AGH é um novo fragmento da cadeia alfa da hemoglobina com atividade antinociceptiva. / AGH is a new hemoglobin alpha-chain fragment with antinociceptive activity.

Natália Mazini Ribeiro

13 May 2013

A proteólise limitada de certas proteínas leva à liberação de peptídeos opióides endógenos. Vários relatos apontam que peptídeos derivados da hemoglobina como hemorfinas e hemopressinas têm efeito antinociceptivo, pela atividade de modulação de receptores acoplados a proteínas G. No presente estudo, um ensaio de captura do substrato (ECS) foi combinado com a marcação isotópica e LC-MS/MS para identificar e caracterizar um novo fragmento da hemoglobina que se liga à EP24.15. O peptídeo AGH, identificado neste trabalho, inibe respostas de hipernocicepção periféricas através de receptores opióides do tipo <font face=\"Symbol\">m . A persistência do peptídeo AGH no tecido nervoso perfundido sugere relevância fisiológica. Embora o AGH seja derivado de hemoglobina e tenha atividade opióide, falta-lhe a sequência chave das hemorfinas (YPWT), indicando que ele pode pertencer a uma nova classe de peptídeos derivados da hemoglobina. Adicionalmente, o AGH modula as interações entre as proteínas 14-3-3<font face=\"Symbol\">e e EP24.15 in vitro, podendo estar relacionado com a secreção não convencional da EP24.15. / Limited proteolysis of certain proteins leads to the release of endogenous opioid peptides. Several reports have shown that hemoglobin-derived peptides such as hemorphins and hemopressins have an antinociceptive effect by modulating GPCR activity. In the present study, a substrate capture assay (SCA) was combined with isotopic labeling and LC-MS/MS to identify and characterize a new bioactive hemoglobin fragment that binds to EP24.15. AGH, a new peptide identified in this work, inhibits peripheral hyperalgesic responses through <font face=\"Symbol\">m opioid receptors (MOR). The persistence of AGH peptide in perfused nervous tissue suggests its physiological relevance. Although AGH is derived from hemoglobin and it is a peptide with opioid activity, it lacks the key sequence of hemorphins (YPWT), indicating that it is part of a new class of peptides derived from hemoglobin. Additionally, the AGH modulates interactions between 14-3-3<font face=\"Symbol\">e and EP24.15 proteins in vitro and may be related to the unconventional EP24.15 secretion.

Dor

Espectrometria de massas

Hemoglobinas

Metabolismo de proteína

Nociceptores

Peptídeos

Hemoglobin

Mass spectrometry

Nociceptors

Pain

Peptides

Protein metabolism

Resurgent sodicum current modulation by auxiliary subunits in dorsal root ganglia neurons and potential implications in pain pathologies

Barbosa Nuñez, Cindy Marie

11 April 2016

Indiana University-Purdue University Indianapolis (IUPUI) / Increased electrical activity in peripheral sensory neurons contributes to pain. A unique type of sodium current, fast resurgent current, is proposed to increase nerve activity and has been associated with pain pathologies. While sodium channel isoform Nav1.6 has been identified as the main carrier of fast resurgent currents, our understanding of how resurgent currents are modulated in sensory neurons is fairly limited. Thus the goal of this dissertation was to identify resurgent current modulators. In particular, we focused on sodium channel beta subunits (Navβs) and fibroblast growth factor homologous factors (FHFs) in dorsal root ganglion (DRG) neurons. We hypothesized that Navβ4 and FHF2B act as positive regulators by mediating resurgent currents and modulating Nav1.6 inactivation, respectively. In contrast, we hypothesized FHF2A negatively regulates resurgent current by increasing the probability of channels in inactivated states. Thus, the aims of this dissertation were to 1) determine if Navβ4 regulates fast resurgent currents in DRG neurons, 2) examine the effects of Navβ4 knockdown on resurgent currents, firing frequency and pain associated behavior in an inflammatory pain model and 3) determine if FHF2A and FHF2B functionally regulate Nav1.6 currents, including resurgent currents in DRG neurons. To examine the aims, we used biochemical, electrophysiological and behavioral assays. Our results suggest that Navβ4 is a positive regulator of resurgent currents: in particular, the C-terminus likely mediates these currents. Localized knockdown of Navβ4 decreased inflammation-induced enhancement of resurgent currents and neuronal excitability, and prevented the development of persistent pain associated behavior in an inflammatory pain model. FHF2B increased resurgent currents and delayed inactivation. In contrast, FHF2A limited resurgent currents; an effect that is mainly contributed by FHF2A's N-terminus activity that increased accumulation of channels in inactivated states. Interestingly, in an inflammatory pain model FHF2B was upregulated and FHFA isoforms were downregulated. Together these results suggest that FHF2A/B modulation might contribute to enhanced resurgent currents and increased neuronal excitability observed in the inflammatory pain model. Overall, our work has identified three resurgent current modulators FHF2A, FHF2B and Navβ4. Manipulation of these proteins or their activity might result in novel strategies for the study and treatment of pain.

Auxiliary subunits

Dorsal Root Ganglia

Pain

Resurgent sodium currents

Sodium channel

Sensory neurons

Sodium channels

Sensory neurons

Pain

Nociceptors

NEUROFIBROMIN, NERVE GROWTH FACTOR AND RAS: THEIR ROLES IN CONTROLLING THE EXCITABILITY OF MOUSE SENSORY NEURONS

Wang, Yue

03 January 2007

Indiana University-Purdue University Indianapolis (IUPUI) / ABSTRACT Yue Wang Neurofibromin, nerve growth factor and Ras: their roles in controlling the excitability of mouse sensory neurons Neurofibromin, the product of the Nf1 gene, is a guanosine triphosphatase activating protein (GAP) for p21ras (Ras) that accelerates the conversion of active Ras-GTP to inactive Ras-GDP. It is likely that sensory neurons with reduced levels of neurofibromin have augmented Ras-GTP activity. In a mouse model with a heterozygous mutation of the Nf1 gene (Nf1+/-), the patch-clamp recording technique is used to investigate the role of neurofibromin in controlling the state of neuronal excitability. Sensory neurons isolated from adult Nf1+/- mice generate more APs in response to a ramp of depolarizing current compared to Nf1+/+ mice. In order to elucidate whether the activation of Ras underlies this augmented excitability, sensory neurons are exposed to nerve growth factor (NGF) that activates Ras. In Nf1+/+ neurons, exposure to NGF increases the production of APs. To examine whether activation of Ras contributes to the NGF-induced sensitization in Nf1+/+ neurons, an antibody that neutralizes Ras activity is internally perfused into neurons. The NGF-mediated augmentation of excitability is suppressed by the Ras-blocking antibody in Nf1+/+ neurons, suggesting the NGF-induced sensitization in Nf1+/+ neurons depends on the activation of Ras. Surprisingly, the excitability of Nf1+/- neurons is not altered by the blocking antibody, suggesting that this enhanced excitability may depend on previous activation of downstream effectors of Ras. To determine the mechanism giving rise to augmented excitability of Nf1+/- neurons, isolated membrane currents are examined. Consistent with the enhanced excitability of Nf1+/- neurons, the peak current density of tetrodotoxin-resistant (TTX-R) and TTX-sensitive (TTX-S) sodium currents (INa) are significantly larger than in Nf1+/+ neurons. Although the voltage for half-maximal activation (V0.5) is not different, there is a significant depolarizing shift in the V0.5 for steady-state inactivation of INa in Nf1+/- neurons. In summary, these results demonstrate that the enhanced production of APs in Nf1+/- neurons results from a larger current amplitude and a depolarized voltage dependence of steady-state inactivation of INa that leads to more sodium channels being available for the subsequent firing of APs. My investigation supports the idea that regulation of channels by the Ras cascade is an important determinant of neuronal excitability. Grant D. Nicol, Ph.D, Chair

dorsal root ganglia

neurofibromin

nerve growth factor

nociceptors

potassium currents

Ras

sodium currents

tetrodotoxin

Guanosine triphosphatase

Sensory neurons

Ras oncogenes

Characterisation of the neurosteroid analgesic alphadolone

Winter, Lara

January 2004

Abstract not available

Neurohormones -- Physiological effect

Steroids -- Physiological effect

Analgesics

Analgesia

GABA -- Receptors

Nociceptors

Opioids

Sedatives -- Side effects

Drug interactions

Diabetic neuropathies

Drug tolerance

Neural circuits engaged in mastication and orofacial nociception

Athanassiadis, Tuija

January 2009

A deeper understanding of both movement control and the effects of nociceptor inputs on our motor systems is critical for proper clinical diagnosis of musculo-skeletal dysfunctions and for development of novel rehabilitation schemes. In the jaw system, masticatory movements are produced by a central pattern generator (CPG) located in the brainstem. Considerable efforts have been made in deciphering this neuronal network. The present thesis contributes towards an increasingly detailed understanding of its essential elements, and presents a hypothesis of how deep somatic pain (i.e. muscle pain) may be evoked and interferes with the masticatory CPG circuitry. In Paper I, the expression of c-Fos-like protein was used as a molecular marker to visualize brainstem neurons that were active during induced fictive mastication in the anesthetized and paralyzed rabbit. Our findings provide a previously lacking detailed record of the neuronal populations that form the masticatory motor pattern. Certain cells were located in brainstem areas previously suggested to be involved in the masticatory CPG. However, it was a new finding that neurons in the dorsal part of the trigeminal main sensory nucleus (NVsnpr-d) may belong to this circuitry. Paper II focused on the discovered neurons in NVsnpr in an in vitro slice preparation from young rats.  Intracellular recordings allowed us to define two cell types based on their response to depolarizing current. Microstimulation applied to the trigeminal motor nucleus, its reticular border, the parvocellular reticular formation and the nucleus reticularis pontis caudalis, elicited postsynaptic potentials in 81% of the neurons tested. Responses obtained were predominately excitatory and sensitive to gluta-matergic antagonists DNQX or/and APV. Some inhibitory and biphasic responses were also evoked. Bicuculline methiodide or strychnine blocked the IPSPs indicating that they were mediated by GABAA or glycinergic receptors. About one third of the stimulations activated both types of neurons antidromically. Neurons in NVsnpr-d seem to gather all the conditions that can theoretically account for a role in masticatory rhythm generation. In Paper III, the masticatory model system was used to investigate the possible role of muscle spindle primary afferents in development of persistent musculoskeletal pain. Following intramuscular acidic (pH 4.0) saline injections of rat masseter muscles, in vitro whole cell recordings were done from jaw closing muscle spindle somata located in the trigeminal mesencephalic nucleus (NVmes). Compared to control neurons, the somata of afferents exposed to acid had more hyperpolarized membrane potentials, more hyperpolarized thresholds for firing, high frequency membrane oscillations and ectopic bursting of action potentials. These changes in membrane properties lasted for up to 35 days. Within the same time frame experi-mental animals showed hypersensitivity to touch on the skin covering the injected muscle. Similar saline injections also resulted in a significant increase of activity dependent c-Fos expression in NVmes neurons compared to controls. Immuno-fluorescence and lectin binding studies indicated that small-caliber muscle afferents containing known nociceptor markers (CGRP, SP, P2X3, TRPV1 and IB4) and expressing glutamate receptors are found close to the annulo-spiral endings of the NVmes afferents. Combined, our new observations support the hypothesis that excessive release of glutamate, within muscle spindles due to ectopically evoked antidromic action potentials, could lead to development of persistent musculoskeletal pain by activation and/ or sensitization of adjacent muscle afferent nociceptors.

Neurophysiology

Neurofysiologi

Aromatase inhibitors produce hypersensitivity in experimental models of pain : studies in vivo and in isolated sensory neurons

Robarge, Jason Dennis

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Aromatase inhibitors (AIs) are the current standard of care for the treatment of hormone receptor positive breast cancer in postmenopausal women. Nearly one-half of patients receiving AI therapy develop musculoskeletal toxicity that is characterized by joint and/or muscle pain and approximately one-fourth of patients discontinue their therapy as a result of musculoskeletal pain. Since there are no effective strategies for prevention or treatment, insight into the mechanisms of AI-induced pain is critical to improve treatment. However, there are few studies of AI effects in animal models of nociception. To determine whether AIs produce hypersensitivity in animal models of pain, I examined the effects of AI administration on mechanical, thermal, and chemical sensitivity in rats. The results demonstrate that (1) repeated injection of 5 mg/kg letrozole in male rats produces mechanical, but not thermal, hypersensitivity that extinguishes when drug dosing is stopped; (2) administering a single dose of 1 or 5 mg/kg letrozole in ovariectomized (OVX) rats also induces mechanical hypersensitivity, without altering thermal sensitivity and (3) a single dose of 5 mg/kg letrozole or daily dosing of letrozole or exemestane in male rats augments flinching behavior induced by intraplantar ATP injection. To determine whether the effects of AIs on nociceptive behaviors are mediated by activation or sensitization of peptidergic sensory neurons, I determined whether letrozole exposure alters release of calcitonin gene-related peptide (CGRP) from isolated rat sensory neurons and from sensory nerve endings in rat spinal cord slices. No changes in basal, capsaicin-evoked or high extracellular potassium-evoked CGRP release were observed in sensory neuronal cultures acutely or chronically exposed to letrozole. Furthermore, letrozole exposure did not alter the ability of ATP to augment CGRP release from sensory neurons in culture. Finally, chronic letrozole treatment did not augment neuropeptide release from spinal cord slices. Taken together, these results do not support altered release of this neuropeptide into the spinal cord as mediator of letrozole-induced mechanical hypersensitivity and suggest the involvement of other mechanisms. Results from this dissertation provide a new experimental model for AI-induced hypersensitivity that could be beneficial in delineating mechanisms mediating pain during AI therapy.

aromatase

aromatase inhibitor

musculoskeletal pain

neuropeptide

nociception

sensory neuron

behavior

Aromatase -- Therapeutic use -- Research

Aromatase -- Inhibitors -- Side effects

Breast -- Cancer -- Chemotherapy

Breast -- Cancer -- Hormone therapy

Drugs -- Side effects

Nociceptors -- Behavior

Myalgia

Neuropeptides -- Research

Nociceptors -- Physiology

Modulation of Voltage-Gated N-Type Calcium Channels by G Protein-Coupled Receptors Involves Lipids and Proteins: A Dissertation

Mitra Ganguli, Tora

15 October 2008

Pain signaling involves transmission of nociceptive stimuli in the spinal cord where a critical balance between excitatory and inhibitory inputs determines the response to noxious stimuli. The neuropeptide, substance P (SP), mediates transmission of pain in part by binding to the tachykinin receptor (NK-1R) in the dorsal horn (DH) of the spinal cord. One of SP’s downstream effects is to modulate N-type Ca2+(N-) channels. While phospholipid breakdown is a part of the inflammatory process that accompanies tissue damage, the role of this metabolic pathway has not been completely described with respect to N-channel modulation during pain signaling. Despite the incomplete understanding of this modulation, pharmacological antagonists of both NK-1R and N-channels have been used to treat pain. In Chapter II, using whole-cell patch clamp recording techniques, the SP signaling cascade that mediates inhibition of recombinant N-channel activity was characterized. By adopting a pharmacological approach, I show that this pathway resembles the slow pathway that was earlier described for modulation of N-current by the M1 muscarinic receptor (M1R). M1R couples to Gq to stimulate phospholipid breakdown. Together with previous observations, the data presented in this chapter provide evidence for involvement of the extracellular receptor kinase (ERK1/2), phospholipase A2 and release of phospholipid metabolites in the modulation of N-current by SP. Overall, this chapter shows that phospholipid metabolism involved in modulation of N-currents is not specific to M1Rs but that other Gq-coupled receptors may also modulate N-currents via the same signal transduction pathway. In Chapter III, enhancement of N-current by SP was studied as part of a collaborative project to understand current enhancement that occurs when a palmitoylated accessory CaVβ2a subunit is co-expressed with the pore-forming subunit CaV2.2 and the accessory subunit α2δ-1. When CaVβ3 is present, SP inhibits N-current as described in Chapter II. However, when palmitoylated CaVβ2a is co-expressed with CaV2.2 (and α2δ-1), current enhancement is observed at negative test potentials, demonstrating that both M1Rs and NK-1Rs exhibit the same profile of N-current modulation. This change in modulation by muscarinic agonists is not observed in the presence of a depalmitoylated CaVβ2a. However a chimeric CaVβ2aβ1b subunit that contains the palmitoylated N-terminus from CaVβ2a confers enhancement. Normally expression of the β1b subunit resulted in current inhibition. These findings indicated that the palmitoylated CaVβ2a participates in enhancement of current. Our data support a model where inhibition dominates over enhancement; when inhibition is blocked, enhancement may be observed. Lastly, we show that N-current inhibition by SP is minimized when exogenous palmitic acid is applied to cells co-expressing CaVβ3 subunits with N-channels. These results indicate that the presence of palmitic acid can prevent N-current inhibition when SP is applied most likely by interacting with CaV2.2. We propose a model where palmitic acid occupies the inhibitory site and serves to antagonize inhibition by a lipid metabolite, which is most likely arachidonic acid. The CaVβ2a protein seems to have a role in positioning the palmitoyl groups near CaV2.2. This chapter provides a new role for protein palmitoylation where the palmitoyl groups of CaVβ2a are both necessary and sufficient to block inhibition of another protein: CaV2.2. In Chapter IV, I probe the role of the relative orientation of CaVβ2a and the pore-forming subunit of the N-channel in N-current modulation. Evidence is presented that shows that not just the presence of a palmitoylated CaVβ2a is necessary, but the relative orientation of CaVβ2a to CaV2.2 is critical for blocking inhibition. Using N-channel mutants that cause a change in the orientation of CaVβ2a relative to CaV2.2, I show that the block of inhibition is disrupted; inhibition by the slow pathway is rescued. These findings further support my model that the palmitoyl groups of CaVβ2a normally reside in a specific location that overlaps with the slow pathway inhibitory site on CaV2.2. Lastly I present data showing that the enhancement of N-current, observed when palmitoylated CaVβ2a is present, occurs via the slow pathway. In Chapter V the effect of CaVβ’s orientation on N-channel modulation by the dopamine D2 receptor is tested. In this form of modulation, inhibition is rapid and voltage-dependent. The signaling pathway is membrane-delimited since Gβγ, released after receptor stimulation, directly interacts with the N-channel at a site that overlaps with a high affinity binding site for CaVβs. While N-currents are modulated by this pathway, the deletion mutants show aberrant membrane-delimited modulation. The findings in this chapter further underscore the importance of proper positioning of CaVβ to CaV2.2 for eliciting proper N-current modulation after GPCR stimulation. Overall, the data presented in this dissertation provides a mechanistic approach into examining modulation of N-current by different GPCRs via two different signaling pathways as well as the role CaVβ subunits serve in each modulatory pathway.

Pain

Calcium Channels

N-Type

Nociceptors

Signal Tranduction

Substance P

Amino Acids, Peptides, and Proteins

Biological Factors

Life Sciences

Medicine and Health Sciences

Psychological Phenomena and Processes

Efeito da toxina botulínica tipo A sobre a expressão de neuropeptídeos e o transporte mucociliar nasal em coelhos / Effect of botulinum toxin type A on nasal neuropeptides and mucociliary clearance in rabbits

Carreirão Neto, Waldir

26 August 2015

INTRODUÇÃO: A toxina botulínica tipo A (TXB-A) tem sido testada no tratamento da rinite, principalmente nos casos de rinite idiopática. Sugere-se que um estado de hiper-reatividade do nervo trigêmeo esteja envolvido na fisiopatologia da rinite idiopática. O nervo trigêmeo possui fibras sensitivas não mielinizadas tipo C (FSNMT-C) que contém os neuropeptídeos substância P (SP) e peptídeo relacionado ao gene da calcitonina (CGRP). O óxido nítrico (NO) produzido pelas enzimas óxido nítrico sintase (NOS) também está envolvido nesse processo de neurorregulação nasal. O transporte mucociliar, mecanismo primário de defesa do sistema respiratório, é formado pelo batimento ciliar e muco nasal, e esses componentes podem ser influenciados por diferentes neuropeptídeos e neurotransmissores presentes na mucosa nasal. OBJETIVO: O objetivo deste estudo foi avaliar o efeito da TXB-A sobre a expressão da SP, CGRP e óxido nítrico sintase neural (nNOS), além de sua influência sobre o transporte mucociliar nasal em coelhos. MÉTODOS: Coelhos machos saudáveis da linhagem Nova Zelândia foram divididos em dois grupos: o grupo tratamento recebeu TXB-A (25UI) na concha nasomaxilar (CNM) do lado direito e soro fisiológico a 0,9% (SF0,9%) na CNM esquerda. O grupo controle recebeu SF0,9% na CNM direita e nenhuma intervenção na CNM esquerda. Foram investigados os efeitos da TXB-A sobre a expressão da SP, CGRP e nNOS no tecido de CNM por meio da imuno-histoquímica. Para esta análise, dividiu-se o tecido em camada externa (CE, acima da membrana basal) e camada interna (CI, abaixo da membrana basal). Avaliou-se também a presença de apoptose celular, a frequência de batimento ciliar (FBC), o perfil histoquímico do muco nasal (glicoproteínas ácidas e neutras) e a espessura do epitélio (ESP-CE). RESULTADOS: Foi observado um aumento significativo na quantidade de células apoptóticas na CNM do grupo tratamento que recebeu TXB-A em comparação aos controles (p <= 0,001). A CNM do grupo tratamento que recebeu SF0,9% exibiu um aumento na quantidade de células apoptóticas na CI ao comparar com os controles (CNM SF0,9%, p=0,035) (CNM sem intervenção, p=0,022), e também um aumento da expressão de SP na CE em comparação aos controles (CNM SF0,9%, p=0,021) (CNM sem intervenção, p=0,040). A expressão de CGRP apresentou um aumento na CNM do grupo tratamento que recebeu TXB-A em comparação à CNM sem intervenção (p=0,008). A FBC, expressão de nNOS, perfil histoquímico do muco nasal e ESP-CE não apresentaram diferenças significativas. DISCUSSÃO: O aumento da expressão de CGRP e SP pode ter sido causado por inibição de sua exocitose vesicular pela TXB-A, levando ao seu acúmulo intracelular. Não foram observadas diferenças significativas na FBC ou perfil histoquímico do muco nasal, indicando que o aumento da expressão de CGRP e SP não foi associado à inflamação. O aumento da quantidade de células apoptóticas e da expressão de SP na CNM SF0,9% do grupo tratamento pode ter sido causado por um efeito central da TXB-A. CONCLUSÃO: A administração nasal de TXB-A aumentou a expressão de CGRP e SP, possivelmente por acúmulo intracelular por causa da inibição da sua exocitose, mas sem alterar a FBC e o perfil histoquímico do muco nasal / INTRODUCTION: Botulinum toxin type A (BoNT-A) has been assessed in the treatment of rhinitis, especially in cases of idiopathic rhinitis. Trigeminal hyper-responsiveness appears to be involved in the pathological process of idiopathic rhinitis. Trigeminal nociceptive type C unmyelinated sensory fibers contain the neuropeptides calcitonin gene-related peptide (CGRP) and substance P (SP). Nitric oxide (NO) produced by the enzyme nitric oxide synthase (NOS) are also involved in this nasal neurorregulation process. The mucociliary clearance, primary defense system of the respiratory system, is composed by the ciliary beat and nasal mucus. These components can be influenced by different nasal neuropeptides and neurotransmitters. OBJECTIVE: The aim of this study was to evaluate the effect of BoNT-A on the expression of SP, CGRP and neural nitric oxide synthase (nNOS), and its influence on nasal mucociliary clearance in rabbits. METHODS: Healthy New Zealand male rabbits were divided into two groups: the treatment group was challenged with BoNT-A (25UI) in the right nasomaxillary turbinate (NMT) and saline (SF0.9%) in the left NMT. The control group received SF0.9% in the right NMT and no-intervention in the left NMT. We investigated the effects of BoNT-A on SP, CGRP and nNOS expression in the NMT tissue by immunohistochemistry. Each area of interest was subdivided into an internal layer (IL: below the basement membrane) and outer layer (OL: above the basement membrane) for analysis. It was also assessed signs of cellular apoptosis, ciliary beat frequency (CBF), mucus histochemical profile (acidic and neutral glycoproteins) and epithelial thickness (EP-TH). RESULTS: It was observed a significant increase in the amount of apoptotic cells in the BoNT-A-challanged NMT compared with controls (p <= 0.001). The NMT of treatment group which received only SF0.9% showed an increase in the amount of apoptotic cells in the IL compared with controls (NMT SF0.9%, p = 0.035) (NMT no-intervention, p = 0.022), and also an increase in the SP expression in the OL compared with controls (NMT SF0.9%, p = 0.021) (NMT no-intervention, p = 0.040). CGRP expression showed higher expression in the BoNT-A-challanged NMT compared with no-intervention NMT (p=0.008). The CBF, nNOS expression, mucus histochemical profile and EP-TH did not show significant differences. DISCUSSION: The increased CGRP and SP expression could be due to inhibition of vesicular exocytosis by BoNT-A, leading to CGRP and SP intracellular accumulation. No significant differences in CBF or mucus histochemical profile were observed, indicating that the increased CGRP and SP expression was not associated with inflammation. The increase in the amount of apoptotic cells and SP expression in the SF0.9% NMT of treatment group may be due to a central effect of BoNT-A. CONCLUSION: Nasal administration of BoNT-A increased SP and CGRP expression, possibly via inhibition of their release, but did not change the CBF or mucus profile

Botulinum toxins type A

Calcitonin gene-related peptide

Coelhos

Depuração mucociliar

Fibras nervosas amielínicas

Hipersensibilidade respiratória

Inflamação neurogênica

Muco

Mucociliary clearance

Mucosa nasal

Mucus

Nasal mucosa

Nerve fibers unmyelinated

Neurogenic inflammation

Nociceptores

Nociceptors

Rabbits

Respiratory hypersensitivity

Rhinitis

Rinite

Substance P

Substância P

Toxinas botulínicas tipo A

Efeito da toxina botulínica tipo A sobre a expressão de neuropeptídeos e o transporte mucociliar nasal em coelhos / Effect of botulinum toxin type A on nasal neuropeptides and mucociliary clearance in rabbits

Waldir Carreirão Neto

26 August 2015

INTRODUÇÃO: A toxina botulínica tipo A (TXB-A) tem sido testada no tratamento da rinite, principalmente nos casos de rinite idiopática. Sugere-se que um estado de hiper-reatividade do nervo trigêmeo esteja envolvido na fisiopatologia da rinite idiopática. O nervo trigêmeo possui fibras sensitivas não mielinizadas tipo C (FSNMT-C) que contém os neuropeptídeos substância P (SP) e peptídeo relacionado ao gene da calcitonina (CGRP). O óxido nítrico (NO) produzido pelas enzimas óxido nítrico sintase (NOS) também está envolvido nesse processo de neurorregulação nasal. O transporte mucociliar, mecanismo primário de defesa do sistema respiratório, é formado pelo batimento ciliar e muco nasal, e esses componentes podem ser influenciados por diferentes neuropeptídeos e neurotransmissores presentes na mucosa nasal. OBJETIVO: O objetivo deste estudo foi avaliar o efeito da TXB-A sobre a expressão da SP, CGRP e óxido nítrico sintase neural (nNOS), além de sua influência sobre o transporte mucociliar nasal em coelhos. MÉTODOS: Coelhos machos saudáveis da linhagem Nova Zelândia foram divididos em dois grupos: o grupo tratamento recebeu TXB-A (25UI) na concha nasomaxilar (CNM) do lado direito e soro fisiológico a 0,9% (SF0,9%) na CNM esquerda. O grupo controle recebeu SF0,9% na CNM direita e nenhuma intervenção na CNM esquerda. Foram investigados os efeitos da TXB-A sobre a expressão da SP, CGRP e nNOS no tecido de CNM por meio da imuno-histoquímica. Para esta análise, dividiu-se o tecido em camada externa (CE, acima da membrana basal) e camada interna (CI, abaixo da membrana basal). Avaliou-se também a presença de apoptose celular, a frequência de batimento ciliar (FBC), o perfil histoquímico do muco nasal (glicoproteínas ácidas e neutras) e a espessura do epitélio (ESP-CE). RESULTADOS: Foi observado um aumento significativo na quantidade de células apoptóticas na CNM do grupo tratamento que recebeu TXB-A em comparação aos controles (p <= 0,001). A CNM do grupo tratamento que recebeu SF0,9% exibiu um aumento na quantidade de células apoptóticas na CI ao comparar com os controles (CNM SF0,9%, p=0,035) (CNM sem intervenção, p=0,022), e também um aumento da expressão de SP na CE em comparação aos controles (CNM SF0,9%, p=0,021) (CNM sem intervenção, p=0,040). A expressão de CGRP apresentou um aumento na CNM do grupo tratamento que recebeu TXB-A em comparação à CNM sem intervenção (p=0,008). A FBC, expressão de nNOS, perfil histoquímico do muco nasal e ESP-CE não apresentaram diferenças significativas. DISCUSSÃO: O aumento da expressão de CGRP e SP pode ter sido causado por inibição de sua exocitose vesicular pela TXB-A, levando ao seu acúmulo intracelular. Não foram observadas diferenças significativas na FBC ou perfil histoquímico do muco nasal, indicando que o aumento da expressão de CGRP e SP não foi associado à inflamação. O aumento da quantidade de células apoptóticas e da expressão de SP na CNM SF0,9% do grupo tratamento pode ter sido causado por um efeito central da TXB-A. CONCLUSÃO: A administração nasal de TXB-A aumentou a expressão de CGRP e SP, possivelmente por acúmulo intracelular por causa da inibição da sua exocitose, mas sem alterar a FBC e o perfil histoquímico do muco nasal / INTRODUCTION: Botulinum toxin type A (BoNT-A) has been assessed in the treatment of rhinitis, especially in cases of idiopathic rhinitis. Trigeminal hyper-responsiveness appears to be involved in the pathological process of idiopathic rhinitis. Trigeminal nociceptive type C unmyelinated sensory fibers contain the neuropeptides calcitonin gene-related peptide (CGRP) and substance P (SP). Nitric oxide (NO) produced by the enzyme nitric oxide synthase (NOS) are also involved in this nasal neurorregulation process. The mucociliary clearance, primary defense system of the respiratory system, is composed by the ciliary beat and nasal mucus. These components can be influenced by different nasal neuropeptides and neurotransmitters. OBJECTIVE: The aim of this study was to evaluate the effect of BoNT-A on the expression of SP, CGRP and neural nitric oxide synthase (nNOS), and its influence on nasal mucociliary clearance in rabbits. METHODS: Healthy New Zealand male rabbits were divided into two groups: the treatment group was challenged with BoNT-A (25UI) in the right nasomaxillary turbinate (NMT) and saline (SF0.9%) in the left NMT. The control group received SF0.9% in the right NMT and no-intervention in the left NMT. We investigated the effects of BoNT-A on SP, CGRP and nNOS expression in the NMT tissue by immunohistochemistry. Each area of interest was subdivided into an internal layer (IL: below the basement membrane) and outer layer (OL: above the basement membrane) for analysis. It was also assessed signs of cellular apoptosis, ciliary beat frequency (CBF), mucus histochemical profile (acidic and neutral glycoproteins) and epithelial thickness (EP-TH). RESULTS: It was observed a significant increase in the amount of apoptotic cells in the BoNT-A-challanged NMT compared with controls (p <= 0.001). The NMT of treatment group which received only SF0.9% showed an increase in the amount of apoptotic cells in the IL compared with controls (NMT SF0.9%, p = 0.035) (NMT no-intervention, p = 0.022), and also an increase in the SP expression in the OL compared with controls (NMT SF0.9%, p = 0.021) (NMT no-intervention, p = 0.040). CGRP expression showed higher expression in the BoNT-A-challanged NMT compared with no-intervention NMT (p=0.008). The CBF, nNOS expression, mucus histochemical profile and EP-TH did not show significant differences. DISCUSSION: The increased CGRP and SP expression could be due to inhibition of vesicular exocytosis by BoNT-A, leading to CGRP and SP intracellular accumulation. No significant differences in CBF or mucus histochemical profile were observed, indicating that the increased CGRP and SP expression was not associated with inflammation. The increase in the amount of apoptotic cells and SP expression in the SF0.9% NMT of treatment group may be due to a central effect of BoNT-A. CONCLUSION: Nasal administration of BoNT-A increased SP and CGRP expression, possibly via inhibition of their release, but did not change the CBF or mucus profile

Coelhos

Depuração mucociliar

Fibras nervosas amielínicas

Hipersensibilidade respiratória

Inflamação neurogênica

Muco

Mucosa nasal

Nociceptores

Rinite

Substância P

Toxinas botulínicas tipo A

Botulinum toxins type A

Calcitonin gene-related peptide

Mucociliary clearance

Mucus

Nasal mucosa

Nerve fibers unmyelinated

Neurogenic inflammation

Nociceptors

Rabbits

Respiratory hypersensitivity

Rhinitis

Substance P