Literature DB >> 34686345

Neurotoxins subvert the allosteric activation mechanism of SARM1 to induce neuronal loss.

Tong Wu1, Jian Zhu2, Amy Strickland3, Kwang Woo Ko4, Yo Sasaki3, Caitlin B Dingwall3, Yurie Yamada3, Matthew D Figley4, Xianrong Mao3, Alicia Neiner3, A Joseph Bloom2, Aaron DiAntonio5, Jeffrey Milbrandt6.   

Abstract

SARM1 is an inducible TIR-domain NAD+ hydrolase that mediates pathological axon degeneration. SARM1 is activated by an increased ratio of NMN to NAD+, which competes for binding to an allosteric activating site. When NMN binds, the TIR domain is released from autoinhibition, activating its NAD+ hydrolase activity. The discovery of this allosteric activating site led us to hypothesize that other NAD+-related metabolites might activate SARM1. Here, we show the nicotinamide analog 3-acetylpyridine (3-AP), first identified as a neurotoxin in the 1940s, is converted to 3-APMN, which activates SARM1 and induces SARM1-dependent NAD+ depletion, axon degeneration, and neuronal death. In mice, systemic treatment with 3-AP causes rapid SARM1-dependent death, while local application to the peripheral nerve induces SARM1-dependent axon degeneration. We identify 2-aminopyridine as another SARM1-dependent neurotoxin. These findings identify SARM1 as a candidate mediator of environmental neurotoxicity and suggest that SARM1 agonists could be developed into selective agents for neurolytic therapy.
Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.

Entities:  

Keywords:  NAMPT; NMNAT; Vacor; base exchange reaction; mass spectrometry; metabolism; myelin; neurolytic block; sciatic nerve; tibial nerve

Mesh:

Substances:

Year:  2021        PMID: 34686345      PMCID: PMC8638332          DOI: 10.1016/j.celrep.2021.109872

Source DB:  PubMed          Journal:  Cell Rep            Impact factor:   9.423


  46 in total

1.  The SARM1 Toll/Interleukin-1 Receptor Domain Possesses Intrinsic NAD+ Cleavage Activity that Promotes Pathological Axonal Degeneration.

Authors:  Kow Essuman; Daniel W Summers; Yo Sasaki; Xianrong Mao; Aaron DiAntonio; Jeffrey Milbrandt
Journal:  Neuron       Date:  2017-03-22       Impact factor: 17.173

2.  NIH Image to ImageJ: 25 years of image analysis.

Authors:  Caroline A Schneider; Wayne S Rasband; Kevin W Eliceiri
Journal:  Nat Methods       Date:  2012-07       Impact factor: 28.547

3.  TIR domains of plant immune receptors are NAD+-cleaving enzymes that promote cell death.

Authors:  Li Wan; Kow Essuman; Ryan G Anderson; Yo Sasaki; Freddy Monteiro; Eui-Hwan Chung; Erin Osborne Nishimura; Aaron DiAntonio; Jeffrey Milbrandt; Jeffery L Dangl; Marc T Nishimura
Journal:  Science       Date:  2019-08-23       Impact factor: 47.728

4.  TIR Domain Proteins Are an Ancient Family of NAD+-Consuming Enzymes.

Authors:  Kow Essuman; Daniel W Summers; Yo Sasaki; Xianrong Mao; Aldrin Kay Yuen Yim; Aaron DiAntonio; Jeffrey Milbrandt
Journal:  Curr Biol       Date:  2018-01-25       Impact factor: 10.834

5.  Increased nuclear NAD biosynthesis and SIRT1 activation prevent axonal degeneration.

Authors:  Toshiyuki Araki; Yo Sasaki; Jeffrey Milbrandt
Journal:  Science       Date:  2004-08-13       Impact factor: 47.728

6.  Neuromodulation With Burst and Tonic Stimulation Decreases Opioid Consumption: A Post Hoc Analysis of the Success Using Neuromodulation With BURST (SUNBURST) Randomized Controlled Trial.

Authors:  Ryan S D'Souza; Natalie Strand
Journal:  Neuromodulation       Date:  2020-09-14

Review 7.  The SARM1 axon degeneration pathway: control of the NAD+ metabolome regulates axon survival in health and disease.

Authors:  Matthew D Figley; Aaron DiAntonio
Journal:  Curr Opin Neurobiol       Date:  2020-04-17       Impact factor: 6.627

8.  A rise in NAD precursor nicotinamide mononucleotide (NMN) after injury promotes axon degeneration.

Authors:  M Di Stefano; I Nascimento-Ferreira; G Orsomando; V Mori; J Gilley; R Brown; L Janeckova; M E Vargas; L A Worrell; A Loreto; J Tickle; J Patrick; J R M Webster; M Marangoni; F M Carpi; S Pucciarelli; F Rossi; W Meng; A Sagasti; R R Ribchester; G Magni; M P Coleman; L Conforti
Journal:  Cell Death Differ       Date:  2014-10-17       Impact factor: 15.828

9.  A Cell-Permeant Mimetic of NMN Activates SARM1 to Produce Cyclic ADP-Ribose and Induce Non-apoptotic Cell Death.

Authors:  Zhi Ying Zhao; Xu Jie Xie; Wan Hua Li; Jun Liu; Zhe Chen; Ben Zhang; Ting Li; Song Lu Li; Jun Gang Lu; Liangren Zhang; Li-He Zhang; Zhengshuang Xu; Hon Cheung Lee; Yong Juan Zhao
Journal:  iScience       Date:  2019-05-04

10.  Structural basis for SARM1 inhibition and activation under energetic stress.

Authors:  Michael Sporny; Julia Guez-Haddad; Tami Khazma; Carsten Mim; Michail N Isupov; Ran Zalk; Michael Hons; Avraham Yaron; Moshe Dessau; Yoel Shkolnisky; Yarden Opatowsky
Journal:  Elife       Date:  2020-11-13       Impact factor: 8.140
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  8 in total

1.  Nicotinic acid mononucleotide is an allosteric SARM1 inhibitor promoting axonal protection.

Authors:  Yo Sasaki; Jian Zhu; Yun Shi; Weixi Gu; Bostjan Kobe; Thomas Ve; Aaron DiAntonio; Jeffrey Milbrandt
Journal:  Exp Neurol       Date:  2021-08-14       Impact factor: 5.330

2.  Selective inhibitors of SARM1 targeting an allosteric cysteine in the autoregulatory ARM domain.

Authors:  Hannah C Feldman; Elisa Merlini; Carlos Guijas; Kristen E DeMeester; Evert Njomen; Ellen M Kozina; Minoru Yokoyama; Ekaterina Vinogradova; Holly T Reardon; Bruno Melillo; Stuart L Schreiber; Andrea Loreto; Jacqueline L Blankman; Benjamin F Cravatt
Journal:  Proc Natl Acad Sci U S A       Date:  2022-08-22       Impact factor: 12.779

Review 3.  Axon Biology in ALS: Mechanisms of Axon Degeneration and Prospects for Therapy.

Authors:  Michael P Coleman
Journal:  Neurotherapeutics       Date:  2022-10-07       Impact factor: 6.088

4.  Enrichment of SARM1 alleles encoding variants with constitutively hyperactive NADase in patients with ALS and other motor nerve disorders.

Authors:  Jonathan Gilley; Oscar Jackson; Menelaos Pipis; Mehrdad A Estiar; Ammar Al-Chalabi; Matt C Danzi; Kristel R van Eijk; Stephen A Goutman; Matthew B Harms; Henry Houlden; Alfredo Iacoangeli; Julia Kaye; Leandro Lima; John Ravits; Guy A Rouleau; Rebecca Schüle; Jishu Xu; Stephan Züchner; Johnathan Cooper-Knock; Ziv Gan-Or; Mary M Reilly; Michael P Coleman
Journal:  Elife       Date:  2021-11-19       Impact factor: 8.713

5.  Structural basis of SARM1 activation, substrate recognition, and inhibition by small molecules.

Authors:  Yun Shi; Philip S Kerry; Jeffrey D Nanson; Todd Bosanac; Yo Sasaki; Raul Krauss; Forhad K Saikot; Sarah E Adams; Tamim Mosaiab; Veronika Masic; Xianrong Mao; Faith Rose; Eduardo Vasquez; Marieke Furrer; Katie Cunnea; Andrew Brearley; Weixi Gu; Zhenyao Luo; Lou Brillault; Michael J Landsberg; Aaron DiAntonio; Bostjan Kobe; Jeffrey Milbrandt; Robert O Hughes; Thomas Ve
Journal:  Mol Cell       Date:  2022-03-24       Impact factor: 19.328

6.  SARM1 is a multi-functional NAD(P)ase with prominent base exchange activity, all regulated bymultiple physiologically relevant NAD metabolites.

Authors:  Carlo Angeletti; Adolfo Amici; Jonathan Gilley; Andrea Loreto; Antonio G Trapanotto; Christina Antoniou; Elisa Merlini; Michael P Coleman; Giuseppe Orsomando
Journal:  iScience       Date:  2022-01-25

Review 7.  Multifaceted roles of SARM1 in axon degeneration and signaling.

Authors:  Thomas J Waller; Catherine A Collins
Journal:  Front Cell Neurosci       Date:  2022-08-25       Impact factor: 6.147

8.  Neurotoxin-mediated potent activation of the axon degeneration regulator SARM1.

Authors:  Andrea Loreto; Carlo Angeletti; Giuseppe Orsomando; Michael P Coleman; Weixi Gu; Andrew Osborne; Bart Nieuwenhuis; Jonathan Gilley; Elisa Merlini; Peter Arthur-Farraj; Adolfo Amici; Zhenyao Luo; Lauren Hartley-Tassell; Thomas Ve; Laura M Desrochers; Qi Wang; Bostjan Kobe
Journal:  Elife       Date:  2021-12-06       Impact factor: 8.713
  8 in total

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