O potencial terapêutico de compostos canabinoides em um modelo in vitro de morte neuronal. / The therapeutic potential of cannabinoid compounds in an in vitro model of neuronal death.

Vrechi, Talita Aparecida de Moraes

08 April 2016

A neurodegeneração é o resultado da destruição progressiva e irreversível dos neurônios no sistema nervoso central, apresentando causas desconhecidas e mecanismos patológicos não totalmente elucidados. Fatores como a idade, o aumento da formação de radicais livres e/ou estresse oxidativo, defeito no metabolismo energético, a inflamação e acúmulo de elementos neurotóxicos e de proteínas malformadas no lúmen do retículo endoplasmático (RE) contribuem para o desenvolvimento dos processos neurodegenerativos. O sistema canabinoide tem sido proposto como neuroprotetor em diversos modelos de neurodegeneração como hipóxia aguda e epilepsia, isquemia cerebral, lesão cerebral e modelos de estresse oxidativo. Assim, este trabalho teve como objetivo investigar o papel do sistema canabinoide em uma linhagem de neuroblastoma (Neuro 2a) submetida a condições de estresse oxidativo (H2O2), inflamação (LPS) e estresse do RE (tunicamicina), avaliando parâmetros de viabilidade celular e vias de sinalização envolvidas. Nossos resultados mostram que o agonista canabinoide ACEA foi capaz de proteger as células da morte celular causada pela inflamação e pelo estresse de retículo endoplasmático, mas não pelo estresse oxidativo. Esse efeito neuroprotetor exercido pelo ACEA parece pelo menos em parte ocorrer via receptor CB1 no modelo de inflamação e ser independente deste receptor no modelo de estresse de RE. Os efeitos neuroprotetores observados envolveram a modulação dos níveis de proteínas pré-apoptóticas, CHOP e Caspase 12, e da proteína relacionada à sobrevivência celular ERK 1/2. Nossos dados sugerem um papel neuroprotetor do sistema canabinoide em mecanismos relacionados aos processos neurodegenerativos e propõem a manipulação desse sistema como possível alvo terapêutico. / Neurodegeneration is the result of progressive and irreversible destruction of neurons in the central nervous system, with unknown causes and pathological mechanisms not fully elucidated. Factors such as age, increased formation of free radicals and/or oxidative stress, defects in energetic metabolism, inflammation and accumulation of neurotoxic factors and misfolded proteins in the lumen of the endoplasmic reticulum (ER) contribute to the development of neurodegenerative processes. The cannabinoid system has been proposed as neuroprotector in several models of neurodegeneration such as acute hypoxia and epilepsy, cerebral ischaemia, brain injury and oxidative stress models. This work aimed to investigate the role of the cannabinoid system in a neuroblastoma line (Neuro 2a) submitted to oxidative stress (H2O2), inflammation (LPS) and ER stress (tunicamycin) conditions, assessing cell viability parameters and signaling pathways involved. Our results show that the ACEA cannabinoid agonist was able to protect cells from cell death caused by inflammation and ER stress, but not from oxidative stress. This neuroprotective effect exerted by ACEA appears to occur at least in part via the CB1 receptor in inflammation model and it seems to be independent of this receptor in the ER stress model. The neuroprotective effects observed involved the modulation of the levels of pre-apoptotic proteins CHOP and Caspase 12 and the cell survival related protein ERK 1/2. Our data suggest a neuroprotective role of the cannabinoid system in mechanisms related to neurodegenerative processes and propose it as possible therapeutic target.

Canabinoide

Cannabinoid

CB1 receptor

Endoplasmic reticulum stress

Estresse de retículo endoplasmático

Neuroinflamação

Neuroinflammation

Neuroproteção

Neuroprotection

Receptor CB1

A reduction in the RNA binding protein TIA1 protects against neurodegeneration, rescues behavioral deficits and prolongs survival

Randhawa, Anantbir

24 July 2018

RNA binding proteins (RBPs) have been found to be frequently involved in neurodegenerative diseases (Ash 2014). Mutations in RBPs cause amyotrophic lateral sclerosis (ALS), spinocerebellar ataxia, frontotemporal dementia (FTD) and myopathies (Ash 2014), and recent studies suggest that aggregation of RBPs are a pathological feature frequently encountered in tauopathies (Vanderweyde 2016). Emerging studies on neurodegenerative diseases are now showing an increasingly important role for tau in regulating the biology of RBPs. In this study, we examine findings that show that reducing the RBP T-cell intracellular antigen 1 (TIA1) in vivo not only protects against neurodegeneration, but also prolongs the survival rate in transgenic P301S tau mice. Furthermore, the reduction of TIA1 decreases the number and size of granules co-localizing with stress granule markers, and inhibits the accumulation of tau oligomers, although at the expense of an increased number of neurofibrillary tangles. However, despite the observed increase in neurofibrillary tangles, this TIA1 reduction still manages to increase neuronal survival, rescue behavioral deficits and prolong lifespan. The in vivo data presented in this study suggests an important role for TIA1 in mediating toxicity and provides evidence that RBPs orchestrate a pathway to tau aggregation and the resulting neurodegeneration.

Medicine

Neurodegeneration

Neuroinflammation

Stress granules

Tau

Tauopathies

T-cell intracellular antigen 1

A função mediadora do receptor para produtos finais de glicação avançada (RAGE) na neuroinflamação e neurodegeneração em diferentes modelos in vivo

Gasparotto, Juciano

January 2017

O RAGE é um receptor transmembrana, imunoglobulina-like que existe em múltiplas isoformas e interage com um amplo repertório de ligantes extracelulares. O RAGE é expresso em níveis baixos na maioria das células, porém o aumento da presença de seus ligantes no domínio extracelular faz com que o RAGE inicie uma cascata de sinalização intracelular complexa, resultando em estresse oxidativo, ativação do fator de transcrição NF-B, aumento da expressão de citocinas, além da indução de sua própria expressão. O envolvimento do RAGE neste amplo espectro de sinalização vincula este receptor a diversas condições patológicas. Nesta tese utilizamos 3 modelos experimentais que induzem inflamação sistêmica (Leishmania amazonensis, Lipopolissacarídeo e sepse) e 1 modelo experimental que mimetiza a denervação neuronal (modelos experimentais in vivo). Além disso utilizamos diferentes abordagens de bloqueio do RAGE a fim de elucidar a função deste receptor. Com base em nossos resultados os modelos experimentais foram eficientes em induzir o aumento do RAGE e sua sinalização no sistema nervoso central, desencadeando a síntese e liberação de moléculas pró-inflamatórias e o aumento do estresse oxidativo, culminando em neuroinflamação e neurodegeneração. As intervenções de bloqueio do RAGE foram eficientes em inibir as vias de sinalização intracelular mediadas pelo receptor, comprovando a via de ação. Levando em conta nossos principais resultados concluímos que: a) RAGE atua como mediador da perda neuronal em resposta ao insulto inflamatório em diversas estruturas do SNC, b) está presente no corpo dos neurônios dopaminérgicos e envolvido na morte destes neurônios; c) o aumento do RAGE é tempo-dependente e a morte dos neurônios está vinculada a ação deste receptor. / RAGE is a transmembrane, immunoglobulin-like receptor that exists in multiple isoforms and interacts with a broad repertoire of extracellular ligands. RAGE is expressed at low levels in most cells, but the increased presence of its ligands initiates a complex intracellular signaling cascade resulting in oxidative stress, activation of transcription factor NF-B, increased expression of cytokines in addition to concomitant upregulation of RAGE itself. In this thesis we used 3 experimental models which induce systemic inflammation (Leishmania amazonensis, Lipopolysaccharide and sepsis) and 1 experimental model that mimics neuronal denervation (experimental models in vivo). In addition, different approaches to block RAGE were used to elucidate the function of this receptor. Based on our results the experimental models were efficient in inducing the increase of RAGE and its signaling in the central nervous system, triggering the synthesis and release of proinflammatory molecules and the increase of oxidative stress, culminating in neuroinflammation and neurodegeneration. The RAGE blocking interventions were effective in inhibiting receptor-mediated signaling, proving the signaling pathway. Considering our main results, we conclude that: a) RAGE acts as a mediator of neuronal loss triggered by inflammatory insults in various CNS structures; b) RAGE is present in the body of dopaminergic neurons and is involved in the death of these neurons; c) the increase of RAGE is time-dependent, and the neuronal death is dependent on the action of this receptor.

Doenças neurodegenerativas

Degeneracao neural

RAGE

Neurodegeneration

Neuroinflammation

Efeito protetor de nanocápsulas poliméricas contendo crisina em modelo de doença de Alzheimer induzida por injeção intracerebroventricular do peptídeo β-amilóide 1-42

Giacomeli, Renata

23 July 2015

Submitted by Marcos Anselmo (marcos.anselmo@unipampa.edu.br) on 2016-09-13T19:44:23Z No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) Renata Giacomeli.pdf: 1026894 bytes, checksum: b5f9c6a47c7fdc580b5b82dbafdcf4a8 (MD5) / Approved for entry into archive by Marcos Anselmo (marcos.anselmo@unipampa.edu.br) on 2016-09-13T19:44:45Z (GMT) No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) Renata Giacomeli.pdf: 1026894 bytes, checksum: b5f9c6a47c7fdc580b5b82dbafdcf4a8 (MD5) / Made available in DSpace on 2016-09-13T19:44:46Z (GMT). No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) Renata Giacomeli.pdf: 1026894 bytes, checksum: b5f9c6a47c7fdc580b5b82dbafdcf4a8 (MD5) Previous issue date: 2015-07-23 / A doença de Alzheimer (DA) é uma desordem neurodegenerativa crônica caracterizada clinicamente pela perda progressiva de função cognitiva, distúrbios neuropsiquiátricos e comportamentais. Patologicamente esta doença caracteriza-se pelo acúmulo anormal do peptídeo β-amilóide (Aβ) no córtex e no hipocampo, emaranhados neurofibrilares intracelulares formados por Tau hiperfosforilada, disfunção progressiva sináptica e, posteriormente perda neuronal. As opções terapêuticas disponíveis melhoram os sintomas, mas não impedem a progressão da doença, portanto, ainda está faltando uma estratégia terapêutica efetiva para DA. A Crisina (5, 7-dihidroxiflavona) é um flavonoide natural encontrada em extratos de plantas (tais como Passiflora caerulea e Populus tremula), própolis e mel que apresenta propriedades farmacológicas relevantes, incluindo efeito antioxidante, antiinflamatório, hipolipidêmico, anti-aterogênico, anticâncer e, de forma mais significativa, efeito neuroprotetor. Porém, existem algumas desvantagens que podem limitar a sua potencial aplicação na terapêutica tais como baixa solubilidade e má absorção intestinal. Somando-se a isso, um fato determinante na neuroterapia é o efeito restritivo da barreira hematoencefálica (BHE), a qual limita a eficácia de tratamentos. Muitos estudos têm-se centrado sobre este problema fundamental através da concepção de estratégias diferentes para 5 facilitar a passagem de ativos em todo a BHE. Entre estes, as abordagens baseadas em nanotecnologia ganharam impulso significativo, já que podem efetivamente transportar substâncias ativas através da BHE. Assim, o objetivo deste trabalho foi preparar um sistema baseado em nanopartículas, capaz de veicular a crisina, bem como investigar os efeitos biológicos em um modelo de DA induzida por injeção intracerebroventricular (icv) do peptídeo beta amiloide1-42 (Aβ1-42) em camundongos Swiss fêmeas com idade entre 18 e 22 meses. Para tanto, determinou-se parâmetros de estresse oxidativo, neuroinflamação e níveis do fator neurotrófico derivado do cérebro (BDNF) no córtex pré-frontal e hipocampo, também verificou-se os efeitos comportamentais cognitivos dos camundongos. Os animais foram divididos em 10 grupos: (1) veículo/tampão phosphate-buffered saline (PBS); (2) veículo/nanocápsula (NC)-branca; (3) veículo/crisina livre (5 mg/kg); (4) veículo/NC-crisina (1 mg/kg); (5) veículo/NC-crisina (5 mg/kg); (6) Aβ1-42/PBS; (7) Aβ1-42/NC-branca; (8) Aβ1-42/crisina livre (5 mg/kg); (9) Aβ1-42/NC-crisina (1 mg/kg) e; (10) Aβ1-42/NC-crisina (5 mg/kg). O peptídeo Aβ1-42 ou o veículo foram infundidos por injeção icv e, um dia depois, iniciou-se o tratamento, por via oral, durante 14 dias. Após o fim do tratamento, os animais foram submetidos aos testes comportamentais. Os resultados demonstraram que os efeitos neuroprotetores do crisina foram mais elevados quando administrada em nanopartículas. O nanossistema melhorou as concentrações de crisina nos tecidos cerebrais, bem como a eficácia farmacológica. O presente estudo demonstrou que o tratamento com crisina, principalmente na formulação de nanopartículas, foi eficaz em atenuar as seguintes alterações resultantes da exposição de camundongos à Aβ1-42: o comprometimento da memória em testes de comportamento, o aumento dos níveis de espécies reativas (RS), fator de necrose tumoral α (TNF-α) e interleucina-1β (IL-1β), a redução dos níveis de tióis não-proteicos (NPSH), BDNF e IL-10; o aumento da atividade de glutationa peroxidase (GPx) e glutationa redutase (GR) em córtex pré-frontal e hipocampo. Em conclusão, esses resultados demonstram que a atenuação da neuroinflamação e do estresse oxidativo está envolvido no efeito neuroprotetor da crisina neste modelo de DA, além disso, sugerem que a formulação de nanopartículas potencializa seus efeitos, o que pode fornecer uma nova abordagem terapêutica para o tratamento e prevenção de DA. / Alzheimer's disease (AD) is a chronic neurodegenerative disorder characterized clinically by progressive loss of cognitive function, neuropsychiatric and behavioral disorders. Pathologically the disease is characterized by abnormal accumulation of β-amyloid peptide (Aß) in cortex and hippocampus, intracellular neurofibrillary tangles consisting of hyperphosphorylated Tau, and synaptic dysfunction progressively later neuronal loss. The therapeutic options available improve symptoms but did not prevent disease progression, therefore, is still missing an effective therapeutic strategy for AD. Chrysin (5, 7-dihidroxiflavone) is a flavonoid found in natural plant extracts (such as Passiflora caerulea and Populus tremula), honey and propolis which has significant pharmacological properties including antioxidant, anti-inflammatory, hypolipidemic, anti-atherogenic, anti-cancer effects and, more significantly, neuroprotection. However, there are some disadvantages that may limit their potential application in therapeutics such as low solubility and intestinal malabsorption. Adding to this, a key fact in Neurotherapy is the restrictive effect of the blood-brain barrier (BBB), which limits the effectiveness of treatments. Many studies have focused on this fundamental problem by designing different strategies to facilitate the transition of assets across the BBB. Among these, nanotechnology-based approaches have gained significant momentum as they can effectively carry active substances through the BBB. The 7 objective of this work was to prepare a system based on nanoparticles, capable of relaying chrysin, as well as investigating the biological effects in a model of AD induced by intracerebroventricular injection (icv) of Beta amyloid1-42 peptide (Aβ1-42) in swiss mice females aged between 18 and 22 months. Therefore, it was determined parameters of oxidative stress, neuroinflammation and levels of brain-derived neurotrophic factor (BDNF) in the prefrontal cortex and hippocampus, it was also observed cognitive behavioral effects in mice. The animals were divided into 10 groups: (1) vehicle/phosphate-buffered saline (PBS); (2) Vehicle/blank-nanocapsule (NC); (3) vehicle/free chrysin (5 mg / kg); (4) Vehicle/NC-chrysin (1 mg / kg); (5) vehicle/NC-chrysin (5 mg / kg); (6) Aβ1-42/PBS; (7) Aβ1-42/blank-NC; (8) Aβ1-42/free chrysin (5 mg / kg); (9) Aβ1-42/NC-chrysin (1mg / kg) and; (10) Aβ1-42/NC-chrysin (5 mg / kg). The Aβ1-42 peptide or vehicle were infused icv injection and, one day later, treatment began, orally, for 14 days. After the end of treatment, animals were subjected to behavioral testing. The results showed that the neuroprotective effects of chrysin were higher when administered in nanoparticles. The nano system improved chrysin concentrations in the brain tissue as well as the pharmacological effectiveness. The present study demonstrated that treatment with chrysin, especially in nanoparticle formulation was effective in attenuating the following shortcomings arising from exposure of mice to Aβ1-42: the memory impairment in behavioral tests; the increased reactive oxygen species (RS), tumor necrosis factor α (TNF-α) and interleukin-1β (IL-1β) levels, reduction non-thiol protein (NPSH), BDNF, and IL-10 levels; increasing the glutathione peroxidase (GPx) and glutathione reductase (GR) activity in the prefrontal cortex and hippocampus. In conclusion, these results demonstrate that blocking neuroinflammation and oxidative stress is involved in the neuroprotective effect of chrysin in this model, moreover, suggest that the nanoparticle formulation potentiates their effects, which may provide a new therapeutic approach for the treatment and prevention of AD.

Doença de alzheimer

Estresse oxidativo

Neuroinflamação

Crisina

Nanopartículas

Alzheimer's disease

Oxidative stress

Neuroinflammation

Chrysin

Nanoparticles

Avaliação da neuroinflamação e da atividade astrocitária em modelo de epilepsia por Li-pilocarpina: S100B possível marcador e alvo farmacológico

Vizuete, Adriana Fernanda Kuckartz

January 2017

A epilepsia do lobo temporal (ELT) é a um dos casos mais frequente epilepsia em humanos e de maior refratariedade nos pacientes. A maioria dos fármacos antiepilépticos são moduladores da atividade neuronal e atuam sobre canais iônicos do receptor GABAA. Estudos vêm demonstrando o papel das células gliais e da neuroinflamação na epileptogênese e a modulação desta resposta pode ser um alvo potencial para drogas adjuvantes aos fármacos anti-epilépticos. Astrócitos são células gliais participantes da sinapse tripartite, moduladores da atividade neuronal. Os astrócitos são capazes de promover a homeostase de íons e de neurotransmissores, são responsáveis pelo metabolismo energético e da produção de fatores neurotróficos, glutationa, glutamina, S100B e citocinas. Neste trabalho, induzimos status epilepticus (SE) em ratos jovens (PN28) através do modelo lítio-pilocarpina que mimetiza alterações neuronais, bioquímicas e morfológicas similares à ELT em humanos. Os animais foram divididos nos tempos 1, 14 e 56 dias após a indução de status epilepticus (SE). Estes períodos são caracterizados respectivamente como a fase aguda, latente e crônica da epilepsia. Inicialmente, analisamos as mudanças neuroquímicas e astrocitárias ao longo do tempo. Foi observada neuroinflamação inicial e transitória que promove morte neuronal e mudanças ao longo do tempo de astrogliose e disfunção astrocitária. Também foi observado que a proteína S100B, proteína ligante de cálcio, predominantemente astrocitária, pode ser considerado um marcador da disfunção neuronal e astrocitária promovida neste modelo de epilepsia. Em seguida, demonstramos que a modulação da secreção de S100B pelo anti-inflamatório dexametasona um dia após indução de SE reverte a neuroinflamação, astrogliose e disfunção astrocitária à curto e à longo prazo. Por conseguinte, observamos que a modulação do receptor GABAA através de agonistas e antagonistas GABAérgicos altera a secreção de S100B em fatias hipocampais agudas e em cultura de astrócitos. Portanto, pode-se sugerir que as alterações astrogliais e a neuroinflamação dependentes do tempo podem estar ligadas à excitabilidade neuronal e/ou à morte neuronal em ratos jovens em modelo de epilepsia; que a proteína S100B pode ser considerada um marcador deste modelo de epilepsia e que a modulação da sua secreção pode ser um possível alvo farmacológico no tratamento da epilepsia. / Temporal lobe epilepsy (TLE) is the most frequent type of epilepsy in humans and is more associated to refractory to anti-epileptic drugs (AED) in patients. The most AEDs are modulators of neuronal activity and act on ion channels, such as GABAA receptor. Studies have been demonstrating the role of glial cells and neuroinflammation in epileptogenesis. The modulation of this response may be a potential target for adjunctive drugs to anti-epileptic drugs. Astrocytes are glial cells that participated in the tripartite synapse and modulated neuronal activity. Astrocytes are able to promote homeostasis of ions and neurotransmitters, are responsible for energy metabolism and the production of neurotrophic factors, glutathione, glutamine, S100B and cytokines. In this work, we induced status epilepticus (SE) in young rats (PN28) through the lithiumpilocarpine model that mimics neuronal, biochemical and morphological alterations similar to ELT in humans. The animals were divided at times 1, 14 and 56 days after the induction of SE. These periods are characterized respectively as the acute, latent and chronic phase of epilepsy. Initially, we analyzed neurochemical and astrocytic changes over time. Initial and transient neuroinflammation was observed and promoted over time neuronal death, astrogliosis and astrocytic dysfunction. It has also been observed that the protein S100B, a calcium-binding protein, predominantly astrocytic, can be considered a marker of neuronal and astrocytic dysfunction promoted by this model of epilepsy. Next, we demonstrate that the modulation of S100B secretion by the antiinflammatory dexamethasone one day after SE induction reverses neuroinflammation, astrogliosis and astrocytic dysfunction in the acute and chronic time. Therefore, we analyzed that modulation of the GABAA receptor through GABAergics agonists and antagonists alters the secretion of S100B in acute hippocampal slices and in astrocyte culture. Therefore, it may be suggested that astroglial changes and time dependent neuroinflammation may be related to neuronal excitability and/or neuronal death in young rats in this epilepsy model; that S100B protein can be considered a marker of this epilepsy model and that the modulation of its secretion may be a possible pharmacological target in the treatment of epilepsy.

Epilepsia

Astrócitos

Pilocarpina

Proteínas S100

Receptores de GABA-A

Inflamação

Sistema nervoso central

Epilepsy

S100B

Astrocytes

Neuroinflammation

Pilocarpine

Définir le rôle de chimiokines comme médiateurs pathologiques de la neuroinflammation dans le modèle MPTP de la Maladie de Parkinson / Defining the role of chemokines as pathological mediator of neuroinflammation in the MPTP model of Parkinson Disease

Parillaud, Romain

25 June 2015

La maladie de Parkinson (MP) est marquée par la présence d'une inflammation, pouvant être bénéfique ou délétère à la neurodégénérescence dopaminergique (DAgique). Nous avons adressé la nature des interactions pathologiques entre neurones DAgiques, cellules gliales et leucocytes infiltrant, nécessaire à la mise en place de cette inflammation. Dans un modèle MPTP murin de la MP, les objectifs de ma thèse ont été 1) d'identifier des signaux inflammatoires neuronaux et gliaux, par une approche transcriptomique associée à de la microdissection laser et 2) de déterminer leurs rôles dans la neuroinflammation ainsi que leurs effets sur la perte DAgique. Nous avons retenu parmi les candidats identifiés: les axes CXCL16-CXCR6 et CCL2-CCR2. Nous reportons dans le modèle MPTP, une expression microgliale de CXCL16 ainsi qu'une infiltration de population lymphocytaire CXCR6. Bien que la déplétion de CXCR6 permette de réduire cette infiltration, aucun effet n'est observé sur la perte DAgique. Nous décrivons une infiltration de monocyte CCR2 en concomitance avec une expression astrocytaire précoce de CCL2 dans le modèle MPTP murin, ainsi qu'une expression plus prolongée de CCL2 chez le primate non-humain MPTP, suggérant une relevance de l'axe CCL2-CCR2 dans la MP. En effet nous montrons que des souris surexprimant CCL2, intoxiquées au MPTP, ont non seulement une augmentation accrue de l'infiltrat monocytaire CCR2, mais également de la lésion DAgique. De manière inattendue, nous montrons que la neurotoxicité accrue observée chez des souris CX3CR1-/- MPTP passe indirectement par la voie CCL2-CCR2. Ainsi, nos données supportent l'hypothèse d'une neurotoxicité des monocytes CCR2 dans la MP. / Parkinson's disease (PD) presents signs of neuroinflammation, which can be beneficial or deleterious for dopaminergic (DA) neurodegeneration. We have analyzed the characteristics of such pathological interactions between DA neurons, glial cells and infiltrating immune cells. Using the neurotoxic MPTP mouse model of PD and focusing on chemokines, my thesis objectives were: 1) to identify using laser-microdissection and RNA profiling, the neuronal and glial inflammatory signals in the affected Substantia Nigra (SN) and 2) to assess the role of promising identified chemokine candidates during DA neurodegeneration. We have focused on the lymphocytic CXCL16-CXCR6 and the monocytic CCL2-CCR2 axes. We have found early microglial CXCL16 induction and parallel SN infiltration of CXCR6 lymphocyte subpopulations. CXCR6-deletion reduced infiltration of specific lymphocyte subpopulations, but did not affect the known deleterious infiltration of CD4 T-lymphocytes. For the CCL2-CCR2 axis, we found evidence for limited SN infiltration of CCR2 monocytes, which was preceded by transient astrocytic CCL2 induction in MPTP mice, but a prolonged CCL2 induction in MPTP monkeys, suggesting a potential relevance for human PD. While CCR2-gene deletion did not affect loss of DA neurons, astrocytic CCL2 overexpression increased MPTP induced DA neural loss, revealing the principally neurotoxic nature of infiltrating CCR2 monocytes in a PD-like environment. Unexpectedly, we also found that the known increased DA loss in CX3CR1-KO mice was mediated indirectly via over-induction of the CCL2-CCR2 axis. Combined, our results suggest a potential deleterious role of the CCL2-CCR2 axis in actual human PD.

Parkinson

MPTP

Neuroinflammation

Chimiokines

Monocyte

Microdissection-Laser

Parkinson's disease

Neurodegeneration

Chemokines

616.8

Glutamatergic and Neuroimmune Mechanisms of N-acetylcysteine-Mediated Inhibition of Cue-Induced Nicotine Seeking

January 2019

abstract: Nicotine self-administration is associated with decreased expression of the glial glutamate transporter 1 (GLT-1) and the cystine-glutamate exchange protein xCT in the nucleus accumbens core (NAcore). N-acetylcysteine (NAC), which is an antioxidant, anti-inflammatory, and glutamatergic agent, restores these proteins associated with increased relapse vulnerability. However, the specific molecular mechanisms driving NAC inhibitory effects on cue-induced nicotine reinstatement are unknown. Thus, the present study assessed NAC’s effects on cue-induced nicotine reinstatement are dependent on NAcore GLT-1 expression. Here, rats were treated with NAC in combination with intra-NAcore vivo-morpholinos to examine the role of GLT-1 in NAC-mediated inhibition of cue-induced nicotine seeking. Subchronic NAC treatment attenuated cue-induced nicotine seeking in male rats and an antisense vivo-morpholino (AS) designed to selectively suppress GLT-1 expression in the NAcore blocked this effect. NAC treatment was also associated with an inhibition of pro-inflammatory tumor necrosis factor alpha (TNFα) expression in the NAcore. As well, GLT-1 AS markedly increased expression of CD40, a known marker of pro-inflammatory M1 activation of microglia and macrophages. To further examine whether NAC-induced decreases in nicotine seeking involve suppression of TNFα, we manipulated a downstream mediator of this pathway, nuclear factor kappa B (NF-kB). Considering the putative role of NF-κB in learning, memory, and synaptic plasticity, separate experiments were performed where rats were treated with herpes simplex virus (HSV) vectors designed to increase (HSV-IKKca) or decrease (HSV-IKKdn) NF-κB signaling through interactions with IκB Kinase (IKK). The goal was to examine the role of NF-κB signaling in mediating nicotine seeking behavior and if NF-κB signaling regulates GLT-1 expression. HSV-IKKdn alone and in combination with NAC inhibited cue-induced nicotine reinstatement, while HSV-IKKca blocked the attenuating effect of NAC on reinstatement. Interestingly, both HSV-IKKdn and HSV-IKKca, regardless of NAC treatment, inhibited GLT-1 expression. Taken together, these results suggest that while GLT-1 may be a conserved neurobiological substrate underlying relapse vulnerability across drugs of abuse, immunomodulatory mechanisms may regulate drug-induced alterations in glutamatergic plasticity that mediate cue-induced drug-seeking behavior through GLT-1-independent mechanisms. / Dissertation/Thesis / Masters Thesis Psychology 2019

Neurosciences

Behavioral sciences

Pharmacology

CD40

GLT-1

neuroinflammation

nucleus accumbens

reinstatement

TNF

ROLE OF MCP-1 AND CCR2 IN ETHANOL-INDUCED DAMAGE IN THE DEVELOPING BRAIN

Zhang, Kai

01 January 2019

Fetal alcohol spectrum disorders (FASD) are caused by alcohol exposure during pregnancy and is the leading cause of mental retardation. Alcohol exposure during development results in the loss of neurons in the developing brain. The underlying molecular mechanisms are unclear and there currently is no cure for FASD. Ethanol-induced neuronal death is accompanied by neuroinflammation. Chemokine monocyte chemoattractant protein 1 (MCP-1) and its receptor C-C chemokine receptor type 2 (CCR2) are critical mediators of neuroinflammation and microglial activation. Using a third trimester equivalent mouse model of ethanol exposure, we found that treatment of Bindarit (MCP-1 synthesis inhibitor) and RS504393 (CCR2 antagonist) significantly reduced ethanol-induced microglia activation/neuroinflammation, and neuroapoptosis in the developing brain. Moreover, ethanol plus MCP-1 caused more neuronal death in a neuron/microglia co-culture system than neuronal culture alone, and Bindarit and RS504393 attenuated ethanol-induced neuronal death in the co-culture system. Ethanol activated TLR4 and GSK3β, two key mediators of microglial activation in the brain and cultured microglial cells (SIM-A9). Blocking MCP-1/CCR2 signaling attenuated ethanol-induced activation of TLR4 and GSK3β. Further, we determined whether knocking out of MCP-1/CCR2 ameliorates neonatal alcohol exposure-induced long-lasting behavioral deficits in adolescent and adult mice. C57BL/6 and MCP-1-/-/CCR2-/- mice were exposed to alcohol (5 g/kg) by subcutaneously injection on PD4. A series of behavioral tests including Open Field (PD 35-36 and PD 70-71), Rotor-Rod (PD 38 and PD 73), Balance Beam (PD 40 and PD75) and Morris Water Maze (PD 42 and PD77) were performed in the adolescence and adulthood. We found that MCP-1-/-/CCR2-/- mice were resistant to neonatal alcohol exposure-induced deficits in motor function in the Rotor-Rod and Balance Beam tests; MCP-1 and CCR2 deficiency also protected mice against neonatal ethanol exposure induced long lasting deficits in learning and memory in the Morris Water Maze testing. Collectively, these results suggest that MCP-1/CCR2 signaling plays an important role in ethanol-induced microglial activation/neuroinflammation and neurodegeneration in the developing brain and also plays an important role in developmental alcohol exposure induced long-lasting behavioral deficits in adolescence and adulthood.

Fetal alcohol syndrome

chemokines

development

glia

neuroinflammation

neurodegeneration

unfolded protein response

Pharmacology

The Effect of Two Novel Anti-Inflammatory Drugs on Sensorimotor Gating and Microglial Activation in the Poly I:C Rodent Model of Schizophrenia

Shelton, Heath W, Gill, W. Drew, Gabbita, Prasad, Brown, Russell W

12 April 2019

Antipsychotic medications remain the first line of treatment for individuals diagnosed with schizophrenia (SCZ). However, antipsychotic treatment is often not compliant due to dysregulation of both the central (CNS) and autonomic (ANS) nervous systems, resulting in debilitating dose-dependent side effects. Recent work suggests a new approach for treatment of SCZ that could potentially lower treatment doses and reduce side effects. Increased neuroinflammation has been shown in patients diagnosed with SCZ, particularly within the prefrontal cortex (PFC) and hippocampal (HPC) regions of the brain. Tumor necrosis factor-alpha (TNFa) is one of the key pro-inflammatory cytokines observed to be secreted during the inflammatory response. When TNFa is chronically secreted, resident CNS microglia become pro-inflammatory and toxic to the local environment. Microglial activation alongside of dopamine dysregulation thereby results in both the behavioral and neuroinflammatory aspects of SCZ. In this study, we hypothesized dietary administration of two different novel TNFamodulators (PD2024 – Experiment 1 and PD340 – Experiment 2) developed by our collaborators from P2D Bioscience, Inc. (Cincinnati, OH) would alleviate auditory sensorimotor gating deficits and reduce microglial cell activation caused by neonatal polyinosinic:polycytidylic acid (Poly I:C) treatment in rats, which is a validated rodent model of SCZ. Four groups (Experiment 1: Poly IC/PD2024, Poly IC/Control, Saline/PD2024, Saline/Control and Experiment 2: Poly IC/PD340, Poly IC/Control, Saline/PD340, Saline/Control) were intraperitoneally administered either Poly I:C (2 mg/kg) or saline (0.9% NaCl) from postnatal days 5-7. From P30-67, animals were placed on the experimental diet containing either low (10 mg/kg) or high (30 mg/kg) doses of either PD2024 or PD340, whereas the control animals remained on a normal diet. Prepulse inhibition (PPI) was used to test for auditory sensorimotor gating (behavioral abnormalities) in both adolescence (P44-46) and in adulthood (P60-66). At P67, immunohistochemistry (IHC) and confocal microscopy were used to evaluate and examine microglial cell activation using the Iba1-GFP antibody (neuroinflammatory abnormalities) in the PFC and HPC. Results revealed auditory sensorimotor gating deficits in Poly IC/Controls were alleviated in both adolescence and adulthood with either PD2024 or PD340. It was also found that both TNFa modulators significantly reduced microglial activation in the HPC, but not the PFC. The data supports our hypothesis that dietary administration of PD2024 or PD340 alleviates behavioral deficits and decreases neuroinflammation generated from the Poly I:C rodent model of SCZ. Therefore, an approach with a TNFa modulator alongside of current antipsychotic medications could treat both the behavioral and neuroinflammatory aspects of SCZ.

Schizophrenia

Neuroinflammation

TNF-alpha

Microglia

Poly I:C

Behavioral Problems or Disorders

Inflammation

MECHANISMS REGULATING AXON INITIAL SEGMENT STABILITY

Benusa, Savannah D

01 January 2018

Axon initial segment (AIS) disruption has been described in a number of pathological environments where neuroinflammation is a contributing factor; however, whether this disruption is reversible in unknown. To address the principle of AIS structural recovery, we employed an acute neuroinflammatory model. Acute neuroinflammation induced disruption of AIS structural and functional domains and, importantly, upon resolution of neuroinflammatory conditions, was reversed. Consistent with other studies, we observed a close interaction of microglia with AISs, and utilized this acute neuroinflammatory model to investigate the relationship between reactive microglia and AIS integrity. Gene expression analysis of microglial transcription profiles identified reactive oxygen species (ROS)-producing enzymes as candidates in AIS pathogenesis. Experiments employing mice lacking the major ROS-producing enzyme NOX2, identified ROS as mediators of AIS disruption. Furthermore, we established calcium-dependent protease calpain as a disruptor of AIS protein clustering in inflammation-induced disruption. Since we observed an intimate interaction between microglia and the AIS, we conducted studies designed to identify a candidate in microglia that regulates microglial-AIS contact. During chronic inflammatory conditions, microglia enhance contact with AISs often completely surrounding the domain. Concomitant with this morphological change, neurofascin (Nfasc) expression increased in microglia. Nfasc is a cell adhesion molecule with cell-specific isoforms known to mediate glial-neuronal interactions, but until now, was not reported to be expressed by microglia. Here, I characterize the unique Nfasc isoform expressed by microglia and present evidence that suggests that microglial Nfasc may mediate microglial-AIS contact, a potentially pivotal interaction in the induction of AIS disruption by pro-inflammatory factors.

Axon Initial Segment

Neuroinflammation

Reactive Oxygen Species

NOX2

AIS Plasticity

Microglia

Neurofascin

Molecular and Cellular Neuroscience