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Revision as of 18:41, 17 October 2016

Table of contents

Introduction

In the twelfth iGEM edition happens the third Interlab Study. This study is based on the characterization of standard biological parts and, as standard parts, it is fundamental to observe reproducibility and repeatability on their behaviour. For instance, even well characterized promoters in a given strain of E. coli may behave reasonably different in another strain. Acknowledging this challenge, the Interlab Studies is a way to gather experiments from all around the world and provide a more unified understanding about the fundamental building blocks of Synthetic Biology. Until last year, each research team had its own strains, plasmids and protocols, however, in an attempt to standardize the obtained data, specific protocols and calibration samples were provided for each iGEM team attending the Interlab 2016. With this approach, we can construct a rich knowledge base of standard biological parts, together with several study cases of different protocols and other details. The value this have to the whole community of Synthetic Biology is beyond doubt.

We have done not only the standard plate reader, cuvette-based and flow cytometry assays, but also tested for better measuring conditions (LB and M9 media) and for alternative methods ranging from DIY ones (digital camera and fluorimetric-based methods) to single cell analysis by fluorescence microscopy. We have also evaluated the promoter strength of all devices by Relative Promoter Units [2] using DH5α E. coli harbouring all devices and controls. Results show interesting differences: Device 2 (J23106) shows half the strength it would be expected in the original library. Thus, we have fulfilled both the InterLab study the extra credit requirements by searching for optimized measurement protocols and generating new cheaper and accessible approaches for assessing promoter strength.

Macroscopic analysis

Imagine you are a Biohacker or someone very interested in Science stuff, but you have no money… How could you avoid expensive high-end equipment and yet, still obtain some data about the promoters you love?

In order to do so and draw a sketch of our promoter’s strength we have followed and updated the 2015 USP_Brazil iGEM team approach for an inexpensive and quick analysis by taking digital photos and analyzing them on open-source softwares for image processing (GIMP and ImageJ)

All test devices and controls were grown on both solid (LB-Agar) and Liquid (LB and M9) media and photos were taken by a regular cellphone under the effect of fluorescent white or blue light lamps (for exciting GFP reporter molecules). The choice of comparing both LB and M9 liquid media was based on an extensive number of reports regarding the influence of auto fluorescence of LB on measurements. Thus, we wanted to have check if the outcome of this effect would be so strong that it could be visually detected.

On a direct analysis under the blue light lamp, we can observe that there is a huge difference between M9 and LB samples (Figure 2). While we can easily observe different degrees of GFP expression on M9, it is almost impossible to do so on LB due to its intrinsic fluorescence. Even though, on both media, TD1 seems to be the strongest promoter, followed by TD2, which is similar to PC and stronger than TD3 (easier to see on M9). The last test device, TD3, seems to behave very similarly to the negative control. To sum up, at a first glance, our promoter’s strength rank is:

TD1 > TD2 = PC > TD3 = NC

Figure 2 Comparison between fluorescence of Test Devices on both M9 and LB. While M9 allows us to easily compare fluorescence intensities the same is not true for LB samples due to its auto fluorescence effect.

Fluorescence Spectrometer analysis

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Plate Reader analysis

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Microscopic analysis/single cell:Fluorescence Microscopy and Quantitative analysis by IMAGEJ

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Discussion

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