Team:ZJU-China/Project/GhostSensor/Results

From 2013.igem.org

(Difference between revisions)
(Characterize the function of aptamers)
(Detect thrombin using membrane scaffold FA and FB)
Line 58: Line 58:
As our aptamers were biotin modified, we used a streptavidin beads pull down assay to see if these aptamers were capable of binding to thrombin.
As our aptamers were biotin modified, we used a streptavidin beads pull down assay to see if these aptamers were capable of binding to thrombin.
 +
 +
== '''Subcellular distribution of inner-membrane scaffolds''' ==
 +
SsDsbA is the signal recognition particle (SRP)-dependent signaling sequence of DsbA. ssDsbA-tagged proteins are thus destined to export to the periplasmic space via the SRP pathway. With ssDsbA fused to the N-terminus, fusion inner-membrane proteins with transmembtrane domain are expected to be anchored onto inner membrane of ''E.coli''.
 +
 +
[[File:ZJU-GhostSensor-4.png|330px|left]]
 +
[[File:ZJU-GhostSensor-5.png|330px|right]]
 +
 +
We tried to confirm the localization of our inner-membrane scaffolds by looking at the subcellular distribution of green fluorescence in the cell.
== '''Detect thrombin using membrane scaffold FA and FB''' ==
== '''Detect thrombin using membrane scaffold FA and FB''' ==

Revision as of 14:54, 26 October 2013

Ghost Sensor: Result

Contents

Characterize the function of protein E

1.1 Protein E was put under the control of pBAD promoter. We recorded the growth curve of transformed E.coli cells treated with different concentrations of L-arabinose varying from 0.2% to 1%. MgSO4 has been reported to allow the expression of protein E but inhibit lysis. MgSO4 was added 30min before the induction according to previous works by others. The results showed that even as low as 0.2% L-arabinose can efficiently induce the lysis E.coli.

Pe.JPG

1.2 The lysed products were viewed under SEM and TEM to confirm the formation of tunnels. MgSO4 allows production of protein E, but inhibits lysis. 150min later cells were collected by centrifugation and resuspended in water causing immediate lysis by osmotic shock. This procedure would produce holes approximately equal in size to the diameter of the cell.

ZJU-ghostsensor-result-2.png
ZJU-ghostsensor-result-3.png

Left: SEM picture of protein E lysed E.coli.

Right: SEM picture of protein E lysed E.coli with MgSO4 protocol. The tunnel is relatively bigger than the left one.

ZJU-ghostsensor-result-4.png

TEM showing protein E lysed E.coli


Characterize the function of aptamers

We chose two well-characterized aptamers, namely 15-mer and 29-mer aptamers, targeting two different sites of thrombin. In order to achieve optimal spatial distance, we linked each of them with either short or long linkers (the underlined sequence below indicates the linker sequence).

Thrombin aptamers with Short linker:

5’-biotin-ttttttggttggtgtggttgg

5’-biotin-tttagtccgtggtagggcaggttggggtgact


Thrombin aptamers with Long linker:

5’-biotin-ttttttttttttggttggtgtggttgg

5’-biotin-tttttttttagtccgtggtagggcaggttggggtgact


As our aptamers were biotin modified, we used a streptavidin beads pull down assay to see if these aptamers were capable of binding to thrombin.

Subcellular distribution of inner-membrane scaffolds

SsDsbA is the signal recognition particle (SRP)-dependent signaling sequence of DsbA. ssDsbA-tagged proteins are thus destined to export to the periplasmic space via the SRP pathway. With ssDsbA fused to the N-terminus, fusion inner-membrane proteins with transmembtrane domain are expected to be anchored onto inner membrane of E.coli.

ZJU-GhostSensor-4.png
ZJU-GhostSensor-5.png

We tried to confirm the localization of our inner-membrane scaffolds by looking at the subcellular distribution of green fluorescence in the cell.

Detect thrombin using membrane scaffold FA and FB

We expressed the first set of membrane scaffolds with split EGFP fragments FA and FB fused to the periplasmic end. Then we tested the function of our membrane scaffolds by adding two sets of aptamers with different linker length. The concentration of thrombin in the solution was adjusted to 0.2nM. 29-mer aptamer and 15-mer aptamer efficiently induced dimerization of membrane scaffolds (Figure C, D versus A) and led to green fluorescence emission under confocal microscopy.

ZJU-ghostsensor-result-A.png
ZJU-ghostsensor-result-B.png
ZJU-ghostsensor-result-C.png
ZJU-ghostsensor-result-D.png


Fluorescence with or without aptamers. BL21 competent cells were co-transformed with FA, FB and protein E. When the OD-600 value reached 0.4, 0.4% was added to induce the expression of protein E. 2h later cells were harvested and washed two times with PBS. 5µL of bacteria were resuspended in 200 µL PBS, and a final concentration of 0.2nM thrombin was added to the solution. Different aptamers were also included in this point. The reaction system was incubated with shaking in room temperature for 30 min and then green fluorescence was viewed under confocal microscopy. Only very weak green fluorescence was visible when no aptamers were added to the reaction system (A). Biotinylated thrombin can readily induce membrane scaffolds dimerization because there were typically 1-4 biontin in one molecule leading to scaffolds crosslinking (B). 15-mer and 29-mer aptamer with short (C) or long (D) linkers were both effective in inducing crosslinking. But it seemed that long linkers (D) is more potent than short linker (C) in this system.