Difference between revisions of "Team:Bielefeld-CeBiTec/Project/toolbox/photolysis"

(added title image)
Line 4: Line 4:
 
<body>
 
<body>
 
<div class="container">
 
<div class="container">
<div class="contentbox">
+
<div id="title" style="background-image: url(https://static.igem.org/mediawiki/2017/7/74/T--Bielefeld-CeBiTec--title-img-centrifuge.jpg);">
<div class="bevel tr"></div>
+
<img src="https://static.igem.org/mediawiki/2017/7/74/T--Bielefeld-CeBiTec--title-img-centrifuge.jpg">
<div class="content">
+
<div id="title-bg">
            <h1> Photolysis </h1>
+
<div id="title-text">
        </div>
+
Photolysis
<div class="bevel bl"></div>
+
</div>
    </div>
+
</div>
 +
</div>
 
      
 
      
 
     <div class="contentbox">
 
     <div class="contentbox">

Revision as of 10:06, 3 October 2017

Photolysis

Short summary

The noncanonical amino acid (ncAA) 2-nitrophenylalanine (2-NPA) has the special property to induce a cleavage of the peptide backbone when irradiated with light of a wavelength of 365 nm. To demonstrate the usage of 2-NPA, we designed a fusion protein of the green fluorescent protein (GFP) and streptavidin connected by a glycine-glycine-serine-linker. The streptavidin compound will form a stable and highly specific non-covalent bond to biotin, so that the fusion protein can easily be immobilized on any biotinylated surface. The GFP is used as a fluorescence tag so that the fusion protein can easily be identified through its fluorescent properties. The immobilized fusion protein can then be irradiated with light to induce the cleavage of the peptide backbone and elute the target protein

Photolysis of peptide chains

This system is an alternative procedure of site-specific protein cleavage compared to a cleavage by proteases or chemicals. A big advantage of this light-induced cleavage is, that it can be used almost universally on any purpose. It prevents disadvantages like an undesired cleavage of the target protein by undetected cleavage sides or a denaturation of the protein through the reagents when cleaved chemically. The system has a wide range of possible applications, such as inactivating proteins by cleaving them, activating them by cleaving an inactive pre-protein releasing an active form, or a combination with other methods as demonstrated in our light-induced elution.

Explanation of the ncAA

The ncAA 2-NPA is able to photochemically cleave the polypeptide backbone by an cinnoline forming reaction based on the photochemistry of (2-nitrophenyl)ethane derivatives which are used as photochemical caging groups. Peters et al. (2009) report that upon photolysis, the nitrobenzyl group rearranges to the α-hydroxy-substituted nitrosophenyl group. The nitroso group then undergoes an additional reaction with the N-terminal amide group to generate the cyclic azo product. Subsequent hydrolysis of the activated carbonyl group affords the terminal cinnoline and carboxylate products (Peters et al., 2009).

Figure 1a: Reaction scheme of the proposed mechanism of photocleavage reaction by Peters et al.

Figure 1b: Animation of the proposed mechanism of photocleavage reaction by Peters et al.

Characteristics of the ncAA

  • Name: 2-Nitro-L-phenylalanine
  • Short: 2-NPA
  • CAS: 19883-75-1
  • MW: 210.19
  • Storage: 2-8°C
  • Source: apolloscientific
  • Prize: 5g - £205.00
  • Function: induces a cleavage of the peptide backbone when radiated with ʎ=365nm

Figure 2: Structure of 2-Nitrophenylalanine

Theoretical basis

Light-induced elution

As an application, we wanted to use 2-NPA in a new purification system for recombinant proteins, similar to affinity chromatography and inspired by a paper form Peters et al. They cleaved a short model peptide containing 2-NPA to show the ability of the ncAA to induce a cleavage of the protein backbone after irradiation with light with a wavelength of 365 nm. We thought about this model peptide as a linker between the target and the binding protein to establish a new light-induced elution system (Figure 8).

Figure 8: Overview of the light induced elution process with our fusion protein containing 2-NPA in the protein purification column.

We use a recombinant fusion protein with streptavidin as binding unit and a medium gly-gly-ser-linker with 2-NPA connecting the streptavidin with a target protein. As a proof of concept, we used GFP as target protein because of its easy optical detection.
We hope that the fusion protein in unfiltered cell lysate will bind strong and specifically to the purification column with biotinylated glass slides, so that the other proteins and cell fragments can be easily washed away. We then want to irradiate the slides with light of 395 nm wave length to detect the GFP and prove the binding efficiency of the streptavidin and the functionality of the selected linker. Afterwards, we want to irradiate the column with UV-light of 365 nm wave length to induce the photocleavage of the 2-NPA. In the following elution step the GFP will be eluted while other proteins that were bound unspecific to the biotinylated surface should not be effected by the irradiation and retain on the column. The elution of the GFP can then also be detected as well as the fluorescence of the eluate.
After using the purification column it should be easily regenerated by simply washing it with SDS-solution. The SDS will denaturate the streptavidin with the linker and the other proteins bound to the column so that they will lose their binding affinity to the biotin and be washed off the glass slides. The biotin itself should not be influenced by the SDS-solution so that the glass slides will still be usable for many purification steps.
To implement all this, we started the development of a purification column, containing the needed biotinylated surfaces and an LED-panel that is able to radiate the needed UV-light with a wave length of 365 nm.

Green fluorescent protein: GFP

GFP is a fluorescent protein isolated from the jellyfish Aequorea victoria. It is one of the most widely studied and used proteins in biochemistry and cell biology. It has been established as a marker for gene expression and protein targeting in living cells and organisms. It is 238 amino acids long with a molecular weight of 26.5 kDa. Inside the protein a self-assembled fluorophore is located which leads to its fluorescence properties. The wild type Aequorea protein has a major excitation peak at 395 nm and a minor peak at 475 nm. In aqueous solution (pH= 7.0), excitation at 395 nm leads to an emission peak at 508 nm, whereas excitation at 475 nm causes a maximum emission at 503 nm (visible green light) (Tsien, 1998). In our project, it is used as a fusion protein to provide the ability to detect it by exciting with a wave length of 395 nm.

Figure 3: Three perspectives of the photoproduct of the tetrameric wild type Aequorea victoria green fluorescent protein from rcsb.org.

Besides GFP, which emits a visible green light, there are other versions of fluorescent proteins like the red fluorescent protein (RFP), able to emit all kinds of colors. They are mostly used to label more than one protein of interest and compare their localization and amount in vivo.

Figure 4: Three perspectives of the photoproduct of the tetrameric wild type Aequorea victoria green fluorescent protein from rcsb.org.

Streptavidin

Streptavidin is a tetrameric protein with a molecular weight of 15 kDa for each subunit. It was isolated from the actinobacterium Streptomyces avidinii and is homologous to avidin. Both proteins can bind up to four molecules of biotin and their derivatives with high affinity resulting in the high dissociation constant Kd = 10-15 M. This leads to its widespread use in diagnostic assays and protein tags that require formation of an irreversible and specific linkage between biological macromolecules (Lichty et al., 2005).

Figure 5: Three perspectives of the structure of a wild type streptavidin tetramer in complex with biotin from rcsb.org.

In our project, streptavidin is used as a tag to provide the ability to immobilize the target protein on a biotinylated surface.

Fusion Proteins

Fusion proteins have been developed as a class of novel biomolecules with multi-functional properties. By successfully genetically fusing two or more proteins together, the product will have the desired properties from each component. The successful construction of a fusion protein requires the component proteins and suitable linkers. They were inspired by naturally-occurring multi-domain proteins with different subunits that are covalently linked together (Weber et al., 1989). Fusion proteins can contain the whole native protein sequences or just parts of it dependent on the desired function and size of the resulting product protein.

Figure 6: Fusion protein of EGFP and Cytochrome b562 by rcsb.org.

In the design process of recombinant fusion proteins, linkers are very important, as they can increase the stability, bioactivity, and expression yield of the fusion protein (Chen et al., 2013). Additionally, a direct fusion of functional domains without a linker can lead to misfolding and other undesirable properties. Linker sequences can be received from natural multi-domain proteins or be rationally designed depending on the desired characteristics. They are mainly classified in three different groups: flexible linkers, rigid linkers, and cleavable linkers (see figure 7). Furthermore they can be classified as small (approximately five amino acids), medium (approximately ten) or large linkers (approximately 20 to 28 amino acids) (Weber et al., 1989).

Figure 7: Three groups of protein linkers. Left: flexible, middle: rigid, right: cleavable.

In our project, we used a rationally designed medium-sized gly-gly-ser-linker with a length of eleven amino acids. These small amino acids will allow a good expose of the 2-NPA to the UV-light while the glycines mediate the flexibility and the serines improve the solubility of the fusion protein and prevent a hydrophobic collapse.

References

Peters, F.B., Brock, A., Wang, J., and Schultz, P.G. (2009). Photocleavage of the Polypeptide Backbone by 2-NitrophenylalaninePeters. Chem. Biol. 16: 148–152.

Roger Y. Tsien (1998). The Green Fluorescent Protein. Annu. Rev. Biochem. 1998. 67:509–44.

Xiaoying Chen, Jennica Zaro, and Wei-Chiang Shen (2013). Fusion Protein Linkers: Property, Design and Functionality. Adv Drug Deliv Rev. 65(10): 1357–1369.

Patricia C. Weber, D. H. Ohlendorf, J. J. Wendoloski and F. R. Salemme (1989). Structural Origins of High-Affinity Biotin Binding to Streptavidin. Science. 243: 85-88.

Lichty, J.J., Malecki, J.L., Agnew, H.D., Michelson-horowitz, D.J., and Tan, S. (2005). Comparison of affinity tags for protein purification. 41: 98–105.