- Open Access
Cav3.2 T-type calcium channels control acute itch in mice
Molecular Brain volume 13, Article number: 119 (2020)
Cav3.2 T-type calcium channels are important mediators of nociceptive signaling, but their roles in the transmission of itch remains poorly understood. Here we report a key involvement of these channels as key modulators of itch/pruritus-related behavior. We compared scratching behavior responses between wild type and Cav3.2 null mice in models of histamine- or chloroquine-induced itch. We also evaluated the effect of the T-type calcium channel blocker DX332 in male and female wild-type mice injected with either histamine or chloroquine. Cav3.2 null mice exhibited decreased scratching responses during both histamine- and chloroquine-induced acute itch. DX332 co-injected with the pruritogens inhibited scratching responses of male and female mice treated with either histamine or chloroquine. Altogether, our data provide strong evidence that Cav3.2 T-type channels exert an important role in modulating histamine-dependent and -independent itch transmission in the primary sensory afferent pathway, and highlight these channels as potential pharmacological targets to treat pruritus.
Acute itch (pruritus) serves a protective function in response to events such as insect bites, allergic reactions, or skin borne parasites [1, 2]. On the other hand, chronic itch reflects pathogenic, maladaptive, and debilitating conditions found in multiple systemic and skin diseases in pathologies such as diabetes, cancers, psoriasis and atopic dermatitis . Akin to the detection of painful stimuli by nociceptors, itch related information is detected by pruriceptive sensory neurons that have their nerve endings in the skin, and is then transmitted to the brain via synaptic connections in the spinal cord and then through the spinothalamic tract [4,5,6]. Even though pruritus and pain are distinct sensations, they display anatomic similarities. Both are transmitted by unmyelinated C fibers and lightly myelinated Aδ fibers . These smaller diameter neurons express voltage gated calcium channels (VGCC) including members of the T-type calcium channel family that are essential for pain signaling . The latter belong to the family of the low voltage activated calcium channels  and are further subdivided into Cav3.1, Cav3.2, and Cav3.3 subtypes, with expression in both the central and peripheral nervous systems. The Cav3.2 subtype is prominently expressed in somatosensory afferent fibers and spinal cord neurons and is a fundamental regulator of sensory signalling to the spinal cord [9, 10]. While the involvement of Cav3.2 in the transmission of pain is clearly established, the roles of these channels in the transmission of itch is only emerging. Indeed, it was reported that Cav3.2 is important for hydrogen sulfide (H2S)-induced itch responses in mice . More recently, it was also demonstrated that Cav3.2 channels are upregulated in the skin of uremic itch sufferers and may thus contribute to itch transmission in these patients . Altogether, these findings suggest that T-type calcium channels may also be important for the activity of pruriceptive neurons, thus we sought to determine whether Cav3.2 calcium channels are involved in chloroquine- and histamine-induced itch. We show that itch responses are reduced in Cav3.2 knockout mice and by pharmacological intervention with the T-type calcium channel blocker DX332 .
Materials and methods
All experiments were performed following approval by the Animal care committee of the University of Calgary. Adult (7–10 weeks old) male or female C57BL/6 J wild-type or male CACNA1H knockout (Cav3.2 null) mice were used and purchased from Jackson laboratories. Mice were housed at a maximum of five per cage (30 × 20 × 15 cm) with free access to food and water. They were kept on a 12-h light/dark cycle (lights on at 7 am) with the room maintained at a temperature of 23 ± 1 °C. Experiments were carried out between 9 am-3 pm. For each condition, separate randomized groups of mice were tested on three different days. Drugs were delivered subcutaneously (s.c.) and standard volumes of 20 μl were injected. DX332 was dissolved in dimethyl sulfoxide (DMSO), and control animals received phosphate buffered solution (PBS) + 1% DMSO, which was the maximum DMSO concentration in the highest dosage of DX332 tested. Different cohorts of mice were used for each test and each mouse was used only once. Chloroquine diphosphate (Tocris) and histamine (Sigma-Aldrich) were dissolved in PBS. The selective Cav3.2 blocker DX332  was dissolved in DMSO 2% and was co-injected subcutaneously (s.c.) with the pruritogens.
Histamine (100 μg in 20 μl) or PBS were injected subcutaneously at the back of the neck of wild-type or CaV3.2 null mice using a BD insulin syringe with a 31-gauge needle. A volume of 20 μl was injected. Animals had the fur on their back trimmed 48 h before the experiments. After receiving an injection of a solution of histamine or PBS, mice were placed into individual plexiglass holding containers and the time spent scratching was scored for 30 min. In a different series of experiments, either male or female wild-type mice were treated with DX332 (100 μg/s.c.) or vehicle (20 μl/s.c.) in association with histamine.
In the same manner as above, injections of 20 μl of chloroquine (200 μg) were performed using a BD insulin syringe with a 31-gauge needle. Injections occurred in the back of the neck 2 days after having the fur trimmed. Following an injection with chloroquine or PBS, animals were placed and kept in plexiglass holding containers and the time spent scratching was scored for 30 min. Male and female wild-type mice were treated with DX332 (10.0–100.0 μg/s.c.) or vehicle (20 μl/s.c.) in association with chloroquine.
Data were analyzed with Graphpad Prism 6.0 and are presented as the mean ± SEM. One- or two-way analysis of variance (ANOVA) with Tukey’s post hoc correction was used. Statistical significance was accepted at the level of p < 0.05.
Results and discussion
We first determined whether deletion of Cav3.2 channels in mice affects scratching behavior induced by histamine or chloroquine injection. Subcutaneously injected histamine (100 μg in 20 μl) into the nape of the neck of wild-type mice elicited robust scratching behavior (Fig. 1), in agreement with previous works . In contrast, Cav3.2 null mice were resistant to histamine induced itch as seen by a dramatic reduction in the time spent scratching (Fig. 1). In a similar manner, injections of chloroquine (200 μg in 20 μl) into the nape of the neck of wild-type mice produced strong and sustained scratching responses that were greatly depressed in Cav3.2 null mice (Fig. 2). Together, these data indicate that the expression of Cav3.2 channels is required for acute itch.
In a separate series of experiments, we evaluated the effect of the T-type channel blocker DX332 (a.k.a. compound 9 in Ref ) in male and female wild-type mice. DX332 is a potent inhibitor of Cav3.2 channels and has been shown by us to mediate analgesia in mouse models of inflammatory and neuropathic pain in a Cav3.2 channel-dependent manner . Treatment with DX332 (10.0–100.0 μg in 20 μl, co-injected) produced dose-dependent inhibition of itch responses in male (Fig. 3) mice injected with chloroquine. A similar effect was observed in female mice (Fig. 4). Again, DX332 (100.0 μg in 20 μl, co-injected) produced a significant decrease of histamine–induced scratching behaviors in male (Fig. 5) and in female (Fig. 6) mice. We did not observe any flinching or vocalization in mice injected with either chloroquine or histamine, thus indicating an absence of behaviors that are a typical indication of nociceptive or nocifensive responses rather than itch . Collectively, our data indicate that local inhibition of Cav3.2 channels in tissues exposed to histamine or chloroquine prevents the development of itch. Previous work suggested that Cav3.1 and Cav3.3 channels, but not Cav3.2, are determinants for itch signal transmission to the spinal cord , however, these experiments were based on intradermal injection of zinc which (although being a preferential inhibitor of Cav3.2 among the T-type calcium channel family) also enhances the activity of Cav3.1 and Cav3.3 channels by slowing inactivation kinetics . By contrast, our use of Cav3.2 null mice allows us to clearly attribute a role of Cav3.2 in the processing of peripheral itch signals.
Itch is transmitted by diverse afferent sensory neurons located in the dorsal root ganglia (DRG) and trigeminal ganglia (TG) which detect nociceptive and pruritogenic stimuli and can be modulated by pruritogens as well as algogens [1, 18, 19]. Despite the neurophysiological similarities between pain and itch, there is accumulating evidence that itch involves unique cellular and molecular mechanisms as well as distinct peripheral and central neuronal circuitry . There are two well characterized types of chemical itch, one known as histamine-dependent and another as histamine-independent itch, both of which are mediated by unmyelinated C fibers and lightly myelinated Aδ fibers . In fact, while some lines of evidence argue that pathways for histamine- and non histamine-mediated itch may almost completely overlap, in more recent studies others have suggested that distinct neuronal pathways mediate histamine and non-histamine itch [14, 22, 23]. Our data suggest that irrespective of these details, Cav3.2 channels are a common feature to both histamine-dependent and histamine-independent itch.
Histamine and chloroquine activate distinct cellular signalling pathways to give rise to itch . This is underscored by the notion that histamine receptor antagonists are effective in histamine mediated pruritus  and allergenic itch, whereas they are ineffective against most types of chronic itch conditions such as eczema and dry skin itch [17, 26, 27]. Histamine-mediated itch is initiated by activation of the histamine type 1 receptor (H1) expressed in TRPV1+/phospholiphase-β-3 (PLCB3) positive neurons , and requires co-activation of the transient receptor potential cation channel subfamily V member 1 (TRPV1) and H1 receptors to elicit behavioral responses . On the other hand, itch produced by chloroquine is mediated by the Mas-related G-protein-coupled receptor (Mrgpr) A3 or C1, and with co-activation of Transient receptor potential cation channel subfamily A member 1(TRPA1) channels [23, 29]. Both groups are members of the GPCR superfamily and are coupled to various G-proteins, through which they transduce their signals via second messengers such as phospholipase Cbeta 3 (PLCB3) and inositol triphosphate (IP3) . It is possible that Cav3.2 channels are direct downstream targets of these signalling pathways, thus leading to increased T-type channel activity and increased neuronal firing. Alternatively, it is conceivable that histamine may directly act on Cav3.2 channels. Finally, it is possible that the activity of pruriceptive sensory neurons is increased by receptor-mediated actions on other types of ion channels, and that pharmacological inhibition or depletion of Cav3.2 channels expressed in nerve endings simply serves to compensate for this increase in activity. At this point we cannot distinguish among the alternatives. The Cav3.2 channel is widely expressed in TRPV1 positive sensory fibers where it is known to participate in the transmission of pain signals from the nerve endings to the spinal cord . It was demonstrated that mechanical hyperalgesia and allodynia caused by hydrogen sulfide (H2S) require activation of both Cav3.2 channels and TRPA1 receptors . Of interest, TRPV1- and TRPA1- positive fibers participate in different modalities of pain, including inflammatory mechanical hyperalgesia, mechanical allodynia and visceral pain , in which Cav3.2 channels have also emerged as potential therapeutic targets [33, 34]. The Cav3.2 channel is also considered as a selective marker for low (C-) threshold mechanoreceptors (LTMRs) that express Tyrosine hydroxylase/VGLUT3/TAFA4 and for the medium (Aδ-) LTMRs that are positive for TrkB . The precise expression and distribution of Cav3.2 channels in pruriceptive neurons is not known, however, given that itch responses were inhibited by local administration of DX332, they must be functionally involved at the level of nerve endings.
In conclusion, our findings reveal that the Cav3.2 T-type channel subtype is involved in both histamine-dependent and histamine-independent acute itch responses in mice of both sexes. While additional studies are necessary to elucidate the role played by the Cav3.2 channel in chronic itch such as atopic dermatitis, our findings strongly demonstrated that targeting Cav3.2 channels could be exploited for the development of novel anti-pruritus therapies.
Availability of data and materials
The data used in our study are available from the authors on reasonable request.
Low threshold mechanoreceptor
Voltage gated calcium channel
Transient receptor potential cation channel subfamily V member 1
Histamine type 1 receptor
Phosphate buffered saline
Ikoma A, Steinhoff M, Ständer S, Yosipovitch G, Schmelz M. The neurobiology of itch. Nat Rev Neurosci. 2006;7:535–47.
Koch SC, Acton D, Goulding M. Spinal circuits for touch, pain, and itch. Annu Rev Physiol. 2018;80:189–217.
Yosipovitch G, Bernhard JD. Chronic pruritus. N Engl J Med. 2013;368:1625–34.
Abraira VE, Ginty DD. The sensory neurons of touch. Neuron. 2013;79:618–39.
Bautista DM, Wilson SR, Hoon MA. Why we scratch an itch: the molecules, cells and circuits of itch. Nat Neurosci. 2014;17:175–82.
LaMotte RH, Dong X, Ringkamp M. Sensory neurons, and circuits mediating itch. Nat Rev Neurosci. 2014;15:19–31.
François A, Schüetter N, Laffray S, Sanguesa J, Pizzocaro A, Dubel S, Mantilleri A, Nargeot J, Noël J, Wood JN, Moqrich A, Pongs O, Bourinet E. The low-threshold Calcium Channel Cav3.2 determines low-threshold mechanoreceptor function. Cell Rep. 2015;10:370–82.
Zamponi GW, Striessnig J, Koschak A, Dolphin AC. The physiology, pathology, and pharmacology of voltage-gated calcium channels and their future therapeutic potential. Pharmacol Rev. 2015;67:821–70.
Snutch TP, Zamponi GW. Recent advances in the development of T-type calcium channel blockers for pain intervention. Pharmacology Br J Pharmacol. 2018;175:2375–83.
Candelas M, Reynders A, Arango-Lievano A, Neumayer C, Fruquière A, Demes E, Hamid J, Lemmers C, Bernat C, Monteil A, Compan V, Laffray S, Inquimbert P, Le Feuvre Y, Zamponi GW, Moqrich A, Bourinet E, Méry PF. Cav3.2 T-type calcium channels shape electrical firing in mouse Lamina II neurons. Sci Rep. 2019;9:3112.
Wang XL, Tian B, Huang Y, Peng XY, Chen LH, Li JC, Liu T. Hydrogen Sulfide-Induced Itch Requires Activation of Cav3.2 T-type Calcium Channel in Mice. Sci Reports. 2015;5:16768.
Momose A, Yabe M, Chiba S, Kumakawa K, Shiraiwa Y, Mizukami H. Role of Dysregulated ion channels in sensory neurons in chronic kidney disease-associated pruritus. Medicines. 2019;6:110.
Bladen C, McDaniel SW, Gadotti VM, Petrov RR, Berger ND, Diaz P. Zamponi, GW characterization of novel cannabinoid-based T-type calcium channel blockers with analgesic effects. ACS Chem Neurosci. 2015;6:277–87.
Han L, Ma C, Liu Q, Weng HJ, Cui Y, Tang Z, Kim Y, Nie H, Qu L, Patel KN, Li Z, McNeil B, He S, Guan Y, Xiao B, Lamotte RH, Dong X. A subpopulation of Nociceptors specifically linked to itch. Nat Neurosci. 2013;16:174–82.
Bell JK, McQueen DS, Rees JL. Involvement of histamine H4 and H1 receptors in scratching induced by histamine receptor agonists in Balb C mice. Br J Pharmacol. 2004;142:374–80.
Lin SF, Wang B, Zhang FM, Fei YH, Gu JH, Li J, Bi LB, Liu XJ. T-type calcium channels, but not Cav3.2, in the peripheral sensory afferents are involved in acute itch in mice. Biochem Biophys Res Commun. 2017;487:801–6.
Traboulsie A, Chemin J, Chevalier M, Quignard JF, Nargeot J, Lory P. Subunit-specific modulation of T-type calcium channels by zinc. J Physiol. 2007;578:159–71.
Paus R, Schmelz M, Biró T, Steinhoff M. Frontiers in pruritus research: scratching the brain for more effective itch therapy. J Clin Invest. 2006;116:1174–86.
Bartsch VB, Niehaus JK, Taylor-Blake B, Zylka MJ. Enhanced histamine-induced itch in diacylglycerol kinase iota knockout mice. PLoS One. 2019;14:e0217819.
Dong X, Dong X. Peripheral and central mechanisms of itch. Neuron. 2018;98:482–94.
Sun YG, Zhao ZQ, Meng XL, Yin J, Liu XY, Chen ZF. Cellular basis of itch sensation. Science. 2009;325:1531–4.
Namer B, Carr R, Johanek LM, Schmelz M, Handwerker HO, Ringkamp M. Separate peripheral pathways for pruritus in man. J Neurophysiol. 2008;100:2062–9.
Liu Q, Tang Z, Surdenikova L, Kim S, Patel KN, Kim A, Ru F, Guan Y, Weng HJ, Geng Y, Undem BJ, Kollarik M, Chen ZF, Anderson DJ, Dong X. Sensory Neuron-Specific GPCR Mrgprs are itch receptors mediating Chloroquine-induced pruritus. Cell. 2009;139:1353–65.
Roberson DP, Gudes S, Sprague JM, Patoski HA, Robson VK, Blasl F, Duan B, Oh SB, Bean BP, Ma Q, Binshtok AM, Woolf CJ. Activity-dependent silencing reveals functionally distinct itch-generating sensory neurons. Nat Neurosci. 2013;16:910–8.
Grundmann S, Stander S. Chronic pruritus: clinics and treatment. Ann Dermatol. 2011;23:1–11.
Yosipovitch G, Papoiu ADP. What causes itch in atopic dermatitis? Curr Allergy Asthma Rep. 2008;8:306–11.
Akiyama T, Carstens MI, Carstens E. Enhanced scratching evoked by PAR-2 agonist and 5-HT but not histamine in a mouse model of chronic dry skin itch. Pain. 2010;151:378–83.
Shim WS, Tak MH, Lee MH, Kim M, Kim M, Koo JY, Lee CH, Kim M, Oh U. TRPV1 mediates histamine-induced itching via the activation of phospholipase A2 and 12-lipoxygenase. J Neurosci. 2007;27:2331–7.
Imamachi N, Park GH, Lee H, Anderson DJ, Simon MI, Basbaum AI, Han SK. TRPV1-expressing primary afferents generate behavioral responses to pruritogens via multiple mechanisms. PNAS. 2009;106:11330–5.
Stemkowski P, García-Caballero A, Gadotti VM, M’Dahoma S, Huang S, Black SAG, Chen L, Souza IA, Zhang Z, Zamponi GW. TRPV1 Nociceptor activity initiates USP5/T-type channel-mediated plasticity. Cell Rep. 2016;17:2901–12.
Okubo K, Matsumara M, Kawaishi Y, Aoki Y, Matsunami M, Okawa Y. Hydrogen sulfide-induced mechanical hyperalgesia and allodynia require activation of both Cav3.2 and TRPA1 channels in mice. Br J Pharmacol. 2012;166:1738–43.
Sousa-Valente J, Andreou AP, Urban L, Nagy I. Transient receptor potential ion channels in primary sensory neurons as targets for novel analgesics. Br J Pharmacol. 2014;171:2508–27.
García-Caballero A, Gadotti VM, Stemkowski P, Weiss N, Souza IA, Hodgkinson V, Bladen C, Chen L, Hamid J, Pizzoccaro A, Deage M, François A, Bourinet E, Zamponi GW. The deubiquitinating enzyme USP5 modulates neuropathic and inflammatory pain by enhancing Cav3.2 channel activity. Neuron. 2014;83:1144–58.
Gadotti VM, Caballero AG, Berger ND, Gladding CM, Chen L, Pfeifer TA, Zamponi GW. Small organic molecule disruptors of Cav3.2 – USP5 interactions reverse inflammatory and neuropathic pain. Mol Pain. 2015;11:12.
This work was supported by a Foundation Grant from the Canadian Institutes of Health Research, and a grant from Alberta Innovates to GWZ. GWZ is a Canada Research Chair. VG is supported by the Vi Riddell program in Pediatric Pain. This work was also supported by the by the National Institute of Arthritis and Musculoskeletal and Skin Disease of the National Institutes of Health: 1R43AR076842–01 and 1R41NS105304–01 (P.D., JMK, NBW), P20GM103546 (P.D.). The content of this paper is solely the responsibility of the authors and does not necessarily reflect the official views of the National Institutes of Health.
Ethics approval and consent to participate
Consent for publication
Dr. Diaz is the founder of DermaXon™. J.K. and L.W. were employed at DermaXon™ during this study. PD and GWZ are inventors of the technology, they are entitled to future royalty payments. The other authors declare no conflicts.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Gadotti, V.M., Kreitinger, J.M., Wageling, N.B. et al. Cav3.2 T-type calcium channels control acute itch in mice. Mol Brain 13, 119 (2020). https://0-doi-org.brum.beds.ac.uk/10.1186/s13041-020-00663-9
- Cav3.2 T-type channel