Team:Paris Bettencourt/Project/Enzyme

Abstract

Anthocyanins, the key pigments present in wine, are polyphenolic molecules that are naturally found in many plants. In this part of our iGEM project we turn to nature in the search for enzymes with the potential ability to degrade these pigments for expression in E. coli. Three potential wine stain removers, BpuI, CatA and XylE, were successfully expressed in E. coli and are ready to be tested for their ability to degrade anthocyanins. To take their stain removal capacity to the next level, we discovered peptide binding domains that supported the localization of the enzymes to cotton, wool, linen and silk. Here we also showed that enzymes XylE and CatA maintained their activity when fused to our Fabric Binding Domains. We believe that our fabric-specific enzyme detergents have opened a new door for the development of innovative laundry products.

Motivation and Background

Nature, from inspiration to a canvas

Polyphenol degrading enzymes

Fabric Binding Domain fusion proteins - enhancing of wine stain degrading properties

Results

Outline of the project

Confirming expression of our proteins

After obtaining E. coli BL21(DE3) strains able to express our polyphenol degrading enzymes, we decided to focus our work on four of them, BpuI, CatA, XylE and BG1. We decided to postpone the experiments with PPO2, since due to its origin in plants, its expression in E. coli was the most demanding out of the set of proteins. We also decided to postpone the experiments on TanLpI due to the fact that it forms inclusion bodies, which ones again demands a complicated setup to make functional.
The first step was to check whether we were correctly expressing our proteins of choice. Figure 3 shows an SDS-PAGE analysis of the cell extracts performed with the cells in which expression of the proteins was induced. The cell extract protocol can be seen in the methods part of this project.

Overexpression of three of the four enzymes was achieved. BG1, although very promising, was not correctly expressed, and therefore we continued our experiments with BpuI, Cat and XylE alone.

Testing our enzymes in their natural substrate

The next natural step was to test whether the overexpressed proteins were functional. We performed cell extracts of BpuI, CatA and XylE enzymes and measured their activity using the appropriate substrates.

In all cases, the proteins were demonstrated to be functional. All three cell extracts carrying them were able to degrade their natural substrates more than the control.

Testing the effect of fusing FBD with proteins

The following step was to construct our fusion proteins, fusing Fabric Binding Domains to our best performing enzymes.
First, we needed to understand whether it was feasible to build a functional FBD-enzyme fusion protein. We needed to understand if the joining together of the two parts would have a negative effect on the binding capacity or in the enzyme itself.
An easy way of testing the feasibility of these constructs is to test the FBDs with GFP first. We constructed fusion proteins with the several FBD on the N'-terminal, since it was the terminal the binding domains were recommended to be placed at.

In figure 5 we can see that some FBDs show high affinity to certain fabrics, and some are even specific. In the case of FBD2, it shows high affinity and specificity for both cotton and linen. This FBD binds poorly to silk and wool, which is interesting given that both cotton and linen are plant-fiber-based, and silk and wool come from animal sources.
FBD5 shows affinity to all four fabrics, and has no specificity for any of them.
Interestingly, most FBDs have affinity for silk, which is very useful in the development of our product given that through our human practises we were able to get to know that silk is one of the most demanding fabrics when it comes to stain removal.
Different washing solutions also influenced differently the several FBDs. For example, FB10 performs very well when washed with water in silk and wool, but performs very badly when washed with the same solution in cotton and linen.

Figure 6 can have two interpretations: either the binding of the FBDs affects the activity of the proteins, or it lowers their expression. Both interpretations would explained the decrease in the activity that we observed. Nonetheless, the enzymes were still active.

Testing our enzymes on their ability to degrade Anthocyanins

The next step is to test our enzymes fused with the FBDs on their ability to degrade anthocyanins. A similar assay to the one performed with Catechol will be performed using Malvidin or a solution of Anthocyanins.

Testing our enzymes on their ability to degrade wine stains

Following the assay with the Anthocyanins, a similar assay to that performed with the fabric assays on the FBD-CBD fusion proteins will be performed, only this time it will be carried out with fabrics stained with wine, on the assay developed by the assay team and analysed with the software designed by the same team as well.

Methods

Codon optimisation of plant and bacterial genes of interest

One important step when expressing heterologously genes in E. coli, specially those of eukaryotic origin, is to perform Codon Optimisation. Different organisms have different codon preferences, which means that each organism has different abundances of the several codons that translate to a same amino acid.
We performed Codon Optimisation using the IDT Codon Optimisation tool.

Golden Gate and Gibson Assembly for Biobrick Construction

We built our plasmids using either Golden Gate or Gibson Assembly.
In the case of Golden Gate, we used NEB’s Golden Gate Assembly mix. 40fmol of backbone and 40fmol of insert were mixed in a 10uL total reaction, following the instructions provided by NEB. The mixure was incubated with the following cycle: 37ºC for 5 min, (37ºC for 2 min, 16ºC for 5min)x50, 37ºC for 5min, 50ºC for 10min and 80ºC for 10min.
In the case of Gibson Assembly, 200ng of DNA (backbone and insert with a ratio of 1:2) were mixed in a 15uL total reaction, using NEB’s 2X Hifi DNA Assembly MasterMix. The mixure was incubated 1h at 37ºC.

Induced protein expression by the use of expression systems

We used E. coli BL21(DE3) as our expression strain. Cells transformed with our constructs were incubated at appropriate temperature until they reached an OD(600nm) of 0.4-0.6. They were then induced with 0.5mM IPTG for 5 hours.

Preparation of cell extract for protein activity testing

We performed our cell extract preparation using ThermoScientific’s B-PER Bacterial Protein Extraction Reagent with Enzymes.

His-tag purification of proteins

We performed the purification of our proteins using ThermoScientific’s His-Pur Ni-NTA Resin and all buffers as indicated by the manufacturer.

SDS-PAGE analysis

We analysed our proteins using pre-made, 10% SDS-PAGE gels from BioRad.

Assaying the binding strength of the Fabric Binding Domains.

We assayed the strength or the Fabric Binding Domains using the assy developed by our team, carrying cotton, wool, silk and linnen untreated, unbleached fabrics. Cell extracts of BL21(DE3) strains carrying GFP-FBD fusion proteins were performed and 1:10 dilutions were made. The diluted cell extracts were incubated in the 96-well-plates-based assay with the fabrics overnight. Several washes of the fabrics were performed using water, PBS, BSA 5%, Ethanol 70% and Catechol 0.03M. The several measurements were performed in a Infinite M200-Pro Tecan plate reader.

Assaying the enhanced stain removal activity of fusion proteins

We assayed the stain removal activity of our fusion proteins in our assay, with the different fabrics stained with wine. The different measurements wera carried out in the Infinite M200-Pro Tecan plate reader.

Attributions

This project was done by Alicia Calvo-Villamañán and Sebastián Sosa-Carrillo. BpuI data was obtained by Mislav Acman. A special thanks to our advisor Nadine Bongaerts for all the insight on Golden Gate and for the GFP sequences. A special thanks to our advisor Jake Wintermute for all the help with the figures and the pDUET system. Thank you to Afonso Bravo for the help with the his-tag purification. Thank you to IDT for the synthesis of our genes, and thanks to NEB for the enzymatic kits.

References

• Cerdan P, Rekik M and Harayama S (1995). Substrate specificity differences between two catechol 2,3-dioxygenases encoded by the TOL and NAH plasmids from Pseudomonas putida. European Journal of Biochemistry. 229, 113-118
• Curiel JA, Rodriguez H, Acebron I, Mancheño JM, de las Rivas B and Muñoz R (2009). Production and physicochemical properties of recombinant Lactobacillus plantarum tannase. Journal of Agricultural Food Chemistry. 57(14), 6224-6230
• Jaiswal V, DerManderosian A, and Porter JR. (2009). Anthocyanins and polyphenol oxidase from dried arils of pomegranate (Punica granatum L.). Food chemistry. 118(1), 11-16
• Kobayashi T, Ishida T, Horiike K, Takara Y, Numao N, Nakazawa A, Nakazawa T and Nozaki M (1995). Overexpression of Pseudomonas putida Catechol 2,3-Dioxygenase with High Specific Activity by Genetically Engineered Escherichia coli. Journal of Biochemistry. 117, 614-622
• Lin J and Milase RN (2015) Purification and characterization of catechol 1,2-dioxygenase from Acinetobacter sp. Y64 Strain and Escherichia coli transformants. Protein Journal. 34(6), 421-433
• Rodriguez Couto S, Toca Herrera JL, (2006). Industrial and biotechnological applications of laccases: a review. Biotechnology Advances. 24/5), 500-513
• Wu YL, Pan LP, Yu SL and Li HH (2010). Cloning, microbial expression and structure-activity relationship of polyphenol oxidases from Camellia sinensis. Journal of Biotechnology. 145(1), 66-72