High Throughput Screen Identifies Small Molecule Effectors That Modulate Thin Filament Activation in Cardiac Muscle.
Priyanka ParijatLaszlo KondacsAlexander AlexandrovichMathias GautelAlexander J A CobbThomas KampourakisPublished in: ACS chemical biology (2020)
Current therapeutic interventions for both heart disease and heart failure are largely insufficient and associated with undesired side effects. Biomedical research has emphasized the role of sarcomeric protein function for the normal performance and energy efficiency of the heart, suggesting that directly targeting the contractile myofilaments themselves using small molecule effectors has therapeutic potential and will likely result in greater drug efficacy and selectivity. In this study, we developed a robust and highly reproducible fluorescence polarization-based high throughput screening (HTS) assay that directly targets the calcium-dependent interaction between cardiac troponin C (cTnC) and the switch region of cardiac troponin I (cTnISP), with the aim of identifying small molecule effectors of the cardiac thin filament activation pathway. We screened a commercially available small molecule library and identified several hit compounds with both inhibitory and activating effects. We used a range of biophysical and biochemical methods to characterize hit compounds and identified fingolimod, a sphingosin-1-phosphate receptor modulator, as a new troponin-based small molecule effector. Fingolimod decreased the ATPase activity and calcium sensitivity of demembranated cardiac muscle fibers in a dose-dependent manner, suggesting that the compound acts as a calcium desensitizer. We investigated fingolimod's mechanism of action using a combination of computational studies, biophysical methods, and synthetic chemistry, showing that fingolimod bound to cTnC repels cTnISP via mainly electrostatic repulsion of its positively charged tail. These results suggest that fingolimod is a potential new lead compound/scaffold for the development of troponin-directed heart failure therapeutics.
Keyphrases
- small molecule
- multiple sclerosis
- heart failure
- protein protein
- high throughput
- left ventricular
- skeletal muscle
- type iii
- hypertrophic cardiomyopathy
- gene expression
- physical activity
- atrial fibrillation
- pulmonary hypertension
- risk assessment
- cardiac resynchronization therapy
- binding protein
- regulatory t cells
- high resolution
- emergency department
- dendritic cells
- climate change
- smooth muscle
- energy transfer
- acute heart failure
- single cell
- genome wide
- quantum dots