Difference between revisions of "Team:OUC-China/Project/Overview"

Latest revision as of 22:20, 18 September 2015

<!DOCTYPE html> Team:OUC-China Project_Overview

Overview

Background

Signal regulation is the fundation to control bacteria. Gene regulation has typically employed chemically mediated expression systems, which are slow, taking on the order of hours to switch on gene expression and up to days to switch off as drugs are eliminated [1]. Though genetically encoded light sensors have provided a robust and convenient way to spatiotemporally control gene expression [2], light delivery has limited penetration. Means for temporally regulating gene expression with minimal perturbation is in demand [3].

Fig.1. Schema of genetically encoded ferritin to generate iron oxide nanoparticles to open the temperature-sensitive channel TRPV1 in response to radio waves [3]

Low and medium electromagnetic wave can penetrate deep tissues with minimal energy absorption [4]. However, induced by electromagnetic signal, magnetic nanoparticles can absorb energy and heat [5]. Properties of electromagnetic wave and magnetic particles provide possibilities of remote regulation.

Sarah A Stanley et al. [3]have successfully constructed remote regulation system in mice (Fig.1.), based on ferritin-TRPV1 system. Ferritin is a kind of iron-storage protein in organisms, which could synthesize ferric oxihydroxide core in its hollow protein shell [6]. TRPV1 is a kind of temperature-sensitive channel: When local temperature rises, TRPV1 gates calcium to activate a Ca²⁺ sensitive promoter [4]. However, TRPV1 has limited use in Prokaryote. Thus, we designed Magthermo coli—a platform for remote regulation of gene expression by electromagnetic signal in E.coli.

Overview

How does it work?

There are two main components in our magthermo coli: magnetic receiver & thermosensitive regulator. Inducing with electromagnetic field, magnetic receiver will heat, raising the ambient temperature. In response to the change of temperature, thermosensitive regulator will initiate the downstream gene (GFP for example) expression.

Magnetic Receiver

Magnetic nanoparticles can serve as a nanosource of heat [5]. That’s why we choose Ferritin magnetic receiver: Ferritin is a kind of iron-storage protein in many organisms, which could synthesize ferric oxihydroxide core in its hollow protein shell [6] (Fig.2.). Once exposed to electromagnetic field, the ferric oxihydroxide core will heat, raising the ambient temperature.

Fig.2. Schema of ferritin

Thermosensitive Regulator

For thermosensitive regulator, we chose RNA thermometer and designed a thermosensitive T7 RNA polymerase. RNA thermometer is a structured RNA which could expose SD sequences only at appropriate temperature [7] (Fig.3.). Thermosensitive T7 RNA polymerase is a T7 RNA polymerase interrupted by a temperature-sensitive intein. Temperature-sensitive Intein is a kind of polypeptide that could self-splice and ligate it’s flanking polypeptides at specific temperature. Thus, interrupted T7 RNA polymerase can initiate the downstream signal only at appropriate temperature[8] (Fig.4.).

Fig.3. RNA Thermometer

Fig.4. Thermosensitive T7 RNA polymerase

Measuring Technique

In magnetic-receiver section:

(1)We found it complicated and costly to measure magnetism of E.coli, thus, constructed a device for easy measure of magnetism—Captor (Fig.5.).
(2)During verification for in vivo mineralization of ferritin, we found little literatures offering accurately detecting method. Thus, we referenced method in vitro[9] and successfully detected iron core in ferritin after in vivo mineralization.
(3)To supply our modeling with concentration of ferritin per cell, we explored a method for valuing protein concentration per cell, and tried to make it more convenient.

In thermosensitive-regulator section:

(1)We explored the measurement method to identify the efficiency of thermosensitive regulator under heat stress.
(2)During testing pBAD, we found it inconvenient to take photos of different plates or compare them. Thus, we extended the function of Captor, and made it convenient for testing optimal inducement concentration on plates (Fig.6.).

Fig.5. Captor—for easy measure of magnetism

Fig.6. Captor—for fluorescence detection on plate

References

[1] R, Bocker, C J, Estler, M, Maywald, et al. Comparison of distribution of doxycycline in mice after oral and intravenous application measured by a high-performance liquid chromatographic method.[J]. Arzneimittelforschung, 1981, 31(12):2116-2117.
[2] Xue, Wang, Xianjun, Chen, Yi, Yang. Spatiotemporal control of gene expression by a light-switchable transgene system.[J]. Nature Methods, 2012, 9(3):266-9.
[3] Stanley S A, Sauer J, Kane R S, et al. Remote regulation of glucose homeostasis in mice using genetically encoded nanoparticles.[J]. Nature Medicine, 2015, 21(1):92-98.
[4] Stanley S A, Gagner J E, Shadi D, et al. Radio-wave heating of iron oxide nanoparticles can regulate plasma glucose in mice.[J]. Science, 2012, 336(6081):604-.
[5]Jean-Paul, Fortin, Claire, Wilhelm, Jacques, Servais, et al. Size-Sorted Anionic Iron Oxide Nanomagnets as Colloidal Mediators for Magnetic Hyperthermia[J]. J.am.chem.soc, 2007, 129(9):2628-2635.
[6]Bou-Abdallah F, Yang H, Awomolo A, et al. Functionality of the Three-Site Ferroxidase Center of Escherichia coli Bacterial Ferritin (EcFtnA)[J]. Biochemistry, 2013, 53(3):483-495.
[7] https://2008.igem.org/Team:TUDelft
[8] Liang R, Liu X, Liu J, et al. A T7-expression system under temperature control could create temperature-sensitive phenotype of target gene in Escherichia coli.[J]. Journal of Microbiological Methods, 2007, 68(3):497-506.
[9] Cai Y, Cao C, He X, et al. Enhanced magnetic resonance imaging and staining of cancer cells using ferrimagnetic H-ferritin nanoparticles with increasing core size.[J]. International Journal of Nanomedicine, 2015, 10(default):2619-34.

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+                     <a href="https://2015.igem.org/Team:OUC-China"><img src="https://static.igem.org/mediawiki/2015/4/4b/OUC-China-Team_Logo.png" alt="" class="img-responsive"></a>
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                  <span class="menu"> Menu</span>
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                              <ul class="dropdown2">
                                  <li><a href="https://2015.igem.org/Team:OUC-China/Project/Overview">Overview</a></li>
-                                 <li><a href="#">Magnetic Receiver</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Project/Magnetic_Receiver">Magnetic Receiver</a></li>
-                                 <li><a href="#">Thermosensitive Regulator</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Project/Thermosensitive_Regulator">Thermosensitive Regulator</a></li>
-                                 <li><a href="#">Captor</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Project/Captor">Captor</a></li>
-                                 <li><a href="#">Results</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Project/Results">Results</a></li>
-                                 <li><a href="#">Parts</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Parts">Parts</a></li>
-                                 <li><a href="#">Achievements</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Project/Achievements">Achievements</a></li>
                              </ul>
                          </li>
-                         <li class="dropdown1"><a href="#">INTERLAB</a>
+                         <li class="dropdown1"><a href="https://2015.igem.org/Team:OUC-China/Interlab">INTERLAB</a>
                          </li>
                          <li class="dropdown1"><a class="down-scroll" href="#">MODELING</a>
                              <ul class="dropdown2">
-                                 <li><a href="#">Overview</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Modeling">Overview</a></li>
-                                 <li><a href="#">Magnetic Receiver</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Modeling/Magnetic_Receiver">Magnetic Receiver</a></li>
-                                 <li><a href="#">Heating</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Modeling/Heating">Heating</a></li>
-                                 <li><a href="#">Thermosensitive Regulator</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Modeling/Thermosensitive_Regulator">Thermosensitive Regulator</a></li>
                              </ul>
                          </li>
-                         <li class="dropdown1"><a class="down-scroll" href="">HUMAN PRACTISE</a>
+                         <li class="dropdown1"><a class="down-scroll"  href="#">HUMAN PRACTISE</a>
                              <ul class="dropdown2">
-                                 <li><a href="#">Overview</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Practices">Overview</a></li>
-                                 <li><a href="#">Safety</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Human_Practice/Safety">Safety</a></li>
-                                 <li><a href="#">Transportation</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Human_Practice/Education">Education</a></li>
-                                 <li><a href="#">Education</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Human_Practice/Transportation">Transportation</a></li>
-                                 <li><a href="#">Communication</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Human_Practice/Communication">Communication</a></li>
-                                 <li><a href="#">Guide of Logo Design</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Human_Practice/Guide_Of_Logo_Design">Guide of Logo Design</a></li>
                              </ul>
                          </li>
-                         <li class="dropdown1"><a class="down-scroll" href="">NOTE BOOK</a>
+                         <li class="dropdown1"><a class="down-scroll" href="#">NOTE BOOK</a>
                              <ul class="dropdown2">
-                                 <li><a href="#">Lab Journal</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Note_Book/Lab_Journal">Lab Journal</a></li>
-                                 <li><a href="#">Protocol</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Note_Book/Protocol">Protocol</a></li>
                              </ul>
                          </li>
-                         <li class="dropdown1"><a class="down-scroll" href="">TEAM</a>
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                              <ul class="dropdown2">
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-                                 <li><a href="#">Attribution</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Attributions">Attribution</a></li>
-                                 <li><a href="#">Collaboration</a></li>
+                                 <li><a href="https://2015.igem.org/Team:OUC-China/Collaborations">Collaboration</a></li>
                              </ul>
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                  <!-- 文字 -->
                  <p>
-                 Gene regulation has typically employed chemically mediated expression systems, which are slow, taking on the order of hours to switch on gene expression and up to days to switch off as drugs are eliminated [1]. Though genetically encoded light sensors have provided a robust and convenient way to spatiotemporally control gene expression [2], light delivery has limited penetration. Means for temporally regulating gene expression with minimal perturbation is in demand [3].
+                 Signal regulation is the fundation to control bacteria. Gene regulation has typically employed chemically mediated expression systems, which are slow, taking on the order of hours to switch on gene expression and up to days to switch off as drugs are eliminated [1]. Though genetically encoded light sensors have provided a robust and convenient way to spatiotemporally control gene expression [2], light delivery has limited penetration. Means for temporally regulating gene expression with minimal perturbation is in demand [3].
                  </p>
                  <div class="row">
                      <div class="col-md-5">
-                         <div style="border:solid 1px #9b9898;background-color:#e2e1e1;padding:0px 7px">
+                         <div style="border:solid 1px #9b9898;background-color:#e2e1e1;padding:0px 7px" class="adjust-ipad1">
                              <img src="https://static.igem.org/mediawiki/2015/9/9c/OUC-China_project_overview_1.png" alt="" class="img-responsive">
-                             <span><center>Fig.1. Schema of genetically encoded ferritin to generate iron oxide nanoparticles to open the temperature-sensitive channel TRPV1 in response to radio waves [3]</center></span>
+                             <span><center class="img-example">Fig.1. Schema of genetically encoded ferritin to generate iron oxide nanoparticles to open the temperature-sensitive channel TRPV1 in response to radio waves [3]</center></span>
                          </div>
                      </div>
@@ Line 134: / Line 144: @@
                          </p>
                          <p>
-                             Sarah A Stanley et al. [3]have successfully constructed remote regulation system in mice (Fig.1.), based on ferritin-TRPV1 system. Ferritin is a kind of iron-storage protein in organisms, which could synthesize ferric oxihydroxide core in its hollow protein shell [6]. TRPV1 is a kind of temperature-sensitive channel: When local temperature rises, TRPV1 gates calciumto activate a Ca2+-sensitive promoter [4]. However, TRPV1 has limited use in Prokaryote. Thus, we designed Magthermo coli—a platform for remote regulation of gene expression by electromagnetic signal in E.coli.
+                             Sarah A Stanley et al. [3]have successfully constructed remote regulation system in mice (Fig.1.), based on ferritin-TRPV1 system. Ferritin is a kind of iron-storage protein in organisms, which could synthesize ferric oxihydroxide core in its hollow protein shell [6]. TRPV1 is a kind of temperature-sensitive channel: When local temperature rises, TRPV1 gates calcium to activate a Ca<sup>2+</sup> sensitive promoter [4]. However, TRPV1 has limited use in Prokaryote. Thus, we designed Magthermo coli—a platform for remote regulation of gene expression by electromagnetic signal in <i>E.coli</i>.
                          </p>
                      </div>
                  </div>
-                <div style="background-color:#f2f2f2">
                  <h2>Overview</h2>
                      <h3>How does it work?</h3>
                          <p>
-                             There are two main components in our magthermo coli: magnetic receiver & thermosensitive regulator. Inducing with electromagnetic field，magnetic receiver would be heated, thus raise the ambient temperature. In response to the change of temperature, thermosensitive regulator would initiate the downstream gene (GFP for example) expression.
+                             There are two main components in our magthermo coli: magnetic <B>receiver & thermosensitive</B> regulator. Inducing with electromagnetic field, magnetic receiver will heat, raising the ambient temperature. In response to the change of temperature, thermosensitive regulator will initiate the downstream gene (GFP for example) expression.
                          </p>
                  <div class="row">
@@ Line 148: / Line 157: @@
                          <h3>Magnetic Receiver</h3>
                          <p>
-                             Magnetic nanoparticles can serve as a nanosource of heat [5]. That’s why we choose Ferritinas magnetic receiver: <B>Ferritin</B> is a kind of iron-storage protein in many organisms, which could synthesizeferric oxihydroxide core in its hollow protein shell [6] (Fig.2.). Once exposed to electromagnetic field, the ferric oxihydroxide core will be heated, raising the ambient temperature.
+                             Magnetic nanoparticles can serve as a nanosource of heat [5]. That’s why we choose Ferritin magnetic receiver: <B>Ferritin</B> is a kind of iron-storage protein in many organisms, which could synthesize ferric oxihydroxide core in its hollow protein shell [6] (Fig.2.). Once exposed to electromagnetic field, the ferric oxihydroxide core will heat, raising the ambient temperature.
                          </p>
                      </div>
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-                         <div style="border:solid 1px #9b9898;background-color:#e2e1e1;padding:0px 7px">
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                              <img src="https://static.igem.org/mediawiki/2015/4/47/OUC-China_project_overview_2.png" alt="" class="img-responsive" style="background-color:white">
-                             <span><center>Fig.2. Schema of ferritin</center></span>
+                             <span><center class="img-example">Fig.2. Schema of ferritin</center></span>
                          </div>
                      </div>
@@ Line 160: / Line 169: @@
                      <h3>Thermosensitive Regulator</h3>
                          <p>
-                             For thermosensitive regulator，we choseRNA thermometer and designed a thermosensitive T7 RNA polymerase. <B>RNA thermometer</B> is a structured RNA which could expose SD sequences only at appropriate temperature [7] (Fig.3.). <B>Thermosensitive T7 RNA polymerase</B> is a T7 RNA polymerase interrupted by a temperature-sensitive intein. Temperature-sensitive Intein is a kind of polypeptide that could self-splice and ligate it’s flanking polypeptides at specific temperature. Thus, interrupted T7 RNA polymerase can ininate the downstream signaling [8] (Fig.4.).
+                             For thermosensitive regulator, we chose RNA thermometer and designed a thermosensitive T7 RNA polymerase. <B>RNA thermometer</B> is a structured RNA which could expose SD sequences only at appropriate temperature [7] (Fig.3.). <B>Thermosensitive T7 RNA polymerase</B> is a T7 RNA polymerase interrupted by a temperature-sensitive intein. Temperature-sensitive Intein is a kind of polypeptide that could self-splice and ligate it’s flanking polypeptides at specific temperature. Thus, interrupted T7 RNA polymerase can initiate the downstream signal only at appropriate temperature[8] (Fig.4.).
                          </p>
                  <div class="row">
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                          <div style="border:solid 1px #9b9898;background-color:#e2e1e1;padding:0px 7px">
                              <img src="https://static.igem.org/mediawiki/2015/8/82/OUC-China_project_overview_3.png" alt="" class="img-responsive" style="background-color:white">
-                             <span><center>Fig.3. RNA Thermometer</center></span>
+                             <span><center class="img-example">Fig.3. RNA Thermometer</center></span>
                          </div>
                      </div>
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                          <div style="border:solid 1px #9b9898;background-color:#e2e1e1;padding:0px 7px">
                              <img src="https://static.igem.org/mediawiki/2015/5/5f/OUC-China_project_overview_4.png" alt="" class="img-responsive" style="background-color:white">
-                             <span><center>Fig.4. Thermosensitive T7 RNA polymerase</center></span>
+                             <span><center class="img-example">Fig.4. Thermosensitive T7 RNA polymerase</center></span>
                          </div>
                      </div>
                  </div>
-                 </div>
                  <h2>Measuring Technique</h2>
-                     <h3>In mag-receiver section:</h3>
+                     <h3>In magnetic-receiver section:</h3>
                      <p>
-                         (1)We found it complex and costly to measure magnetism of E.coli, thus, constructed a device for easy measure of magnetism—Captor (Fig.5.).<BR>(2)During verification for in vivo mineralization of ferritin, we found little literatures offering accurately detecting method. Thus, we referenced method in vitro[9] and successfully detected iron core in ferrin after in vivo mineralization.<BR>(3)To supply ourmodeling with concentration of ferritin per cell, we explored a method for valuing protein concentration per cell, and tried to make it more convenient.
+                         (1)We found it complicated and costly to measure magnetism of <i>E.coli</i>, thus, constructed a device for easy measure of magnetism—Captor (Fig.5.).<BR>(2)During verification for <i>in vivo</i> mineralization of ferritin, we found little literatures offering accurately detecting method. Thus, we referenced method in vitro[9] and successfully detected iron core in ferritin after <i>in vivo</i> mineralization.<BR>(3)To supply our modeling with concentration of ferritin per cell, we explored a method for valuing protein concentration per cell, and tried to make it more convenient.
                      </p>
-                     <h3>In thermo-regulator section:</h3>
+                     <h3>In thermosensitive-regulator section:</h3>
                      <p>
-                         (1)We explored the measurement method to identify the efficiency of thermosensitive regulator under heat stress.<BR>(2)During testing PBAD, we found it inconvenient to take photos of different plates and comparing them. Thus, we extended the function of Captor, and made it convenient for testing optimal inducement concentration on plates (Fig.6.).
+                         (1)We explored the measurement method to identify the efficiency of thermosensitive regulator under heat stress.<BR>(2)During testing pBAD, we found it inconvenient to take photos of different plates or compare them. Thus, we extended the function of Captor, and made it convenient for testing optimal inducement concentration on plates (Fig.6.).
                      </p>
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                              <img src="https://static.igem.org/mediawiki/2015/4/45/OUC-China_project_overview_5.jpg" alt="" class="img-responsive">
-                             <span><center>Fig.5. Captor—for easy measure of magnetism</center></span>
+                             <span><center class="img-example">Fig.5. Captor—for easy measure of magnetism</center></span>
                          </div>
                      </div>
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                              <img src="https://static.igem.org/mediawiki/2015/c/c9/OUC-China_project_overview_6.jpg" alt="" class="img-responsive">
-                             <span><center>Fig.6. Captor beta—for fluorescence detection on plate</center></span>
+                             <span><center class="img-example">Fig.6. Captor—for fluorescence detection on plate</center></span>
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@@ Line 202: / Line 211: @@
                  <div style="background-color:#f2f2f2">
                      <h2>References</h2>
-                         <p>
+                         <p style="font-size:13px;">
-.R, Bocker, C J, Estler, M, Maywald, et al. Comparison of distribution of doxycycline in mice after oral and intravenous application measured by a high-performance liquid chromatographic method.[J]. Arzneimittelforschung, 1981, 31(12):2116-2117.<BR>2.Xue, Wang, Xianjun, Chen, Yi, Yang. Spatiotemporal control of gene expression by a light-switchable transgene system.[J]. Nature Methods, 2012, 9(3):266-9.<BR>3.Stanley S A, Sauer J, Kane R S, et al. Remote regulation of glucose homeostasis in mice using genetically encoded nanoparticles.[J]. Nature Medicine, 2015, 21(1):92-98.<BR>4.Stanley S A, Gagner J E, Shadi D, et al. Radio-wave heating of iron oxide nanoparticles can regulate plasma glucose in mice.[J]. Science, 2012, 336(6081):604-.<BR>5.Jean-Paul, Fortin, Claire, Wilhelm, Jacques, Servais, et al. Size-Sorted Anionic Iron Oxide Nanomagnets as Colloidal Mediators for Magnetic Hyperthermia[J]. J.am.chem.soc, 2007, 129(9):2628-2635.<BR>6.Bou-Abdallah F, Yang H, Awomolo A, et al. Functionality of the Three-Site Ferroxidase Center of Escherichia coli Bacterial Ferritin (EcFtnA)[J]. Biochemistry, 2013, 53(3):483-495.<BR>7.https://2008.igem.org/Team:TUDelft<BR>8.Liang R, Liu X, Liu J, et al. A T7-expression system under temperature control could create temperature-sensitive phenotype of target gene in Escherichia coli.[J]. Journal of Microbiological Methods, 2007, 68(3):497-506.<BR>9.Cai Y, Cao C, He X, et al. Enhanced magnetic resonance imaging and staining of cancer cells using ferrimagnetic H-ferritin nanoparticles with increasing core size.[J]. International Journal of Nanomedicine, 2015, 10(default):2619-34.
+                             [1] R, Bocker, C J, Estler, M, Maywald, et al. Comparison of distribution of doxycycline in mice after oral and intravenous application measured by a high-performance liquid chromatographic method.[J]. Arzneimittelforschung, 1981, 31(12):2116-2117.<BR>[2] Xue, Wang, Xianjun, Chen, Yi, Yang. Spatiotemporal control of gene expression by a light-switchable transgene system.[J]. Nature Methods, 2012, 9(3):266-9.<BR>[3] Stanley S A, Sauer J, Kane R S, et al. Remote regulation of glucose homeostasis in mice using genetically encoded nanoparticles.[J]. Nature Medicine, 2015, 21(1):92-98.<BR>[4] Stanley S A, Gagner J E, Shadi D, et al. Radio-wave heating of iron oxide nanoparticles can regulate plasma glucose in mice.[J]. Science, 2012, 336(6081):604-.<BR>[5]Jean-Paul, Fortin, Claire, Wilhelm, Jacques, Servais, et al. Size-Sorted Anionic Iron Oxide Nanomagnets as Colloidal Mediators for Magnetic Hyperthermia[J]. J.am.chem.soc, 2007, 129(9):2628-2635.<BR>[6]Bou-Abdallah F, Yang H, Awomolo A, et al. Functionality of the Three-Site Ferroxidase Center of Escherichia coli Bacterial Ferritin (EcFtnA)[J]. Biochemistry, 2013, 53(3):483-495.<BR>[7] https://2008.igem.org/Team:TUDelft<BR>[8] Liang R, Liu X, Liu J, et al. A T7-expression system under temperature control could create temperature-sensitive phenotype of target gene in Escherichia coli.[J]. Journal of Microbiological Methods, 2007, 68(3):497-506.<BR>[9] Cai Y, Cao C, He X, et al. Enhanced magnetic resonance imaging and staining of cancer cells using ferrimagnetic H-ferritin nanoparticles with increasing core size.[J]. International Journal of Nanomedicine, 2015, 10(default):2619-34.
                          </p>
                  </div>
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