Glutamate Turnover and Energy Metabolism in Brain Injury : Clinical and Experimental Studies

Samuelsson, Carolina

January 2008

<p>During brain activity neurons release the major excitatory transmitter glutamate, which is taken up by astrocytes and converted to glutamine. Glutamine returns to neurons for re-conversion to glutamate. This glutamate-glutamine cycle is energy demanding. Glutamate turnover in injured brain was studied using an animal iron-induced posttraumatic epilepsy model and using neurointensive care data from 33 patients with spontaneous subarachnoid hemorrhage (SAH). Immunoblotting revealed that the functional form of the major astrocytic glutamate uptake protein GLT-1 was decreased 1-5 days following a cortical epileptogenic iron-injection, presumably due to oxidation-induced aggregation. Using microdialysis it was shown that the GLT-1 decrease was associated with increased interstitial glutamate levels and decreased interstitial glutamine levels. The results indicate a possible posttraumatic and post-stroke epileptogenic mechanism. Analysing 3600 microdialysis hours from patients it was found that the interstitial lactate/pyruvate (L/P) ratio correlate with the glutamine/glutamate ratio (r =-0.66). This correlation was as strong as the correlation between L/P and glutamate (r=0.68) and between lactate and glutamate (r=0.65). Pyruvate and glutamine correlated linearly (r=0.52). Energy failure periods, defined as L/P>40, were associated with high interstitial glutamate levels. Glutamine increased or decreased during energy failure periods depending on pyruvate. Energy failure periods were clinically associated with delayed ischemic neurological deficits (DIND) or development of radiologically verified infarcts, confirming that L/P>40 is a pathological microdialysis pattern that can predict ischemic deterioration after SAH. DIND-associated microdialysis patterns were L/P elevations and surges in interstitial glutamine. Glutamine and pyruvate correlated with the cerebral perfusion pressure (r=0.25, r=0.24). Glutamine and the glutamine/glutamate ratio correlated with the intracranial pressure (r=-0.29, r=0.40). Glutamine surges appeared upon substantial lowering of the intracranial pressure by increased cerebrospinal fluid drainage. Increased interstitial glutamine and pyruvate levels may reflect augmented astrocytic glycolysis in recovering brain tissue with increased energy demand due to a high glutamate-glutamine turnover.</p>

Neurosciences

glutamate

glutamine

lactate

pyruvate

microdialysis

GLT-1

energy metabolism

intracranial pressure

cerebral perfusion pressure

subarachnoid hemorrhage

ischemia

epilepsy

Neurovetenskap

Les mécanismes excitotoxiques et le rôle de transporteurs de glutamate dans la physiopathologie des traumatismes crâniens = Excitotoxic mechanisms and the role of glutamate transporters in the pathophysiology of traumatic brain injury

Yi, Jae-Hyuk

January 2006

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Traumatismes crâniens

Percussion hydraulique

Glutamate

Transporteurs du glutamate

GLT-1v

EAAT4

Neurotransmetteurs

Complexin I

Complexin II

Excitotoxicité

Anti-oxydant

Glutamate Turnover and Energy Metabolism in Brain Injury : Clinical and Experimental Studies

Samuelsson, Carolina

January 2008

During brain activity neurons release the major excitatory transmitter glutamate, which is taken up by astrocytes and converted to glutamine. Glutamine returns to neurons for re-conversion to glutamate. This glutamate-glutamine cycle is energy demanding. Glutamate turnover in injured brain was studied using an animal iron-induced posttraumatic epilepsy model and using neurointensive care data from 33 patients with spontaneous subarachnoid hemorrhage (SAH). Immunoblotting revealed that the functional form of the major astrocytic glutamate uptake protein GLT-1 was decreased 1-5 days following a cortical epileptogenic iron-injection, presumably due to oxidation-induced aggregation. Using microdialysis it was shown that the GLT-1 decrease was associated with increased interstitial glutamate levels and decreased interstitial glutamine levels. The results indicate a possible posttraumatic and post-stroke epileptogenic mechanism. Analysing 3600 microdialysis hours from patients it was found that the interstitial lactate/pyruvate (L/P) ratio correlate with the glutamine/glutamate ratio (r =-0.66). This correlation was as strong as the correlation between L/P and glutamate (r=0.68) and between lactate and glutamate (r=0.65). Pyruvate and glutamine correlated linearly (r=0.52). Energy failure periods, defined as L/P&gt;40, were associated with high interstitial glutamate levels. Glutamine increased or decreased during energy failure periods depending on pyruvate. Energy failure periods were clinically associated with delayed ischemic neurological deficits (DIND) or development of radiologically verified infarcts, confirming that L/P&gt;40 is a pathological microdialysis pattern that can predict ischemic deterioration after SAH. DIND-associated microdialysis patterns were L/P elevations and surges in interstitial glutamine. Glutamine and pyruvate correlated with the cerebral perfusion pressure (r=0.25, r=0.24). Glutamine and the glutamine/glutamate ratio correlated with the intracranial pressure (r=-0.29, r=0.40). Glutamine surges appeared upon substantial lowering of the intracranial pressure by increased cerebrospinal fluid drainage. Increased interstitial glutamine and pyruvate levels may reflect augmented astrocytic glycolysis in recovering brain tissue with increased energy demand due to a high glutamate-glutamine turnover.

Neurosciences

glutamate

glutamine

lactate

pyruvate

microdialysis

GLT-1

energy metabolism

intracranial pressure

cerebral perfusion pressure

subarachnoid hemorrhage

ischemia

epilepsy

Neurovetenskap

Análise de viabilidade econômica ambiental para uso da espécie Paricá em vigas laminadas coladas / Analysis environmental economic feasibility for use the Paricá specie in glued-laminated beams

Furtado, Francisco Raphael Cabral

28 July 2014

Made available in DSpace on 2016-12-12T20:12:29Z (GMT). No. of bitstreams: 1 PGEF14MA018.pdf: 2251475 bytes, checksum: 4100f5ef3f222de175d6c1fdf9eb1671 (MD5) Previous issue date: 2014-07-28 / Structural elements in glued laminated timber (GLT) are made mostly with exotic wood from planted forests. However, no studies to evaluate the economic performance of native forest species planted in Brazil for use in GLT. This study aimed to evaluate the economic and environmental viability of native species planted forest, Paricá (Schizolobium amazonicum) for the design of structural parts in GLT. For this, we used a tool called, Business Plan to analyze the production and market for GLT Paricá chain as well as in the manufacture of laboratory GLT beams with this species to determine the coefficients of production cost and sustainability indexes. Based on these studies it was found that the result shows great potential economic profitability, low cost and potential market growth. And the environmental scenario, this product is characterized as sustainable, obtaining the LEED Reference and House, and other seals being possible. In this sense, it is concluded that the beam GLT Paricá product has great market potential for being an innovative and strong environmental appeal producer, thus meeting the demand for products and solutions in the construction of the Brazil market that meet environmental requirements / Elementos estruturais em Madeira Laminada Colada (MLC) são constituídos, em sua maioria, com madeiras exóticas de florestas plantadas. Entretanto, não existem pesquisas que avaliem o desempenho econômico de espécies nativas de floresta plantada no Brasil para uso em MLC. Este trabalho teve como objetivo avaliar a viabilidade econômica e ambiental da espécie nativa de floresta plantada, o Paricá (Schizolobium amazonicum) para a concepção de peças estruturais em MLC. Para tanto, foi empregado, uma ferramenta denominada, Plano de Negócios para a análise da cadeia de produção e mercado para o MLC de Paricá, bem como a confecção em laboratório de vigas MLC com esta espécie para a determinação dos coeficientes de custo de produção e índices de sustentabilidade. Com base nestes estudos verificou-se que o resultado econômico demonstra grande potencial de lucratividade, custos baixos, mercado potencial e em crescimento. E no cenário ambiental, este produto caracteriza-se como sustentável, sendo possível a obtenção dos selo LEED e Referencial Casa, e demais selos. Neste sentido, conclui-se que o produto viga MLC de Paricá tem grande potencial de mercado por ser um produtor inovador e forte apelo ambiental, atendendo desta forma a demanda por produtos e soluções no mercado da construção civil do Brasil que cumpram exigências ambientais

sustentabilidade

inovação

MLC

economia

Paricá (Schizolobium amazonicum)

sustainability

innovation

GLT

economy

Paricá (Schizolobium amazonicum)

CNPQ::CIENCIAS AGRARIAS::AGRONOMIA

GLT-1 over-expression attenuates visceral nociception by pharmacological and gene therapy approaches

Roman, Kenny M.

20 June 2012

No description available.

Biomedical Research

Bladder

Interstitial cystitis

GLT-1

over-expression

EAAT2

Ceftriaxone

AAV9

Colon

Viscera

Chronic visceral pain

Efeitos da nandrolona e da ceftriaxona na homeostasia glutamatérgica : uma busca por mecanismos interativos entre astrócitos e neurônios envolvidos no comportamento agressivo

Rodolphi, Marcelo Salimen

January 2017

Os esteroides anabolizantes androgênicos (EAA) como o decanoato de nandrolona (ND) são hormônios sintéticos derivados da testosterona. Sabe-se que um dos efeitos mais marcantes da administração abusiva destes esteroides é o aumento do comportamento agressivo. Evidências indicam que altas doses de EAA alteram a morfologia e causam hiperativação de sinapses glutamatérgicas, o que se correlaciona com um fenótipo agressivo exacerbado. Fisiologicamente o glutamato é considerado o principal neurotransmissor excitatório no cérebro de mamíferos, entretanto, em níveis elevados, pode causar hiperexcitabilidade neuronal mediada pelos receptores glutamatérgicos ionotrópicos do tipo N-metil-d-aspartato (NMDAr) e, consequentemente alterações no metabolismo mitocondrial. A terminação da sinalização excitatória glutamatérgica é realizada majoritariamente por transportadores existentes em astrócitos. Neste sentido, o transportador astrocitário de glutamato GLT-1 é responsável por mais de 90% da remoção do glutamato da fenda sináptica, contribuindo significativamente, para a manutenção da homeostasis da sinalizacão glutamatérgica. A administração do antibiótico β-lactâmico ceftriaxona (CEF) aumenta a expressão de GLT-1 e diminui a hiperexcitabilidade glutamatérgica, o que poderia potencialmente contrapor mecanismos cerebrais associados ao aumento do fenótipo agressivo induzidos pelo decanoato de nandrolona (ND). Entretanto, estas possíveis interacões moleculares e comportamentais ainda não foram exploradas. Assim, o objetivo primário deste trabalho foi investigar se o aumento da expressão do transportador astrocitário GLT-1 modula mecanismos glutamatérgicos envolvidos na agressividade induzida pelo ND, e a atividade mitocondrial. Para tanto, camundongos CF-1 machos de 60 dias de idade foram divididos em 4 grupos: veículo oleoso (VEH), nandrolona (ND), ceftriaxona (CEF) e nandrolona+ceftriaxona (ND/CEF). A nandrolona foi injetada por via subcutânea (15mg/Kg) por 19 dias. A ceftriaxona (200mg/Kg) ou solução salina foram administradas intraperitonealmente por 5 dias. Após a última injeção foi avaliada a latência para o primeiro ataque e o número de ataques no teste do intruso. Os animais foram sacrificados logo após o teste, e homogeneizados de córtex foram utilizados para imunoquantificação do GLT-1 e da fosforilação da subunidade pNR2Bser1232 do NMDAr. A atividade mitocondrial foi avaliada em sinaptossoma de cérebro total. Os níveis de glutamato foram medidos no líquido cefalorraquidiano. Comparado com o veículo, o tratamento com ND diminuiu significativamente a expressão do GLT-1, aumentou os níveis de glutamato e a expressão da subnidade pNR2Bser1232 o que foi mecanisticamente associado ao aumento do fenótipo agressivo; diminuicão da latência e aumento do número de ataques ao intruso. Ainda, a ND diminuiu o controle respiratório mitocondrial. A administração de CEF aumentou significativamente a expressão do GLT-1 e diminuiu os níveis de glutamato em relação ao grupo ND, enquanto que os níveis de pNR2Bser1232 e a agressividade foram similar ao grupo controle. No grupo ND/CEF o immunoconteúdo de GLT-1 e de pNR2Bser1232, os níveis de glutamato e o fenótipo agressivo, foram significativamente menores que no grupo ND, e similares ao grupo controle. Ainda, a CEF foi capaz de atenuar o prejuízo no controle respiratório mitocondrial causado pela ND. Nossos resultados demonstram que a interação bidirecional entre o transportador astrocitário GLT-1 e a subunidade pNR2Bser1232 neuronal mediada pelo glutamato, exercem um impacto regulatório no fenótipo agressivo induzido pela ND, e no controle respiratório mitocondrial. Desta maneira, este modelo reforça a importância da homeostasia funcional da sinapse tripartide glutamatérgica no fenótipo agressivo. / Anabolic androgenic steroids (AAS) such as nandrolone decanoate (ND) are synthetic hormones derived from testosterone. It is known that one of the most important adverse effects of abusive administration of these steroids is the increase in aggressive behavior. Evidence indicates that high doses of AAS alter morphology and cause hyperactivation of glutamatergic synapses which correlates with an aggressive exacerbated phenotype. Physiologically, glutamate is considered the main excitatory neurotransmitter in the mammalian brain. At high glutamate levels, occurs neuronal hyperexcitability mainly trhough the ionotropic N-methyl-d-aspartate (NMDAr) type of glutamatergic receptors and, consequently, changes in mitochondrial metabolism. Existing transporters in astrocytes predominantly perform the termination of glutamatergic excitatory signaling. In this sense, the GLT-1 glutamate astrocytic transporter is responsible for more than 90% of glutamate removal from the synaptic cleft, contributing significantly to the maintenance of glutamatergic signaling homeostasis. Administration of the β-lactam antibiotic ceftriaxone (CEF) increases GLT-1 expression and decreases glutamatergic hyperexcitability, which could potentially counteract brain mechanisms associated to increased aggressive phenotype mediated by nandrolone decanoate (ND). However, a possible molecular and behavioral interaction has not yet been explored in context. Thus, the primary objective of this work was to investigate whether increased expression of the GLT-1 astrocyte transporter modulates the glutamatergic mechanisms involved in ND-induced aggressive phenotype, and mitochondrial activity. Sixty-day-old male CF-1 mice were divided into 4 groups: oil vehicle (VEH), nandrolone (ND), ceftriaxone (CEF) and nandrolone + ceftriaxone (ND / CEF). Nandrolone was injected subcutaneously (15mg / kg) for 19 days. Ceftriaxone (200mg / kg) or saline solution were administered intraperitoneally for 5 days. After the last injection, the latency for the first attack and the number of attacks on the intruder test were evaluated. The animals were sacrificed after the test, and homogeinized cortex were used for immunoquantification of GLT-1 and phosphorylation of the NMDAr pNR2Bser1232 subunit. Mitochondrial activity was evaluated in total brain sinaptossomes. Glutamate levels were measured in the cerebrospinal fluid. Compared to the vehicle group, treatment with ND significantly decreased the expression of GLT-1, increased glutamate levels and expression of the pNR2Bser1232 which was mechanistically associated with an increase in the aggressive phenotype; decrease in the latency and increase in the number of attacks. Also, ND decreased mitochondrial respiratory control. Administration of CEF significantly increased GLT-1 expression and decreased glutamate levels relative to the ND group, whereas pNR2Bser1232 levels and aggressive phenotype were similar to the control group. In the ND / CEF group the expression of GLT-1 and pNR2Bser1232, glutamate levels and aggressive phenotype were significantly lower than in the ND group, and similar to the control group. Furthermore, CEF was able to attenuate the alteration in the mitochondrial respiratory control caused by ND. Our results demonstrated that the levels of glutamate astrocytic transporter GLT-1 and pNR2Bser1232 are important mechanism behind the increased aggressive phenotype induced by ND, and decreased mitochondrial respiratory control. Also, this model reinforces the importance of glutamate levels and astrocytic molecular targets in the regulation of the aggressive phenotype.

Agressão

Anabolizantes

Androgênios

Glutamato

Receptores de N-metil-D-aspartato

Mitocôndrias

Nandrolona

Ceftriaxona

Esteroides

Sistema glutamatérgico

Androgenic anabolic steroids

Glutamate

Ceftriaxone

GLT-1

NMDAr

Mitochondria

Applications of Lexicographic Breadth-first Search to Modular Decomposition, Split Decomposition, and Circle Graphs

Tedder, Marc

31 August 2011

This thesis presents the first sub-quadratic circle graph recognition algorithm, and develops improved algorithms for two important hierarchical decomposition schemes: modular decomposition and split decomposition. The modular decomposition algorithm results from unifying two different approaches previously employed to solve the problem: divide-and-conquer and factorizing permutations. It runs in linear-time, and is straightforward in its understanding, correctness, and implementation. It merely requires a collection of trees and simple traversals of these trees. The split-decomposition algorithm is similar in being straightforward in its understanding and correctness. An efficient implementation of the algorithm is described that uses the union-find data-structure. A novel charging argument is used to prove the running-time. The algorithm is the first to use the recent reformulation of split decomposition in terms of graph-labelled trees. This facilitates its extension to circle graph recognition. In particular, it allows us to efficiently apply a new lexicographic breadth-first search characterization of circle graphs developed in the thesis. Lexicographic breadth-first search is additionally responsible for the efficiency of the split decomposition algorithm, and contributes to the simplicity of the modular decomposition algorithm.

Modular Decomposition

Split Decomposition

Circle Graphs

Lexicographic Breadth-First Search

LBFS

LexBFS

Charging argument

Amortized analysis

Aggregate analysis

Recognition

Graph Labelled Trees

GLT

0984

Applications of Lexicographic Breadth-first Search to Modular Decomposition, Split Decomposition, and Circle Graphs

Tedder, Marc

31 August 2011

This thesis presents the first sub-quadratic circle graph recognition algorithm, and develops improved algorithms for two important hierarchical decomposition schemes: modular decomposition and split decomposition. The modular decomposition algorithm results from unifying two different approaches previously employed to solve the problem: divide-and-conquer and factorizing permutations. It runs in linear-time, and is straightforward in its understanding, correctness, and implementation. It merely requires a collection of trees and simple traversals of these trees. The split-decomposition algorithm is similar in being straightforward in its understanding and correctness. An efficient implementation of the algorithm is described that uses the union-find data-structure. A novel charging argument is used to prove the running-time. The algorithm is the first to use the recent reformulation of split decomposition in terms of graph-labelled trees. This facilitates its extension to circle graph recognition. In particular, it allows us to efficiently apply a new lexicographic breadth-first search characterization of circle graphs developed in the thesis. Lexicographic breadth-first search is additionally responsible for the efficiency of the split decomposition algorithm, and contributes to the simplicity of the modular decomposition algorithm.

Modular Decomposition

Split Decomposition

Circle Graphs

Lexicographic Breadth-First Search

LBFS

LexBFS

Charging argument

Amortized analysis

Aggregate analysis

Recognition

Graph Labelled Trees

GLT

0984

Efeitos da nandrolona e da ceftriaxona na homeostasia glutamatérgica : uma busca por mecanismos interativos entre astrócitos e neurônios envolvidos no comportamento agressivo

Rodolphi, Marcelo Salimen

January 2017

Os esteroides anabolizantes androgênicos (EAA) como o decanoato de nandrolona (ND) são hormônios sintéticos derivados da testosterona. Sabe-se que um dos efeitos mais marcantes da administração abusiva destes esteroides é o aumento do comportamento agressivo. Evidências indicam que altas doses de EAA alteram a morfologia e causam hiperativação de sinapses glutamatérgicas, o que se correlaciona com um fenótipo agressivo exacerbado. Fisiologicamente o glutamato é considerado o principal neurotransmissor excitatório no cérebro de mamíferos, entretanto, em níveis elevados, pode causar hiperexcitabilidade neuronal mediada pelos receptores glutamatérgicos ionotrópicos do tipo N-metil-d-aspartato (NMDAr) e, consequentemente alterações no metabolismo mitocondrial. A terminação da sinalização excitatória glutamatérgica é realizada majoritariamente por transportadores existentes em astrócitos. Neste sentido, o transportador astrocitário de glutamato GLT-1 é responsável por mais de 90% da remoção do glutamato da fenda sináptica, contribuindo significativamente, para a manutenção da homeostasis da sinalizacão glutamatérgica. A administração do antibiótico β-lactâmico ceftriaxona (CEF) aumenta a expressão de GLT-1 e diminui a hiperexcitabilidade glutamatérgica, o que poderia potencialmente contrapor mecanismos cerebrais associados ao aumento do fenótipo agressivo induzidos pelo decanoato de nandrolona (ND). Entretanto, estas possíveis interacões moleculares e comportamentais ainda não foram exploradas. Assim, o objetivo primário deste trabalho foi investigar se o aumento da expressão do transportador astrocitário GLT-1 modula mecanismos glutamatérgicos envolvidos na agressividade induzida pelo ND, e a atividade mitocondrial. Para tanto, camundongos CF-1 machos de 60 dias de idade foram divididos em 4 grupos: veículo oleoso (VEH), nandrolona (ND), ceftriaxona (CEF) e nandrolona+ceftriaxona (ND/CEF). A nandrolona foi injetada por via subcutânea (15mg/Kg) por 19 dias. A ceftriaxona (200mg/Kg) ou solução salina foram administradas intraperitonealmente por 5 dias. Após a última injeção foi avaliada a latência para o primeiro ataque e o número de ataques no teste do intruso. Os animais foram sacrificados logo após o teste, e homogeneizados de córtex foram utilizados para imunoquantificação do GLT-1 e da fosforilação da subunidade pNR2Bser1232 do NMDAr. A atividade mitocondrial foi avaliada em sinaptossoma de cérebro total. Os níveis de glutamato foram medidos no líquido cefalorraquidiano. Comparado com o veículo, o tratamento com ND diminuiu significativamente a expressão do GLT-1, aumentou os níveis de glutamato e a expressão da subnidade pNR2Bser1232 o que foi mecanisticamente associado ao aumento do fenótipo agressivo; diminuicão da latência e aumento do número de ataques ao intruso. Ainda, a ND diminuiu o controle respiratório mitocondrial. A administração de CEF aumentou significativamente a expressão do GLT-1 e diminuiu os níveis de glutamato em relação ao grupo ND, enquanto que os níveis de pNR2Bser1232 e a agressividade foram similar ao grupo controle. No grupo ND/CEF o immunoconteúdo de GLT-1 e de pNR2Bser1232, os níveis de glutamato e o fenótipo agressivo, foram significativamente menores que no grupo ND, e similares ao grupo controle. Ainda, a CEF foi capaz de atenuar o prejuízo no controle respiratório mitocondrial causado pela ND. Nossos resultados demonstram que a interação bidirecional entre o transportador astrocitário GLT-1 e a subunidade pNR2Bser1232 neuronal mediada pelo glutamato, exercem um impacto regulatório no fenótipo agressivo induzido pela ND, e no controle respiratório mitocondrial. Desta maneira, este modelo reforça a importância da homeostasia funcional da sinapse tripartide glutamatérgica no fenótipo agressivo. / Anabolic androgenic steroids (AAS) such as nandrolone decanoate (ND) are synthetic hormones derived from testosterone. It is known that one of the most important adverse effects of abusive administration of these steroids is the increase in aggressive behavior. Evidence indicates that high doses of AAS alter morphology and cause hyperactivation of glutamatergic synapses which correlates with an aggressive exacerbated phenotype. Physiologically, glutamate is considered the main excitatory neurotransmitter in the mammalian brain. At high glutamate levels, occurs neuronal hyperexcitability mainly trhough the ionotropic N-methyl-d-aspartate (NMDAr) type of glutamatergic receptors and, consequently, changes in mitochondrial metabolism. Existing transporters in astrocytes predominantly perform the termination of glutamatergic excitatory signaling. In this sense, the GLT-1 glutamate astrocytic transporter is responsible for more than 90% of glutamate removal from the synaptic cleft, contributing significantly to the maintenance of glutamatergic signaling homeostasis. Administration of the β-lactam antibiotic ceftriaxone (CEF) increases GLT-1 expression and decreases glutamatergic hyperexcitability, which could potentially counteract brain mechanisms associated to increased aggressive phenotype mediated by nandrolone decanoate (ND). However, a possible molecular and behavioral interaction has not yet been explored in context. Thus, the primary objective of this work was to investigate whether increased expression of the GLT-1 astrocyte transporter modulates the glutamatergic mechanisms involved in ND-induced aggressive phenotype, and mitochondrial activity. Sixty-day-old male CF-1 mice were divided into 4 groups: oil vehicle (VEH), nandrolone (ND), ceftriaxone (CEF) and nandrolone + ceftriaxone (ND / CEF). Nandrolone was injected subcutaneously (15mg / kg) for 19 days. Ceftriaxone (200mg / kg) or saline solution were administered intraperitoneally for 5 days. After the last injection, the latency for the first attack and the number of attacks on the intruder test were evaluated. The animals were sacrificed after the test, and homogeinized cortex were used for immunoquantification of GLT-1 and phosphorylation of the NMDAr pNR2Bser1232 subunit. Mitochondrial activity was evaluated in total brain sinaptossomes. Glutamate levels were measured in the cerebrospinal fluid. Compared to the vehicle group, treatment with ND significantly decreased the expression of GLT-1, increased glutamate levels and expression of the pNR2Bser1232 which was mechanistically associated with an increase in the aggressive phenotype; decrease in the latency and increase in the number of attacks. Also, ND decreased mitochondrial respiratory control. Administration of CEF significantly increased GLT-1 expression and decreased glutamate levels relative to the ND group, whereas pNR2Bser1232 levels and aggressive phenotype were similar to the control group. In the ND / CEF group the expression of GLT-1 and pNR2Bser1232, glutamate levels and aggressive phenotype were significantly lower than in the ND group, and similar to the control group. Furthermore, CEF was able to attenuate the alteration in the mitochondrial respiratory control caused by ND. Our results demonstrated that the levels of glutamate astrocytic transporter GLT-1 and pNR2Bser1232 are important mechanism behind the increased aggressive phenotype induced by ND, and decreased mitochondrial respiratory control. Also, this model reinforces the importance of glutamate levels and astrocytic molecular targets in the regulation of the aggressive phenotype.

Agressão

Anabolizantes

Androgênios

Glutamato

Receptores de N-metil-D-aspartato

Mitocôndrias

Nandrolona

Ceftriaxona

Esteroides

Sistema glutamatérgico

Androgenic anabolic steroids

Glutamate

Ceftriaxone

GLT-1

NMDAr

Mitochondria

Efeitos da nandrolona e da ceftriaxona na homeostasia glutamatérgica : uma busca por mecanismos interativos entre astrócitos e neurônios envolvidos no comportamento agressivo

Rodolphi, Marcelo Salimen

January 2017

Os esteroides anabolizantes androgênicos (EAA) como o decanoato de nandrolona (ND) são hormônios sintéticos derivados da testosterona. Sabe-se que um dos efeitos mais marcantes da administração abusiva destes esteroides é o aumento do comportamento agressivo. Evidências indicam que altas doses de EAA alteram a morfologia e causam hiperativação de sinapses glutamatérgicas, o que se correlaciona com um fenótipo agressivo exacerbado. Fisiologicamente o glutamato é considerado o principal neurotransmissor excitatório no cérebro de mamíferos, entretanto, em níveis elevados, pode causar hiperexcitabilidade neuronal mediada pelos receptores glutamatérgicos ionotrópicos do tipo N-metil-d-aspartato (NMDAr) e, consequentemente alterações no metabolismo mitocondrial. A terminação da sinalização excitatória glutamatérgica é realizada majoritariamente por transportadores existentes em astrócitos. Neste sentido, o transportador astrocitário de glutamato GLT-1 é responsável por mais de 90% da remoção do glutamato da fenda sináptica, contribuindo significativamente, para a manutenção da homeostasis da sinalizacão glutamatérgica. A administração do antibiótico β-lactâmico ceftriaxona (CEF) aumenta a expressão de GLT-1 e diminui a hiperexcitabilidade glutamatérgica, o que poderia potencialmente contrapor mecanismos cerebrais associados ao aumento do fenótipo agressivo induzidos pelo decanoato de nandrolona (ND). Entretanto, estas possíveis interacões moleculares e comportamentais ainda não foram exploradas. Assim, o objetivo primário deste trabalho foi investigar se o aumento da expressão do transportador astrocitário GLT-1 modula mecanismos glutamatérgicos envolvidos na agressividade induzida pelo ND, e a atividade mitocondrial. Para tanto, camundongos CF-1 machos de 60 dias de idade foram divididos em 4 grupos: veículo oleoso (VEH), nandrolona (ND), ceftriaxona (CEF) e nandrolona+ceftriaxona (ND/CEF). A nandrolona foi injetada por via subcutânea (15mg/Kg) por 19 dias. A ceftriaxona (200mg/Kg) ou solução salina foram administradas intraperitonealmente por 5 dias. Após a última injeção foi avaliada a latência para o primeiro ataque e o número de ataques no teste do intruso. Os animais foram sacrificados logo após o teste, e homogeneizados de córtex foram utilizados para imunoquantificação do GLT-1 e da fosforilação da subunidade pNR2Bser1232 do NMDAr. A atividade mitocondrial foi avaliada em sinaptossoma de cérebro total. Os níveis de glutamato foram medidos no líquido cefalorraquidiano. Comparado com o veículo, o tratamento com ND diminuiu significativamente a expressão do GLT-1, aumentou os níveis de glutamato e a expressão da subnidade pNR2Bser1232 o que foi mecanisticamente associado ao aumento do fenótipo agressivo; diminuicão da latência e aumento do número de ataques ao intruso. Ainda, a ND diminuiu o controle respiratório mitocondrial. A administração de CEF aumentou significativamente a expressão do GLT-1 e diminuiu os níveis de glutamato em relação ao grupo ND, enquanto que os níveis de pNR2Bser1232 e a agressividade foram similar ao grupo controle. No grupo ND/CEF o immunoconteúdo de GLT-1 e de pNR2Bser1232, os níveis de glutamato e o fenótipo agressivo, foram significativamente menores que no grupo ND, e similares ao grupo controle. Ainda, a CEF foi capaz de atenuar o prejuízo no controle respiratório mitocondrial causado pela ND. Nossos resultados demonstram que a interação bidirecional entre o transportador astrocitário GLT-1 e a subunidade pNR2Bser1232 neuronal mediada pelo glutamato, exercem um impacto regulatório no fenótipo agressivo induzido pela ND, e no controle respiratório mitocondrial. Desta maneira, este modelo reforça a importância da homeostasia funcional da sinapse tripartide glutamatérgica no fenótipo agressivo. / Anabolic androgenic steroids (AAS) such as nandrolone decanoate (ND) are synthetic hormones derived from testosterone. It is known that one of the most important adverse effects of abusive administration of these steroids is the increase in aggressive behavior. Evidence indicates that high doses of AAS alter morphology and cause hyperactivation of glutamatergic synapses which correlates with an aggressive exacerbated phenotype. Physiologically, glutamate is considered the main excitatory neurotransmitter in the mammalian brain. At high glutamate levels, occurs neuronal hyperexcitability mainly trhough the ionotropic N-methyl-d-aspartate (NMDAr) type of glutamatergic receptors and, consequently, changes in mitochondrial metabolism. Existing transporters in astrocytes predominantly perform the termination of glutamatergic excitatory signaling. In this sense, the GLT-1 glutamate astrocytic transporter is responsible for more than 90% of glutamate removal from the synaptic cleft, contributing significantly to the maintenance of glutamatergic signaling homeostasis. Administration of the β-lactam antibiotic ceftriaxone (CEF) increases GLT-1 expression and decreases glutamatergic hyperexcitability, which could potentially counteract brain mechanisms associated to increased aggressive phenotype mediated by nandrolone decanoate (ND). However, a possible molecular and behavioral interaction has not yet been explored in context. Thus, the primary objective of this work was to investigate whether increased expression of the GLT-1 astrocyte transporter modulates the glutamatergic mechanisms involved in ND-induced aggressive phenotype, and mitochondrial activity. Sixty-day-old male CF-1 mice were divided into 4 groups: oil vehicle (VEH), nandrolone (ND), ceftriaxone (CEF) and nandrolone + ceftriaxone (ND / CEF). Nandrolone was injected subcutaneously (15mg / kg) for 19 days. Ceftriaxone (200mg / kg) or saline solution were administered intraperitoneally for 5 days. After the last injection, the latency for the first attack and the number of attacks on the intruder test were evaluated. The animals were sacrificed after the test, and homogeinized cortex were used for immunoquantification of GLT-1 and phosphorylation of the NMDAr pNR2Bser1232 subunit. Mitochondrial activity was evaluated in total brain sinaptossomes. Glutamate levels were measured in the cerebrospinal fluid. Compared to the vehicle group, treatment with ND significantly decreased the expression of GLT-1, increased glutamate levels and expression of the pNR2Bser1232 which was mechanistically associated with an increase in the aggressive phenotype; decrease in the latency and increase in the number of attacks. Also, ND decreased mitochondrial respiratory control. Administration of CEF significantly increased GLT-1 expression and decreased glutamate levels relative to the ND group, whereas pNR2Bser1232 levels and aggressive phenotype were similar to the control group. In the ND / CEF group the expression of GLT-1 and pNR2Bser1232, glutamate levels and aggressive phenotype were significantly lower than in the ND group, and similar to the control group. Furthermore, CEF was able to attenuate the alteration in the mitochondrial respiratory control caused by ND. Our results demonstrated that the levels of glutamate astrocytic transporter GLT-1 and pNR2Bser1232 are important mechanism behind the increased aggressive phenotype induced by ND, and decreased mitochondrial respiratory control. Also, this model reinforces the importance of glutamate levels and astrocytic molecular targets in the regulation of the aggressive phenotype.

Agressão

Anabolizantes

Androgênios

Glutamato

Receptores de N-metil-D-aspartato

Mitocôndrias

Nandrolona

Ceftriaxona

Esteroides

Sistema glutamatérgico

Androgenic anabolic steroids

Glutamate

Ceftriaxone

GLT-1

NMDAr

Mitochondria