Difference between revisions of "Team:Czech Republic/Protocols"
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= Genome extraction = | = Genome extraction = | ||
+ | ==Extraction of genomic DNA from yeast cells for PCR-based applications== | ||
+ | *200ul of overnight yeast culcure (OD=0.4) | ||
+ | *100ul of 200mM LioAc, 1% SDS | ||
+ | *20ul 1M LiOAc | ||
+ | *5ul SDS 20% | ||
+ | *75ul NF water | ||
+ | *300ul of ethanol 96-100% | ||
+ | *300ul of ethanol 70% | ||
+ | *NF water | ||
+ | Protocol: | ||
+ | #Heat shaker on 70°C. | ||
+ | #spin ddown 100-200 ul of yeast culture 3min at 5000g. | ||
+ | #Suspend cells in 100ul of 200mM LioAc, 1% SDS. | ||
+ | #Incubate for 5min at 70°C. | ||
+ | #Add 300ul of ethanol 96-100%, vortex, spin down 3min at 5000g. | ||
+ | #Remove supernatant. Add 300ul of ethanol 70%, vortex, spin down 3min at 5000g. | ||
+ | #Remove supernatant. DIssolve pellet in 100ul NF water, spin down for 15sec at 15000g. | ||
+ | #Use 1ul of supernatant for PCR. | ||
= Soft lithography - PDMS molding = | = Soft lithography - PDMS molding = |
Revision as of 11:56, 18 September 2015
Protocols
Contents
Purification
- Nucleospin Gel and PCR clean-up
- 1.5ml eppendorf tube
Protocols:
- Mix 1 volume of sample with 2 volumes of NTI buffer (for example 100ul of sample with 200ul of NTI buffer) or for each 100mg of agarose gel add 200ul Buffer NTI and incubate the gel-sample for 5 – 10min at 50C and vortex until the gel slice is completely dissolved.
- Transfer at max 700ul of sample into the spin column and centrifuge 30s at 11,000g (for sample from gel is maybe necessary to repeat this and next step).
- Discard the flow-through.
- Add 700uL of NT3 buffer, centrifuge 1min at 11,000g.
- Discard the flow-through.
- Centrifuge empty column 3min at 11,000g.
- Discard the flow-through and place the spin column into eppendorf tube.
- Put the tube in shaker pre-heated on 70 C and incubate for 3min at 70 C.
- Instil 15uL of Elution buffer into the center of spin column filter.
- Incubate for 3min at room temperature or 70 C if the DNA fragments is longer than 1000 bp.
- Centrifuge 1min at 11,000g.
- Repeat again steps 9-11 .
Transformation (bacteria)
- Electrocompetent cells
- Plasmid DNA (5pg - 100ng)
- Box with ice
- Electroporation cuvette
- 1.5mL eppendorf tube
- LB-agar plate with appropriate antibiotic
- 950μL SOC at room-temperature
Protocol:
- Put electroporation cuvette, eppendorf tube, pipette tips in a freezer.
- Chill DNA samples in ice.
- Place LB-agar plate in 37° C incubator.
- Thaw electrocompetent cells on ice in a frige for 40min.
- Prepare 950μL SOC into 1000μL pipette
- Pipet 1-2μL DNA sample (diluted to an appropriate amount) and add to electrocompetent cells. Swirl tip around gently in cell to 11mix DNA with cells.
- If using iGEM DNA distribution kit, punch a hole through the foil cover into the corresponding well, hydrate DNA (add 10μL of ultrapure dH20 to the well, pipette up and down a few times and let sit for 5min to make sure the dried DNA is fully resuspended).
- Place cells back on ice to ensure they remain cold.
- Transfer cell-DNA mixture to cuvette. Try not to handle cuvette base too much so that it stays cold.
- Make sure the electrodes on the cuvette are dry.
- Place the cuvette into electroporator and pulse the cells with shock.
- Immediately add SOC, pipet up and down to make sure all cells are in SOC.
- Transfer SOC-cell mixture to chilled eppendorf tube and put it on ice for 2min to permit the cells to recover.
- Transfer eppendorf tube to 37°C shaking incubator for 1-1.5hr to per- mit expression of antibiotic resistance gene.
- Plate 200μL onto prewarmed LB-agar plate with appropriate antibi-otic.
- Incubate overnight at 37°C.
Transformation (yeast)
Gel electrophoresis
TBE stock 10X (1000ml)
- 108g Trisbase
- 55g Boric acid
- 9.3g EDTA (Ethylenediaminetetraacetic acid)
- dH20
- Add the ingredients into 900ml of dH20, mix it properly and fill to 1000ml.
- Store at room temperature.
NaOH stock 0,1M (200mL)
- 0.8g NaOH
- Boric acid
- dH20
- Add the ingredients into 200ml of dH20.
- Set pH on 8,5 by Boric acid.
- Store at room temperature.
Electrophoresis gel (100ml) 1%
- Agarose
- 1X TBE or 0,1M NaOH
- Ethidium bromide
Protocol:
- Add 0,7g agarose to 100ml 1X TBE or 10mM NaOH.
- Heat in microwave for 1 min at high power.
- Mix it and put it again into microwave for 1 min at high power.
- Make sure you have nitril gloves.
- Let it chill down for 6min and add 4 uL of ethidium bromide.
- Pour the balanced plate, don't forget to put the rake on.
- After the gel congeal, cover it with 1X TBE or 10mM NaOH.
For making small electrophoresis use half the amounts.
Miniprep
- Miniprep NucleoSpin Plasmid
- 2x 1.5ml eppendorf tube
Protocol:
- Overnight culture: Centrifuge 5ml at 11,000g for 30s, remove the liquid, add 250 uL A1 buffer, vortex properly and transfer it to the eppendorf tube.
- Petri dish: Add 250 L A1 buffer to the eppendorf tube, scrape off and add a culture from one partition, vortex properly.
- Add 250 uL A2 buffer (blue), gently invert 8 times, incubate for 5min at room temperature.
- Add 300 uL A3 buffer, gently invert to the change of colour (from blue to white).
- Centrifuge 7min at 11,000g.
- Transfer max 750 uL of the supernatant into 2ml spin column.
- Centrifuge 1min at 11,000g.
- Discard the flow-through and add 600 uL A4 buffer, centrifuge 1min at 11,000g.
- Discard flow-through and centrifuge 3min at 11,000g.
- Put the spin column into new eppendorf tube.
- Instil 25 uL DNA free water into the center of spin column filter, incubate for 3min at room temperature.
- Centrifuge for 1min at 11,000g.
- Repeat again steps 10-12.
Restriction digest
For a restriction digest of 500ng DNA, you need
- Restriction enzymes
- Corresponding NEB buffer
- 100X BSA
- XμL DNA (500ng)
- (42.5-X)μL dH2O
- 0.6mL tube
Protocol:
- Add appropriate amount od dH2O to the tube
- Vortex NEB buffer and add 5μL
- Vortex BSA and add 0.5μL (no need to add BSA when using NEB CutSmart buffer)
- Vortex DNA and add appropriate amount to the tube
- Vortex each enzyme and add 1μL to the tube
- Incubate at 37°C for 30min, then heat-inactivate at 80°C for 20min
- Store at 4°C
DNA Ligation
Insert mass in ng = \(3\frac{Insert\,length\,in\,bp}{Vector\,length\,in\,bp}Vector\,mass\,in\,ng\)
- 10X T4 ligase buffer
- 0.5uL T4 ligase
- Purified insert and vector (~50ng vector) DNA
- (8.5 - vector and insert)uL ultrapure dH20
- 0.6mL tube
Protocol:
- Add appropriate amount of ultrapure water to sterile 0.6mL tube.
- Vortex 10X T4 ligase buffer and add 1uL to the tube.
- Add appropriate amount of vortexed insert and vector DNA to the tube.
- Vortex T4 ligase and add 0.5uL to the tube.
- Place the tube in thermal cycler and run ligation protocol (60min incubation at 16°C, 10min at 65°C to denaturate the ligase)
- Store at -20°C
PCR Methods
Preparation of Primers
- Centrifuge a primer in the original tube.
- For 1 nmol of primer add 10 ul of DNA free H2O into original tube and vortex properly.
- Into new eppendorf tube add 24 ul of DNA free H2O, 3 ul of forward primer and 3 ul of reverse primer – work concentration
One Taq PCR protocol (25 ul reaction)
- Into PCR tube add 17,875ul of dH2O
- Add 5ul 5X One Taq Standard reaction buffer, 0,5ul dNTPs, 0,5ul of mix primers – work concentration, 1ul template DNA – work concentration 1 ng/ul and 0,125ul One Taq DNA polymerase.
Q5 PCR protocol
- Into PCR tube add 17 ul DNA free H2O.
- Add 5 ul 5X Q5 reaction buffer, 0,5 ul dNTPs, 1,25 ul of mix primers – work concentration, 1 ul template DNA – work concentration 1 ng/ul and 0,25 ul Q5 High-Fidelity DNA polymerase.
Adjustement of thermo cycler
- Denaturation – 10s, 98°C
- Annaeling - 30s, temperature depends on the primers
- Extension – time depends on the length of PCR construct - 30s for 1000bp, 68° for Taq / 72° for Q5
Band-stab PCR
Excellent technique when you want to amplify specific band from a gel. http://bitesizebio.com/13512/pcr-rescue/ More info..
- Prepare a complete 50μL PCR reaction without DNA template
- Take a sterile pipette tip and stab the desired band of interest 2-3 times
- Swirl the tip in the tube with prepared PCR reaction
- Run the PCR as usual
Gibson
5X Isothermal Reaction Buffer (3mL)
- 0.75g 25% PEG-8000
- 1.5ml 1M Tris-HCl (pH 7.5)
- 75 uL 2M MgCl2
- 150 uL 1M DTT
- 30 uL 100mM dATP
- 30 uL 100mM dTTP
- 30 uL 100mM dCTP
- 30 uL 100mM dGTP
- 300 uL 50mM NAD
Aliquot 3 x 1mL and store at 20 C. Note: You can use 30 L of 100mM dNTP instead of dNTPs individually.
1.33X Gibson Master Mix (375 uL)
- 100 uL 5X Isothermal Reaction Buffer
- 50 uL (40U/ uL) Taq DNA ligase
- 2 uL (10U/ uL) T5 exonuclease
- 6.25 uL (2U/ uL) Phusion DNA polymerase
- 216.75 L udH20
- Add DNA to the Master Mix in volumetric ratio 1:3 (between 10 and 100ng of each DNA fragment)
- Incubate for 1 hour at 50 C
Genome extraction
Extraction of genomic DNA from yeast cells for PCR-based applications
- 200ul of overnight yeast culcure (OD=0.4)
- 100ul of 200mM LioAc, 1% SDS
- 20ul 1M LiOAc
- 5ul SDS 20%
- 75ul NF water
- 300ul of ethanol 96-100%
- 300ul of ethanol 70%
- NF water
Protocol:
- Heat shaker on 70°C.
- spin ddown 100-200 ul of yeast culture 3min at 5000g.
- Suspend cells in 100ul of 200mM LioAc, 1% SDS.
- Incubate for 5min at 70°C.
- Add 300ul of ethanol 96-100%, vortex, spin down 3min at 5000g.
- Remove supernatant. Add 300ul of ethanol 70%, vortex, spin down 3min at 5000g.
- Remove supernatant. DIssolve pellet in 100ul NF water, spin down for 15sec at 15000g.
- Use 1ul of supernatant for PCR.
Soft lithography - PDMS molding
- Mix 40g of PDMS with 4g of curing agent
- Centrifuge the mixture at 3250 RPM for 3 minutes to remove the bubbles introduced during the mixing
- Clean silicon master with air gun
- Wrap an aluminium foil around the edges of the silicon master to create a container
- Pour the PDMS mixture over the silicon master
- Cure the PDMS in an oven at 80°C for 2 hours
- Leave the PDMS to cool down
- Detach the PDMS carefully from the silicon master
Soft lithography - Bonding PDMS-Glass
Preparation of the substrates
Glass slide
- Rinse the glass slide with acetone, isopropanol, and deionized water
- Dry the glass slide with air gun
- Dehydrate the glass slide on a hot plate at 120°C for 30 minutes
PDMS
- Slice the PDMS to individual PDMS replicas
- Drill holes for microfluidic inlets and outlets
- Clean the PDMS using a scotch tape
Air plasma treatment
- Place the glass slide and the PDMS replicas into a plasma cleaner, contact surfaces facing upwards
- Exhaust the atmosphere with a vacuum pump and wait until the pressure drops to 500 mTorr
- Activate the plasma for 2.5 minutes at Hi power
- Stop the plasma and open the valve to stabilize the pressure, continue immediately with the bonding phase
Permanent irreversible bonding
- Place the PDMS replica on the glass slide
- Place the bonded device in an oven at 80°C for 60 minutes.
- Seal the inlets and outlets with a scotch tape until use