C. Hutchinsonii Media
This is the media used for C. Hutch and co cultures with E. Coli. The media contains all the salts needed for both bacteria but not the carbon source (filter paper) due to the carbon source not being liquid. Cultures are made by adding the salt solution to a tube containing a piece of filter paper where the tube with the paper in it has been sterilized (usually by autoclave).
C Hutch ALONE in 1 L
Paper: 50 grams per liter of media, which is one 0.5g 9cm No. 1 filter paper disks per 100 mL.
Component
|
Amount
|
KH2PO4
|
0.2 g
|
MgSO4*7H2O
|
0.5 g
|
KCl
|
0.5 g
|
NaNO3
|
0.5 g
|
FeSO4*7H2O
|
20 mg
|
K2HPO4
|
0.8 g
|
tryptone
|
1 g
|
Autoclave 15 min.
E Coli ALONE (M9) in 1 L
- Make 5x M9 salts
- To make M9 Salts aliquot 800ml H2O and add
- 64g Na2HPO4-7H2O
- 15g KH2PO4
- 2.5g NaCl
- 5.0g NH4Cl
- Stir until dissolved
- Adjust to 1000ml with distilled H2O
- Sterilize by autoclaving
- Measure ~700ml of distilled H2O (sterile)
- Add 200ml of M9 salts
- Add 2ml of 1M MgSO4 (sterile)
- Add 20 ml of 20% glucose (or other carbon source)
- Add 100ul of 1M CaCl2 (sterile)
- Adjust to 1000ml with distilled H2O
C Hutch is slow to grow, so experiments will be much faster if large initial concentrations of C Hutch is used. This is achieved by having a continual stock of C Hutch in the incubator which is used to provide cells for experiments
Protocol:
Stripette:
- 10ml of current stock
- 90ml of DSM3T media
- 5g of autoclaved filter paper strips
into a 500ml flask, and place in shaker.
Preparing the Gel
- Check to see if there is a gel waiting in the fridge.
- Dissolve UltraPure agarose to a final concentration of 1%(by mass) in TAE buffer in a glass bottle.
- Heat the solution in the microwave with frequent stirring to dissolve the agarose homogenously. ~1 minute/200ml solution
- Let sit until cool enough to handle.
- Add 10 µl SYBRSafe (1:10000) per 100 ml of the solution and mix well.
- Pour 50ml* of solution per small gel tray. The gel trays and combs should be pre-cleaned with water and wiped dry.
- Note for combs: 15-well combs hold about 6 ul liquid per well, 12-well combs hold about 15 ul per well, 8-well combs hold about 20 ul per well
- Taping two 8-well comb wells together results in a well that holds up to 100 ul
- Taping three 8-well comb wells together result in a well that holds up to 200 ul
- Use 120 ml per large gel tray. [need to update amounts]
- For the small set: small trays hold 20 ml, large trays hold 50 ml
- Wait for the gels to solidify. ~15 mins
- Label and store at 4C.
*Most of the iGEM gel trays are the small trays that fit 50ml of solution for making the gel.
Running the Gel
When doing gel extraction, it is important to run both an analytical gel (to view under UV) and an extraction gel (from which bands are excised). UV damages DNA, and so we dont want to expose our extracted DNA.
Analytical Gel:
The analytical gel should have between 20 and 100 ng of DNA in each well. It should be an exact copy of the extraction gel with respect to position, voltage, and run time.
Extraction Gel:
This should be the rest of the digestion(s).
The analytical and extraction gels can technically be part of the same physical gel. Make sure to separate with a razor blade before imaging.
Refer to Gel Prep protocol above to determine the amounts of liquid to load for the specific well.
Appropriate Hyperladder to be used for PCR product which is linear. Usually Hyperladder I will be used.
- While casting gel, add two sets of lanes; use one set to load an analytical gel.
- Add 2ul gel loading buffer (Orange G 6X; it helps DNA sink into the bottom of the well) to DNA.
- Make sure there is enough 1xTAE in the plate holder.
- Load 5.0ul of appropriate hyperladder to one of the lanes.
- Load appropriate amount of DNA - As much as possible! Usually 15-18ul - (mixed with the buffer) in each well.
- Set the timer and voltage to 100V and 25 min.
Analytical Gel Annotation
The following things need to be added to the analytical gel image BEFORE it is posted to the wiki:
- Label each lane with part number and amount of DNA loaded
- Label each band with length and proposed identification
- Include wt% agarose, run time, and voltage
- Place the extraction gel on the blue light table.
- Cut out the appropriate bands. Place into 2mL microtube(s). Try to cut out as small a piece as possible while still getting all the DNA.
- Weigh gel slice (tare with empty microtube). Add 3 volumes of ADB buffer per mg of gel (so a 100mg gel gets 300 uL of ADB buffer).
- Incubate at 55C for 10 minutes. Make sure that the gel is completely dissolved.
- Add dissolved gel solution to Zymo column in collection tube. Max volume is 800 uL at a time.
- Spin 14000 rpm for 30 sec.
- Discard liquid in collection tube.
- Repeat step 5-7 if had more than 800 uL dissolve gel.
- Add 200 uL DNA wash buffer.
- Spin 14000 rpm 30 seconds.
- Discard liquid in collection tube.
- Add 200 uL DNA wash buffer
- Spin 14000 rpm 1 min.
- Discard liquid in collection tube.
- Spin 14000 rpm 1 min one more time (dry spin).
- Discard collection tube (but not the column).
- (Optional: 2nd dry spin into clean collection tube.)
- Place column in a clean labeled microtube.
- Add 10 uL (min 6 uL for higher DNA concentration) of sterile DDH2O to top of column. Water should be pipetted directly onto center of filter.
- Incubate at RT 1 min (or longer).
- Spin 1 min at 14000 rpm. Discard the column.
- Measure the concentration on the nanodrop. (You may recover the 1uL from the nanodrop if needed.)
- Cut the gel to separate analytical and extraction gel; place analytical gel in UV illuminator.
- Look at the gel under low wavelength UV (high wavelengths will denature DNA). Quickly take a polaroid image and shut OFF the UV.
- Cut extraction gel under white light; avoid UV illuminating the extraction gel as this drastically decreases the DNA yield. If necessary, stain with Methyl Blue.
- Place the cut bands in 2ml Eppendorf tubes; Weigh slices; No more than 400mg per tube
- Add 3 volumes (6 volumes if you are afraid of getting a low yield) of Buffer QG to 1 volume of gel (100mg ~ 100ul)
- Incubate at 50C for 10min or until gel is dissolved; vortex every 2-3 min
- Confirm that color of mixture is yellow (if not, add 10ul of 3M NaAc, pH 5.0)
- Add 1 gel volume of isopropanol
- Add max of 770ul to QIAquick column and centrifuge for 1 min (max speed, ~13,000rpm, RT)
- Run flow-through over column one more time.
- After the second time, discard flow-through and place column back in tube.
- If needed, add rest of mixture to same tube (up to additional 770ul), spin, and discard flow-through
- Add 500uL of Buffer QG to column and centrifuge for 1 min (wash).
- Wash: add 0.75ml Buffer PE (make sure that the buffer has ethanol added to it) to column. Let stand for 2-5 minutes and then centrifuge for 1 min
- Discard flow-through & centrifuge for 1 min
- Place column into clean Eppendorf tube
- Add 50ul Buffer EB or water to center of membrane. Make sure to use warm EB (50C). (Use 30uL if worried about low concentration.)
- Let stand at RT for 4 min
- Centrifuge for 1 min
- Measure the concentration using the UV spectrophotometer.
Pro Tips
- You don't need 2 lanes if you aren't putting your gel under UV light (the blue light and SYBR safe is fine)
- You can up the IPA to 1/4 of the total volume
- Warm EB (50 mL conical filled w/ water, plop the tube inside, put it in the heat block)
- Don't let it stand at room temperature, you can do it at 5 degrees (heat block)
- Cut the gel to separate analytical and extraction gel; place analytical gel in UV illuminator.
- Look at the gel under low wavelength UV (high wavelengths will denature DNA). Quickly take a polaroid image and shut OFF the UV.
- Cut extraction gel under white light; avoid UV illuminating the extraction gel as this drastically decreases the DNA yield. If necessary, stain with Methyl Blue.
- Place the cut bands in 2ml Eppendorf tubes; Weigh slices; No more than 300mg per tube
- Add 3 volumes of Buffer QG to 1 volume of gel (100mg ~ 100ul)
- Incubate at 50C for 10min or until gel is dissolved; vortex every 2-3 min
- Confirm that color of mixture is yellow (if not, add 10ul of 3M NaAc, pH 5.0)
- Add 1 gel volume of isopropanol
- Add max of 800ul to MinElute column and centrifuge for 1 min (speed >= 10,000 G, RT)
- Discard flow-through and place column back in tube.
- If needed, add rest of mixture to same tube (up to additional 770ul), spin, and discard flow-through
- Add 500 uL of buffer QG and spin column for 1 min and discard flow-through
- Wash: add 0.75ml Buffer PE(make sure that the buffer has ethanol added to it) to column and centrifuge for 1 min
- Discard flow-through & centrifuge for 1 min
- Place column into clean Eppendorf tube
- Add 10ul Buffer EB (10 mM TrisCl,pH 8.5) or water to center of membrane
- Let stand at RT for 1 min
- Centrifuge for 1 min
- Measure the concentration using the UV spectrophotometer.
50 ng of each piece of DNA being joined
Use nanodrop to find concentration in ng/ul, then divide 50 by that concentration to find the required volume of DNA:
Conc: x ng/uL
Vol: 50/x uL
NOTE: If GGDonr is too concentrated, dilute it with EB or water.
NOTE: Ligase buffer does not like to be freeze-thawed, so use one-time-use aliquots.
x1 uL of DNA1
x2 uL of DNA2
y uL (100ng) Donor
2ul 10X T4 Ligase Buffer
2ul 10X BSA
1ul BsaI (enzyme) HC (high concentration)
1ul T4 Ligase (enzyme) HC (high concentration)
fill to 20uL with SDIH20 (put water in before the buffer and enzymes)
-------------
20ul total
(NOTE: Make sure that Buffer and Enzyme added last, enzyme after buffer)
Take a p20, set it to 10uL and then pipet up and down.
Example: Excel File
ADD
|
CONC.
|
VOLUME
|
ORDER
|
DNA1
|
c1 ng/ul
|
x1 = 50/c1 ul (50ng)
|
2
|
...
|
...
|
...
|
...
|
DNAn
|
cn ng/ul
|
xn = 50/cn ul (50ng)
|
2
|
GGDonr
|
d ng/ul
|
y = 50/d ul (100ng)
|
2
|
10x T4 Ligase Buffer
|
|
2ul
|
3
|
10x BSA
|
|
2ul
|
3
|
BsaI (enzyme)
|
|
1ul
|
4
|
T4 Ligase (enzyme)
|
|
1ul
|
3
|
H20
|
|
20 - (x1 + ... + xn + y) ul
|
1
|
|
|
|
|
TOTAL
|
|
20ul
|
|
THERMOCYCLER:
(Protocol EBGG)
37C for 5min
Part 1
50X:
37C for 2.5min
4C for 0.5min
16C for 5.5min
Part 2
37C for 10 min
80C for 20 min
4C hold (for 8+ hours)
(Check protocol by looking up the paper or other online GG protocols)
Appending Prefix and Suffix
Things to keep in mind!
See designing primers page
- Annealing temperature of primers (Tm) should be around 60 C and both primers should be within 1-2C of each other
- Check the secondary structure of the primers before you order them!
- no individual secondary structures i.e. hairpins
- no heterostructure with the forward and reverse primers together
- free energy of primers should be greater than -4 kCal
- GC content should be around 50% (40-60% is okay)
If using Phusion Master Mix, use this protocol: https://www.neb.com/protocols/2012/09/06/protocol-phusion-high-fidelity-pcr-master-mix-with-hf-buffer-m0531
- Dilute your DNA to the following concentrations:
DNA
|
Concentrations
|
Template
|
0.1 - 1 ng/ul
|
Forward Primer
|
10 uM
|
Reverse Primer
|
10 uM
|
- Set up a small box (e.g. empty pipette tip box) with ice and water. Your DNA and polymerase mix will go into this box before going into the the thermocycler in order to limit endonucelase activity.
- Add the following DNA to a labeled 0.6ml PCR tube
DNA
|
Volume
|
Template
|
1 uL
|
Forward Primer
|
500 nM
|
Reverse Primer
|
500 nM
|
- Program the thermocycler as follows
Temperature
|
Time
|
98
|
30s
|
PAUSE
|
98
|
5s
|
Tm
|
15
|
72
|
(15s)x(#kb)
|
72
|
5m
|
4
|
forever
|
- Wait for thermocycler to heat up
- Add 22.5uL of polymerase mix (Phusion Master Mix) to your DNA. Mix well and spin down. Transfer tubes to ice as soon as possible.
- Once the thermocycler has heated up to the right temperature (it should be paused at 98C), add tubes to thermocycler and resume PCR program.
Calculating Reaction Conditions
- Use idtdna.com or VectorNTI to calculate melting temperatures of primers
without common overhangs (base pairs 30 to end when read 5' to 3').
- Phusion elongates at a rate of 1kb (1000bp) per 15s. Look up the length of the
gene of interest and calculate time of elongation.
- You should get your Tm from NEB.
If you get the melting temperature of your primer from Genious, the annealing
temperature will be that number minus 2.
|
Assembling Reaction
- Get 0.6mL PCR tubes (not the strip tubes).
- Get primers for gene of interest. Resuspend if necessary.
- Thaw Phusion supermix on ice.
- Add the following (in order):
VOLUME
|
REAGENT
|
22.5uL (for 35 cycles)
|
Phusion Supermix
|
2uL
|
5uM Forward Primer
|
2uL
|
5uM Reverse Primer
|
1uL
|
Template DNA(~150ng)
|
|
Programming The Thermocycler
(In the 3rd floor thermocycler, the PCR program is named "PHUSION")
Initial Denaturation: 98C for 5min
LOOP: 30-35 cycles
CYCLE:
Denaturation: 98C for 10s
Annealing: calculated temperature (typically 55-65C) for 30s
Elongation: 72C for 15s per kb
Final Elongation: 72C for 10min
Store: 4C
|