Global ETD Search

41	The Interferon Response Dampens the Usutu Virus Infection-Associated Increase in Glycolysis Wald, Maria Elisabeth, Sieg, Michael, Schilling, Erik, Binder, Marco, Vahlenkamp, Thomas Wilhelm, Claus, Claudia 03 April 2023 (has links) The mosquito-borne Usutu virus (USUV) is a zoonotic flavivirus and an emerging pathogen. So far therapeutical options or vaccines are not available in human and veterinary medicine. The bioenergetic profile based on extracellular flux analysis revealed an USUV infection-associated significant increase in basal and stressed glycolysis on Vero and with a tendency for basal glycolysis on the avian cell line TME-R derived from Eurasian blackbirds. On both cell lines this was accompanied by a significant drop in the metabolic potential of glycolysis. Moreover, glycolysis contributed to production of virus progeny, as inhibition of glycolysis with 2-deoxy-D-glucose reduced virus yield on Vero by one log10 step. Additionally, the increase in glycolysis observed on Vero cells after USUV infection was lost after the addition of exogenous type I interferon (IFN) b. To further explore the contribution of the IFN response pathway to the impact of USUV on cellular metabolism, USUV infection was characterized on human A549 respiratory cells with a knockout of the type I IFN receptor, either solely or together with the receptor of type III IFN. Notably, only the double knockout of types I and III IFN receptor increased permissiveness to USUV and supported viral replication together with an alteration of the glycolytic activity, namely an increase in basal glycolysis to an extent that a further increase after injection of metabolic stressors during extracellular flux analysis was not noted. This study provides evidence for glycolysis as a possible target for therapeutic intervention of USUV replication. Moreover, presented data highlight type I and type III IFN system as a determinant for human host cell permissiveness and for the infection-associated impact on glycolysis. info:eu-repo/classification/ddc/610 ddc:610
42	Methanocaldococcus jannaschii and the Recycling of S-adenosyl-L-methionine Miller, Danielle Virginia 25 April 2017 (has links) S-Adenosyl-L-methionine (SAM) is an essential metabolite for all domains of life. SAM- dependent reactions result in three major metabolites: S-adenosyl-L-homocysteine (SAH), methylthioadenosine (MTA), and 5'-deoxyadenosine (5'-dA). Each of these has been demonstrated to be feedback inhibitors of SAM dependent enzymes. Thus, each metabolite has a pathway to prevent inhibition through the salvage of nucleoside and ribose moieties. However, these salvage pathways are not universally conserved. In the anaerobic archaeal organism Methanocaldococcus jannaschii, the salvage of SAH, MTA, and 5'-dA, proceeds first via deamination to S-inosylhomocysteine (SIH), methylthioinosine (MTI), and 5'-deoxyinosine (5'-dI). The annotated SAH hydrolase from M. jannaschii is specific for SIH and the hydrolyzed product homocysteine is then methylated to methionine. The salvage of MTA is known to proceed through the methionine salvage pathway, however, an anaerobic route for the salvage of MTA is still mostly unknown. Only two enzymes from the methionine salvage pathway are annotated in M. jannaschii's proteome, a methylthioinosine phosphorylase (MTIP) and methylthioribose 1-phosphate isomerase (MTRI). These enzymes were shown to produce methylthioribulose 1-phosphate from MTI. Unfortunately, how MTI is converted to either 2-keto-(4-methylthio)butyrate or methionine remains unknown. The two enzymes involved in the salvage of MTI have also been demonstrated to be involved in the salvage of 5'-dI. Interestingly, there is little information on how 5'-dA or 5'-dI is recycled and it is proposed here to be the source of deoxysugars for the production methylglyoxal, a precursor for aromatic amino acids. MTIP and MTRI were demonstrated to produce 5-deoxyribulose 1-phosphate from 5'-dI. Additionally, two enzymes annotated as part of the pentose phosphate pathway, ribulose 5-phosphate 3-epimerase and transketolase, were able to convert 5-deoxyribulose 1-phosphate to lactaldehyde. Lactaldehyde was then reduced to methylglyoxal by an essential enzyme in methanogenesis, N5, N10-methylenetetahydromethanopterin reductase with NADPH. These results further demonstrate a novel route for the biosynthesis of methylglyoxal. Lastly, hypoxanthine produced from phosphorolysis of inosine, MTI, and 5'-dI was demonstrated to be reincorporated through the hypoxanthine/guanine phosphoribosyltransferase (Hpt) to IMP. Together these reactions represent novel pathways for the salvage of the SAM nucleoside and ribose moieties in M. jannaschii. / Ph. D. / In the anaerobic methanogenic archaea <i>Methanocaldococcus jannaschii</i> traditional metabolic pathways are often missing or incomplete and are substituted by unique ones. <i>M. jannaschii</i> is deeply rooted on the phylogenetic tree and serves as a model organism for the study of primitive metabolism. Discussed here are the recycling pathways of the essential cofactor S-adenosyl-L-methionine (SAM). SAM recycling pathways in <i>Archaea</i> have not been investigated prior to this work. Two of the universal pathways responsible for recycling SAM to methionine were found to be modified and unique. A third pathway was proposed that would be responsible for generating an essential precursor for the biosynthesis of aromatic amino acids. The identification of the pathways and enzymes from <i>M. jannaschii</i> will give insight into the biochemical reactions that were occurring when life originated. Eight enzymes are discussed here that demonstrate how the recycling pathways in <i>M. jannaschii</i> are interconnected and the enzymes are shared between them. This work further describes the importance of understanding these unique microorganisms and the metabolic pathways they utilize to help understand primitive life. S-adenosyl-L-methionine SAM recycling 6-deoxy-5-ketofructose 1-phosphate aromatic amino acids methionine salvage 5'-deoxyadenosine S-adenosylhomoysteine methylthioadenosine
43	Synthèse de nouveaux analogues de la Fosmidomycine : inhibiteurs potentiels de l'enzyme 1-Deoxy-D-Xylulose-5-Phosphate Reductoisomerase (DXR) / Targeting of the 1-Deoxy-D-Xylulose-5-Phosphate Reductoisomerase (DXR) enzyme : design and synthesis of new Fosmidomycin analogues as potential herbicides Midrier, Camille 16 December 2010 (has links) La synthèse enzymatique de terpénoides chez les mammifères provient de la voie mevalonique. Récemment une voie différente a été découverte et s'est révélée être prépondérante pour de nombreux organismes comme les plantes et bactéries. L'identification d'un inhibiteur de cette cascade enzymatique permettrait le développement d'une nouvelle famille d'herbicide. Les caractéristiques de la 1-déoxy-D-xylulose 5-phosphate réductoisomérase (DXR) font de cette enzyme très spécifique une cible pour la synthèse de nouveaux composés. La Fosmidomycine ainsi que son analogue acétylé le plus proche, FR-900098 restent des références pour l'inhibition de la DXR. Dans ce contexte, l'ensemble des molécules décrites dans la littérature en tant qu'inhibiteurs a été classé en fonction des modifications apportées sur le substrat naturel ou la Fosmidomycine. A partir de l'ensemble de ces informations, cinq familles ont été synthétisées pour trouver un nouveau motif complexant. Pour deux d'entre elles, le squelette de base contient un acide phosphonique et un acide phosphinique sur lequel a été introduit la diversité moléculaire grâce aux réactions de Pudovik et de couplage pallado-catalysé. Les autres motifs complexant originaux sont constitués d'une fonction carbonyle et d'un hétérocycle en α ou β. Après optimisation de la synthèse des précurseurs, la diversité a été introduite à l'aide, par exemple, d'une réaction de trois composantes permettant la préparation d'hétérocycle. Enfin, deux modifications ont été faites sur le bras espaceur : l'introduction d'atomes de fluor pour modifier les propriétés physicochimiques ou d'un atome d'azote, point d'attache de nouveaux groupements. / The non-mevalonate pathway is widely found in higher plants and in many eubacteria, including pathogenic ones, but not in mammals. Identifying a non-mevalonate pathway inhibitor would greatly contribute to the search for new herbicides. The unique properties of 1-Deoxy-D-xylulose 5-phosphate reductoisomerase make it remarkable and rational target for drug design. The phosphonohydroxamic acid Fosmidomycin, which acts through inhibition of DXR, is a natural compound produced in the fermentation of Streptomyces and still remains, with its N-acetyl homologue FR900098, one of the most active compounds. First of all, the enzyme and all the potential inhibitors tested in literature were classified in order to understand the global quest for therapeutically useful compounds. In this context, we designed and synthesized five different families of Fosmidomycin analogues containing a new chelating unit. Two targets molecules families bearing a phosphinophonic acid as common core were imagined. Divergent approach allowed the introduction of the chemical diversity thank to powerful pallado-catalyzed coupling reaction. The other families containing carbonyl group and heterocycle in α‐ and β‐position were regarded as highly potent complexing units. Chemical diversity was introduced mainly at the end of the synthesis. For one of them convergent ring formation using three-components reaction was developed. Finally two modifications of the Fosmidomycin linker were performed by the introduction of fluorine atoms on the parent structure as well as the replacement of a carbon by a nitrogen atom in order to create a new point of modifications. Herbicide Fosmidomycine Organophosphorés Addition radicalaire Couplage par les métaux de transition Herbicide Fosmidomycin Organophosphorus compounds Radical Chemistry Transition metal coupling
44	Targeting Infectious Disease : Structural and functional studies of proteins from two RNA viruses and Mycobacterium tuberculosis Jansson, Anna M. January 2013 (has links) The recent emergence of a number of new viral diseases as well as the re-emergence of tuberculosis (TB), indicate an urgent need for new drugs against viral and bacterial infections. Coronavirus nsp1 has been shown to induce suppression of host gene expression and interfere with host immune response. However, the mechanism behind this is currently unknown. Here we present the first nsp1 structure from an alphacoronavirus, Transmissible gastroenteritis virus (TGEV) nsp1. Contrary to previous speculation, the TGEV nsp1 structure clearly shows that alpha- and betacoronavirus nsp1s have a common evolutionary origin. However, differences in conservation, shape and surface electrostatics indicate that the mechanism for nsp1-induced suppression of host mRNA translation is likely to be different in the alpha- and betacoronavirus genera. The Modoc virus is a neuroinvasive rodent virus with similar pathology as flavivirus encephalitis in humans. The flaviviral methyltransferase catalyses the two methylations required to complete 5´ mRNA capping, essential for mRNA stability and translation. The structure of the Modoc NS5 methyltransferase domain was determined in complex with its cofactor S-adenosyl-L-methionine. The observed methyltransferase conservation between Modoc and other flaviviral branches, indicates that it may be possible to identify drugs that target a range of flaviviruses and supports the use of Modoc virus as a model for general flaviviral studies. 1-deoxy-D-xylulose 5-phosphate reductoisomerase (DXR) is part of the methylerythritol phosphate (MEP) pathway that produces essential precursors for isoprenoid biosynthesis. This pathway is used by a number of pathogens, including Mycobacterium tuberculosis and Plasmodium falciparum, but it is not present in humans. Using a structure-based approach, we designed a number of MtDXR inhibitors, including a novel fosmidomycin-analogue that exhibited improved activity against P.falciparum in an in vitro blood cell growth assay. The approach also allowed the first design of an inhibitor that bridge both DXR substrate and co-factor binding sites, providing a stepping-stone for further optimization. RNA virus coronavirus alphacoronavirus nsp1 TGEV flavivirus Modoc virus NS5 methyltransferase mRNA capping Mycobacterium tuberculosis tuberculosis DXR fosmidomycin analogues MEP pathway drug development xray-crystallography
45	Characterisation and Control of 3-Deoxy-D-arabino-heptulosonate 7-phosphate Synthase from Geobacillus sp Othman, Mohamad January 2014 (has links) 3-Deoxy-D-arabino heptulosonate 7-phosphate synthase (DAH7PS) catalyses the first step of the shikimate pathway, responsible for the biosynthesis of aromatic amino acids. This pathway is found in microorganisms, plants and apicomplexan parasites and its absence in mammals makes it a viable target for antimicrobial drug design. DAH7PS enzymes differ in the regulatory machinery that decorates the catalytic (β/α)8 barrel. Some DAH7PS enzymes are fused to chorismate mutase (CM), another enzyme in the shikimate pathway. This fusion protein is allosterically regulated by chorismate (CA) or prephenate (PA), the precursor of tyrosine and phenylalanine. It has been suggested that DAH7PS enzymes evolved these extensions to the core barrel for the sole purpose of regulation. Geobacillus sp DAH7PS (GspDAH7PSWT) is a thermophilic type Iβ DAH7PS enzyme with an N-terminal CM domain fused through a linker region. This thesis describes the functional characterisation work carried out on GspDAH7PSWT, in attempt to help determine how DAH7PS enzymes evolved such diverse methods of regulation. Chapter 2 describes the functional characterisation work carried out on the catalytic and regulatory domains of GspDAH7PSWT. The enzyme demonstrated both DAH7PS and CM activities with the DAH7PS domain determined to be metal dependent and most activated by Cd2+. PA completely inhibited the catalytic activity of GspDAH7PSWT, and AUC demonstrated an equilibrium exists between the dimeric and tetrameric quaternary states of the enzyme in solution. Chapter 3 describes the domain truncation of GspDAH7PSWT carried out at the linker region in order to obtain two separate protein domains, the catalytic domain lacking the N-terminal domain (GspDAH7PSDAH7PS) and the regulatory domain without the catalytic domain (GspDAH7PSCM). Both variants were fully characterised, and information obtained from each domain was compared to the respective catalytic and regulatory domains of the wild-type enzyme, which was also characterised. Like GspDAH7PSWT, GspDAH7PSDAH7PS showed greatest activation in the presence of Cd2+, with other metals having varying effects on activation rates and stability of the enzyme. Both truncated variants followed Michaelis-Menten kinetics where GspDAH7PSDAH7PS was found to be more active than GspDAH7PSWT and unaffected by PA, whereas GspDAH7PSCM was a less efficient catalyst than the CM domain of GspDAH7PSWT. AUC demonstrated that in solution an equilibrium occurs between the monomeric and tetrameric oligomeric states of GspDAH7PSDAH7PS. Chapter 4 summarises the findings of the thesis along with future directions of this research, combining the results obtained and expanding upon them. It is concluded that the catalytic regulatory CM domain supports both protein structure and allosteric regulation of GspDAH7PSWT DAH7PS GspDAH7PS Geobacillus sp Gsp Enzyme Inhibition Regulation Protein Shikimate Pathway Chorimate Mutase CM Prephenate Truncation Crystal Structure DSF Analytical Ultracentrifugation Metal Activation Cloning Purification Chromatography
46	Characterisation and Control of 3-Deoxy-D-arabino-heptulosonate 7-phosphate Synthase from Geobacillus sp Othman, Mohamad January 2014 (has links) 3-Deoxy-D-arabino heptulosonate 7-phosphate synthase (DAH7PS) catalyses the first step of the shikimate pathway, responsible for the biosynthesis of aromatic amino acids. This pathway is found in microorganisms, plants and apicomplexan parasites and its absence in mammals makes it a viable target for antimicrobial drug design. DAH7PS enzymes differ in the regulatory machinery that decorates the catalytic (β/α)8 barrel. Some DAH7PS enzymes are fused to chorismate mutase (CM), another enzyme in the shikimate pathway. This fusion protein is allosterically regulated by chorismate (CA) or prephenate (PA), the precursor of tyrosine and phenylalanine. It has been suggested that DAH7PS enzymes evolved these extensions to the core barrel for the sole purpose of regulation. Geobacillus sp DAH7PS (GspDAH7PSWT) is a thermophilic type Iβ DAH7PS enzyme with an N-terminal CM domain fused through a linker region. This thesis describes the functional characterisation work carried out on GspDAH7PSWT, in attempt to help determine how DAH7PS enzymes evolved such diverse methods of regulation. Chapter 2 describes the functional characterisation work carried out on the catalytic and regulatory domains of GspDAH7PSWT. The enzyme demonstrated both DAH7PS and CM activities with the DAH7PS domain determined to be metal dependent and most activated by Cd2+. PA completely inhibited the catalytic activity of GspDAH7PSWT, and AUC demonstrated an equilibrium exists between the dimeric and tetrameric quaternary states of the enzyme in solution. Chapter 3 describes the domain truncation of GspDAH7PSWT carried out at the linker region in order to obtain two separate protein domains, the catalytic domain lacking the N-terminal domain (GspDAH7PSDAH7PS) and the regulatory domain without the catalytic domain (GspDAH7PSCM). Both variants were fully characterised, and information obtained from each domain was compared to the respective catalytic and regulatory domains of the wild-type enzyme, which was also characterised. Like GspDAH7PSWT, GspDAH7PSDAH7PS showed greatest activation in the presence of Cd2+, with other metals having varying effects on activation rates and stability of the enzyme. Both truncated variants followed Michaelis-Menten kinetics where GspDAH7PSDAH7PS was found to be more active than GspDAH7PSWT and unaffected by PA, whereas GspDAH7PSCM was a less efficient catalyst than the CM domain of GspDAH7PSWT. AUC demonstrated that in solution an equilibrium occurs between the monomeric and tetrameric oligomeric states of GspDAH7PSDAH7PS. Chapter 4 summarises the findings of the thesis along with future directions of this research, combining the results obtained and expanding upon them. It is concluded that the catalytic regulatory CM domain supports both protein structure and allosteric regulation of GspDAH7PSWT DAH7PS GspDAH7PS Geobacillus sp Gsp Enzyme Inhibition Regulation Protein Shikimate Pathway Chorimate Mutase CM Prephenate Truncation Crystal Structure DSF Analytical Ultracentrifugation Metal Activation Cloning Purification Chromatography
47	Hit Identification and Hit Expansion in Antituberculosis Drug Discovery : Design and Synthesis of Glutamine Synthetase and 1-Deoxy-D-Xylulose-5-Phosphate Reductoisomerase Inhibitors Nordqvist, Anneli January 2011 (has links) Since the discovery of Mycobacterium tuberculosis (Mtb) as the bacterial agent causing tuberculosis, the permanent eradication of this disease has proven challenging. Although a number of drugs exist for the treatment of tuberculosis, 1.7 million people still die every year from this infection. The current treatment regimen involves lengthy combination therapy with four different drugs in an effort to combat the development of resistance. However, multidrug-resistant and extensively drug-resistant strains are emerging in all parts of the world. Therefore, new drugs effective in the treatment of tuberculosis are much-needed. The work presented in this thesis was focused on the early stages of drug discovery by applying different hit identification and hit expansion strategies in the exploration of two new potential drug targets, glutamine synthetase (GS) and 1-deoxy-D-xylulose-5-phosphate reductoisomerase (DXR). A literature survey was first carried out to identify new Mtb GS inhibitors from compounds known to inhibit GS in other species. Three compounds, structurally unrelated to the typical amino acid derivatives of previously known GS inhibitors, were then discovered by virtual screening and found to be Mtb GS inhibitors, exhibiting activities in the millimolar range. Imidazo[1,2-a]pyridine analogues were also investigated as Mtb GS inhibitors. The chemical functionality, size requirements and position of the substituents in the imidazo[1,2-a]pyridine hit were investigated, and a chemical library was designed based on a focused hierarchical design of experiments approach. The X-ray structure of one of the inhibitors in complex with Mtb GS provided additional insight into the structure–activity relationships of this class of compounds. Finally, new α-arylated fosmidomycin analogues were synthesized as inhibitors of Mtb DXR, exhibiting IC50 values down to 0.8 µM. This work shows that a wide variety of aryl groups are tolerated by the enzyme. Cinnamaldehydes are important synthetic intermediates in the synthesis of fosmidomycin analogues. These were prepared by an oxidative Heck reaction from acrolein and various arylboronic acids. Electron-rich, electron-poor, heterocyclic and sterically hindered boronic acids could be employed, furnishing cinnamaldehydes in 43–92% yield. Tuberculosis Glutamine synthetase Imidazo[1 2-a]pyridine analogues DXR Fosmidomycin analogues Cinnamaldehydes Oxidative Heck reaction Pharmaceutical chemistry Läkemedelskemi
48	Efeito da secção do nervo isquiático sobre parâmetros ultraestrutural, histoquímico, imunoistoquímico e de captação de análogos da glicose em gânglio da raiz dorsal de rãs Lithobates catesbianus Rigon, Fabiana January 2013 (has links) As rãs são utilizadas como modelos experimentais em diferentes situações experimentais. Uma delas é o estudo dos efeitos da seção do nervo isquiático (SNI) sobre o tecido nervoso. Essa ampla utilização desses animais como modelos experimentais justifica a realização de estudos que visam o conhecimento morfofuncional de seus tecidos. Inúmeros estudos mostram que, assim como nos mamíferos, o principal substrato energético no tecido nervoso de rãs é a glicose. Porém, é desconhecida a distribuição dos transportadores de glicose no tecido nervoso de rãs, bem como se a SNI altera esse transporte. Outra questão em aberto é se o lactato, cuja concentração está aumentada no plasma de rãs durante períodos de hibernação e após atividades motoras, é usado como substrato energético pelo tecido nervoso, o que está demonstrado em outras espécies de vertebrados. É desconhecida ainda no gânglio da raiz dorsal (GRD) de rãs a distribuição e os efeitos da SNT sobre a reação à nicotinamida adenina dinucleotídeo fosfato diaforase (NADPH-diaforase), enzima considerada equivalente a óxido nítrico sintase, responsável pela síntese de óxido nítrico, e a reação ao ácido periódico-reativo de Schiff (PAS), que indica a presença de mucopolissarídeos, incluindo o glicogênio, uma importante reserva energética no tecido nervoso de rãs. Desconhece-se também a distribuição e os efeitos da SNT sobre a imunorreatividade à serotonina, importante molécula com função neurotransmissora e/ou moduladora no sistema nervoso, tirosina hidroxilase, enzima limitante na síntese de catecolaminas, moléculas com diversos papéis fisiológicos, incluindo ação neurotransmissora e/ou neuromoduladora no tecido nervoso, e c-Fos, proteína considerada marcadora de ativação neural por estimulação nociva. Outras questões ainda em aberto são os efeitos da SNT sobre: a captação do análogo da glicose 1-14C 2-deoxi-D-glicose (14C-2-DG) e concentração plasmática de glicose e lactato; se os tipos II e III de células gliais satélites (CGSs), recentemente descritas no GRD de coelho, estão presentes nesse gânglio de rãs; e os efeitos da SNT sobre a ultraestrutura de CGSs e neurônios do GRD. Assim, o objetivo dessa tese foi determinar: 1) a ultraestrutura de neurônios e CGSs; 2) a distribuição das reações à NADPH-diaforase e PAS, e a imunoistoquímica à serotonina, tirosina hidroxilase, c-Fos e transportadores de glicose tipo 1 e 3; e 3) a captação de 14C-2-DG, na presença e ausência de lactato, em GRD de rãs Lithobates catesbianus com e sem SNI. A escolha pelos transportadores de glicose tipos 1 e 3 foi pelo fato de ocorrerem na membrana de endotélio, células gliais e de neurônios. Para a realização do estudo inicialmente 12 rãs Lithobates catesbianus, adultas, machos, com peso de 100-200g, que não sofreram qualquer manipulação cirúrgica foram mortas por decapitação e os gânglios das raízes dorsais (GRDs) do nervo isquiático retirados e preparados para análises ultraestrutural, histoquímica à NADPH-diaforase e PAS, e imunoistoquímica à serotonina, tirosina hidroxilase e transportadores de glicose dos tipos 1 e 3. Feito isso, 18 outras rãs, nas mesmas condições físicas, foram divididas em três grupos experimentais (n=6/grupo): controle (rãs que não sofreram qualquer manipulação cirúrgica), sham (rãs onde foram efetuados apenas os procedimentos para isolamento do nervo isquiático) e SNI (rãs que tiveram o nervo isquiático direito totalmente seccionado em seu tronco comum). Esses animais foram mortos três dias após a intervenção cirúrgica e seus GRDs do nervo isquiático usados para demonstrar os efeitos da secção nervosa sobre a ultraestrutura, a reação à NADPH-diaforase, e a imunoistoquímica à serotonina, tirosina hidroxilase, c-Fos e transportadores de glicose dos tipos 1 e 3 no GRD. Outros 20 animais, divididos nos mesmos grupos experimentais, foram usados para demonstrar os efeitos da SNI sobre a captação de 14C-2-DG, na presença ou ausência de lactato, e a taxa de produção de 14CO2 a partir de 14C-L-lactato e de 14C-glicose no GRD. Essas rãs foram usadas ainda para demonstrar os efeitos da denervação periférica sobre a concentração plasmática de glicose e lactato. Nossos resultados mostraram que os neurônios sensoriais do GRD de rã Lithobates catesbianus tiveram distribuição, diâmetro e morfologia que foi similar àquela descrita para essas células em gânglio de mamíferos. As CGSs apresentaram morfologia similar àquela descrita para essas células em gânglios de outras espécies de vertebrados. As células dos tipos II e III, observadas no GRD de coelho, não ocorreram no GRD de Lithobates catesbianus. O padrão de atividade à NADPH-diaforase e a distribuição da imunorreatividade à serotonina, tirosina hidroxilase e Glut 1 e 3 foram também similares ao descrito em mamíferos. Pela primeira vez foi demonstrada, em anfíbios, a presença de reação à NADPH-diaforase em CGCs do GRD. A captação de 14C-2-DG foi reduzida quando o lactato foi acrescentado ao meio de incubação. As alterações induzidas pela SNI foram também similares àquelas descritas nos mamíferos. Houve acréscimo no número de mitocôndrias, retículo endoplasmático, ribossomas e filamentos no citoplasma das CGSs, mais neurônios e CGCs com reação positiva à NADPH-diaforase, um maior número de prolongamentos imunorreativos à tirosina hidroxilase em torno de somas de neurônios sensoriais, e mais núcleos neuronais imunorreativos a c-Fos. Nenhuma alteração ocorreu na imunorreatividade a serotonina e transportadores de glicose. Houve aumento na captação de 14C-2-DG, que foi reduzido quando o lactato foi acrescentado ao meio de incubação. Porém, a formação de 14CO2 a partir de 14C-L-lactato e de 14C-glicose não alterou nessas condições. Todavia, diferentemente dos mamíferos, a SNI não provocou mudança no número de CGCs no GRD, mostrando uma peculiaridade na resposta das rãs à SNI. Assim, nosso estudo reforça o uso de rãs como modelo experimental para estudo dos efeitos da SNI, um modelo de dor fantasma, sobre o tecido nervoso. Porém, dada a diferença peculiar ocorrida no GRD de rãs com SNI, é evidente a necessidade de mais conhecimento dos efeitos dessa situação experimental nesses animais. / Frogs have been used as experimental models in different experimental situations. One of these is the study of the effects of the sciatic nerve transection (SNT) on the nerve tissue. The wide use of these animals as experimental models justifies the studies aimed at morphofunctionally understanding of their tissues. Numerous studies have shown that glucose is the main energy substrate in the nerve tissue of frogs as well as in mammals. However, the distribution of glucose transporters in the nerve tissue of frogs is unknown as well as whether SNT alters such transportation. Another unanswered question is whether the lactate, whose concentration is increased in the frog plasma during hibernation periods and after motor activities, is used as an energy substrate by the nerve tissue, which has been demonstrated in other vertebrate species. In the dorsal root ganglion (DRG) cells of frogs are still unknown the distribution and effects of SNT on the reaction of nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-diaphorase), an enzyme that is considered equivalent to nitric oxide synthase, responsible for the synthesis of nitric oxide, and on the reaction of periodic acid-Schiff (PAS), which indicates the presence of mucopolysaccharides, including glycogen, an important energy reserve in frog nerve tissue. Moreover, the distribution and effects of SNT on immunoreactivity to serotonin, an important molecule that functions as a neurotransmitter and / or neuromodulator in the nervous system, tyrosine hydroxylase, the rate-limiting enzyme in catecholamine biosynthesis, molecules with various physiological roles, including neurotransmitter and / or neuromodulator action in the nerve tissue, and c-Fos, a protein that is regarded as a marker of neuronal activation by noxious stimulation are also unknown. Other questions regarding is the effect of SNT on the uptake of glucose analogue 2-Deoxy-D-glucose-1-14C (14C-2-DG) and glucose and lactate concentration plasma; whether the types II and III of satellite glial cells (SGCs), recently described in rabbit DRG, are present in this ganglion of frogs; and the effects of SNT on the ultrastructure of SGCs and DRG neurons remain unanswered as well. Thus, this thesis aimed to determine: 1) the ultrastructure of neurons and SGCs; 2) the distribution of NADPH-diaphorase and PAS reaction, and immunohistochemistry for serotonin, tyrosine hydroxylase, c-Fos and glucose transporters types 1 and 3; and 3) the uptake of 2-DG-14C, in the presence and absence of lactate, in DRG of frogs, Lithobates catesbianus, with and without SNT. Glucose transporters types 1 and 3 were chosen because they occur in the membrane of endothelial cells, glial cells and neurons. Initially, 12 adult male frogs, Lithobates catesbianus, weighing 100-200g, not having undergone any previous surgical manipulation, were killed by decapitation. The DRGs of the sciatic nerve were removed and prepared for ultrastructural analysis, histochemistry of NADPH-diaphorase and PAS, and immunohistochemistry for serotonin, tyrosine hydroxylase and glucose transporters types 1 and 3. After that, 18 other frogs in the same physical conditions were divided into three experimental groups (n = 6/group): control group (frogs not subjected to any surgical manipulation), sham (frogs in which only surgical procedures for isolating the sciatic nerve were performed), and SNT (frogs in which the right sciatic nerve was completely transected). These animals were killed three days after the procedure, and their sciatic nerve DRGs used to demonstrate the effects of nerve transection on the ultrastructure, NADPH-diaphorase reaction, and immunohistochemical serotonin, tyrosine hydroxylase, c-Fos and glucose transporters types 1 and 3 in the DRG. Other 20 animals, divided into the same experimental groups, were used to demonstrate the effects of SNI on the uptake of 14C-2-DG in the presence or absence of lactate, the production rate of 14CO2 from 14C-L-lactate and 14C-glucose in the DRG. These frogs were used to further demonstrate the effects of peripheral denervation on plasma glucose and lactate levels. Our results have demonstrated that sensory neurons of bullfrog, Lithobates catesbianus, DRG showed distribution, diameter and morphology similar to those described for these ganglion cells in mammals. The CGSs showed morphology similar to that described for these cells in the lymph nodes of other vertebrate species. Cells types II and III, observed in rabbit DRG did not occur in the Lithobates catesbianus DRG. The pattern of NADPH-diaphorase activity and distribution of immunoreactivity of serotonin, tyrosine hydroxylase and Glut 1 and 3 were also similar to those described in mammals. For the first time, it has been demonstrated the presence of NADPH-diaphorase reaction on SGCs of DRG in amphibians. The uptake of 14C-2-DG was reduced when lactate was added to the incubation medium. SNT-induced changes were also similar to those ones described in mammals. There was an increase in the number of mitochondria, endoplasmic reticulum, ribosomes and filaments in the SGCs cytoplasm; more neurons and SGCs with positive reaction to NADPH-diaphorase; a greater number of tyrosine hydroxylase immunoreactive extensions around body sensory neurons; and more c-Fos immunoreactivity in neuronal nuclei. No changes occurred in serotonin immunoreactivity and glucose transporters. There was an increase in the uptake of 14C-2-DG, which was reduced when lactate was added to the incubation medium. However, the formation of 14C-2-DG from 14C-L-lactato and glucose did not change under these conditions. Unlike mammals, SNT caused no change in the number of SGCs in DRG, showing a peculiarity in the response of frogs to SNT. Therefore, our study supports the use of frogs as an experimental model to study the effects of SNT, a model of phantom pain on the nerve tissue. However, given the peculiar differences occurred in the DRG of frogs with SNT, it is clearly necessary to carry out further studies to better understand the effects of an experimental situation like this in such animals. Nervo isquiático Axotomia Imuno-histoquímica NADPH diaforase Serotonina Tirosina hidroxilase Glucose Axotomy Histochemistry Immunoreactivity NADPH-diaphorase Serotonin Tyrosine hydroxylase 1-[14C] 2-deoxy-D-glucose 3-O-[14C] methyl-D-glucose
49	Efeito da secção do nervo isquiático sobre parâmetros ultraestrutural, histoquímico, imunoistoquímico e de captação de análogos da glicose em gânglio da raiz dorsal de rãs Lithobates catesbianus Rigon, Fabiana January 2013 (has links) As rãs são utilizadas como modelos experimentais em diferentes situações experimentais. Uma delas é o estudo dos efeitos da seção do nervo isquiático (SNI) sobre o tecido nervoso. Essa ampla utilização desses animais como modelos experimentais justifica a realização de estudos que visam o conhecimento morfofuncional de seus tecidos. Inúmeros estudos mostram que, assim como nos mamíferos, o principal substrato energético no tecido nervoso de rãs é a glicose. Porém, é desconhecida a distribuição dos transportadores de glicose no tecido nervoso de rãs, bem como se a SNI altera esse transporte. Outra questão em aberto é se o lactato, cuja concentração está aumentada no plasma de rãs durante períodos de hibernação e após atividades motoras, é usado como substrato energético pelo tecido nervoso, o que está demonstrado em outras espécies de vertebrados. É desconhecida ainda no gânglio da raiz dorsal (GRD) de rãs a distribuição e os efeitos da SNT sobre a reação à nicotinamida adenina dinucleotídeo fosfato diaforase (NADPH-diaforase), enzima considerada equivalente a óxido nítrico sintase, responsável pela síntese de óxido nítrico, e a reação ao ácido periódico-reativo de Schiff (PAS), que indica a presença de mucopolissarídeos, incluindo o glicogênio, uma importante reserva energética no tecido nervoso de rãs. Desconhece-se também a distribuição e os efeitos da SNT sobre a imunorreatividade à serotonina, importante molécula com função neurotransmissora e/ou moduladora no sistema nervoso, tirosina hidroxilase, enzima limitante na síntese de catecolaminas, moléculas com diversos papéis fisiológicos, incluindo ação neurotransmissora e/ou neuromoduladora no tecido nervoso, e c-Fos, proteína considerada marcadora de ativação neural por estimulação nociva. Outras questões ainda em aberto são os efeitos da SNT sobre: a captação do análogo da glicose 1-14C 2-deoxi-D-glicose (14C-2-DG) e concentração plasmática de glicose e lactato; se os tipos II e III de células gliais satélites (CGSs), recentemente descritas no GRD de coelho, estão presentes nesse gânglio de rãs; e os efeitos da SNT sobre a ultraestrutura de CGSs e neurônios do GRD. Assim, o objetivo dessa tese foi determinar: 1) a ultraestrutura de neurônios e CGSs; 2) a distribuição das reações à NADPH-diaforase e PAS, e a imunoistoquímica à serotonina, tirosina hidroxilase, c-Fos e transportadores de glicose tipo 1 e 3; e 3) a captação de 14C-2-DG, na presença e ausência de lactato, em GRD de rãs Lithobates catesbianus com e sem SNI. A escolha pelos transportadores de glicose tipos 1 e 3 foi pelo fato de ocorrerem na membrana de endotélio, células gliais e de neurônios. Para a realização do estudo inicialmente 12 rãs Lithobates catesbianus, adultas, machos, com peso de 100-200g, que não sofreram qualquer manipulação cirúrgica foram mortas por decapitação e os gânglios das raízes dorsais (GRDs) do nervo isquiático retirados e preparados para análises ultraestrutural, histoquímica à NADPH-diaforase e PAS, e imunoistoquímica à serotonina, tirosina hidroxilase e transportadores de glicose dos tipos 1 e 3. Feito isso, 18 outras rãs, nas mesmas condições físicas, foram divididas em três grupos experimentais (n=6/grupo): controle (rãs que não sofreram qualquer manipulação cirúrgica), sham (rãs onde foram efetuados apenas os procedimentos para isolamento do nervo isquiático) e SNI (rãs que tiveram o nervo isquiático direito totalmente seccionado em seu tronco comum). Esses animais foram mortos três dias após a intervenção cirúrgica e seus GRDs do nervo isquiático usados para demonstrar os efeitos da secção nervosa sobre a ultraestrutura, a reação à NADPH-diaforase, e a imunoistoquímica à serotonina, tirosina hidroxilase, c-Fos e transportadores de glicose dos tipos 1 e 3 no GRD. Outros 20 animais, divididos nos mesmos grupos experimentais, foram usados para demonstrar os efeitos da SNI sobre a captação de 14C-2-DG, na presença ou ausência de lactato, e a taxa de produção de 14CO2 a partir de 14C-L-lactato e de 14C-glicose no GRD. Essas rãs foram usadas ainda para demonstrar os efeitos da denervação periférica sobre a concentração plasmática de glicose e lactato. Nossos resultados mostraram que os neurônios sensoriais do GRD de rã Lithobates catesbianus tiveram distribuição, diâmetro e morfologia que foi similar àquela descrita para essas células em gânglio de mamíferos. As CGSs apresentaram morfologia similar àquela descrita para essas células em gânglios de outras espécies de vertebrados. As células dos tipos II e III, observadas no GRD de coelho, não ocorreram no GRD de Lithobates catesbianus. O padrão de atividade à NADPH-diaforase e a distribuição da imunorreatividade à serotonina, tirosina hidroxilase e Glut 1 e 3 foram também similares ao descrito em mamíferos. Pela primeira vez foi demonstrada, em anfíbios, a presença de reação à NADPH-diaforase em CGCs do GRD. A captação de 14C-2-DG foi reduzida quando o lactato foi acrescentado ao meio de incubação. As alterações induzidas pela SNI foram também similares àquelas descritas nos mamíferos. Houve acréscimo no número de mitocôndrias, retículo endoplasmático, ribossomas e filamentos no citoplasma das CGSs, mais neurônios e CGCs com reação positiva à NADPH-diaforase, um maior número de prolongamentos imunorreativos à tirosina hidroxilase em torno de somas de neurônios sensoriais, e mais núcleos neuronais imunorreativos a c-Fos. Nenhuma alteração ocorreu na imunorreatividade a serotonina e transportadores de glicose. Houve aumento na captação de 14C-2-DG, que foi reduzido quando o lactato foi acrescentado ao meio de incubação. Porém, a formação de 14CO2 a partir de 14C-L-lactato e de 14C-glicose não alterou nessas condições. Todavia, diferentemente dos mamíferos, a SNI não provocou mudança no número de CGCs no GRD, mostrando uma peculiaridade na resposta das rãs à SNI. Assim, nosso estudo reforça o uso de rãs como modelo experimental para estudo dos efeitos da SNI, um modelo de dor fantasma, sobre o tecido nervoso. Porém, dada a diferença peculiar ocorrida no GRD de rãs com SNI, é evidente a necessidade de mais conhecimento dos efeitos dessa situação experimental nesses animais. / Frogs have been used as experimental models in different experimental situations. One of these is the study of the effects of the sciatic nerve transection (SNT) on the nerve tissue. The wide use of these animals as experimental models justifies the studies aimed at morphofunctionally understanding of their tissues. Numerous studies have shown that glucose is the main energy substrate in the nerve tissue of frogs as well as in mammals. However, the distribution of glucose transporters in the nerve tissue of frogs is unknown as well as whether SNT alters such transportation. Another unanswered question is whether the lactate, whose concentration is increased in the frog plasma during hibernation periods and after motor activities, is used as an energy substrate by the nerve tissue, which has been demonstrated in other vertebrate species. In the dorsal root ganglion (DRG) cells of frogs are still unknown the distribution and effects of SNT on the reaction of nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-diaphorase), an enzyme that is considered equivalent to nitric oxide synthase, responsible for the synthesis of nitric oxide, and on the reaction of periodic acid-Schiff (PAS), which indicates the presence of mucopolysaccharides, including glycogen, an important energy reserve in frog nerve tissue. Moreover, the distribution and effects of SNT on immunoreactivity to serotonin, an important molecule that functions as a neurotransmitter and / or neuromodulator in the nervous system, tyrosine hydroxylase, the rate-limiting enzyme in catecholamine biosynthesis, molecules with various physiological roles, including neurotransmitter and / or neuromodulator action in the nerve tissue, and c-Fos, a protein that is regarded as a marker of neuronal activation by noxious stimulation are also unknown. Other questions regarding is the effect of SNT on the uptake of glucose analogue 2-Deoxy-D-glucose-1-14C (14C-2-DG) and glucose and lactate concentration plasma; whether the types II and III of satellite glial cells (SGCs), recently described in rabbit DRG, are present in this ganglion of frogs; and the effects of SNT on the ultrastructure of SGCs and DRG neurons remain unanswered as well. Thus, this thesis aimed to determine: 1) the ultrastructure of neurons and SGCs; 2) the distribution of NADPH-diaphorase and PAS reaction, and immunohistochemistry for serotonin, tyrosine hydroxylase, c-Fos and glucose transporters types 1 and 3; and 3) the uptake of 2-DG-14C, in the presence and absence of lactate, in DRG of frogs, Lithobates catesbianus, with and without SNT. Glucose transporters types 1 and 3 were chosen because they occur in the membrane of endothelial cells, glial cells and neurons. Initially, 12 adult male frogs, Lithobates catesbianus, weighing 100-200g, not having undergone any previous surgical manipulation, were killed by decapitation. The DRGs of the sciatic nerve were removed and prepared for ultrastructural analysis, histochemistry of NADPH-diaphorase and PAS, and immunohistochemistry for serotonin, tyrosine hydroxylase and glucose transporters types 1 and 3. After that, 18 other frogs in the same physical conditions were divided into three experimental groups (n = 6/group): control group (frogs not subjected to any surgical manipulation), sham (frogs in which only surgical procedures for isolating the sciatic nerve were performed), and SNT (frogs in which the right sciatic nerve was completely transected). These animals were killed three days after the procedure, and their sciatic nerve DRGs used to demonstrate the effects of nerve transection on the ultrastructure, NADPH-diaphorase reaction, and immunohistochemical serotonin, tyrosine hydroxylase, c-Fos and glucose transporters types 1 and 3 in the DRG. Other 20 animals, divided into the same experimental groups, were used to demonstrate the effects of SNI on the uptake of 14C-2-DG in the presence or absence of lactate, the production rate of 14CO2 from 14C-L-lactate and 14C-glucose in the DRG. These frogs were used to further demonstrate the effects of peripheral denervation on plasma glucose and lactate levels. Our results have demonstrated that sensory neurons of bullfrog, Lithobates catesbianus, DRG showed distribution, diameter and morphology similar to those described for these ganglion cells in mammals. The CGSs showed morphology similar to that described for these cells in the lymph nodes of other vertebrate species. Cells types II and III, observed in rabbit DRG did not occur in the Lithobates catesbianus DRG. The pattern of NADPH-diaphorase activity and distribution of immunoreactivity of serotonin, tyrosine hydroxylase and Glut 1 and 3 were also similar to those described in mammals. For the first time, it has been demonstrated the presence of NADPH-diaphorase reaction on SGCs of DRG in amphibians. The uptake of 14C-2-DG was reduced when lactate was added to the incubation medium. SNT-induced changes were also similar to those ones described in mammals. There was an increase in the number of mitochondria, endoplasmic reticulum, ribosomes and filaments in the SGCs cytoplasm; more neurons and SGCs with positive reaction to NADPH-diaphorase; a greater number of tyrosine hydroxylase immunoreactive extensions around body sensory neurons; and more c-Fos immunoreactivity in neuronal nuclei. No changes occurred in serotonin immunoreactivity and glucose transporters. There was an increase in the uptake of 14C-2-DG, which was reduced when lactate was added to the incubation medium. However, the formation of 14C-2-DG from 14C-L-lactato and glucose did not change under these conditions. Unlike mammals, SNT caused no change in the number of SGCs in DRG, showing a peculiarity in the response of frogs to SNT. Therefore, our study supports the use of frogs as an experimental model to study the effects of SNT, a model of phantom pain on the nerve tissue. However, given the peculiar differences occurred in the DRG of frogs with SNT, it is clearly necessary to carry out further studies to better understand the effects of an experimental situation like this in such animals. Nervo isquiático Axotomia Imuno-histoquímica NADPH diaforase Serotonina Tirosina hidroxilase Glucose Axotomy Histochemistry Immunoreactivity NADPH-diaphorase Serotonin Tyrosine hydroxylase 1-[14C] 2-deoxy-D-glucose 3-O-[14C] methyl-D-glucose
50	Efeito da secção do nervo isquiático sobre parâmetros ultraestrutural, histoquímico, imunoistoquímico e de captação de análogos da glicose em gânglio da raiz dorsal de rãs Lithobates catesbianus Rigon, Fabiana January 2013 (has links) As rãs são utilizadas como modelos experimentais em diferentes situações experimentais. Uma delas é o estudo dos efeitos da seção do nervo isquiático (SNI) sobre o tecido nervoso. Essa ampla utilização desses animais como modelos experimentais justifica a realização de estudos que visam o conhecimento morfofuncional de seus tecidos. Inúmeros estudos mostram que, assim como nos mamíferos, o principal substrato energético no tecido nervoso de rãs é a glicose. Porém, é desconhecida a distribuição dos transportadores de glicose no tecido nervoso de rãs, bem como se a SNI altera esse transporte. Outra questão em aberto é se o lactato, cuja concentração está aumentada no plasma de rãs durante períodos de hibernação e após atividades motoras, é usado como substrato energético pelo tecido nervoso, o que está demonstrado em outras espécies de vertebrados. É desconhecida ainda no gânglio da raiz dorsal (GRD) de rãs a distribuição e os efeitos da SNT sobre a reação à nicotinamida adenina dinucleotídeo fosfato diaforase (NADPH-diaforase), enzima considerada equivalente a óxido nítrico sintase, responsável pela síntese de óxido nítrico, e a reação ao ácido periódico-reativo de Schiff (PAS), que indica a presença de mucopolissarídeos, incluindo o glicogênio, uma importante reserva energética no tecido nervoso de rãs. Desconhece-se também a distribuição e os efeitos da SNT sobre a imunorreatividade à serotonina, importante molécula com função neurotransmissora e/ou moduladora no sistema nervoso, tirosina hidroxilase, enzima limitante na síntese de catecolaminas, moléculas com diversos papéis fisiológicos, incluindo ação neurotransmissora e/ou neuromoduladora no tecido nervoso, e c-Fos, proteína considerada marcadora de ativação neural por estimulação nociva. Outras questões ainda em aberto são os efeitos da SNT sobre: a captação do análogo da glicose 1-14C 2-deoxi-D-glicose (14C-2-DG) e concentração plasmática de glicose e lactato; se os tipos II e III de células gliais satélites (CGSs), recentemente descritas no GRD de coelho, estão presentes nesse gânglio de rãs; e os efeitos da SNT sobre a ultraestrutura de CGSs e neurônios do GRD. Assim, o objetivo dessa tese foi determinar: 1) a ultraestrutura de neurônios e CGSs; 2) a distribuição das reações à NADPH-diaforase e PAS, e a imunoistoquímica à serotonina, tirosina hidroxilase, c-Fos e transportadores de glicose tipo 1 e 3; e 3) a captação de 14C-2-DG, na presença e ausência de lactato, em GRD de rãs Lithobates catesbianus com e sem SNI. A escolha pelos transportadores de glicose tipos 1 e 3 foi pelo fato de ocorrerem na membrana de endotélio, células gliais e de neurônios. Para a realização do estudo inicialmente 12 rãs Lithobates catesbianus, adultas, machos, com peso de 100-200g, que não sofreram qualquer manipulação cirúrgica foram mortas por decapitação e os gânglios das raízes dorsais (GRDs) do nervo isquiático retirados e preparados para análises ultraestrutural, histoquímica à NADPH-diaforase e PAS, e imunoistoquímica à serotonina, tirosina hidroxilase e transportadores de glicose dos tipos 1 e 3. Feito isso, 18 outras rãs, nas mesmas condições físicas, foram divididas em três grupos experimentais (n=6/grupo): controle (rãs que não sofreram qualquer manipulação cirúrgica), sham (rãs onde foram efetuados apenas os procedimentos para isolamento do nervo isquiático) e SNI (rãs que tiveram o nervo isquiático direito totalmente seccionado em seu tronco comum). Esses animais foram mortos três dias após a intervenção cirúrgica e seus GRDs do nervo isquiático usados para demonstrar os efeitos da secção nervosa sobre a ultraestrutura, a reação à NADPH-diaforase, e a imunoistoquímica à serotonina, tirosina hidroxilase, c-Fos e transportadores de glicose dos tipos 1 e 3 no GRD. Outros 20 animais, divididos nos mesmos grupos experimentais, foram usados para demonstrar os efeitos da SNI sobre a captação de 14C-2-DG, na presença ou ausência de lactato, e a taxa de produção de 14CO2 a partir de 14C-L-lactato e de 14C-glicose no GRD. Essas rãs foram usadas ainda para demonstrar os efeitos da denervação periférica sobre a concentração plasmática de glicose e lactato. Nossos resultados mostraram que os neurônios sensoriais do GRD de rã Lithobates catesbianus tiveram distribuição, diâmetro e morfologia que foi similar àquela descrita para essas células em gânglio de mamíferos. As CGSs apresentaram morfologia similar àquela descrita para essas células em gânglios de outras espécies de vertebrados. As células dos tipos II e III, observadas no GRD de coelho, não ocorreram no GRD de Lithobates catesbianus. O padrão de atividade à NADPH-diaforase e a distribuição da imunorreatividade à serotonina, tirosina hidroxilase e Glut 1 e 3 foram também similares ao descrito em mamíferos. Pela primeira vez foi demonstrada, em anfíbios, a presença de reação à NADPH-diaforase em CGCs do GRD. A captação de 14C-2-DG foi reduzida quando o lactato foi acrescentado ao meio de incubação. As alterações induzidas pela SNI foram também similares àquelas descritas nos mamíferos. Houve acréscimo no número de mitocôndrias, retículo endoplasmático, ribossomas e filamentos no citoplasma das CGSs, mais neurônios e CGCs com reação positiva à NADPH-diaforase, um maior número de prolongamentos imunorreativos à tirosina hidroxilase em torno de somas de neurônios sensoriais, e mais núcleos neuronais imunorreativos a c-Fos. Nenhuma alteração ocorreu na imunorreatividade a serotonina e transportadores de glicose. Houve aumento na captação de 14C-2-DG, que foi reduzido quando o lactato foi acrescentado ao meio de incubação. Porém, a formação de 14CO2 a partir de 14C-L-lactato e de 14C-glicose não alterou nessas condições. Todavia, diferentemente dos mamíferos, a SNI não provocou mudança no número de CGCs no GRD, mostrando uma peculiaridade na resposta das rãs à SNI. Assim, nosso estudo reforça o uso de rãs como modelo experimental para estudo dos efeitos da SNI, um modelo de dor fantasma, sobre o tecido nervoso. Porém, dada a diferença peculiar ocorrida no GRD de rãs com SNI, é evidente a necessidade de mais conhecimento dos efeitos dessa situação experimental nesses animais. / Frogs have been used as experimental models in different experimental situations. One of these is the study of the effects of the sciatic nerve transection (SNT) on the nerve tissue. The wide use of these animals as experimental models justifies the studies aimed at morphofunctionally understanding of their tissues. Numerous studies have shown that glucose is the main energy substrate in the nerve tissue of frogs as well as in mammals. However, the distribution of glucose transporters in the nerve tissue of frogs is unknown as well as whether SNT alters such transportation. Another unanswered question is whether the lactate, whose concentration is increased in the frog plasma during hibernation periods and after motor activities, is used as an energy substrate by the nerve tissue, which has been demonstrated in other vertebrate species. In the dorsal root ganglion (DRG) cells of frogs are still unknown the distribution and effects of SNT on the reaction of nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-diaphorase), an enzyme that is considered equivalent to nitric oxide synthase, responsible for the synthesis of nitric oxide, and on the reaction of periodic acid-Schiff (PAS), which indicates the presence of mucopolysaccharides, including glycogen, an important energy reserve in frog nerve tissue. Moreover, the distribution and effects of SNT on immunoreactivity to serotonin, an important molecule that functions as a neurotransmitter and / or neuromodulator in the nervous system, tyrosine hydroxylase, the rate-limiting enzyme in catecholamine biosynthesis, molecules with various physiological roles, including neurotransmitter and / or neuromodulator action in the nerve tissue, and c-Fos, a protein that is regarded as a marker of neuronal activation by noxious stimulation are also unknown. Other questions regarding is the effect of SNT on the uptake of glucose analogue 2-Deoxy-D-glucose-1-14C (14C-2-DG) and glucose and lactate concentration plasma; whether the types II and III of satellite glial cells (SGCs), recently described in rabbit DRG, are present in this ganglion of frogs; and the effects of SNT on the ultrastructure of SGCs and DRG neurons remain unanswered as well. Thus, this thesis aimed to determine: 1) the ultrastructure of neurons and SGCs; 2) the distribution of NADPH-diaphorase and PAS reaction, and immunohistochemistry for serotonin, tyrosine hydroxylase, c-Fos and glucose transporters types 1 and 3; and 3) the uptake of 2-DG-14C, in the presence and absence of lactate, in DRG of frogs, Lithobates catesbianus, with and without SNT. Glucose transporters types 1 and 3 were chosen because they occur in the membrane of endothelial cells, glial cells and neurons. Initially, 12 adult male frogs, Lithobates catesbianus, weighing 100-200g, not having undergone any previous surgical manipulation, were killed by decapitation. The DRGs of the sciatic nerve were removed and prepared for ultrastructural analysis, histochemistry of NADPH-diaphorase and PAS, and immunohistochemistry for serotonin, tyrosine hydroxylase and glucose transporters types 1 and 3. After that, 18 other frogs in the same physical conditions were divided into three experimental groups (n = 6/group): control group (frogs not subjected to any surgical manipulation), sham (frogs in which only surgical procedures for isolating the sciatic nerve were performed), and SNT (frogs in which the right sciatic nerve was completely transected). These animals were killed three days after the procedure, and their sciatic nerve DRGs used to demonstrate the effects of nerve transection on the ultrastructure, NADPH-diaphorase reaction, and immunohistochemical serotonin, tyrosine hydroxylase, c-Fos and glucose transporters types 1 and 3 in the DRG. Other 20 animals, divided into the same experimental groups, were used to demonstrate the effects of SNI on the uptake of 14C-2-DG in the presence or absence of lactate, the production rate of 14CO2 from 14C-L-lactate and 14C-glucose in the DRG. These frogs were used to further demonstrate the effects of peripheral denervation on plasma glucose and lactate levels. Our results have demonstrated that sensory neurons of bullfrog, Lithobates catesbianus, DRG showed distribution, diameter and morphology similar to those described for these ganglion cells in mammals. The CGSs showed morphology similar to that described for these cells in the lymph nodes of other vertebrate species. Cells types II and III, observed in rabbit DRG did not occur in the Lithobates catesbianus DRG. The pattern of NADPH-diaphorase activity and distribution of immunoreactivity of serotonin, tyrosine hydroxylase and Glut 1 and 3 were also similar to those described in mammals. For the first time, it has been demonstrated the presence of NADPH-diaphorase reaction on SGCs of DRG in amphibians. The uptake of 14C-2-DG was reduced when lactate was added to the incubation medium. SNT-induced changes were also similar to those ones described in mammals. There was an increase in the number of mitochondria, endoplasmic reticulum, ribosomes and filaments in the SGCs cytoplasm; more neurons and SGCs with positive reaction to NADPH-diaphorase; a greater number of tyrosine hydroxylase immunoreactive extensions around body sensory neurons; and more c-Fos immunoreactivity in neuronal nuclei. No changes occurred in serotonin immunoreactivity and glucose transporters. There was an increase in the uptake of 14C-2-DG, which was reduced when lactate was added to the incubation medium. However, the formation of 14C-2-DG from 14C-L-lactato and glucose did not change under these conditions. Unlike mammals, SNT caused no change in the number of SGCs in DRG, showing a peculiarity in the response of frogs to SNT. Therefore, our study supports the use of frogs as an experimental model to study the effects of SNT, a model of phantom pain on the nerve tissue. However, given the peculiar differences occurred in the DRG of frogs with SNT, it is clearly necessary to carry out further studies to better understand the effects of an experimental situation like this in such animals. Nervo isquiático Axotomia Imuno-histoquímica NADPH diaforase Serotonina Tirosina hidroxilase Glucose Axotomy Histochemistry Immunoreactivity NADPH-diaphorase Serotonin Tyrosine hydroxylase 1-[14C] 2-deoxy-D-glucose 3-O-[14C] methyl-D-glucose

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