Becca Roth scite author profile

TRPM2 is critically involved in diverse physiological processes including core temperature sensing, apoptosis, and immune response. TRPM2’s activation by Ca2+ and ADP ribose (ADPR), an NAD+-metabolite produced under oxidative stress and neurodegenerative conditions, suggests a role in neurological disorders. We provide a central concept between triple-site ligand binding and the channel gating of human TRPM2. We show consecutive structural rearrangements and channel activation of TRPM2 induced by binding of ADPR in two indispensable locations, and the binding of Ca2+ in the transmembrane domain. The 8-Br-cADPR—an antagonist of cADPR—binds only to the MHR1/2 domain and inhibits TRPM2 by stabilizing the channel in an apo-like conformation. We conclude that MHR1/2 acts as a orthostatic ligand-binding site for TRPM2. The NUDT9-H domain binds to a second ADPR to assist channel activation in vertebrates, but not necessary in invertebrates. Our work provides insights into the gating mechanism of human TRPM2 and its pharmacology.

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Structures of the TRPM5 channel elucidate mechanisms of activation and inhibition

Ruan

Haley

Orozco

et al. 2021

Nat Struct Mol Biol

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Neurexin-3 subsynaptic densities are spatially distinct from Neurexin-1 and essential for excitatory synapse nanoscale organization in the hippocampus

et al. 2023

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Proteins critical for synaptic transmission are non-uniformly distributed and assembled into regions of high density called subsynaptic densities (SSDs) that transsynaptically align in nanocolumns. Neurexin-1 and neurexin-3 are essential presynaptic adhesion molecules that non-redundantly control NMDAR- and AMPAR-mediated synaptic transmission, respectively, via transsynaptic interactions with distinct postsynaptic ligands. Despite their functional relevance, fundamental questions regarding the nanoscale properties of individual neurexins, their influence on the subsynaptic organization of excitatory synapses and the mechanisms controlling how individual neurexins engage in precise transsynaptic interactions are unknown. Using Double Helix 3D dSTORM and neurexin mouse models, we identify neurexin-3 as a critical presynaptic adhesion molecule that regulates excitatory synapse nano-organization in hippocampus. Furthermore, endogenous neurexin-1 and neurexin-3 form discrete and non-overlapping SSDs that are enriched opposite their postsynaptic ligands. Thus, the nanoscale organization of neurexin-1 and neurexin-3 may explain how individual neurexins signal in parallel to govern different synaptic properties.

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Author response: Ligand recognition and gating mechanism through three ligand-binding sites of human TRPM2 channel

Huang

Roth

Lü

et al. 2019

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Author Correction: Structures of the TRPM5 channel elucidate mechanisms of activation and inhibition

Ruan

Haley

Orozco

et al. 2021

Nat Struct Mol Biol

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In the version of this article initially published, the reference "Liu, D. & Liman, E. R. Intracellular Ca 2+ and the phospholipid PIP 2 regulate the taste transduction ion channel TRPM5. Proc. Natl Acad. Sci. USA ( 2003)" was omitted. It should have been cited in the first paragraph of the Introduction after the phrase "TRPM5 is activated upon the elevation of cytoplasmic Ca 2+ concentration... " as reference 3. Reference 12 in the original version of the article (Prawitt et al.) should also have been cited at this location, and it should have been reference 4. The errors have been corrected in the HTML and PDF versions of the article.

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Becca Roth

Ligand recognition and gating mechanism through three ligand-binding sites of human TRPM2 channel

Structures of the TRPM5 channel elucidate mechanisms of activation and inhibition

Neurexin-3 subsynaptic densities are spatially distinct from Neurexin-1 and essential for excitatory synapse nanoscale organization in the hippocampus

Author response: Ligand recognition and gating mechanism through three ligand-binding sites of human TRPM2 channel

Author Correction: Structures of the TRPM5 channel elucidate mechanisms of activation and inhibition

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