Effets de la noradrénaline sur les transmissions synaptiques dans la corne dorsale de la moelle épinière de rat / Effects of noradrenaline on synaptic transmissions in the dorsal horn of the rat spinal cord

Seibt, Frederik

07 July 2015

La corne dorsale de la moelle épinière (CDME) est un site d’intégration et de modulation de l’information somatosensorielle. Les laminae profondes de la CDME jouent un rôle important dans la modulation des informations nociceptives. Notre objectif a été de caractériser les effets de la NA sur la transmission synaptique des laminae profondes de la CDME. Nous montrons que la NA facilite la transmission synaptique inhibitrice dans les laminae III-V de la CDME. Ce phénomène met en jeu l’activation d’adrénocepteurs alpha1, alpha2, et bêta et nécessite une communication interlaminaire intacte entre les laminae III-IV et V. L’inhibition du métabolisme glial produit les mêmes effets qu’une section mécanique entre les laminae IV et V. Une interaction entre les cellules gliales et les neurones des laminae profondes la CDME semble donc indispensable à l’effet facilitateur de la NA. / The dorsal horn of the spinal cord (DH) is an important site of integration and modulation of somatosensory information and deep laminae of the DH play an important role in the modulation of nociceptive information in the neuronal network of the spinal cord.Our aim was to characterize the effects of NA on synaptic transmission in deep laminae of the DH.We show that NA facilitates inhibitory synaptic transmission in laminae III-IV of the DH. This phenomenon involves the activation of alpha1, alpha2, and beta adrenoceptors and requires intact interlaminar communications between laminae III-IV and V. Glial cell metabolism inhibition has the same consequences as a mechanical section between laminae IV and V. These results indicate that an interaction between glial cell and deep laminae neurons of the DH seems essential for the facilitatory effect of NA on inhibitory synaptic communications in laminae III-IV of the DH.

Moelle épinière

Corne dorsale

Noradrénaline

Transmission synaptique

Glie

Spinal cord

Dorsal horn

Noradrenaline

Synaptic transmission

Glia

572.4

573.8

Úloha míšních TRPV1 receptorů v nociceptivním přenosu a modulační účinky chemokinu CCL2 a agonistů µ-opioidního receptoru / The role of spinal TRPV1 receptors in nociceptive signalling and the modulatory effect of chemokine CCL2 and µ-opioid receptor agonists

Šulcová, Dominika

January 2017

The first nociceptive synapse in the spinal cord dorsal horn represents an important site, where nociceptive synaptic transmission can be modulated under pathological conditions. One of the modulatory mechanism involves activation of the transient receptor potential vanilloid 1 (TRPV1) that is expressed on central terminals of primary nociceptive neurons, where it regulates release of neurotransmitters and neuromodulators. Previous studies suggested that changes in TRPV1 activity may be related to effects of chemokine CCL2 (C-C motif ligand 2) and may be also involved in synaptic transmission modulation after µ-opioid receptors (MOP-R) activation. Because CCL2 receptors CCR2 often co-localize with TRPV1 and MOP-R, the goal of this work was to studypossible interactions of these receptors on the pre-synaptic endings of primaryafferents in the spinal cord dorsal horn and their role in nociceptive signalling under pathological conditions. The presented thesis focused on the effect of CCL2 during peripheral neuropathy and its interference with µ-opioid receptor activation. To studysynaptic transmission at the spinal cord level, patch-clamp recordings of excitatory post-synaptic currents (EPSC) in superficial spinal cord dorsal horn neurons in acute lumbar spinal cord slices from rats was used....

Protéine kinase C γ et hypersensibilité mécanique trigéminale chez le rat / Protein kinase C γ and trigeminal mechanical hypersensitivity in rats

Pham Dang, Nathalie

19 December 2014

Les syndromes douloureux chroniques, inflammatoires ou neuropathiques, se caractérisent par une hypersensiblitité douloureuse, sous forme de douleurs spontanées et d’allodynie et d’hyperalgésie. L’isoforme γ de la protein kinase C (PKCγ), concentrée dans un type spécifique d’interneurones de la couche II interne (IIi) de la corne dorsale de la moelle ou du sous-noyau caudal du trijumeau (Sp5C) est impliqué dans mécanismes centraux de l’allodynie mécanique, une condition dans laquelle le toucher provoque une douleur. Nous avons utilisé des techniques comportementales et immunohistochimiques dans le système trigéminal.Le rôle de la PKCγ dans le développement de l’allodynie mécanique est bien établi après lésion nerveuse périphérique. Par contre, il l’est beaucoup moins dans l’allodynie d’origine inflammatoire. Nous avons testé l’hypothèse que l’allodynie mécanique persistante à la suite d’une inflammation périphérique provoquée par l’adjuvent complet de Freund (‘complete Freund’s adjuvant’ ou CFA) est bien due à une activation de la PKCγ. L’injection sous-cutanée de CFA au niveau de la zone d’insertion des vibrisses induit une allodynie persistante spécifiquement statique. L’immunomarquage phopho-ERK1/2 montre que l’expression de cette allodynie s’accompagne d’une activation d’interneurones des couches I-IIe et IIi-IIIe, dont des interneurones PKCγ de la couche IIi. Cette allodynie statique est supprimée par l’application intracisternale de l’antagoniste PKCγ, KIG31-1, avant l’injection de CFA, mais pas 3 jours après l’injection de CFA. Ainsi, comme pour l’allodynie mécanique neuropathique, l’activation de la PKCγ est nécessaire au développement de l’allodynie mécanique inflammatoire.Nous avons aussi examiné si l’activation de la PKCγ est suffisante pour le développement de l’allodynie mécanique. L’injection intracisternale de phorbol ester, 12,13-dibutyrate (PDBu), un activateur de la PKCγ, induit simultanément une allodynie mécanique statique et dynamique de la face. L’immunoréactivité phospho-ERK1/2 révèle que l’expression de ces deux allodynies mécaniques s’accompagne de la même activation d’interneurones des couches I-IIe et IIi-IIIe, dont des interneurones PKCγ de la couche IIi . Les effets de l’application de PDBu sont bloqués par l’application simultanée de KIG31-1.L’activation de la PKCγ seule est suffisante pour que se développe une allodynie mécanique, à la fois statique et dynamique. On sait que les interneurones PKCγ de la couche IIi sont directement activés par des afférences myélinisées mécaniques non nociceptives. Le niveau d’activation de la PKCγ contrôlerait la transmission de cette information vers les neurones de projection de la couche I, et donc la transformation du toucher en douleur. / Inflammatory and neuropathic chronic pain syndromes are characterized by pain hypersensitivy, manifest as spontaneous pain, allodynia and hyperalgesia. The γ isoform of protein kinase C (PKCγ), which is concentrated in a specific class of interneurons within inner lamina II (IIi) of the spinal (SDH) and medullary (MDH) dorsal horns, has been implicated in the central mechanisms underlying mechanical allodynia, a condition wherein touch produces pain. We used behavioral and immunohistochemical techniques in the trigeminal system.Whereas there is clear evidence for the involvement of PKCγ in neuropathic mechanical allodynia, that for the involvement of PKCγ in inflammatory mechanical allodynia is still controversial. We investigated the involvement of PKCγ into the persistent mechanical allodynia induced by complete Freund’s adjuvant (CFA) inflammation. Subcutaneous injection of CFA into the vibrissa pad of rats induced a persistent selectively static mechanical allodynia. Monitoring neuronal activity within medullary dorsal horn (MDH) with phospho-ERK1/2 immunoreactivity showed that activation of both laminae I-IIo and IIi-IIIo neurons, including lamina IIi PKCγ-expressing interneurons, was associated with the expression of static mechanical allodynia. Intracisternal injection of the selective PKCγ antagonist, KIG31-1, prevented CFA-induced static mechanical allodynia only when it was injected before, but not 3 days after, CFA injection. These results show that, as for neuropathic mechanical allodynias, PKCγ activation is necessary for inflammatory mechanical allodynia.We also examined whether PKCγ activation in naïve animals is sufficient for the establishment of mechanical allodynia. Intracisternal injection of the phorbol ester, 12,13-dibutyrate (PDBu), concomitantly induced static and dynamic facial mechanical allodynias Monitoring neuronal activity within MDH with phospho-ERK1/2 immunoreactivity revealed that the same activation of both laminae I-IIo and IIi-IIIo neurons, including lamina IIi PKCγ-expressing interneurons, was associated with the manifestation of both mechanical allodynias. PDBu-induced mechanical allodynias and associated neuronal activations were all prevented by intracisternal KIG31-1.Our findings reveal that PKCγ activation is sufficient for the development of static and dynamic mechanical allodynias. Lamina IIi PKCγ interneurons have been shown to be directly activated by low-threshold mechanical inputs carried by myelinated afferents. The level of PKCγ activation might thus gate the transmission of innocuous mechanical inputs to lamina I, nociceptive output neurons, thus turning touch into pain.

Interneurone

PK C γ

Allodynie mécanique

Douleur

Caudalis

Douleur inflammatoire orofaciale

PK C γ

Interneuron

Mechanical allodynie

Pain

Dorsal horn

Orafacial inflammatory pain

610

Spinal cholinergic system and chronic pain / Douleur chronique et système cholinergique spinal

Dhanasobhon, Dhanasak

24 October 2017

Chez les rongeurs et humains, un « tonus » cholinergique spinal endogène modulant les comportements nociceptifs (douloureux) a été décrit. Une source potentielle de cette acétylcholine sont les interneurones cholinergiques de la corne dorsale (CD) de la moelle épinière. Nos objectifs étaient les suivants : (1) caractériser le « tonus » cholinergique spinal responsable de l’établissement des seuils mécaniques nociceptifs et (2) élucider le rôle des neurones cholinergiques CD dans la modulation de l'information sensorielle chez des animaux naïfs et neuropathiques. Nous avons confirmé la présence d'un « tonus » cholinergique qui module les seuils mécaniques et démontré qu'il est encore présent, bien qu'il soit modifié, après une neuropathie. Les interneurones cholinergiques reçoivent des entrées excitatrices localisées sur des segments plus distants et reçoivent généralement une faible fréquence d’entrées inhibitrices. De plus, ils sont indirectement reliés par des afférences primaires nociceptives qui expriment TRPV1, ce qui démontre leur implication dans le circuit nociceptif. Dans les conditions neuropathiques, les entrées des neurones LIII / IV ne sont pas affectées après une lésion du nerf périphérique. Une meilleure compréhension du système cholinergique spinal peut ouvrir la voie à une thérapie alternative contre la douleur. / An endogenous spinal cholinergic tone modulating nociceptive (pain­like) behaviors has been demonstrated in rodents and humans. One potential source of this acetylcholine is the spinal Dorsal Horn (DH) cholinergic interneurons. Our objectives were to: (1) characterize the spinal cholinergic tone establishing mechanical nociceptive thresholds and (2) to elucidate the role of DH cholinergic neurons in the modulation of sensory information of naïve and neuropathic animals. We have confirmed the presence of a cholinergic tone modulating mechanical thresholds and demonstrated that it is still present, although altered, after neuropathy. The DH cholinergic interneurons receive excitatory inputs from distant spinal segments and generally receive lower inhibitory inputs. In addition, they are indirectly connected by a subset of nociceptive primary afferents expressing TRPV1, demonstrating their involvement in nociceptive processing. In neuropathic spinal circuits, the inputs to LIII/IV neurons appears to be unaffected after injury. Better understanding the spinal cholinergic system can pave way to alternative pain therapy.

Moelle épinière

Corne Dorsale

Neuropathique

Douleur chronique

Acétylcholine

Seuils mécanique

Transmission synaptique

Spinal cord

Dorsal Horn

Neuropathy

Chronic pain

Acetylcholine

Mechanical thresholds

Synaptic transmission

573.8

616.8

Modulace míšního synaptického přenosu při vzniku bolestivých stavů / Modulation of synaptic transmission in the development of painful states

Slepička, Jakub

January 2019

My thesis introduces the topic of nociceptive signalisation and processes involved in the formation and spreading of neuropathic pain. This study focuses on the mechanisms of nociceptive synaptic transmission mechanisms in the level of spinal dorsal horn and its modulation by paclitaxel, a chemotherapeutic drug inducing neuropathic changes. The attention is put especially on the possibility of glial activity participation in paclitaxel side effects. This idea stems from the existing hypothesis of the functional connection between TLR4 and TRPV1 receptor activity. TRPV1 is well known for its participation in chemical, thermal and nociceptive sensory transmission. Minocycline antibiotic is considered as an inhibitor of microglial activation therefore it was used for blocking neuroinflammation. The experimental part is comparing an impact of substances applied to the model of tachyphylaxis used for monitoring of nociceptive transmission changes according to decreasing activity of TRPV1 receptors. Electrophysiological recording of miniature excitatory postsynaptic currents from neurons in the Rexed laminae I. and II. of spinal dorsal horn was used. The results of my measurements show that minocycline is able to suppress acute effects of paclitaxel application in vitro if the spinal slice is incubated...

Impact des glucocorticoïdes circulants sur la maturation et le fonctionnement de l'inhibition spinale GABAergique / Impact of glucocorticoids on maturation and functioning of the inhibitory transmission involving GABA neurotransmitter

Zell, Vivien

22 November 2013

Les glucocorticoïdes (GC) sont des hormones stéroïdes synthétisées par les glandes surrénales. La production de ces GC est une des réponses de l’organisme pour rétablir l’homéostasie grâce à différentes actions comprenant des effets centraux sur le comportement et la douleur. C’est ce dernier qui a fait l’objet de mes travaux dans le cadre de cette thèse.Les afférences sensorielles primaires véhiculent les informations de la périphérie dans les cornes dorsales de la moelle épinière. Ces informations qui peuvent être nociceptives sont modulées par un réseau de neurones spinal avant d’être transmises et intégrées. Nous avons montré que les GC sont impliqués dans la maturation et le fonctionnement de la transmission inhibitrice faisant intervenir le neurotransmetteur GABA. Dans les cornes dorsales, cette inhibition est cruciale pour limiter les mécanismes de transmission de l’information nociceptive. / Glucocorticoids (GC) are steroid hormones synthesized in adrenals following HPA axis activation. GC production is a response of the organism to alleviate homeostasis perturbations through different actions. One of them involves central neuronal modulation of behavior and pain perception.Primary afferents convey peripheral sensory information in the dorsal horns of the spinal cord. This information can be nociceptive and are modulated by a spinal neuronal network before being transmitted and integrated. We showed that GC are implied in the maturation and functioning of the inhibitory transmission involving GABA neurotransmitter. In the dorsal horns this inhibitory transmission is of major importance, limiting the processing of nociceptive information.

Glucocorticoïdes

Cornes dorsales de la moelle épinière

Nociception

Corticostérone

Plasticité développementale

Électrophysiologie in vitro / in vivo

Glucocorticoids

Spinal cord dorsal horn

Nociception

Corticosterone

Developmental plasticity

In vitro / in vivo electophysiology

573.8

616.8

Cold thermal processing in the spinal cord

Wrigley, Paul John

January 2006

Doctor of Philosophy(PhD) / Two recently identified transient receptor potential (TRP) channels, TRPM8 and TRPA1, have been proposed to play an important role in mammalian cool and cold peripheral sensory transduction. When expressed in cell-lines the cloned TRPM8 and TRPA1 receptors have distinct pharmacological and temperature response characteristics. Although these receptors are also transported to the central terminals of primary afferents, little is known about their centrally mediated actions. In this thesis, I use an in vitro electrophysiological approach to investigate the dorsal horn processing of cool afferent modalities and the role of TRP ion channels. The results of this thesis provide further information on thermal processing, indicate direction for further research and suggest possible therapeutic targets for the management of abnormal cold sensory processing. Initial experiments demonstrate that the cooling agents and known TRPM8 and TRPA1 agonists, menthol and icilin, inhibit primary afferent evoked excitatory postsynaptic currents (EPSCs) in rat spinal cord dorsal horn neurons. In addition, temperature reduction, menthol and icilin increase the frequency of miniature EPSCs without affecting amplitude distribution or kinetics. Little or no direct postsynaptic effect on dorsal horn neurons, GABAergic or glycinergic transmission was found. In combination, these observations demonstrate that temperature reduction, menthol and icilin act presynaptically to increase the probability of glutamate release from primary afferent fibres. Further examination of the changes in glutamatergic synaptic transmission induced by temperature reduction, menthol and icilin reveals a subset of neurons sensitive to innocuous cool (< 29 oC) and low concentrations of icilin (3-10 µM) which closely match the temperature activation and pharmacological profile of TRPM8. In addition, the majority of lamina I and II neurons displayed characteristics partly consistent with TRPA1-activation, including a concentration-dependent response to icilin and blockade by ruthenium red. The present experiments did not allow thermal characterisation of these TRPA1-like responses. Together these observations indicate that the effects of menthol and icilin on glutamatergic synaptic transmission in the superficial dorsal horn are mediated by TRPM8 and possibly by TRPA1. Examination of the anatomical location of neurons activated by temperature reduction, menthol, icilin and capsaicin allowed the central termination pattern of thermoreceptive primary afferent fibres with specific TRP-like response characteristics to be determined. TRPM8-like presynaptic activation was confined to a subpopulation of neurons located in lamina I and outer lamina II, while the majority of neurons throughout laminae I and II received inputs sensitive to menthol, high concentrations of icilin and capsaicin. These findings suggest that innocuous cool sensation projects to a specific subpopulation of superficial dorsal horn neurons unlike other modalities (mediated by TRPV1, possibly TRPA1 and other receptors), which non-selectively engage circuits within the entire superficial dorsal horn. No morphological specificity was identified for recovered neurons after electrophysiological characterisation. Finally, mu-opioids were shown to inhibit basal glutamatergic synaptic transmission as well as menthol- and icilin-induced transmission in the superficial dorsal horn. Of particular interest, delta-opioids selectively inhibited icilin-induced synaptic transmission within the same location. The selective effect of delta-opioids suggests a possible role in modulating receptors activated by icilin (TRPM8 and TRPA1). Overall, this thesis provides further evidence that TRPM8 is responsible for the transduction of innocuous cold sensation in mammals and is a potential therapeutic target in humans with cold hyperaesthesia secondary to abnormal thermal processing. The use of delta-opioid agonists warrants further investigation in cold hypersensitivity states and potentially other forms of pain.

cold

cool

central thermal processing

spinal cord

superficial dorsal horn

synaptic transmission

whole-cell patch clamping

transient receptor potential receptors

TRPM8

TRPA1

TRPV1

menthol

icilin

capsaicin

opioid agonists

delta-opioid agonists

Cold thermal processing in the spinal cord

Wrigley, Paul John

January 2006

Doctor of Philosophy(PhD) / Two recently identified transient receptor potential (TRP) channels, TRPM8 and TRPA1, have been proposed to play an important role in mammalian cool and cold peripheral sensory transduction. When expressed in cell-lines the cloned TRPM8 and TRPA1 receptors have distinct pharmacological and temperature response characteristics. Although these receptors are also transported to the central terminals of primary afferents, little is known about their centrally mediated actions. In this thesis, I use an in vitro electrophysiological approach to investigate the dorsal horn processing of cool afferent modalities and the role of TRP ion channels. The results of this thesis provide further information on thermal processing, indicate direction for further research and suggest possible therapeutic targets for the management of abnormal cold sensory processing. Initial experiments demonstrate that the cooling agents and known TRPM8 and TRPA1 agonists, menthol and icilin, inhibit primary afferent evoked excitatory postsynaptic currents (EPSCs) in rat spinal cord dorsal horn neurons. In addition, temperature reduction, menthol and icilin increase the frequency of miniature EPSCs without affecting amplitude distribution or kinetics. Little or no direct postsynaptic effect on dorsal horn neurons, GABAergic or glycinergic transmission was found. In combination, these observations demonstrate that temperature reduction, menthol and icilin act presynaptically to increase the probability of glutamate release from primary afferent fibres. Further examination of the changes in glutamatergic synaptic transmission induced by temperature reduction, menthol and icilin reveals a subset of neurons sensitive to innocuous cool (< 29 oC) and low concentrations of icilin (3-10 µM) which closely match the temperature activation and pharmacological profile of TRPM8. In addition, the majority of lamina I and II neurons displayed characteristics partly consistent with TRPA1-activation, including a concentration-dependent response to icilin and blockade by ruthenium red. The present experiments did not allow thermal characterisation of these TRPA1-like responses. Together these observations indicate that the effects of menthol and icilin on glutamatergic synaptic transmission in the superficial dorsal horn are mediated by TRPM8 and possibly by TRPA1. Examination of the anatomical location of neurons activated by temperature reduction, menthol, icilin and capsaicin allowed the central termination pattern of thermoreceptive primary afferent fibres with specific TRP-like response characteristics to be determined. TRPM8-like presynaptic activation was confined to a subpopulation of neurons located in lamina I and outer lamina II, while the majority of neurons throughout laminae I and II received inputs sensitive to menthol, high concentrations of icilin and capsaicin. These findings suggest that innocuous cool sensation projects to a specific subpopulation of superficial dorsal horn neurons unlike other modalities (mediated by TRPV1, possibly TRPA1 and other receptors), which non-selectively engage circuits within the entire superficial dorsal horn. No morphological specificity was identified for recovered neurons after electrophysiological characterisation. Finally, mu-opioids were shown to inhibit basal glutamatergic synaptic transmission as well as menthol- and icilin-induced transmission in the superficial dorsal horn. Of particular interest, delta-opioids selectively inhibited icilin-induced synaptic transmission within the same location. The selective effect of delta-opioids suggests a possible role in modulating receptors activated by icilin (TRPM8 and TRPA1). Overall, this thesis provides further evidence that TRPM8 is responsible for the transduction of innocuous cold sensation in mammals and is a potential therapeutic target in humans with cold hyperaesthesia secondary to abnormal thermal processing. The use of delta-opioid agonists warrants further investigation in cold hypersensitivity states and potentially other forms of pain.

cold

cool

central thermal processing

spinal cord

superficial dorsal horn

synaptic transmission

whole-cell patch clamping

transient receptor potential receptors

TRPM8

TRPA1

TRPV1

menthol

icilin

capsaicin

opioid agonists

delta-opioid agonists

Propriétés morphologiques et électrophysiologiques des interneurones PKCγ de la couche IIi du Sp5C chez le rat / Morphological and electrophysiological characterization of lamina IIi PKCγ-interneurons within the medullary dorsal horn of adult rats.

El Khoueiry, Corinne

28 September 2015

L'allodynie mécanique est un symptôme cardinal des douleurs persistantes. Elle est due à l’activation de circuits, habituellement bloqués, des couches superficielles de la corne dorsale spinale ou du sous-noyau caudal du trijumeau (Sp5C), par lesquels les afférences mécaniques à bas seuil peuvent accéder aux neurones nociceptifs de projection de la couche I. Un élément déterminant de ces circuits est une classe d’interneurones excitateurs de la couche II interne (IIi) exprimant l'isoforme gamma de la protéine kinase C (PKCγ), et recevant des afférences des mécanorecepteurs à bas seuil. La modulation de l’inhibition tonique de ces interneurones PKCγ contribue à l’apparition de l’allodynie mécanique. Cependant la morphologie, les propriétés électrophysiologiques et les caractéristiques des afférences excitatrices et inhibitrices de ces interneurones PKCγ ne sont toujours pas connues. Utilisant des techniques d’électrophysiologie (enregistrements patch-clamp) et d'immunohistochimie sur tranches de Sp5C, nous avons caractérisé les propriétés des interneurones PKCγ de la couche IIi du Sp5C chez le rat adulte et comparé ces propriétés avec celles d’interneurones voisins n’exprimant pas la PKCγ.Cette étude révèle que l’arborisation neuritique des interneurones PKCγ s’étend largement au sein de la couche IIi, et peut se prolonger du coté dorsal jusqu’à la couche II externe, sans jamais atteindre la couche I. En outre, en fonction de cette extension neuritique, au moins deux sous-populations d'interneurones PKCγ peuvent être dissociées – centrales et radiales – qui s’avèrent être aussi fonctionnellement différentes. Comparés aux autres neurones non-PKCγ de la conche IIi, les interneurones PKCγ, dans leur ensemble, présentent un seuil de déclenchement des potentiels d’action plus bas et, souvent associée, plus fréquemment une réponse tonique à un courant dépolarisant, indiquant ainsi qu’ils sont plus facilement excitables. Cependant, ils reçoivent inversement une excitation synaptique plus faible. Quant aux afférences inhibitrices, la plupart des interneurones PKCγ expriment des synapses mixtes associant récepteurs GABAAergiques (GABAAR) et récepteurs glycinergiques (GlyR). Seul un petit nombre d’entre eux exprime des synapses uniquement GABAAR ou GlyR. Pourtant, tous les interneurones PKCγ reçoivent non seulement des mIPSCs mixtes GABAAR-GlyR, mais aussi des mIPSCs uniquement GABAAR ou uniquement GlyR. / Mechanical allodynia, a cardinal symptom of persistent pain, is associated with the unmasking of usually blocked local circuits within the superficial spinal or medullary dorsal horn (MDH), through which low-threshold mechanical inputs can gain access to the lamina I nociceptive output neurons. Key determinants of these circuits are lamina II (IIi) excitatory interneurons that selectively concentrate the gamma isoform of protein kinase C (PKCγ) and receive low-threshold mechanical receptor (LTMR) inputs. Tonic inhibition of PKCγ interneurons is thought to gate circuits underlying mechanical allodynia. However, the morphology, electrophysiological properties and excitatory and inhibitory synaptic inputs on these PKCγ interneurons are still unknown. Using whole-cell patch-clamp recordings and immunohistochemical techniques in slices of adult rat MDH, we characterized these lamina IIi PKCγ interneurons and compared them with neighboring non-PKCγ interneurons. Our results reveal that the neurites of PKCγ interneurons arborize extensively within lamina IIi, can spread dorsally into lamina IIo, but never reach lamina I. In addition, according to cell bodies and the orientation and extent of dendritic arbors, at least two morphologically different classes of PKCγ interneurons can be identified – central and radial – which appear to be also functionally different. Compared with neighboring lamina IIi non-PKCγ interneurons, PKCγ interneurons exhibit a lower threshold for action potentials, consistent with a more frequent tonic spike discharge to depolarizing step current, indicating that they are more excitable than other lamina IIi neurons. On the other hand, they receive a weaker excitatory synaptic drive. According to inhibitory inputs, most PKCγ interneurons display mixed-GABAA (GABAAR) and glycine (GlyR) receptor synapses with only very few of them displaying also GABAAR-alone or GlyR-alone synapses. Interestingly, all PKCγ interneurons exhibit mixed GABAAR–GlyR as well as GABAAR-only and GlyR-only mIPSCs. Altogether, this study indicates that PKCγ interneurons within lamina IIi of MDH are different from other lamina IIi neighboring neurons according to morphology, electrophysiological properties and synaptic inputs. This is consistent with their specific role in the gating of dorsally directed circuits within the MDH underlying mechanical allodynia. Moreover, we have identified two morphological and functional subclasses of PKCγ interneurons which might thus differently contribute to this gating.

Corne dorsale médullaire

Allodynie mécanique

Glycine

GABA

Inhibition

Morphologie

Électrophysiologie

Interneurone

Protéine kinase C- γ

Medullary Dorsal Horn

Mechanical allodynia.

Glycine

GABA

Inhibition

Morphology,

Electrophysiology

Interneurons

Protein kinase C-γ

570

Système cholinergique et modulation de la transmission nociceptive spinale / Cholinergic system and spinal nociceptive transmission modulation

Mesnage, Bruce

04 November 2013

L’acétylcholine (ACh) endogène de la corne dorsale de la moelle épinière (CDME) exerce une analgésie puissante utilisée en clinique, dont la source et les mécanismes demeurent inconnus. Elle siège probablement au niveau d’un plexus de fibres cholinergiques de la CDME d’origine non-élucidée. Dans ce contexte, nous avons pu établir que ce plexus est principalement issu d’interneurones cholinergiques spinaux caractérisés dans ces travaux, qui seraient donc le substrat probable de l’analgésie décrite. Décrits comme concourant aux effets aigus et analgésiques de la morphine, nous avons, par ailleurs, pu observer que les récepteurs de l’ACh participaient également aux effets chroniques et pro-algésique de la morphine, notamment au niveau de la CDME. Ceci place donc l’ACh comme un effecteur ou intermédiaire de la morphine.Nos travaux suggèrent ainsi que le système cholinergique spinal pourrait constituer une cible thérapeutique alternative pour de nouveaux traitements de la douleur / In the spinal cord dorsal horn (SCDH), endogenous acetylcholine (ACh) acts as a powerful analgesia, of clinical use. Though its source and mechanisms remain unravelled, this analgesia probably lies in a plexus of cholinergic fibers (PCF) located in the SCDH and of undetermined origin. In this context, we established that the PCF mainly originates from a spinal population of cholinergic interneurons, fully characterized in this work. These are, thus, the likely substrate of the spinal cholinergic analgesia.Besides, ACh receptors (AChR) partly mediate the analgesic acute effects of morphine. In this work, we also observed that a chronically-administered AChR agonist reproduces as well the pro-algesic effects of morphine in the same conditions. Thus, ACh appears as a possible intermediary or a final effecter of the morphine pain pathways.Our data suggest that the cholinergic system could become a new putative therapeutic target in pain management and treatment.

Injection spinale de toxine CTb

Reconstruction 3D

Electrophysiologie

Morphine

Récepteur nicotinique cholinergique

Acétylcholine et système cholinergique

Corne dorsale de la moelle épinière

Nociception et douleur

Pain and nociception

Spinal cord dorsal horn

Acetylcholine and cholinergic system

Nicotinic cholinergic receptor

Morphine

Electrophysiology

3-D Reconstruction

CTb spinal injection

572.8

615.7