Falcon High Clarity PP Centrifuge Tubes, 15 mLCorning352097Or equivalent 15 mL polypropylene centrifuge tubes. Do not substitute polystyrene centrifuge tubes as it will lead to substantial cell loss.
Corning Cell Strainer (70 μm or 100 μm)Corning431751 (70 μm) 431752 (100 μmFor cells larger than 40 μm, the 40 μm strainer should be replaced throughout the protocol with the appropriate size mesh (70 μm or 100 μm).
DNA LoBind Tubes, 1.5 mL, Snap CapEppendorf022431021Or equivalent DNA low-binding, nuclease-free 1.5 mL tubes.
DNA LoBind Tubes, 5 mL, Snap CapEppendorf0030108310Or equivalent DNA low-binding, nuclease-free 5 mL tubes.
TempAssure PCR 8-Tube Strips, 0.2 mLUSA Scientific1402-4700Or equivalent nuclease-free 0.2 mL PCR tubes.
Pipette Tips TR LTS 20 μL, 200 μL, 1000 μLRainin17014961
17014963
17014967Or appropriate sterile, DNA low-binding, and filtered pipette tips. Do not use wide bore tips. Autoclaved pipette tips are not RNase and DNase free.
RNaseZap RNase Decontamination SolutionThermo Fisher ScientificAM9780Or equivalent RNase decontamination solution.
Ethyl alcohol, PureSigma-Aldrich459844Or equivalent 100% non-denatured ethanol.
Nuclease-Free WaterSigma-AldrichW4502Or equivalent nuclease-free water.
Trypan BlueVarious SuppliersVariesOr alternative dyes that can be used to assess cell viability, such as AOPI.
KAPA Pure BeadsRocheKK8000 (5 mL) KK8001 (30 mL)Choose one. We do not recommend substituting other magnetic beads, including SPRIselect (Beckman Coulter) and ProNex (Promega).
AMPure XP ReagentBeckman CoulterA63880 (5 mL) A63881 (60 mL)
Qubit dsDNA HS (High Sensitivity) Assay KitThermo Fisher ScientificQ33230 (100 assays) Q33231 (500 assays)Or equivalent DNA quantifier.
High Sensitivity DNA KitAgilent5067-4626
Choose one that corresponds to chosen Bioanalyzer or TapeStation.
High Sensitivity D5000 ScreenTape and ReagentsAgilent5067-5592 (screen tape) 5067-5593 (sample buffer and ladder)
Consumables

Before start

User Supplied Equipment and Consumables: Before starting an experiment, check the "User Supplied Equipment and Consumables" section and confirm that your lab has all of the supplies that are not provided by the kit. Avoid substituting custom materials for those that are provided in the kit. Each item has been deliberately chosen to attain optimal results.
Avoiding RNase Contamination: Standard precautions should be taken to avoid introducing RNases into samples or reagents throughout the workflow. Always wear proper laboratory gloves and use aseptic technique. RNases are not inactivated by ethanol or isopropanol, but can be inactivated by specific products such as RNaseZap RNase Decontamination Solution (Thermo Fisher Scientific). These can be sprayed on benchtops and used to clean pipette. It is recommended to use pre-sterilized, filter pipette tips to reduce RNase contamination from pipettes.
Centrifuges: Use a swinging bucket centrifuge for all high speed spin steps in this protocol. Use of a fixed-angle centrifuge will lead to substantial cell loss. Although the recommended centrifugation speeds are appropriate for most sample types, they can be adjusted to improve retention.
Centrifuge Tubes: Ensure that the tubes will be used are polypropylene and not polystyrene. Polystyrene tubes will lead to substantial cell loss.
Sample Handling: It is critical that cells are thoroughly resuspended after centrifugation. Resuspend cells by slowly (to prevent mechanical damage) and repeatedly pipetting up and down until no clumps are visible. Wide bore pipette tips are not recommended as they make it difficult to adequately resuspend cell pellets. Due to cell adherence to tubes, it is recommended to carefully pipette along the bottom and sides of the centrifuge tubes to minimize cell loss.
Sample Loading Table: The "WT Mega - Sample Loading Table V1.2.0" (Excel spreadsheet) should be completed before starting the experimental workflow. If not working properly, ensure that the Macros are enabled in the Sample Loading Table. Be sure to only edit the colored cells on the table to avoid disturbing the necessary formatting.
Maximizing Cell Retention During Pooling Steps: During the barcoding steps, some cells may stick to the side of the wells in the 96-well plates. To increase cell retention, it is important to pipette up and down several times in each well before removing and pooling cells. Note that additional pipetting may lead to increased bubbles while pooling. While bubbles will not affect results, we advise using caution when pipetting to prevent excess bubble formation and maintain experimental ease. We recommend the following procedure when pooling:
Set the multichannel P200 to 10 µL less than the volume in each well. The volumes for Barcoding Rounds 1, 2, and 3 should be 30 µL, 50 µL, and 70 µL, respectively. This will avoid bubbles while pipetting up and down.
Insert tips into the bottom of the wells. Pipette up and down 3x in the middle of the well, then pipette up and down 3x on the front side of the well, followed by 3x on the back side of the well, before proceeding with pooling cells.
Pool any remaining liquid left in the wells (should be ~10 µL).
Sealing Plates in Original Container: There are multiple steps requiring the removal and application of seals to 96-well plates. In either motion, ensure that the plate is in its original container for best support. Failure to do so may result in plate slippage and loss, or swapping, of liquid between wells.
Cell Strainers: A 40 µm cell strainer will be used in multiple steps. To maximize cell retention, press the pipette tip directly against the stainer. Ensure that ample pressure is applied to hold contact between the tip and the strainer to force liquid through in ~1 second. For cells larger than 40 µm, the 40 µm strainer should be replaced throughout the protocol with the appropriate size mesh (70 µm or 100 µm).
Lysis Buffer Precipitate: Ensure that there is no precipitate when using the 2x Lysis Buffer. Warming the 2x Lysis Buffer at 37C for 5 minutes should resolubilize solution. If precipitate remains, warm 2x Lysis buffer at 37C for another 5 minutes.
Sequencing Libraries: Multiple sequencing libraries can be prepared from the same experiment. At the end of barcoding (Section 1), the recovered cells can be split across different sublibraries. The number of cells to be sequenced is determined when cells are divided into sublibraries at the lysis step. Thus, not all of the cells prepared in these steps must be sequenced together.

Section 1: Barcoding Single Cells

1.1: Experimental Setup

Prepare for the first round of barcoding with the following checklist:
Each sample should have been counted after nuclei fixation and recorded on the spreadsheet in order to calculate volumes to normalize concentrations to 2,500 cells/nuclei per ul. Adjust target volumes as necessary depending on the volume needed in the final plate(s).
At least a day ahead of the experiment, distribute dilution buffer in a new sample normalization plate one well at a time (NOT the actual barcoding plate) and store at -20C.
On the day of the experiment, take out sample normalization plate and thaw at room temperature. Centrifuge the plate at 100 x g for 1 minute and place on ice. 
Set your swinging bucket centrifuge to 4C.
Prepare a 37C water bath.
Fill some ice buckets, enough to hold 3 96-well plates and several tubes.

ItemLocationQuantityFormatAfter taking out
Adhesive 96-well plate coverAccessories (Room Temp)1With white protectorKeep at room temperature
Spin Additive4C Reagents (4C)11.5 mL tubeKeep at room temperature.
Dilution BufferBarcoding Reagents (-20C)22 mL tubeThaw, then place on ice
Resuspension BufferBarcoding Reagents (-20C)15 mL tubeThaw, then place on ice
Ligation MixBarcoding Reagents (-20C)15 mL tubeThaw, then place on ice
Round 2 Ligation EnzymeBarcoding Reagents (-20C)11.5 mL tubeThaw, then place on ice
Round 1 PlateBarcoding Reagents (-20C)196-well plateThaw, then place on ice
Round 2 PlateBarcoding Reagents (-20C)196-well plateThaw, then place on ice
Critical! Only proceed if you have completed the checklist in step 1 and taken out all the items listed in step 2.

To thaw, place the Round 1 Plate into a thermocycler and set the following protocol below. The heated lid will force any liquid on the plastic plate seal back down into the well. Proceed to the next step while the thermocycler is running.


Run TimeLid TemperatureSample Volume
10 min70C26 µl 
Round 1 Plate Thaw Protocol Overview

StepTimeTemperature
110 min25C
2Hold4C
Round 1 Plate Thaw Protocol

1.2: Sample Counting and Loading Setup

Thaw the fixed cell samples in a 37C water bath until all ice crystals dissolve, then place on ice. It is important to fully thaw samples before placing on ice.

Arrange samples in desired order in 1.5 mL plate racks on ice. 
Critical! Double-check order of samples matches the order on the spreadsheet.

Note: This step requires a new box of 20 µl tips.
Using a Move-it multichannel pipette with adjustable spacer, pipette fixed nuclei/cells from 1.5 mL tubes to sample normalization plate. Should be same volume across entire plate. When pipetting cells/nuclei, mix gently by pipetting up and down when taking cells/nuclei and again when dispensing.

1.3: Reverse Transcription Barcoding
During this section, cDNA will be reverse transcribed from RNA with barcoded RT primers specific to each well. 

Gently remove the Round 1 Plate from the thermocycler and place into the original green plastic plate holder. Centrifuge the plate at 100 x g for 1 minute.

Place the plate (and holder) on a flat surface and remove the plastic seal. Store on ice.
Note: Plate seals may be difficult to remove. Carefully peel the plate seal while applying downward pressure to keep the plates from moving (to minimize cross-contamination of wells).

Add diluted samples to wells in the Round 1 Plate.
Note: To prevent sample loss, mix cells as indicated below. Additionally, this step requires a new box of 20 µl tips.
Follow the Sample Loading Table during this step to determine which samples to add to each well. Using a multichannel pipette, add 15 µl nuclei/cells from the sample normalization plate to each of the 96 wells in the Round 1 Plate. Immediately after dispensing cells, mix gently by pipetting up and down exactly 3x. When pipetting the same sample into many wells, the same sample should be periodically mixed by gentle pipetting to avoid cells settling. Do not vortex your cells.
Critical! Different tips must be used when pipetting cells into the 96-well plate. Never place a tip that has entered one of the 96 wells into a different well. 

Remove the Round 1 Plate and holder from the ice bucket and place on a flat surface. Seal the Round 1 Plate with an additional 96-well plate seal cover.
Note: Plate sealer is included in the Accessories box.

Start the reverse transcription reaction. Put the Round 1 Plate with cells into a thermocycler with the following thermocycling protocol:


Run TimeLid TemperatureSample Volume
~40 min70C40 µl 
Round 1 Plate Barcoding Protocol Overview


StepTimeTemperature
110 min50C
212 sec8C
345 sec15C
445 sec20C
530 sec30C
62 min42C
73 min, then go to step 2 and repeat 2 times 3 cycles total)50C
85 min50C
9Hold4C
Round 1 Plate Barcoding Protocol

Transfer the Round 1 Plate from the thermocycler back to the original green plate holder and place on ice.

Thaw the Round 2 Plate by transferring the plate from the ice bucket into the thermocycler and running the following protocol. Proceed directly to the next step.

Run TimeLid TemperatureSample Volume
10 min70C10 µl 
Round 2 Plate Thaw Protocol Overview


StepTimeTemperature
110 min25C
2Hold4C
Round 2 Plate Thaw Protocol

Place the Round 1 Plate (and holder) on a flat surface and remove adhesive seal. Place back on ice.

Pool all wells from the Round 1 Plate into a single 15-mL centrifuge tube on ice.
Note: Proper mixing is required to prevent substantial cell loss during pooling. See "Maximizing Cell Retention During Pooling Steps" in Notes Before Starting.
The pooling process can be simplified (see figure below). With the multichannel pipette set to 30 µL, pool rows B-D into the wells in Row A, then pool rows F-H into the wells in Row E. To maximize cell retention while pooling, pipette up and down 3x in the middle of the well, 3x on the front side of the well, and 3x on the back side of the well before transferring the volume of the rows to Row A or Row E. Recover residual liquid across rows B-D and F-H using the multichannel pipette set to 10 µL. Next, pipette the total volume in Row A up and down 3x, then transfer the total volume of each well in Row A into the same 15 mL centrifuge tube with a single channel P200 pipette set to 200 µL. Do the same with Row E. Do not be concerned if there are a few µL of residual volume in the wells after pooling. 
Note: Bubbles may form while pooling. They will not affect the quality of the experiment.
Critical! Do NOT pool all eight rows into a single row or the liquid may overflow. Keep the Round 1 Plate and the 15 mL falcon tube with pooled cells on ice during the pooling step.

Discard the Round 1 Plate.

Add 19.2 µL of Spin Additive to the 15 mL tube with pooled cells. Gently invert the tube once to mix. 
Critical! Do NOT discard the Spin Additive as it will be needed in another step.

Centrifuge the pooled cells in a swinging bucket centrifuge cooled to 4C for 10 minutes at 200 x g.
Critical! Move to the next step as soon as the centrifuge finishes and handle the tube gently to avoid dislodging the cell pellet. Waiting too long to aspirate supernatant increases the risk of dislodging the pellet.

Using a P1000 pipette for the first 3 mL, then a P200 pipette for remaining volume, aspirate supernatant such that about ~40 µL of liquid remains above the pellet. Do not disturb the pellet. Depending on the number of starting cells and cell types, the pellet may not be visible.

Note: To prevent substantial cell loss during resuspension, see "Sample Handling" in Notes Before Starting.
Gently resuspend cells with 1 mL of Resuspension Buffer. Once cells are fully resuspended, add an additional 1 mL  of Resuspension Buffer to make a total volume of 2 mL. Keep this solution on ice and proceed to Ligation Barcoding.

1.4: Ligation Barcoding

Gather the following items and handle as indicated below:


ItemLocationQuantityFormatAfter taking out
Adhesive 96-well plate coverAccessories (Room Temp)3With white protectorKeep at room temperature
40 um strainerAccessories (Room Temp)2In plastic bagKeep at room temperature
BasinsAccessories (Room Temp)6In plastic bagKeep at room temperature
Round 2 Stop MixBarcoding Reagents (-20C)12 mL tubeThaw, then place on ice
Round 3 Stop MixBarcoding Reagents (-20C)15 mL tubeThaw, then place on ice
Pre-Lyse Wash BufferBarcoding Reagents (-20C)15 mL tubeThaw, then place on ice
Round 3 Ligation EnzymeBarcoding Reagents (-20C)11.5 mL tubeThaw, then place on ice
Round 3 PlateBarcoding Plates (-20C)196-well platePlace directly on ice

Lightly centrifuge the Round 2 Ligation Enzyme and add 20 µL of Round 2 Ligation Enzyme directly into the cold Ligation Mix tube to make Ligation Mix + Enzyme.

Using a P1000 pipette, add 2 mL of cells in Resuspension Buffer into the Ligation Mix + Enzyme tube. Mix 10x with a P1000 pipette set to 1000 µL and place back on ice.
Critical! Do NOT vortex the Ligation Mix.

Transfer the Round 2 Plate from the thermocycler back to its original blue plate holder and keep at room temperature. Centrifuge the plate at 100 x g  for 1 minute. Place the plate (and holder) on a flat surface and remove the seal. Keep at room temperature.
Note: Plate seals may be difficult to remove. Carefully peel the plate seal while applying downward pressure to keep the plates from moving (to minimize cross-contamination of wells).

Using a P1000 pipette, add the entirety of cells in the Ligation Mix + Enzyme to a basin.

Add pooled cells to the Round 2 Plate.
Note: To prevent sample loss, mix cells as indicated below. Additionally, this step requires a new box of 200 µL tips.
Using a multichannel P200 pipette, add 40 µL of mix in the basin to each of the 96 wells in the Round 2 Plate. As you add the 40 µL to each well, pipette up and down exactly 2x to ensure proper mixing. To avoid cells settling in the basin, also gently pipette up and down 2x with the multichannel pipette in the basin before transferring the cells from the basin to each row.
Note: Using a single channel pipette and tilting the basin may be required to fill the last row if volume in the basin is low. If volume is insufficient to fill every well, a few wells can be left empty without impacting experimental results.
Critical! Different tips must be used when pipetting cells into the 96-well plate. Never place a tip that has entered one of the 96 wells back into the basin.

Reseal the Round 2 Plate with an adhesive seal.

Start the second round of barcoding. Incubate the Round 2 Plate in a thermocycler with the following protocol:

Run TimeLid TemperatureSample Volume
30 min50C50 µL 
Round 2 Ligation Barcoding Overview

StepTimeTemperature
130 min37C
2Hold4C
Round 2 Ligation Barcoding Protocol

Vortex the Round 2 Stop Mix briefly (2-3 sec) and using a P1000 pipette, and the entirety (~1.4 mL) to a new basin.

Transfer the Round 2 Plate from the thermocycler back to its original blue plate holder and remove the seal. Keep the plate at room temperature.

Add Round 2 Stop Mix to each well.
Note: This step requires a new box of 20 µL tips.
Using a multichannel P20 pipette, add 10 µL of the Round 2 Stop Mix in the basin to each of the 96 wells of the Round 2 Plate. Pipette up and down exactly 3x to ensure proper mixing after adding Round 2 Stop Mix to each well.
Critical! Different tips must be used when pipetting Round 2 Stop Mix into the 96-well plate. Never place a tip that has entered one of the 96 wells back into the basin.

Reseal the Round 2 Plate with an adhesive seal. 

Incubate the Round 2 Plate in a thermocycler with the following protocol:

Run TimeLid TemperatureSample Volume
30 min50°C60 μL
Round 2 Stop Overview

StepTimeTemperature
130 min37°C
2Hold4°C
Round 2 Stop Protocol

Transfer the Round 2 Plate from the thermocycler to its original blue plate holder and keep at room temperature.

Thaw the Round 3 Plate by transferring it from the ice bucket into the thermocycler and running the following protocol. Proceed directly to the next step.

Run TimeLid TemperatureSample Volume
10 min70C10 µl 
Round 3 Plate Thaw Overview

StepTimeTemperature
110 min25C
2Hold4C
Round 3 Plate Thaw Protocol

Remove the seal on the Round 2 Plate.

Pool all wells from the Round 2 Plate into a new basin. 
Note: Proper mixing is required to prevent substantial cell loss during pooling. See "Maximizing Cell Retention During Pooling Steps" in Notes Before Starting.
With the multichannel pipette set to 50 µL, pool volume from each well into a new basin. To maximize cell retention while pooling, pipette up and down 3x in the middle of the well, 3x on the front sides of the well, and 3x on the back side of the well before transferring the volume of rows A-H to the basin. Recover residual liquid across all rows using the multichannel pipette. Do not be concerned if there are a few µL of residual volume in the wells after pooling.
Note: Bubbles may form while pooling. They will not affect the quality of the experiment.

Discard the Round 2 Plate.

Remove the 40 µm strainer from the packaging and carefully hold the strainer using the outside casing without touching the mesh. Using a P1000 pipette set to 1000 µL, pass all cells from this basin through the 40 µm strainer into a new basin. Mix cells in the basin between passages. The original basin must be tilted in order to pipette the final volume.
Note: For cells larger than 40 µm, the 40 µm strainer should be replaced throughout the protocol with the appropriate size mesh (70 µm or 100 µm). Additionally, bubbles may form while straining. They will not affect the quality of the experiment.
Critical! To ensure that all of the liquid passes through the strainer, press the tip of the pipette against the filter and press the pipette plunger down steadily. All of the liquid should pass through the strainer in ~1 second.

Add 20 µL of Round 3 Ligation Enzyme to the basin with the strained cells and mix by gently pipetting up and down ~20x with a P1000 pipette set to 1000 µL.

Transfer the Round 3 Plate from the thermocycler back to its original orange plate holder. Centrifuge the plate at 100 x g for 1 minute. Plate the plate (and holder) on a flat surface and remove the seal. Keep at room temperature.
Note: Plate seals may be difficult to remove. Carefully peel the plate seal while applying downward pressure the keep the plates from moving (to minimize cross-contamination of wells).

Add pooled cells to the Round 3 Plate.
Note: To prevent sample loss, mix cells as indicated below. Additionally, this step requires a new box of 200 µL tips.
Using a multichannel P200 pipette, add 50 µL of mix in the basin to each of the 96 wells in the Round 3 Plate. As you add the 50 µL to each well, pipette up and down exactly 2x to ensure proper mixing. To avoid cells settling in the basin, also gently pipette up and down 2x with the multichannel pipette in the basin before transferring the cells from the basin to each row.
Note: Using a single channel pipette and tilting the basin may be required to fill the last row if volume in the basin is low. If volume is insufficient to fill every well, a few wells can be left empty without impacting experimental results.
Critical! Different tips must be used when pipetting cells into the 96-well plate. Never place a tip that has entered one of the 96 wells back into the basin.

Reseal the Round 3 Plate with an adhesive seal.

Start the third round of barcoding. Incubate the Round 3 Plate in a thermocycler with the following protocol:

Run TimeLid TemperatureSample Volume
30 min50C60 µL
Round 3 Ligation Barcoding Overview

StepTimeTemperature
130 min37C
2Hold4C
Round 3 Ligation Barcoding

Remove the Round 3 Plate from the thermocycler, place it in its original orange plate holder on a flat surface and remove the seal. Keep at room temperature.

Vortex the Round 3 Stop Mix briefly (2-3 sec) and using a P1000 pipette, add the entirety of the Round 3 Stop Mix to a new basin.

Add Round 3 Stop Mix to each well.
Note: This step requires of 20 µL tips. 
Using a multichannel P20 pipette, add 20 µL of the Round 3 Stop Mix in the basin to each of the 96 wells of the Round 3 Plate. Pipette up and down exactly 3x to ensure proper mixing after adding the Round 3 Stop Mix to each well. No incubation required after this step, proceed directly to the next step.
Critical! Different tips must be used when pipetting stop mix into the 96-well plate. Never place a tip that has entered one of the 96 wells back into the basin.

Pool all cells from the Round 3 Plate into a new basin.
Note: Proper mixing is required to prevent substantial cell loss during pooling. See "Maximizing Cell Retention During Pooling Steps" in Notes Before Starting.
With the multichannel pipette set to 70 µL, pool volume from each well into a new basin. To maximize cell retention while pooling, pipette up and down 3x in the middle of the well, 3x on the front sides of the well, and 3x on the back side of the well before transferring the volume of rows A-H to the basin. Recover residual liquid across all rows using the multichannel pipette. Do not be concerned if there are a few µL of residual volume in the wells after pooling.
Note: Bubbles may form while pooling. They will not affect the quality of the experiment.
 

Discard the Round 3 Plate.

Remove a 40 µm strainer from the packaging and carefully hold the strainer using the outside casing without touching the mesh. Using a P1000 pipette set to 1000 µL, pass all the cells from this basin through a 40 µm strainer into a new 15 mL tube on ice. Mix cells in the basin in between passages. The basin must be tilted in order to pipette the final volume. Keep the 15 mL tube on ice and proceed to lysis.
Note: Bubbles may form while straining. They will not affect the quality of the experiment.

1.5: Lysis and Sublibrary Generation

Gather the following items and handle as indicated below:

ItemLocationQuantityFormat After taking out
2x Lysis Buffer4C Reagents (4C)11.5 mL tubeKeep warm at 37C until use.
Lysis EnzymeBarcoding Reagents (-20C)11.5 mL tubePlace directly on ice.
Dilution BufferBarcoding Reagents (-20C)22 mL tubeThaw, then place on ice.

Add 70 µL of Spin Additive to your cells in a 15 mL centrifuge tube. Gently invert the tube once to mix.

Use a swinging bucket centrifuge to spin down the cells for 10 minutes at 200 x g at 4C.

Using a P1000 pipette for the first 6 mL, then a P200 pipette for the remaining volume, aspirate supernatant such that ~40 µL of liquid remains above the pellet. Do not disturb the pellet. Depending on the number of starting cells and cell types, the pellet may not be visible.

Note: To prevent substantial cell loss during resuspension, see "Sample Handling" in Notes Before Starting.
Gently resuspend cells with 1 mL of Pre-Lyse Wash Buffer. When resuspending the pellet, pipette slowly to prevent mechanical damage to cells. Once cells are fully resuspended, add an additional 3 mL of Pre-Lyse Wash Buffer for a total volume of 4 mL.

Use a swinging bucket centrifuge to spin down for 10 minutes at 200 x g at 4C.

Using a P1000 for the first 3 mL, then a P200 pipette for the remaining volume, aspirate supernatant such that ~40 µL of liquid remains above the pellet (see image on the right for estimate of 40 µL). Do not disturb the pellet. Depending on the number of starting cells and cell types, the pellet may not be visible.

Note: To prevent substantial cell loss during resuspension, see "Sample Handling" in Notes Before Starting.
Using a P200 pipette, gently resuspend the pellet with an additional 200 µL of Dilution Buffer, bringing the final volume to ~240 µL. When resuspending the pellet, pipette slowly to prevent mechanical damage to cells. Keep tubes on ice.
Critical! Do NOT discard Dilution Buffer as it will be needed in another step.

Using a P200 pipette set to 200 µL, gently pipette up and down the 5x and immediately use 5 µL of the mixed cells to count using a hemocytometer. Keep the 15 mL tube on ice.
Note: When using a hemocytometer, dilute 5 µL of the mixed cell solution into 5 µL of Trypan Blue or DAPI. Mix well and load onto the hemocytometer. Some level of debris is normal at this step. Alternatively, cells can be counted via flow cytometry, but using a hemocytometer is strongly recommended. 

Choosing Sublibrary SIzes: In the following step, cells will be aliquoted into different sublibraries that will be prepared for sequencing. At the end of the library prep, each sublibrary will have its own sublibrary index, making it possible to sequence each sublibrary with different numbers of reads. It is also possible to add different numbers of cells to each sublibrary. In practice it can be useful to have at least one sublibrary with very few cells (200-500) that can be sequenced deeply (>50,000 reads per cells) with a limited number of overall reads. This sublibrary then provides a good estimate of gene and transcript detection per cell that would be expected if the other sublibraries were also sequenced deeply. The maximum number of cells that can eventually be sequenced will be the sum of the number of cells across all sublibraries.

We slightly overload 15 subpools with 67,000 cells/nuclei and one subpool with 13,000 cells/nuclei for exome capture and long read sequencing. Any extra barcoded cells/nuclei are distributed in additional 67,000 aliquots and kept at -80C.

Determine sublibrary size(s) and dilutions. Up to 16 sublibraries, of varying sizes, can be made. Use the "Sublibrary Generation Table" (Appendix A) to determine the volume of cells and Dilution Buffer to add to each sublibrary (dependent on desired sublibrary size and the concentration of cells measured in the previous step). Give each sublibrary a unique label. Make sure to record which sublibrary sizes correspond to what labels. Label both the top and side of the PCR tube with those labels. 
Critical! Do NOT overload a sublibrary. 62,500 cells/sublibrary is the maximum. Overloading a sublibrary lysate with too many cells will result in increased doublets.

Using a P200 pipette set to 200 µL, gently pipette up and down 5x. Aliquot the determined volume of cells (from the previous step) to each correctly labelled sublibrary PCR tube and add Dilution Buffer to bring to total volume to 25 µL. Between each aliquot, gently pipette mix the cells to avoid settling. Store sublibraries on ice.

Make a Lysis Master Mix. Ensure there is no precipitate present in the 2x Lysis Buffer. Add 440 µL of 2x Lysis Buffer to 88 µL of Lysis Enzyme in a 1.5 mL tube.
Critical! Do NOT place Lysis Master Mix on ice, as a precipitate will form.

Add Lysis Master Mix to sublibraries. Add 30 µL of Lysis Master Mix to each tube, bringing the total volume to 55 µL. Keep sublibraries at room temperature.

Vortex samples for 10 sec to initiate lysis. Be sure to keep caps closed on tubes. Briefly centrifuge tubes (~2 sec).

Incubate the sublibrary lysates in a thermocycler with the following protocol.

Run TimeLid TemperatureSample Volume
60 min80C55 µL
Sublibrary Lysis Overview

StepTimeTemperature
160 min65C
2Hold4C
Sublibrary Lysis Protocol

Freeze sublibrary lysate(s) at -80C. Sublibrary lysates can be stored for up to 6 months.
[STOPPING POINT]

Section 2: Amplification of Barcoded cDNA

2.1 Preparing Binder Beads
Any number of sublibraries (1-16) can be chosen for processing, where each sublibrary will ultimately be barcoded a fourth time with a sublibrary index. Take care not to cross-contaminate any sublibraries for the remainder of the experiment.
Setup
- Fill an ice bucket.
- Take out a magnetic rack for 1.5 mL tubes.
- Take out the Parse Biosciences magnetic rack for 0.2 mL PCR tubes.
- Ensure you have at least 79 µL of SPRI beads (Ampure XP or KAPA Pure Beads) per sublibrary.
Gather the following items and handle as indicated below:
Note: Do NOT remove sublibrary lysates from the freezer until the beginning of Section 2.2.

ItemLocationQuantityFormatAfter taking out
Binder Beads4C Reagents (4C)11.5 mL tubeKeep at room temperature.
Bead Wash BuffercDNA Amplification (-20C)15 mL tubeKeep at room temperature.
Bind Buffer AcDNA Amplification (-20C)11.5 mL tubeKeep at room temperature.
Bind Buffer BcDNA Amplification (-20C)15 mL tubeKeep at room temperature.
Bind Buffer CcDNA Amplification (-20C)15 mL tubeKeep at room temperature.
Bead Storage BuffercDNA Amplification (-20C)15 mL tubeKeep at room temperature.
TS BuffercDNA Amplification (-20C)12 mL tubeThaw, then place on ice.
Lysis NeutralizationcDNA Amplification (-20C)11.5 mL tubePlace directly on ice.

Vortex Binder Beads until fully mixed and add a volume to an empty 1.5 mL tube according to the number of sublibrary lysates that you plan to process:

ABCDEFGHIJ
# Sublibrary Lysates1234567816
Binder Beads (µL)4488132176220264308352704
Volume to Add by Number of Sublibrary Lysates (µL)

Capture the Binder Beads to a magnet using a magnetic rack (for 1.5 mL tubes) and wait until liquid becomes clear (~2 min).

Remove the clear supernatant with a pipette and discard.

Remove the tube from the magnetic rack and resuspend beads with the appropriate volume of Bead Wash Buffer (see table below). Ensure that all beads are fully resuspended and not stuck to the side of the tube.


ABCDEFGHIJ
# Sublibrary Lysates1234567816
Bead Wash Buffer (µL)50100150200250300350400800
Volume to Add by Number of Sublibrary Lysates (µL)

Capture the Binder Beads to a magnet using a magnetic rack (for 1.5 mL tubes) and wait until liquid becomes clear (~2 min).

Remove the clear supernatant with a pipette and discard.

Repeat steps 4-6 twice more for a total of three washes.

Remove the tube from the magnetic rack and resuspend beads in the appropriate volume of Bind Buffer A (see table below). Keep beads at room temperature and proceed to Section 2.2.

ABCDEFGHIJ
# Sublibrary Lysates1234567816
Bind Buffer A (µL)55110165220275330385440880
Volume to Add by Number of Sublibrary Lysates (µL)

2.2 Applying Binder Beads to Sublibrary Lysates

Remove the desired sublibrary lysates from the -80C freezer and incubate at 37C for 5 minutes, ensuring that no precipitate is present before proceeding. If precipitate is still present, incubate at 37C for 5 more minutes.

Briefly centrifuge sublibrary lysates (~ 2 sec).

Lightly centrifuge the Lysis Neutralizer, mix gently with a pipette, and add 2.5 µL to each sublibrary lysate. Place tubes into a 96-well plastic plate holder (press tubes securely into holder) and put plate holder lid back on. Vortex the plastic holder on 10 (or equivalent max setting) for 1 minute. Remove tubes from plate holder. Briefly centrifuge (~2 sec), and incubate at room temperature for 10 minutes.

Add Binder Beads to sublibrary lysates. First mix the Binder Beads suspended in Bind Buffer A by pipetting up and down. Then add 50 µL to each sublibrary lysate without pipette mixing the lysates. Place tubes in a plastic plate holder (press tubes securely into holder) and put plate holder lid back on. Vortex plastic holder on 10 (or equivalent max setting) for 1 minute. Discard the tube with any excess Binder Beads.
Critical! After adding beads to sublibrary lysates, mix by vortexing and not by pipetting.

Agitate the sublibrary lysates with Binder Beads at room temperature for 60 minutes. Place the tubes in a 96-well plastic plate holder (press tubes securely into the holder) with the lid on and then put the plastic holder into a foam attachment for a vortexer. Vortex on 2 (out of 10) for the duration of the 60 minute incubation (~800-1000 RPM).

Take the tubes off of the vortexer (beads may have settled somewhat). Vortex briefly (~5 sec) and then briefly centrifuge (~1 sec) without letting beads collect at the bottom of the tubes.

Place the tubes against a magnetic rack (for 0.2 mL tubes) on the high position (with magnets closest to the top) and wait for all the beads to bind to the magnet (~2 min).
Critical! The supernatant should be clear before proceeding. The cDNA is unamplified at this step, so discarding any beads in the supernatant will result in a reduction of transcripts and genes detected per cell.

Remove the clear supernatant with a pipette and discard, while still keeping the tubes in the magnetic rack.

Remove tubes from the magnetic rack and resuspend beads with 125 µL of Bind Buffer B. 

Keep tubes at room temperature for 1 minute.

Place the tubes against a magnetic rack on the high position and wait for all the beads to bind to the magnet (~2 min; liquid should be clear).

Remove the clear supernatant with a pipette and discard., while still keeping the tubes in the magnetic rack.

Repeat steps 9-12 for a second wash during Bind Buffer B.

Remove the tubes from the magnetic rack and resuspend beads with 125 µL of Bead Storage Buffer.

Keep tubes at room temperature for 1 minute.

Proceed directly to Section 2.3: Template Switch

2.3 Template Switch

Gather the following items and handle as indicated below:

ItemLocationQuantityFormatAfter taking out
TS Primer MixcDNA Amplification (-20C)11.5 mL tubeThaw, then place on ice
TS EnzymecDNA Amplification (-20C)11.5 mL tubePlace directly on ice

Ensure that the TS Buffer is fully thawed and has no white precipitate before proceeding.

In a new 1.5 mL tube, make the Template Switch Mix by adding the following volumes of TS Buffer, TS Primer Mix, and TS Enzyme together. Mix well and store on ice.
Critical! If processing more than 10 sublibrary lysates at one time, use a. new 5 mL or 15 mL tube to make the Template Switch Mix.

ABCDEFGHIJ
# Sublibrary Lysates1234567816
TS Buffer101.75203.5305.25407508.75610.5712.258141,628
TS Primer Mix2.755.58.251113.7516.519.252244
TS Enzyme5.51116.52227.53338.54488
Total1102203304405506607708801,760
Volume to Add by Number of Sublibrary Lysates (µL)

Place the sublibrary tubes against a magnetic rack (for 0.2 mL tubes) on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).
Critical! The supernatant should be clear before proceeding. The cDNA is unamplified at this step, so discarding any beads in the supernatant will result in a reduction of transcripts and genes detected per cell.

Remove the clear supernatant with a pipette and discard while still keeping the tubes in the magnetic rack.

Without resuspending beads, add 125 µL of Bind Buffer C and wait 1 minute.
Critical! Do NOT discard the supplied stock of Bind Buffer C as it will be used again in a later step.

Without removing tubes (still in magnetic rack), remove and discard Bind Buffer C from each tube using a pipette. 

Remove the tubes from the magnetic rack and resuspend beads with 100 µL of Template Switch Mix.
Note: Template Switch Mix is a viscous solution. Ensure that beads are fully resuspended and well mixed before progressing.

Centrifuge tubes very briefly (~1 sec). Longer centrifugation times will cause beads to settle.

Incubate sublibraries at room temperature for 30 minutes.

Mix sublibraries by pipetting 5x, ensuring that beads that may have settled are resuspended. Be careful to prevent any losses of bead volumes while pipetting. Incubate sublibraries in a thermocycler with the following protocol:

Run TimeLid TemperatureSample Volume
90 min70C100 µL
Sublibrary Template Switching Overview

StepTimeTemperature
190 min42C
2Hold4C
Sublibrary Template Switching

If you would like to stop and store sublibraries, proceed with the following steps. If you are continuing the protocol, proceed directly to Section 2.4: cDNA Amplification.
Note: You may need to pipette mix to resuspend settled beads.
a. Place the tubes against a magnetic rack on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).
b. Remove the clear supernatant with a pipette and discard, while still keeping the tubes in the magnetic rack.
c. Resuspend the beads in 125 µL of Bead Storage Buffer.
d. Store tubes at 4C overnight. Do not freeze sublibraries.

2.4 cDNA Amplification
Multiple thermocyclers may be needed for this section depending on your sample types and sublibrary sizes. Refer to step 2.4.8 to determine how many thermocyclers are needed.

Gather the following items and handle as indicated below:

ItemLocationQuantityFormatAfter taking out
Amplification Master BuffercDNA Amplification (-20C)11.5 mL tubeThaw, then place on ice
Amplification Primer MixcDNA Amplification (-20C)11.5 mL tubeThaw, then place on ice

In a new 1.5 mL tube, make the Amplification Reaction Solution by adding the following volumes of Amplification Master Buffer and Amplification Primer Mix. Mix well and store on ice.
Critical! If processing more than 10 sublibrary lysates at one time, use a new 5 mL tube or 15 mL tube to make the Amplification Reaction Solution.

# Sublibraries1234567816
Amplification Master Buffer60.5121181.5242302.5363423.5484968
Amplification Primer Mix60.5121181.5242302.5363423.5484968
Total1212423634846057268479681,936
Volume to Add by Number of Sublibrary Lysates (µL)

Place the sublibrary tubes against a magnetic rack (for 0.2 mL tubes) on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).
Note: You may need to pipette mix to resuspend settled beads.

Remove the clear supernatant with a pipette and discard while still keeping the tubes in the magnetic rack.

Without resuspending beads, add 125 µL of Bind Buffer C and wait for 1 minute. Do not remove the tubes from the magnetic rack during this time.

Remove the clear supernatant with a pipette and discard.

Remove the tubes from the magnetic rack and resuspend beads in each time with 100 µL of Amplification Reaction Solution. Place tubes with Amplification Reaction Solution on ice.

For each sublibrary, determine the cDNA amplification cycling conditions. Only the number of 2nd cycles (X) changes with cell type and sublibrary size. Below are recommended cycling conditions for commonly used cell types.

Cell TypeNumber of Cells/Nuclei in Individual SublibraryNumber of 1st Cycles (PCR Steps 2-4)Number of 2nd cycles (X) (PCR Steps 5-7)
Mammalian Cell Lines200-1,000512
1,000-2,000510
2,000-6,00058
6,000-12,50056
12,500-25,00055
25,000-62,50054
Nuclei200-1,000513
1,000-2,000511
2,000-6,00059
6,000-12,50057
12,500-25,00056
25,000-62,50055
Immune cells (PBMCs)200-1,000514
1,000-2,000512
2,000-6,000510
6,000-12,50058
12,500-25,00057
25,000-62,50056
Note: 1-2 cycles may need to be added (to 2nd cycling) to account for cells with low RNA content. The cycling protocol may need to be optimized for your sample type.

Start cDNA amplification. Group sublibraries with the same cycling conditions in their own thermocycler with the following protocol, adjusting the number of 2nd cycles (X) according to the table on step 2.4.8.
Note: For primer annealing, steps 3 and 6 below (*) have different time and temperature settings. Double check the settings you input into the thermocycler before starting the amplification protocol.

Run TimeLid TemperatureSublibrary Volume
50-70 min105C100 µL
Amplification Overview

StepTimeTemperature
13 min95C
220 sec98C
3*45 sec*65C
43 min, then go to step 2, repeat 4 times (5 cycles total)72C
520 sec98C
6*20 sec*67C
73 min, then go to step 5, repeat X-1 times (X cycles total)72C
85 min72C
9Hold4C
Amplification Protocol
Example: If you had 500 cells (with medium to high RNA content), your cycling conditions would be: 5 (first cycling) and 12 (second cycling). In this scenario, you would *Go to step 2, repeat 4 times (5 cycles total)" and "Go to step 5, repeat 11 times (12 cycles total)".

Remove tubes from the thermocycler. Sublibraries can be stored at this point at 4C overnight. If you wish to continue, proceed directly to Section 2.5: Post-Amplification SPRI Clean Up.
[STOPPING POINT]

2.4 Post-Amplification SPRI Clean Up

Place the sublibrary tubes against a magnetic rack (for 0.2 mL tubes) on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).
Critical! Do NOT discard the supernatant at this step.

Transfer 90 µL of the clear supernatant into new 200 µL PCR tubes. Discard the original tubes with the magnetic beads.

Remove SPRI beads (Ampure XP or KAPA Pure Beads) from the 4C fridge and aliquot the following amount into a 1.5 mL tube (this accounts for 10% extra volume):

ABCDEFGHIJ
# Sublibraries1234567816
SPRI Beads Needed791582383173964755546341,266
Volume to Add by Number of Sublibrary Lysates (µL)

Prepare a fresh 85% ethanol solution (400 µL) for each sublibrary.

Add 72 µL of SPRI beads to each sublibrary (90 µL) for a total volume of 162 µL.

Close the tops of the tubes securely, vortex (~5 sec), then centrifuge briefly (~2 sec).

Incubate at room temperature for 5 minutes.

Place the tubes against a magnetic rack on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).

With SPRI beads still against a magnetic rack, aspirate and discard the clear supernatant with a pipette.

Without resuspending beads, add 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard the ethanol from each tube.

Without resuspending beads, add another 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard the ethanol from each tube (it may be necessary to remove the final few drops with a P20 pipette). With the tube still on the rack, air dry the beads (~2 min).
Critical! Do NOT over-dry the beads. Over-drying of beads can lead to substantial losses in yield. "Cracking" of the beads is a sign of over-drying.

Remove the tubes from the magnetic rack and resuspend beads from each tube in 25 µL of molecular biology grade water.

Incubate the tubes at 37C for 10 minutes to maximize elution of amplified cDNA.

Place the tubes against a magnetic rack on the low position (with magnets closest to the bottom) and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).

Transfer 25 µL of the eluted DNA into new PCR tubes with a P200 pipette. Discard the tubes with the SPRI beads. The amplified cDNA is now ready to be quantified.
Note: Label the new PCR tubes as cDNA to avoid confusion in subsequent steps.

Measure the concentration of the cDNA using the Qubit dsDNA HS protocol.
Note: Be sure to record sample concentrations as they will be needed for further downstream steps (Section 3.5: Sublibrary Index PCR).

Run 1 µL of the cDNA on a Bioanalyzer or TapeStation. Use the concentration obtained from the Qubit to determine the appropriate dilution necessary (check manufacturer specifications, 1:10 dilution is generally appropriate). See Figure 1 for the expected cDNA size distribution.

Fig. 1: Expected cDNA Size Distribution after cDNA Amplification. (A) Example trace of cDNA run on a Bioanalyzer. (B) Example trace of cDNA run on a TapeStation (it is normal for libraries to be shifted to the left on a TapeStation relative to a Bioanalyzer).
Note: The traces above are representative of typical Bioanalyzer and TapeStation cDNA traces. The shape and prominence of the trace is dependent on cell type, sublibrary size, and amount of DNA loaded into the Bioanalzyer or TapeStation. Sublibraries with minor deviations can still produce high quality data.

Sublibraries can be stored at this point at 4C for up to 2 days or at -20C for up to 3 months. If you wish to continue, proceed directly to Section 3: Preparing Libraries for Sequencing.
[STOPPING POINT].

Section 3: Preparing Libraries for Sequencing

Setup
- Prepare ~1.2 mL 85% ethanol per sublibrary lysate (e.g. 2.4 mL for 2 sublibraries).
- Fill an ice bucket.
- Take out the Parse Biosciences magnetic rack for 0.2 mL PCR tubes.
- Ensure you have at least 176 µL of SPRI beads (Ampure XP or KAPA Pure Beads) per sublibrary. These will be used throughout Section 3.
- Obtain recorded cDNA concentrations from step 2.5.18.
Gather the following items and handle as indicated below:

3.1 Fragmentation, End Repair, and A-Tailing
Vortex amplified cDNA briefly (2-3 sec). Be sure to keep caps closed on tubes. Briefly centrifuge tubes (~2 sec).

For each sublibrary to be sequenced, aliquot 100 ng of cDNA into a PCR strip tube, then add molecular biology grade water to bring the total volume to 35 µL. Ensure that any concentrations obtained by the Qubit, not the Bioanalyzer, are recorded for further downstream steps (Section 3.5: Sublibrary Index PCR) and store any remaining cDNA at -20C to be used for future experiments.
Note: Keep these tubes on ice.

Set the thermocycler to the following program:

Run TimeLid TemperatureSublibrary Volume
40 min70C50 µL
Sublibrary Fragmentation, End Repair, and A-Tailing Overview

StepTimeTemperature
1Hold4C
210 min32C
330 min65C
4Hold4C
Sublibrary Fragmentation, End Repair, and A-Tailing Protocol

Initiate the thermocycling program such that the machine is pre-cooled to 4C.

Vortex the Fragmentation Buffer followed by a brief centrifugation (~2 sec) and confirm it is fully thawed (no precipitate). 

Make the Fragmentation Mix, ensuring the Fragmentation Buffer and Fragmentation
Enzyme blend are well mixed before using (mix ~10x with a pipette after adding Fragmentation Enzyme):
ABCDEFGHIJ
# Sublibraries1234567816
Fragmentation Buffer5.51116.52227.53338.54488
Fragmentation Enzyme1122334455667788176
Total16.53349.56682.599115.5132264
Volume to Add by Number of Sublibrary Lysates (µL)

Add 15 µL of Fragmentation Mix to each sublibrary (should still be in cold block), bringing the total volume to 50 µL.

Mix sublibraries with a P200 multichannel pipette set to 40 µL Briefly centrifuge sublibraries (~2 sec) and place back on ice.

Place tubes in the chilled thermocycler and press "skip" or similar option to allow the machine to proceed to the next step. Confirm that the thermocycler has elevated to 32C and has proceeded to the rest of the protocol before leaving the machine.

Proceed directly to Section 3.2 after the thermocycling protocol finishes.

3.2 Post-Fragmentation Double-Sided SPRI Selection

Remove your SPRI beads (Ampure XP or KAPA Pure Beads) from the 4C fridge and aliquot the following amount into a 1.5 mL tube (this accounts for 10% extra volume):

ABCDEFGHIJ
# Sublibraries1234567816
SPRI Beads Needed4488132176220264308352704
Volume to Add by Number of Sublibrary Lysates (µL)

Add 30 µL of SPRI beads to the 50 µL of fragmented sublibraries and vortex briefly (2-3 sec) followed by a brief centrifugation (~2 sec).

Incubate at room temperature for 5 minutes.

Place the sublibrary tubes against a magnetic rack (for 0.2 mL tubes) on the high position (with magnet closest to the top) and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).
Critical! Do NOT discard the supernatant at this step.

With SPRI beads still against the magnetic rack, transfer 75 µL of the clear supernatant into new 200 µL PCR tubes. Discard the tubes with the SPRI beads.

Add 10 µL of SPRI beads to the 75 µL of supernatant and vortex briefly (2-3 sec) followed by a brief centrifugation (~2 sec).

Incubate at room temperature for 5 minutes.

Place the tubes against a magnetic rack on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).
Critical! This may take longer than other SPRI bead binding due to the low volume of beads. Ensure that all of the beads have bound before proceeding.

With SPRI beads still against the magnetic rack, aspirate and discard the clear supernatant with a pipette.

Without resuspending beads, add 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard the ethanol from each tube.

Without resuspending beads, add another 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard all of the ethanol from each tube (it may be necessary to remove the final few drops with a P20 pipette). Air dry the beads (only ~30 seconds due to the small amount of beads).
Critical! Do NOT over-dry the beads. Over-drying of beads can lead to substantial losses in yield. "Cracking" of the beads is a sign of over-drying.

Remove the tubes form the magnetic rack and resuspend beads from each tube in 50 µL of molecular biology grade water.

Incubate the tubes at room temperature for 5 minutes to elute fragmented DNA.

Place the tubes against a magnetic rack on the high position and wait for all the beads to bind to. the magnet (~2 min: liquid should be clear).

Transfer exactly 50 µL of the eluted DNA into new PCR tubes. Discard. the tubes with SPRI beads.

Sublibraries can be stored at this point at 4C overnight or at -20C or up to 2 weeks. If you wish to continue, proceed directly to section 3.3: Adaptor Ligation.
[STOPPING POINT].

3.3 Adaptor Ligation

Make the Adaptor Ligation Mix in the order shown below. Ensure that all the reagents are fully thawed and mixed well before using. Mis the Adaptor Ligation Mix by pipetting and store on ice.

ABCDEFGHIJ
# Sublibraries1234567816
Nuclease-free water (not supplied)19.2538.557.757796.25115.5134.75154308
Adaptor Ligation Buffer22446688110132154176352
Adaptor Ligase1122334455667788176
Adaptor DNA2.75228.251113.7516.519.252244
Total55110165220275330385440880
Volume to Add by Number of Sublibrary Lysates (µL) 

Add 50 µL of the Adaptor Ligation Mix to the 50 µL of the eluted DNA (from the end of Section 3.2).

Mix sublibraries 10x with a P200 pipette set to 80 µL. Briefly centrifuge sublibraries (~2 sec).

Put the tubes into a thermocycler with the following protocol:

Run TimeLid TemperatureSublibrary Volume
15 min30C100 µL
Sublibrary Adaptor Ligation Overview

StepTimeTemperature
115 min20C
2Hold4C
Sublibrary Adaptor Ligation

Proceed directly to the next step. Do NOT leave the tube in the thermocycler for longer than the indicated time.

3.4 Post-Ligation SPRI Clean Up

Remove your SPRI beads (Ampure XP or KAPA Pure Beads) from the 4C fridge and aliquot the following amount into a 1.5 mL tube (this accounts for 10% extra volume):

ABCDEFGHIJ
# Sublibraries1234567816
SPRI Beads Needed881762643524405286167041,408
Volume to Add by Number of Sublibrary Lysates (µL)

Add 80 µL of SPRI beads to each sublibrary (100 µL) to a total volume of 180 µL Ensure the caps are secured and then vortex briefly (2-3 sec) followed by a brief centrifugation (~2 sec).

Incubate at room temperature for 5 minutes.

Place the sublibrary tubes against a magnetic rack (for 0.2 mL tubes) on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).

With SPRI beads still against the magnetic rack, aspirate and discard the clear supernatant with a pipette.

Without resuspending beads, add 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard the ethanol from each tube.

Without resuspending beads, add another 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard all of the ethanol from each tube (it may be necessary to remove the final few drops with a P20 pipette). Air dry the beads (~3 min).
Critical! Do NOT over-dry the beads. Over-drying of beads can lead to substantial losses in yield. "Cracking" of the beads is a sign of over-drying.

Remove the tubes from the magnetic rack and resuspend beads from each tube in 23 µL of molecular biology grade water.

Incubate the tubes at room temperature for 5 minutes to elute DNA.

Place the tubes against a magnetic rack on the low position (with magnets closest to the bottom) and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).

Transfer exactly 21 µL of the eluted DNA into new PCR tubes. Discard the tubes with the SPRI beads.

3.5 Sublibrary Index PCR
If using the alternative version of Evercode Mega WT v2 (ECW02050) that includes RX100
instead of RX200, follow the protocol modifications described in Appendix D.

Multiple thermocyclers may be needed for this section depending on the amount ofcDNA added to each sublibrary during the fragmentation reaction. Refer to the step 3.5.6.

Ensure that each well of the UDI Plate - WT is properly thawed. Centrifuge the plate at 100 x g for 1 minute.
Critical! Double-check the label on the plate as specific plates are used in different protocols.

Thoroughly wipe the UDI Plate - WT seal with 70% ethanol and allow it to dry completely.

Note: Before proceeding, ensure the UDI Plate is properly orientated. The notched corner should be in the bottom left (see image on the right). Only wells from columns 1-6, and only one well/sublibrary can be used.

Add well-specific index primers from the UDI Plate - WT to your sublibraries as follows:

Using a multichannel P20 pipette set to 4 μL, pierce new, unused wells of the UDI Plate - WT. Mix 5x then transfer 4 μL of the index primer solution into your sublibraries.

Note: Ensure that no two sublibraries contain index primers from the same well. To minimize cross-contamination, use a new pipette tip for each sublibrary and avoid splashing or mixing the liquid between individual wells.

For each sublibrary, record the UDI Plate - WT's well position (e.g., 'A1', 'B1') and sublibrary index ID (see Section 4.1) for sequencing and demultiplexing purposes.

If the UDI Plate - WT has unused wells, store it at -20°C for future use.

Add 25 µL of the Index PCR Mix to each sublibrary, bringing the total volume to 50 µL. Pipette up and down 10x with the pipette set to 25 µL to ensure proper mixing, followed by brief centrifugation (~2 sec).
Critical! Different tips must be used when pipetting Index PCR Mix into each sublibrary.
Never place a tip that has entered a sublibrary back into the Index PCR Mix.

Place the sample(s) into a thermocycler and run the program below. The number of cycles (X) should be adjusted based on the amount of cDNA added to the fragmentation reaction.

Run TimeLid TemperatureSublibrary Volume
~30 min105C50 µL 
Sublibrary Index Amplification Overview

StepTimeTemperature
13 min95C
220 sec98C
320 sec67C
41 min, then go to step 2, repeat X-1 times (X cycles total)72C
55 min72C
6Hold4C
Sublibrary Index Amplification


ABCDEFG
cDNA in Fragmentation (ng)10-2425-4950-99100-299300-8991,000+
Total PCR Cycles Required (X) 1312111087
PCR Cycles based on cDNA in Fragmentation

Note: cDNA concentration was recorded in step 2.5.18, and 10 μL from each sublibrary should have been added into the fragmentation reaction (step 3.1.2).

Sublibraries can be stored at this point at 4C overnight. If you wish to continue, proceed directly to Section 3.6: Post-Amplification Double-Sided Selection.
[STOPPING POINT] 

3.6 Post-Amplification Double-Sided Size Selection

Remove your SPRI beads (Ampure XP or KAPA Pure Beads) from the 4C fridge and aliquot the following amount into a 1.5 mL tube (this accounts for 10% extra volume):

ABCDEFGHIJ
# Sublibraries1234567816
SPRI Beads Needed4488132176220264308352704
Volume to Add by Number of Sublibrary Lysates (µL)

For each sublibrary, add 30 µL of SPRI beads to the 50 µL of fragmented sublibraries (80 µL total volume). Vortex briefly (2-3 sec) followed by a brief centrifugation (~2 sec).

Incubate at room temperature for 5 minutes.

Place the tubes against a magnetic rack on the high position and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).
Critical! This may take longer than other SPRI bead binding due to the low volume of beads. Ensure that all of the beads have bound before proceeding.

With SPRI beads still against the magnetic rack, transfer 75 µL of the clear supernatant into new PCR  tubes. Discard the tubes with the SPRI beads.

Add 10 µL of SPRI beads to the 75 µL of supernatant. Vortex briefly (2-3 sec) followed by a brief centrifugation (~2 sec).

Incubate the tubes at room temperature for 5 minutes.

Place the tubes against a magnetic rack on the high position and wait for all the beads to bind to the magnet (~2 min; liquid should be clear).
Critical! This may take longer than other SPRI bead binding due to the low volume of beads. Ensure that all of the beads have bound before proceeding.

With SPRI beads still against the magnetic rack, aspirate and discard the clear supernatant with a pipette.

Without resuspending beads, add 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard the ethanol from each tube.

Without resuspending beads, add another 180 µL of 85% ethanol and wait for 1 minute.

Using a pipette, aspirate and discard the ethanol from each tube (it may be necessary to remove the final few drops with a P20 pipette). With the tube still on the rack, air dry the beads (~2 min).
Critical! Do NOT over-dry the beads. Over-drying of beads can lead to substantial losses in yield. "Cracking" of the beads is a sign of over-drying.

Remove the tubes from the magnetic rack and resuspend beads from each tube in 20 µL of molecular biology grade water.

Incubate the tubes at room temperature for 5 minutes to elute DNA.

Place the tubes against a magnetic rack on the low position (with magnets closest to the bottom) and wait for all the beads to bind to the magnet (~2 min: liquid should be clear).

Transfer the eluted DNA into new PCR tubes. Discard the tubes with the SPRI beads. The products are now ready to be quantified for sequencing.

Measure the concentration of the fragmented DNA using the Qubit dsDNA HS protocol.

Run 1 µL of the DNA on a Bioanalyzer or TapeStation. Use the concentration obtained from the Qubit to determine the appropriate dilution necessary (check manufacturer specifications, 1:10 dilution is generally appropriate). There should be a peak between 400-500 bp. See Figure 2 (next page) for the expected DNA size distribution.

Sublibraries can be stored at this point at -20C for up to 3 months. If you wish to continue, proceed directly to Section 4: Sequencing Libraries.
[STOPPING POINT]

Note: The traces above are representative of typical Bioanalyzer and TapeStation from indexed sublibraries. There should be a peak between 400-500 bp. The prominence of the trace is dependent on amount of DNA loaded into the Bioanalzyer or TapeStation. Sublibraries with minor deviations can still produce high quality data.

Bioanalyzer Note: There may be an additional peak present on the Bioanalyzer. This typically occurs if products are overamplified, but should not impact sequencing or data quality (assuming there is still a peak present at 400-500bp). Do not use this additional peak when estimating amplicon size.

Section 4: Sequencing Libraries

4.1 Illumina Run Configuration

If single indexing primers were used in Section 3, see Appendix D2. Otherwise, use the
following UDI-specific Illumina run configuration and sequence information.

Evercode sequencing libraries should be diluted and denatured according to the instruction for the relevant sequencing instrument. We strongly recommend adding 5% PhiX for optimal sequencing quality. Libraries should be sequenced with paired reads using the following read structure.

ReadCycles
Read 1130
i7 Index (Index 1)8
i5 Index (Index 2)8
Read 286

The fourth barcode that tags each sublibrary acts as a standard Illumina UDI with i7 and i5 indexes. Please refer to the following table to demultiplex Whole Transcriptome sublibraries with UDIs that were sequenced together in the same run.


Sublibrary IndexWell Positioni7 Forward Sequence (For Sample Sheet)i5 Reverse Complementary Sequencei5 Forward Sequence
UDI_WT_1 A1 CAGATCAC ATGTGAAG CTTCACAT 
UDI_WT_2 B1 ACTGATAG GTCCAACC GGTTGGAC 
UDI_WT_3 C1 GATCAGTC AGAGTCAA TTGACTCT 
UDI_WT_4 D1 CTTGTAAT AGTTGGCT AGCCAACT 
UDI_WT_5 E1 AGTCAAGA ATAAGGCG CGCCTTAT 
UDI_WT_6 F1 CCGTCCTA CCGTACAG CTGTACGG 
UDI_WT_7 G1 GTAGAGTA CATTCATG CATGAATG 
UDI_WT_8 H1 GTCCGCCT AGATACGG CCGTATCT 
UDI_WT_9 A2 GTGAAACT TACAGACT AGTCTGTA 
UDI_WT_10 B2 TCATTCCT AATGCCTG CAGGCATT 
UDI_WT_11 C2 GGTAGCAT TGCTTGCC GGCAAGCA 
UDI_WT_12 D2 ACTTGATC TTTGGGTG CACCCAAA 
UDI_WT_13 E2 ATGAGCAT GAATCTGA TCAGATTC 
UDI_WT_14 F2 GCGCTATC CGACTGGA TCCAGTCG 
UDI_WT_15 G2 TGACCAGT ACATTGGC GCCAATGT 
UDI_WT_16 H2 TATAATCA ACCACTGT ACAGTGGT 
UDI_WT_17 A3 CAAAAGTC CGGTTGTT AACAACCG 
UDI_WT_18 B3 CGATGTCA CATGAGGA TCCTCATG 
UDI_WT_19 C3 CTCAGAGT TGGAGAGT ACTCTCCA 
UDI_WT_20 D3 TAATCGAC TGACTTCG CGAAGTCA 
UDI_WT_21 E3 CATTTTCT GGAAGGAT ATCCTTCC 
UDI_WT_22 F3 CTATACTC TGTTCGAG CTCGAACA 
UDI_WT_23 G3 CACTCACA AAGGCTGA TCAGCCTT 
UDI_WT_24 H3 CTCGAACA CTCGAGTG CACTCGAG 
UDI_WT_25 A4 CTCTATCG ATCGGTGG CCACCGAT 
UDI_WT_26 B4 TCCTCATG AGGTCTTG CAAGACCT 
UDI_WT_27 C4 AACAACCG AGGAAGCG CGCTTCCT 
UDI_WT_28 D4 GCCAATGT ACATGTGT ACACATGT 
UDI_WT_29 E4 TGGTTGTT ATACAGTT AACTGTAT 
UDI_WT_30 F4 TCTGCTGT ATCGCCTT AAGGCGAT 
UDI_WT_31 G4 TTGGAGGT TTCGACGC GCGTCGAA 
UDI_WT_32 H4 TCGAGCGT TGTCGTTC GAACGACA 
UDI_WT_33 A5 TGCGATCT TCCATAGC GCTATGGA 
UDI_WT_34 B5 TTCCTGCT TAAGTGTC GACACTTA 
UDI_WT_35 C5 TTCCATTG CTGGCATA TATGCCAG 
UDI_WT_36 D5 TAACGCTG CTGAGCCA TGGCTCAG 
UDI_WT_37 E5 TTGGTATG CTCAATGA TCATTGAG 
UDI_WT_38 F5 TGAACTGG CGCATACA TGTATGCG 
UDI_WT_39 G5 TCCAGTCG CCGAAGTA TACTTCGG 
UDI_WT_40 H5 TGTATGCG CCAGTTCA TGAACTGG 
UDI_WT_41 A6 TGGCTCAG CAGCGTTA TAACGCTG 
UDI_WT_42 B6 TATGCCAG CAATGGAA TTCCATTG 
UDI_WT_43 C6 GGTTGGAC ATCCTGTA TACAGGAT 
UDI_WT_44 D6 GACACTTA AGCAGGAA TTCCTGCT 
UDI_WT_45 E6 GAACGACA ACGCTCGA TCGAGCGT 
UDI_WT_46 F6 AAGGCGAT ACAGCAGA TCTGCTGT 
UDI_WT_47 G6 ATGCTTGA ACAAGCTA TAGCTTGT 
UDI_WT_48H6AGTATCTGCATCAAGT ACTTGATG

Appendix

Appendix D: Single Indexing
If using the alternative version of Evercode Mega WT v2 (ECW02030) that includes RX100 instead of RX200, follow the protocol modifications described here.

Original SectionReplacement Section
3.5: Sublibrary Index PCR with UDIsAppendix D1: Sublibrary Index PCR (see protocol on the next page)
4.1: Illumina Run Configuration with UDIsAppendix D2: Illumina Run Configuration with Single Indexing

Appendix D1: Part List

ComponentFormatQuantityPart Number
Fragmentation Buffer1.5 mL tube1WX101
Fragmentation Enzyme1.5 mL tube1WX102
Adaptor DNA1.5 mL tube1WX103
Adaptor Ligation Buffer1.5 mL tube1WX104
Adaptor Ligase1.5 mL tube1WX105
Index PCR Mix1.5 mL tube1WX106
Universal Index Primer1.5 mL tube1WX107
Sublibrary Index Primer 11.5 mL tube1WX108
Sublibrary Index Primer 21.5 mL tube1WX109
Sublibrary Index Primer 31.5 mL tube1WX110
Sublibrary Index Primer 41.5 mL tube1WX111
Sublibrary Index Primer 51.5 mL tube1WX112
Sublibrary Index Primer 61.5 mL tube1WX113
Sublibrary Index Primer 71.5 mL tube1WX114
Sublibrary Index Primer 81.5 mL tube1WX115
Fragmentation (-20°C) RX100

Appendix D2: Sublibrary Single Index PCR
If using unique dual indexes (UDIs) instead of sublibrary single index primers for
indexing, see Section 3.5. Otherwise, replace the entirety of Section 3.5 with the
following steps.

Multiple thermocyclers may be needed for this section depending on the amount of cDNA added to each sublibrary during the fragmentation reaction. Refer to step next page to determine how many thermocyclers are needed.

Using a new 1.5 mL tube, combine the Universal Index Primer and Index Primer Mix to make the Sublibrary Amplification Mix. Mix well by pipetting and store on ice.


ABCDEFGHIJ
# Sublibraries1234567816
Index PCR Mix27.55582.5110137.5165192.5220440
Universal Index Primer2.24.46.68.81113.215.417.635.2
Total29.759.489.1118.8148.5178.2207.9237.6475.2

Add 2 μL of different index primers to each sublibrary ensuring that no two sublibraries contain the same sublibrary index primer. Make sure to record which sublibrary contains which index primer.

Add 27 μL Sublibrary Amplification Mix to the 23 μL sublibrary from the previous step. Pipette up and down 10x with the pipette set to 27 μL to ensure proper mixing, followed by brief centrifugation (~2 sec).

Place the samples(s) into a thermocycler and run the program below. The number of cycles (X) should be adjusted based on the amount of cDNA added to the fragmentation reaction.


Run TimeLid TemperatureSublibrary Volume
~30 min105C50 μL
Sublibrary Index Amplification Overview


StepTimeTemperature
13 min95°C
220 sec98°C
320 sec67°C
41 min, then go to step 2, repeat X-1 times (X cycles total)72°C
55 min72°C
6Hold4°C
Sublibrary Index Amplification


ABCDEFG
cDNA in Fragmentation (ng)10-2425-4950-99100-299300-9991,000+
Total PCR Cycles Required (X)1312111087
PCR Cycles based on cDNA in Fragmentation

Note: cDNA concentration was recorded in step 2.5.18, and 10 μL from each sublibrary should have been added into the fragmentation reaction (step 3.1.2).

Sublibraries can be stored at this point at 4°C overnight. If you wish to continue, proceed directly to Section 3.6: Post-Amplification Double-Sided Size Selection.
[STOPPING POINT]

Appendix D3: Illumina Run Configuration
If unique dual indexes (UDIs) instead of sublibrary index primers were used for indexing, see Section 4.1. Otherwise, use the following single index Illumina run configuration and sequence information.

Evercode sequencing libraries should be diluted and denatured according to the instruction for the relevant sequencing instrument. We strongly recommended adding 5% PhiX for optimal sequencing quality. Libraries should be sequenced with paired reads using the following read structure.

ReadCycles
Read 1140
i7 Index (Index 1)6
Read 286
i5 Index (Index 2)0

The 4th barcode that tags each sublibrary acts as a standard Illumina index. Please refer to the following table to demultiplex sublibraries that have been sequenced together in the same run.


Sublibrary IndexForward Sequence
1CAGATC
2ACTTGA
3GATCAG
4TAGCTT
5ATGTCA
6CTTGTA
7AGTCAA
8AGTTCC
9GAGTGG
10CCGTCC
11GTAGAG
12GTCCGC
13GTGAAA
14GTGGCC
15GTTTCG
16CGTACG

Protocol references

Please see the attachment for the original Parse Biosciences protocol with more information, including estimation of time required for each section.

Item	Supplier	Part Number	Notes
Centrifuge with Swinging Bucket Rotors	Various Suppliers	Varies	Capable of reaching 4°C. Compatible with 15 mL centrifuge tubes and 96-well plates.
Microcentrifuge	Various Suppliers	Varies	Compatible with 1.5 mL and 0.2 mL tubes.
Heat Block	Various Suppliers	Varies	Or equivalent water bath, bead bath, or thermomixer capable of holding temperature at 37°C.
Hemocytometer	Sigma-Aldrich	Z359629	Or other cell counting device. We recommend validating alternatives relative to a hemocytometer.
Single Channel Pipettes: P20, P200, P1000 12-channel: P20, P200	Various Suppliers	Varies	Or 8-channel pipettes can be substituted for 12-channel.
T100 Thermal Cycler	Bio-Rad Laboratories	1861096	Or an equivalent thermocycler compatible with unskirted 96-well plates and a heated lid capable of 50-105°C.
Parse Biosciences Magnetic Rack	Parse Biosciences	SB1004	Magnetic strength is critical. If 3rd party magnetic racks are used, the number of transcripts and genes detected per cell will be compromised. This magnetic rack is compatible with most 0.2 mL PCR tubes.
6-Tube Magnetic Separation Rack	New England Biolabs	S1506S	Or an equivalent magnetic rack for 1.5 mL tubes.
Vortex-Genie 2	Scientific Industries	SI-0236	Compatible with a vortex adapter for 96-well plates. Or a shaker set to 800-1000 RPM. Part number varies with different lab voltage and frequency requirements.
6-inch Platform	Scientific Industries	146-6005-00	Or an equivalent vortex adapter for 96-well plates.
Microplate Foam Insert	Scientific Industries	504-0235-00	Or an equivalent vortex adapter for 96-well plates.
Qubit Flex Fluorometer	Thermo Fisher Scientific	Q33327	Or an equivalent fluorometer.
2100 Bioanalyzer	Agilent	G2939BA	Choose one.
4200 TapeStation System	Agilent	G2991BA	Choose one.

Item	Location	Quantity	Format	After taking out
Adhesive 96-well plate cover	Accessories (Room Temp)	1	With white protector	Keep at room temperature
Spin Additive	4C Reagents (4C)	1	1.5 mL tube	Keep at room temperature.
Dilution Buffer	Barcoding Reagents (-20C)	2	2 mL tube	Thaw, then place on ice
Resuspension Buffer	Barcoding Reagents (-20C)	1	5 mL tube	Thaw, then place on ice
Ligation Mix	Barcoding Reagents (-20C)	1	5 mL tube	Thaw, then place on ice
Round 2 Ligation Enzyme	Barcoding Reagents (-20C)	1	1.5 mL tube	Thaw, then place on ice
Round 1 Plate	Barcoding Reagents (-20C)	1	96-well plate	Thaw, then place on ice
Round 2 Plate	Barcoding Reagents (-20C)	1	96-well plate	Thaw, then place on ice

Step	Time	Temperature
1	10 min	50C
2	12 sec	8C
3	45 sec	15C
4	45 sec	20C
5	30 sec	30C
6	2 min	42C
7	3 min, then go to step 2 and repeat 2 times 3 cycles total)	50C
8	5 min	50C
9	Hold	4C

A	B	C	D	E	F	G	H	I	J
# Sublibrary Lysates	1	2	3	4	5	6	7	8	16
Binder Beads (µL)	44	88	132	176	220	264	308	352	704

A	B	C	D	E	F	G	H	I	J
# Sublibrary Lysates	1	2	3	4	5	6	7	8	16
Bead Wash Buffer (µL)	50	100	150	200	250	300	350	400	800

A	B	C	D	E	F	G	H	I	J
# Sublibrary Lysates	1	2	3	4	5	6	7	8	16
Bind Buffer A (µL)	55	110	165	220	275	330	385	440	880

A	B	C	D	E	F	G	H	I	J
# Sublibrary Lysates	1	2	3	4	5	6	7	8	16
TS Buffer	101.75	203.5	305.25	407	508.75	610.5	712.25	814	1,628
TS Primer Mix	2.75	5.5	8.25	11	13.75	16.5	19.25	22	44
TS Enzyme	5.5	11	16.5	22	27.5	33	38.5	44	88
Total	110	220	330	440	550	660	770	880	1,760

# Sublibraries	1	2	3	4	5	6	7	8	16
Amplification Master Buffer	60.5	121	181.5	242	302.5	363	423.5	484	968
Amplification Primer Mix	60.5	121	181.5	242	302.5	363	423.5	484	968
Total	121	242	363	484	605	726	847	968	1,936

Cell Type	Number of Cells/Nuclei in Individual Sublibrary	Number of 1st Cycles (PCR Steps 2-4)	Number of 2nd cycles (X) (PCR Steps 5-7)
Mammalian Cell Lines	200-1,000	5	12
	1,000-2,000	5	10
	2,000-6,000	5	8
	6,000-12,500	5	6
	12,500-25,000	5	5
	25,000-62,500	5	4
Nuclei	200-1,000	5	13
	1,000-2,000	5	11
	2,000-6,000	5	9
	6,000-12,500	5	7
	12,500-25,000	5	6
	25,000-62,500	5	5
Immune cells (PBMCs)	200-1,000	5	14
	1,000-2,000	5	12
	2,000-6,000	5	10
	6,000-12,500	5	8
	12,500-25,000	5	7
	25,000-62,500	5	6

	Run Time	Lid Temperature	Sublibrary Volume
	50-70 min	105C	100 µL

A	B	C	D	E	F	G	H	I	J
# Sublibraries	1	2	3	4	5	6	7	8	16
SPRI Beads Needed	79	158	238	317	396	475	554	634	1,266

A	B	C	D	E	F	G	H	I	J
# Sublibraries	1	2	3	4	5	6	7	8	16
Fragmentation Buffer	5.5	11	16.5	22	27.5	33	38.5	44	88
Fragmentation Enzyme	11	22	33	44	55	66	77	88	176
Total	16.5	33	49.5	66	82.5	99	115.5	132	264

A	B	C	D	E	F	G	H	I	J
# Sublibraries	1	2	3	4	5	6	7	8	16
Nuclease-free water (not supplied)	19.25	38.5	57.75	77	96.25	115.5	134.75	154	308
Adaptor Ligation Buffer	22	44	66	88	110	132	154	176	352
Adaptor Ligase	11	22	33	44	55	66	77	88	176
Adaptor DNA	2.75	22	8.25	11	13.75	16.5	19.25	22	44
Total	55	110	165	220	275	330	385	440	880

A	B	C	D	E	F	G	H	I	J
# Sublibraries	1	2	3	4	5	6	7	8	16
SPRI Beads Needed	88	176	264	352	440	528	616	704	1,408

A	B	C	D	E	F	G
cDNA in Fragmentation (ng)	10-24	25-49	50-99	100-299	300-899	1,000+
Total PCR Cycles Required (X)	13	12	11	10	8	7

	Read	Cycles
	Read 1	130
	i7 Index (Index 1)	8
	i5 Index (Index 2)	8
	Read 2	86

Sublibrary Index	Well Position	i7 Forward Sequence (For Sample Sheet)	i5 Reverse Complementary Sequence	i5 Forward Sequence
UDI_WT_1	A1	CAGATCAC	ATGTGAAG	CTTCACAT
UDI_WT_2	B1	ACTGATAG	GTCCAACC	GGTTGGAC
UDI_WT_3	C1	GATCAGTC	AGAGTCAA	TTGACTCT
UDI_WT_4	D1	CTTGTAAT	AGTTGGCT	AGCCAACT
UDI_WT_5	E1	AGTCAAGA	ATAAGGCG	CGCCTTAT
UDI_WT_6	F1	CCGTCCTA	CCGTACAG	CTGTACGG
UDI_WT_7	G1	GTAGAGTA	CATTCATG	CATGAATG
UDI_WT_8	H1	GTCCGCCT	AGATACGG	CCGTATCT
UDI_WT_9	A2	GTGAAACT	TACAGACT	AGTCTGTA
UDI_WT_10	B2	TCATTCCT	AATGCCTG	CAGGCATT
UDI_WT_11	C2	GGTAGCAT	TGCTTGCC	GGCAAGCA
UDI_WT_12	D2	ACTTGATC	TTTGGGTG	CACCCAAA
UDI_WT_13	E2	ATGAGCAT	GAATCTGA	TCAGATTC
UDI_WT_14	F2	GCGCTATC	CGACTGGA	TCCAGTCG
UDI_WT_15	G2	TGACCAGT	ACATTGGC	GCCAATGT
UDI_WT_16	H2	TATAATCA	ACCACTGT	ACAGTGGT
UDI_WT_17	A3	CAAAAGTC	CGGTTGTT	AACAACCG
UDI_WT_18	B3	CGATGTCA	CATGAGGA	TCCTCATG
UDI_WT_19	C3	CTCAGAGT	TGGAGAGT	ACTCTCCA
UDI_WT_20	D3	TAATCGAC	TGACTTCG	CGAAGTCA
UDI_WT_21	E3	CATTTTCT	GGAAGGAT	ATCCTTCC
UDI_WT_22	F3	CTATACTC	TGTTCGAG	CTCGAACA
UDI_WT_23	G3	CACTCACA	AAGGCTGA	TCAGCCTT
UDI_WT_24	H3	CTCGAACA	CTCGAGTG	CACTCGAG
UDI_WT_25	A4	CTCTATCG	ATCGGTGG	CCACCGAT
UDI_WT_26	B4	TCCTCATG	AGGTCTTG	CAAGACCT
UDI_WT_27	C4	AACAACCG	AGGAAGCG	CGCTTCCT
UDI_WT_28	D4	GCCAATGT	ACATGTGT	ACACATGT
UDI_WT_29	E4	TGGTTGTT	ATACAGTT	AACTGTAT
UDI_WT_30	F4	TCTGCTGT	ATCGCCTT	AAGGCGAT
UDI_WT_31	G4	TTGGAGGT	TTCGACGC	GCGTCGAA
UDI_WT_32	H4	TCGAGCGT	TGTCGTTC	GAACGACA
UDI_WT_33	A5	TGCGATCT	TCCATAGC	GCTATGGA
UDI_WT_34	B5	TTCCTGCT	TAAGTGTC	GACACTTA
UDI_WT_35	C5	TTCCATTG	CTGGCATA	TATGCCAG
UDI_WT_36	D5	TAACGCTG	CTGAGCCA	TGGCTCAG
UDI_WT_37	E5	TTGGTATG	CTCAATGA	TCATTGAG
UDI_WT_38	F5	TGAACTGG	CGCATACA	TGTATGCG
UDI_WT_39	G5	TCCAGTCG	CCGAAGTA	TACTTCGG
UDI_WT_40	H5	TGTATGCG	CCAGTTCA	TGAACTGG
UDI_WT_41	A6	TGGCTCAG	CAGCGTTA	TAACGCTG
UDI_WT_42	B6	TATGCCAG	CAATGGAA	TTCCATTG
UDI_WT_43	C6	GGTTGGAC	ATCCTGTA	TACAGGAT
UDI_WT_44	D6	GACACTTA	AGCAGGAA	TTCCTGCT
UDI_WT_45	E6	GAACGACA	ACGCTCGA	TCGAGCGT
UDI_WT_46	F6	AAGGCGAT	ACAGCAGA	TCTGCTGT
UDI_WT_47	G6	ATGCTTGA	ACAAGCTA	TAGCTTGT
UDI_WT_48	H6	AGTATCTG	CATCAAGT	ACTTGATG

	Original Section	Replacement Section
	3.5: Sublibrary Index PCR with UDIs	Appendix D1: Sublibrary Index PCR (see protocol on the next page)
	4.1: Illumina Run Configuration with UDIs	Appendix D2: Illumina Run Configuration with Single Indexing

Component	Format	Quantity	Part Number
Fragmentation Buffer	1.5 mL tube	1	WX101
Fragmentation Enzyme	1.5 mL tube	1	WX102
Adaptor DNA	1.5 mL tube	1	WX103
Adaptor Ligation Buffer	1.5 mL tube	1	WX104
Adaptor Ligase	1.5 mL tube	1	WX105
Index PCR Mix	1.5 mL tube	1	WX106
Universal Index Primer	1.5 mL tube	1	WX107
Sublibrary Index Primer 1	1.5 mL tube	1	WX108
Sublibrary Index Primer 2	1.5 mL tube	1	WX109
Sublibrary Index Primer 3	1.5 mL tube	1	WX110
Sublibrary Index Primer 4	1.5 mL tube	1	WX111
Sublibrary Index Primer 5	1.5 mL tube	1	WX112
Sublibrary Index Primer 6	1.5 mL tube	1	WX113
Sublibrary Index Primer 7	1.5 mL tube	1	WX114
Sublibrary Index Primer 8	1.5 mL tube	1	WX115

	Sublibrary Index	Forward Sequence
	1	CAGATC
	2	ACTTGA
	3	GATCAG
	4	TAGCTT
	5	ATGTCA
	6	CTTGTA
	7	AGTCAA
	8	AGTTCC
	9	GAGTGG
	10	CCGTCC
	11	GTAGAG
	12	GTCCGC
	13	GTGAAA
	14	GTGGCC
	15	GTTTCG
	16	CGTACG

Public workspaceEvercode WT Mega v2.2.1

Evercode WT Mega v2.2.1