<aside> <img src="/icons/light-bulb_gray.svg" alt="/icons/light-bulb_gray.svg" width="40px" /> Getting Started
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The primary purpose of Alpha hemolysin as used here is to provide a gate through the membrane for small molecules to enter the cytosol.
Alpha hemolysin (aHly) is a pore-forming protein produced by Staphylococcus aureus. It was rigorously characterized in the 90’s [Song et al. 1996]. The pore is formed from an assembly of 6 protein monomers each with a molecular weight of 33.2 kDa corresponding to 293 amino acid residues. The assembled pore has an outer diameter of 10 nm and inner diameter of 1.6-4.6 nm or 5-17 water molecules across. This size is sufficient to gate the transport of molecules with molecular weight of 3 kDa.
The pore has a height of 10 nm along which there is a hydrophobic patch spanning 3 nm. This corresponds to the thickness of the non-polar section of a typical phospholipid bilayer. For this reason, aHly has often been used in the literature as a tool for confirming the formation of bilayer (as opposed to multilayer) in synthetic cells. The pore is functional if inserted from the outside in or vice versa. Introduction from the exterior can lead to lower efficiencies due to molecular jamming [Noireaux and Libchaber, 2004; Harjung, Fracassi, and Devaraj, 2023].
We characterized the following behaviors of this module:
<aside> <img src="/icons/chemistry_gray.svg" alt="/icons/chemistry_gray.svg" width="40px" /> Usage
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We recommend purchasing aHly as purified protein (e.g., from MedChemExpress, Cat. No. HY-P2967) and resuspending to 10 uM in milliQ water.
We demonstrated aHly function in synthetic cells by expressing the pore directly in PURE, using pT7-aHly as a template. The reactions are constructed following the protocol described in Assemble PURE Reactions.
| Component | Reaction Volume (ul) | Target |
|---|---|---|
| Master Mix | ||
| Solution A | 4 | |
| Solution B | 3 | |
| RNase I | 1 | |
| pT7-aHly | 1 | 10 fmol/uL |
| ddH2O | 1 | |
| Total | 10 |
Here, we demonstrate the functional insertion of aHly into the cell membrane by using it to quench a PURE reaction.
In this case, the cytosol contains the PURE system and NEB solution A (shorthand: N) along with two modules: pT7-aHly (hereafter “a”) and pT7-eGFP (hereafter “G”). The outer solution consists of a buffered, osmolarity-matched solution (hereafter “B”) made of 10 mM HEPES and 790 mM glucose.
As aHly is expressed in the cytosol and inserted into the membrane of synthetic cells, the small molecules required for transcription and translation diffuse out into the outer solution. As a result, production of GFP is significantly reduced and should not be easily detected. In the absence of pT7-aHly, we expect to observe the production of GFP.
In the following table, reactions are denoted [OS-T1T2-IS], where OS = outer solution, T1 = template DNA 1, T2 = template DNA 2, Cy = cytosol. The details are described using the shorthand symbols defined above.
While the table below describes 2 reactions, we prepare enough master mix for 3 reactions to account for dead volume. In practice, a 10% excess should be sufficient though slightly more tedious to prepare.