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Contents

Introduction

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Circularization

Millions of years of evolution have allowed proteins to performed extremely specific chemical modifications that are not only essential for living organisms but can also be of great benefit to produce useful molecules for our life, efficiently and at low cost. A major limitation of the use of enzyme for industrial application and in general for usage out of their natural environment is their stability. They can be destroyed by other enzymes and they can unfold and take non-functional conformation when exposed to non-physiological temperature and pH. Such limitations has motivated research in species that can grow at extreme temperatures [6]. Another major area of chemical research if the design of strategies to stabilize enzymes, and more generally proteins and peptides. Protein circularization, meaning ligation of the N- and C-terminal ends of a protein, represents a promising way to achieve this stabilization. While conserving the functionality of their linear counterpart, circular proteins can be superior to linear proteins in terms of thermostability [1][2][3], resistance against chemical denaturation [4] and protection from exopeptidases [2][4]. Moreover, a circular backbone can improve in vivo stability of therapeutical proteins and peptides [5]. These remarkable properties motivated us to develop new tools to circularize any protein of interest.

Our Toolbox Guide provides a step-by-step strategy to clone a circularization linker and express it in e. Coli. Moreover, in case of complex structures where the protein extremities are far from each other, we have developed a software that will design the appropriate rigid linkers.

Oligomerization

Split inteins constitute a useful tool to produce huge polymers in vivo: Hauptmann et al. managed to fabricate synthetic spider silk with microfiber structure. The results using an easy-to-handle split intein system were stunning: The polymers had a molecular weight of 250 kDa and more.[1]

Standardization of a unique tool

The valuable properties of spider silk, for example its exceptional strength and elasticity, result from numerous repeats of certain protein motifs. Convenitonal methods to multimerize these motifs bear a lot of difficulties: Often genetic and mRNA instability constitute a barrier for the production of multimers as fusion proteins.[1] Posttranslational assembly through split inteins is therefore the solution to overcome these problems. The successfull polimerization of spider silk potein motifs demonstrates the potential of split inteins to be a useful tool for the production of new biomaterials by performing oligomerization reactions with split inteins. The iGEM team Heidelberg standardized (lik to toolbox guide) the oligomerization procedure with split inteins to allow easy handling with different proteins.

The mechanism

Oligomerization reactions require the same constructs as the ones used for protein circularization.

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Circularization is achieved by bringing the N and C terminus of a protein very close together, so both intein parts can asseble, cut out off the protein and thereby circularize it. In contrast, oligomerization occurs when the both termini of a protein cannot reach each other and the intein parts of two neighbouring proteins assemble, at the same assembling the protein parts.

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References

[1] Hauptmann, V. et al.: Native-sized spider silk proteins synthesized in planta via intein-based multimerization. Transgenic Res (2013) 22:369–377. DOI 10.1007/s11248-012-9655-6.

Fusion and Tagging

Post-translational modifications are highly prevalent in nature: Almost every protein in a cell is modified after being translated, numerous varieties of the protein are formed from the mere protein backbone. Synthetic Biology, however, has not yet made use of the innumerable possibilities nature has developed. With our collection of intein assembly constructs we expand the arsenal of synthetic biology by enabling unlimited changes of a protein's amino acid sequence even after translation.

To be able to fuse any two halves of a protein together can have many different uses. We therefore saw the need for a standardised construct, the intein assembly part. This BioBrick part allows the user to clone two DNA-sequences coding for two parts of a peptide into a plasmid prepared with selection markers and standardised overhangs. Those parts were all send in with additional hexahistidine-tags to enable quick analysis on a western blot, however there are highly customisable parts available as well. In an extensive assay we proved the principle behind split protein assembly by showing that GFP can be artificially split into two halves and thereafter be reassembled so the fluorescence is restored. Visit the split Fluorescent Protein

Applying the Tagging Tool allows for all kinds of natural as well as synthetic posttranslational modifications by the chemoselective addition of a peptide to a recombinant protein. The principle is based on intein-mediated protein fusion using the SspDnaB split intein for N-terminal modifications and SspDnaX-S11 for C-terminal ones. The split SspDnaB intein has a very short N-terminal part, consisting of only 11 amino acids intein, 5 amino acids extein sequence and a much longer C-terminal part. By contrast, SspDnaX-S11 has a C-terminal part consisting of only 6 amino acids intein and 3 amino acids extein sequence, but a much longer N-terminal part. The short part including the desired modification is easy to obtain by chemical synthesis. This offers the possibility to introduce this modification at a specific locus. There are different publications on intein-based introduction of posttranslational modifications, including phosphorylation, lipidation, glycosylation, acetylation and ubiquitination (1). Phosphorylation, for example has been applied with tyrosine kinase C-terminal Src kinase (Csk) in order to be able to study the structure and function of this specifically modified protein (2). In general, split inteins are powerful tools to easily introduce post-translational modifications in a chemoselective manner and with the intein fusion and tagging parts this tool becomes easily available to many people.



Translocation Tags

Regulated targeting of proteins to certain loci inside the cell can be achieved using the iGEM Heidelberg 2014 translocation tags for either E. coli or eukaryotic expression systems.

We provide following tags:
E. coli: MinD membrane targeting sequence (BBa_K1362055) → membrane localization
OmpA (BBa_K1362060) → surface display
pelB leader sequence (BBa_K1362058) → periplasmic localization
Eucaryotic: myristooilation signal sequence (BBa_K1362056) → membrane localization
PKI-NES (BBa_K1362059) → cytoplasmic localization
NLS (BBa_K1362057) → nuclear localization


Use our [:Team:Heidelberg/Toolbox toolbox guide] to post-translationally assemble proteins, attach tags or change the location of your protein!


References

[1] Vila-Perello, Miquel et al.: Biological Applications of Protein Splicing. Cell 143. October 15,

    2010. DOI 10.1016/j.cell.2010.09.031.

[2] Muir, Tom W. et al.: Expressed protein ligation: A general method for protein engineering. Proc. Natl. Acad. Sci. USA 95 (1998).

Purification

figure 1) Purification with inteins.
figure 1) Purification with inteins.

Split-inteins can be used to simplify conventional protein purification in many aspects: a split-intein based system is cheaper, faster and more efficient than other purification procedures. In fact, only a single chromatographic step is necessary for both, binding of the protein fused to an affinity tag to the affinity column and tag removal. Also, there is no need for expensive proteases. We standardized this split-intein purification system, so it is easy applicable to all kinds of proteins.

In previous purification procedures, there a several steps to take to get solely the purified protein: The first step is the binding of the protein to the affinity matrix, the washing and finally release of the protein from the affinity column, the protein still being bound to the affinity tag. The next step is the removal of the affinity tag from the protein by protease cleavage, which causes undesirable secondary cleavage within the protein sequence. In industrial scales proteases are the most expensive component during the purification process. Finally, the split off affinity tag has to be separated from the protein, which takes again a lot of effort.

The split-intein based system is manifold easier: All these steps can be combined into one by using Ssp DnaB mini-intein, an artificial split intein. It performs the trans-splicing reaction only under certain pH and temperature conditions. A mutation of the SspDnaB N-intein at Cys1 to Ala prevents cleavage at the N-terminus, cleavage at the C-terminus still occurs. The N-terminal intein part, attached to a chitin binding domain can be used as an affinity ligand, while the C-terminal part, fused to a protein of interest, can be used as an affinity tag binding highly specific to the ligand part. After loading the protein of interest on a chitin column, the trans-splicing reaction can be induced by adjusting temperature and pH: the both split inteins fuse together, disrupting the fusion to the protein of interest in one single step [1].

References

[1] Lu, Wei et al.: Split intein facilitated tag affinity purification for recombinant proteins with controllable tag removal by inducible auto-cleavage. J. Chromatogr. A 1218 (2011) 2553–2560. DOI: 10.1016/j.chroma.2011.02.053.