The long-term goals of this project are to develop a high-resolution understanding of voltage-gated calcium channel (CaV) function and regulation. These molecular switches play pivotal roles in cardiac action potential propagation, neurotransmitter release, muscle contraction, calcium-dependent gene-transcription, and synaptic transmission. Calcium influx is a potent activator of intracellular signaling pathways but is toxic in excess. As a result, its entry into cells is tightly regulated. CaVs are major sources of activity-dependent calcium influx and possess a number of mechanisms that allow them to self-regulate. These mechanisms depend critically on interactions of the pore-forming subunit with cytoplasmic proteins that regulate channel activity. Our studies are aimed at understanding the molecular architecture that underlies CaV function and on developing novel reagents that can control channel function. We are investigating the hypothesis that two principal CaV inactivation mechanisms, calcium-dependent inactivation (CDI) and voltage-dependent inactivation (VDI) center on changes in the region of the selectivity filter. This is a paradigm-shifting view, based on our recent findings, that stands to align CaV inactivation mechanisms with a growing number of examples from other voltage-gated ion channel (VGIC) superfamily members. Due to the extraordinary challenges in studying mammalian membrane protein structure, part of our efforts focus on understanding basic structural mechanisms that are shared between CaVs and their ancestors, bacterial voltage gated sodium channels (BacNaVs). Production of multiprotein membrane proteins, such as CaVs, is a significant barrier to structural studies. To bridge this gap, we direct efforts to develop systems for production of full-length CaV complexes. In parallel, we investigate the how a novel class of reagents, anti-CaV? subunit nanobodies, interact with CaV? and modify channel function. Knowledge of such interactions will inform studies of how these novel, genetically-encodable reagents can be developed as versatile and selective agents to control CaV activity. Our studies integrate a multidisciplinary effort that includes biochemical, biophysical, X-ray crystallographic, cryo-electronmicroscopy, electrophysiological, and cell biology approaches. Because of their important role in human physiology, CaVs are the targets for drugs with great utility for the treatment of cardiac arrhythmias, hypertension, congestive heart failure, epilepsy, and chronic pain. Thus, understanding their structures and mechanisms of action in detail should greatly assist the development of valuable therapeutic agents for a wide range of human cardiac and neurological problems.

Public Health Relevance

Calcium channels are the targets of drugs used to treat hypertension, arrhythmia, pain, epilepsy, and mood disorders. Our work aims to understand the molecular architecture and mechanisms that underlie calcium channel function and to define new tools that can be used to influence their activity. Such understanding has direct relevance for development of more efficacious treatments of nervous system and cardiovascular disorders.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
2R01HL080050-14A1
Application #
9972679
Study Section
Biophysics of Neural Systems Study Section (BPNS)
Program Officer
Balijepalli, Ravi C
Project Start
2005-05-01
Project End
2024-03-31
Budget Start
2020-04-01
Budget End
2021-03-31
Support Year
14
Fiscal Year
2020
Total Cost
Indirect Cost
Name
University of California San Francisco
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
094878337
City
San Francisco
State
CA
Country
United States
Zip Code
94118
Ely, Lauren K; Lolicato, Marco; David, Tovo et al. (2018) Structural Basis for Activity and Specificity of an Anticoagulant Anti-FXIa Monoclonal Antibody and a Reversal Agent. Structure 26:187-198.e4
Arrigoni, Cristina; Minor Jr, Daniel L (2018) Global versus local mechanisms of temperature sensing in ion channels. Pflugers Arch 470:733-744
Dang, Shangyu; Feng, Shengjie; Tien, Jason et al. (2017) Cryo-EM structures of the TMEM16A calcium-activated chloride channel. Nature 552:426-429
Minor Jr, Daniel L (2017) Channel surfing uncovers a dual-use transporter. EMBO J 36:3272-3273
Findeisen, Felix; Campiglio, Marta; Jo, Hyunil et al. (2017) Stapled Voltage-Gated Calcium Channel (CaV) ?-Interaction Domain (AID) Peptides Act As Selective Protein-Protein Interaction Inhibitors of CaV Function. ACS Chem Neurosci 8:1313-1326
Minor Jr, Daniel L (2016) Let It Go and Open Up, an Ensemble of Ion Channel Active States. Cell 164:597-8
Arrigoni, Cristina; Rohaim, Ahmed; Shaya, David et al. (2016) Unfolding of a Temperature-Sensitive Domain Controls Voltage-Gated Channel Activation. Cell 164:922-36
Gaudet, Rachelle; Roux, Benoit; Minor Jr, Daniel L (2015) Insights into the molecular foundations of electrical excitation. J Mol Biol 427:1-2
Payandeh, Jian; Minor Jr, Daniel L (2015) Bacterial voltage-gated sodium channels (BacNa(V)s) from the soil, sea, and salt lakes enlighten molecular mechanisms of electrical signaling and pharmacology in the brain and heart. J Mol Biol 427:3-30
Shaya, David; Findeisen, Felix; Abderemane-Ali, Fayal et al. (2014) Structure of a prokaryotic sodium channel pore reveals essential gating elements and an outer ion binding site common to eukaryotic channels. J Mol Biol 426:467-83

Showing the most recent 10 out of 20 publications