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  • Overview
  • Device Designs
  • Safety

Project Description

Current medical practices are only able to scratch the surface of tissue engineering. Fortunately, nature has provided us with robust, cellular systems capable of governing the autonomous formation of complex structures. To pursue control of multicellular systems, we made use of three modules of biological parts. These modules include a signaling module, an internal logic processing module, and an output module for differential adhesion.

For the first module, we engineered the Notch-Delta juxtacrine signaling pathway, a ubiquitous system in animal development. The Notch-Delta system allows for cell-cell communication, a crucial element in symmetry breaking during development. We modified the existing Notch-Delta system to feed into an array of articial, introduced orthogonal molecular circuits, our second module. This module is responsible for integrating these signals to determine a certain cellular state. Once cells have fallen into different states in a desired pattern, one of the outputs from these states would be adhesion in order to hold our cells together to maintain pattern formation. We introduced cadherin, a natural intercellular glue.

To understand and predict multicellular behavior, we developed a simulation framework based on the Synthetic Biology Open Language (SMOL) and CompuCell 3D modelling environment. Our models motivated several circuit designs we subsequently tested in the laboratory. Altogether, our developments establish a paradigm for manipulation of intercellular communication systems to drive self-assembly of ever more complex patterns and tissues.


Device Designs

Elowitz Sender

MITE-S1.png

In this circuit, found in the "receiver" type CHO cells from Elowitz, CMV-TO is normally inhibited by TetR. This inhibition itself is inhibited by doxycycline binding to TetR. In this way, we can turn on expression of Delta-mCherry with dox in a modulated fashion

Elowitz Receivers

MIT CMV cerulean.pngMITE2.pngMITE3.png

These genetic constructs have been stably integrated into our "receiver" type Elowtiz CHO cells. CMV (from the cytomegalovirus) is a strong constitutive promoter that will express Cerulean (a cyan fluorescent protein) and Notch. When Notch is bound by Delta, the Gal4esn is cleaved off and can activate expression of genes downstream of UAS.

Hef1a:Gal4-VP16, UAS:Reporter

MIT OO1.png

This circuit represents the behavior of the Gal4 activator. Hef1a is a constitutive promoter that will express Gal4-VP16 that can later bind to a UAS promoter, leading to the expression of downstream reporter genes.

Hef1a:LacI, Hef1a-LacOid:eYFP

MIT Fix1.png

Here we represent the activity of the LacI inhibitor. LacI binds to the upstream LacO site and can inhibit expression of downstream reporter genes.

Hef1a:Gal4-VP16, UAS:LacI, Hef1a-LacOid:eYFP

MIT Fix2.png

Here we see a circuit that integrates the two systems described above. By tying LacI expression to the Gal4/UAS system, we can activate expression of lacI by GV16 and thus inhibit expression of a reporter gene. This results in overall repression of reporter expression.

Gal4-VP16, UAS_NCad-2A-eYFP

MIT LastMinute1.png

Here we created a part that is activated by the Gal4-VP16 transactivator to produce N-Cadherin joined to eYFP by a 2A tag, which is cleaved to result in the expression of both proteins.

Hef1a:rtTA3, TRE:Mnt-VP16, minCMV-4xMnt:mKate

MIT F1.png

Here we represent a circuit that has an upstream rtTA3 system feeding into the Mnt activator system. When bound by doxycycline, rtTA3 is capable of inducing expression at the TRE promoter. This in turn leads to expression of the activator Mnt-VP16 which can bind to Mnt sites and activate expression of the reporter gene (mKate, a red fluorescent protein, in this case).

Hef1a:rtTA3, TRE:CI434-VP16, minCMV-1xCI434:mKate

MIT LAST CIRCUIT.png

This circuit is very similar in design to the above, instead using a different orthogonal activator-promoter pair: CI434. In this schematic, doxycycline induced expression of CI434 leads to activation of reporter expression downstream of the CI434 binding site (minCMV-1xCI434).

Safety

Would any of your project ideas raise safety issues in terms of:

  • researcher safety,
  • public safety, or
  • environmental safety?

This summer, our team worked on cell patterning in mammalian cells. Part of our team worked with E. Coli in a BL1 lab, and a smaller group worked with mammalian cells in a BL2 lab. Both groups within the team adhered to national and local safety protocols. Extra care was taken not to cross-contaminate lab spaces. Cross contamination from these settings was minimized by designating specific equipment for mammalian cells and for bacteria, as well as immediately changing personal protective equipment when moving between the different lab spaces.

Do any of the new BioBrick parts (or devices) that you made this year raise any safety issues? If yes,

  • did you document these issues in the Registry?
  • how did you manage to handle the safety issue?
  • how could other teams learn from your experience?

Our bacteria and our mammalian cells do not contain any BioBrick parts that code for hazardous proteins or molecules. We also determined that none of our circuits would survive if released outside the lab and thus, the circuits pose no safety concerns to researchers, the public, or the environment.

Is there a local biosafety group, committee, or review board at your institution?

  • If yes, what does your local biosafety group think about your project?

The EHS (Environment, Health, and Safety) Office is MIT's biosafety group that enforces lab safety in all labs on campus. They provide safety training, waste management services, and resources for safe lab practices. The safety training included General Biosafety for Researchers, Managing Hazardous Waste, General Chemical Hygiene, lab-specific training, and Bloodborne Pathogen Training. All undergraduates were trained by the EHS to work safely in BL1 labs, and students working with mammalian cells received BL2 lab safety training. EHS is an integral part of our biosafety system and continues to be involved by conducting daily lab safety inspections.

Do you have any other ideas how to deal with safety issues that could be useful for future iGEM competitions? How could parts, devices and systems be made even safer through biosafety engineering?

Our MammoBlock construction standard not only aids in the construction of mammalian parts but also facilitates safer and easier storage of these parts. The MammoBlock standard uses bacterial entry vectors which allows mammalian parts to be stored in BL1 conditions.

Our team is greatly concerned with the safety issues regarding future iGEM research, especially relating to mammalian cells. This standard has allowed us to enter mammalian parts into the registry, and will facilitate the safe shipping and submission of mammalian parts constructed by future iGEM teams. and competitions.