Line 191: | Line 191: | ||
</p> | </p> | ||
− | <div style = "float:left;"> | + | <div style = "float:left; width:50%"> |
<figure data-ref="4"> | <figure data-ref="4"> | ||
− | <img | + | <img src="https://static.igem.org/mediawiki/2016/4/4a/T--Slovenia--3.6.2.png"> |
<figcaption><b>Split calcium sensing reporter with a single mutation E104Q within calmodulin demonstrated the highest signal-to-noise ratio for calcium | <figcaption><b>Split calcium sensing reporter with a single mutation E104Q within calmodulin demonstrated the highest signal-to-noise ratio for calcium | ||
activation.</b><br/> | activation.</b><br/> | ||
Line 202: | Line 202: | ||
</div> | </div> | ||
− | <div style = "float:left;"> | + | <div style = "float:left; width:50%"> |
<figure data-ref="5"> | <figure data-ref="5"> | ||
− | <img | + | <img src="https://static.igem.org/mediawiki/2016/5/50/T--Slovenia--3.6.3.png" > |
<figcaption><b>Response of split calcium sensor depending on the ration of both protein components.</b><br/> Fold activation of split calcium sensor depended | <figcaption><b>Response of split calcium sensor depending on the ration of both protein components.</b><br/> Fold activation of split calcium sensor depended | ||
on ratio between the CaM:cLuc and nLuc:M13. HEK293T cells were transfected with split calcium sensor CaM:cLuc and nLuc:M13. 24 h after transfection | on ratio between the CaM:cLuc and nLuc:M13. HEK293T cells were transfected with split calcium sensor CaM:cLuc and nLuc:M13. 24 h after transfection |
Revision as of 23:54, 17 October 2016
Ca-dependent reporter and mediator
While calcium influx could be detected by exogenous fluorescent dyes such as the FuraRed and Fluo-4, we needed a genetically encoded calcium sensor that would couple a change in the calcium concentration to a biologically relevant output, such as the luciferase reporter or reconstitution of a split protease the initiation of the signaling pathway. The ideal calcium sensor should be inactive at intracellular concentration of calcium and have a high response to calcium concentrations above physiological levels and should be detected by a quick and easy readout. For our intended application, the calcium sensor should also have the potential to act as the reconstitution mechanism for split proteins so that a conformational rearrangement in the presence of calcium would bring the two split protein fragments together and reconstitute the protein’s activity.
Results
CaMeleon
A wide pallet of genetically encoded calcium sensors are used for mapping intracellular calcium concentration
CaMeleons are based on a genetic fusion of a recombinant calcium binding protein with a pair of fluorescent proteins, forming a FRET (Förster resonance energy
transfer) based sensor. Yellow CaMeleon 2.12 is a CaMeleon composed of calmodulin and a CaM-binding domain of the skeletal muscle myosin light chain kinase
(M13), forming the backbone of the sensor, and a FRET pair linked to the termini of the construct. The binding of calcium causes calmodulin to wrap around the
M13 domain, bringing the two fluorescent proteins closer to each other, thus producing FRET
We replaced the FRET pair of CaMeleon2.12 by a split firefly luciferase (fLuc) as it provides a distinct signal even in small amounts and has a remarkable
signal-to-noise ratio. The new luciferase based calcium sensor was named fLuc2.12. The fLuc2.12 was tested on HEK293 cells, but we found that the sensor was active
already in resting cells (1). We hypothesized the activation was a consequence of a close proximity of calmodulin and M13 in the fusion even in the absence
of calcium binding. In order to resolve this problem we set out to test a similar sensor based on two separate molecules. Two-molecule-based CaM sensors have not been
widely studied, but lower leakage in comparison to a single molecule sensor has been reported by Miyawaki et al.
An inspection of the crystal structure of CaM-M13 complex in its closed state (PDB code: 2BBM) suggested that reporter proteins can be directly fused to the termini of these two interacting proteins (1).
We therefore decided to fuse the N-terminal fragment of the split firefly luciferase to the N-terminus of M13 (nLuc:M13) and the C-terminal fragment of the split firefly luciferase to the C-terminus of calmodulin (CaM:cLuc). The split calcium sensor is represented in 2A. When transfected into HEK293T cells the sensor was expressed in the cytosol (2B).
Split calcium sensor
The split luciferase was tested on live cells (3) but the ratio of the outputs from stimulated and non-stimulated cells remained low,
because activation of the sensor was still detectable at the cytoplasmic concentration of calcium. In order to decrease the activation of the sensor at resting
levels of calcium we introduced two mutations E31Q, E104Q in EF hand motifs, reported previously to decrease the affinity of CaM to calcium
Split calcium reporter with a single mutation (E104Q) introduced into calmodulin was proved to work best, whereas the sensor with two mutations (E31Q, E104Q) generated a low signal. The sensor with E104Q mutation had the highest ratio of the stimulated vs. resting cells, therefore representing the best with calcium sensor. We additionally tested whether the ratio between parts of the calcium sensor affects the fold change between signal of non-stimulated and stimulated cells (5). The response of the reported depended on the ratio, favoring an excess of the nLuc:M13, with the highest ratio close to 10.
Those reporters were later used to detect response of cells to activation of mechanoreceptors based on the ultrasound and mechanical stress, where they enables clean difference between stimulated and unstimulated cells, already few minutes after the stimulation and could be used for real time monitoring.