Difference between revisions of "Part:BBa K3457009"

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==iGEM 2020 QHFZ-China, new documentation (For Bronze)==
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<h3><b>Group: QHFZ-China iGEM 2020</b></h3>
+
__NOTOC__
 +
<partinfo>BBa_K3457009 short</partinfo>
 +
 
 +
<p>&nbsp;&nbsp;&nbsp;&nbsp;This biological part is the CDS sequence of Cytosolic-abundant heat soluble protein 89226, also called CAHS 89226. It is a kind of Tardigrade intrinsically Disordered Protein (TDP). It is a heat soluble protein found from Tardigrade <i>Hypsibius dujardini</i> in 2017 <sup>[1]</sup>. Tardigrade, also called water bear, is a kind of tenacious organism. It can survive extreme environment, such as desiccation, freeze and vacuum. The super capacity of Tardigrade partially owes to TDPs. CAHS 89226 has been proven to protect the activity of purified proteins <sup>[1]</sup>. Here we found that expressing this protein can help bacteria survive the freeze-drying process and then the resultant dry bacteria powder can be stored for a long time at room temperature. </p>
 +
 
 +
===Contribution===
 +
<h2><b>Group: QHFZ-China iGEM 2020</b></h2>
 
<h3><b>Author: Yixian Yang</b></h3>
 
<h3><b>Author: Yixian Yang</b></h3>
<p>&nbsp;&nbsp;&nbsp;&nbsp; We measured [https://parts.igem.org/Part:BBa_J23100 BBa_J23100], [https://parts.igem.org/Part:BBa_J23107 BBa_J23107] and [https://parts.igem.org/Part:BBa_J23109 BBa_J23109] as a strong, moderate and weak promoter respectively in 2020. For all the experiments below, we use <i>E. coli</i> BL21(DE3) strain.</p>
+
<h3><b>Design</b></h3>
<h3>Part 1: Measurement with a reprter, sfGFP</h3>
+
[[File:T--QHFZ-China--89226 basic design.png|400px|thumb|left|Figure 1. The Schematic cartoon of the DNA construct of BBa_K3457009.]]
<h4>Description</h4>
+
 
<p>&nbsp;&nbsp;&nbsp;&nbsp;First, we measured the strength of the promoter by sfGFP [https://parts.igem.org/Part:BBa_K3457015 BBa_K3457015].</p>
+
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;This part is the CDS of CAHS 89226. We obtained the sequence from the research paper in 2017 <sup>[1]</sup>. Then with the help of a company, we optimized the sequence, so that the part is suitable to work in <i>E. coli</i> and there is no biobrick restriction enzyme cutting site in it. Moreover, we added an 6x His tag at the N-terminal of CAHS 89226, so it can be easily detected by Western Blot and be purified by Ni-chelating affinity chromatography (Fig.1). This year, the part is used in the composite part [https://parts.igem.org/Part:BBa_K3457032 BBa_K3457032]</p>
<h4>Protocol</h4>
+
 
<p>&nbsp;&nbsp;&nbsp;&nbsp;The gene circuit we used is as below:</p>
+
<h3><b>Documentation:</b></h3>
[[File:T--QHFZ-China--J2310-1.png|600px|thumb|left|Figure 1. The Schematic cartoon of the DNA construct to test J23100 /
+
<h4><b>Introduction: </b></h4>
J23107 / J23109 with sfGFP.]]
+
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;This year, we tried to introduce a new biopreservation method. We used freeze-drying to make the engineered into dry powder. Then the powder can be stored at room temperature for a long time. This method can make the storage of bacteria get rid of ultra-low temperature freezer, so that it will promote the practical application of engineered bacteria out of laboratory. However, the stresses during freeze-drying and subsequent dry storage, including freeze, dry and vacuum, are lethal to bacteria. We use TDPs, including CAHS 89226, to help bacteria survive the situation. </p>
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;The protocol is as below: <br>
+
 
    (1) Pick clones which are in good condition and put them into 500 μL LB medium containing antibiotics. Shake them to
+
<h4><b>Protocol: </b></h4>
    grow at 37℃ for 5~7 hours until the bacteria solution becomes turbid. <br>
+
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;To test the effect of CAHS 89226, we modified a frequently and widely used vector, pet28a+ and put this part into it (Fig. 2). Then we transformed the plasmid into <i>E. coli</i> BL21 strain. </p>
    (2) Add 2mM iPTG into 3 mL LB medium containing antibiotics. Add 3 μL of the bacteria solution mentioned in step 1
+
 
    to dilute the bacteria by the ratio of 1:1000. Shake the solution to grow the bacteria at 37℃ overnight.<br>
+
[[File:T--QHFZ-China--pet28am.png|400px|thumb|left|Figure 2. The Schematic cartoon of the vector.]]
    (3) The bacteria solution was centrifuged and the LB medium was removed. Then the bacteria was resuspended by PBS.
+
 
    100 μL such solution was put into a well of a 96-well palte. The GFP fluorescence and OD<sub>600</sub> were detected
+
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;Then we used the following protocols to verify its function (Fig. 3): </p>
    by a microplate readers (Bio-Teck). The parameters are: exciting light: 488 nm, light reception: 520 nm, gain: 50.
+
 
    <br>
+
[[File:T--QHFZ-China--freeze-dry protocol.jpg|400px|thumb|left|Figure 3. Experiment protocol.]]
    (4) The value of PBS was deducted from the result above. GFP / OD<sub>600</sub> was calculated.<br>
+
 
</p>
+
<h4>Result</h4>
+
[[File:T--QHFZ-China--sfGFP.jpg|600px|thumb|left|Figure 2. sfGFP was expressed with J23100 / J23107 / J23109.]]
+
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;We set the strehgth of J23109 as 1. The relative strengths of J23107 and J23109 were 4.4 and
+
    12.0. Though they are not the same as the data at the top of this page, they worked well anb the strength order of
+
    the three promoters was accordance was consistent with other people's data. The difference may owe to the certain
+
    gene circuit and protocol. </p>
+
<h3>Part 2: Measurement with CHAS 106094</h3>
+
<h4>Description</h4>
+
<p>&nbsp;&nbsp;&nbsp;&nbsp;Second, we measured the strength of the promoter by CAHS 106094
+
    [https://parts.igem.org/Part:BBa_K3457012 BBa_K3457012]. This year, we used CAHS 106094 to protect bacteria from
+
    freeze-drying and dry storage. We used different promoters to adjust the expression level of CAHS 106094, to study
+
    the relationship between the survival rate and CAHS 106094 expression level.</p>
+
<h4>Protocol</h4>
+
<p>&nbsp;&nbsp;&nbsp;&nbsp;The gene circuit we used is as below:</p>
+
[[File:T--QHFZ-China--J2310-2.png|600px|thumb|left|Figure 3. The Schematic cartoon of the DNA construct to test J23100 /
+
J23107 / J23109 with sfGFP.]]
+
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;The protocol is as below: </p>
+
[[File:T--QHFZ-China--freeze-dry protocol.jpg|600px|thumb|left|Figure 4. Experiment protocol.]]
+
 
<p style="clear:left;">
 
<p style="clear:left;">
    【Day 1】Induction culture<br>
+
【Day 1】Induction culture<br>
    (1) Pick clones which are in good condition and put them into 500 μL LB medium containing antibiotics. Shake them to
+
(1) Pick clones which are in good condition and put them into 500 μL LB medium containing antibiotics. Shake them to grow at 37℃ for 5~7 hours until the bacteria solution becomes turbid. <br>
    grow at 37℃ for 5~7 hours until the bacteria solution becomes turbid. <br>
+
(2) Add 2mM iPTG into 3 mL LB medium containing antibiotics. Add 3 μL of the bacteria solution mentioned in step 1 to dilute the bacteria by the ratio of 1:1000. Shake the solution to grow the bacteria at 37℃ overnight.<br>
    (2) Add 2mM iPTG into 3 mL LB medium containing antibiotics. Add 3 μL of the bacteria solution mentioned in step 1
+
【Day 2】Freeze-dried<br>
    to dilute the bacteria by the ratio of 1:1000. Shake the solution to grow the bacteria at 37℃ overnight.<br>
+
(1) If fluorescence induced by the iPTG is detectable in the control group (GFP), continue conducting the experiment.<br>
    【Day 2】Freeze-dried<br>
+
(2) Use spectrophotometer to measure the OD<sub>600</sub> of the bacteria solution, OD<sub>600</sub> = 1 equals to 10<sup>9</sup> cells. If the OD<sub>600</sub> value is between 0.1 and 1, There is a linear relationship between OD<sub>600</sub> and bacterial density. Calculate the volume of bacterial solution for 10<sup>9</sup> cells by using the formula V = 100 / (OD<sub>600</sub> × Dilution ratio).<br>
    (1) If fluorescence induced by the iPTG is detectable in the control group (GFP), continue conducting the
+
(3) Take out a measured amount of 10<sup>9</sup> cells and centrifuge it at 8000 rpm for 3 min. Then pour out the supernatant.<br>
    experiment.<br>
+
(4) Resuspend the bacteria in a 15 mL tube with pre-refrigerated 100 μL 3% glucose solution.<br>
    (2) Use spectrophotometer to measure the OD<sub>600</sub> of the bacteria solution, OD<sub>600</sub> = 1 equals to
+
(5) Take off the cover of the tube and put the bacteria into the cold trap. Open the compressor of the lyophilization machine and freeze the shake tube for 2 h at -70℃.<br>
    10<sup>9</sup> cells. If the OD<sub>600</sub> value is between 0.1 and 1, There is a linear relationship between
+
(6) Put the caky bacteria solution into the drying chamber of the lyophilization machine. Open the vacuum pump to dry it in vacuum for 6h at 1 Pa vacuum degree.<br>
    OD<sub>600</sub> and bacterial density. Calculate the volume of bacterial solution for 10<sup>9</sup> cells by using
+
(7) Turn off the vacuum pump, place it at seal box filled with silica-gel desiccant a for 2 days at room temperature.<br>
    the formula V = 100 / (OD<sub>600</sub> × Dilution ratio).<br>
+
【Day 3】Room temperature storage<br>
    (3) Take out a measured amount of 10<sup>9</sup> cells and centrifuge it at 8000 rpm for 3 min. Then pour out the
+
【Day 4】Detect the survival rate<br>
    supernatant.<br>
+
(1) Add 1 mL of sterile water to the tube, vortex for 15 s, placed it at room temperature for 10 min.<br>
    (4) Resuspend the bacteria in a 15 mL tube with pre-refrigerated 100 μL 3% glucose solution.<br>
+
(2) Adjust the density of the bacteria solution by gradient dilution, then spread 100 μL of the bacteria solution on the LB plate.<br>
    (5) Take off the cover of the tube and put the bacteria into the cold trap. Open the compressor of the
+
(3) If the density above is not suitable, take 100μL of the solution and spread it on the LB plate after several gradient dilutions.<br>
    lyophilization machine and freeze the shake tube for 2 h at -70℃.<br>
+
(4) Culture the bacteria overnight at 37℃.<br>
    (6) Put the caky bacteria solution into the drying chamber of the lyophilization machine. Open the vacuum pump to
+
【Day 5】Cell Count<br>
    dry it in vacuum for 6h at 1 Pa vacuum degree.<br>
+
(1) Take out the LB plate and take photos to record experimental results.<br>
    (7) Turn off the vacuum pump, place it at seal box filled with silica-gel desiccant a for 2 days at room
+
(2) Use the automatic cell counting function of Image J to count the colone number on the LB plate, then compare the results between each group.
    temperature.<br>
+
    【Day 3】Room temperature storage<br>
+
    【Day 4】Detect the survival rate<br>
+
    (1) Add 1 mL of sterile water to the tube, vortex for 15 s, placed it at room temperature for 10 min.<br>
+
    (2) Adjust the density of the bacteria solution by gradient dilution, then spread 100 μL of the bacteria solution on
+
    the LB plate.<br>
+
    (3) If the density above is not suitable, take 100μL of the solution and spread it on the LB plate after several
+
    gradient dilutions.<br>
+
    (4) Culture the bacteria overnight at 37℃.<br>
+
    【Day 5】Cell Count<br>
+
    (1) Take out the LB plate and take photos to record experimental results.<br>
+
    (2) Use the automatic cell counting function of Image J to count the colone number on the LB plate, then compare the
+
    results between each group.<br>
+
 
</p>
 
</p>
<h4>Result</h4>
 
[[File:T--QHFZ-China--J2310-3.png|600px|thumb|left|Figure 5. The Cfu of bacteria expressing CAHS 106094 after
 
freeze-drying with J23100 / J23107 / J23109.]]
 
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;As expected, J23100 is the strongest promoter and it gave the best survival rate. J23107 is
 
    the second and J23109 seemed too weak to express enough CAHS 106094. In conclusion, J23100 and J23107 is effective
 
    in this situation, but J23109 is not.</p>
 
    <!-- The end of QHFZ-China 2020-->
 
  
<span id="UT_Austin_2019"><br><br><br><br><br></span>
+
<h4><b>Results:</b></h4>
 +
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;First, by a reporter, sfGFP, we confirmed that the plasmid can normally expressed exogenous proteins in <i>E. coli</i> BL21 strain (Fig. 4). Via SDS-PAGE, we observed the band of CAHS 89226, further verified the successfully expression (Fig.5). </p>
 +
 
 +
[[File:T--QHFZ-China--pet28am sfGFP.png|400px|thumb|left|Figure 4. Via a reporter, sfGFP, the expression function of the modified pet28a vector was verified.]]
 +
[[File:T--QHFZ-China--TDP SDS.png|400px|thumb|left|Figure 5. CAHS 89226 was expressed as expected.]]
 +
 
 +
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;Then, by freeze-drying and recover experiment, we found that compared with the control group (sfGFP), the bacteria expressing CAHS 89226 had a better survival rate (Fig. 6). We placed an enlarged picture as well (Fig. 7). </p>
 +
 
 +
[[File:T--QHFZ-China--TDP freeze-dry.png|400px|thumb|left|Figure 6. CAHS 89226 protected bacteria during freeze-drying and subsequent dry storage.]]
 +
[[File:T--QHFZ-China--89226.png|400px|thumb|left|Figure 7. An enlarged picture of fig. 6.]]
 +
 
 +
<h4 style="clear:left;"><b>Summary: </b></h4>
 +
<p style="clear:left;">&nbsp;&nbsp;&nbsp;&nbsp;CAHS 89226 helps the bacteria survive freeze-drying and subsequent dry storage. To achieve that, you need only to transform the sequence into your bacteria. You can also use the part to express and purify CAHS 89226 through Ni-chelating affinity chromatography. The purified CAHS 89226 can be used to protect protein products. </p>
 +
 
 +
<h4><b>Reference: </b></h4>
 +
<p style="clear:left;">[1] Boothby, T.C., Tapia, H., Brozena, A.H., Piszkiewicz, S., Smith, A.E., Giovannini, I., Rebecchi, L., Pielak, G.J., Koshland, D., and Goldstein, B. (2017). Tardigrades Use Intrinsically Disordered Proteins to Survive Desiccation. Mol Cell 65, 975-984 e975.</p>
 +
 
 +
 
 +
 
 +
<!-- Add more about the biology of this part here
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===Usage and Biology===
 +
 
 +
 
 +
<!-- -->
 +
<span class='h3bb'><b>Sequence and Features</b></span>
 +
<partinfo>BBa_K3457009 SequenceAndFeatures</partinfo>
 +
 
 +
 
 +
<!-- Uncomment this to enable Functional Parameter display
 +
===Functional Parameters===
 +
<partinfo>BBa_K3457009 parameters</partinfo>
 +
<!-- -->

Revision as of 00:41, 27 October 2020


CAHS 89226 with a 6X His tag

    This biological part is the CDS sequence of Cytosolic-abundant heat soluble protein 89226, also called CAHS 89226. It is a kind of Tardigrade intrinsically Disordered Protein (TDP). It is a heat soluble protein found from Tardigrade Hypsibius dujardini in 2017 [1]. Tardigrade, also called water bear, is a kind of tenacious organism. It can survive extreme environment, such as desiccation, freeze and vacuum. The super capacity of Tardigrade partially owes to TDPs. CAHS 89226 has been proven to protect the activity of purified proteins [1]. Here we found that expressing this protein can help bacteria survive the freeze-drying process and then the resultant dry bacteria powder can be stored for a long time at room temperature.

Contribution

Group: QHFZ-China iGEM 2020

Author: Yixian Yang

Design

Figure 1. The Schematic cartoon of the DNA construct of BBa_K3457009.

    This part is the CDS of CAHS 89226. We obtained the sequence from the research paper in 2017 [1]. Then with the help of a company, we optimized the sequence, so that the part is suitable to work in E. coli and there is no biobrick restriction enzyme cutting site in it. Moreover, we added an 6x His tag at the N-terminal of CAHS 89226, so it can be easily detected by Western Blot and be purified by Ni-chelating affinity chromatography (Fig.1). This year, the part is used in the composite part BBa_K3457032

Documentation:

Introduction:

    This year, we tried to introduce a new biopreservation method. We used freeze-drying to make the engineered into dry powder. Then the powder can be stored at room temperature for a long time. This method can make the storage of bacteria get rid of ultra-low temperature freezer, so that it will promote the practical application of engineered bacteria out of laboratory. However, the stresses during freeze-drying and subsequent dry storage, including freeze, dry and vacuum, are lethal to bacteria. We use TDPs, including CAHS 89226, to help bacteria survive the situation.

Protocol:

    To test the effect of CAHS 89226, we modified a frequently and widely used vector, pet28a+ and put this part into it (Fig. 2). Then we transformed the plasmid into E. coli BL21 strain.

Figure 2. The Schematic cartoon of the vector.

    Then we used the following protocols to verify its function (Fig. 3):

Figure 3. Experiment protocol.

【Day 1】Induction culture
(1) Pick clones which are in good condition and put them into 500 μL LB medium containing antibiotics. Shake them to grow at 37℃ for 5~7 hours until the bacteria solution becomes turbid.
(2) Add 2mM iPTG into 3 mL LB medium containing antibiotics. Add 3 μL of the bacteria solution mentioned in step 1 to dilute the bacteria by the ratio of 1:1000. Shake the solution to grow the bacteria at 37℃ overnight.
【Day 2】Freeze-dried
(1) If fluorescence induced by the iPTG is detectable in the control group (GFP), continue conducting the experiment.
(2) Use spectrophotometer to measure the OD600 of the bacteria solution, OD600 = 1 equals to 109 cells. If the OD600 value is between 0.1 and 1, There is a linear relationship between OD600 and bacterial density. Calculate the volume of bacterial solution for 109 cells by using the formula V = 100 / (OD600 × Dilution ratio).
(3) Take out a measured amount of 109 cells and centrifuge it at 8000 rpm for 3 min. Then pour out the supernatant.
(4) Resuspend the bacteria in a 15 mL tube with pre-refrigerated 100 μL 3% glucose solution.
(5) Take off the cover of the tube and put the bacteria into the cold trap. Open the compressor of the lyophilization machine and freeze the shake tube for 2 h at -70℃.
(6) Put the caky bacteria solution into the drying chamber of the lyophilization machine. Open the vacuum pump to dry it in vacuum for 6h at 1 Pa vacuum degree.
(7) Turn off the vacuum pump, place it at seal box filled with silica-gel desiccant a for 2 days at room temperature.
【Day 3】Room temperature storage
【Day 4】Detect the survival rate
(1) Add 1 mL of sterile water to the tube, vortex for 15 s, placed it at room temperature for 10 min.
(2) Adjust the density of the bacteria solution by gradient dilution, then spread 100 μL of the bacteria solution on the LB plate.
(3) If the density above is not suitable, take 100μL of the solution and spread it on the LB plate after several gradient dilutions.
(4) Culture the bacteria overnight at 37℃.
【Day 5】Cell Count
(1) Take out the LB plate and take photos to record experimental results.
(2) Use the automatic cell counting function of Image J to count the colone number on the LB plate, then compare the results between each group.

Results:

    First, by a reporter, sfGFP, we confirmed that the plasmid can normally expressed exogenous proteins in E. coli BL21 strain (Fig. 4). Via SDS-PAGE, we observed the band of CAHS 89226, further verified the successfully expression (Fig.5).

Figure 4. Via a reporter, sfGFP, the expression function of the modified pet28a vector was verified.
Figure 5. CAHS 89226 was expressed as expected.

    Then, by freeze-drying and recover experiment, we found that compared with the control group (sfGFP), the bacteria expressing CAHS 89226 had a better survival rate (Fig. 6). We placed an enlarged picture as well (Fig. 7).

Figure 6. CAHS 89226 protected bacteria during freeze-drying and subsequent dry storage.
Figure 7. An enlarged picture of fig. 6.

Summary:

    CAHS 89226 helps the bacteria survive freeze-drying and subsequent dry storage. To achieve that, you need only to transform the sequence into your bacteria. You can also use the part to express and purify CAHS 89226 through Ni-chelating affinity chromatography. The purified CAHS 89226 can be used to protect protein products.

Reference:

[1] Boothby, T.C., Tapia, H., Brozena, A.H., Piszkiewicz, S., Smith, A.E., Giovannini, I., Rebecchi, L., Pielak, G.J., Koshland, D., and Goldstein, B. (2017). Tardigrades Use Intrinsically Disordered Proteins to Survive Desiccation. Mol Cell 65, 975-984 e975.


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]