Difference between revisions of "Team:Slovenia/Mechanosensing/CaDependent mediator"

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<p>Based on the inspection of the 3D structure of the CaM-M13 complex (<a href="http://www.rcsb.org/pdb/explore.do?structureId=2BBM">PDB code: 2BBM</a>), we fused the
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<p style="clear:both">Based on the inspection of the 3D structure of the CaM-M13 complex (<a href="http://www.rcsb.org/pdb/explore.do?structureId=2BBM">PDB code: 2BBM</a>), we fused 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  
 
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 <ref>2</ref>A. When transfected into HEK293T cells the sensor was expressed in the cytosol  
 
of calmodulin (CaM:cLuc). The split calcium sensor is represented in <ref>2</ref>A. When transfected into HEK293T cells the sensor was expressed in the cytosol  

Revision as of 23:57, 15 October 2016

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nbsp;Calcium-depended mediator

A new split calcium sensing/reporting system based on split firefly luciferase linked to M13 and calmodulin was designed that is able to report the increase of the cytosolic calcium ions induced by mechanoreceptor stimulation by emitted light.

Motivation


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.

A wide pallet of genetically encoded calcium sensors are used for mapping intracellular calcium concentration Whitaker2010, including calmodulin, troponin C and aequorin Wilms2014. These reporters are based on different mechanisms of detection. From this abundant collection we chose the calmodulin (CaM)-based calcium sensors (in particular CaMeleons), since their mechanism is based on a large conformational change, allowing reconstitution of split proteins Whitaker2010.

Further explanation ...

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 Whitaker2010.


A luminescence based calcium sensor fLuc2.12 has high activity already at the resting levels of calcium.
HEK293T cells were transfected with 50 ng fLuc2.12. 24 h after transfection luciferase activities were measured immediately after addition of calcium ionophore A23187 (10 µM). Scheme: The chimeric protein M13-calmodulin fused to N- and C- fragments of split luciferase changes conformation upon calcium binding.

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. Miyawaki1997.

Based on the inspection of the 3D structure of the CaM-M13 complex (PDB code: 2BBM), we fused 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 is expressed in the cytosol.
(A) Scheme of the function of the split calcium sensor. Calmodulin is fused to the C-terminal fragment and M13 is fused to N-terminal fragment of split firefly luciferase. Free calcium ions trigger binding of M13 to calmodulin and formation of active luciferase. (B) Split calcium sensor is expressed in the cytosol. HEK293T cells were transfected with 50 ng of nLuc:M13 and 10 ng of CaM:cLuc. 24 h after transfection cells were fixed, stained with anti-HA and anti-Myc antibodies and localization was confirmed on the confocal microscope.