Global ETD Search

61	Two of the Mechanims Used by Bacteria to Modify the Environment: Quorum Sensing and ACC Deaminase Hao, Youai January 2009 (has links) Quorum sensing (QS) cell-cell communication systems are utilized by bacteria to coordinate their behaviour according to cell density. Several different types of QS signal molecules have been identified, among which acyl-homoserine lactones (AHLs) produced by Proteobacteria have been studied to the greatest extent. QS has been shown to be involved in many aspects of bacterial life, including virulence, bioluminescence, symbiosis, antibiotic production, swarming and swimming motility, biofilm formation, conjugation and growth inhibition. Although QS has been studied extensively in cultured microorganisms, little is known about the QS systems of uncultured microorganisms and the roles of these systems in microbial communities. To extend our knowledge of QS systems and to better understand the signalling that takes place in the natural environment, in the first part of this thesis, isolation and characterization of new QS systems from metagenomic libraries constructed using DNA from activated sludge and soil were described. Using an Agrobacterium biosensor strain, three cosmids (QS6-1, QS10-1 and QS10-2) that encode the production of QS signals were identified and DNA sequence analysis revealed that all three clones encode a novel luxI family AHL synthase and a luxR family transcriptional regulator. Thin layer chromatography revealed that these LuxI homolog proteins are able to synthesize multiple AHL signals. Tandem mass spectrometry analysis revealed that LuxIQS6-1 directs the synthesis of at least three AHLs, 3-O-C14:1 HSL, 3-O-C16:1 HSL and 3-O-C14 HSL; LuxIQS10-1 directs the synthesis of at least 3-O-C12 HSL and 3-O-C14 HSL; while LuxIQS10-2 directs the synthesis of at least C8 HSL and C10 HSL. Two possible new AHLs, C14:3 HSL and (?)-hydroxymethyl-3-O-C14 HSL, were also found to be synthesized by LuxIQS6-1. Agrobacterium tumefaciens is a plant pathogen that causes crown gall disease. Its ability to transfer and integrate foreign DNA into plant genome also makes it a useful tool for plant genetic engineering. Ethylene, the gaseous plant hormone, has been reported to be important for both crown gall development and A. tumefaciens mediated transformation efficiency to plants. ACC deaminase, an enzyme that can break down ACC, the direct precursor of ethylene biosynthesis in plants, is a mechanism used by some plant growth promoting bacteria (PGPB) to promote plant growth by reducing stress ethylene levels. In the second part of this thesis, the effect of ACC deaminase on A. tumefaciens induced crown gall development and on A. tumefaciens mediated transformation efficiency was studied. By either introduction of an ACC deaminase encoding gene into the virulent strain A. tumefaciens C58 or co-inoculation of A. tumefaciens C58 with an ACC deaminase containing PGPB P. putida UW4, using different plant systems including tomato plants and castor bean plants, it was found that the presence of an ACC deaminase significantly inhibited crown gall development. It was also found that introduction of an acdS gene into the disarmed A. tumefaciens strain GV3101::pMP90 reduced the ethylene levels evolved by plants during infection and cocultivation process and increased the transformation efficiency of commercialized canola cultivars. The A. tumefaciens D3 strain was reported to contain an ACC deaminase encoding gene (acdS). In this study it was determined that this strain is an avirulent strain and shows plant growth promoting activity. When co-inoculated with A. tumefaciens C58 on castor bean stems, both the wild type and the acdS knockout mutant showed biocontrol activity and were able to significantly inhibit crown gall formation, with the wild type strain showing slightly better tumor inhibition effects. The mutation of acdS and its regulatory gene lrpL in A. tumefaciens D3 was also found to affect QS signal production of this strain, which indicates a cross talk between the two sets of genes. Quorum sensing Metagenomics LuxI/LuxR AHL ACC deaminase Transformation efficiency Crown gall Canola Agrobacterium tumefaciens Biology
62	Developmental Regulation of Cell Fate And Disease Resistance in Plants Plett, JONATHAN 20 October 2010 (has links) Plant-wide communication between tissues and cells is organized, in part, by a suite of compounds called hormones. I have chosen to focus on the effects of one plant hormone, ethylene; how its synthesis is controlled and how its perception is mediated to differentially control cell development and response to pathogens. In the production of ethylene, one level of control is by modulating the levels of the immediate precursor to ethylene, 1-aminocyclopropane-1-carboxylic acid (ACC). I characterize here a plant encoded gene homologous to bacterial ACC Deaminases, AtACD1, and show through up- and down-regulation of the gene that it can modulate the plants sensitivity to exogenous ACC. Once ethylene is produced, it is sensed in Arabidopsis thaliana by a family of 5 receptors. I show that ETR2 in Arabidopsis is responsible for modulation of the microtubule cytoskeleton assembly as loss-of –function mutations to this gene cause randomized microtubule assembly in trichomes and increase sensitivity to microtubule depolymerising drugs in root hairs. In studies of plant:pathogen interactions, ethylene is a central signaling agent required for plant resistance. While it has been shown that etr1 mutants show increased susceptibility to fungal pathogens, exogenous ethylene has also been shown to speed the progress of pathogenesis. Using Fumonisin B1 (FB1) to induce cell death I show that etr1-1 has accelerated cell death while ein4-1 has a reduced rate of necrosis. Further to this, mutations to the other three ethylene receptors do not have any effect on the rate of cell death. My interest in cell development led to the characterization of an activation tagged Populus tremula x P. alba line with increased trichome initiation. The gene responsible for these phenotypes was identified as PtMYB186, which also affected growth rate, transpiration rate, photosynthetic capacity, and resistance to the Tussock moth larvae. Together these studies provide a new framework for our understanding of how the ethylene signal is modulated in plants and the controls behind cellular development. This knowledge will help reconcile studies which show that ethylene has different effects on plant development and provide new avenues of research into trichome development. / Thesis (Ph.D, Biology) -- Queen's University, 2009-01-13 10:08:03.605 ethylene trichome ACC Deaminase Fumonisin Poplar Activation tagging hormone pest resistance
63	Investigations into the Targeting and Substrate Specificity of Activation-induced Deaminase Parsa, Jahan-Yar 18 December 2012 (has links) The processes of secondary antibody diversification are initiated by the mutagenic, B cell specific enzyme, Activation-Induced Deaminase (AID). AID deaminates deoxycytosine (dC) that is located in single-stranded DNA (ssDNA) in actively transcribed DNA to initiate the processes of somatic hypermutation (SHM), gene conversion (GCV) and class switch recombination (CSR) at the antibody gene loci. These processes lead to high affinity antibodies and antibodies of various effector functions that are required to efficiently neutralize invading pathogens. It is currently unclear how the antibody genes are specifically targeted by AID over other genes. I found that AID is able to mutate a non-immunoglobulin (Ig) transgene independent of its chromosomal integration site at rates that were above background mutation rates, but were ~10-fold lower than at the antibody variable (V) region. This result suggests that AID can mutate non-Ig genes at low rates, which may explain AID’s role in oncogenesis, but nevertheless shows that AID preferentially mutates the Ig locus over other loci. While it is understood that AID specifically deaminates dC bases in ssDNA, the size, distribution and origin of these ssDNA substrates is unknown. By utilizing a unique in situ sodium bisulfite assay to detect regions of ssDNA in intact nuclei, I characterized ssDNA regions and found that they are accurate predictors of AID activity during the processes of SHM and CSR in mammalian B cells and E.coli. Importantly, with the use of E.coli models, I show that these ssDNA substrates are the product of transcription-induced negative-supercoiled DNA that correlates strongly with the mutagenic activity of AID. While several underlying mechanisms exist to prevent the mistargeting of AID, my findings suggest that by simply gaining access to ssDNA that is produced by transcription-induced negative supercoiling, AID has the potential to mutate non-Ig genes, albeit at lower rates than the antibody V-region. activation induced cytidine deaminase antibodies somatic hypermutation class switch recombination 0982
64	Investigations into the Targeting and Substrate Specificity of Activation-induced Deaminase Parsa, Jahan-Yar 18 December 2012 (has links) The processes of secondary antibody diversification are initiated by the mutagenic, B cell specific enzyme, Activation-Induced Deaminase (AID). AID deaminates deoxycytosine (dC) that is located in single-stranded DNA (ssDNA) in actively transcribed DNA to initiate the processes of somatic hypermutation (SHM), gene conversion (GCV) and class switch recombination (CSR) at the antibody gene loci. These processes lead to high affinity antibodies and antibodies of various effector functions that are required to efficiently neutralize invading pathogens. It is currently unclear how the antibody genes are specifically targeted by AID over other genes. I found that AID is able to mutate a non-immunoglobulin (Ig) transgene independent of its chromosomal integration site at rates that were above background mutation rates, but were ~10-fold lower than at the antibody variable (V) region. This result suggests that AID can mutate non-Ig genes at low rates, which may explain AID’s role in oncogenesis, but nevertheless shows that AID preferentially mutates the Ig locus over other loci. While it is understood that AID specifically deaminates dC bases in ssDNA, the size, distribution and origin of these ssDNA substrates is unknown. By utilizing a unique in situ sodium bisulfite assay to detect regions of ssDNA in intact nuclei, I characterized ssDNA regions and found that they are accurate predictors of AID activity during the processes of SHM and CSR in mammalian B cells and E.coli. Importantly, with the use of E.coli models, I show that these ssDNA substrates are the product of transcription-induced negative-supercoiled DNA that correlates strongly with the mutagenic activity of AID. While several underlying mechanisms exist to prevent the mistargeting of AID, my findings suggest that by simply gaining access to ssDNA that is produced by transcription-induced negative supercoiling, AID has the potential to mutate non-Ig genes, albeit at lower rates than the antibody V-region. activation induced cytidine deaminase antibodies somatic hypermutation class switch recombination 0982
65	Discovery of Deaminase Activities in COG1816 Goble, Alissa M 03 October 2013 (has links) Improved sequencing technologies have created an explosion of sequence information that is analyzed and proteins are annotated automatically. Annotations are made based on similarity scores to previously annotated sequences, so one misannotation is propagated throughout databases and the number of misannotated proteins grows with the number of sequenced genomes. A systematic approach to correctly identify the function of proteins in the amidohydrolase superfamily is described in this work using Clusters of Orthologous Groups of proteins as defined by NCBI. The focus of this work is COG1816, which contains proteins annotated, often incorrectly, as adenosine deaminase enzymes. Sequence similarity networks were used to evaluate the relationship between proteins. Proteins previously annotated as adenosine deaminases: Pa0148 (Pseudomonas aeruginosa PAO1), AAur_1117 (Arthrobacter aurescens TC1), Sgx9403e and Sgx9403g, were purified and their substrate profiles revealed that adenine and not adenosine was a substrate for these enzymes. All of these proteins will deaminate adenine with values of kcat/Km that exceed 105 M-1s-1. A small group of enzymes similar to Pa0148 was discovered to catalyze the hydrolysis of N-6-substituted adenine derivatives, several of which are cytokinins, a common type of plant hormone. Patl2390, from Pseudoalteromonas atlantica T6c, was shown to hydrolytically deaminate N-6-isopentenyladenine to hypoxanthine and isopentenylamine with a kcat/Km of 1.2 x 107 M^-1 s^-1. This enzyme does not catalyze the deamination of adenine or adenosine. Two small groups of proteins from COG1816 were found to have 6-aminodeoxyfutalosine as their true substrate. This function is shared with 2 small groups of proteins closely related to guanine and cytosine deaminase from COG0402. The deamination of 6-aminofutalosine is part of the alternative menaquinone biosynthetic pathway that involves the formation of futalosine. 6-Aminofutalosine is deaminated with a catalytic effeciency of 105 M-1s-1 or greater, Km’s of 0.9 to 6.0 µM and kcat’s of 1.2 to 8.6 s-1. Another group of proteins was shown to deaminate cyclic- 3’, 5’ -adenosine monophosphate (cAMP) to produce cyclic-3’, 5’-inosine monophosphate, but will not deaminate adenosine, adenine or adenosine monophosphate. This protein was cloned from a human pathogen, Leptospira interrogans. Deamination may function in regulating the signaling activities of cAMP. deaminase enzyme adenosine adenine cytokinin cyclic-3' 5'-adenosine monophosphate function discovery amidohydrolase
66	Novel sites of A-to-I RNA editing in the mammalian brain / Ohlson, Johan, January 2007 (has links) Diss. (sammanfattning) Stockholm : Stockholms universitet, 2007. / Härtill 4 uppsatser.
67	Adenosina deaminase em trichomonas vaginalis : estudo da localização celular e do efeito de nutrientes essenciais Barros, Muriel Primon de January 2013 (has links) Trichomonas vaginalis é o protozoário flagelado que parasita o trato urogenital humano causando a tricomonose, doença sexualmente transmissível (DST) de origem não viral mais comum no mundo. Durante a infecção a aquisição de nutrientes, como nucleotídeos púricos, pirimidínicos e ferro é essencial à sobrevivência do parasito. T. vaginalis não sintetiza de novo purinas e pirimidinas, dependendo de vias de salvação para aquisição destas moléculas. O ferro desempenha um papel crucial na patogenicidade da tricomonose, influenciando a expressão de múltiplos genes envolvidos na virulência. Nucleotídeos extracelulares, especialmente o ATP, são liberados em situações de estresse, anoxia ou injúria, atuando como sinalizadores pró-inflamatórios ao sistema imune. As enzimas NTPDase e ecto-5'-nucleotidase degradam ATP à adenosina, esta com ação anti-inflamatória. A enzima adenosina deaminase (ADA) degrada adenosina à inosina. A presença desta cadeia enzimática em T. vaginalis sugere a modulação das concentrações nucleotídeos/nucleosídeos durante a inflamação. A atividade da ADA foi caracterizada em T. vaginalis, porém há poucos relatos sobre a participação desta enzima na sobrevivência do parasito, bem como, a localização celular e o efeito de nutrientes essenciais na atividade enzimática e na expressão gênica. O estudo da localização da ADA em T. vaginalis foi realizado, indicando a presença da enzima na membrana celular e no citoplasma do trofozoíto. Avaliando-se o perfil da ADA de diferentes isolados de T. vaginalis em uma condição de limitação de soro bovino, o qual representa a fonte de adenosina aos trofozoítos, não se observou diferenças significativas na deaminação da adenosina à inosina. Na avaliação do efeito de diferentes fontes de ferro ou a privação deste cátion na atividade e na expressão gênica da ADA foi possível verificar uma diminuição da atividade e um aumento na expressão gênica após a privação do ferro, reforçando a hipótese que este elemento pode modular a atividade das enzimas envolvidas na sinalização purinérgica. Os resultados obtidos nesta dissertação permitem a avaliação de importantes aspectos da ADA, contribuindo para o melhor entendimento do sistema purinérgico em T. vaginalis e seu papel no estabelecimento e manutenção da infecção e consequente sobrevivência do parasito. / Trichomonas vaginalis is a flagellate protozoan that parasitizes the urogenital human tract causing trichomonosis, the non-viral sexually transmitted disease (STD) most common in the world. During infection the acquisition of nutrients such as purine and pyrimidine nucleotides, and iron is essential to the parasite survival. T. vaginalis lacks de novo purines and pyrimidines synthesis depending on the salvation pathway for the acquisition of these molecules. Iron plays a crucial role in trichomonosis pathogenesis, influencing the expression of multiple genes involved in virulence. Extracellular nucleotides, especially ATP, are released during stress, injury or anoxia, acting as a pro-inflammatory signaling to the immune system. The enzymes NTPDase and ecto-5'-nucleotidase degrade ATP to adenosine with anti-inflammatory action. The adenosine deaminase (ADA) enzyme degrades adenosine to inosine. The presence of this enzymatic chain in T. vaginalis suggests the modulation of nucleotides/nucleosides concentrations during inflammation. The ADA activity was characterized in T. vaginalis, but there are few reports on the participation of this enzyme in the parasite survival, as well as the cellular localization and the effect of essential nutrients on enzyme activity and gene expression. The study of ADA localization in T. vaginalis was performed, indicating the presence of the enzyme on trophozoite cell membrane and cytoplasm. Evaluating the ADA profile in different T. vaginalis isolates in bovine serum limitation condition, which is the source of adenosine for the trophozoites, no significant differences were observed in the deamination of adenosine to inosine. Regarding the effect of different iron sources or iron deprivation in activity and gene expression of ADA, it was observed a decrease in activity and an increase in gene expression after iron deprivation, reinforcing the hypothesis that this element can modulate the activity of enzymes involved in the purinergic signaling. The results obtained in this study allow the assessment of important aspects of ADA, contributing to a better understanding of the purinergic system in T. vaginalis and its role in the establishment and maintenance of infection and consequent survival of the parasite. Adenosina desaminase Trichomonas vaginalis Sistema purinérgico Parasitologia Purinergic system Adenosine deaminase Cellular localization Essential nutrients
68	Adenosina deaminase em trichomonas vaginalis : estudo da localização celular e do efeito de nutrientes essenciais Barros, Muriel Primon de January 2013 (has links) Trichomonas vaginalis é o protozoário flagelado que parasita o trato urogenital humano causando a tricomonose, doença sexualmente transmissível (DST) de origem não viral mais comum no mundo. Durante a infecção a aquisição de nutrientes, como nucleotídeos púricos, pirimidínicos e ferro é essencial à sobrevivência do parasito. T. vaginalis não sintetiza de novo purinas e pirimidinas, dependendo de vias de salvação para aquisição destas moléculas. O ferro desempenha um papel crucial na patogenicidade da tricomonose, influenciando a expressão de múltiplos genes envolvidos na virulência. Nucleotídeos extracelulares, especialmente o ATP, são liberados em situações de estresse, anoxia ou injúria, atuando como sinalizadores pró-inflamatórios ao sistema imune. As enzimas NTPDase e ecto-5'-nucleotidase degradam ATP à adenosina, esta com ação anti-inflamatória. A enzima adenosina deaminase (ADA) degrada adenosina à inosina. A presença desta cadeia enzimática em T. vaginalis sugere a modulação das concentrações nucleotídeos/nucleosídeos durante a inflamação. A atividade da ADA foi caracterizada em T. vaginalis, porém há poucos relatos sobre a participação desta enzima na sobrevivência do parasito, bem como, a localização celular e o efeito de nutrientes essenciais na atividade enzimática e na expressão gênica. O estudo da localização da ADA em T. vaginalis foi realizado, indicando a presença da enzima na membrana celular e no citoplasma do trofozoíto. Avaliando-se o perfil da ADA de diferentes isolados de T. vaginalis em uma condição de limitação de soro bovino, o qual representa a fonte de adenosina aos trofozoítos, não se observou diferenças significativas na deaminação da adenosina à inosina. Na avaliação do efeito de diferentes fontes de ferro ou a privação deste cátion na atividade e na expressão gênica da ADA foi possível verificar uma diminuição da atividade e um aumento na expressão gênica após a privação do ferro, reforçando a hipótese que este elemento pode modular a atividade das enzimas envolvidas na sinalização purinérgica. Os resultados obtidos nesta dissertação permitem a avaliação de importantes aspectos da ADA, contribuindo para o melhor entendimento do sistema purinérgico em T. vaginalis e seu papel no estabelecimento e manutenção da infecção e consequente sobrevivência do parasito. / Trichomonas vaginalis is a flagellate protozoan that parasitizes the urogenital human tract causing trichomonosis, the non-viral sexually transmitted disease (STD) most common in the world. During infection the acquisition of nutrients such as purine and pyrimidine nucleotides, and iron is essential to the parasite survival. T. vaginalis lacks de novo purines and pyrimidines synthesis depending on the salvation pathway for the acquisition of these molecules. Iron plays a crucial role in trichomonosis pathogenesis, influencing the expression of multiple genes involved in virulence. Extracellular nucleotides, especially ATP, are released during stress, injury or anoxia, acting as a pro-inflammatory signaling to the immune system. The enzymes NTPDase and ecto-5'-nucleotidase degrade ATP to adenosine with anti-inflammatory action. The adenosine deaminase (ADA) enzyme degrades adenosine to inosine. The presence of this enzymatic chain in T. vaginalis suggests the modulation of nucleotides/nucleosides concentrations during inflammation. The ADA activity was characterized in T. vaginalis, but there are few reports on the participation of this enzyme in the parasite survival, as well as the cellular localization and the effect of essential nutrients on enzyme activity and gene expression. The study of ADA localization in T. vaginalis was performed, indicating the presence of the enzyme on trophozoite cell membrane and cytoplasm. Evaluating the ADA profile in different T. vaginalis isolates in bovine serum limitation condition, which is the source of adenosine for the trophozoites, no significant differences were observed in the deamination of adenosine to inosine. Regarding the effect of different iron sources or iron deprivation in activity and gene expression of ADA, it was observed a decrease in activity and an increase in gene expression after iron deprivation, reinforcing the hypothesis that this element can modulate the activity of enzymes involved in the purinergic signaling. The results obtained in this study allow the assessment of important aspects of ADA, contributing to a better understanding of the purinergic system in T. vaginalis and its role in the establishment and maintenance of infection and consequent survival of the parasite. Adenosina desaminase Trichomonas vaginalis Sistema purinérgico Parasitologia Purinergic system Adenosine deaminase Cellular localization Essential nutrients
69	Adenosina deaminase em trichomonas vaginalis : estudo da localização celular e do efeito de nutrientes essenciais Barros, Muriel Primon de January 2013 (has links) Trichomonas vaginalis é o protozoário flagelado que parasita o trato urogenital humano causando a tricomonose, doença sexualmente transmissível (DST) de origem não viral mais comum no mundo. Durante a infecção a aquisição de nutrientes, como nucleotídeos púricos, pirimidínicos e ferro é essencial à sobrevivência do parasito. T. vaginalis não sintetiza de novo purinas e pirimidinas, dependendo de vias de salvação para aquisição destas moléculas. O ferro desempenha um papel crucial na patogenicidade da tricomonose, influenciando a expressão de múltiplos genes envolvidos na virulência. Nucleotídeos extracelulares, especialmente o ATP, são liberados em situações de estresse, anoxia ou injúria, atuando como sinalizadores pró-inflamatórios ao sistema imune. As enzimas NTPDase e ecto-5'-nucleotidase degradam ATP à adenosina, esta com ação anti-inflamatória. A enzima adenosina deaminase (ADA) degrada adenosina à inosina. A presença desta cadeia enzimática em T. vaginalis sugere a modulação das concentrações nucleotídeos/nucleosídeos durante a inflamação. A atividade da ADA foi caracterizada em T. vaginalis, porém há poucos relatos sobre a participação desta enzima na sobrevivência do parasito, bem como, a localização celular e o efeito de nutrientes essenciais na atividade enzimática e na expressão gênica. O estudo da localização da ADA em T. vaginalis foi realizado, indicando a presença da enzima na membrana celular e no citoplasma do trofozoíto. Avaliando-se o perfil da ADA de diferentes isolados de T. vaginalis em uma condição de limitação de soro bovino, o qual representa a fonte de adenosina aos trofozoítos, não se observou diferenças significativas na deaminação da adenosina à inosina. Na avaliação do efeito de diferentes fontes de ferro ou a privação deste cátion na atividade e na expressão gênica da ADA foi possível verificar uma diminuição da atividade e um aumento na expressão gênica após a privação do ferro, reforçando a hipótese que este elemento pode modular a atividade das enzimas envolvidas na sinalização purinérgica. Os resultados obtidos nesta dissertação permitem a avaliação de importantes aspectos da ADA, contribuindo para o melhor entendimento do sistema purinérgico em T. vaginalis e seu papel no estabelecimento e manutenção da infecção e consequente sobrevivência do parasito. / Trichomonas vaginalis is a flagellate protozoan that parasitizes the urogenital human tract causing trichomonosis, the non-viral sexually transmitted disease (STD) most common in the world. During infection the acquisition of nutrients such as purine and pyrimidine nucleotides, and iron is essential to the parasite survival. T. vaginalis lacks de novo purines and pyrimidines synthesis depending on the salvation pathway for the acquisition of these molecules. Iron plays a crucial role in trichomonosis pathogenesis, influencing the expression of multiple genes involved in virulence. Extracellular nucleotides, especially ATP, are released during stress, injury or anoxia, acting as a pro-inflammatory signaling to the immune system. The enzymes NTPDase and ecto-5'-nucleotidase degrade ATP to adenosine with anti-inflammatory action. The adenosine deaminase (ADA) enzyme degrades adenosine to inosine. The presence of this enzymatic chain in T. vaginalis suggests the modulation of nucleotides/nucleosides concentrations during inflammation. The ADA activity was characterized in T. vaginalis, but there are few reports on the participation of this enzyme in the parasite survival, as well as the cellular localization and the effect of essential nutrients on enzyme activity and gene expression. The study of ADA localization in T. vaginalis was performed, indicating the presence of the enzyme on trophozoite cell membrane and cytoplasm. Evaluating the ADA profile in different T. vaginalis isolates in bovine serum limitation condition, which is the source of adenosine for the trophozoites, no significant differences were observed in the deamination of adenosine to inosine. Regarding the effect of different iron sources or iron deprivation in activity and gene expression of ADA, it was observed a decrease in activity and an increase in gene expression after iron deprivation, reinforcing the hypothesis that this element can modulate the activity of enzymes involved in the purinergic signaling. The results obtained in this study allow the assessment of important aspects of ADA, contributing to a better understanding of the purinergic system in T. vaginalis and its role in the establishment and maintenance of infection and consequent survival of the parasite. Adenosina desaminase Trichomonas vaginalis Sistema purinérgico Parasitologia Purinergic system Adenosine deaminase Cellular localization Essential nutrients
70	ATIVIDADE DA ADENOSINA DESAMINASE NO SORO E NOS LINFÓCITOS DE RATOS INFECTADOS POR Sporothrix schenckii / ADENOSINE DEAMINASE ACTIVITY IN SERUM AND LYMPHOCYTES OF RATS INFECTED BY Sporothrix schenckii Castro, Verônica Souza Paiva 03 October 2011 (has links) Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Sporotrichosis is a subcutaneous fungal infection of evolution subacute or chronic, inflammatory lesions characterized by pyogranulomatous aspect, caused by the dimorphic fungus Sporothrix schenckii. Adenosine deaminase (ADA) is a key enzyme in the purine metabolism, promoting the deamination of adenosine, an important anti-inflammatory molecule. The increase in ADA activity has been demonstrated in several inflammatory conditions, however, no data in the literature associated with this fungal infection. The objective of this study was to evaluate the activity of serum ADA (S-ADA) and lymphocytes (L-ADA) of rats infected with S. schenckii. We used seventy-eight rats divided into two groups. In the first experiment, rats were infected subcutaneously and in the second experiment, infected intraperitoneally. Blood samples for hematologic evaluation and activities of S-ADA and ADA-L were performed on days 15, 30 and 40 post-infection (PI) to assess disease progression. In experiment II, was observed in an acute decrease in activity of S-ADA and L-ADA (p <0.05), suggesting a compensatory mechanism in the body's attempt to protect the host from excessive tissue damage. Chronicity of the disease the rats in the experiment I and II at 30 days PI, showed an increased activity of L-ADA (p <0.05), promoting an inflammatory response in an attempt to combat the spread of the agent. Thus, it is suggested that infection with S. schenckii alters the activities of S-ADA experimentally infected rats, demonstrating the involvement of this enzyme in the pathogenesis of sporotrichosis. / A esporotricose é uma infecção micótica subcutânea de evolução subaguda ou crônica, caracterizada por lesões inflamatórias de aspecto piogranulomatoso, causada pelo fungo dimórfico Sporothrix schenckii. A adenosina desaminase (ADA) é uma enzima chave no metabolismo das purinas, promovendo a desaminação da adenosina uma importante molécula anti-inflamatória. O aumento na atividade da ADA tem sido demonstrado em várias condições inflamatórias, porém, não existem dados na literatura associados com esta infecção micótica. O objetivo deste estudo foi avaliar a atividade da ADA no soro (S-ADA) e nos linfócitos (L-ADA) de ratos infectados por S. schenckii. Foram utilizados setenta e oito ratos distribuídos em dois grupos. No experimento I, os ratos foram infectados por via subcutânea e no experimento II, infectados por via intraperitoneal. A coleta de sangue para a avaliação hematológica e atividades da S-ADA e L-ADA foram realizadas nos dias 15, 30 e 40 pós-infecção (PI), para avaliar a evolução da doença. No experimento II, foi observada na fase aguda uma diminuição na atividade da S-ADA e L-ADA (p<0.05), sugerindo um mecanismo compensatório do organismo na tentativa de proteger o hospedeiro da lesão tecidual excessiva. Com a cronicidade da enfermidade os ratos do experimento I e II aos 30 dias PI, apresentaram um aumento na atividade da L-ADA (p<0.05), promovendo uma resposta inflamatória na tentativa de combater a proliferação do agente. Assim, sugere-se que a infecção pelo S. schenckii altera as atividades da S-ADA e L-ADA de ratos infectados experimentalmente, demonstrando o envolvimento desta enzima na patogênese da esporotricose. Esporotricose Adenosina desaminase Linfócitos Soro Sporotrichosis Adenosine deaminase Lymphocytes Serum

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