In excitable cells, intracellular Ca2+ release and uptake from and into the endo/sarcoplasmic reticulum, via the Ryanodine Receptor (RyR) and SERCA-Ca2+-ATPase, respectively, are functionally coupled. This allows for tight spatiotemporal control of local Ca2+ signals (Ca2+ sparks) and safeguards cell viability through low resting Ca2+ concentrations. Despite the eminent role of RyR Ca2+ release channels and SERCA Ca2+-pumps in the brain, heart, pancreas and skeletal muscle, both in health and disease, their molecularly targeted manipulation remains challenging and complex. For example, patient mutations cause dangerous arrhythmias via RyR2 channels in the heart through increased Ca2+ leak. However, in experimental cellular models Ca2+ leak is commonly induced by non-physiological, typically pharmacological interventions at the cost of significant off-target effects. Importantly, the lack of RyR- and SERCA-specific tools compromises and delays the development of drug compounds for a large number of diseases, including arrhythmias, cancer, cognitive dysfunction, diabetes, epilepsy, heart failure, and muscle fatigue. While optogenetic manipulation of RyR channels and SERCA pumps addresses a challenging area, our collaborative efforts to develop the first OptoRyR tool are not only promising, but can open major opportunities for target-specific functional studies, which may facilitate drug development and testing.In the first funding period we have developed de novo strategies for light-induced Ca2+ release. The most successful strategy used a Ca2+-conducting Channelrhodopsin2 variant fused to the RyR2 channel. This OptoRyR2 relies on an endogenous amplification mechanism of Ca2+-induced Ca2+-release through cytosolic Ca2+-activation of RyR2 channels. For the second funding period we will significantly extend the planned work through three major directions: In Aim 1 we will apply the mechanistic concept of OptoRyR2 to C. elegans and human stem cell-derived cardiomyocytes using CRISPR/Cas9 mediated gene editing to address fundamental biological questions in intact animals and human cardiomyocytes to develop a novel optogenetic platform for drug-safety testing of RyR2-targeted chemical compounds. Aim 2 broadens the utility concept through a new mechanistic approach of direct opto-mechanical light-gating of RyR2 through insertion of LOV domains in the channel’s large cytosolic shell structure. This became possible through existing high-resolution CryoEM structures of RyR channels. Aim 3, and closing the circle, extends the optogenetic toolbox to control Ca2+ uptake through two parallel strategies: light-activation of cAMP production molecularly linked to phospholamban and opto-mechanical control of SERCA will both modulate Ca2+ uptake. Thus, we will develop a toolbox for subcellular Ca2+ control and apply this in vitro and in vivo to enable exploring basic questions of Ca2+ homeostasis, as well as a new concept of drug-safety testing.

DFG Programme Priority Programmes

Subproject of SPP 1926:  Next Generation Optogenetics: Tool Development and Application