Team:Rutgers

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The Next Step in DNA Synthesis

De novo DNA Synthesis is extremely important to the world of Synthetic Biology, but the low efficiency of today's DNA Synthesis technology limits us.

We can only synthesize about 100 bases at a time (explained below), so new genes have to be stitched together from smaller strands, which adds a lot to the time and cost required. This needs to change.

a primer on DNA synthesis

We currently use organic (anhydrous) solvents and reactive amidites to synthesize all custom DNA sequences, whether for antibody/enzyme engineering, multi-gene pathway building, or even genome construction. The process looks something like this:

This is one cycle in the process of DNA Synthesis. A solution of blocked nucleotides (whichever A, C, G, or T comes next in the sequence) is added to a group of immobilized DNA strands, and a single nucleotide is incorporated at the end of each strand. The trouble with this highly unnatural method is that each of the chemicals depicted (trichloroacetic acid, 2-benzylthiotetrazole, acetonitrile) causes some harm to the chemical structure of DNA, and this will limit the yield in a way that gets exponentially worse when building longer and longer pieces of DNA.

The process pictured above typically causes enough side-reactions to chemically "break" 1.5% of the existing DNA strands, in each and every cycle (leaving 98.5% of them intact and with correct sequence). This concept is called coupling efficiency, and it's the reason we can only synthesize up to 130-150 bases at a time (or even 200 bases if you're willing to pay a whole lot extra).

but it may be prudent to begin investigating more natural, aqueous environments for synthesis using enzymes evolved alongside nucleic acids for billions of years.

Abstract

In today's world we use organic solvents and reactive amidites to synthesize all custom DNA.
These methods are in need of improvement. The efficiencies are too low for many of today's applications.
It may be prudent to begin investigating more natural, aqueous environments that are chemically less harmful to the DNA during synthesis.
An aqueous synthesis environment would allow us to use the enzymes that have evolved alongside nucleic acids for billions of years.

WHY

Due to the inefficiencies of today's methods, even the best companies can only perform DNA Synthesis for 150 bases at a time.
This raises costs to the point where a typical enzyme will run you $300+ to synthesize the DNA for.
A Ribosome would cost thousands of dollars to create custom DNA for.
These prices need to be negligible if we want to see Synthetic Biology tech move as fast as computers (which have negligible coding costs).
Cost follows efficiency. If we begin using enzymes for DNA Synthesis, perhaps some cost barriers could be broken.

HOW

The best Polymerase for the job is Terminal Transferase, which adds dNTP's randomly to the 3' ends of DNA strands.
The principles of DNA Synthesis are as follows: A solution of blocked nucleotides (whichever A, C, G, or T comes next in the desired custom sequence) is added to the immobilized DNA strands, then the blocking group of the newly-incorporated terminal nucleoside is taken off (or "deblocked") and the next solution of nucleotides can be added.
By using enzymes, we can eliminate the harmful chemicals and conditions that cause all of today's side-reactions (which in turn limit efficiency and yield). For example, instead of using tetrazoles to activate the monomers, we can rely on the enzyme's catalytic machinery to specifically and efficiently promote the nucleotide additions that we desire.

Accomplishments

Established that TdT adds dTTP (unblocked) monomers until long tail ends are formed.
blocked time test
blocked pH test

Parts

Name	Type	Decription	Length
BBa_K1556000	coding	Mouse TdT	1590

Students

Kenny Kostenbader

Chem Eng

Scott Lazaro

Cell Bio & Neurosci

Wilson Wong

Mol Bio

Jay Patel

Chem Eng

Faculty

Sagar Khare

P.I.

Andrew Laudisi

Lab Manager

Attributions

Dr Jones is a professor in the Rutgers Chemistry Department who researches modified nucleotides. He gave valuable feedback on our initial project ideas, and suggested a way to create (and characterize) 3'-acetylated thymidine triphosphate in our lab. We attempted this synthesis (involving pyridine and acetic anhydride) and got promising results (via LC/MS), but then we found out that TriLink (below) could simply synthesize and purify it for us for free.

Arun Nayar was on last year's Rutgers iGEM team, so he helped train us with various lab protocols.

All of the pictured results on the Project page represent assays that were designed jointly by the students and Dr Khare, and carried out completely by the students in the lab. Additional help was provided by other Rutgers students as well, namely: Diego Barreto, Wesley Okwemba, Neil Patel, Harsh Patel, and Samantha Ashley.

Trilink Biotech supported the project by custom-synthesizing acetylated thymidine triphosphate, and supplying it free of charge.

NEB Inc supported the project by supplying a Terminal Transferase enzyme kit and a dNTP set, both free of charge.

Gen9 supported the project with a $500 donation.

Protocols

Click to download a copy of each protocol that we followed and/or wrote this summer: