Team:Valencia UPV/Modeling

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Modeling

Do you think it is possible to mathematically describe a cell? Would you like to know the possibilities that Printeria modeling offers you?

One of the fundamental bases of the Printeria project has undoubtedly been mathematical modeling. Thanks to the development and application of new mathematical models, it is possible to quantify the expression of proteins in cells, and therefore characterize through different experiments the parts designed by Printeria. From the Printeria modeling team, we intend to reach different goals:

  • Design simple mathematical models based on differential equations that describe the biochemical processes of a cell. With them, we can simulate the different genetic circuits that Printeria allows us to build.

  • Develop a Simulation Tool that allows the user to visualize a prediction of the results of their experiment before running it in Printeria.

  • Optimize model parameters to match simulation results to experimental data obtained from Printeria constructions.

  • Characterize the parts of our Part Collection from the optimization results and provide the user with all the information about the Printeria kit.

Although in the development of the project we have dealt with all these aspects, all of them have a single purpose: to understand and describe in a mathematical way the biological processes that take place inside the cell.

Models & Experiments

Characterisation procedures

Simulation Tool

Models & Experiments

Characterisation procedures

Valencia UPV iGEM team has designed an extensive Part Collection in purpose of allowing the user to design multiple genetic constructions and experiments. One of our main objectives has been to show the user clear and structured information about the pieces that make up the Printeria kit. For this reason, we have considered the characterization of the parts as a priority when developing the project. In this way, we have elaborated some procedures which have allowed us to systematically obtain and structure information from the parts.

Procedure for obtaining protein spectra

Obtaining excitation and emission spectra is a fundamental aspect in the process of characterization of a fluorescent protein. Each protein has a characteristic spectrum, which indicates the energy in which the molecule is excited or emits at a certain wavelength.

Owing to this reason, a protocol has been established in the lab by Lab and Modeling team to obtain the spectrum of any reporter protein.

Materials:

  • Measuring equipment: Biotek Cytation3

  • 96 well plate

  • MATLAB 2018a software

Method:

  1. We look for the theoretical spectra of the protein to be measured (or similar molecules) to determine the wavelength at which the protein is excited or emitted at maximum energy, i.e. where the theoretical spectral peaks occur.

  2. We define the protocol of our equipment to get the absorbance and fluorescence dataset. In our protocol, the most important parameters to be established are the following:

Comparison between sfGFP and GFP relative fluorescence intensity

Simulation Tool

CONTACT US igem.upv.2018@gmail.com