Análise do transporte de glutamato e GABA em epimastigotas de Trypanosoma cruzi. / Analysis of glutamate and GABA Transport in Trypanosoma Cruzi.

Robert Leonardo Galvez Rojas

09 August 2007

A importância de aminoácidos em tripanossomatídeos vai além da síntese de aminoácidos, envolvendo processos tais como a diferenciação, osmorregulação e metabolismo energético. A disponibilidade dos aminoácidos envolvidos nestas funções depende, entre outras coisas, de seu transporte na célula. Aqui, caracterizamos o transporte de glutamato e GABA do parasita protozoário humano Trypanosoma cruzi. No transporte de glutamato dados cinéticos amostram um único sistema saturável com uma Km de 0.30 mM e uma velocidade máxima de 98.34 pmoles min-1 per 2 x 107 células para epimastigotas é 20 pmoles min-1 per 2 x 107 células para trypomastigotas, e uma Vmax de 84.45 pmoles/min/20x106 células com uma Km de 0.4 mM para o sistema de transporte de GABA. O transporte não apresentou alterações em condições de jejum de até 3 horas. Aspartato, alanina, glutamina, asparagina, metionina, oxaloacetato é alfa-cetoglutarato competiram com o substrato em concentrações dez vezes em excesso na incorporação de glutamato. Interessantemente, o transporte de glutamato aumentou fortemente na presença de GABA. O transporte de glutamato foi fortemente dependente do pH, mas não de concentrações de Na+ e K+ no meio extracelular, e o transporte de GABA foi fortemente dependente de K+. Estes dados foram consistentes com uma sensibilidade do sistema de transporte a um ionóforo (FCCP), sugerindo que o transporte é levado por um gradiente de concentração de H+ na membrana plasmática nos dois sistemas de transporte. O transporte de glutamato e GABA aumentou linearmente com a temperatura na faixa de 15 a 40o C. / The role of amino acids in trypanosomatids goes beyond protein synthesis, involving processes such as differentiation, osmoregulation and energy metabolism. The availability of the amino acids involved in those functions depends, among other things, on their transport into the cell. Here we characterize a glutamate transporter and GABA transport from the human protozoan parasite Trypanosoma cruzi. In the glutamate transport, data kinetics show a single saturable system with a Km of 0.30 mM and a maximum velocity of 98.34 pmoles min-1 per 2 x 107 cells for epimastigotes and 20 pmoles min-1 per 2 x 107 cells for trypomastigotes, and, a Vmax de 84.45 pmoles/min/20x106 cells and a Km of 0.4 mM for GABA transport system. Transport was not affected by parasite nutrient starvation for up to 3h in the two transport system. Aspartate, alanine, glutamine, asparagine, methionine, oxaloacetate and alpha-ketoglutarate competed with the substrate in 10-fold excess concentrations in the glutamate incorporation. Interestingly, the glutamate transport was strongly increased in the presence of GABA. Glutamate uptake was strongly dependent on pH, but not on Na+ or K+ concentrations in the extracellular medium, and the GABA transport was strongly dependent of K+. These data were consistent with the sensitivity of the system to the H+ ionophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone, suggesting that transport is driven by H+ concentration gradient across the cytoplasm membrane in two transport systems. The glutamate and GABA transport increased linearly with temperature in a range from 15 to 40 degrees C.

Trypanosoma cruzi

Doença chagas

GABA

Glutamato

Metabolismo

Quimioterapia

Trypanosoma cruzi

Chagas disease

Chemotherapy

GABA

Glutamate

Metabolism

Separação materna e enriquecimento ambiental: envolvimento de células da glia, transportadores e receptores de glutamato no hipocampo de ratos jovens / Maternal separation and environmental enrichment: involvement of glial cells, glutamate transporters and glutamate receptors in the hippocampus of young rats

Priscila Mendes Comassio

09 May 2017

O desenvolvimento humano pode ser influenciado pelo ambiente. Estímulos recebidos ao longo da vida determinam seu progresso e sucesso. Estímulos positivos levam ao desenvolvimento de habilidades, melhorando funções cognitivas e da memória, enquanto estímulos negativos podem predispor a patologias como o estresse. Eventos estressantes durante a infância aumentam a predisposição para o desenvolvimento de transtornos psiquiátricos ao longo da vida. A separação materna, modelo animal de estresse pós-natal, promove diversas alterações comportamentais e encefálicas. Animais submetidos à separação materna apresentam comportamentos que mimetizam doenças psiquiátricas humanas. Por outro lado, diversos trabalhos sugerem que o enriquecimento ambiental pode ter efeito benéfico na reversão ou atenuação de modificações comportamentais e encefálicas promovidas por modelos animais de depressão, esquizofrenia, ansiedade e hiperatividade. Esses aspectos motivaram-nos a estudar se as alterações causadas por estresse podem ser revertidas ou atenuadas pelo enriquecimento do ambiente. Há evidências que sugerem um importante envolvimento de células gliais e de transportadores de glutamato presentes nessas células em modelos animais de transtornos psiquiátricos. Sendo assim, investigamos a expressão de mRNA e proteínas de dois transportadores de glutamato gliais e um neuronal, do receptor de glutamato AMPA, de marcadores gliais GFAP, S100?, glutamina sintase (GS) e do marcador de neurônios maduros NeuN na camada molecular e granular do giro denteado do hipocampo de ratos de 60 dias. Observamos que a separação materna diminui a expressão das proteínas GLAST, GLT-1, GS e NeuN, reduz a expressão dos genes Gria1 (AMPA) e S100?, e aumenta a expressão da proteína EAAC1 no giro denteado. Nossos dados sugerem uma reversão das alterações causadas pela separação materna em relação ao gene Gria1/AMPA e às proteínas GLAST, GLT-1 e EAAC1 após o enriquecimento ambiental. Portanto, o enriquecimento ambiental pode reverter as modificações causadas pela separação materna nas vias glutamatérgicas. Esses efeitos benéficos podem ser investigados para auxiliar no tratamento de transtornos psiquiátricos relacionados à separação materna. / Human development can be influenced by the environment. Stimuli received throughout life determine its progress and success. Positive stimuli lead to development of skills, improving cognitive and memory functions, while negative stimuli may predispose to pathologies such as stress. Stressful events during childhood increase the predisposition to psychiatric disorders throughout life. Maternal separation, an animal model of postnatal stress, promotes several behavioral and encephalic changes. Animals submitted to maternal separation stage behaviors associated with psychiatric diseases in humans. On the other hand, some researches have suggested that environmental enrichment may have some beneficial effects on the reversal or attenuation of behavioral and encephalic modifications promoted by animal models of depression, schizophrenia, anxiety and hyperactivity, which motivates us to study if these changes, stirred by this kind of stress, can be reversed or mitigated by environmental enrichment. There are evidences suggesting the involvement of glial cells and glutamate transporters existent in these cells in psychiatric disorders and animal models of these disorders. Therefore, we investigated mRNA and protein expression of two glial and one neuronal glutamate transporters, AMPA glutamate receptor, glial markers GFAP, S100?, glutamine synthase (GS), and the NeuN neuronal marker in the molecular and granular layer of the hippocampal gyrus in sixty-days-old rats. We observed that maternal separation decreases expression of GLAST, GLT-1, GS and NeuN proteins, reduces Gria1 (AMPA) and S100? gene expression, and increases EAAC1 protein expression in the dentate gyrus. After environmental enrichment, our data suggests a reversal of the maternal separation changes in the Gria1/AMPA gene and the GLAST, GLT-1 and EAAC1 proteins. Therefore, environmental enrichment may reverse the maternal separation changes in the glutamatergic pathways. These beneficial effects may be investigated to aid in the treatment of psychiatric disorders related to maternal separation.

AMPA

Astrócitos

Enriquecimento ambiental

Separação materna

Transportadores de glutamato

AMPA

Astrocytes

Environmental enrichment

Glutamate transporters

Maternal separation

Alterações do metabolismo oxidativo mitocondrial e neurodegeneração por metilmalonato / Changes in mitochondrial oxidative metabolism and neurodegeneration by methymalonate

Melo, Daniela Rodrigues de, 1982-

20 August 2018

Orientador: Roger Frigério Castilho / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-20T07:07:00Z (GMT). No. of bitstreams: 1 Melo_DanielaRodriguesde_D.pdf: 21069496 bytes, checksum: f3406a56ba7ffca25021b4803fc73a92 (MD5) Previous issue date: 2012 / Resumo: A acidemia metilmalônica é uma desordem metabólica hereditária envolvendo uma deficiência na atividade da enzima metilmalonil-CoA mutase, com resultante acúmulo de ácido metilmalônico (MMA) no organismo dos pacientes. Há evidências de comprometimento do metabolismo energético mitocondrial por MMA levando à neurodegeneração. Neste estudo avaliou-se o efeito in vitro de MMA no consumo de oxigênio por mitocôndrias isoladas de cérebro de rato na presença de diferentes substratos para a cadeia respiratória. MMA (1-10 mM) inibiu fortemente a respiração mantida por glutamato ou succinato. Nós confirmamos, por meio de experimentos sobre o transporte mitocondrial de succinato, que o efeito inibitório do MMA na respiração mantida por succinato deve-se à inibição do transportador mitocondrial de dicarboxilatos, impedindo a captação de succinato pela mitocôndria. Medidas do transporte mitocondrial de glutamato revelaram que o efeito do MMA na respiração mitocondrial mantida por glutamato não está relacionado à inibição da captação deste substrato pela mitocôndria. Enquanto o MMA mostrou um fraco efeito inibitório sobre a atividade das enzimas glutamato desidrogenase e aspartato transaminase, a atividade da 'alfa'-cetoglutarato desidrogenase foi significativamente inibida por MMA (Ki = 3,65 mM). Medidas do transporte mitocondrial de 'alfa'-cetoglutarato mostraram que o MMA extramitocondrial pode ser trocado pelo 'alfa'-cetoglutarato intramitocondrial, depletando este substrato da matriz mitocondrial, com consequente inibição da respiração mantida por glutamato. Nós observamos que organelas isoladas de cérebro podem acumular aproximadamente o triplo da concentração de MMA presente no meio extramitocondrial. Em adição, a inibição pelo MMA do consumo de oxigênio por fragmentos de cérebro de rato foi parcialmente prevenida pela presença de malato. Os efeitos in vivo do MMA foram estudados por meio das medidas de respiração e produção de espécies reativas de oxigênio em mitocôndrias isoladas de cérebro de ratos jovens cronicamente tratados (ip, 15 d) com MMA. Nenhuma diferença foi observada entre as amostras controle e tratadas com MMA, indicando que o tratamento in vivo com MMA não leva à disfunção mitocondrial permanente. Ainda, estudos sobre o efeito do MMA na viabilidade e metabolismo de células neuronais e gliais foram realizados. Na linhagem neuronal tumoral PC12, o MMA diminuiu a viabilidade celular após 24h de tratamento. Os parâmetros de potencial de membrana mitocondrial e respiração foram avaliados após 7h de tratamento com MMA. MMA inibiu a respiração nas células intactas, porém, não alterou a respiração nas células permeabilizadas, nas quais não há restrição de substratos. A viabilidade de células de glioblastoma humano, U-87MG, não foi afetada pelo tratamento com MMA. Já em astrócitos de cérebro de rato em cultura primária exposta ao MMA, a viabilidade e área celular foram reduzidas significativamente e alterações morfológicas também foram notadas. Tais observações nas células gliais primárias sugerem que as células tumorais sejam mais resistentes aos efeitos deletérios do MMA. Em conjunto, estes resultados indicam que o efeito inibitório de MMA no metabolismo oxidativo mitocondrial pode ser atribuído à inibição concomitante de enzimas específicas e transportadores, limitando a disponibilidade de substratos para as vias metabólicas mitocondriais / Abstract: Methylmalonic acidemia is an inherited metabolic disorder involving a deficiency in the activity of the enzyme methylmalonyl-CoA mutase or its cofactor 5'-deoxyadenosylcobalamin that results in an accumulation of methylmalonate (MMA) in the body. There is evidence that MMA impairs mitochondrial oxidative metabolism, leading to neurodegeneration. In this study we evaluated the in vitro effect of MMA on oxygen consumption by isolated rat brain mitochondria in the presence of different respiratory chain substrates. MMA (1-10 mM) strongly inhibited glutamate-supported and succinatesupported respiration. We confirmed that the inhibitory effect of MMA on succinatesupported respiration is due to inhibition of the mitochondrial dicarboxylate transporter by MMA, blocking succinate uptake by mitochondria. Glutamate transport measurements revealed that the MMA effect on glutamate-supported respiration is not due to inhibition of mitochondrial uptake of this substrate. While MMA showed a weak inhibitory effect on glutamate dehydrogenase and aspartate transaminase, _'alfa'-ketoglutarate dehydrogenase activity was significantly inhibited by MMA (Ki = 3.65 mM). 'alfa'-ketoglutarate transport measurements showed that an exchange can take place between extramitochondrial MMA and intramitochondrial 'alfa'-ketoglutarate, depleting this substrate and consequently causing inhibition of glutamate-supported respiration. We observed that isolated brain organelles can accumulate nearly three times the concentration of extramitochondrial MMA. In addition, MMA inhibition of respiration by diced rat brain tissue was partially prevented by malate. MMA effects in vivo were studied by measuring respiration and reactive oxygen species generation in isolated brain mitochondria from young rats chronically injected (ip, 15 d) with MMA. No differences were observed between control and MMA-treated samples, indicating that in vivo MMA treatment does not lead to permanent mitochondrial dysfunction. In addition, a study into the effect of MMA on the viability and metabolism of neuronal and glial cells was carried out. In the PC12 neuronal tumor cell line, MMA decreased cell viability after 24 hours of treatment. Mitochondrial membrane potential and respiration were evaluated after 7 hours of MMA treatment. MMA inhibited respiration in intact cells but did not alter respiration in permeabilized cells, where there is no substrate deprivation. Cell viability of U-87MG human glioblastoma cells was not affected by MMA treatment. However, in cells from a primary culture of rat cerebral astrocytes, viability and cell area were significantly reduced and morphological alterations were also noted. The most evident effects of MMA were observed in primary cells, suggesting that tumor cells are more resistant to the deleterious effects of MMA. Taken together, these results indicate that the inhibitory effect of MMA on mitochondrial oxidative metabolism can be ascribed to the concurrent inhibition of specific enzymes and transporters, limiting the availability of substrates for mitochondrial metabolic pathways / Doutorado / Biologia Estrutural, Celular, Molecular e do Desenvolvimento / Doutor em Ciências

Ácido metilmalônico

Ácido glutâmico

Mitocôndria

Metabolismo

Degeneração neural

Methylmalonic acid

Glutamate

Mitochondria

Metabolism

Neurodegeneration

Distribuição de receptores ionotrópicos de glutamato e sua co-localização com a fosfoproteína neural DARPP-32 em neurônios espinhosos de tamanho médio e interneurônios no núcleo acumbens. / Distribution of ionotropic glutamate receptors and their colocalization with the neural phosphoprotein DARPP-32 in medium sized spiny neurons and interneurons in the nucleus accumbens.

Aline Coelho Macedo

27 October 2009

O núcleo acumbens (Acb) é envolvido em comportamentos adaptativos e emocionais. A maioria dos neurônios do Acb são neurônios de projeção (MSNs) que contém a fosfoproteína DARPP-32 e são modulados por distintos tipos de interneurônios. Há pouca informação sobre os receptores de glutamato (Glu) expressos no Acb. Este estudo investiga, através de técnicas de imunohistoquímica, a distribuição e co-localização de marcadores do sistema dopaminérgico, dos receptores de Glu do tipo AMPA (GluR1-GluR4) e NMDAR1 e marcadores de interneurônios. Nossos resultados mostram que o Acb possui uma neuroquímica semelhante ao estriado dorsal. Porém, detectamos uma distribuição distinta de alguns dos marcadores no Acb. Os estudos de co-localização revelam que quase todos os neurônios no Acb expressam GluR2/3 ou GluR2. Em contraste, GluR1 e GluR4 são fracamente expressas e co-localizam com parvalbumina. Esses resultados indicam que GluR2 e GluR2/3 são expressas em MSNs DARPP-32+ e na maioria dos interneurônios do Acb enquanto GluR1 e GluR4 são exclusivamente expressas em interneurônios. / The nucleus accumbens is involved in adaptive and emotional behaviors. The majority of neurons in the Acb are projection neurons that express the phosphoprotein DARPP-32 and are modulated by distinct types of interneurons. There is little information about the glutamate receptors expressed in the Acb. This study investigates by immunohistochemical methods the distribution and co-localization of markers of the dopaminergic system, AMPA (GluR1-4) and NMDAR1 type Glu receptor subunits and specific markers of interneurons. Our results show that the neurochemistry of the Acb is similar to that of the dorsal striatum. However, we detected a distinct distribution of some markers in the Acb. Our co-localization studies reveal that almost all neurons of the Acb express GluR2/3 or GluR2. In contrast, GluR1 and GluR4 are weakly expressed and are co-localized with parvalbumin. These results indicate that GluR2 and GluR2/3 are expressed by MSNs DARPP-32+ and by the majority of interneurons of the Acb, whereas GluR1 and GluR4 are exclusively expressed by interneurons.

AMPA

DARPP-32

Dopamina

Glutamato

Neurotransmissores

Núcleo acumbens

AMPA

DARPP-32

Dopamine

Glutamate

Neurotransmitters

Nucleus accumbens

Optimisation et caractérisation de nouveaux inhibiteurs pharmacologiques de DYRKs et CLKs, les leucettines / Optimization and characterization of Leucettines, a novel class of pharmacological inhibitors of DYRKs and CLKs

Tahtouh, Tania

27 March 2013

Les DYRKs (dual specificity, tyrosine phosphorylation regulated Kinases) et CLKs (cdc2-like kinases) sont deux familles de kinases du groupe CMGC. Elles sont impliquées dans le développement de la maladie d'Alzheimer et de la trisomie 21. Nous présentons ici une optimisation et une caractérisation biologique détaillée des Leucettines, une famille d’inhibiteurs pharmacologiques de DYRKs/CLKs dérivés de la Leucettamine B, un alcaloïde extrait d'une éponge marine. Nous avons étudié la relation structure/activité de cette classe d'inhibiteurs sur un ensemble de réponses biologiques. Afin d'étudier les cibles potentielles de ces inhibiteurs, nous avons mis en œuvre une méthode de chromatographie d’affinité. La sélectivité de la Leucettine L41, sélectionnée comme représentative des Leucettines, a été étudiée par des essais d'activité et d'interaction de kinases recombinantes in vitro, et des tests de chromatographie d'affinité (Leucettines immobilisées sur billes d'agarose, compétition sur billes d’inhibiteurs non sélectifs). Des approches transcriptomiques et protéomiques ont été utilisées afin de mieux comprendre le mécanisme d'action cellulaire de la Leucettine L41. Ces approches ont confirmé la sélectivité de la Leucettine L41 pour DYRKs et CLKs mais aussi révélé l’existence de cibles secondaires intéressantes. La Leucettine L41 module l'épissage alternatif de pré-ARNm. Elle présente des propriétés neuroprotectrices vis-à-vis de la mort cellulaire induite par le glutamate. Les Leucettines méritent un développement en tant qu'agents thérapeutiques potentiels pour le traitement de la maladie d'Alzheimer et de la trisomie 21. / DYRKs (dual specificity, tyrosine phosphorylation regulated kinases) and CLKs (cdc2-like kinases) are two families of kinases belonging to the CMGC group. They are involved in the development of Alzheimer's disease and Down syndrome. We here present the optimization and a detailed biological characterization of Leucettines, a family of pharmacological inhibitors of DYRKs/CLKs derived from Leucettamine B, an alkaloid produced by a marine sponge. We studied the structure/activity relationship of this class of inhibitors on a set of biological responses. To investigate potential targets of these inhibitors, we implemented an affinity chromatography method. The selectivity of Leucettine L41, selected as a representative Leucettine, was studied by in vitro activity and interaction assays of recombinant kinases and affinity chromatography approaches (Leucettines immobilized on agarose beads, competition on non-selective inhibitors). Transcriptomics and proteomics approaches were used to better understand the cellular mechanism of action of Leucettine L41. These approaches confirmed the selectivity of Leucettine L41 for DYRKs and CLKs but also revealed the existence of interesting secondary targets. Leucettine L41 modulates alternative splicing of pre-mRNAs. It displays neuroprotective properties towards glutamate-induced cell death. Leucettines deserve further development as potential therapeutic agents for the treatment of Alzheimer's disease and Down syndrome.

Protéines kinases

Maladie d’Alzheimer

Criblage pharmacologique

Inhibiteurs des tyrosine kinases

Épissage alternatif

Atp

Glutamate

Protéine amyloïde bêta

Differential modulation of T-type voltage gated calcium channels by G-protein coupled receptors.

Hildebrand, Michael Earl

11 1900

T-type voltage-gated calcium (Ca2+) channels play critical roles in controlling neuronal excitability, firing patterns, and synaptic plasticity, although the mechanisms and extent to which T-type Ca2+ channels are modulated by G-protein coupled receptors (GPCRs) remains largely unexplored. Investigations into T-type modulation within native neuronal systems have been complicated by the presence of multiple GPCR subtypes and a lack of pharmacological tools to separate currents generated by the three T-type isoforms; Cav3.1, Cav3.2, and Cav3.3. We hypothesize that specific Cav3 subtypes play unique roles in neuronal physiology due to their differential functional coupling to specific GPCRs. Co-expression of T-type channel subtypes and GPCRs in a heterologous system allowed us to identify the specific interactions between muscarinic acetylcholine (mAChR) or metabotropic glutamate (mGluR) GPCRs and individual Cav3 isoforms. Perforated patch recordings demonstrated that activation of Galpha<q/11>-coupled GPCRs had a strong inhibitory effect on Cav3.3 T-type Ca2+ currents but either no effect or a stimulating effect on Cav3.1 and Cav3.2 peak current amplitudes. Further study of the inhibition of Cav3.3 channels by a specific Galpha<q/11>-coupled mAChR (M1) revealed that this reversible inhibition was associated with a concomitant increase in inactivation kinetics. Pharmacological and genetic experiments indicated that the M1 receptor-mediated inhibition of Cav3.3 occurs specifically through a Galpha<q/11> signaling pathway that interacts with two distinct regions of the Cav3.3 channel. As hypothesized, the potentiation of Cav3.1 channels by a Galpha<q/11>-coupled mGluR (mGluR1) initially characterized in the heterologous system was also observed in a native neuronal system: the cerebellar Purkinje cell (PC). In recordings on PCs within acute cerebellar slices, we demonstrated that the potentiation of Cav3.1 currents by mGluR1 activation is strongest near the threshold of T-type currents, enhancing the excitability of PCs. Ultrafast two-photon Ca2+ imaging demonstrated that the functional coupling between mGluR1 and T-type transients occurs within dendritic spines, where synaptic integration and plasticity occurs. A subset of these experiments utilized physiological synaptic activation and specific mGluR1 antagonists in wild-type and Cav3.1 knock-out mice to show that the mGluR1-mediated potentiation of Cav3.1 T-type currents may promote synapse-specific Ca2+ signaling in response to bursts of excitatory inputs. / Medicine, Faculty of / Graduate

T-type modulation

Calcium channel receptor

Glutamate

Acetylcholine

Purkinje cell

Electrophysiology

Role of Angiotensin II, Glutamate, Nitric Oxide and an Aldosterone-ouabain Pathway in the PVN in Salt-induced Pressor Responses in Rats

Gabor, Alexander

January 2012

High salt intake contributes to the development of hypertension in salt-sensitive humans and animals and the mechanistic causes are poorly understood. In Dahl salt-sensitive (S) but not salt-resistant (R) rats, high salt diet increases cerebrospinal fluid (CSF) [Na+] and activates an aldosterone-mineralocorticoid receptor-epithelial sodium channel-endogenous ouabain (MR-ENaC-EO) neuromodulatory pathway in the brain that enhances the activity of sympatho-excitatory angiotensinergic and glutamatergic pathways, leading to an increase in sympathetic nerve activity (SNA) and blood pressure (BP). We hypothesize that high salt diet in Dahl S rats enhances Ang II release in the paraventricular nucleus (PVN), causing a decrease in local nitric oxide (NO) action and an increase in local glutamate release thereby elevating SNA, BP and heart rate (HR). The present study evaluated the effects of agonists or blockers of MR, ENaC, EO, nitric oxide synthase (NOS) or glutamate and AT1-receptors on the BP and HR responses to acute infusions of Na+ rich aCSF, intracerebroventricularly (icv), or in the PVN of Dahl S, R or Wistar rats or to high salt diet in Dahl S and R rats. In Wistar rats, aldosterone in the PVN enhanced the BP and HR responses to infusion of Na+ rich aCSF in the PVN, but not in the CSF, and only the enhancement was prevented by blockers of MR, ENaC and EO in the PVN. AT1-receptor blockers in the PVN fully blocked the enhancement by aldosterone and the responses to infusion of Na+ rich aCSF icv, or in the PVN. Na+ rich aCSF in the PVN caused larger increases in BP and HR in Dahl S vs. R rats and the responses to Na+ were fully blocked by an AT1-receptor blocker in the PVN. BP and HR responses to a NOS blocker in the PVN were the same, but L-NAME enhanced Na+ effects more in Dahl R than S rats. High salt diet attenuated increases in BP from L-NAME in the PVN of Dahl S but not R rats. AT1 and glutamate receptor blockers candesartan and kynurenate in the PVN decreased BP in Dahl S but not R rats on high salt diet. At the peak BP response to candesartan, kynurenate in the PVN further decreased BP whereas candesartan did not further decrease BP at the peak BP response to kynurenate. Our findings indicate that both an acute increase in CSF [Na+] and high salt intake in Dahl S rats increases AT1-receptor activation and decreases NO action in the PVN thereby contributing to the pressor responses to Na+ and presumably, to dietary salt-induced hypertension. The increased BP response to AT1-receptor activation in the PVN of Dahl S is mediated by enhanced local glutamate receptor activation. An MR-ENaC-EO pathway in the PVN can be functionally active and further studies need to assess its role in Dahl S rats on high salt intake.

Aldosterone

Ouabain

angiotensin II

glutamate

nitric oxide

paraventricular nucleus

hypertension

Dahl salt sensitive rat

The Effect of Ketamine and Glutamate on Proliferation, Differentiation and Migration of Neural Progenitor Cells Derived from the Subventricular Zone and Spinal Cord

Shanmugalingam, Ushananthini

January 2013

During spinal cord injury (SCI), glutamate excitotoxicity and astrocytic scar formation can impede repair. In a preliminary study we found that ketamine, a N-methyl-D-aspartate (NMDA) receptor non-competitive antagonist, can contribute to functional recovery post SCI. Therefore, we investigated the cellular basis for this recovery with respect to neural progenitor cells using an in vitro cell culture model. We examined whether ketamine and glutamate influenced the proliferation, differentiation, and migration of differentiating endogenous neural progenitor cells (NPCs) found in the subventricular zone and spinal cord. Our study illustrates that the post functional recovery may have been due to ketamine’s influence on delaying spinal cord NPCs derived astrocyte maturation and migration while increasing radial glial cell migration. These results are promising since ketamine administration may help alleviate some of the adverse affects glutamate has on the NPCs found in the spinal cord following SCI.

Ketamine

Spinal cord

Subventricular zone

Neural progenitor cells

Glutamate

Proliferation

Differentiation

Migration

The Role of N-Acetyl-Aspartyl-Glutamate (NAAG) in the Modulation of NMDA Receptors

Khacho, Pamela

January 2016

Ischemic strokes cause excessive release of glutamate, leading to overactivation of N-methyl-D-aspartate receptors (NMDARs) and excitotoxicity-induced neuronal death. For this reason, inhibition of NMDARs has been a central focus in identifying mechanisms to avert this extensive neuronal damage. N-acetyl-aspartyl-glutamate (NAAG), the most abundant neuropeptide in the brain, is neuroprotective in ischemic conditions in vivo. Despite this evidence, the exact mechanism underlying its neuroprotection, and more specifically its effect on NMDARs, is currently unknown due to conflicting results in the literature. Here, we uncover a pH-dependent and subunit specific action of NAAG on NMDARs. Using whole-cell electrophysiological recordings on acute hippocampal slices from adult mice and on HEK293 cells, we found that NAAG increases synaptic GluN2A-containing NMDAR excitatory postsynaptic currents (EPSCs), while effectively decreasing extrasynaptic GluN2B-containing NMDAR EPSCs in physiological pH. Intriguingly, the results of our study further show that in low pH, which is a physiological occurrence during ischemia, NAAG depresses GluN2A-containing NMDAR EPSCs and amplifies its inhibitory effect on GluN2B-containing NMDAR EPSCs, as well as upregulates the surface expression of the GluN2A subunit. Altogether, our data demonstrate that NAAG has differential effects on NMDAR function based on subunit composition and extracellular pH levels. These findings suggest that the role of NAAG as a neuroprotective agent during an ischemic stroke is likely mediated by its ability to reduce NMDAR excitation. The inhibitory effect of NAAG on NMDARs and its enhanced function in acidic conditions makes NAAG a prime therapeutic agent for the treatment of ischemic events.

N-acetyl-aspartyl-glutamate (NAAG)

NMDA receptors

Protons

Neuroprotection

Hippocampus

Electrophysiology

The effect of NMDA receptor antagonists and antidepressants on resting state in major depressive disorder

Dutta, Arpan

January 2015

Introduction: The aim of the project was to investigate the effects of antidepressants on brain networks whilst at rest. My hypothesis was that antidepressants work by reversing persistent activity in the brain’s default mode network (DMN). The DMN is implicated in self-reflection and rumination in MDD. The methodologies and results of studies of resting state networks in MDD and the effects of antidepressants are reviewed in the thesis. Increasing evidence implicates glutamate in the action of antidepressant drugs. Whether there are illness related changes in glutamate function is unresolved, largely because of the lack of techniques for assessing it. Ketamine and other NMDA antagonists have improved MDD symptoms within 24 hours though the effects are short lasting. The molecular neural networks involved in ketamine’s putative antidepressant effects are unclear. The thesis reviews the evidence. Much evidence implicates ACC as a site of action of antidepressant effects but whether this is through its regulation of the DMN or other networks is not known. This thesis compares the effect of ketamine and citalopram on ACC-related systems. Method: The thesis combines two systematic reviews of the effects of MDD and antidepressant drugs on i) resting state networks (53 studies) and ii) glutamate neurotransmission (45 studies of clinical efficacy of ketamine). There are two experimental chapters. The first describes investigation into two rapid acting antidepressant drugs acting via glutamate mechanisms. 54 unmedicated cMDD were scanned across two centres on 3T MRI scanners while being infused with placebo (0.5% saline), 0.5mg/kg ketamine or 100mg AZD6765 over 1 hour. fMRI resting state data between drug treatments was compared for the final 25 minutes of the drug infusion and for a 25 minute resting state scan a day later. The second experimental chapter examines whether these effects were shared by citalopram, a standard antidepressant. 67 unmedicated cMDD, rMDD and HC were administered citalopram 7.5mg i.v. and scanned on a 1.5T MRI scanner. In a second study 63 cMDD and HC were administered i.v. citalopram 7.5mg or placebo (0.5% saline). fMRI resting state data for the final 12 ½ minutes following drug infusion was compared. Independent Component Analysis was performed using the Group ICA for fMRI toolbox. The resting component with the highest spatial correlation to the ACC was used. Brain maps of the intensity of the selected component were constructed for each individual. Group averages were calculated and compared using SPM. Regional analysis was performed using Marseille Boite a Regions d'interet. Results: On day 1 AZD6765 significantly increased mean intensity of ACC resting component in the right insula, right IPL and left cingulate gyrus greater than ketamine or placebo. Ketamine increased mean intensity of ACC resting component greater than placebo in the right lentiform nucleus and left mFG. Significantly decreased mean intensity of ACC resting component in the left insula in the AZD6765 group compared to placebo was noted. On day 2 AZD6765 increased mean intensity of ACC resting component greater than ketamine and placebo in the left and right lentiform nuclei. AZD6765 reduced mean intensity of the ACC resting component in the left and right MFG. The first citalopram study revealed reduced mean intensity of ACC resting component in cMDD compared to rMDD and HC in PCC. rMDD had reduced mean intensity of ACC resting component in the precuneus compared to HC. In the second study, citalopram had no effect in HC but normalised precuneus activity in cMDD producing a significant drug x group interaction. Conclusions: The acute antidepressant effects of citalopram are modulated by changes in the bilateral precuneus. The precuneus is central to connectivity with other regions in MDD. It has a prominent role in the DMN and is linked to rumination. The mechanism of the antidepressant effects of AZD6765 is different from those of ketamine and citalopram. The insula, IPL, MFG, cingulate gyrus and lentiform nuclei are all regions implicated in MDD suggesting antidepressant effects. The rapid antidepressant effects of AZD6765 are possibly due to a resetting of the interface between DMN and salience networks.

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