Harvard 2006

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*Our design consisted of a streptavidin aptamer and thrombin aptamer linked together by a short, variable-length double-stranded region of linker DNA.
*Our design consisted of a streptavidin aptamer and thrombin aptamer linked together by a short, variable-length double-stranded region of linker DNA.
*In order to prevent interaction of linker DNA with aptamers, we wrote a program that can evolve a sequence for the linking region given two aptamer sequences. This program can be used for any aptamer sequences and will be utilized for future adaptamer designs.
*In order to prevent interaction of linker DNA with aptamers, we wrote a program that can evolve a sequence for the linking region given two aptamer sequences. This program can be used for any aptamer sequences and will be utilized for future adaptamer designs.
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*We successfully showed that four separate adaptamer designs are capable of targeting thrombin to streptavidin-coated magnetic beads by probing targeted beads with thrombin antibodies.
+
*We successfully showed that four separate adaptamer designs are capable of targeting thrombin to streptavidin-coated magnetic beads by probing targeted beads with thrombin antibodies (see gallery).
*We successfully showed that addition of a low concentration of displacement strand which breaks apart adaptamers was capable of quenching adaptamer function (see gallery).
*We successfully showed that addition of a low concentration of displacement strand which breaks apart adaptamers was capable of quenching adaptamer function (see gallery).
*Interestingly, high concentrations of displacement strand led to greater maintenance of thrombin targeting. See Project Notebook for details. We have proposed a lever-hypothesis for this observation (see gallery).
*Interestingly, high concentrations of displacement strand led to greater maintenance of thrombin targeting. See Project Notebook for details. We have proposed a lever-hypothesis for this observation (see gallery).

Revision as of 02:21, 30 October 2006


Harvard University 2006 iGEM Team
HarvardTeamPhoto2006.jpg
Students
  • Tiffany Chan
  • Katherine Fifer
  • Lewis Hahn
  • Hetmann Hsieh
  • Jeffrey Lau
  • Valerie Lau
  • Matthew Meisel
  • David Ramos
  • Zhipeng Sun
  • Perry Tsai

Teaching Fellows

  • [http://openwetware.org/wiki/User:Doucette Chris Doucette]
  • [http://openwetware.org/wiki/User:ShawnDouglas Shawn Douglas]
  • [http://openwetware.org/wiki/User:Stroustr Nicholas Stroustrup]

Faculty Advisors

  • [http://arep.med.harvard.edu/ George Church] (HMS)
  • [http://www.eecs.harvard.edu/~rad/ Radhika Nagpal] (DEAS)
  • [http://hst.mit.edu/biosketch/Shah.html Jagesh Shah] (HMS)
  • [http://research2.dfci.harvard.edu/shih/ William Shih] (HMS)
  • [http://silver.med.harvard.edu/ Pamela Silver] (HMS)

The Harvard University 2006 iGEM Team

This year Harvard's team consisted of 10 undergraduate students, with backgrounds in molecular and cellular biology, biochemistry, and computer science. With the help of five faculty advisors and three graduate-level teaching advisors, they devised and executed three separate projects.

1. Construction of novel DNA nanostructures for the purpose of stealth drug delivery,

2. Exploration of cell-surface targeting using interchangable and linkable aptamers (adaptamers) and Lpp-OmpA fusion vehicle for bacterial surface display.

3. Reconstitution of a circadian oscillator from cyanobacteria into E. coli,


DNA Nanobox: A Nanoscale Device for Stealth Drug Delivery

Project Overview

  • Traditional drug delivery is fairly low-tech. Tablets containing a mixture of active small molecules and binders are ingested, and the small molecules circulate non-specifically throughout the body. Even when a specific cell or tissue type is targeted (e.g. cancerous cells or bacterial infections), many other tissues are exposed to the drugs, often with serious side effects. We envision a future in which medicines will be delivered in a highly specific manner to targeted tissues and cell types, and set out to make initial steps toward realizing this vision.
  • Our goal for the summer was to design and implement nanoscale molecular containers, which could be dynamically opened and closed by an external stimulus. This is the first step to making more sophisticated drug-delivery vehicles.
  • The containers were implemented as DNA nanostructures, which afford a significant degree of positional control and chemical versatility.
  • To demonstrate that our designs successfully self-assembled, we used negative-stain electron microscopy to visualize the containers.
  • As an initial proof-of-concept, we planned to demonstrate that our DNA containers could be used to "protect" biotinylated oligonucleotides from binding by streptavidin-coated magnetic beads.
  • We were able to successfully show that nanoboxes with internal biotinylated oligonucleotides did not bind to streptavidin-coated magnetic beads, while nanoboxes that were externally decorated with biotinylated oligonucleotides were bound by the same beads.

Results

  • The following images show our most successful container design, both as a 3D cartoon and in actual negative-stain EM images. The length, width, and depth of this container design is approximately 30x30x30 nanometers, so it is bigger than a typical ribosome.
  • More details about this design can be found [http://openwetware.org/wiki/IGEM:Harvard/2006/Container_Design_5 here].
  • The basic design of this container is a hexagonal barrel, closed off by two flat lids.
  • The lids are designed to reversibly attach to the barrel using complementary oligonucleotides using a "toehold" strategy in which the strands include unpaired overhangs that can be displaced with the addition of oligos that match for the full length of the sequence.


Future Plans

  • We have demonstrated the first steps toward building a sophisticated, versatile drug delivery vehicle out of DNA.
  • Short term plans include assembly of closed containers (which include lids), and further characterization of assembled structures (both imaging and functional assays). We have not determined the maximum size for a molecule that can still diffuse between DNA helices that comprise our container, but for a closed container we expect it to be around 1 nanometer in diameter.
  • In the long term, we envision designing containers that incorporate cell-surface targeting mechanisms that would allow delivery of a payload to a specific cell type. Advances also need to be made if the container is going to deliver small molecules - perhaps by encapsulating the container with a liposome (or vice versa).

Electronic Notebook

  • [http://openwetware.org/wiki/IGEM:Harvard/2006/DNA_nanostructures openwetware page]

Cell Surface Targeting

Adaptamers

Project Overview

  • In order to target nanostructures to cells, we developed adaptamers, universal nucleic acid adaptars which can link two substrates.
  • Such an interface could also be used to link together entire cells for the study of cell-cell interactions and the linkage of two interacting proteins, in effect creating a nucleic acid enzyme.
  • Adaptamers generally depend on aptamers, short sequences of nucleic acid that bind with high specificity and affinity to particular substrates.
  • Tahiri-Alaoui et al. created the first aptamer in 2002, consisting of two aptamer sequences linked together by a bulky basepairing region ~100 nucleotides long.
  • Our goal was to create an adaptamer that could link together streptavidin and thrombin. Delivery of thrombin to a streptavidin-coated magnetic bead would show the potential for delivery of a macromolecule to a cell surface (see gallery).
  • Additionally, we wished to be able to be able to quench adaptamer function through the addition of an adapatamer-disabling oligonucleotide (see gallery).

Results

  • Our design consisted of a streptavidin aptamer and thrombin aptamer linked together by a short, variable-length double-stranded region of linker DNA.
  • In order to prevent interaction of linker DNA with aptamers, we wrote a program that can evolve a sequence for the linking region given two aptamer sequences. This program can be used for any aptamer sequences and will be utilized for future adaptamer designs.
  • We successfully showed that four separate adaptamer designs are capable of targeting thrombin to streptavidin-coated magnetic beads by probing targeted beads with thrombin antibodies (see gallery).
  • We successfully showed that addition of a low concentration of displacement strand which breaks apart adaptamers was capable of quenching adaptamer function (see gallery).
  • Interestingly, high concentrations of displacement strand led to greater maintenance of thrombin targeting. See Project Notebook for details. We have proposed a lever-hypothesis for this observation (see gallery).

Future Plans

  • We will demonstrate the modular design of adaptamers by using an adaptamer to target thrombin to Jurkat cells.
  • We will attempt to prove the lever-hypothesis.

Electronic Notebook

  • [http://openwetware.org/wiki/IGEM:Harvard/2006/Adaptamers/Overview openwetware page]

Cell surface streptavidin

Project Overview

  • The cell surface streptavidin project approaches targeting from a different direction, that is, from the cell. While the adaptamer project uses nucleic acids to target any two substrates to each other, the cell surface streptavidin project seeks to target any substrate(s) to the cell surface.
  • The method of targeting would be through the expression of streptavidin protein on the cell surface. Streptavidin is a protein which binds strongly to the biotin molecule, thus there is a common practice of biotinylating (adding biotin to) nucleic acids or peptides for streptavidin affinity purification or antibody conjugation. We would be utilizing this strong streptavidin-biotin binding to target any biotinylated nucleic acid or peptide to the outside of a cell expressing streptavidin on the surface.

Results

Future Plans

Electronic Notebook

  • [http://openwetware.org/wiki/IGEM:Harvard/2006/Fusion_proteins openwetware page]

A Circadian Oscillator for E.coli

Project Overview

  • Oscillators are used in a variety of electronic circuits and would be essential in complex, time-dependant biocircuitry. The synthetic "repressilator" system engineered by Elowitz et al. (2000), though a good proof of concept, lacks the stability needed for long-term usage.
  • In cyanobacteria, a naturally evolved oscillator exists that relies on the interactions between three proteins, labeled KaiA, KaiB, and KaiC. This oscillator is robust and can be modified for longer and short periods by point mutations (Kondo et al. 1994). In addition, the proteins do not need transcriptional regulation and have been found to oscillate in vitro (Nakajima et al. 2005)
The Kai Protein Interactions


  • Based on these discoveries, our goal for the summer was to reconstitute the Kai oscillation cycle in E. coli. This would be the first step in creating a new oscillator part for the registry, as well as providing an important breakthrough for circadian biology research.
  • Since the ways in which the Kai proteins affect transcription factors in cyanobacteria is not well known, we would measure expression and interaction in E. coli by recording phosphorylated and unphosphorylated KaiC on Western blots.

Results

  • As our recent Western blots show, we were able to express the three proteins in E. coli, and show interaction between A+C and possible interaction between B+C.
KaiC Western Blot Results


Future Plans

  • Short term plans include confirming our previous Western blot results as well as confirming interaction between KaiA, KaiB, and KaiC.
  • In cyanobacteria, a mechanism exists by which the Kai clock is reset by a period of darkness. This serves to synchronize the phosphorylation cycle of KaiC as well as the other Kai proteins. However, this mechanism is not yet well known (except that it relies on something besides the three Kai proteins), and so it cannot yet be reconstituted in E.coli. We have designed a set of experiments aimed at synchronizing all of the Kai molecules within each cell, as well as between different cells. The goal here would be to create a colony of E.coli cells oscillating on a single circadian cycle.
  • As more is discovered concerning the ways in which the Kai cycle affects transcription in cyanobacteria, we would ideally like to be able to hook up complex behaviors that depend on the rhythm provided by the Kai circadian clock.

Electronic Notebook

  • [http://openwetware.org/wiki/IGEM:Harvard/2006/Cyanobacteria openwetware page]

Complete Electronic Notebooks

Detailed records of our summer activities, including results, can be found on openwetware, which the team used to host its [http://openwetware.org/wiki/IGEM:Harvard/2006 electronic notebook]. Links to specific project pages can be found in the above descriptions.

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