Difference between revisions of "Team:ColumbiaNYC"

Line 147: Line 147:
 
     slides[slideIndex-1].style.display = "block";   
 
     slides[slideIndex-1].style.display = "block";   
 
     dots[slideIndex-1].className += " active";
 
     dots[slideIndex-1].className += " active";
     setTimeout(showSlides, 3000); // Change image every 3 seconds
+
     setTimeout(showSlides, 2000); // Change image every 3 seconds
 
}
 
}
 
</script>
 
</script>

Revision as of 18:22, 2 August 2017

SilenshR

developing an shRNA-induced Silencing Therapy for Cancer

1 / 3
In 2010, cancer costs exceeded $2.5 trillion
2 / 3
Our team proposes to use shRNA to knockdown the expression of aberrant oncogenes and consequently treat cancer. Taken in the form of a probiotic oral treatment, SilenshR is more accessible than most contemporary treatments such as chemotherapy and radiation therapy.
3 / 3
With the appropriate shRNA sequence, this products lends itself to many various applications. Its great versatility allows it to be a useful therapeutic avenue in the field of medicine.

The Advantages to a Synthetic Biology Approach

A cornerstone in synthetic biology is the connection of distinct biological functions to create useful system level behavior. We can take advantage of how bacteria naturally localize in tumors while failing to survive in healthy tissue in the body to use bacteria as a cancer-specific delivery mechanism. Also, bacteria can mass produce products, invade cells, and release the products directly into the cells. This allows easily-degraded compounds to be effective delivered into cancer cells. It also prevents these compounds from affecting healthy cells. The combination of these mechanisms creates a powerful, cancer-specific circuit for gene therapy.

Expanding the Possibilities of Gene Therapy

Anticipating the applications of synthetic biology to healthcare, Columbia iGEM 2017 is devising a therapeutic approach to modulate mammalian gene expression at the post-transcriptional level. Recombinant E. coli with the capacity to invade mammalian cells will deliver an shRNA payload against an aberrantly expressed gene, for example an oncogene in cancer or proinflammatory cytokine in inflammation, to the host cytoplasm. This shRNA payload will then inhibit protein function, which can combat mutations that confer resistance to traditional therapies, as with the tyrosine kinase inhibitors gefitinib and imatinib.

The Future Outlook

Our mechanism to modulate mammalian gene expression can have a variety of applications, extending throughout as well beyond healthcare. The engineered bacteria would have a significant application to human health particularly in conditions characterized by aberrant gene expression, such as with oncogenes in cancer, cytokines in inflammation, and many others. For cancer applications, the engineered bacteria can be taken as an oral probiotic, which will then selectively localize in tumor cells to prove gene therapy.