Ativação supraespinal da via das quinureninas contribui para a manutenção da dor neuropática / Supraspinal kynurenine pathway contributes to the maintenance of neuropathic pain

Reis, Dênis Augusto Santana

03 February 2015

Introdução: Um fator que pode contribuir para o desenvolvimento da dor neuropática é a modulação negativa da via descendente da dor pelo aumento da degradação do triptofano pela ativação da enzima indoleamina 2,3-dioxigenase 1 (IDO1) ou a ativação da via descendente facilitatória da dor por um agonista glutamatérgicos produzido pela enzima quinurenina 3 monoxigenase (KMO). Objetivo: Foi avaliar a participação das enzimas IDO1 e a KMO presente na substância cinzenta periaquedutal (PAG) e no bulbo rostral ventromedial (RVM) no desenvolvimento da dor neuropática em camundongos induzida pelo modelo SNI. Metodologia: A indução da neuropatia experimental foi realizada de acordo com (Bourquin et al., 2006). A expressão da IDO1 e KMO foi realizada pela técnica de Western blotting. A administração de drogas foi realizada por via oral, intraperitoneal, intratecal e intracerebroventricular (i.c.v.). Resultados: Foi observado o aumento da expressão da enzima IDO1 no RVM (7 dias) e PAG (3, 7, 14 e 21 dias) após SNI. A microinjeção de Norharmane no espaço i.c.v. reduziu a hipersensibilidade mecânica no 7, 14 e 21 dias após SNI. Corroborando com esses achados, animais deficientes para a enzima IDO1 submetidos a SNI não desenvolvem a hipersensibilidade mecânica. Além disso, a expressão da enzima KMO aumenta significativamente no 7 e 14 dias no RVM e 7 dias na PAG após SNI. Por conseguinte, a administração oral de JM6, pró-droga de liberação lenta do Ro61-8048, ou Ro61-8048 (inibidor da KMO) no espaço i.c.v. reduziu significativamente a hipersensibilidade mecânica nos dias 7, 14 ou 21 após SNI. Sabendo que a expressão da enzima IDO1 é modulada pela citocina IFN-, verificamos que os animais deficientes para a citocina IFN- apresentam hipersensibilidade mecânica reduzida. Ainda, os animais IFN- KO possuem expressão reduzida da IDO1 no RVM 7 dias e na PAG 14 dias após a SNI. Em adição, a microinjeção de doses crescentes de IFN- no espaço i.c.v. induz uma hipernocicepção mecânica em camundongos naives. Constatamos também que animais CD4+ KO, mas não os animais CD8+ KO apresentam reduzida expressão da enzima IDO1 no RVM e na PAG e consequentemente menor hipersensibilidade mecânica após SNI. A microinjeção dos metabolitos da via das quinureninas, no espaço i.c.v. de camundongos causou hipersensibilidade mecânica, sendo o QUIN o mais potente. Sugerimos que a ativação da via das quinureninas seja dependente da ativação do receptor NMDA, visto que o pré-tratamento local com o MK801 (antagonista seletivos dos receptores NMDA) reverte os efeitos nociceptivos induzidos pelos metabólitos. Além disso, o efeito nociceptivo induzido por QUIN depende ativação da via descendente facilitatória. Constatamos que os animais neuropáticos exibem um comportamento do tipo depressivo e esse comportamento não é observado em animais IFN- KO e CD4KO. Por último, avaliamos a participação da via das quinureninas no desenvolvimento do comportamento depressivo associado à SNI e constatamos que esse comportamento depende da ativação das enzimas IDO1 e KMO. Conclusão: Os resultados sugerem que as enzimas IDO1 e KMO, localizadas em regiões supraespinais desempenham um importante papel no desenvolvimento da dor neuropática, assim como da comorbidade depressão. Além disso, a expressão da IDO1 é dependente da sinalização via citocina IFN- e células CD4+. O mecanismo responsável pelo desenvolvimento da hipersensibilidade neuropática deve-se tanto a redução dos níveis de triptofano/5-HT, diminuição da eficiência da via descendente inibitória, quanto ao aumento dos níveis de QUIN, que ativa a via descendente facilitatória da dor. / Introduction: One factor that may contribute to the development of neuropathic pain is the negative modulation of the descending pain pathway by increased degradation of the activation of tryptophan by enzyme indoleamine 2,3-dioxygenase1 (IDO1) or activation of the descending facilitatory pain pathway for a glutamate agonist produced by the enzyme kynurenine 3 monooxygenase (KMO). Aim: We evaluate the role of IDO1 and KMO in the periaqueductal gray (PAG) and the rostral ventromedial medulla (RVM) in the development of neuropathic pain in mice induced by SNI model. Methods: Induction of experimental neuropathy was performed according to (Bourquin et al. 2006). The expression of IDO1 and KMO was carried out by Western blotting technique. The drug administration was performed orally, intraperitoneally and intracerebroventricularly (i.c.v) Results. We observed increased IDO1 expression in the RVM (7 days) and PAG (3, 7, 14 and 21 days) after SNI. The microinjection Norharmane in i.c.v. space reduced mechanical hypersensitivity in the 7, 14 and 21 days after SNI. Corroborating these findings, mice deficient for the enzyme IDO1 undergoing SNI did not develop mechanical hypersensitivity. Furthermore, the KMO expression was significantly increased in the 7 and 14 days in the RVM and 7 days in PAG after SNI. Therefore, oral administration of JM6, prodrug slow release from Ro61-8048 or Ro61-8048 (KMO inhibitors) within i.c.v. significantly reduced the mechanical hypersensitivity at day 7, 14 or 21 after SNI. Knowing that the expression of IDO1 enzyme is modulated by IFN- cytokine, it was found that animals deficient for IFN- cytokine have reduced mechanical hypersensitivity. Moreover, IFN- ko animals have reduced expression of IDO1 RVM 7 days and 14 days after SNI in the PAG. In addition, microinjection of increasing doses of IFN- in i.c.v. induced mechanical hyperalgesia. We also found that CD4 + KO animals, but not CD8 + KO animals showed reduced expression of the enzyme IDO1 RVM and PAG and consequently lower mechanical hypersensitivity after SNI. The microinjection of the main metabolites of kynurenine pathway into the i.c.v. spaces induced mechanical hypersensitivity, QUIN being the most potent. We suggest that the activation of the kynurenine pathway was dependent of NMDA receptor activation, whereas the spot pre-treatment with MK801 (selective NMDA receptor antagonist) reverses the effects induced by noxious metabolites. After that, the microinjection into i.c.v. spaces of MK801 reduced mechanical hypersensitivity after SNI. Furthermore, nociceptive effect induced by QUIN depends activation of the descending facilitatory. We found that the neuropathic animals exhibit depressive-like behavior and this behavior is not observed in IFN- KO and CD4KO mice. Finally, we evaluate the participation of kynurenine pathway in the development of depressive-like behavior associated with SNI and found that this behavior depends on the activation of IDO1 and KMO Conclusion: These results suggest that IDO1 and KMO enzyme, located in supraspinal regions play a role in the development of neuropathic pain as well as comorbidity depression. Furthermore, the expression of IDO1 are dependent on signaling via cytokine IFN- and CD4+ cells. The mechanism responsible for the development of neuropathic hypersensitivity is due to both reduced levels of tryptophan/5-HT decrease the descending inhibitory pain pathway efficiency, as the increased levels of QUIN, which activates the descending facilitatory pain pathway.

Dor neuropática

IDO1

IDO1

KMO

KMO

Kynurenine pathway

Neuropathic pain

Via das quinureninas

Ativação supraespinal da via das quinureninas contribui para a manutenção da dor neuropática / Supraspinal kynurenine pathway contributes to the maintenance of neuropathic pain

Dênis Augusto Santana Reis

03 February 2015

Introdução: Um fator que pode contribuir para o desenvolvimento da dor neuropática é a modulação negativa da via descendente da dor pelo aumento da degradação do triptofano pela ativação da enzima indoleamina 2,3-dioxigenase 1 (IDO1) ou a ativação da via descendente facilitatória da dor por um agonista glutamatérgicos produzido pela enzima quinurenina 3 monoxigenase (KMO). Objetivo: Foi avaliar a participação das enzimas IDO1 e a KMO presente na substância cinzenta periaquedutal (PAG) e no bulbo rostral ventromedial (RVM) no desenvolvimento da dor neuropática em camundongos induzida pelo modelo SNI. Metodologia: A indução da neuropatia experimental foi realizada de acordo com (Bourquin et al., 2006). A expressão da IDO1 e KMO foi realizada pela técnica de Western blotting. A administração de drogas foi realizada por via oral, intraperitoneal, intratecal e intracerebroventricular (i.c.v.). Resultados: Foi observado o aumento da expressão da enzima IDO1 no RVM (7 dias) e PAG (3, 7, 14 e 21 dias) após SNI. A microinjeção de Norharmane no espaço i.c.v. reduziu a hipersensibilidade mecânica no 7, 14 e 21 dias após SNI. Corroborando com esses achados, animais deficientes para a enzima IDO1 submetidos a SNI não desenvolvem a hipersensibilidade mecânica. Além disso, a expressão da enzima KMO aumenta significativamente no 7 e 14 dias no RVM e 7 dias na PAG após SNI. Por conseguinte, a administração oral de JM6, pró-droga de liberação lenta do Ro61-8048, ou Ro61-8048 (inibidor da KMO) no espaço i.c.v. reduziu significativamente a hipersensibilidade mecânica nos dias 7, 14 ou 21 após SNI. Sabendo que a expressão da enzima IDO1 é modulada pela citocina IFN-, verificamos que os animais deficientes para a citocina IFN- apresentam hipersensibilidade mecânica reduzida. Ainda, os animais IFN- KO possuem expressão reduzida da IDO1 no RVM 7 dias e na PAG 14 dias após a SNI. Em adição, a microinjeção de doses crescentes de IFN- no espaço i.c.v. induz uma hipernocicepção mecânica em camundongos naives. Constatamos também que animais CD4+ KO, mas não os animais CD8+ KO apresentam reduzida expressão da enzima IDO1 no RVM e na PAG e consequentemente menor hipersensibilidade mecânica após SNI. A microinjeção dos metabolitos da via das quinureninas, no espaço i.c.v. de camundongos causou hipersensibilidade mecânica, sendo o QUIN o mais potente. Sugerimos que a ativação da via das quinureninas seja dependente da ativação do receptor NMDA, visto que o pré-tratamento local com o MK801 (antagonista seletivos dos receptores NMDA) reverte os efeitos nociceptivos induzidos pelos metabólitos. Além disso, o efeito nociceptivo induzido por QUIN depende ativação da via descendente facilitatória. Constatamos que os animais neuropáticos exibem um comportamento do tipo depressivo e esse comportamento não é observado em animais IFN- KO e CD4KO. Por último, avaliamos a participação da via das quinureninas no desenvolvimento do comportamento depressivo associado à SNI e constatamos que esse comportamento depende da ativação das enzimas IDO1 e KMO. Conclusão: Os resultados sugerem que as enzimas IDO1 e KMO, localizadas em regiões supraespinais desempenham um importante papel no desenvolvimento da dor neuropática, assim como da comorbidade depressão. Além disso, a expressão da IDO1 é dependente da sinalização via citocina IFN- e células CD4+. O mecanismo responsável pelo desenvolvimento da hipersensibilidade neuropática deve-se tanto a redução dos níveis de triptofano/5-HT, diminuição da eficiência da via descendente inibitória, quanto ao aumento dos níveis de QUIN, que ativa a via descendente facilitatória da dor. / Introduction: One factor that may contribute to the development of neuropathic pain is the negative modulation of the descending pain pathway by increased degradation of the activation of tryptophan by enzyme indoleamine 2,3-dioxygenase1 (IDO1) or activation of the descending facilitatory pain pathway for a glutamate agonist produced by the enzyme kynurenine 3 monooxygenase (KMO). Aim: We evaluate the role of IDO1 and KMO in the periaqueductal gray (PAG) and the rostral ventromedial medulla (RVM) in the development of neuropathic pain in mice induced by SNI model. Methods: Induction of experimental neuropathy was performed according to (Bourquin et al. 2006). The expression of IDO1 and KMO was carried out by Western blotting technique. The drug administration was performed orally, intraperitoneally and intracerebroventricularly (i.c.v) Results. We observed increased IDO1 expression in the RVM (7 days) and PAG (3, 7, 14 and 21 days) after SNI. The microinjection Norharmane in i.c.v. space reduced mechanical hypersensitivity in the 7, 14 and 21 days after SNI. Corroborating these findings, mice deficient for the enzyme IDO1 undergoing SNI did not develop mechanical hypersensitivity. Furthermore, the KMO expression was significantly increased in the 7 and 14 days in the RVM and 7 days in PAG after SNI. Therefore, oral administration of JM6, prodrug slow release from Ro61-8048 or Ro61-8048 (KMO inhibitors) within i.c.v. significantly reduced the mechanical hypersensitivity at day 7, 14 or 21 after SNI. Knowing that the expression of IDO1 enzyme is modulated by IFN- cytokine, it was found that animals deficient for IFN- cytokine have reduced mechanical hypersensitivity. Moreover, IFN- ko animals have reduced expression of IDO1 RVM 7 days and 14 days after SNI in the PAG. In addition, microinjection of increasing doses of IFN- in i.c.v. induced mechanical hyperalgesia. We also found that CD4 + KO animals, but not CD8 + KO animals showed reduced expression of the enzyme IDO1 RVM and PAG and consequently lower mechanical hypersensitivity after SNI. The microinjection of the main metabolites of kynurenine pathway into the i.c.v. spaces induced mechanical hypersensitivity, QUIN being the most potent. We suggest that the activation of the kynurenine pathway was dependent of NMDA receptor activation, whereas the spot pre-treatment with MK801 (selective NMDA receptor antagonist) reverses the effects induced by noxious metabolites. After that, the microinjection into i.c.v. spaces of MK801 reduced mechanical hypersensitivity after SNI. Furthermore, nociceptive effect induced by QUIN depends activation of the descending facilitatory. We found that the neuropathic animals exhibit depressive-like behavior and this behavior is not observed in IFN- KO and CD4KO mice. Finally, we evaluate the participation of kynurenine pathway in the development of depressive-like behavior associated with SNI and found that this behavior depends on the activation of IDO1 and KMO Conclusion: These results suggest that IDO1 and KMO enzyme, located in supraspinal regions play a role in the development of neuropathic pain as well as comorbidity depression. Furthermore, the expression of IDO1 are dependent on signaling via cytokine IFN- and CD4+ cells. The mechanism responsible for the development of neuropathic hypersensitivity is due to both reduced levels of tryptophan/5-HT decrease the descending inhibitory pain pathway efficiency, as the increased levels of QUIN, which activates the descending facilitatory pain pathway.

Dor neuropática

IDO1

KMO

Via das quinureninas

IDO1

KMO

Kynurenine pathway

Neuropathic pain

Mécanismes d'action des cellules stromales mésenchymateuses dans le traitement de la réaction du greffon contre l'hôte

Lemieux, William

12 1900

La maladie du greffon contre l’hôte (GvHD) est un effet secondaire sérieux de la transplantation de cellules souches hématopoïétiques (HSCT). Cette maladie entraine une haute mortalité et ses symptômes sont dévastateurs. Les traitements actuels de la GvHD comportent plusieurs produits, tels les corticostéroïdes, mais ces derniers sont immunosuppresseurs et leurs effets secondaires sont aussi très dommageables pour les patients et leur guérison. Les cellules stromales mésenchymateuses (MSC) représentent une alternative ou une addition potentielle de traitement pour la GvHD et ces cellules ne semblent pas posséder les effets secondaires des traitements classiques. Un nombre important d’études cliniques faisant l’objet des MSC ont été enregistrées. Malgré cet engouement, le mécanisme de leur immunomodulation reste encore à élucider. Notre objectif est donc de mieux définir ce mécanisme. Nous avons utilisé un modèle simplifié pour simuler la GvHD in vitro. Ce modèle se base sur la stimulation de lymphocytes CD4+ par des cellules dendritiques allogéniques. La mesure de la prolifération de ces cellules stimulées sert d’indicateur de leur réactivité. Selon les résultats obtenus par la technologie CRISPR de génie génétique, les MSC exerceraient leur immunosuppression sur les cellules T CD4+ principalement par la sécrétion de l’enzyme IDO1. Les MSC seraient également capables d’induire certaines cellules CD4+ en cellules régulatrices, un processus indépendant de la sécrétion d’IDO1. Toutefois, ces cellules ne semblent pas correspondre aux cellules Treg conventionnelles. / Graft versus host disease (GvHD) is a very serious side effect of hematopoietic stem cell transplantation (HSCT). This disease results in high mortality and devastating symptoms. Treatments for GvHD include a lot of pharmaceuticals, including corticosteroids, but these are immunosuppressive and their adverse effects cause a lot of damage to the patient and hinder the healing process. Mesenchymal stromal cells (MSC) represent a potential alternative or addition to the GvHD treatment regimen. These cells do not seem to carry the secondary effects associated with classical treatments. A number of studies have been registered concerning MSC. In spite of the spike of interest, the mechanism of immunomodulation deployed by MSC remains to be elucidated. Our objective is to better characterise this mechanism. We have used a simple in vitro model to simulate GvHD. This model is based on the stimulation of CD4+ T cells by allogenic dendritic cells. The measure of the proliferation of the stimulated lymphocytes serves as an indicator of the reactivity. According to the results obtained by CRISPR genetic engineering, MSC exert this immunomodulatory effect on T cells mainly by the secretion of IDO1 enzyme. These MSC are also able to induce T cells to become inhibitory, a process independent of the secretion of IDO1. However, these inhibitory T cells would not correspond to conventional Treg cells.

MSC

GvHD

Cellules T CD4+

HSCT

IDO1

CRISPR

CD4+ T cells

Respiratory Syncytial Virus-infected Mesenchymal Stem Cells Regulate Immunity via Interferon-beta and Indoleamine-2,3-dioxygenase

Cheung, Michael B.

30 June 2016

Respiratory syncytial virus (RSV) is the most common cause of acute lower respiratory tract infection in young children worldwide, accounting for an estimated 33.8 million cases of respiratory disease, over 3 million of which require hospitalization, and between 66,000 and 199,000 deaths in this susceptible population. Additionally, severe RSV infection early in life is associated with an increased risk of wheeze and other airway disorders later in life. Despite this, there is currently no vaccine or economically reasonable prophylactic regimen to prevent infection. While disease is typically more severe in infancy RSV can infect throughout the lifespan repeatedly as the body does not develop protective immunity during primary or subsequent infection. The mechanisms behind this incomplete immunity are unclear. RSV has been reported to infect numerous extra-epithelial cell types. Interestingly, viral infection in human mesenchymal stem cells (MSCs) has been reported, but the consequences are poorly understood. MSCs are an immune regulatory cell population present in nearly every organ including the nasal mucosa and the lung. They play a role in regulating immune responses and mediating tissue repair. In the following studies we sought to determine whether RSV infection of MSCs enhances their immune regulatory functions and contributes to RSV-associated lung disease. RSV was shown to replicate in human MSCs by fluorescence microscopy, plaque assay, and expression of RSV transcripts. RSV-infected MSCs showed differentially altered expression of cytokines and chemokines such as IL-1β, IL-6, IL-8 and SDF-1 compared to normal human bronchial epithelial cells. Notably, RSV-infected MSCs exhibited significantly increased expression of IFN-β (~100-fold) and indoleamine-2,3-dioxygenase (IDO) (~70-fold) compared with mock-infected MSCs. IDO was identified in cytosolic protein of infected cells by Western blots and enzymatic activity was detected by tryptophan catabolism assay. Treatment of PBMCs with culture supernatants from RSV-infected MSCs reduced their proliferation in a dose dependent manner. This effect on PBMC activation was reversed by treatment of MSCs with the IDO inhibitors 1-methyltryptophan and vitamin K3 during RSV infection. We also demonstrated the pathway leading to IDO expression in RSV infected MSCs. Neutralizing IFN-β prevented IDO expression and activity indicating its role as a viral response factor perhaps “high jacked” by the virus in immune escape. Treatment of MSCs with an endosomal TLR, but not a RIG-I, inhibitor prevented IFN-β and IDO expression. Additionally, TLR3/dsRNA complex inhibitor was able to block IFN-β stimulation, while a TLR7/8/9 inhibitory ODN did not, suggesting that endosomal TLR3 detection of RSV dsRNA was leading to IFN-β and IDO expression. Together, these findings indicate that RSV infection of MSCs triggers their immune regulatory function via TLR3 recognition of dsRNA, upregulating IFN-β expression and IDO activity, ultimately affecting immune cell proliferation. This finding may account for the lack of protective RSV immunity and consequent repeated infections throughout one's lifetime.

Respiratory infections

Stromal cells

Immune regulation

Viral response

IDO1

IFN- β

Cell Biology

Immunology and Infectious Disease

Virology

新規ケミカルスペースの開拓を指向した八員環縮環インドール及びスピロ環状ペプチドの合成研究

山口, 亞由太

23 March 2023

京都大学 / 新制・課程博士 / 博士(薬科学) / 甲第24556号 / 薬科博第173号 / 新制||薬科||19(附属図書館) / 京都大学大学院薬学研究科医薬創成情報科学専攻 / (主査)教授 大野 浩章, 教授 高須 清誠, 教授 大宮 寛久 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

金触媒連続環化反応

八員環縮環インドール

IDO1阻害剤

スピロ環状ペプチド

遠隔位C-H結合官能基化

499.3

Lymph node and peri-lymph node stroma : phenotype and interaction with T-cells

Stoffel, Nicholas J.

11 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / The non-hematopoietic, stationary stromal cells located inside and surrounding skin-draining lymph nodes play a key role in regulating immune responses. We studied distinct populations of lymph node stromal cells from both human subjects and animal models in order to describe their phenotype and function. In the mouse model, we studied two distinct populations: an endothelial cell population expressing Ly51 and MHC-II, and an epithelial cell population expressing the epithelial adhesion molecule EpCAM. Analysis of intra-nodal and extra-nodal lymph node (CD45-) stromal cells through flow cytometry and qPCR provides a general phenotypic profile of the distinct populations. My research focused on the EpCAM+ epithelial cell population located in the fat pad surrounding the skin draining lymph nodes. The EpCAM+ population has been characterized by surface marker phenotype, anatomic location, and gene expression profile. This population demonstrates the ability to inhibit the activation and proliferation of both CD4 and CD8 T cells. This population may play a role in suppressing overactive inflammation and auto-reactive T cells that escaped thymic deletion. The other major arm of my project consisted of identifying a novel endothelial cell population in human lymph nodes. Freshly resected lymph nodes were processed into single cell suspensions and selected for non-hematopoietic CD45- stromal cells. The unique endothelial population expressing CD34 HLA-DR was then characterized and analyzed for anatomic position, surface marker expression, and gene profiles. Overall, these studies emphasize the importance of stationary lymph node stromal cells to our functioning immune systems, and may have clinical relevance to autoimmune diseases, inflammation, and bone marrow transplantation.

Lymph Node Stroma

Lymph Node

EpCAM

Ly51

iNOS

IDO1

Mesenchymal stem cells -- Research

Lymph nodes

Inflammation

Immune response -- Regulation

Inflammation -- Animal models

Bone marrow -- Transplantation

Autoimmune diseases

Endothelial cells

Epithelium

Phenotype

Flow cytometry -- Diagnostic use

T cells

Gene targeting

Gene expression

Lymphocytes

Animal models in research