Jun 25, 2024

Public workspaceAmplicon Sequencing for Genotyping S. Typhi V.3

DOI
dx.doi.org/10.17504/protocols.io.36wgq31dylk5/v3
  • 1Imperial College London;
  • 2London School of Hygiene and Tropical Medicine
  • Jaspreet Mahindroo: *Equal contribution;
  • Anton Spadar: *Equal contribution
  • Kathryn Holt: #Equal contribution
  • Nick Grassly: #Equal contribution
Jaspreet Mahindroo
Open access
DOI: dx.doi.org/10.17504/protocols.io.36wgq31dylk5/v3
Protocol CitationJaspreet Mahindroo, Anton Spadar, Catherine Troman, Zoe Dyson, Kathryn Holt, Nick Grassly 2024. Amplicon Sequencing for Genotyping S. Typhi. protocols.io https://dx.doi.org/10.17504/protocols.io.36wgq31dylk5/v3Version created by Jaspreet Mahindroo
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: January 04, 2024
Last Modified: June 25, 2024
Protocol Integer ID: 101674
Keywords: Salmonella, Typhi, Paratyphi, wastewater, environmental surveillance, nanopore, AMR
Funders Acknowledgement:
Bill and Melinda Gates Foundation
Abstract
The following protocol is for amplifying and sequencing amplicons targeting Salmonella Typhi. It is primarily for use with samples that are already suspected to be positive for S. Typhi and has been designed for use with DNA extracted from environmental surveillance samples.

The resulting sequences can be analysed and used for genotyping (given that the genotype is targeted by the primer panel) and determining antimicrobial resistance. The genotypes targeted in the panel in this protocol are listed but primers can be designed for other S. typhi genotypes of interest.

The library preparation steps of this protocol are adapted from the Oxford nanopore protocol "Ligation Sequencing Amplicons - Native Barcoding Kit 24 V14 (SQK-NBD114.24)" which is available on the Nanopore community.
Materials
Consumables
ReagentNEBNext Ultra II End Repair/dA-Tailing Module - 96 rxnsNew England BiolabsCatalog #E7546L ReagentBlunt/TA Ligase Master Mix - 250 rxnsNew England BiolabsCatalog #M0367L ReagentAgencourt AMPure XPBeckman CoulterCatalog #A63880 ReagentUltrapure BSAAmbionCatalog #AM2616 ReagentLongAmp Taq 2X Master Mix - 100 rxnsNew England BiolabsCatalog #M0287S or ReagentLongAmp Taq 2X Master Mix - 500 rxnsNew England BiolabsCatalog #M0287L
ReagentNanopore Flow Cell R10.4.1Oxford Nanopore TechnologiesCatalog #FLO-MIN114 ReagentNative barcoding kit (96)Oxford Nanopore TechnologiesCatalog #SQK-NBD114.96 orReagentONT Native barcoding sequencing kit v14 (24)Oxford Nanopore TechnologiesCatalog #SQk-NBD114.24 Reagent80% Ethanol Contributed by users
ReagentNuclease-Free Water Contributed by users
ReagentQubit dsDNA Broad Range assay kit (500 assays)Invitrogen - Thermo FisherCatalog #Q32853
ReagentQubit™ Assay TubesInvitrogen - Thermo FisherCatalog #Q32856
ReagentUltraPure™ BSA (50 mg/mL)Thermo Fisher ScientificCatalog # AM2616 ReagentNEBNext Quick Ligation Module - 20 rxnsNew England BiolabsCatalog #E6056S or ReagentNEBNext Quick Ligation Module - 100 rxnsNew England BiolabsCatalog #E6056L
ReagentONT Flow Cell Wash KitOxford Nanopore TechnologiesCatalog #EXP-WSH004 or EXP-WSH004-XL (48 washes)

Sterile low retention filter tips- for P1000, P200 and P10 pipettes.
200ul strip tubes/96 well plates
1.5 ml microcentrifuge tubes
Primers - high purity



Equipment
  • Qubit Fluorometer- Q33238 (Invitrogen)- to quantify DNA and library
  • Benchtop vortex - for mixing reagents
  • Minifuge - for spinning down reagents
  • Hula mixer/rotator- for mixing during the bead clean-up step.
  • Plate centrifuge, if you will be using PCR plates instead of strips
  • Thermocycler- for PCR and end-prep DNA preparation
  • P10 to P1000- single channel pipettes
  • P10 and P200- multichannel pipettes
  • Laboratory timer
  • Benchtop minicooler/ ice bucket
  • Magnetic stand for 96 well plate
  • Magnetic rack for 1.5 ml tube
  • High powered GPU laptop, requirements listed on the ONT website at: https://community.nanoporetech.com/requirements_documents/minion-it-reqs.pdf

















Protocol materials
ReagentLongAmp Taq 2X Master Mix - 100 rxnsNew England BiolabsCatalog #M0287S
Materials
ReagentNEBNext Quick Ligation Module - 20 rxnsNew England BiolabsCatalog #E6056S
Materials
ReagentNEBNext Quick Ligation Module - 100 rxnsNew England BiolabsCatalog #E6056L
Materials
ReagentQubit assay tubesThermo Fisher ScientificCatalog #Q32856
Step 11
ReagentONT Flow Cell Wash KitOxford Nanopore TechnologiesCatalog #EXP-WSH004
Materials
ReagentNuclease-Free Water
Materials
ReagentQubit™ Assay TubesInvitrogen - Thermo FisherCatalog #Q32856
Materials
ReagentNative barcoding kit (96)Oxford Nanopore TechnologiesCatalog #SQK-NBD114.96
Materials
ReagentNEBNext Ultra II End Repair/dA-Tailing Module - 96 rxnsNew England BiolabsCatalog #E7546L
Materials
ReagentUltrapure BSAAmbionCatalog #AM2616
Materials
ReagentONT Native barcoding sequencing kit v14 (24)Oxford Nanopore TechnologiesCatalog #SQk-NBD114.24
Materials
ReagentAgencourt AMPure XPBeckman CoulterCatalog #A63880
Materials, Step 10.1
ReagentQubit™ dsDNA BR Assay KitThermo Fisher ScientificCatalog #Q32853
Step 11
ReagentUltraPure™ BSA (50 mg/mL)Thermo Fisher ScientificCatalog # AM2616
Materials
ReagentBlunt/TA Ligase Master Mix - 250 rxnsNew England BiolabsCatalog #M0367L
Materials
Reagent80% Ethanol
Materials
ReagentNanopore Flow Cell R10.4.1Oxford Nanopore TechnologiesCatalog #FLO-MIN114
Materials
ReagentQubit dsDNA Broad Range assay kit (500 assays)Invitrogen - Thermo FisherCatalog #Q32853
Materials
ReagentLongAmp Taq 2X Master Mix - 500 rxnsNew England BiolabsCatalog #M0287L
Materials
Before start
Nanopore sequencing requires a high performance laptop with a GPU. The requirements for computing power can be found on the ONT website at the following link: https://community.nanoporetech.com/requirements_documents/minion-it-reqs.pdf
In summary, a n 8GB GPU minimum, 16GB RAM, 1TB storage, and CPU Intel i7, i9, Xeon, or better, with at least 4 cores/8 threads.
Primer Panel
Primer Panel
The following primers have been designed for identifying some S. Typhi genotypes and markers for AMR both in the chromosome and in a plasmid. These can be ordered lyophilised from your preferred oligo supplier.
Genotyping Panel_version1

ABCDE
Forward primerForward sequenceReverse primerReverse sequenceProduct size
1_3_4.3.1_FACGATGGTACTGAACAACCCT1_3_4.3.1_RTACGCTGTTCAGCCCGATATC1703
2.2.2_2_FAGCACAGTTCATCCGAGTGAT2.2.2_2_RAGCATCAGACTCTGCGACAC2,126
2.5_4.3.1.2.1_3.3_FCGGTTCGTTGTCCATTTCGG2.5_4.3.1.2.1_3.3_RGGCGGCTTTCTTCAGTTTTTCA1,155
tviD_842_FTGCAAGCTGCTTAGTGATCGAtviD_842_RTGAGTCCGGTAAAACGAGCTC842
4.3.1.1_FTCTGGCCTGATACCTGGATGT4.3.1.1_RCGATCGGATATCCAGCACCA702
gyrA_FTGACGCCTTCTTCGTACTCACgyrA_RCTGAAGCTGATCGCCGATAAAC2099
4.3.1.2.1.1_4_FGTCAGGCCTGGTTTGACAATC4.3.1.2.1.1_4_RCCTGTGAACTAACCCCTGCA1626
2.3.2_FGACGATAAACCGCTTCCGTCA2.3.2_RAGCCGGGTACAGTAGTCCAA711
acrB_v2_FACACAGGAAGACGACGATTAGCacrB_v2_RAAAGTGCTGGATGAGGTCACG897
parC_v7_FTGGCACAATCACTAAACGCGparC_v7_RGCGACGTACTGGGTAAGTAT701
3.3.1_1182_FTCCGTTTTGCGAAATCGTTCC3.3.1_1182_RGGGCGCTCTGGTAGACATAC1182
4.3.1.2_3694947_v3_FTGTTTCTGGCTTCGCTGCTGG4.3.1.2_3694947_v3_RTGATGTCTTTCCGGCAGTCC734
4.3.1.1.P1_FTTAGGTCGACCAGCGCAAAT4.3.1.1.P1_RCCCCGTTAACCCAGGAGAAA734
3.1.1_v5_FTGTATGGCTTCTGGTTGGCTT3.1.1_v5_RAAACAACACGCCATTCACGG1155
2.3.1_v12_FACTGCGCCCATTATTGATCTC2.3.1_v12_RGTAGTGTCCCTACCCCCTGT859

MDR Panel_version1


ABCDE
Forward primerForward sequenceReverse primerReverse sequenceProduct size
C19241A_FATTACTGGGCGAGCTGGATTCC19241A_RGACAGTCTTCTTCTGGGATCTCG440
chr_mdr_cyaACCATTGAGCGGAACAAGGTTTmdr_RCCATATCACCAGCTCACCGT1,271
chr_mdr_yidAGAGGTGGGTTCTCACTTCCAC1,290
plasmid_2.2_none_LT904892.1_FTCCCTACCATGGATTCCCACT1,276
plasmid_4.3.1.3_PST6_CP029957.1_FAGCACTGCTGGCTCGATTATAT1,160
plasmid_4.3.1.1_PST6_CP029645.1_FCCGTGAGCTCAGGAAAAAGC1,280
plasmid_4.3.1.3_PST6_CP029924.1_FCATGCTACTCGTGCTGACCAT1,341
plasmid_4.3.1.1_PST6_LT904879.1_FTCGCCAGTTTCTCAAACAACCT1,328
plasmid_3.2.1_non-PST6_AL513383.1_FCAATGGATTATGCTCTCCCTCGA1,301
plasmid_4.3.1.3_PST6_CP029879.1GGGTCACTTCGGGCTGAAAA1,309

PCR amplification
PCR amplification
Primer reconstitution
The primers are received in lyophilized form and need to be reconstituted before use. Prepare a stock solution of 100μM primers.
To reconstitute the lyophilised primers, use the nmole information on the sheet received with the primers.
Convert the nmol to μmol and then divide by the 100 μmol/L.
For example: for a primer with 24 nmoles, to make 100μM stock solution:

24 nmol / 1000 = 0.024 μmol
0.024μmol / 100μmol/L =0.00024 L
0.00024 L x 1000 = 0.24 ml or 240 µl
So add 240 µl to make a 100 μM solution.

In simple words, multiply the nmol value by 10. Example: for 24 nmol x10 = 240 µl to make a 100 μM solution.
Add the required volume of nuclease free water to the primer vial, pulse vortex and spin down. This is the primer stock with 100µM concentration. Store at -20°C for long-term storage.
Primer Dilution
Using the 100µM stock, prepare a 10uM working stock of each primer
In a fresh tube add 5 µl of 100µM primer stock to 45 µl nuclease-free water to give 50 µl of 10µM primer.
Store at 4°C for frequent usage or -20°C for long-term storage.
Primer pooling
The PCR is currently performed with two reactions per sample with a different primer panel used in each reaction. Using the 10µM working stocks prepare the following primer panels:
Genotyping panel
Pool the primers listed in 1.1 into a single tube as follows:
Add 10 μl of each forward and reverse primer to a single tube, pulse vortex and spin down and use this pool for PCR reactions. Scale up the volume as required.
MDR panel
MDR panel has a common reverse primer for nine targets. To set the multiplex reaction pool the primers in 1.2 as follows:
Add 10 µl of each forward primer + 90 µl of common reverse primer + 10 µl of reverse primer for C19241A into a single tube. Pulse vortex, spin down and use this pool for PCR reactions. Scale up the volume as required.
PCR reaction
Thaw the primer panels and LongAmp taq 2x Mastermix on ice.

Pulse vortex and spin down the primer panels, then return to ice.
Do not vortex the LongAmp taq, mix by flicking or pipetting and spinning down before placing back on ice.

Prepare the master mix as follows for the number of samples, plus two controls, and one more extra reaction to account for the pipetting error.
AB
ReagentVolume for 1 reaction
2x LongAmp Taq12.5 µl
Primer pool2 µl
Water5.5 µl
Total20 µl


Dispense 20 µl of master mix per reaction into 0.2 ml PCR tubes.

Add 5 µl of sample DNA.

Mix well by pipetting and spin down.
PCR Controls
Positive control: Salmonella Typhi strain H58 DNA (or use appropriate control strain that is available)

Additionally, synthetic gene fragments such as G blocks (IDT) can be used as positive control. Use tviD amplicon sequence and the MDR amplicon sequences as positive control for genotyping and MDR panels respectively. Refer to the attached document for these sequences.
Download Positive control amplicon sequence.docxPositive control amplicon sequence.docx16KB

G blocks are received lyophilized and need to be resuspended with Tris-EDTA pH 8.0 or nuclease free water (as recommended by the supplier). Centrifuge the tube briefly (~30 seconds) to bring down any contents of the tube sticking to the wall or cap.


For control strain DNA or the G blocks, a concentration of at least 10 ng/μL is recommended for a stock dilution. For example if the stock has 1000ng then resuspend in 100 µl of diluent to get 10 ng/μl concentration.
A working solution of 1 ng/μL is used in PCR reactions. To make working solution dilute 10 µl of the 10ng/µl stock solution in 90 µl nuclease free water. Quantify using Qubit.
Make 6 µl aliquots of the working solution to avoid contamination and repeated free-thaw cycles then use 5 µl for each positive control reaction.

Negative control: 5µl nuclease-free water for a no template control
Thermocycler conditions/ program
Set up the thermocycler conditions as follows:
ABCD
StepTemperatureTimeCycles
I94°C30 seconds1 cycle
II94°C30 seconds40 cycles
58°C30 seconds
65°C2 minutes 40 seconds
III65°C10 minutes1 cycle
IV10°C

Store the amplicons at 4ºC for a short duration or -20°C for long-term storage if not proceeding with library preparation immediately.
Gel electrophoresis (Optional)
You may check the amplification of PCR targets by running the PCR products on a 1% agarose gel or on a TapeStation using a D5000 DNA screen tape.
PCR clean-up and quantification
PCR clean-up and quantification
PCR clean-up
Prepare the ReagentAgencourt AMPure XPBeckman CoulterCatalog #A63880 for use; resuspend by vortexing.

Add the required volume of resuspended AMPure XP beads to the reaction and mix by pipetting or flicking the tube.
The volume is calculated as the 0.8x PCR reaction volume.
For example: For 25 ul of PCR reaction = 0.8 x 25 = 20 ul of beads   
Incubate on a rotator for 5 minutes at room temperature. If you do not have a rotator, you can flick the tube every 2 minutes to ensure the beads are still in suspension.
Spin down the sample and pellet on a magnet. Keep the tube on the magnet, and pipette off the supernatant.
Keep on the magnet, wash beads with 100 µL of freshly prepared 80% ethanol without disturbing the pellet
Remove the 80% ethanol using a pipette and discard.
Repeat steps 10.5 & 10.6.
Spin down briefly (~5 seconds) and place the tube back on the magnet.
Pipette off any residual 80% ethanol using a small tip (10-20µl).
Allow to air dry for 1-2 minutes.
Remove the tube from the magnetic rack and resuspend the pellet in 20µl of nuclease free water, mix by gently flicking or pipetting.
Incubate for 2 minutes at room temperature.
Pellet beads on magnet until the eluate is clear and colourless.
Still on the magnet, remove 20µl eluate and store it in a clean tube.

Avoid disturbing the pelleted beads. If you find the beads keep getting drawn up the pipette tip, try removing 18µl instead.
Quantification
The PCR products are quantified using the ReagentQubit™ dsDNA BR Assay KitThermo Fisher ScientificCatalog #Q32853 ReagentQubit assay tubesThermo Fisher ScientificCatalog #Q32856
Equipment
Qubit 4
NAME
Fluorometer
TYPE
Invitrogen
BRAND
Q33238
SKU

Standards
The Qubit dsDNA kit requires 2 standards for calibration-- Standard #1 and Standard #2.
Label the tube lids. Do not label the side of the tube as this could interfere with the sample reading
Prepare Qubit working solution for the required number of samples and standards as follows

Each sample:
Qubit dsDNA BR Reagent 1 µL
Qubit dsDNA BR Buffer 199 µL
Aliquot Qubit working solution to each tube: standard tubes require 190µL of Qubit working solution sample tubes require 198µL of Qubit working solution
Add 10µL of the standard to the appropriate tube.
Add 2µL of each cleaned PCR product to the appropriate tube.

The final volume in each tube must be 200µL once the sample/standard has been added.
Mix each tube vigorously by vortexing for 3–5 seconds.
Allow all tubes to incubate at room temperature for 2 minutes, then proceed to “Read standards and samples.
On the Home screen of the Qubit Fluorometer, press DNA, then select 1X dsDNA broad range as the assay type. The Read standards screen is displayed. Press Read Standards to proceed.
Insert the tube containing Standard #1 into the sample chamber, close the lid, then press Read standard. When the reading is complete (~3 seconds), remove Standard #1.
Insert the tube containing Standard #2 into the sample chamber, close the lid, then press Read standard. When the reading is complete, remove Standard #2.
The instrument displays the results on the Read standard screen. Then press run samples.
On the assay screen, select the sample volume and units:
Press the + or – buttons on the wheel, or anywhere on the wheel itself, to select the sample volume added to the assay tube (2µL).
From the unit dropdown menu, select the units for the output sample concentration (in this case choose ng/µL).
Insert a sample tube into the sample chamber, close the lid, then press Read tube. When the reading is complete (~3 seconds), remove the sample tube and carefully record the calculated sample concentration.
The top value (in large font) is the calculated concentration of the original sample.

The bottom value is the dilution concentration. For information on interpreting the sample results, refer to the Qubit Fluorometer User Guide.
Repeat step 9.14 until all samples have been read.
All negative controls should ideally be ‘too low’ to read on the Qubit machine, but MUST be < 1ng per ul. If your negative controls >1ng per ul, considerable contamination has occurred and you must redo previous steps.
200fmol calculation
The nanopore protocol recommends using 200fmol of your sample DNA in the first step of library preparation (End-preparation)
Based on the DNA concentration obtained from Qubit, transfer 200fmol of DNA into a fresh tube and add nuclease free water to total 12.5ul.

You can use the spreadsheet attached to help calculate the volume required of each sample. We have based the ng required of each sample using the average amplicon length for the primer panel to calculate the ng required for 200fmol product (1148ng for the genotyping panel and 1200ng for the MDR panel)

Download 200fmol calculation.xlsx200fmol calculation.xlsx10KB

Use this 12.5ul for the End-preparation reaction.
Preparation for sequencing using ONT Native barcodes
Preparation for sequencing using ONT Native barcodes
End-preparation
From the ONT kit (SQK-NBD114.24 or .96) thaw AMPure XP beads (AXP), mix by vortexing, then keep at room temperature.

Thaw the NEBnext Ultra II End Repair reagents on ice, flick or invert the tubes to mix, then spin down.
To the 12.5μl of prepared 200fmol amplicon DNA, add the following:

AB
ReagentVolume (μl)
Ultra II End-prep Reaction Buffer1.75
Ultra II End-prep Enzyme Mix0.75
Total2.5
You may make up a master mix of these reagents for the number of samples (+1 for pipetting error) and aliquot 2.5μl for each sample.
Gently mix by pipetting or flicking the tube then spin down (5 seconds).
Incubate in a thermal cycler at 20ºC for 5 minutes then 65ºC for 5 minutes
The end prep DNA can be stored at 4ºC overnight and protocol can be paused at this point.
Native barcode ligation
From the ONT kit:
Thaw the EDTA at room temperature, mix by vortexing, spin down, then place on ice.
Thaw the required Native barcodes at room temperature (a different barcode for each sample), mix by flicking of pipetting, spin down, then place on ice.

Thaw the Blunt/TA ligase master mix at room temperature, mix by inverting and flicking well, spin down, then place on ice.
Select a different barcode for each sample and note this down in your sample spreadsheet (the same spreadsheet used to calculate sample volumes).

Add the following reagents to a clean 0.2ml tube:

AB
ReagentVolume
Native barcode2.5μl
Blunt/TA Ligase Master Mix10μl
End-prepped DNA7.5ul

Mix by gently pipetting or flicking then spin down (5 seconds).
Incubate at room temperature for 20 minutes.
To each sample add the following volume of EDTA depending on the colour of its cap:

AB
Clear cap EDTA2μl
Blue cap EDTA4μl

Pipette to mix on addition of the EDTA then spin each tube down.
Pool all samples into a single 1.5ml tube and note down the final volume.

You can estimate this by multiplying the volume of each sample (22μl if clear cap EDTA, 24μl if blue cap EDTA) by the total number of samples.
Add 0.4x AMPure XP beads to the pooled reaction and mix by flicking the tube.
For example if the pool volume is 200μl, add 80μl AMPure XP beads.

Incubate at room temperature for 10 minutes, flicking the tube every 2-3 minutes to maintain the beads suspension.
Spin down and pellet the beads on a magnet until the eluate is clear and colourless (3-5 minutes). Whilst still on the magnet remove and discard the supernatant.
Wash the pellet with 700μl 80% ethanol, without disturbing the pellet remove the ethanol and repeat this step.
Spin down (5 seconds), place the tube back on the magnet and remove any residual ethanol. Allow the pellet to air dry for 30 seconds then remove from the magnet and resuspend in 35μl nuclease free water.
Incubate at 37°C for 10 minutes, gently flicking the tube every couple of minutes to encourage elution.
Pellet the beads on the magnet until clear and colourless then take 30μl into a clean 1.5ml tube.
The samples can be stored at 4ºC overnight and protocol can be paused at this point.
Adapter ligation
Thaw NEBnext Quick ligation buffer, Short Fragment Buffer (SFB - ONT kit), and Elution Buffer (EB) at room temperature, vortex to mix, spin down and place on ice.

Flick gently to mix then spin down the NEBNext Quick T4 ligase enzyme and the Native Adapter (NA - from ONT kit) and place on ice.
To the tube with 30μl cleaned barcoded samples, add the following:

AB
ReagentVolume (μl)
Native adapter (NA)5
NEBNext Quick Ligation buffer10
Quick T4 DNA ligase5

Gently flick the tube to mix then spin down (5 seconds).
Incubate at room temperature for 20 minutes

Note: At this point, you can remove your flow cell (FLO-MIN114) from the fridge to allow it to come to room temperature.
Resuspend AMPure beads by vortexing then add 20μl to the reaction and mix by gently flicking the tube. Incubate at room temperature for 10 minutes, gently flicking the tube every 2-3 minutes.

Note: At this point you can start up MinKNOW and run the Flow Cell check.
Spin down and pellet on the magnet. Still on the magnet, remove and discard the supernatant.
Wash the pellet with 125μl Short Fragment Buffer, flick the tube to resuspend the beads, spin down, then place back on the magnet to pellet the beads.
Repeat this step.
Spin down and place back on the magnet then remove any residual buffer. Resuspend in 15μl of Elution Buffer.
Incubate at 37°C for 10 minutes, flicking every couple of minutes to aid elution.

During this time, thaw Flow Cell Flush (FCF), Flow Cell Tether (FCT), Sequencing Buffer (SB), and Library Beads (LB) at room temperature, mix by vortexing, then spin down and place on ice.

You can also perform the flow cell check. Insert the MinION device into your laptop, open MinKNOW, insert the room temperature flow cell into the MinION, then select Start, then Flow Cell Check.
Spin down then place back on the magnet to pellet the beads. Remove and retain 15μl in a clean 1.5ml tube and keep on ice until ready to load.
Quantify 1 μl of the library using the Qubit fluorometer to ensure the library is not lost during clean-up steps. This value may be useful later for troubleshooting.
Priming the flow cell and loading the library
Prepare the flow cell priming mix by adding the following to a clean 1.5ml tube:

AB
ReagentVolume (μl)
Flow Cell Flush (FCF)1170
Bovine Serum Albumin (BSA; 50mg/ml)5
Flow Cell Tether (FCT)30

Open the lid of the nanopore sequencing device and slide the flow cell's priming port cover clockwise so that the priming port is visible. After opening the priming port, check for any bubbles under the cover. Draw back a small volume to remove any bubbles (a few µLs). Visually check that there is continuous buffer from the priming port across the sensor array.
Using a P1000 pipette, slowly load 800μL of the priming mix into the flow cell via the priming port.

Leave a small amount of liquid in the end of the pipette tip to ensure you do not introduce air into the flowcell.

Leave for 5 minutes.
Mix the contents of the LIB tube by pipetting just before adding to the following library mix in a 1.5ml tube:

AB
ReagentVolume (μL)
DNA library12
Sequencing buffer (SB)37.5
Library beads (LIB)25.5

Complete the flowcell priming by opening the SpotOn port cover and carefully loading 200μL of the priming mix into the priming port. As before, leave a small amount of liquid in the bottom of the tip to avoid the introduction of air bubbles.
When adding the priming mix, you may see a small amount of liquid come up through the SpotOn port. If you do, pause and allow the liquid to flow back into the flowcell before continuing putting through the priming mix.
Mix the prepared library mix gently by pipetting.

Add the library mix to the flowcell via the SpotOn port in a dropwise fashion, allowing each drop to flow into the flowcell before adding the next.
Replace the SpotOn port cover and close the priming port, then replace the lid of your sequencing device.
Starting the Sequencing Run
Open the ONT MinKNOW software and follow the steps below to set up and start your sequencing run.
Click start, then start sequencing.
Create a name for you sequencing run, it is good practise to make this unique and identifiable for if you ever need to revisit the data. The date and an experiment name are recommended. In sample name you can put a number or repeat the experiment name - this is not as important as the run name. Then click continue.
Select the kit used - this is SQK-NBD114.24 or SQK-NBD114.96 depending on whether you have purchased the 24 or 96 barcode kit. Click continue.
In the run length options, set the run time; refer to the attached guide for calculating the sequencing time. Click continue.
Download Calculating the sequencing time and output.docxCalculating the sequencing time and output.docx16KB

In the basecalling options, select high accuracy basecalling. In the barcoding options, make sure barcoding is enabled and toggle to use ''barcode at both ends'' and ''trim barcodes''. Click continue until you reach the run overview, where you can double check the selected options, then click start run.
Washing the flow-cell after sequencing
Washing the flow-cell after sequencing
A nanopore flow cell can be used multiple times, so it must be washed to remove the library from the previous run.
Place the tube of Wash Mix (WMX) on ice. Do not vortex the tube and thaw one tube of Wash Diluent (DIL) at room temperature.
In a clean 1.5 ml Eppendorf DNA LoBind tube, prepare the following Flow Cell Wash Mix:


AB
Reagent Volume per cell (µl)
Wash Mix (WMX) 2
Wash Diluent (DIL)398
Total 400
Mix well by pipetting, and place on ice. Do not vortex the tube.
After the sequencing run, close the ONT MinKNOW software. Detach the MinION device from the laptop and leave the flowcell in the device.
Before removing the waste fluid, ensure that the flow cell priming port cover and SpotON sample port cover are closed.
Using a P1000, remove all fluid from the waste channel through waste port 1. As both the flow cell priming port and SpotON sample port are closed, no fluid should leave the sensor array area.
Rotate the flow cell priming port cover clockwise so that the priming port is visible.
After opening the priming port, check for a small air bubble under the cover. Draw back a small volume to remove any bubbles.
Load 200 µl of the prepared Flow Cell Wash Mix into the flow cell priming port, avoiding the introduction of air and incubate for 5 minutes.
Load the remaining 200 µl of Flow Cell Wash Mix into the flow cell priming port.
Close the flow cell priming port and incubate for 60 minutes.
Before removing the waste fluid a second time, ensure that the flow cell priming port cover and SpotON sample port cover are closed.
Using a P1000, remove all fluid from the waste channel through waste port 1. As both the flow cell priming port and SpotON sample port are closed, no fluid should leave the sensor array area.
You can now either run a second library on the flow cell straight away or store the flow cell for later use.
To run a second library straight away, follow the flow cell priming instructions in step 16.
To store the flowcell for later use, thaw one tube of Storage Buffer (S) at room temperature, mix contents thoroughly by pipetting and spin down briefly (~30 seconds).
Rotate the flow cell priming port cover clockwise so that the priming port is visible.
After opening the priming port, check for a small air bubble under the cover. Draw back a small volume to remove any bubbles.
Slowly add 500 μl of Storage Buffer (S) through the flow cell priming port.
Close the priming port.
Using a P1000, remove all fluid from the waste channel through waste port 1. As both the flow cell priming port and SpotON sample port are closed, no fluid should leave the sensor array area.
The flow cell can now be stored at 4-8°C.