Difference between revisions of "Team:NJU-China/Proof"

 
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     <h1>Parts</h1>
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     <header>
    <h2>1.BBa_K1942000</h2>
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        <nav class="top-nav">
    <b>anti-KRAS siRNA (siRNA for KRAS gene silencing)</b>
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            <div class="container">
    <h3>INTRODUCTION</h3>
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                <div class="nav-wrapper"><a class="page-title">Proof</a></div>
    <p>This part is an artificially designed RNA strand. It serves as an element of the Team NJU-CHINA RNAi module which can be used for down-regulation of KRAS expression in Lung adenocarcinoma cells. We designed specific KRAS siRNA with algorithm based on a software developed by SYSU-Software team. This tool can find the best siRNA sequences on target gene KRAS to ascertain the maximum gene-specificity and silencing efficacy and also designs the pair of oligonucleotides needed to generate short hairpin RNAs (shRNAs) in the plasmid. Then we synthesize the shRNA sequence from a DNA synthesis company (Genscript).</p>
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    <img src="https://static.igem.org/mediawiki/2016/6/67/NJU_China_2016_iGEM_result-figure-1.png">
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    <span>Figure 1. The sequence of KRAS shRNA</span>
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        <div class="container">
    <h3>USAGE AND BIOLOGY</h3>
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            <a href="#" data-activates="nav-mobile" class="button-collapse top-nav full hide-on-large-only"> <i class="material-icons">menu</i> </a>
    <p>We package KRAS siRNA into exosomes by transfecting HEK293 cells with a plasmid expressing KRAS siRNA and then collect siRNA-encapsulated exosomes modified by iRGD peptide. When inject the modified exosomes into the vein, exosome will specifically recognize integrin receptors and fuse with Lung adenocarcinoma cells under the direction of the iRGD peptide. Once inside cells, KRAS siRNA will degrade KRAS mRNA by base-pairing, resulting in sharp decrease of K-ras in Lung cancer cells. As a consequence, K-ras reduction and disturbed function will result in the inhabitation of the proliferation of cancer cells, which ultimately have some therapeutic effects on Lung cnacer.</p>
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    <h3>CHARACTERIZATION</h3>
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        <ul id="nav-mobile" class="side-nav fixed">
    <b>Interference efficiency of anti-KRAS siRNA plasmid</b>
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    <p>To ensure the interference efficiency of anti-KRAS siRNA plasmid, we transfected it into human Lung adenocarcinoma cell line A549 and then extracted protein to perform a western blotting. Significant downregulation of K-ras can be observed in A549 cells treating with anti-KRAS siRNA, demonstrating that anti-KRAS siRNA has a gene silencing effect on Lung cancer cells.</p>
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                <a href="https://2016.igem.org/Team:NJU-China"><img class="background responsive-img" src="https://static.igem.org/mediawiki/2016/c/c8/NJU_China_2016_iGEM_logo.png" alt="NJU-China LOGO"></a>
    <img src="https://static.igem.org/mediawiki/2016/0/06/NJU_China_2016_iGEM_result-figure-2.png">
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            </li>
    <span>Figure 2. Protein quantitatively analysis made for intuitively support that anti-KRAS siRNA can suppress KRAS expression.</span>
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            <li class="bold"><a href="https://2016.igem.org/Team:NJU-China/Background" class="waves-effect waves-teal">Background</a></li>
    <h2>2.BBa_K1942002</h2>
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            <li class="bold no-padding">
    <b>Coding sequence of iRGD proteins and position it outside the membrane</b>
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                <ul class="collapsible collapsible-accordion">
    <h3>USAGE AND BIOLOGY</h3>
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                    <li class="bold"> <a class="collapsible-header waves-effect waves-teal">Project Design</a>
    <p>iRGD is a tumor-penetrating peptide that can increase vascular and tissue permeability. Importantly, this effect did not require the drugs to be chemically conjugated to the peptide. To enhance the accuracy of drug delivery system and improve targeting index of drugs, iRGD peptide was displayed on the surface of the exosome containing K-rasour previously designed siRNA, allowing us to target recipient cells in vivo efficiently.</p>
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                        <div class="collapsible-body">
    <p>The tumor targeting capability of exosomes was conferred by engineering the immature dendritic cells (imDCs) to express lysosome-associated membrane glycoprotein 2b (Lamp2b), a well-characterized exosomal membrane protein, fused with iRGD (CRGDKGPDC) targeting peptide for av integrin. Immature DCs were transfected with the vector expressing iRGD-Lamp2b fusion proteins using Lipofectamine 2000 transfection reagent. Lamp-2b is a protein found specifically abundant in exosomal membranes. So we connect iRGD with Lamp2b by a glycine-linker, and promote the expression usingby cmv promoter. We engineered our chassis, human embryonic kidney 293 (HEK293) cells, to express iRGD-Lamp2b fusion protein. Therefore, the iRGD exosomes (iRGD-Exos) are endowed with site-specific recognition ability and were purified from cell culture supernatants and loaded with Dox by electroporation</p>
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                            <ul>
    <h3>CHARACTERIZATION</h3>
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Project_Design">RNAi Module</a></li>
    <p>The iRGD-Lamp2b expressing vector was thoroughly described in Tian’s article .(Yanhua Tian. etc, Biomaterials, 2013). He shows that exosomes, endogenous nano-sized membrane vesicles secreted by most cell types, can deliver chemotherapeutics such as doxorubicin (Dox) to tumor tissue in BALB/c nude mice. To reduce immunogenicity and toxicity, mouse immature dendritic cells (imDCs) were used for exosome production. Tumor targeting was facilitated by engineering the imDCs to express a well-characterized exosomal membrane protein (Lamp2b) fused to av integrin-specific iRGD peptide (CRGDKGPDC). Purified exosomes from imDCs were loaded with Dox via electroporation, with an encapsulation efficiency of up to 20%. iRGD exosomes showed highly efficient targeting and Dox delivery to av integrin-positive breast cancer cells in vitro as demonstrated by confocal imaging and flow cytometry. Intravenously injected targeted exosomes delivered Dox specifically to tumor tissues, leading to inhibition of tumor growth without overt toxicity. The results suggest that exosomes modified by targeting ligands can be used therapeutically for the delivery of Dox to tumors, thus having great potential value for clinical applications in our project.</p>
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Project_Design#Targeting_Module">Targeting Module</a></li>
   
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Project_Design#Assembly">Assembly</a></li>
    <h1>Results</h1>
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                            </ul>
    <p>According to our study design, we transfected a targeting plasmid into HEK293 cells to express a fusion protein composed of the exosomal membrane protein Lamp2b and the peptide iRGD. Simultaneously, we transfected KRAS siRNA plasmid into HEK293 cells to collect exosomes. Then, the modified exosomes carrying KRAS siRNA were continually produced by the transfected HEK293 cells. Subsequently, we ensure the function of KRAS siRNA and determine whether KRAS siRNA encapsulated by iRGD-modified exosomes had a KRAS gene silencing effect and could effectively suppress the K-ras expression. Generally, the experimental procedure can be divided into three steps:
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        <br>(1) silencing capability validation in vitro
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                    </li>
        <br>(2) silencing capability validation in vivo
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                </ul>
        <br>(3) safety validation
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            </li>
    </p>
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            <li class="bold"><a href="https://2016.igem.org/Team:NJU-China/Modeling" class="waves-effect waves-teal">Modeling</a></li>
    <h2>1. Silencing capability validation in vitro</h2>
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                <ul class="collapsible collapsible-accordion">
    <h3>1.1 Verification of interference of efficiency of KRAS siRNA Interference efficiency of anti-KRAS siRNA plasmid in vitro</h3>
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                    <li class="bold"> <a class="collapsible-header waves-effect waves-teal">Results</a>
    <p>To ensure the interference efficiency of anti-KRAS siRNA plasmid, we transfected it into human Lung adenocarcinoma cell line A549 and then extracted protein to perform a western blotting. Significant downregulation of K-ras can be observed in A549 cells treating with anti-KRAS siRNA, demonstrating that anti-KRAS siRNA has a gene silencing effect on Lung cancer cells.</p>
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                        <div class="collapsible-body">
    <img src="https://static.igem.org/mediawiki/2016/b/b3/NJU_China_2016_iGEM_result-figure-3.png">
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                            <ul>
    <span>igure 3. Anti-KRAS siRNA transfected into A549 cells successfully reduce KRAS expression. Left panel: Western blot analysis of KRAS protein levels in cells without any treatment or treated with negative control siRNA and transfected with anti-KRAS siRNA using Lipo2000. Right panel:  Protein quantitatively analysis made for intuitive support that anti-KRAS siRNA can suppress KRAS expression.</span>
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Results">Parts</a></li>
 
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Results#Validations">Validations</a></li>
    <h3>1.2 TEM images of exosomes carrying KRAS siRNA inside and expressing iRGD  peptide on their membranes</h3>
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Results#Safety">Safety</a></li>
    <p>Subsequently, we performed a transmission electron microscopy (TEM) to characterize the iRGD-modified exosomes loaded with KRAS siRNA. The TEM images showed that the exosomes presented normal morphological characteristics after outside modification and siRNA loading, with a diameter of approximately 90 nm and a double-layer membrane. These characteristics indicate that the exosome properties were not affected by these modifications. </p>
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Results#Conclusions">Conclusions</a></li>
    <img src="https://static.igem.org/mediawiki/2016/5/5d/NJU_China_2016_iGEM_result-figure-4.png">
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                            </ul>
    <span>Figure 4. TEM image of iRGD-modified exosomes packaging KRAS siRNA</span>
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                    </li>
    <h3>1.3 anti-KRAS siRNA encapsulated by iRGD-modified exosomes suppress the KRAS expression in A549 cells in vitro</h3>
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                </ul>
    <p>We next evaluate the effect of anti-KRAS siRNA packaged by exosomes on KRAS expression in vitro. The KRAS expression levels were assayed in A549 cells after transfected with anti-KRAS siRNA-loaded exosomes. Nonloaded iRGD exosomes were used as control to ascertain that any RNAi response observed did not derive from the exosomes per se. The western electrophoresis and knockdown data obtained from qPCR analysis of KRAS gene expression indicate that KRAS protein and mRNA levels both dramatically decreased in the cells incubating with iRGD exosome-delivered siRNA compared with cells treating with nude exosome or without any treatment. This result suggest that iRGD-modified exosomes containing anti-KRAS siRNA can specifically target A549 cells, deliver siRNA into cells and finally reduce the KRAS expression.</p>
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            </li>
    <img src="https://static.igem.org/mediawiki/2016/c/ca/NJU_China_2016_iGEM_result-figure-5.png">
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            <li class="bold"><a href="https://2016.igem.org/Team:NJU-China/Human_Practices" class="waves-effect waves-teal">Human Practices</a></li>
    <span>Figure 5. Quantitative RT-pcr analysis of KRAS mRNA levels in A549 cells without any treatment and transfected with nonloaded exosomes or anti-KRAS siRNA-loaded exosomes shows that anti-KRAS siRNA can be transfected into exosomes and target KRAS gene to realize silencing effect, down-regulating KRAS mRNA levels.</span>
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            <li class="bold"><a href="https://2016.igem.org/Team:NJU-China/Team" class="waves-effect waves-teal">Team</a></li>
 
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            <li class="bold"><a href="https://2016.igem.org/Team:NJU-China/Attributions" class="waves-effect waves-teal">Attributions</a></li>
    <h3>1.4 anti-KRAS siRNA loaded into exosomes efficiently arrests cell proliferation in vitro</h3>
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            <li class="bold"><a href="https://2016.igem.org/Team:NJU-China/Collaborations" class="waves-effect waves-teal">Collaborations</a></li>
    <p>KRAS over-expression has been demonstrated to promote the growth of Lung adenocarcinoma cells and be involved in migration and invasion of Lung cancer. For further support, we had to examine to ascertain the role of anti-KRAS siRNA-loaded iRGD exosomes in cell proliferation by down-regulating the KRAS expression. An EDU assay was carried out after transfection and as a control, nude exosome also transfected into A549 cells, respectively. The assay result indicates that KRAS knockdown had an anti-proliferative effect on the tumor cells while the nude exosomes were not capable of decreasing the tumor cells growth.</p>
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            <li class="bold no-padding">
    <img src="">
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                <ul class="collapsible collapsible-accordion">
    <span>Figure 6.</span>
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                    <li class="bold"> <a class="collapsible-header waves-effect waves-teal">Notebook</a>
 
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                        <div class="collapsible-body">
    <h2>2. Silencing capability validation in vivo</h2>
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                            <ul>
    <p>The anti-KRAS siRNA-loaded exosomes can be transfected into A549 cells and suppress the expression of KRAS in vitro. To examine the consequence of KRAS knockdown by anti-KRAS siRNA packaged by exosomes, we built a non-small cell lung cancer mouse model for in vivo experiment. Forty mice were subcutaneously injected with A549-Luc cells to implant tumors and tumors volumes were measured with bioluminescent imaging several times after injection. The parts emitting fluorescence in the mice bodies represent the tumors xenografted with A549-Luc, which helps monitor the tumor growth, location and metastasis.</p>
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Notebook/Calendar">Calendar</a></li>
    <img src="https://static.igem.org/mediawiki/2016/0/09/NJU_China_2016_iGEM_result-figure-7.png">
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                                <li><a href="https://2016.igem.org/Team:NJU-China/Notebook/Protocol">Protocol</a></li>
    <span>Figure 7. Heatmap of tumor-bearing mice. The parts in the mice body representing the tumors xenografted with A549-Luc indicates that the tumors are relatively uniform in size. Left panel: the heatmap of tumor-bearing mice injected with PBS. Right panel: the heatmap of tumor-bearing mice treated with KRAS siRNA packaged by exosomes.</span>
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                            </ul>
    <img src="https://static.igem.org/mediawiki/2016/5/52/NJU_China_2016_iGEM_result-figure-8.png">
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                        </div>
    <span>Figure 8. Quantitative analysis of fluorescence intensity of tumor implanted in mice after treatment with PBS and KRAS siRNA injections.The intensity of fluorescence in mice treated with PBS is much more than mice treated with iRGD exosomes losded with KRAS siRNA.</span>
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                    </li>
    <p>Mice were randomly assigned to 2 groups(n=20 per group) and treated differently. One group received PBS injections, the other group is treated with anti-KRAS siRNA encapsulated by iRGD-modified exosomes via tail-vein injections. The administrations were given five times for 2 successive weeks since contamination of HEK293 cells resulted in exosomes shortage and the treatment of mice were delayed.</p>
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                </ul>
    <p>Subsequently, mice were sacrificed for tumor harvest after in vivo imaging system. All the tumors were measured for length,volumes and weight. The Small piece of each tumor was cut and fixed with paraformaldehyde to make preparation for histopathological examination. </p>
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            </li>
    <img src="https://static.igem.org/mediawiki/2016/3/38/NJU_China_2016_iGEM_result-figure-9.png">
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        </ul>
    <span>Figure 9. The tumor harvested from the killed mice and measured for volumes and weight. The first row are tumors from mice injected PBS, the second row are tissues from mice administered with KRAS siRNA encapsulated by iRGD exosomes.</span>
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    <img src="https://static.igem.org/mediawiki/2016/7/73/NJU_China_2016_iGEM_result-figure-10.png">
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    <span>Figure 10. The weight measurement of tumor tissues harvested from model mice With analytical balance</span>
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     <main>
     <p>Then, total protein and RNA were extracted from the rest tumor tissues to evaluate the expression levels of KRAS in vivo. As a result, both KRAS protein and mRNA levels were reduced in the tumor cells of mice injected with iRGD exosomes-delivered anti-KRAS siRNA compared with mice treated with PBS. Though the down-regulation is not so evident, taking the short time of treatment into account, it clearly demonstrats that anti-KRAS siRNA using exosomes as efficient RNAi delivery agents were capable of delivering siRNA into cancer cells and regulating target gene expression.</p>
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        <div class="fixed-action-btn" style="bottom: 45px; right: 24px;">
     <img src="https://static.igem.org/mediawiki/2016/b/b5/NJU_China_2016_iGEM_result-figure-11.png">
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            <a class="btn-floating btn-large red">
    <span>Figure 11. Quantitative RT-pcr analysis of KRAS mRNA levels in tumor cells after treatment of PBS and KRAS siRNA packaged by iRGD-modified exosomes. </span>
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    <h2>3.safety validation</h2>
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                <li onclick="$('html, body').animate({ scrollTop: 0 }, 'fast');"><a class="btn-floating green tooltipped" data-position="left" data-delay="50" data-tooltip="Scroll to Top"><i class="material-icons">arrow_upward</i></a></li>
   
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                <li onclick="$('html, body').animate({scrollTop: $('html').height()-$(window).height()}, 'fast')"><a class="btn-floating yellow darken-2 tooltipped" data-position="left" data-delay="50" data-tooltip="Scroll to Bottom"><i class="material-icons">arrow_downward</i></a></li>
    <h3>Endotoxin detecting of anti-KRAS siRNA-loaded exosomes</h3>
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                <li onclick="$(this).parent().parent().hide('slow')"><a class="btn-floating purple darken-3"><i class="close material-icons tooltipped" data-position="left" data-delay="50" data-tooltip="Hide FAB">close</i></a></li>
    <p>Endotoxins is a type of pyrogen which are natural compounds found in the outer cell membrane of Gram-negative bacteria and can impact over 30 biological activities. To ensure the safety and quality of, avoiding toxicities, proving that our achievement is of great value for clinical application, an endotoxin detecting assay was carried out using endotoxins test kit. The result was negative, demonstrating that our drug system satisfy the safety requirement.</p>
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                <li><a class="btn-floating blue button-collapse hide-on-large-only tooltipped" data-position="left" data-delay="50" data-tooltip="Show Navigation" data-activates="nav-mobile"><i class="material-icons">menu</i></a></li>
    <img src="https://static.igem.org/mediawiki/2016/9/9f/NJU_China_2016_iGEM_result-figure-12.png">
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            </ul>
    <span>Figure 12. Endotoxin detecting of anti-KRAS siRNA-loaded exosomes</span>
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    <h1>Conclusions</h1>
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    <p>KRAS mutations were identified in NSCLC tumors more than 20 years ago, but the clinic importance of KRAS mutant in cancer therapy just began to be appreciated. This project aimed to develop a drug system that employed modified exosomes expressing the iRGD peptide on the exosomal membrane surface to deliver KRAS siRNA into cancer cells, targeting KRAS gene and down-regulating K-ras expression to treat cancers. Our results had demonstrated that exosomes mediated by iRGD peptide can effectively and specifically help KRAS siRNA into Lung cancer cells and silence KRAS gene to realize the expression level reduction both in vitro and in vivo. In silencing validation , we transfect the KRAS siRNA into A549 cells using Lipo 2000 and performed a western blotting to ensure the function of our RNA sequence. Subsequently, we collected iRGD-modified exosomes loaded with KRAS siRNA, evaluating its effect on Lung cancer cells by examining the KRAS expression after transfection. The result confirmed that iRGD exosomes carrying KRAS siRNA can effectively down-regulate the expression level of KRAS mRNA and reduce the K-ras protein. Later, the EDU assay further ascertained the biological role of KRAS siRNA on cell proliferation suppression in vitro.</p>
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    <p>In vivo experiment, the none-small cell cancer mouse model was established after implanting tumor in 40 mice by subcutaneous injection with A549-LUC cells. After short-time treatment, the tumor tissues harvested from killed mice were measured, then protein and RNA extracted were tested, which supported that KRAS siRNA can efficiently suppress the KRAS expression, inhibit cell proliferation and have a potential to treat cancers. Besides, the endotoxin detecting validated that our drug system satisfy the safety requirement and will not impact biological activities.</p>
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                            <li class="tab col s4"><a class="active" href="#Parts">Parts</a></li>
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                            <li class="tab col s4"><a href="#Validations">Validations</a></li>
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                            <li class="tab col s4"><a href="#Safety">Safety</a></li>
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                            <li class="tab col s4"><a href="#Conclusions">Conclusions</a></li>
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                                <div class="collapsible-header active"><i class="material-icons">settingss</i>BBa_K1942000</div>
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                                    <p>Anti-KRAS siRNA (siRNA for KRAS gene silencing)</p>
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                                    <h4>Introduction</h4>
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                                    <p style="padding-top: 0;">This part is an artificially designed RNA strand. It serves as an element of the Team NJU-CHINA RNAi module which can be used for down-regulation of KRAS expression in lung adenocarcinoma cells. We designed specific KRAS siRNA with algorithm based on a software developed by SYSU-Software team. This tool can find the best siRNA sequence on target gene KRAS to ascertain the maximum gene-specificity and silencing efficacy and also designs the pair of oligonucleotides needed to generate short hairpin RNAs (shRNAs) in the plasmid. Then we synthesize the shRNA sequence from a DNA synthesis company (Genscript).</p>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/9/98/NJU_China_2016_iGEM_Result-1.png" class="responsive-img">
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                                    </div>
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                                    <div align="middle">Figure 1. The sequence of KRAS shRNA</div>
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                                    <h4>Usage and Biology</h4>
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                                    <p style="padding-top: 0;">We packaged KRAS siRNA into exosomes by transfecting HEK293 cells with a plasmid expressing KRAS siRNA and then collected siRNA-encapsulated exosomes. When modified exosomes being intravenously injected, they will specifically recognize integrin receptors and fuse with lung adenocarcinoma cells under the direction of the iRGD peptide. Once inside cells, KRAS siRNA will bind to KRAS mRNA through base-pairing and digest the mRNA, resulting in sharp decrease of K-ras in lung cancer cells. As a consequence, K-ras protein’s reduction and disturbed function will both result in the inhabitation of the proliferation of cancer cells, which ultimately have some therapeutic effects on lung cancer (non-small cell lung cancer in this case).</p>
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                                    <h4>Characterization</h4>
 +
                                    <h5>Interference efficiency of anti-KRAS siRNA plasmid</h5>
 +
                                    <p style="padding-top: 0;">To ensure the interference efficiency of anti-KRAS siRNA plasmid, we transfected it into human lung adenocarcinoma cell line A549 and then extracted protein from these cells to perform western blot. Significant down-regulation of K-ras can be observed in A549 cells treated with anti-KRAS siRNA, demonstrating that anti-KRAS siRNA has the gene silencing effect on lung cancer cells.</p>
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                                        <img src="https://static.igem.org/mediawiki/2016/0/05/NJU_China_2016_iGEM_Result-2.jpg" class="responsive-img">
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                                    </div>
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                                    <div align="middle" style="padding-bottom: 30px;">Figure 2. Protein quantitatively analysis of K-ras extracted from cells without any treatment (Nude) and cells transfected with control siRNA (NC, siRNA targeting a random sequence) or anti-KRAS siRNA, which was made for intuitively support that anti-KRAS siRNA can suppress K-ras expression.</div>
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                                </div>
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                            </li>
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                            <li>
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                                <div class="collapsible-header active"><i class="material-icons">settings</i>BBa_K1942002</div>
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                                <div class="collapsible-body">
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                                    <p>A coding sequence of iRGD peptide and position it outside the membrane.</p>
 +
                                    <h4>Usage and Biology</h4>
 +
                                    <p style="padding-top: 0;">iRGD is a tumor-penetrating peptide that can increase vascular and tissue permeability. Importantly, this effect did not require the drugs to be chemically conjugated to the peptide. To enhance the accuracy of drug delivery system and improve targeting index of drugs, iRGD peptide was displayed on the surface of the exosome containing our previously designed siRNA, allowing us to target recipient cells in vivo efficiently. Lamp-2b is a protein found specifically abundant in exosomal membranes. So we connect iRGD with Lamp2b by a glycine-linker, and promote the expression using cmv promoter. We engineered our chassis, human embryonic kidney 293 (HEK293) cells, to express iRGD-Lamp2b fusion protein. Therefore, the iRGD exosomes (iRGD-Exos) are endowed with site-specific recognition ability and were purified from cell culture supernatants and loaded with Dox by electroporation.</p>
 +
                                    <h4>Characterization</h4>
 +
                                    <p style="padding-top: 0;">The iRGD-Lamp2b expressing vector was thoroughly described in Tian’s article (Yanhua Tian, et al. Biomaterials, 2013). He showed that exosomes, endogenous nano-sized membrane vesicles secreted by most cell types, could deliver chemotherapeutics such as doxorubicin (Dox) to tumor tissue in BALB/c nude mice. To reduce immunogenicity and toxicity, mouse immature dendritic cells (imDCs) were used for exosome production. Tumor targeting was facilitated by engineering the imDCs to express a well-characterized exosomal membrane protein (Lamp2b) fused to αν integrin-specific iRGD peptide (CRGDKGPDC). Purified exosomes from imDCs were loaded with Dox via electroporation, with an encapsulation efficiency of up to 20%. iRGD exosomes showed highly efficient targeting and Dox delivery to αν integrin-positive breast cancer cells in vitro as demonstrated by confocal imaging and flow cytometry. Intravenously injected targeted exosomes delivered Dox specifically to tumor tissues, leading to inhibition of tumor growth without overt toxicity. The results suggested that exosomes modified by targeting ligands could be used therapeutically for the delivery of Dox to tumors, thus having great potential value for clinical applications in our project.</p>
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                                </div>
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                            </li>
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                        </ul>
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                    </div>
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                    <div id="Validations" class="col s12">
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                        <ul class="collapsible popout" data-collapsible="expandable">
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                            <li>
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                                <div class="collapsible-header active"><i class="material-icons">filter_drama</i>Silencing capability validation in vitro</div>
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                                <div class="collapsible-body">
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                                    <h5>1.1 KRAS siRNA interference efficiency verification in vitro</h5>
 +
                                    <p style="padding-top: 0;">To ensure the interference efficiency of anti-KRAS siRNA, we transfected the plasmid loaded with this siRNA into human lung adenocarcinoma cell line A549 and extracted protein to perform western blot. Significant down-regulation of K-ras can be observed in A549 cells treating with anti-KRAS siRNA plasmid, compared with the control group, demonstrating that anti-KRAS siRNA has a gene silencing effect on lung cancer cells.</p>
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                                        <img src="https://static.igem.org/mediawiki/2016/d/d1/NJU_China_2016_iGEM_Result-3.jpg" class="responsive-img">
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                                    </div>
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                                    <div align="middle" style="padding-left: 30px; padding-right: 30px;">
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                                        Figure 3. Anti-KRAS siRNA transfected into A549 cells successfully reduced KRAS expression. Left panel: western blot analysis of KRAS protein levels in cells without any treatment (Nude) or treated with negative control siRNA (NC, siRNA targeting at a random sequence) and transfected with anti-KRAS siRNA using Lipo2000. Right panel: protein quantitative analysis made for intuitive support that anti-KRAS siRNA can suppress KRAS expression.
 +
                                    </div>
 +
                                    <h5 style="padding-top: 30px;">1.2 TEM imaging of exosomes carrying KRAS siRNA and expressing iRGD peptide on their membrane</h5>
 +
                                    <p style="padding-top: 0;">After co-transfection of the two plasmids mentioned above, we performed a transmission electron microscopy (TEM) to characterize the iRGD-KRAS-siRNA-exosomes. The TEM image showed that the exosomes presented normal morphological characteristics after outside modification and siRNA loading, with a diameter of approximately 200 nanometer and a double-layer membrane. </p>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/0/0c/NJU_China_2016_iGEM_Result-4.png" class="responsive-img">
 +
                                    </div>
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                                    <div align="middle">Figure 4. TEM image of iRGD-modified exosomes packaging KRAS siRNA</div>
 +
                                    <h5 style="padding-top: 30px;">1.3 Nanoparticle tracking analysis to ascertain the relationship between protein concentration and exosomes quantity </h5>
 +
                                    <p style="padding-top: 0;">We then asked NUDT_CHINA to help us perform nanoparticle tracking analysis (NTA) for a further evaluation of the quantity and size of secreted exosomes. The use of Nanosight enabled quantification and size determination of the extracellular vesicles, as nanoparticles can be automatically tracked and sized based on Brownian motion and the diffusion coefficient. The size of exosomes attained ranged around 270nm. Basing the particle size and relative intensity, we also created a 3D plot for a visual explanation. Under measurement condition listed, the exosomes secreted by HEK293 cells were assayed for 2.95 E8 particles each milliliter. Then the relationship between particle number and protein was determined that exosomes in 1 ng protein were equivalent to 6277.95 particles, according to the dilution multiple (24) and protein concentration (1127.756 ng/ul) we have tested. All the data collected helped us decide the transfection dosage of siRNA and dosing of treatment prepared for animal experiment.</p>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/b/bb/NJU_China_2016_iGEM_Result-5.png" class="responsive-img">
 +
                                    </div>
 +
                                    <div align="middle">Figure 5. Nanoparticle tracking analysis (NTA) for Characterization of secreted exosomes. (a) Concentration of different particle sizes of exosomes. (b) 3D plot of particle size and relative intensity. (c) Experiment condition for our measurement. (d) Results attained after measurement of exosomes.</div>
 +
                                    <h5 style="padding-top: 30px;">1.4 The iRGD-KRAS-siRNA-exosomes suppressed KRAS expression in A549 cells in vitro</h5>
 +
                                    <p style="padding-top: 0;">We next evaluate the effect of iRGD-KRAS-siRNA-exosomes on KRAS expression in vitro. The KRAS expression level was assayed in A549 cells after co-cultured with exosomal KRAS siRNA. Non-loaded iRGD-exosomes were used as control to ascertain that any RNAi response observed did not derive from the exosomes per se. The western electrophoresis and knockdown data obtained from qPCR analysis of KRAS gene expression indicated that KRAS protein and mRNA levels both dramatically decreased in the cells incubating with iRGD-KRAS-siRNA-exosomes compared with cells treating with nude exosomes or without any treatment. This result suggests that iRGD-KRAS-siRNA-exosomes can deliver siRNA into target cells and finally reduce the KRAS expression.</p>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/8/89/NJU_China_2016_iGEM_Result-6.jpg" class="responsive-img">
 +
                                    </div>
 +
                                    <div align="middle">Figure 6. Quantitative RT-PCR analysis of KRAS mRNA levels in A549 cells without any treatment (NC), transfected with non-loaded exosomes (exosome) and transfected with iRGD-KRAS-siRNA-exosomes (siRNA-exosome) shows that exosomal KRAS siRNA can down-regulate KRAS expression in transcription level.</div>
 +
                                    <h5 style="padding-top: 30px;">1.5 The iRGD-KRAS-siRNA-exosomes efficiently arrests cancer cell proliferation in vitro</h5>
 +
                                    <p style="padding-top: 0;">KRAS over-expression has been demonstrated to promote the growth of lung adenocarcinoma cells and be involved in migration and invasion of lung cancer. For further verification, we examined the role of iRGD-KRAS-siRNA-exosomes in cell proliferation. An EDU assay using Cell-Light™ EdUTP Apollo®567 TUNEL Cell Detection Kit, was carried out after siRNA-iRGD-exosome incubation and as a control, nude exosomes were also treated to A549 cells. The result indicated that KRAS knockdown had an anti-proliferation effect on lung tumor cells while nude exosomes were not capable of inhibiting the growth of tumor cells. </p>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/c/cf/NJU_China_2016_iGEM_Result-7.jpg" class="responsive-img">
 +
                                    </div>
 +
                                    <div align="middle" style="padding-bottom: 30px;">Figure 7. Cell proliferation assay for A549 cells treated with PBS or transfected with iRGD-KRAS-siRNA-exosomes (exosome). Left panel: Fluorescence microscope photos of A549 cells. The red points represent divided cells for cell proliferation rate calculation. Right panel: Quantitative analysis of cell proliferation rate, indicating that iRGD-KRAS-siRNA-exosomes can effectively suppress cell proliferation. (**: p < 0.01)</div>
 +
                                </div>
 +
                            </li>
 +
                            <li>
 +
                                <div class="collapsible-header active"><i class="material-icons">filter_drama</i>Silencing capability validation in vivo</div>
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                                <div class="collapsible-body">
 +
                                    <h5>2.1 Establishment of none-small cell lung cancer mouse model with 40 mice to perform validation experiment in vivo</h5>
 +
                                    <p style="padding-top: 0;">The iRGD-KRAS-siRNA-exosomes can be released into A549 cells and suppress the expression of KRAS in vitro. To examine the consequence of KRAS knockdown by anti-KRAS siRNA in vivo, we built a non-small cell lung cancer mouse model for in vivo experiment. Forty mice were subcutaneously injected A549-LUC cells to realize tumor implantation. Then tumor volume were measured through bioluminescent imaging several times after injection. The areas that emit fluorescence in the mice bodies represent labeled tumors (tumors developed from the implanted A549-LUC cells), which helps us to monitor the tumor growth, location and metastasis.</p>
 +
                                    <h5 style="padding-top: 30px">2.2 Mice were divided to receive different treatment, testing the function of iRGD-KRAS-siRNA-exosomes</h5>
 +
                                    <p style="padding-top: 0;">Mice were randomly assigned to 2 groups (n=20 per group) and treated differently. One group received PBS injections, the other group is treated with iRGD-KRAS-siRNA-exosomes via tail-vein injections. The administrations were given five times for 2 successive weeks since contamination of HEK293 cells resulted in exosomes shortage and the treatment of mice were delayed.</p>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/1/1f/NJU_China_2016_iGEM_Result-8.jpg" class="responsive-img">
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                                    </div>
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                                    <div align="middle">
 +
                                        Figure 8. In vivo imaging of tumor-bearing mice. The parts in the mice body representing the tumors xenografted with A549-Luc indicates that the tumors are relatively uniform in size. First panel: the imaging of tumor-bearing mice injected with PBS. Second panel: the imaging of tumor-bearing mice treated with iRGD-KRAS-siRNA-exosomes.
 +
                                    </div>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/9/93/NJU_China_2016_iGEM_Result-9.png" class="responsive-img">
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                                    </div>
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                                    <div align="middle">
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                                        Figure 9. Quantitative analysis of fluorescence intensity of tumors in mice after treatment of PBS or KRAS-siRNA-iRGD-exosomes (exosome). The intensity of tumor fluorescence in mice treated with KRAS-siRNA-iRGD-exosomes showed dramatically decrease compared with the group treated with PBS. (****: p < 0.0001)
 +
                                    </div>
 +
                                    <h5 style="padding-top: 30px;">2.3 The measurement of tissues harvested indicates the function of KRAS siRNA on the tumor treatment</h5>
 +
                                    <p style="padding-top: 0;">Subsequently, mice were sacrificed for tumor harvest after in vivo imaging. All the tumors were measured for length, volumes and weight. Small pieces from every tumor was cut independently and fixed by paraformaldehyde to prepare for histopathological examination. </p>
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                                    <div align="middle">
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                                        <img src="https://static.igem.org/mediawiki/2016/9/96/NJU_China_2016_iGEM_Result-10.png" class="responsive-img">
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                                    </div>
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                                    <div align="middle">
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                                        Figure 10. Quantitative analysis of tumor weight measurement for mice treated with PBS or KRAS-siRNA-iRGD-exosomes (exosome).
 +
                                    </div>
 +
                                    <h5 style="padding-top: 30px;">2.4 Pathological section to observe tumor cells</h5>
 +
                                    <p style="padding-top: 0;">After measurement of tumors, HE staining was conducted to verify the function of iRGD-exosomal siRNA. HE staining enabled better visualization of tissue structure and cell morphology, which can be used for morphological observation of normal and diseased tissue. The detection result showed that tumor cell necrosis rate in experimental group was much higher than control group. In other words, iRGD exosomes KRAS siRNA can effectively induce tumor cell necrosis and suppress cell proliferation</p>
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                                        <img src="https://static.igem.org/mediawiki/2016/5/54/NJU_China_2016_iGEM_Result-11.jpg" class="responsive-img">
 +
                                    </div>
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                                    <p>Figure 11. Pathological section of tumor tissues from model mice treated with PBS or iRGD-KRAS-siRNA-exosomes (exosome).</p>
 +
                                    <h5 style="padding-top: 30px">2.5 iRGD-KRAS-siRNA-exosomes reduce the KRAS expression in tumor cells in vivo</h5>
 +
                                    <p style="padding-top: 0;">Then, total protein and RNA were extracted from the rest tumor tissues to evaluate the expression level of KRAS in vivo. Results showed both KRAS protein and mRNA level were reduced in tumor cells of mice injected with KRAS-siRNA-iRGD-exosomes compared with mice treated with PBS. Though the down-regulation is not that evident, it still demonstrated that iRGD-KRAS-siRNA-exosomes can efficiently be delivered into tumor cells and regulate target gene expression, taking the short time of treatment into account.</p>
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                                        <img src="https://static.igem.org/mediawiki/2016/6/68/NJU_China_2016_iGEM_Result-12.jpg" class="responsive-img">
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                                    </div>
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                                    <p>Figure 12. Quantitative RT-PCR analysis of KRAS mRNA level in tumor cells after treatment of PBS and KRAS-siRNA-iRGD-exosomes (exosome). (***: p < 0.001)</p>
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                                </div>
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                            </li>
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                        </ul>
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                    </div>
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                    <div id="Safety" class="col s12">
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                        <ul class="collapsible popout" data-collapsible="expandable">
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                            <li>
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                                <div class="collapsible-header active"><i class="material-icons">youtube_searched_for</i>Endotoxin detecting of anti-KRAS siRNA-loaded exosomes</div>
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                                <div class="collapsible-body">
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                                    <p>Endotoxin is a type of natural pyrogen that was found in outer cell membrane of Gram-negative bacteria and can make impact on over 30 biological activities. To ensure the safety of our drug system, avoid toxicities, thus prove that our achievement is of great value for clinical application, a detecting assay was carried out using an endotoxin test kit. The result was negative, demonstrating that our drug system satisfies the safety requirement.</p>
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                                        <img src="https://static.igem.org/mediawiki/2016/8/87/NJU_China_2016_iGEM_Result-13.png" class="responsive-img">
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                                    </div>
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                                    <div align="middle" style="padding-bottom: 30px;">Figure 13. Endotoxin detecting of anti-KRAS siRNA-loaded exosomes</div>
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                                </div>
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                            </li>
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                        </ul>
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                    <div id="Conclusions" class="col s12">
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                            <li>
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                                <div class="collapsible-header active"><i class="material-icons">check</i>An efficient drug delivery system</div>
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                                <div class="collapsible-body">
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                                    <p>KRAS mutation was identified in NSCLC more than 20 years ago, but its clinical importance in cancer therapy just began to be appreciated. Our project aimed to develop a drug system that employed modified exosomes with iRGD peptide on its surface to deliver KRAS-siRNA into lung cancer cells specifically, thus target KRAS gene and down-regulate K-ras protein expression to treat lung cancer cases. Our results had demonstrated that iRGD-KRAS-siRNA-exosomes can be delivered into tumor cells and efficiently down-regulate KRAS expression both in vitro and in vivo. In silencing validation, we transfected KRAS siRNA into A549 cells using Lipo 2000 and performed western blot to test the function of our siRNA. Subsequently, we collected iRGD-modified exosomes loaded with KRAS siRNA, evaluating its effect on lung cancer cells (A549) by examining KRAS expression after transfection. The result confirmed that iRGD-KRAS-siRNA-exosomes could effectively down-regulate KRAS transcription level and reduce its protein expression. Later, the EDU assay further ascertained the biological role of KRAS siRNA in cell proliferation suppression in vitro.</p>
 +
                                    <p style="padding-bottom: 30px;">To perform in vivo validation, none-small cell cancer mouse model was established after implanting tumor in 40 mice by subcutaneous injection with A549-LUC cells. After a short-time treatment, tumors harvested from killed mice were measured, then protein and RNA extracted from these tissues were examined, results supporting that KRAS siRNA can efficiently suppress KRAS expression, inhibit cell proliferation and thus have its potential to be taken as a cancer treatment. Besides, endotoxin detecting validated that our drug system satisfies the safety requirement and won’t impact on biological activities. To be more meaningful, we purified the batch of iRGD-KRAS-siRNA-exosomes for liquid fill, completing a full process including experiment design, compounds synthesis, effect test and drug production.</p>
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                                        <img src="https://static.igem.org/mediawiki/2016/a/ab/NJU_China_2016_iGEM_Result-14.jpg" class="responsive-img">
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                                    </div>
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                                    <div align="middle" style="padding-bottom: 30px;">Figure 14. Exosome final products</div>
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Latest revision as of 02:35, 20 October 2016

  • settingssBBa_K1942000

    Anti-KRAS siRNA (siRNA for KRAS gene silencing)

    Introduction

    This part is an artificially designed RNA strand. It serves as an element of the Team NJU-CHINA RNAi module which can be used for down-regulation of KRAS expression in lung adenocarcinoma cells. We designed specific KRAS siRNA with algorithm based on a software developed by SYSU-Software team. This tool can find the best siRNA sequence on target gene KRAS to ascertain the maximum gene-specificity and silencing efficacy and also designs the pair of oligonucleotides needed to generate short hairpin RNAs (shRNAs) in the plasmid. Then we synthesize the shRNA sequence from a DNA synthesis company (Genscript).

    Figure 1. The sequence of KRAS shRNA

    Usage and Biology

    We packaged KRAS siRNA into exosomes by transfecting HEK293 cells with a plasmid expressing KRAS siRNA and then collected siRNA-encapsulated exosomes. When modified exosomes being intravenously injected, they will specifically recognize integrin receptors and fuse with lung adenocarcinoma cells under the direction of the iRGD peptide. Once inside cells, KRAS siRNA will bind to KRAS mRNA through base-pairing and digest the mRNA, resulting in sharp decrease of K-ras in lung cancer cells. As a consequence, K-ras protein’s reduction and disturbed function will both result in the inhabitation of the proliferation of cancer cells, which ultimately have some therapeutic effects on lung cancer (non-small cell lung cancer in this case).

    Characterization

    Interference efficiency of anti-KRAS siRNA plasmid

    To ensure the interference efficiency of anti-KRAS siRNA plasmid, we transfected it into human lung adenocarcinoma cell line A549 and then extracted protein from these cells to perform western blot. Significant down-regulation of K-ras can be observed in A549 cells treated with anti-KRAS siRNA, demonstrating that anti-KRAS siRNA has the gene silencing effect on lung cancer cells.

    Figure 2. Protein quantitatively analysis of K-ras extracted from cells without any treatment (Nude) and cells transfected with control siRNA (NC, siRNA targeting a random sequence) or anti-KRAS siRNA, which was made for intuitively support that anti-KRAS siRNA can suppress K-ras expression.
  • settingsBBa_K1942002

    A coding sequence of iRGD peptide and position it outside the membrane.

    Usage and Biology

    iRGD is a tumor-penetrating peptide that can increase vascular and tissue permeability. Importantly, this effect did not require the drugs to be chemically conjugated to the peptide. To enhance the accuracy of drug delivery system and improve targeting index of drugs, iRGD peptide was displayed on the surface of the exosome containing our previously designed siRNA, allowing us to target recipient cells in vivo efficiently. Lamp-2b is a protein found specifically abundant in exosomal membranes. So we connect iRGD with Lamp2b by a glycine-linker, and promote the expression using cmv promoter. We engineered our chassis, human embryonic kidney 293 (HEK293) cells, to express iRGD-Lamp2b fusion protein. Therefore, the iRGD exosomes (iRGD-Exos) are endowed with site-specific recognition ability and were purified from cell culture supernatants and loaded with Dox by electroporation.

    Characterization

    The iRGD-Lamp2b expressing vector was thoroughly described in Tian’s article (Yanhua Tian, et al. Biomaterials, 2013). He showed that exosomes, endogenous nano-sized membrane vesicles secreted by most cell types, could deliver chemotherapeutics such as doxorubicin (Dox) to tumor tissue in BALB/c nude mice. To reduce immunogenicity and toxicity, mouse immature dendritic cells (imDCs) were used for exosome production. Tumor targeting was facilitated by engineering the imDCs to express a well-characterized exosomal membrane protein (Lamp2b) fused to αν integrin-specific iRGD peptide (CRGDKGPDC). Purified exosomes from imDCs were loaded with Dox via electroporation, with an encapsulation efficiency of up to 20%. iRGD exosomes showed highly efficient targeting and Dox delivery to αν integrin-positive breast cancer cells in vitro as demonstrated by confocal imaging and flow cytometry. Intravenously injected targeted exosomes delivered Dox specifically to tumor tissues, leading to inhibition of tumor growth without overt toxicity. The results suggested that exosomes modified by targeting ligands could be used therapeutically for the delivery of Dox to tumors, thus having great potential value for clinical applications in our project.

  • filter_dramaSilencing capability validation in vitro
    1.1 KRAS siRNA interference efficiency verification in vitro

    To ensure the interference efficiency of anti-KRAS siRNA, we transfected the plasmid loaded with this siRNA into human lung adenocarcinoma cell line A549 and extracted protein to perform western blot. Significant down-regulation of K-ras can be observed in A549 cells treating with anti-KRAS siRNA plasmid, compared with the control group, demonstrating that anti-KRAS siRNA has a gene silencing effect on lung cancer cells.

    Figure 3. Anti-KRAS siRNA transfected into A549 cells successfully reduced KRAS expression. Left panel: western blot analysis of KRAS protein levels in cells without any treatment (Nude) or treated with negative control siRNA (NC, siRNA targeting at a random sequence) and transfected with anti-KRAS siRNA using Lipo2000. Right panel: protein quantitative analysis made for intuitive support that anti-KRAS siRNA can suppress KRAS expression.
    1.2 TEM imaging of exosomes carrying KRAS siRNA and expressing iRGD peptide on their membrane

    After co-transfection of the two plasmids mentioned above, we performed a transmission electron microscopy (TEM) to characterize the iRGD-KRAS-siRNA-exosomes. The TEM image showed that the exosomes presented normal morphological characteristics after outside modification and siRNA loading, with a diameter of approximately 200 nanometer and a double-layer membrane.

    Figure 4. TEM image of iRGD-modified exosomes packaging KRAS siRNA
    1.3 Nanoparticle tracking analysis to ascertain the relationship between protein concentration and exosomes quantity

    We then asked NUDT_CHINA to help us perform nanoparticle tracking analysis (NTA) for a further evaluation of the quantity and size of secreted exosomes. The use of Nanosight enabled quantification and size determination of the extracellular vesicles, as nanoparticles can be automatically tracked and sized based on Brownian motion and the diffusion coefficient. The size of exosomes attained ranged around 270nm. Basing the particle size and relative intensity, we also created a 3D plot for a visual explanation. Under measurement condition listed, the exosomes secreted by HEK293 cells were assayed for 2.95 E8 particles each milliliter. Then the relationship between particle number and protein was determined that exosomes in 1 ng protein were equivalent to 6277.95 particles, according to the dilution multiple (24) and protein concentration (1127.756 ng/ul) we have tested. All the data collected helped us decide the transfection dosage of siRNA and dosing of treatment prepared for animal experiment.

    Figure 5. Nanoparticle tracking analysis (NTA) for Characterization of secreted exosomes. (a) Concentration of different particle sizes of exosomes. (b) 3D plot of particle size and relative intensity. (c) Experiment condition for our measurement. (d) Results attained after measurement of exosomes.
    1.4 The iRGD-KRAS-siRNA-exosomes suppressed KRAS expression in A549 cells in vitro

    We next evaluate the effect of iRGD-KRAS-siRNA-exosomes on KRAS expression in vitro. The KRAS expression level was assayed in A549 cells after co-cultured with exosomal KRAS siRNA. Non-loaded iRGD-exosomes were used as control to ascertain that any RNAi response observed did not derive from the exosomes per se. The western electrophoresis and knockdown data obtained from qPCR analysis of KRAS gene expression indicated that KRAS protein and mRNA levels both dramatically decreased in the cells incubating with iRGD-KRAS-siRNA-exosomes compared with cells treating with nude exosomes or without any treatment. This result suggests that iRGD-KRAS-siRNA-exosomes can deliver siRNA into target cells and finally reduce the KRAS expression.

    Figure 6. Quantitative RT-PCR analysis of KRAS mRNA levels in A549 cells without any treatment (NC), transfected with non-loaded exosomes (exosome) and transfected with iRGD-KRAS-siRNA-exosomes (siRNA-exosome) shows that exosomal KRAS siRNA can down-regulate KRAS expression in transcription level.
    1.5 The iRGD-KRAS-siRNA-exosomes efficiently arrests cancer cell proliferation in vitro

    KRAS over-expression has been demonstrated to promote the growth of lung adenocarcinoma cells and be involved in migration and invasion of lung cancer. For further verification, we examined the role of iRGD-KRAS-siRNA-exosomes in cell proliferation. An EDU assay using Cell-Light™ EdUTP Apollo®567 TUNEL Cell Detection Kit, was carried out after siRNA-iRGD-exosome incubation and as a control, nude exosomes were also treated to A549 cells. The result indicated that KRAS knockdown had an anti-proliferation effect on lung tumor cells while nude exosomes were not capable of inhibiting the growth of tumor cells.

    Figure 7. Cell proliferation assay for A549 cells treated with PBS or transfected with iRGD-KRAS-siRNA-exosomes (exosome). Left panel: Fluorescence microscope photos of A549 cells. The red points represent divided cells for cell proliferation rate calculation. Right panel: Quantitative analysis of cell proliferation rate, indicating that iRGD-KRAS-siRNA-exosomes can effectively suppress cell proliferation. (**: p < 0.01)
  • filter_dramaSilencing capability validation in vivo
    2.1 Establishment of none-small cell lung cancer mouse model with 40 mice to perform validation experiment in vivo

    The iRGD-KRAS-siRNA-exosomes can be released into A549 cells and suppress the expression of KRAS in vitro. To examine the consequence of KRAS knockdown by anti-KRAS siRNA in vivo, we built a non-small cell lung cancer mouse model for in vivo experiment. Forty mice were subcutaneously injected A549-LUC cells to realize tumor implantation. Then tumor volume were measured through bioluminescent imaging several times after injection. The areas that emit fluorescence in the mice bodies represent labeled tumors (tumors developed from the implanted A549-LUC cells), which helps us to monitor the tumor growth, location and metastasis.

    2.2 Mice were divided to receive different treatment, testing the function of iRGD-KRAS-siRNA-exosomes

    Mice were randomly assigned to 2 groups (n=20 per group) and treated differently. One group received PBS injections, the other group is treated with iRGD-KRAS-siRNA-exosomes via tail-vein injections. The administrations were given five times for 2 successive weeks since contamination of HEK293 cells resulted in exosomes shortage and the treatment of mice were delayed.

    Figure 8. In vivo imaging of tumor-bearing mice. The parts in the mice body representing the tumors xenografted with A549-Luc indicates that the tumors are relatively uniform in size. First panel: the imaging of tumor-bearing mice injected with PBS. Second panel: the imaging of tumor-bearing mice treated with iRGD-KRAS-siRNA-exosomes.
    Figure 9. Quantitative analysis of fluorescence intensity of tumors in mice after treatment of PBS or KRAS-siRNA-iRGD-exosomes (exosome). The intensity of tumor fluorescence in mice treated with KRAS-siRNA-iRGD-exosomes showed dramatically decrease compared with the group treated with PBS. (****: p < 0.0001)
    2.3 The measurement of tissues harvested indicates the function of KRAS siRNA on the tumor treatment

    Subsequently, mice were sacrificed for tumor harvest after in vivo imaging. All the tumors were measured for length, volumes and weight. Small pieces from every tumor was cut independently and fixed by paraformaldehyde to prepare for histopathological examination.

    Figure 10. Quantitative analysis of tumor weight measurement for mice treated with PBS or KRAS-siRNA-iRGD-exosomes (exosome).
    2.4 Pathological section to observe tumor cells

    After measurement of tumors, HE staining was conducted to verify the function of iRGD-exosomal siRNA. HE staining enabled better visualization of tissue structure and cell morphology, which can be used for morphological observation of normal and diseased tissue. The detection result showed that tumor cell necrosis rate in experimental group was much higher than control group. In other words, iRGD exosomes KRAS siRNA can effectively induce tumor cell necrosis and suppress cell proliferation

    Figure 11. Pathological section of tumor tissues from model mice treated with PBS or iRGD-KRAS-siRNA-exosomes (exosome).

    2.5 iRGD-KRAS-siRNA-exosomes reduce the KRAS expression in tumor cells in vivo

    Then, total protein and RNA were extracted from the rest tumor tissues to evaluate the expression level of KRAS in vivo. Results showed both KRAS protein and mRNA level were reduced in tumor cells of mice injected with KRAS-siRNA-iRGD-exosomes compared with mice treated with PBS. Though the down-regulation is not that evident, it still demonstrated that iRGD-KRAS-siRNA-exosomes can efficiently be delivered into tumor cells and regulate target gene expression, taking the short time of treatment into account.

    Figure 12. Quantitative RT-PCR analysis of KRAS mRNA level in tumor cells after treatment of PBS and KRAS-siRNA-iRGD-exosomes (exosome). (***: p < 0.001)

  • youtube_searched_forEndotoxin detecting of anti-KRAS siRNA-loaded exosomes

    Endotoxin is a type of natural pyrogen that was found in outer cell membrane of Gram-negative bacteria and can make impact on over 30 biological activities. To ensure the safety of our drug system, avoid toxicities, thus prove that our achievement is of great value for clinical application, a detecting assay was carried out using an endotoxin test kit. The result was negative, demonstrating that our drug system satisfies the safety requirement.

    Figure 13. Endotoxin detecting of anti-KRAS siRNA-loaded exosomes
  • checkAn efficient drug delivery system

    KRAS mutation was identified in NSCLC more than 20 years ago, but its clinical importance in cancer therapy just began to be appreciated. Our project aimed to develop a drug system that employed modified exosomes with iRGD peptide on its surface to deliver KRAS-siRNA into lung cancer cells specifically, thus target KRAS gene and down-regulate K-ras protein expression to treat lung cancer cases. Our results had demonstrated that iRGD-KRAS-siRNA-exosomes can be delivered into tumor cells and efficiently down-regulate KRAS expression both in vitro and in vivo. In silencing validation, we transfected KRAS siRNA into A549 cells using Lipo 2000 and performed western blot to test the function of our siRNA. Subsequently, we collected iRGD-modified exosomes loaded with KRAS siRNA, evaluating its effect on lung cancer cells (A549) by examining KRAS expression after transfection. The result confirmed that iRGD-KRAS-siRNA-exosomes could effectively down-regulate KRAS transcription level and reduce its protein expression. Later, the EDU assay further ascertained the biological role of KRAS siRNA in cell proliferation suppression in vitro.

    To perform in vivo validation, none-small cell cancer mouse model was established after implanting tumor in 40 mice by subcutaneous injection with A549-LUC cells. After a short-time treatment, tumors harvested from killed mice were measured, then protein and RNA extracted from these tissues were examined, results supporting that KRAS siRNA can efficiently suppress KRAS expression, inhibit cell proliferation and thus have its potential to be taken as a cancer treatment. Besides, endotoxin detecting validated that our drug system satisfies the safety requirement and won’t impact on biological activities. To be more meaningful, we purified the batch of iRGD-KRAS-siRNA-exosomes for liquid fill, completing a full process including experiment design, compounds synthesis, effect test and drug production.

    Figure 14. Exosome final products