Team:MIT

From 2013.igem.org

(Difference between revisions)
Line 19: Line 19:
<p>This summer, the 2013 MIT iGEM team worked to engineer exosome mediated cell-cell communication. In vivo cell-cell communication is vital for pattern formation, organ development, coordinated responses to environmental changes, and the maintenance of an organism (Bacchus, 2012)</p>
<p>This summer, the 2013 MIT iGEM team worked to engineer exosome mediated cell-cell communication. In vivo cell-cell communication is vital for pattern formation, organ development, coordinated responses to environmental changes, and the maintenance of an organism (Bacchus, 2012)</p>
<h1>Our Contribution</h1>
<h1>Our Contribution</h1>
-
<p>The 2013 MIT iGEM demonstrated that exosomes can be engineered to transport protein and miRNA signals of interest. These signals remain functional can actuate a response in a receiver cell. By co-culturing sender and receiver cells, we have demonstrated exosome mediated one-way cell-cell communication. </p>
+
<p>We demonstrated that exosomes can be engineered to transport protein and miRNA signals of interest. These signals remain functional and can actuate a response in a receiver cell. By co-culturing sender and receiver cells, we have demonstrated exosome mediated one-way cell-cell communication. </p>
<h1>Our Vision</h1>
<h1>Our Vision</h1>
-
<p> The MIT iGEM teams believes that exosomes provide an innovative means of engineering cell-cell communication that can have exciting application in drug testing and development. Tissue engineers are currently working to develop organoids small tissue structures that recapitulate the behavior of organs in vitro  (Lancaster, 2013). Organoids can be used to test drugs more rigorously in a human-like context rather than relying solely on animal models. Thus drugs can be developed with a better understanding of their toxicity and efficacy. These multicellular structures require cell-cell communication, and our exosome mediated communication system could serve as an enabling technology for organoid development<p>  
+
<p> Exosomes provide an innovative means of engineering cell-cell communication that can have exciting application in drug testing and development. Tissue engineers are currently working to develop organoids small tissue structures that recapitulate the behavior of organs in vitro  (Lancaster, 2013). Organoids can be used to test drugs more rigorously in a human-like context rather than relying solely on animal models. Thus drugs can be developed with a better understanding of their toxicity and efficacy. These multicellular structures require cell-cell communication, and our exosome mediated communication system could serve as an enabling technology for organoid development<p>  
<p> Lancaster, Madeline et al. Cerebral organoids model human brain development and microcephaly. Nature 501, 373–379 (2013)  
<p> Lancaster, Madeline et al. Cerebral organoids model human brain development and microcephaly. Nature 501, 373–379 (2013)  
</p>
</p>

Revision as of 03:48, 29 October 2013

iGEM 2012

Motivation

This summer, the 2013 MIT iGEM team worked to engineer exosome mediated cell-cell communication. In vivo cell-cell communication is vital for pattern formation, organ development, coordinated responses to environmental changes, and the maintenance of an organism (Bacchus, 2012)

Our Contribution

We demonstrated that exosomes can be engineered to transport protein and miRNA signals of interest. These signals remain functional and can actuate a response in a receiver cell. By co-culturing sender and receiver cells, we have demonstrated exosome mediated one-way cell-cell communication.

Our Vision

Exosomes provide an innovative means of engineering cell-cell communication that can have exciting application in drug testing and development. Tissue engineers are currently working to develop organoids small tissue structures that recapitulate the behavior of organs in vitro (Lancaster, 2013). Organoids can be used to test drugs more rigorously in a human-like context rather than relying solely on animal models. Thus drugs can be developed with a better understanding of their toxicity and efficacy. These multicellular structures require cell-cell communication, and our exosome mediated communication system could serve as an enabling technology for organoid development

Lancaster, Madeline et al. Cerebral organoids model human brain development and microcephaly. Nature 501, 373–379 (2013)

Sponsors