Part:BBa_K4189012

_NOTOC__ PP5

Introduction

s we all know, plastic is not biodegradable. Indeed, it’s created from fossils such as crude oil and heated to create strong polymers that cannot be found in nature which results in micro-organisms that didn’t evolve to attack these strong and high energy-demanding bonds. That is why we tried to find and modify adherence proteins that bind our degradation system to the chosen plastics.

Usage and Biology

it’s one peptide that is normally capable of binding to a PP plastic

The patent in which we found the peptides is the following one: Cunningham, S.D., Ford, C., Lowe, D.J., O’Brien, J.P., Sq, K., and Wilkins, A.E. (54) POLYPROPYLENE BINDING PEPTIDES AND. 55.

Sequence and Features

Assembly Compatibility:

10
COMPATIBLE WITH RFC[10]
12
COMPATIBLE WITH RFC[12]
21
COMPATIBLE WITH RFC[21]
23
COMPATIBLE WITH RFC[23]
25
COMPATIBLE WITH RFC[25]
1000
COMPATIBLE WITH RFC[1000]

Characterization

The promoter was characterized using GFP to measure gene expression at different concentrations and on various plastics to check its affinity and specificity. To do so, we inoculated E. Coli BL21 strain with pET GFP in LB-medium, and after inoculation, we induced and purified it in an Econocolumn Biorad.

The GFP was used as a tracker to be able to, during our adhesion tests to quantify the protein that adhered to the plastic by using a fluorometer.

Adherence tests

We had some issues finding and creating the proper protocol since we wanted consistent qualitative, and quantitative results. To start, we used the test of another iGEM team as a base to then modify it for our own tests: https://static.igem.org/mediawiki/2019/c/c8/T--Kyoto--wikimethod.pdf

They created the following part of it: Part: BBa_K3185007

First, we created a little contraption where our solution was put on glass tubes upside-down during a set time to keep the surface contact size uniform for each and every test.

Then, we decided to use 50 μL droplets, creating a perfect dome on the desired plastic. |400px|Figure 1. 50 μL droplets

We also prepared a dilution at ¼ of the solution to know to what extent the concentration helps the adherence. We then used a Tecan, a Fluorescence Microplate Reader, to quantify the GFP left on the plastic after three washes.

Results

Fluorometer result for PP5 :

	Elution (PP)	Droplet (PP)	Elution (PE)	Droplet (PE)	Replica (PP)
Result	C1. 42 631 C2. 5206	C1. 9241 C2. 722	C1. 12 680 C2. 5483	C1. 8063 C2. 1682	C1. 12 021 C2. 4360
SDS alone	C1 3441	C1 3408	C1 3902	C1. 2816	C1. 2000
GFP alone	C1. 4428 C2. 2640	C1. 27549 C2. 523	C1. 11 800 C2. 4288	C1. 1130 C2. 317	C1. 3998 C2. 3997

Elution(PE) means that the protein was put in contact with a PE plastic and Elution(PP) was put in contact with a PP plastic.

Elution PP has a stronger signal than SDS alone and GFP alone whether it is in the first concentration (350µg/µL) or at that diluted to 1/4. This means the protein has adhered correctly to the PP plastic. The protein in contact with PE plastic has a stronger signal than the GFP, meaning that this protein can also adhere to PE. Even if the signal between GFP and Elution(PE) is not that great, the peptide still adhere to PE plastics. There is no specificity of adherence for this protein.