Editorial
Migraine meets membrane trafficking
Cephalalgia 2014, Vol. 34(11) 851–852 ! International Headache Society 2014 Reprints and permissions: sagepub.co.uk/journalsPermissions.nav DOI: 10.1177/0333102414529194 cep.sagepub.com
Andrew F Russo
Having a drug that works clinically, but without a clear mechanism, is like having a key that can be tried on many doors—eventually one will open, but what will be found? The paper by Burstein and colleagues (1) in this issue of Cephalalgia describes an unexpected connection between migraine and membrane trafficking associated with mechanical pain. In an elegant series of experiments, they show that onabotulinumtoxinA (BoNT-A) inhibits mechanical hyperalgesia, and proposed that it may act by preventing the insertion of mechanoreceptors at the plasma membrane. The authors used their well-established rat model of inflammatory agent-induced cranial pain to test the effect of BoNT-A on electrophysiological responses to mechanical stimulation. As an added bonus, they examined both intracranial and extracranial nociceptive branches of meningeal nociceptors, which was logical given that BoNT-A is injected extracranially. BoNT-A inhibited C-fiber responses to suprathreshold stimuli that could produce mechanical pain, but not responses to threshold non-pain stimuli. The remarkably long latency of hours for BoNT-A action is consistent with inhibition of mechanoreceptor translocation to the plasma membrane. This study is the first to test BoNT-A effects on nociceptive neurons believed to mediate migraine headache. As such, it takes us a step closer to understanding how this therapy may benefit migraine patients. While clinically proven effective for chronic migraine, the mechanism of action has been a mystery. Dogma predicted that BoNT-A would inhibit neurotransmission similar to its known action at the neuromuscular junction by inhibiting soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE)-mediated vesicle fusion to the plasma membrane. Indeed, BoNT-A was shown to inhibit peripheral glutamate release from sensory neurons in vivo (2) and CGRP release from cultured trigeminal neurons (3). A similar inhibitory mechanism at the central terminals of trigeminal neurons has also been proposed (4). Those mechanisms may still contribute to BoNT-A action, but there had to be more to the story. As cell biologists know, vesicles do not just carry neurotransmitters, but their cargo also includes transmembrane proteins for delivery to
the plasma membrane. So a regulated membrane trafficking role fits well with the known actions of BoNT-A. To further underscore the importance of this process, this past year’s Nobel Prize for Physiology or Medicine was awarded for discoveries of the proteins regulating vesicle trafficking. This finding begins, but does not end, the story. Like any good experiment, it has left more questions. What is the molecular identity of the suprathreshold mechanoreceptor? The sensitivity to BoNT-A should help with this pursuit. Is induced translocation a common theme of chronic pain? As discussed in Burstein et al. (1), SNAREs are involved in cell surface delivery of TRPV1, TRPA1 and P2X3 receptors in neurons, TRPV1 channels are trafficked to the cell surface in response to inflammation and contribute to inflammatory hyperalgesia, and nociceptive signals induce TRPA1 translocation (5–7). In addition, regulated translocation has been observed for other pain-associated receptors, including the 5-HT1D triptan receptor (8), delta-opioid receptor (9), and the CGRP receptor, which is normally localized only on central, not peripheral, terminals of trigeminal neurons (10). Since many of these molecules are involved in peripheral nociceptor sensitization, it is tempting to speculate that Burstein and colleagues may have uncovered a broader target of BoNT-A action at peripheral terminals. Perhaps regulation of receptor trafficking to the cell surface may be an emerging mechanism underlying chronic pain. Conflict of interest None declared.
References 1. Burstein R, Zhang X, Levy D, et al. Selective inhibition of meningeal nociceptors by botulinum neurotoxin type A: Therapeutic implications for migraine and other
Molecular Physiology and Biophysics, University of Iowa, USA Corresponding author: Andrew F Russo, Molecular Physiology and Biophysics, University of Iowa, 51 Newton Rd, Iowa City, IA 52242, USA. Email: [email protected]
852
2.
3.
4.
5.
6.
pains. Cephalalgia 2014 (in press). DOI: 10.1177/ 0333102414527648. Cui M, Khanijou S, Rubino J, et al. Subcutaneous administration of botulinum toxin A reduces formalin-induced pain. Pain 2004; 107: 125–133. Durham PL, Cady R and Cady R. Regulation of calcitonin gene-related peptide secretion from trigeminal nerve cells by botulinum toxin type A: Implications for migraine therapy. Headache 2004; 44: 35–42; discussion 42–43. Filipovic B, Matak I, Bach-Rojecky L, et al. Central action of peripherally applied botulinum toxin type A on pain and dural protein extravasation in rat model of trigeminal neuropathy. PLoS One 2012; 7: e29803. Schmidt M, Dubin AE, Petrus MJ, et al. Nociceptive signals induce trafficking of TRPA1 to the plasma membrane. Neuron 2009; 64: 498–509. Shimizu T, Shibata M, Toriumi H, et al. Reduction of TRPV1 expression in the trigeminal system by botulinum neurotoxin type-A. Neurobiol Dis 2012; 48: 367–378.
Cephalalgia 34(11) 7. Camprubı´ -Robles M, Planells-Cases R and FerrerMontiel A. Differential contribution of SNARE-dependent exocytosis to inflammatory potentiation of TRPV1 in nociceptors. FASEB J 2009; 23: 3722–3733. 8. Bergerot A, Holland PR, Akerman S, et al. Animal models of migraine: Looking at the component parts of a complex disorder. Eur J Neurosci 2006; 24: 1517–1534. 9. Bao L, Jin SX, Zhang C, et al. Activation of delta opioid receptors induces receptor insertion and neuropeptide secretion. Neuron 2003; 37: 121–133. 10. Lennerz JK, Ruhle V, Ceppa EP, et al. Calcitonin receptor-like receptor (CLR), receptor activity-modifying protein 1 (RAMP1), and calcitonin gene-related peptide (CGRP) immunoreactivity in the rat trigeminovascular system: Differences between peripheral and central CGRP receptor distribution. J Comp Neurol 2008; 507: 1277–1299.
Migraine meets membrane trafficking
Cephalalgia 2014, Vol. 34(11) 851–852 ! International Headache Society 2014 Reprints and permissions: sagepub.co.uk/journalsPermissions.nav DOI: 10.1177/0333102414529194 cep.sagepub.com
Andrew F Russo
Having a drug that works clinically, but without a clear mechanism, is like having a key that can be tried on many doors—eventually one will open, but what will be found? The paper by Burstein and colleagues (1) in this issue of Cephalalgia describes an unexpected connection between migraine and membrane trafficking associated with mechanical pain. In an elegant series of experiments, they show that onabotulinumtoxinA (BoNT-A) inhibits mechanical hyperalgesia, and proposed that it may act by preventing the insertion of mechanoreceptors at the plasma membrane. The authors used their well-established rat model of inflammatory agent-induced cranial pain to test the effect of BoNT-A on electrophysiological responses to mechanical stimulation. As an added bonus, they examined both intracranial and extracranial nociceptive branches of meningeal nociceptors, which was logical given that BoNT-A is injected extracranially. BoNT-A inhibited C-fiber responses to suprathreshold stimuli that could produce mechanical pain, but not responses to threshold non-pain stimuli. The remarkably long latency of hours for BoNT-A action is consistent with inhibition of mechanoreceptor translocation to the plasma membrane. This study is the first to test BoNT-A effects on nociceptive neurons believed to mediate migraine headache. As such, it takes us a step closer to understanding how this therapy may benefit migraine patients. While clinically proven effective for chronic migraine, the mechanism of action has been a mystery. Dogma predicted that BoNT-A would inhibit neurotransmission similar to its known action at the neuromuscular junction by inhibiting soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE)-mediated vesicle fusion to the plasma membrane. Indeed, BoNT-A was shown to inhibit peripheral glutamate release from sensory neurons in vivo (2) and CGRP release from cultured trigeminal neurons (3). A similar inhibitory mechanism at the central terminals of trigeminal neurons has also been proposed (4). Those mechanisms may still contribute to BoNT-A action, but there had to be more to the story. As cell biologists know, vesicles do not just carry neurotransmitters, but their cargo also includes transmembrane proteins for delivery to
the plasma membrane. So a regulated membrane trafficking role fits well with the known actions of BoNT-A. To further underscore the importance of this process, this past year’s Nobel Prize for Physiology or Medicine was awarded for discoveries of the proteins regulating vesicle trafficking. This finding begins, but does not end, the story. Like any good experiment, it has left more questions. What is the molecular identity of the suprathreshold mechanoreceptor? The sensitivity to BoNT-A should help with this pursuit. Is induced translocation a common theme of chronic pain? As discussed in Burstein et al. (1), SNAREs are involved in cell surface delivery of TRPV1, TRPA1 and P2X3 receptors in neurons, TRPV1 channels are trafficked to the cell surface in response to inflammation and contribute to inflammatory hyperalgesia, and nociceptive signals induce TRPA1 translocation (5–7). In addition, regulated translocation has been observed for other pain-associated receptors, including the 5-HT1D triptan receptor (8), delta-opioid receptor (9), and the CGRP receptor, which is normally localized only on central, not peripheral, terminals of trigeminal neurons (10). Since many of these molecules are involved in peripheral nociceptor sensitization, it is tempting to speculate that Burstein and colleagues may have uncovered a broader target of BoNT-A action at peripheral terminals. Perhaps regulation of receptor trafficking to the cell surface may be an emerging mechanism underlying chronic pain. Conflict of interest None declared.
References 1. Burstein R, Zhang X, Levy D, et al. Selective inhibition of meningeal nociceptors by botulinum neurotoxin type A: Therapeutic implications for migraine and other
Molecular Physiology and Biophysics, University of Iowa, USA Corresponding author: Andrew F Russo, Molecular Physiology and Biophysics, University of Iowa, 51 Newton Rd, Iowa City, IA 52242, USA. Email: [email protected]
852
2.
3.
4.
5.
6.
pains. Cephalalgia 2014 (in press). DOI: 10.1177/ 0333102414527648. Cui M, Khanijou S, Rubino J, et al. Subcutaneous administration of botulinum toxin A reduces formalin-induced pain. Pain 2004; 107: 125–133. Durham PL, Cady R and Cady R. Regulation of calcitonin gene-related peptide secretion from trigeminal nerve cells by botulinum toxin type A: Implications for migraine therapy. Headache 2004; 44: 35–42; discussion 42–43. Filipovic B, Matak I, Bach-Rojecky L, et al. Central action of peripherally applied botulinum toxin type A on pain and dural protein extravasation in rat model of trigeminal neuropathy. PLoS One 2012; 7: e29803. Schmidt M, Dubin AE, Petrus MJ, et al. Nociceptive signals induce trafficking of TRPA1 to the plasma membrane. Neuron 2009; 64: 498–509. Shimizu T, Shibata M, Toriumi H, et al. Reduction of TRPV1 expression in the trigeminal system by botulinum neurotoxin type-A. Neurobiol Dis 2012; 48: 367–378.
Cephalalgia 34(11) 7. Camprubı´ -Robles M, Planells-Cases R and FerrerMontiel A. Differential contribution of SNARE-dependent exocytosis to inflammatory potentiation of TRPV1 in nociceptors. FASEB J 2009; 23: 3722–3733. 8. Bergerot A, Holland PR, Akerman S, et al. Animal models of migraine: Looking at the component parts of a complex disorder. Eur J Neurosci 2006; 24: 1517–1534. 9. Bao L, Jin SX, Zhang C, et al. Activation of delta opioid receptors induces receptor insertion and neuropeptide secretion. Neuron 2003; 37: 121–133. 10. Lennerz JK, Ruhle V, Ceppa EP, et al. Calcitonin receptor-like receptor (CLR), receptor activity-modifying protein 1 (RAMP1), and calcitonin gene-related peptide (CGRP) immunoreactivity in the rat trigeminovascular system: Differences between peripheral and central CGRP receptor distribution. J Comp Neurol 2008; 507: 1277–1299.
