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Speaker

Colline Sanchez

Description

Excitation-contraction (EC) coupling in skeletal muscle corresponds to the sequence of events through which muscle fiber contraction is triggered in response to plasma membrane electrical activity. EC coupling takes place at the triads; these are nanoscopic domains in which the transverse invaginations (t-tubules) of the surface membrane are in close apposition with two adjacent terminal cisternae of the sarcoplasmic reticulum (SR) membrane. More precisely, EC coupling starts with action potentials fired at the endplate, propagating throughout the surface membrane and in depth into the muscle fiber through the t-tubules network. When reaching the triadic region, action potentials activate the voltage-sensing protein Cav1.1. In turns, Cav1.1 directly opens up the type 1 ryanodine receptor (RYR1) in the immediately adjacent SR membrane, through intermolecular conformational coupling. This triggers RYR1-mediated SR Ca2+ release which produces an increase in cytosolic Ca2+ triggering contraction.

Current understanding of the mechanisms involved in the control and regulation of RYR1 channels function is still limited. One reason is related to the fact that detection of RYR1 channel activity in intact muscle fibers is only achieved with indirect methods. Also, whether the SR membrane voltage experiences changes during muscle activity has so far never been experimentally assessed. Yet, deeper knowledge of these processes is essential for our understanding of muscle function in normal and disease conditions.

In this context, the general aim of my PhD project was to design and use fluorescent protein biosensors specifically localized at the SR membrane of differentiated muscle fibers, by fusing them to an appropriate targeting sequence. Thanks to a combination of single cell physiology and biophysics techniques based on electrophysiology and biosensor fluorescence detection, we were able to study the SR activity during muscle fiber function. Specifically, my PhD work focused on two major issues: SR membrane voltage and SR calcium signaling during EC coupling.

The first aim of my work was to characterize SR membrane voltage changes during muscle fiber activity. For this, we used voltage sensitive FRET-biosensors of the Mermaid family. Results show that the SR trans-membrane voltage experiences no substantial change during EC coupling. This provides the first experimental evidence, in physiological conditions, for the existence of ion counter-fluxes that balance the charge deficit associated with RYR1-mediated SR Ca2+ release. Indeed, this process is essential for maintaining the SR Ca2+ flux upon RYR1 channels opening and thus critically important for EC coupling efficiency.

The second objective of my work aimed at detecting the changes in Ca2+ concentration occurring in the immediate vicinity of the RYR1 Ca2+ release channels during muscle fiber activation. For this, we took advantage of one member of the recent generation of genetically encoded Ca2+ biosensors: GCaMP6f. The SR-targeted biosensor provides a unique access to the individual activity of RYR1 channels populations within distinct triads of a same muscle fiber. Beyond allowing a detailed characterization of the biosensor properties in this preparation, results highlight the remarkable uniformity of SR Ca2+ release activation from one triad to another, during EC coupling. These results open up stimulating perspectives for the investigation of disease conditions associated with defective behavior of RYR1 channels.