Significance of Methylthioadenosine Metabolism to Plant Growth and Development

Waduwara-Jayabahu, Chammika Ishari

06 November 2014

Arabidopsis thaliana contains two genes annotated as methylthioadenosine nucleosidases (MTN): MTN1, At4g38800 and MTN2, At4g34840. This enzyme activity hydrolyzes the methylthioadenosine (MTA) produced by nicotianamine (NA), polyamine (PA), and ethylene biosynthesis to methylthioribose (MTR) within the Yang cycle. Comprehensive analysis of the mtn1-1mtn2-1 mutant line with 14 % residual MTN activity revealed a complex phenotype that includes male and female infertility and abnormal vascular development. Based on metabolite profiling, mtn1-1mtn2-1 has a reduced NA content, altered PA profiles with higher putrescine (Put) and lower spermidine (Spd) and spermine (Spm) levels, disrupted metal ion profiles, and abnormal auxin distribution. The modeling of Arabidopsis PA synthases developed by comparison with the crystal structures of human Spd and spermine synthases complexed with MTA suggests that Arabidopsis PA synthases are product inhibited by MTA. Thus, these pleiotropic mutant phenotypes possibly are the result of one metabolite directly inhibiting numerous pathways. By creating and analyzing a series of mutants and transgenic lines with moderate levels of MTN activity the complex phenotype of mtn1-1mtn2-1 was dissected in order to determine the fundamental trait associated with MTN deficiency. Two double mutants were identified by crossing single T-DNA mutants, and an artificial micro RNA (amiRNA) line was generated by transforming mtn1-1 with amiRNA specific to MTN2. The T-DNA double mutants, mtn1 4mtn2-1, and mtn1-1mtn2-5 had 98 % and 28 % MTN activity, respectively, whereas the amiRNA line has 16 % MTN activity. The growth, development, and metabolite analysis of these mutants revealed that their delayed bolting, correlated with an increased number of leaves, was the common trait observed across all lines. Xylem proliferation defects and increased number of vascular bundles per unit area were shared in all lines except mtn1 4mtn2-1. Based on these results, auxin distribution is proposed as the key target of the accumulated MTA that results from MTN deficiency. The infertility related to MTN-deficiency was restored by supplying 100 ??M of Spd to the mtn1-1mtn2-1 seedlings over 14 days. The data presented in this thesis reveals two potential links that work synergistically to recover fertility in this mtn1-1mtn2-1 line. Based on a detailed analysis of the female gynoecia morphology, transcript, hormone and metabolite profiles, it is proposed that the Spd partially reverses the mutant phenotypes through the recovery of auxin distribution and /or vascular development. Interestingly, the Spd effect seems to be transgenerational: they give rise to plants that are genotypically mtn1-1mtn2-1 but phenotypically WT over generations. Taken together, all of the results suggest that MTN-deficient mutants provide the potential for unraveling the molecular mechanism associated with nicotianamine, polyamines, auxin, and vascular development with respect to enhancing the efficiency of nutrient use and yields in plants.

methylthioadenosine nucleosidases

methylthioadenosine

polyamine

Yang cycle

vascular development

auxin

Cytotoxic methylthioadenosine analogues

Doerksen, Thomas

09 September 2016

The gene for methylthioadenosine phosphorylase (MTAP) is absent in almost 30% of cancers, opening a door for selective chemotherapy. One strategy to target the absence of MTAP involves the design of a cytotoxic methylthioadenosine (MTA) analogue. Non-cancerous cells would break down the cytotoxic analogue, since they contain MTAP, but cancerous cells would not, since they do not have MTAP. However, before such a compound can be made, we need to better understand the types of substrates accommodated by MTAP. The purpose of this thesis was therefore to explore a series of MTA analogues, probing the structure-function relationships between MTAP and specific structural modifications of MTA. Nine phenylthioadenosine (PTA) derivatives bearing ortho-, meta-, or para- methyl carboxylate, carboxylate, and hydroxymethyl substituents were synthesized and tested for cytotoxicity and as substrates for MTAP. The biological results of these nine compounds suggested that addition of substituents to the ortho-position was not tolerated by MTAP, and substituents similar to the hydroxymethyl might be accommodated by MTAP. None of the compounds were cytotoxic. This informed the design of ten more PTA derivatives, most of which were synthesized and tested for cytotoxicity and as substrates for MTAP. The range of functionalities included an amine, an acetamide, a urea, an isovaleramide, and an N-nitrosourea group inspired by the known anticancer agent lomustine. The amine derivatives of PTA were the best substrates of all MTA analogues tested (including PTA). The meta-amine derivative and the meta-isovaleramide showed minor cytotoxicity. Finally, the urea derivatives were moderate substrates of MTAP, and this pointed towards the future creation of other nitrosoureas as potential cytotoxic MTAP substrates. / Graduate / 2017-08-25

Drug discovery

Chemotherapy

Methylthioadenosine phosphorylase

Chemical synthesis

Methylthioadenosine

Methylthioadenosine analogue

Cytotoxicity

MTAP

Characterization of the Substrate Specificity and Catalytic Mechanism of 5'-Methylthioadenosine/S-adenosylhomocysteine nucleosidase

Siu, Karen Ka Wing

17 February 2011

Methionine is essential for proper functioning of cellular processes such as protein synthesis, transmethylation and polyamine synthesis. Efficient recycling of methionine is important because of its limited bioavailability and metabolically expensive de novo synthesis. Further, cellular accretion of the nucleoside metabolites of the methionine salvage pathway compromises polyamine biosynthesis, transmethylation reactions and quorum sensing pathways, all critical reactions in cellular metabolism. 5’-methylthioadenosine/S-adenosylhomocysteine nucleosidase (MTAN) is a key component of the methionine salvage pathway of plants and many bacterial species, including Escherichia coli, Enterococcus faecalis, Salmonella typhimerium, Haemophilus influenza and Streptococcus pneumoniae. In bacteria, this enzyme displays dual-substrate specificity for two methionine metabolites, 5’-methylthioadenosine (MTA) and S-adenosylhomocysteine (SAH), and catalyzes the irreversible cleavage of the glycosidic bond to form adenine and the corresponding thioribose products, methylthioribose (MTR) and S-ribosylhomocysteine (SRH), respectively. In plants, MTAN is highly specific towards MTA and shows 0-16 % activity towards SAH. Plants rely on SAH hydrolase to metabolize SAH. Mammals do not have the nucleosidase enzyme and MTA is metabolized by MTA phosphorylase (MTAP). Like plants, mammals utilize SAH hydrolase to degrade SAH. Because MTAN is required for viability in multiple bacterial species and is not found in humans, it has been identified as a target for novel antibiotic development. This thesis describes the structural and functional characterization of bacterial and plant MTANs, with the aim of better understanding the molecular determinants of substrate specificity and the catalytic mechanism of this enzyme. The catalytic activities of representative plant MTANs from Arabidopsis thaliana, AtMTAN1 and AtMTAN2, were kinetically characterized. While AtMTAN2 shows 14 % activity towards SAH relative to MTA, AtMTAN1 is completely inactive towards SAH. As such, AtMTAN1 was selected for further examination and comparison with the bacterial MTAN from Escherichia coli (EcMTAN). The structures, dynamics and thermodynamic properties of these enzymes were analyzed by X-ray crystallography, hydrogen-exchange coupled mass spectrometry and isothermal titration calorimetry, respectively. Our studies reveal that structural differences alone do not sufficiently explain the divergence in substrate specificity, and that conformational flexibility also plays an important role in substrate selection in MTANs. MTANs from the pathogenic bacterial species, Staphylococcus aureus and Streptococcus pneumoniae, were examined kinetically and structurally. Comparison of the structures and catalytic activities of these enzymes with EcMTAN shows that the discrepancies in kinetic activities arefully explained by structural differences, as the overall structure and active sites of these bacterial MTANs are nearly identical. These experiments are in agreement with our proposal that dynamics play a significant role in catalytic activity of MTAN, and suggest that both structure and dynamics must be considered in future antibiotic design. To further our understanding on the catalytic mechanism of MTAN, the putative catalytic residues of AtMTAN1 were identified by structural comparison to EcMTAN and mutated by site-directed mutagenesis. The AtMTAN1 mutants were analyzed by circular dichroism and kinetic studies. Our results suggest that the catalytic mechanism is largely conserved between bacterial and plant MTANs, although the role of the putative catalytic acid remains to be confirmed.

Characterization of the Substrate Specificity and Catalytic Mechanism of 5'-Methylthioadenosine/S-adenosylhomocysteine nucleosidase

Siu, Karen Ka Wing

17 February 2011

Methionine is essential for proper functioning of cellular processes such as protein synthesis, transmethylation and polyamine synthesis. Efficient recycling of methionine is important because of its limited bioavailability and metabolically expensive de novo synthesis. Further, cellular accretion of the nucleoside metabolites of the methionine salvage pathway compromises polyamine biosynthesis, transmethylation reactions and quorum sensing pathways, all critical reactions in cellular metabolism. 5’-methylthioadenosine/S-adenosylhomocysteine nucleosidase (MTAN) is a key component of the methionine salvage pathway of plants and many bacterial species, including Escherichia coli, Enterococcus faecalis, Salmonella typhimerium, Haemophilus influenza and Streptococcus pneumoniae. In bacteria, this enzyme displays dual-substrate specificity for two methionine metabolites, 5’-methylthioadenosine (MTA) and S-adenosylhomocysteine (SAH), and catalyzes the irreversible cleavage of the glycosidic bond to form adenine and the corresponding thioribose products, methylthioribose (MTR) and S-ribosylhomocysteine (SRH), respectively. In plants, MTAN is highly specific towards MTA and shows 0-16 % activity towards SAH. Plants rely on SAH hydrolase to metabolize SAH. Mammals do not have the nucleosidase enzyme and MTA is metabolized by MTA phosphorylase (MTAP). Like plants, mammals utilize SAH hydrolase to degrade SAH. Because MTAN is required for viability in multiple bacterial species and is not found in humans, it has been identified as a target for novel antibiotic development. This thesis describes the structural and functional characterization of bacterial and plant MTANs, with the aim of better understanding the molecular determinants of substrate specificity and the catalytic mechanism of this enzyme. The catalytic activities of representative plant MTANs from Arabidopsis thaliana, AtMTAN1 and AtMTAN2, were kinetically characterized. While AtMTAN2 shows 14 % activity towards SAH relative to MTA, AtMTAN1 is completely inactive towards SAH. As such, AtMTAN1 was selected for further examination and comparison with the bacterial MTAN from Escherichia coli (EcMTAN). The structures, dynamics and thermodynamic properties of these enzymes were analyzed by X-ray crystallography, hydrogen-exchange coupled mass spectrometry and isothermal titration calorimetry, respectively. Our studies reveal that structural differences alone do not sufficiently explain the divergence in substrate specificity, and that conformational flexibility also plays an important role in substrate selection in MTANs. MTANs from the pathogenic bacterial species, Staphylococcus aureus and Streptococcus pneumoniae, were examined kinetically and structurally. Comparison of the structures and catalytic activities of these enzymes with EcMTAN shows that the discrepancies in kinetic activities arefully explained by structural differences, as the overall structure and active sites of these bacterial MTANs are nearly identical. These experiments are in agreement with our proposal that dynamics play a significant role in catalytic activity of MTAN, and suggest that both structure and dynamics must be considered in future antibiotic design. To further our understanding on the catalytic mechanism of MTAN, the putative catalytic residues of AtMTAN1 were identified by structural comparison to EcMTAN and mutated by site-directed mutagenesis. The AtMTAN1 mutants were analyzed by circular dichroism and kinetic studies. Our results suggest that the catalytic mechanism is largely conserved between bacterial and plant MTANs, although the role of the putative catalytic acid remains to be confirmed.

Structural Analysis of 5'-Methylthioadenosine/S-Adenosylhomocysteine Nucleosidase from Helicobacter pylori for the Purpose of Drug Development

Iacopelli, Natalie Marie

23 September 2009

No description available.

Biochemistry

5'-Methylthioadenosine

S-Adenosylhomocysteine

Nucleosidase

Caracterização estrutural e funcional de duas Nucleosídeo Fosforilases de Schistosoma mansoni / Structural and functional characterization of two Nucleoside Phosphorylase from Schistosoma mansoni.

Souza, Juliana Roberta Torini de

18 August 2016

As doenças parasitárias são uma das maiores causas de morte em países em desenvolvimento, e recebem pouca ou nenhuma atenção das indústrias farmacêuticas para o desenvolvimento de terapias. Causada pelo parasita Schistosoma mansoni a esquistossomose mansônica afeta aproximadamente 259 milhões de pessoas no mundo sendo aproximadamente 6 milhões somente no Brasil. O S. mansoni não possui a via \"de novo\" para a biossíntese de bases púricas e depende integralmente da via de salvação para o suprimento dessas bases, portanto, essa via é um alvo em potencial. Agentes capazes de bloquear a atividade das enzimas participantes desta via atuam de forma inespecífica e são quase sempre tóxicos ao homem e por isso o estudo minucioso das pequenas diferenças encontradas entre as enzimas do hospedeiro e do parasita são de extrema importância. Uma diferença marcante entre a via de salvação de purinas do parasita e do hospedeiro humano é a presença de atividade para adenosina fosforilase, que no parasita é exercida por duas entidades distintas: pela enzima Metiltioadenosina fosforilase de S. mansoni (SmMTAP) e por uma enzima até então desconhecida. A enzima SmMTAP naturalmente converte 5\'-deoxi-5\'-metiltioadenosina (MTA) em adenina livre, mas ao contrário do que é visto no hospedeiro, no parasita essa enzima atua preferencialmente na conversão de adenosina. Substituições encontradas no sítio ativo dessa enzima, podem explicar tamanha preferência pelo substrato alternativo, revelando mecanismos distintos da enzima humana. A enzima Purina nucleosídeo fosforilase de S. mansoni (SmPNP) converte inosina e guanosina à hipoxantina e guanina, respectivamente, mas não possui atividade catalítica para adenosina. No entanto, no genoma de S. mansoni é descrita uma isoforma para a SmPNP (SmPNP2), cuja atividade catalítica é desconhecida e, portanto, essa enzima pode também atuar na conversão de adenosina juntamente com a SmMTAP. Assim, os objetivos deste trabalho foram realizar estudos bioquímicos da ação da enzima SmMTAP e realizar a caracterização estrutural e funcional da enzima SmPNP2. Para isso, foram realizadas mutações no sítio ativo da SmMTAP (S12T, N87T, Q289L, S12T/N87T e S12T/N87T/Q289L), as mutantes da SmMTAP juntamente com a enzima SmPNP2 foram clonadas, expressas de forma heteróloga e purificadas. Foram realizados ensaios de cristalização e cinéticos por espectrofotometria utilizando um sistema acoplado. A atividade da SmPNP2 foi ainda avaliada por calorimetria e HPLC. Foram determinadas as constantes catalíticas da forma nativa e para os cinco mutantes da SmMTAP para cinco diferentes substratos. Foi determinada atividade catalítica da SmPNP2 por 3 diferentes substratos: adenosina, inosina e citidina, as constantes catalíticas foram determinadas para os três substratos. Foram obtidos cristais para os mutantes da SmMTAP e da SmPNP2, que foram submetidos à difração de raios X nas linhas I04-1 e I02 do laboratório de radiação síncrotron Diamond Light Source (DLS). Foram resolvidas 9 estruturas dos mutantes da SmMTAP e 4 da proteína SmPNP2. Os dados cinéticos, juntamente com os dados estruturais, permitiram compreender mecanismos catalíticos e de interação das proteínas estudadas, complementando o conhecimento do metabolismo do parasita Schistosoma mansoni e revelando alvos em potencial para o desenvolvimento de fármacos específicos. / The parasitic illness are the leading cause of deaths in developing countries, and receives little or no attention from drug companies to develop therapies. The schistosomiasis is caused by Schistosoma mansoni parasite and affects approximately 259 million people worldwide with 6 million only in Brazil. The Schistosoma mansoni parasite does not possess the \"de novo\" pathway for purine bases biosynthesis and depends entirely on salvage pathway for its purine requirement, therefore this pathway is a potential target. Compounds able to block the enzymes from this pathway, are not specific and are often toxic to humans, thus the thorough study about the particularity found between enzymes from host and parasite are extremely important. A notable difference between human and parasite metabolism, is the activity existence to Adenosine phosphorylase that in parasite is carried out by two distinct entities: by Methylthioadenosine phosphorylase (SmMTAP) and by a hitherto unknown enzyme. The SmMTAP enzyme, naturally converts 5\'-deoxy-5\'-methylthioadenosine (MTA) to free adenine and in opposition to host, in the parasite this enzyme acts manly in adenosine conversion. Substitutions found in the active site from SmMTAP, can explain the huge preference by alternative substrate and to expose a distinct mechanisms from human enzyme. The Purine nucleoside Phosphorylase from S. mansoni (SmPNP) converts inosine and guanosine to hypoxanthine and guanine, respectively, but it not possess catalytic activity to adenosine conversion. However in the S. mansoni genome there is a isoform to SmPNP, whose activity is unknown, thus is possible that SmPNP2 enzyme also can to convert adenosine. This study aimed to perform biochemical studies to investigate the SmMTAP enzyme action and perform the structural and functional characterization of SmPNP2. For this propose was made site-directed mutagenesis (S12T, N87T, Q289L, S12T/N87T e S12T/N87T/Q289L). The SmMTAP mutants and SmPNP2 enzyme were cloned, expressed by heterolog process and purified. Were perform kinetic assays by spectrophotometric method in a coupled system. The SmPNP2 activity was also available by calorimetry and HPLC methods. Were determined the catalytic constants to wild and mutants SmMTAP to five different substrate. Was determinated to SmPNP2 catalictical activity and kinetics parameters to three substrate: adenosine, inosine e cytidine. Were obtained crystals from SmMTAP mutants and SmPNP2 enzyme, those crystals were submitted to X-rays diffractions in the I04-1 and I02 beamlines from Diamond Light Source (DLS). Nine structures were obtained from SmMTAP mutants and four from SmPNP2 enzyme. The kinetics and structural data allowed understanding the catalytic and interaction mechanisms about the protein studied, supplementing the knowledge around Schistosoma mansoni metabolism and reporting potential targets for the specific drugs development.

Schistosoma mansoni

Schistosoma mansoni

Methylthioadenosine phosphorylase

Metiltioadenosina fosforilase

Purina nucleosideo fosforilase

Purine nucleoside phosphorylase

Determinação estrutural e funcional da enzima 5´-deoxi-5´-metiltioadenosina Fosforilase de Schistosoma mansoni / Structural and Functional Determination of 5´-deoxy-5´-methylthioadenosine Phosphorylase enzyme from Schistosoma mansoni

Souza, Juliana Roberta Torini de

16 April 2012

As doenças parasitárias são uma das maiores causas de morte em países em desenvolvimento, e recebem pouca ou nenhuma atenção das indústrias farmacêuticas para o desenvolvimento de terapias. A esquistossomose mansoni também conhecida como barriga d´água ou doença do caramujo é uma doença parasitária crônica que afeta aproximadamente 207 milhões de pessoas no mundo sendo aproximadamente 6 milhões somente no Brasil. Os medicamentos disponíveis no mercado causam graves efeitos colaterais. Além disso, há relatos de cepas de S. mansoni resistentes à esses medicamentos, justificando assim a busca por novos fármacos. O Schistosoma mansoni não possui a via de novo para a biosíntese de bases púricas e depende integralmente da via de salvação para o suprimento dessa. Assim, este trabalho teve como objetivo determinar as constantes catalíticas e a estrutura tridimensional da MTAP (EC 2.4.2.28), enzima esta que participam da via de salvação de purinas, e é desta forma essencial para a reprodução do parasita. Esta enzima foi expressa de forma heteróloga, purificada e cristalizada. A proteína foi submetida à ensaios cinéticos em sistema acoplado, onde foram determinadas as constantes catalíticas. A proteína foi também cristalizada em condições que continham 100 mM de Bis-tris ou MES com pH variando entre 6,1 a 6,5 e PEG3350, cuja concentração variou ente 14-18%. Os cristais foram submetidos à difração de raios-X no LNLS e no DLS. Foram obtidos, quatro conjuntos de dados, que foram processados, refinados e analisados. Obteve-se estrutura apoenzima em complexo com fosfato, em complexo com adenina e sulfato, em complexo com tubercidina e sulfato e em complexo com adenina e glicerol em um grupo espacial diferente dos demais. Através da estrutura secundária, foi possível analisar o sítio ativo, além de obter informações preliminares do mecanismo catalítico da enzima alvo. Este trabalho colabora para a futura elucidação completa da via de salvação de purinas em S. mansoni, e fornece informações básicas para que a busca por novos fármacos tenha novos ramos a serem explorados. / The parasitic illness are the leading cause of deaths in developing countries, and receives little or no attention from drug companies to develop therapies. Schistosomiasis mansoni also known as water belly or snail´s disease is a chronic parasitic illness that affects approximately 207 million people worldwide with approximately 6 million in Brazil. Schistosomiasis is treated by the use of drugs that are not-in fact effective for the eradication of the disease, and although their efficiency cause serious side effects. In addition, there are reports of S. mansoni´s resistant strains to these drugs, thus justifying the search for new drugs. The Schistosoma mansoni parasite does not possess the de novo pathway for purine bases biosynthesis and depends entirely on salvage pathways for its purine requirement. Thus this study aimed to determine the catalytic constants and three-dimensional structure of MTAP (EC 2.4.2.28), an enzyme that is involved in purine salvation pathway, and is thus essential to the reproduction of the parasite. The MTAP was heterologously expressed, purified and crystallized. The protein was submitted to kinetic assays in coupled system, to determine the catalytic constants. The protein was crystallized in 100mM Bis-tris or MES pH 6.1-6.5 and 14-18% PEG 3350. The crystals were submitted to diffraction of rays-X in the LNLS and DLS. Data sets were obtained, processed, refined and analyzed. Structures were obtained in apoenzyme form complexed with fosfate, complexed with adenine and sulfate, complexed with tubercidin and sulfate, and with adenine and glycerol in a space group different of the others. Through the secondary structure, it was possible to analyze the active site and obtained preliminary information of the catalytic mechanism of the target enzyme. This study contributes to the complete elucidation of the purine salvation pathway in S. mansoni, and provides basic information for the research of the new drugs.

Schistosoma mansoni

Schistosoma mansoni

Crystallographic structure

Estrutura cristalográfica

Methylthioadenosine Phosphorylase

Metiltioadenosina Fosforilase

Determinação estrutural e funcional da enzima 5´-deoxi-5´-metiltioadenosina Fosforilase de Schistosoma mansoni / Structural and Functional Determination of 5´-deoxy-5´-methylthioadenosine Phosphorylase enzyme from Schistosoma mansoni

Juliana Roberta Torini de Souza

16 April 2012

As doenças parasitárias são uma das maiores causas de morte em países em desenvolvimento, e recebem pouca ou nenhuma atenção das indústrias farmacêuticas para o desenvolvimento de terapias. A esquistossomose mansoni também conhecida como barriga d´água ou doença do caramujo é uma doença parasitária crônica que afeta aproximadamente 207 milhões de pessoas no mundo sendo aproximadamente 6 milhões somente no Brasil. Os medicamentos disponíveis no mercado causam graves efeitos colaterais. Além disso, há relatos de cepas de S. mansoni resistentes à esses medicamentos, justificando assim a busca por novos fármacos. O Schistosoma mansoni não possui a via de novo para a biosíntese de bases púricas e depende integralmente da via de salvação para o suprimento dessa. Assim, este trabalho teve como objetivo determinar as constantes catalíticas e a estrutura tridimensional da MTAP (EC 2.4.2.28), enzima esta que participam da via de salvação de purinas, e é desta forma essencial para a reprodução do parasita. Esta enzima foi expressa de forma heteróloga, purificada e cristalizada. A proteína foi submetida à ensaios cinéticos em sistema acoplado, onde foram determinadas as constantes catalíticas. A proteína foi também cristalizada em condições que continham 100 mM de Bis-tris ou MES com pH variando entre 6,1 a 6,5 e PEG3350, cuja concentração variou ente 14-18%. Os cristais foram submetidos à difração de raios-X no LNLS e no DLS. Foram obtidos, quatro conjuntos de dados, que foram processados, refinados e analisados. Obteve-se estrutura apoenzima em complexo com fosfato, em complexo com adenina e sulfato, em complexo com tubercidina e sulfato e em complexo com adenina e glicerol em um grupo espacial diferente dos demais. Através da estrutura secundária, foi possível analisar o sítio ativo, além de obter informações preliminares do mecanismo catalítico da enzima alvo. Este trabalho colabora para a futura elucidação completa da via de salvação de purinas em S. mansoni, e fornece informações básicas para que a busca por novos fármacos tenha novos ramos a serem explorados. / The parasitic illness are the leading cause of deaths in developing countries, and receives little or no attention from drug companies to develop therapies. Schistosomiasis mansoni also known as water belly or snail´s disease is a chronic parasitic illness that affects approximately 207 million people worldwide with approximately 6 million in Brazil. Schistosomiasis is treated by the use of drugs that are not-in fact effective for the eradication of the disease, and although their efficiency cause serious side effects. In addition, there are reports of S. mansoni´s resistant strains to these drugs, thus justifying the search for new drugs. The Schistosoma mansoni parasite does not possess the de novo pathway for purine bases biosynthesis and depends entirely on salvage pathways for its purine requirement. Thus this study aimed to determine the catalytic constants and three-dimensional structure of MTAP (EC 2.4.2.28), an enzyme that is involved in purine salvation pathway, and is thus essential to the reproduction of the parasite. The MTAP was heterologously expressed, purified and crystallized. The protein was submitted to kinetic assays in coupled system, to determine the catalytic constants. The protein was crystallized in 100mM Bis-tris or MES pH 6.1-6.5 and 14-18% PEG 3350. The crystals were submitted to diffraction of rays-X in the LNLS and DLS. Data sets were obtained, processed, refined and analyzed. Structures were obtained in apoenzyme form complexed with fosfate, complexed with adenine and sulfate, complexed with tubercidin and sulfate, and with adenine and glycerol in a space group different of the others. Through the secondary structure, it was possible to analyze the active site and obtained preliminary information of the catalytic mechanism of the target enzyme. This study contributes to the complete elucidation of the purine salvation pathway in S. mansoni, and provides basic information for the research of the new drugs.

Schistosoma mansoni

Estrutura cristalográfica

Metiltioadenosina Fosforilase

Schistosoma mansoni

Crystallographic structure

Methylthioadenosine Phosphorylase

Caracterização estrutural e funcional de duas Nucleosídeo Fosforilases de Schistosoma mansoni / Structural and functional characterization of two Nucleoside Phosphorylase from Schistosoma mansoni.

Juliana Roberta Torini de Souza

18 August 2016

As doenças parasitárias são uma das maiores causas de morte em países em desenvolvimento, e recebem pouca ou nenhuma atenção das indústrias farmacêuticas para o desenvolvimento de terapias. Causada pelo parasita Schistosoma mansoni a esquistossomose mansônica afeta aproximadamente 259 milhões de pessoas no mundo sendo aproximadamente 6 milhões somente no Brasil. O S. mansoni não possui a via \"de novo\" para a biossíntese de bases púricas e depende integralmente da via de salvação para o suprimento dessas bases, portanto, essa via é um alvo em potencial. Agentes capazes de bloquear a atividade das enzimas participantes desta via atuam de forma inespecífica e são quase sempre tóxicos ao homem e por isso o estudo minucioso das pequenas diferenças encontradas entre as enzimas do hospedeiro e do parasita são de extrema importância. Uma diferença marcante entre a via de salvação de purinas do parasita e do hospedeiro humano é a presença de atividade para adenosina fosforilase, que no parasita é exercida por duas entidades distintas: pela enzima Metiltioadenosina fosforilase de S. mansoni (SmMTAP) e por uma enzima até então desconhecida. A enzima SmMTAP naturalmente converte 5\'-deoxi-5\'-metiltioadenosina (MTA) em adenina livre, mas ao contrário do que é visto no hospedeiro, no parasita essa enzima atua preferencialmente na conversão de adenosina. Substituições encontradas no sítio ativo dessa enzima, podem explicar tamanha preferência pelo substrato alternativo, revelando mecanismos distintos da enzima humana. A enzima Purina nucleosídeo fosforilase de S. mansoni (SmPNP) converte inosina e guanosina à hipoxantina e guanina, respectivamente, mas não possui atividade catalítica para adenosina. No entanto, no genoma de S. mansoni é descrita uma isoforma para a SmPNP (SmPNP2), cuja atividade catalítica é desconhecida e, portanto, essa enzima pode também atuar na conversão de adenosina juntamente com a SmMTAP. Assim, os objetivos deste trabalho foram realizar estudos bioquímicos da ação da enzima SmMTAP e realizar a caracterização estrutural e funcional da enzima SmPNP2. Para isso, foram realizadas mutações no sítio ativo da SmMTAP (S12T, N87T, Q289L, S12T/N87T e S12T/N87T/Q289L), as mutantes da SmMTAP juntamente com a enzima SmPNP2 foram clonadas, expressas de forma heteróloga e purificadas. Foram realizados ensaios de cristalização e cinéticos por espectrofotometria utilizando um sistema acoplado. A atividade da SmPNP2 foi ainda avaliada por calorimetria e HPLC. Foram determinadas as constantes catalíticas da forma nativa e para os cinco mutantes da SmMTAP para cinco diferentes substratos. Foi determinada atividade catalítica da SmPNP2 por 3 diferentes substratos: adenosina, inosina e citidina, as constantes catalíticas foram determinadas para os três substratos. Foram obtidos cristais para os mutantes da SmMTAP e da SmPNP2, que foram submetidos à difração de raios X nas linhas I04-1 e I02 do laboratório de radiação síncrotron Diamond Light Source (DLS). Foram resolvidas 9 estruturas dos mutantes da SmMTAP e 4 da proteína SmPNP2. Os dados cinéticos, juntamente com os dados estruturais, permitiram compreender mecanismos catalíticos e de interação das proteínas estudadas, complementando o conhecimento do metabolismo do parasita Schistosoma mansoni e revelando alvos em potencial para o desenvolvimento de fármacos específicos. / The parasitic illness are the leading cause of deaths in developing countries, and receives little or no attention from drug companies to develop therapies. The schistosomiasis is caused by Schistosoma mansoni parasite and affects approximately 259 million people worldwide with 6 million only in Brazil. The Schistosoma mansoni parasite does not possess the \"de novo\" pathway for purine bases biosynthesis and depends entirely on salvage pathway for its purine requirement, therefore this pathway is a potential target. Compounds able to block the enzymes from this pathway, are not specific and are often toxic to humans, thus the thorough study about the particularity found between enzymes from host and parasite are extremely important. A notable difference between human and parasite metabolism, is the activity existence to Adenosine phosphorylase that in parasite is carried out by two distinct entities: by Methylthioadenosine phosphorylase (SmMTAP) and by a hitherto unknown enzyme. The SmMTAP enzyme, naturally converts 5\'-deoxy-5\'-methylthioadenosine (MTA) to free adenine and in opposition to host, in the parasite this enzyme acts manly in adenosine conversion. Substitutions found in the active site from SmMTAP, can explain the huge preference by alternative substrate and to expose a distinct mechanisms from human enzyme. The Purine nucleoside Phosphorylase from S. mansoni (SmPNP) converts inosine and guanosine to hypoxanthine and guanine, respectively, but it not possess catalytic activity to adenosine conversion. However in the S. mansoni genome there is a isoform to SmPNP, whose activity is unknown, thus is possible that SmPNP2 enzyme also can to convert adenosine. This study aimed to perform biochemical studies to investigate the SmMTAP enzyme action and perform the structural and functional characterization of SmPNP2. For this propose was made site-directed mutagenesis (S12T, N87T, Q289L, S12T/N87T e S12T/N87T/Q289L). The SmMTAP mutants and SmPNP2 enzyme were cloned, expressed by heterolog process and purified. Were perform kinetic assays by spectrophotometric method in a coupled system. The SmPNP2 activity was also available by calorimetry and HPLC methods. Were determined the catalytic constants to wild and mutants SmMTAP to five different substrate. Was determinated to SmPNP2 catalictical activity and kinetics parameters to three substrate: adenosine, inosine e cytidine. Were obtained crystals from SmMTAP mutants and SmPNP2 enzyme, those crystals were submitted to X-rays diffractions in the I04-1 and I02 beamlines from Diamond Light Source (DLS). Nine structures were obtained from SmMTAP mutants and four from SmPNP2 enzyme. The kinetics and structural data allowed understanding the catalytic and interaction mechanisms about the protein studied, supplementing the knowledge around Schistosoma mansoni metabolism and reporting potential targets for the specific drugs development.

Schistosoma mansoni

Metiltioadenosina fosforilase

Purina nucleosideo fosforilase

Schistosoma mansoni

Methylthioadenosine phosphorylase

Purine nucleoside phosphorylase

Targeting the nucleotide metabolism of the mammalian pathogen Trypanosoma brucei

Vodnala, Munender

January 2013

Trypanosoma brucei causes African sleeping sickness in humans and Nagana in cattle. There are no vaccines available against the disease and the current treatment is also not satisfactory because of inefficacy and numerous side effects of the used drugs. T. brucei lacks de novo synthesis of purine nucleosides; hence it depends on the host to make its purine nucleotides. T. brucei has a high affinity adenosine kinase (TbAK), which phosphorylates adenosine, deoxyadenosine (dAdo), inosine and their analogs. RNAi experiments confirmed that TbAK is responsible for the salvage of dAdo and the toxicity of its substrate analogs. Cell growth assays with the dAdo analogs, Ara-A and F-Ara-A, suggested that TbAK could be exploited for drug development against the disease. It has previously been shown that when T. brucei cells were cultivated in the presence of 1 mM deoxyadenosine (dAdo), they showed accumulation of dATP and depletion of ATP nucleotides. The altered nucleotide levels were toxic to the trypanosomes. However the salvage of dAdo in trypanosomes was dramatically reduced below 0.5 mM dAdo. Radiolabeled dAdo experiments showed that it (especially at low concentrations) is cleaved to adenine and converted to ATP. The recombinant methylthioadenosine phosphorylase (TbMTAP) cleaved methylthioadenosine, dAdo and adenosine into adenine and sugar-1-P in a phosphate-dependent manner. The trypanosomes became more sensitive to dAdo when TbMTAP was down-regulated in RNAi experiments. The RNAi experiments confirmed that trypanosomes avoid dATP accumulation by cleaving dAdo. The TbMTAP cleavage-resistant nucleoside analogs, FANA-A and Ara-A, successfully cured T. brucei-infected mice. The DNA building block dTTP can be synthesized either via thymidylate synthase in the de novo pathway or via thymidine kinase (TK) by salvage synthesis. We found that T. brucei and three other parasites contain a tandem TK where the gene sequence was repeated twice or four times in a single open reading frame. The recombinant T. brucei TK, which belongs to the TK1 family, showed broad substrate specificity. The enzyme phosphorylated the pyrimidine nucleosides thymidine and deoxyuridine, as well as the purine nucleosides deoxyinosine and deoxyguanosine. When the repeated sequences of the tandem TbTK were expressed individually as domains, only domain 2 was active. However, the protein could not dimerize and had a 5-fold reduced affinity to its pyrimidine substrates but a similar turnover number as the full-length enzyme. The expressed domain 1 was inactive and sequence analysis revealed that some active residues, which are needed for substrate binding and catalysis, are absent. Generally, the TK1 family enzymes form dimers or tetramers and the quaternary structure is linked to the affinity for the substrates. The covalently linked inactive domain-1 helps domain-2 to form a pseudodimer for the efficient binding of substrates. In addition, we discovered a repetition of an 89-bp sequence in both domain 1 and domain 2, which suggests a genetic exchange between the two domains. T. brucei is very dependent on de novo synthesis via ribonucleotide reductase (RNR) for the production of dNTPs. Even though T. brucei RNR belongs to the class Ia RNR family and contains an ATP-binding cone, it lacks inhibition by dATP. The mechanism behind the RNR activation by ATP and inactivation by dATP was a puzzle for a long time in the ~50 years of RNR research. We carried out oligomerization studies on mouse and E. coli RNRs, which belongs to the same family as T. brucei, to get an understanding of the molecular mechanism behind overall activity regulation. We found that the oligomerization status of RNRs and overall activity mechanism are interlinked with each other. / Targeting the nucleotide metabolism of the mammalian pathogen Trypanosoma brucei.

Trypanosoma brucei

adenosine kinase

thymidine kinase

methylthioadenosine phosphorylase

mouser ribonucleotide reductase

E. coli ribonucleotide reductase

RNR

Ara-A

F-Ara-A

dNTP

NTP

doexynucleotide metabolism

nucleosides

nucleoside kinases

allosteric regulation