Abstract
TRPM2 (transient receptor potential channel, subfamily melastatin, member 2) is a Ca2+-permeable non-selective cation channel activated by the binding of adenosine 5′-diphosphoribose (ADPR) to its cytoplasmic NUDT9H domain (NUDT9 homology domain). Activation of TRPM2 by ADPR downstream of oxidative stress has been implicated in the pathogenesis of many human diseases, rendering TRPM2 an attractive novel target for pharmacological intervention. However, the structural basis underlying this activation is largely unknown. Since ADP (adenosine 5′-diphosphate) alone did not activate or antagonize the channel, we used a chemical biology approach employing synthetic analogues to focus on the role of the ADPR terminal ribose. All novel ADPR derivatives modified in the terminal ribose, including that with the seemingly minor change of methylating the anomeric-OH, abolished agonist activity at TRPM2. Antagonist activity improved as the terminal substituent increasingly resembled the natural ribose, indicating that gating by ADPR might require specific interactions between hydroxyl groups of the terminal ribose and the NUDT9H domain. By mutating amino acid residues of the NUDT9H domain, predicted by modelling and docking to interact with the terminal ribose, we demonstrate that abrogating hydrogen bonding of the amino acids Arg1433 and Tyr1349 interferes with activation of the channel by ADPR. Taken together, using the complementary experimental approaches of chemical modification of the ligand and site-directed mutagenesis of TRPM2, we demonstrate that channel activation critically depends on hydrogen bonding of Arg1433 and Tyr1349 with the terminal ribose. Our findings allow for a more rational design of novel TRPM2 antagonists that may ultimately lead to compounds of therapeutic potential.
Highlights
The presence of adenosine 50-diphosphoribose (ADPR) in mammalian cells has been known for a long time ([1] and references therein), but was mainly considered to be a result of the metabolism of the redox coenzyme β-NAD+ or the Ca2+ mobilizing second messenger cyclic adenosine 50-diphosphoribose [2], or degradation of either mono- or poly-adenosine 50-diphosphate (ADP)-ribosylated proteins [3]
Preparation of ADPR analogues with modifications to the terminal ribose structure To investigate the role of the terminal ribose of ADPR in the activation of transient receptor potential channel (TRPM2), we synthesized four derivatives of ADPR (Figure 1)
Using a homology model built on the basis of the crystal structure of human NUDT9 with different docked and modelled poses of ADPR in the binding pocket, we identified Thr1347, Tyr1349, Leu1381, Arg1433, and Tyr1485 as amino acids in proximity to the terminal ribose of ADPR that might potentially engage in hydrogen bonding or otherwise interact with the natural ligand
Summary
The presence of adenosine 50-diphosphoribose (ADPR) in mammalian cells has been known for a long time ([1] and references therein), but was mainly considered to be a result of the metabolism of the redox coenzyme β-NAD+ (nicotinamide adenosine 50-dinucleotide) or the Ca2+ mobilizing second messenger cyclic adenosine 50-diphosphoribose [2], or degradation of either mono- or poly-ADP (adenosine 50-diphosphate)-ribosylated proteins [3]. Activation of a non-selective cation channel of the melastatin subfamily of TRP (transient receptor potential) channels, TRPM2 (transient receptor potential channel, subfamily melastatin, member 2), by ADPR [4,5] has renewed interest in ADPR as a potential second messenger in its own right. Ca2+ entering via the activated channel subsequently sensitizes the channel to ADPR, resulting in a positive feedback loop [18]
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