Team:Kyoto/Material and Method

From 2014.igem.org

(Difference between revisions)
 
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     <a name="modeling" class="kyoto-jump"></a>
     <a name="modeling" class="kyoto-jump"></a>
<h2>Modeling</h2>
<h2>Modeling</h2>
-
<p>We calculated the theoretical VOR of the <i>E. coli</i> group, assuming that every individual has one vesicle (<i>i.e. </i>the part efficiency=100%).</p>
+
<p>We calculated the theoretical VOR of the <i>E. coli</i> group, assuming that every individual has one vesicle (<i>i.e.</i> the part efficiency = 100%).</p>
<p>We calculated the measured VOR of the pLQ and pLQB transformants from the section sliced vertically to x-axis (Represented by circule in the figure), to reduce the effect of the 3-D direction of the cells in the slice.</p>
<p>We calculated the measured VOR of the pLQ and pLQB transformants from the section sliced vertically to x-axis (Represented by circule in the figure), to reduce the effect of the 3-D direction of the cells in the slice.</p>
<p>Finally, we determined the part efficiency from the theoretical VOR and the measured VOR to calculate the part efficiency of the negative control, pLQ, and pLQB.</p>
<p>Finally, we determined the part efficiency from the theoretical VOR and the measured VOR to calculate the part efficiency of the negative control, pLQ, and pLQB.</p>
-
<p><h4>The caluculation of the theoretical VOR</h4></p>
+
<h4>The caluculation of the theoretical VOR</h4>
-
<p>1. Measure transformants' height and radius and determine the values of "b" and"c". </p>
+
<p>1. Measure transformants' height and radius and determine the values of "b" and "c".</p>
-
<p>*Assuming that the vesicle is detectable when the shortest distance of the center of modeled vesicle (a spherical shape) to the face of the slice is lower than the vesicle’s radius ( The value of “a” is lower than that of “b”/2).</p>
+
<p>*Assuming that the vesicle is detectable when the shortest distance of the center of modeled vesicle (a spherical shape) to the face of the slice is lower than the vesicle's radius (The value of "a" is lower than that of "b"/2).</p>
</p>
</p>
<p>2. Subsititute them in the fomula.(<a href="#fig1">Fig. 1</a>)</p>
<p>2. Subsititute them in the fomula.(<a href="#fig1">Fig. 1</a>)</p>
-
<div class="kyoto-fig">
 
-
<a name="fig1" class="kyoto-jump"></a>
 
<figure>
<figure>
 +
<a name="fig1" class="kyoto-jump"></a>
<img src="https://static.igem.org/mediawiki/2014/4/4a/Kyoto-magfig15.png" width=500px>
<img src="https://static.igem.org/mediawiki/2014/4/4a/Kyoto-magfig15.png" width=500px>
-
<figcaption><span class="kyoto-fig-title">Fig. 1 Our model of E. coli</span></figcation>
+
<figcaption><span class="kyoto-fig-title">Fig. 1 Our model of <i>E. coli</i></span></figcation>
</figure>
</figure>
-
</div>
+
<h4>The calcuration of the measured VOR</h4>
-
<p><h4>The calcuration of the measured VOR</h4></p>
+
<p>1. Pick up sections that are considered to be sliced vertically to x-axis. </p>
<p>1. Pick up sections that are considered to be sliced vertically to x-axis. </p>
-
<p>Count the section only when the ratio to long axis and short axis of the section is lower than 2.0.(<a href="#fig2">Fig. 2 </a>)</p>
+
<p>Count the section only when the ratio to long axis and short axis of the section is lower than 2.0.(<a href="#fig2">Fig. 2</a>)</p>
<p>2.  Count the sections and the number of vesicles of them.</p>
<p>2.  Count the sections and the number of vesicles of them.</p>
<p>3. Divide the number of vesicles by the number of the sections</p>
<p>3. Divide the number of vesicles by the number of the sections</p>
-
<div class="kyoto-fig">
 
-
<a name="fig2" class="kyoto-jump"></a>
 
<figure>
<figure>
 +
<a name="fig2" class="kyoto-jump"></a>
<img src="https://static.igem.org/mediawiki/2014/c/cd/Kyoto-magfig14.png" width=500px>
<img src="https://static.igem.org/mediawiki/2014/c/cd/Kyoto-magfig14.png" width=500px>
<figcaption><span class="kyoto-fig-title">Fig. 2 The criterion of the section counted</span><br>We count left but did't count right.</figcation>
<figcaption><span class="kyoto-fig-title">Fig. 2 The criterion of the section counted</span><br>We count left but did't count right.</figcation>
</figure>
</figure>
-
</div>
 
-
<p><h4>The calculation of the part efficiency</h4></p>
+
<h4>The calculation of the part efficiency</h4>
<p>Divide the value of measured VOR by the value of theoretical VOR</p>
<p>Divide the value of measured VOR by the value of theoretical VOR</p>

Latest revision as of 01:46, 18 October 2014

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Material & Method

Parts

If you see our team's parts in part.igem.org, Click Here.

<groupparts>iGEM014 Kyoto</groupparts>

Primers

Magnetosome

mamL
mamL-AMB-FGCAGTATTGGCGTCAGCTTGGAG
mamL-AMB-RAACCGCTCTTCCTCATCCTTACTCAC
Xba-RBS-mamL-FGCTCTAGAAAAGAGGAGAAAAGTGGCATGGTAAGATTGATCG
Pst-Spe-His-mamL-RAACTGCAGCGGCCGCTACTAGTATCAGTGGTGATGGTGATGATGGCGCTTGATGACGATGCTC
mamQ
mamQ-AMB-FCCGCATTTCAAGAAGGCCAATGAAC
mamQ-AMB-RAACGAATCAGGCCCAGCACC
Xba-RBS-mamQ-FGCTCTAGAAAAGAGGAGAAAGCGGATATGGCATTAGGCG
Pst-Spe-His-mamQ-RAACTGCAGCGGCCGCTACTAGTATCAGTGGTGATGGTGATGATGTTTCTTGATGTCCTGCGCATG
mamB
mamB-AMB-FGGGACGATCAAGGCGAAGAAGG
mamB-AMB-RACGGCTCAACATACGCTCTGG
Eco-Xba-RBS-mamB-FCGGAATTCGCGGCCGCTTCTAGAGAAAGAGGAGAAAGAACCGATGAAGTTCGAAAATTGCA
Spe-mamB-RGGACTAGTGGCTCAACATACGCTCTGG
Eco-Pcon-Xba-RBS-mamB-FCGGAATTCTTGACGGCTAGCTCAGTCCTAGGTACAGTGCTAGCTCTAGAAAAGAGGAGAAAGAACCGATGAAGTTCGAAAATTGCA
Spe-His-mamB-RGGACTAGTCTAGTGGTGATGGTGATGATGGACGAACAGGCGGATGTCG
mutation-mamB-FCTGCAAACCGCCTGGCAGGTGGCCA
mutation-mamB-RCCAGGCGGTTTGCAGCAATTCCGTATCC
Sequence
pLQB-seq-1AGCTGCTTGCCCAGTTG
pQLB-seq-2TTTGATGGCGGTGGTGG
pQLB-seq-3TCGGCTACGGCAACATC
pLQB-seq-4AGTTCGACATCCGCCTG

DMS

AT
Fw AT cloning primer 61GGAATAGAAACAAAGTGGCAGCAACG
Rv AT cloning primer 61GCTACCAGGAGAAGTTGGGTTGAC
AT OE primer A 59CCGGAATTCGCGGCCGCTTCTAGATGGTATGTGTACAGTATATGATTCTCAGT
AT OE primer B 60TCGGTCGACTACCGGGACTGAGAATCATATACTG
AT OE primer C 59GTCCCGGTAGTCGACCGAAATGAAAACTTTG
AT OE primer D 61AACTGCAGCGGCCGCTACTAGTAATTTGAATAAAAATAGTCCATTGCTTTAG
AT2 OE primer B 61GTGGGGTTGTTAGGAGAACATAAATAGACGACATCG
AT2 OE primer C 60TTATGTTCTCCTAACAACCCCACTGGTGCTGC
Rv AT cloning for His 60CTAAAACTGCAGATCTTTCTTCATTGTAACTTTCAATCG
AT Mutation Insert Fw 55TCCCGGTATCGACCGAAATGAAAACT
AT Mutation Insert Rv 55CTAAAACTGCAGATCTTTCTTCATTGTAACTTTCAATCG
AT Deletion Mutation Fw 63GCCGATGTCgTCTATTTATGTTCTCCTAACAACCCCAC
AT Deletion Mutation Rv 63ATAGAGGACATCGGCACGGGGTAA
present from SantaACCTCGCTCTGCTAATCCTGTTAC
REDOX
Fw REDOX cloning primer 59CATTCGCATCTCACATCGTCTCATAG
Rv REDOX primer Ver.2 64CCTTCTCATTCTTAACGTGCAGGTAGG
Fw Pre-REDOX 59CCGGAATTCGCGGCCGCTTCTAGATGTCGTCCAAAAATGTGGTTC
Rv Suf-REDOX 58AACTGCAGCGGCCGCTACTAGTATGTATTATATTGCATTGTCCCTCC
Rv REDOX cloning for His 59CTAAAACTGCAGTGGTATTCCATATGCTTTTTTTTG
SAMmt
Fw SAMmt cloning primer 58ACGACGATGACGATGACGAC
Rv SAMmt cloning primer 57AGCATGGAAGAACGCATCAG
SAMmt OE primer A 60CCGGAATTCGCGGCCGCTTCTAGATGATTGGTGCTTCATTCTATGCT
SAMmt OE primer B 59ACGGGTAGTCGGTACAAAAGATTTTGAATATTCTC
SAMmt OE primer C 60ATCTTTTGTACCGACTACCCGTACATGGTCACATTCTA
SAMmt OE primer D 61AACTGCAGCGGCCGCTACTAGTAATGGGAACAGAACATGTTAAGTCTTG
Fw SAMmt mutation PstI 62TGTACCAGTGCAACATTCCATACC
Rv SAMmt mutation PstI 61TGTTGCACTGGTACAATAAATAATTGTT
Rv SAMmt cloning for His 61CTAAAACTGCAGTATTTTTTCTATAACTAAATAGGAATGGACG
dddD
F dddD cloning 66GTTCAAGCAGGCAGGCAAG
R dddD cloning 65AGCAACGGCACATATTCGAG
Fw Pre-dddD cloning Ver.2 68CCGGAATTCGCGGCCGCTTCTAGATGCAGAATCGCCCGCTTTCC
Rv SpeI-dddD cloning ver3 68CTACTAGTACGAGGCGTGGTTGCTGGTCC
Fw dddD PstI mutation 78.7TGCAACGTGAAAGCGAAGGCGAGATCGAC
Rv dddD PstI mutation 78.4CGCTTTCACGTTGCAGGCCCGCATC
T7-RBS-His-pSB1C3
Fw Add His to T7-RBS Ver.2 65CATCATCACCATCACCACTAATCCGGCAAAAAAGGGCAA
Rv Add His to T7-RBS Ver.2 64TTAGTGGTGATGGTGATGATGCTGCAGCGGCCGCTACTAG
Sequence
Sequence primer VF2 56.4TGCCACCTGACGTCTAAGAA
Sequence primer No.1 57.9TGATCGAGAACTTCCGCCC
Sequence primer No.2 57.3GCGAGCAGATCGAGGACTAC
Sequence primer No.3 57.6GAATGGGAGGAGCTGTTCG
Sequence primer No.4 56.3TATTGGATCGACACTGGCAC
Sequence primer No.5 57.2GGAAACACCCGAGGAACAC
Sequence primer No.6 56.4ACTGGATGCGAGCCTTTG
SAMmt sequence No.1 56ATTGTGAAAGCTGTTCGTGAA
AT sequence No.1TAGTGACGGTGCTAAATGTGATA
AT sequence No.2TGTTCCAGCGGGATTGA
REDOX sequence No.1GTGACACCCGAGTATAACCATT

Modeling

We calculated the theoretical VOR of the E. coli group, assuming that every individual has one vesicle (i.e. the part efficiency = 100%).

We calculated the measured VOR of the pLQ and pLQB transformants from the section sliced vertically to x-axis (Represented by circule in the figure), to reduce the effect of the 3-D direction of the cells in the slice.

Finally, we determined the part efficiency from the theoretical VOR and the measured VOR to calculate the part efficiency of the negative control, pLQ, and pLQB.

The caluculation of the theoretical VOR

1. Measure transformants' height and radius and determine the values of "b" and "c".

*Assuming that the vesicle is detectable when the shortest distance of the center of modeled vesicle (a spherical shape) to the face of the slice is lower than the vesicle's radius (The value of "a" is lower than that of "b"/2).

2. Subsititute them in the fomula.(Fig. 1)

Fig. 1 Our model of E. coli

The calcuration of the measured VOR

1. Pick up sections that are considered to be sliced vertically to x-axis.

Count the section only when the ratio to long axis and short axis of the section is lower than 2.0.(Fig. 2)

2. Count the sections and the number of vesicles of them.

3. Divide the number of vesicles by the number of the sections

Fig. 2 The criterion of the section counted
We count left but did't count right.

The calculation of the part efficiency

Divide the value of measured VOR by the value of theoretical VOR

Protocol

Contents

PCR

  • Mix the following.
NameVolume
25mM MgSO41.5 µL
2mM dNTPs2.5 µL
10xBuffer for KOD -Plus- ver.22.5 µL
Template DNAproperly
Primer Forward (10 µM)0.75 µL
Primer Reverse (10 µM)0.75 µL
KOD -Plus-0.5 µL
MilliQup to 25 µL
Total25 µL
  • Put samples into Thermal Cyclers and run the following steps.
PreDenatureDenatureAnealingExtensioncycle
94 °C98 °CTm-5 °C68 °C--
2 min10 sec30 sec1 min/kb30 cycles
  • Agarose Gel Electrophoresis for confirmation.

PCR: ToYoBo Quick Taq HS DyeMix

  • Mix the following.
NameVolume
Template DNAproperly
Primer Forward (10 µM)0.2 µL
Primer Reverse (10 µM)0.2 µL
2x Quick Taq HS DyeMix5 µL
MilliQup to 10 µL
Total10 µL
  • Put samples into Thermal Cyclers and run the following steps.
PreDenatureDenatureAnealingExtensioncycle
94 °C94 °CTm-5 °C68 °C--
2 min30 sec30 sec1 min/kb30 cycles
  • Agarose Gel Electrophoresis for confirmation.


Mutation PCR

Use TaKaRa PrimeSTAR Mutagenesis BasaI Kit

  • Dilute the concentration of template DNA with MilliQ.
  • Mix the following
PrimeSTAR Max Premix (2x)25µL
Primer Forward 10pmol
Primer Reverse10pmol
Template DNA (1ng/µL)1~2µL
MilliQup to 50µL
Total50µL
  • 30 cycles for 10s at 98°C, for 15s 55°C, and for 40sec at 72°C.
  • Agalose Gel Electrophoresis for confirmation.
  • Negative Control: Use nothing.
  • Add 2L PCR products and 20L competent cells for transformation.


RNA Extraction

Use ISOGEN-LS(NIPPON GENE,311-02621

  • Add 1mL ISOGEN-LS to sample and vortex.
  • Store for 5min on ice.
  • Add 250µL chloroform and shake vigorously for 15 sec.
  • Store for 3min. on ice.
  • Centrifuge 17400xg for 10min. at 4°C.
  • Transfer aqueous phase to another tube and add 0.8 volume isopropanol.
  • Store for 10min. on ice.
  • Centrifuge 17400xg for 10min. at 4°C.
  • Discard the supernatant.
  • Add 800µL 80% ethanol and vortex.
  • Centrifuge 7500xg for 5min. at 4°C.
  • Discard the supernatant.
  • Dry briefly.
  • Dissolve in nuclease-free water.


Making Competent Cells

  • Streak E.coli cells on an LB plate
  • Allow cells to grow at 37°C overnight
  • Place one colony in 3 mL LB media (+antibiotic selection if necessary), grow overnight at 37°C
  • Take 2 ml LB media and save for blank. Transfer 500 µL overnight culture into 50 mL LB media in 500 mL flask
  • Allow cell to grow at 37°C (250 rpm), until OD600= 0.4 (~2-3 hours)
  • Place cells on ice for 30 mins
  • Transfer cells to a centrifuge tube (50 mL), and centrifuge cells in High Speed refrigirated centrifuge at 4°C for 10 mins at 3,000 g.
  • Pour off media and resuspend cells in 12 mL of cold TB.
  • Centrifuge cells at 4°C for 10 mins at 3,000 g (2500 rpm)
  • Pour supernatant and resuspend cells (by pipetting) in 5 mL of cold TB and 350 µL of DMSO. Transfer 20 µL to 1.5 mL tube
  • Ependorff tubes placed on ice. Freeze the cells in liquid nitrogen. Cells stored at -80°C can be used for transformation for up to ~6 months


Miniprep

Use LaboPass Plasmid Mini Purification Kit.

  • Pick a single colony from a freshly streaked selective plate and inoculate a culture of about 3mL Plusgrow medium containing the appropriate selective antibiotic.
  • Incubate at 160 rpm for 8 h at 37 °C with vigorous shaking.
  • Pellet the bacterial culture by centrifugation for 1 min at 15,000 g in a tabletop centrifuge.
  • Discard the supernatant as much as possible.
  • Resuspend pelleted bacterial cells in 250 µL of Buffer S1.
  • Transfer the suspension to a new 1.5 mL tube.
  • Add 250 µL of Buffer S2 and mix by inverting the tube 4 times (do not vortex).
  • Add 350 µL of Buffer S3 and immediately mix by inverting the tube 4-6 times (do not vortex).
  • Centrifuge for 10min.
  • Transfer carefully the supernatant to a spin column and centrufuge for 1 min.
  • Remove the spin column, discard the flowthrough, and re-insert the spin column to the collection tube.
  • Apply the 750 µL of Buffer PW and centrifuge for 1 min.
  • Remove the spin column, discard the flowthrough, and re-insert the spin column to the collection tube.
  • Discard the flowthrough, and centrifuge for an additional 1 min to remove residual wash buffer.
  • Transfer the spin column to a new 1.5 mL tube.
  • Add 30 µL of MilliQ, let stand for 1 min, and centrifuge for 1 min.


Ethanol Precipitation

Use Ethachinmate (NIPPON GENE、312-01791).

  • Add 3.3 µL of 3M Sodium Acetate (attached with Ethachinmate) into 100µL of DNA solution.
  • Add 1µL of Ethachinmate.
  • Vortex.
  • Add ethanol, 200-250µL.
  • Vortex.
  • Centrifuge at 12000xg for 5min.
  • Precipitation.


Electrophoresis

  • Prepare 200mL of a 1.0% agarose solution:
  • Measure 2.0g agarose into a beaker.
  • Add 200mL 1xTAE buffer.
  • Wrap the top of the beaker with plastic wrap.
  • Punch a hole through the wrap with a pipette tip (To let out steam).
  • Dissolve the agarose by heating in microwave and swirling without boiling.
  • Allow the agarose to cool.
  • Pour the agarose solution into a gel tray on a gel maker.
  • If there is air bubbles, pushing them with a pipette tip.
  • Place comb in the maker.
  • Cover the maker with a plastic wrap.
  • Let stand for about 45min.
  • Remove the comb carefully.
  • Store in the Tupperware in the refrigerator.
  • Place the tray in electrophoresis chamber.
  • Cover the tray with 1xTAE buffer.
  • To prepare samples for electrophoresis, add 1µL of 10x Loading Buffer for every 9µL of DNA solution and mix well.
  • Load 6µL of the DNA solution per well.
  • Electrophoresis at 100V for about 30min until Loading Buffer have migrated approximately three-quarters of the gel.
  • Stain the gel in ethidium bromide.
  • Place a plastic wrap on the transilluminator in the cabinet of Printgraph.
  • Place the gel on the transilluminator.
  • Turn on the transilluminator and confirm the position of the gel.
  • Shoot the picture.
  • Turn off the transilluminator.
  • Dispose of the gel.


Gel Extraction and PCR Purification

Gel Extraction
Use LMP agarose gel

  • Perform electrophoresis using an established protocol, using 1% LMP agarose gel.
  • Visualize and photograph the DNA using a long-wavelength UV lamp and an intercalating dye such as ethidium bromide. To reduce nicking, irradiate the gel for the absolute minimum time as possible. Excise the DNA fragment of interest in a minimal volume of agarose using a clean scalpel or razor blade.
  • Transfer the gel slice to a microcentrifuge tube.
  • If gel volume is less than 200mL, add 600mL of MilliQ. If not, add 900mL of MilliQ.
  • Vortex the mixture and incubate at 70°C for 20 minutes or until the gel slice is completely dissolved.
  • Vortex the tube every few minutes to increase the rate of agarose gel melting.
  • Add same volume of phenol as that of gel solution, and vortex the tube.
  • Centrifuge the tube in a microcentrifuge at 15,000 rpm for 5 min.
  • Transfer the supernatant to new microcentrifuge tube.
  • Centrifuge the tube in a microcentrifuge at 15,000 rpm for 5 min.
  • To avoid with contaminating phenol, transfer the one-eighth from the top of supernatant to new microcentrifuge tube.
  • Add same volume of butanol as that of solution, and vortex the tube.
  • Centrifuge the tube in a desktop small-sized centrifuge for few seconds.
  • Discard the supernatant. Repeat the extraction process by butanol until water layer reduce less than 100 µL.
  • Add 10 µL of 3M Sodium Acetate, 1 µL of glycogen and 250 µL of 99.5% ethanol.
  • Cool the tube at -30°C for 10 minutes.
  • Centrifuge the tube in a microcentrifuge at 15,000 rpm for 10 min.
  • Discard the supernatant.
  • Add 200 µL of 70% ethanol, and Centrifuge the tube in a microcentrifuge at 15,000 rpm for 10 min.
  • Discard the supernatant.
  • Open the cap and centrifuge the tube in a microcentrifuge at 15,000 rpm for 10 min.
  • Add 10 µL of MilliQ, and dissolve the DNA.



Use Promega Wizard SV Gel and PCR Clean-Up System.

  • Perform electrophoresis using an established protocol.
  • Weigh a 1.5 mlL microcentrifuge tube for each DNA fragment to be isolated and record the weight.
  • Visualize and photograph the DNA using a long-wavelength UV lamp and an intercalating dye such as ethidium bromide. To reduce nicking, irradiate the gel for the absolute minimum time possible. Excise the DNA fragment of interest in a minimal volume of agarose using a clean scalpel or razor blade.
  • Transfer the gel slice to the weighed microcentrifuge tube and record the weight. Subtract the weight of the empty tube from the total weight to obtain the weight of the gel slice.
  • Add Membrane Binding Solution at a ratio of 10 µL of solution per 10 mg of agarose gel slice.
  • Vortex the mixture and incubate at 52 °C for 10 minutes or until the gel slice is completely dissolved. Vortex the tube every few minutes to increase the rate of agarose gel melting. Once the agarose gel is melted, the gel will not resolidify at room temperature.
  • Proceed to General.

PCR Purification

  • Amplify target of choice using standard amplification conditions.
  • Add an equal volume of Membrane Binding Solution to the PCR amplification.
  • Proceed to General.

General

  • Place one SV Minicolumn in a Collection Tube for each dissolved gel slice or PCR amplification.
  • Transfer the dissolved gel mixture or prepared PCR product to the SV Minicolumn assembly and incubate for 1 minute at room temperature.
  • Centrifuge the SV Minicolumn assembly in a microcentrifuge at 16,000 g for 1 min. Remove the SV Minicolumn from the Spin Column assembly and discard the liquid in the Collection Tube. Return the SV Minicolumn to the Collection Tube.
  • Wash the column by adding 700 µL of Membrane Wash Solution, previously diluted with 95% ethanol, to the SV Minicolumn. Centrifuge the SV Minicolumn assembly for 1 min at 16,000 g.
  • Remove the SV Minicolumn assembly from the centrifuge, being careful not to wet the bottom of the column with the flowthrough. Empty the Collection Tube and recentrifuge the column assembly for 1 min with the microcentrifuge lid open (or off) to allow evaporation of any residual ethanol.
  • Carefully transfer the SV Minicolumn to a clean 1.5 mL microcentrifuge tube. Apply 30 mL of MilliQ directly to the center of the column without touching the membrane with with the pipette tip. Incubate at room temperature for 1 min. Centrifuge for 1 min at 16,000 g.
  • Discard the SV Minicolumn and store the microcentrifuge tube containing the eluted DNA at 4 °C or 20 °C


Ligation

Use ToYoBo Ligation High Ver.2.

  • Mix the vector DNA and the insert DNA (the vector and the insert at 1 : 5-10).
  • Add a half volume of Ligation High Ver.2 to the DNA solution.
  • Incubate at 16 °C for 1 hour (or at 4 °C for overnight).


Restriction Enzyme Digestion

Use EcoRI, XbaI, SpeI, PstI (TaKaRa).

  • Mix the following.
NameVolume
Sample DNA2 µg
Restriction Enzyme0.5µL
10x Buffer3 µL
(If use XbaI,) 10x BSA3 µL
MilliQup to 30 µL
total30 µL
  • Let stand for 1 hour at 37 °C.

Use EcoRI, XbaI, SpeI, PstI (Promega).

  • Mix the following.
NameVolume
Sample DNA2 µg
Restriction Enzyme0.5µL
10x Buffer3 µL
100x BSA3 µL
MilliQup to 30 µL
total30 µL
  • Let stand for 1 hour at 37 °C.


Media

M9 medium

  • Stir Na2HPO4 6 g, KH2PO4 3 g, NaCl 0.5 g and NH4Cl 1 g with water 500 mL.
  • If you make M9 plates, add agar 15 g.
  • After autoclave, add 1 mL filter sterilized 1 M MgSO4, 5.6 mL 2 M glucose, 0.1 mL 1 M CaCl2, and 1 mL 1 % thiamine-HCl.

If you need, add 10 mL filter sterilized 20 % casamino acid.
LB medium

  • Stir BactoTryptone 2 g, Bacto-yeast extract 1 g, NaCl 1 g and 1M NaOH 200 µL with water 200mL.
  • If you make LB plates, add agar 2 g.
  • Autoclave.

SOB medium

  • Stir BactoTryptone 20 g and Bacto-yeast extract 5 g with water.
  • Add 2 mL 5 M NaCl and 840 µL 3 M KCl and add water up to 1 L.
  • After autoclave, add 10 mL filter sterilized 1 M MgSO4 and 1 M MgCl2.

SOC medium

  • Add 2 M glucose 1 mL to 100 mL SOB.

Plusgrow Medium

  • Stir plusgrow 20 g and with water 500 mL.
  • Autoclave.

YTSS medium

  • Stir BactoTryptone 0.5 g,Bacto-yeast extract 0.8 g and Red sea salt(Red sea) 40g with water 1000mL.
  • Autoclave.


Buffer TB

  • Stir 0.6g PIPES and 30mg CaCl2 with 10 mL water.
  • Add 2.5mL 2M KCl.
  • Add KOH and adjust pH 6.7.
  • Add 0.218g MnCl2・4H2O.
  • Add water up to 20 mL.
  • Filter sterilize.


Solubilization of Antibiotics

  • Mix the following (Final concentration is 50mg/mL).

Ampicillin

Ampicillin1.0g
MilliQ20mL

Kanamycin

Kanamycin0.5g
MilliQ10mL

Chloramphenicol

Chloramphenicol0.5g
99.5% EtOH10mL
  • Dispense 1.1mL of the solution into 1.5mL tubes.
  • Store in the -20°C freezer.


Transformation

  • Unfreeze conpetent cells on ice.
  • Dry a plate by letting the plate upside down and partly open in incubator.
  • Add 1~20µL DNA solution and 10~50µL competent cells to 1.5mL tube, let stand for 30min on ice. If few colonies are observed, increase the amount of the competent cells or DNA, but make the amount of DNA not to get over that of the competent cells.
  • Heatshock for 45s at 42°C.
  • Let stand for 2min on ice.
  • Culture for 1h in preculture medium (LB or SOC medium), and plate by using spreader. Do not heat spreader too much because E.coli will dead for heat.
  • Culture overnight at 37°C.

Sequence

Use Big Dye Terminator 3.1(ABI)

  • Mix the following
5xBuffer1.75µL
Primer (3.2µM)0.5µL
Template Plasmid400ng
Big Dye Terminator 3.10.5µL
MilliQup to 10.5µL
  • Let stand for 1min at 96°C.
  • 30 cycles for 5s at 98°C, for 5s 50°C, and for 4min at 68°C.
  • Add 25µL 100% ethanol and 1µL NAOAC


qRT-PCR

Use QuantiTect SYBR green PCR kit Cat. No. 204143 by QIAGEN

  • Dilute primer to 1.5µM.
  • Dilute RT products.
  • Mix the following;
2x QuantiTect SYBR Green PCR Master Mix22.5µL
1/20xRT products4.5µL
MilliQ9µL
total36µL
  • Mix the reaction mix thoroughly, and dispense 36µL into 96 wells plate.
  • Add primer set 9µL.
  • Mix by inverting and voltex.
  • Dispense 10µL into 384 wells plate and centrifuge.
  • Let stand for 2min at 50°C and for 15min for 95°C.
  • 40 cycles for 15sec at 95°, for 30sec at 60°, and for 1min at 72°C.
  • Let stand for 15sec at 95°.


SDS-PAGE

Make the Running gel

  • Mix the following

20% gel (Running gel) for 1gel

30% AcrylAmide5.3mL
1.5M Tris (pH8.8)2mL
MilliQ500mL
10% SDS80µL
10% APS80µL
TEMED4.8µL
Total8mL
  • Insert Isopropanol on the running gel.
  • Let stand for about 20 min

Make the Stacking Gel

  • Mix the following

Stacking Gel for 1gel

30% AcrylAmide0.41mL
1.5M Tris (pH8.8)0.21mL
MilliQ18.2mL
10% SDS25µL
10% APS25µL
TEMED2.5µL
Total2.5mL
  • Discard the Isopropanol
  • Place the stacking gel on the running gel
  • Place the comb, 12 well
  • Let stand for 20 min
  • Load the gel into the phoresis tank
  • Fill 1xSDS buffer into the phoresis tank
  • If there is air bubbles, pushing them with a syringe.
  • Load the proper amount of protein sample solution per well
  • Electrophoresis at 25mA for about 60 min


Western Blotting

  • Soak the filter paper and the gel in transfer-buffer.
  • Soak the Membrane in Methanol and in transfer-buffer.
  • Put 3 filter paper, membrane, gel, 3 filter paper on the transcription machinary.
  • Transcript at 200 mA for 73 min.
  • Wash the membrane by TBS-T buffer.
  • Let shake for about 10 min 3 times.
  • Block the Membrane for about 60 min.
  • The Blocking reagent is "DS Pharma Biomedical Co..Ltd, Block Ace Powder."
  • Let shake for 60 min.
  • Antibody is "MBL,Anti-His-tag mAb-HRP-DirecT"
  • Make the antibody 5000 times dilution by TBS-T buffer.
  • Mix the antibody with membrane.
  • Let shake for 60 min.
  • Wash the membrane by TBS-T buffer.
  • Let shake for about 10 min.
  • Place the membrane on the Western Lightening.
  • Shoot the picture.
  • Dispose the membrane.

Transmission Electron Microscopy Observation

Ultramicrotome -> LEICA ULTRACUT UCT

Transmission electron microscopy -> JEM-1005X

Prefix solution

Final Conc.Stock Sol.
Glutaraldehyde (20 %)2 %1.25 mL
Phosphate buffer (pH 7.4)0.05 M5 mL
DW 3.75 mL
Total 10 mL

0.1 M Phosphate buffer (pH 7.4)

NaH2PO4·H2O1.38 g
NaH2PO4·H2O14.34 g
DWup to 500 mL

Postfix solution

Final Conc.Stock Sol.
osmic acid1 %0.5 mL
Phosphate buffer0.05 M0.5 mL
Total 1 mL

TAAB EPON812 RESIN KIT

TAAB EPON812 RESIN24 g
TAAB MNA20 g
TAAB DDSA6 g
TAAB DMP-301 g

(Deaerate for 15 minute by Vacuum pumps)

lead citrate (Reynold method)

  • Measure 1.33g lead nitrate and 1.76g sodium citrate into a beaker.
  • Add 30mL DW and shake hard for 1 minute.
  • Let stand the beaker for 30 minute as shaking the tube every few minutes.
  • Add 8mL 1N-NaOH and DW up to 50mL.



  • 1. Pick a single colony from a freshly streaked selective plate and inoculate a culture of about 4mL LB medium containing the appropriate selective antibiotic. Incubate at 160 rpm at 37 °C with vigorous shaking until reaching appropriate concentration.
  • 2. Transfer the 1.5mL cultured medium to microcentrifuge tube.
  • 3. Pellet the bacterial culture by centrifugation for 10 min at 3,000 g in a tabletop centrifuge.
  • 4. Discard the supernatant as much as possible.
  • 5. Add the 1.2mL prefix solution, and resuspent by pipetting.
  • 6. Incubate at 4 °C overnight.
  • 7. Rinse (Centrifugation: 10 min, 3,000 g and resuspention) by 0.1M Phosphate buffer twice.
  • 8. Add 50 µL postfix solution, and incubate on ice for 2 hours.
  • 9. Discard the postfix solution, and add 50 µL 50% ethanol. Incubate on ice for 15 min.
  • 10. Replace the solution with 50 µL 70% ethanol. Incubate at room temperature for 15 min.
  • 11. Replace the solution with 50 µL 90% ethanol. Incubate at room temperature for 15 min.
  • 12. Replace the solution with 50 µL 95% ethanol. Incubate at room temperature for 15 min.
  • 13. Replace the solution with 50 µL 99.5% ethanol. Incubate at room temperature for 15 min.
  • 14. Replace the solution with 50 µL 100% ethanol (using molecular sieve). Incubate at room temperature for 15 min.
  • 15. Replace the solution with 50 µL 100% ethanol . Incubate at room temperature for 15 min.
  • 16. Replace the solution with 50 µL propylene oxide. Incubate at room temperature for 15 min.
  • 17. Replace the solution with 50 µL propylene oxide. Incubate at room temperature for 15 min.
  • 18. Replace the solution with 50 µL half and half mixture of propylene oxide and Epon 812 Resin Kit mixed liquor. Incubate at room temperature for 1 hour.
  • 19. Replace the solution with 50 µL Epon 812 Resin Kit mixed liquor. Incubate in the desiccator at 4°C overnight.
  • 20. Incubate at 60°C for 2 days.
  • 21. Trim the sample into 0.5~2mm square and slice into 1 micro meter thick by a glass knife.
  • 22. Observe the sections, and trim smaller to make ultra-thin section.
  • 23. To make the smooth aspect, slice into 1 micro meter thick by a new glass nife.
  • 24. Slice into 90~100nm thick by diamond knife.
  • 25. Collect the section by collodion coated mesh (VECO GRID ,NISSIN EM ,Japan).
  • 26. Stain the sample by 1% uranyl acetate for 30 min.
  • 27. Stain the sample by lead citrate for 3 min.
  • 28. Observe by TEM, and take the photograph.

High Performance Liquid Chromatograpy

  • Culture
  • 1. Cultivate E.coli in LB medium till OD600 becomes 0.8. LB contains 1% Methionine and 1mM 2-oxoglutarate.
  • 2. When OD600 become 0.8, add IPTG to medium for its density become 10mM
  • 3.Cultivate E.coli for 14 hours.
  • HPLC
  • 1. Centrifuge 1mL of culture of E.coli 120rpm,2min to pelletize cells.
  • 2. Add 250μL of Lysis Buffer(50mM Tris, 1mM EDTA, 1mM DTT).
  • 3. Sonicate 30sec 3times.
  • 4. Centrifuge 15000rpm 15min at 4℃.
  • 5. Apply the supernatant to 3K cut off membrane(Amicon Ultra-0.5 mL Centrifugal Filters for Protein Purification and Concentration,Merck Millipore)15000rpm 30min at 4℃.
  • 6. 10 fold dilute and add equivalent DMB Solution(composition will show below;) and incubate 2h30min at 50℃.
  • DMB Solution
  • 3.15mg DMB
  • 160.8μL Acetic acid
  • 105.6μL 2-mercaptoethanol
  • 18μL 2M Na-hydrosulfonide
  • 641.6μL Distilled water
  • 7. 10 fold dilute and inject 3μL of the sample into column. HPLC condition will show below;
  • HPLC: SHIMADZU LC-10A
  • Column: ZORBAX Eclipse® XDB-C18
  • Total Flow: 0.5mL/min
  • Gradient: Pump A: acetonitrile: MeOH: H2O=9:7:84 Pump B: 50:7:43
  • 0:01 B Percentage=5%
  • 0:01 Total flow=0.5mL/min
  • 0:01 Start
  • 20:00 B Percentage=20%
  • 25:00 B Percentage=100%
  • 30:00 B Percentage=100%
  • 35:00 B Percentage=5%
  • 45:00 Stop

DMS Detecting Tube Assay

  • 1.Cultivate E.coli in LB medium for hours.
  • In the experimental, medium contains 1mM IPTG, 1nM DMSP, and E.coli which was transformed DddD generator.
  • In the positive control, medium contains 1mM IPTG, 1nM DMSP, 1mM DMS and E.coli which was transformed DddD generator.
  • In the negative control 1, medium contains 1mM IPTG, 1mM DMSP and E.coli which wasn't transformed.
  • In the negative control 2, medium contains 1mM IPTG and E.coli which was transformed DddD generator.
  • In the negative control 3, medium contains 1mM DMSP and E.coli which was transformed DddD generator.
  • Falcon tube in which samples incubated was sealed by Parafilm.


  • 2.After cultivating E.coli, sample 30mL vapor in the syringe and inject it in DMS Detector tube.
  • We used Tokyo Gas Engineering Co.,Ltd, DMS Detecting tube .