X-ray crystallographic studies of glycogen phosphorylase b

Wild, David Leslie

January 1981

The structure of rabbit muscle glycogen phosphorylase b, an important regulatory enzyme in glycogen metabolism, has been studied by X-ray crystallographic techniques. This work was carried out as part of a group project, and the crystal structure of the enzyme had already been solved to 3 Å resolution, using the technique of Multiple Isomorphous Replacement. A search for additional heavy atom isomorphous derivatives was carried out, and photographic data to 3 Å resolution were collected for a further ethylmercurythiosalicylate derivative, using a screenless oscillation camera. The collection and reduction of this data, and the refinement of the heavy atom positions is described. The inclusion of this data allowed a new electron density map (with figure of merit = O.63) to be calculated, which enabled previously ambiguous areas in the electron density to be interpreted. Data to 2 Å resolution have been collected on an oscillation camera, using a synchrotron radiation source and cylindrical film cassettes. An intensity gain of up to 13O times, compared to a GX6 rotating anode source, was obtained with the synchrotron radiation source. A reduction in radiation damage, was also observed. The collection and reduction of the 2 Å data is described. The final overall merging R-factor was 15%. Some systematic errors remain in the data, and possible sources of these errors are discussed, and improvements to the data processing procedure suggested. The 2 Å data were empirically scaled to the 3 Å data and have been used in the first stages of the refinement of the phosphorylase b structure. The contribution of the crystallographic results towards an understanding of phosphorylase b as an allosteric protein is discussed.

548

Caracterização estrutural da Uridina Fosforilase de Schistosoma mansoni / Structural characterization of Uridine Phosphorylase from Schistosoma mansoni

Silva Neto, Antonio Marinho da

16 August 2013

A esquistossomose humana, doença causada pelo S. mansoni e com 6 milhões de infectados somente no Brasil, possui uma única estratégia terapêutica eficiente atualmente disponível. Esta se baseia na utilização de praziquantel e relatos de cepas resistentes à essa droga tem despertado o interesse da comunidade científica sobre o desenvolvimento de novas estratégias terapêuticas. Uma melhor caracterização dos processos metabólicos do parasita podem auxiliar nestas buscas. Diante desse contexto, nosso grupo tem trabalhado na caracterização estrutural e funcional das enzimas que compõem a via de salvação de purinas e pirimidinas deste parasita, com dez enzimas já caracterizadas. Uma das enzimas remanescentes é a uridina fosforilase (UP) (EC 2.4.2.3), cujo a qual o genoma do parasita apresenta duas isoformas, a smUPa e smUPb (92% de identidade entre elas). Com o objetivo de caracterizar estruturalmente estas enzimas, ambas foram obtidas via expressão heteróloga, purificadas e submetidas a ensaios de cristalização e co-cristalização (para obtenção das estruturas interagindo com diferentes ligantes). Após coleta de dados de difração de raio-x, processamento e refinamento adequado foram obtidas seis estruturas da smUPa (smUPaapo, smUPa+Timidina, smUPa+timina, smUPa+uracil, smUPa-5fluorouracil) e duas da smUPb (smUPbapo e smUPb+citrato). A análise das estruturas revela que as duas isoformas apresentam essencialmente a mesma estrutura, no entanto, apesar das poucas divergências em nível de sequência de aminoácidos, existem diferenças significativas entre os sítios ativos. A smUPa apresenta o sítio com as mesmas características de UPs conhecidas, em contrapartida a smUPb apresenta duas mudanças significativas que elimina a capacidade de interagir com a base nitrogenada (Q201L) e a cavidade que acomoda a base nitrogenada (G126D), o que torna as smUPs um caso único de isoformas de UP em um mesmo organismo conhecidas. É plausível que a smUPb não seja capaz de catalisar a fosforólise reversível da uridina, sendo ou um pseudogene ou alguma outra enzima com atividade catalítica diferente da UP. Para a completa caracterização destas enzimas, testes de atividade enzimática serão realizados e deverão auxiliar a determinar a real função da smUPb. / Human schistosomiasis, a disease caused by Schistosoma sp., is estimated to affect six million individuals in Brazil alone and there is currently only one therapeutic strategy available. This is based on the use of praziquantel and reports of the appearance of strains resistant to the drug has motivated the scientific community towards the search for new possible therapies. Biochemical characterization of the parasites metabolism is essential for the rational development of new therapeutic alternatives. Based on this,reasoning our group has been working on the structural and functional characterization of the enzymes involved in the pyrimidine and purine salvage pathways of S. mansoni. One of the remaining enzymes to be characterized is uridine phosphorylase (UP) (EC 2.4.2.3), for which there are two isoforms present in the parasite genome, smUPa and smUPb, which share 92% sequence identity. In order to structurally characterize these enzymes, both smUPs were produced by heterologous expression, purified and submitted to crystallization e co-crystallization assays, in the latter case in order to obtain the structure of different enzyme-ligand complexes. After data collection, processing and refinement, five structures of smUPa (smUPaapo, smUPa+Timidina, smUPa+timina, smUPa+uracil and smUPa+5fluorouracil) and two structures of smUPb (smUPbapo and smUPb+citrato) were obtained. Analysis of the structures revealed that the isoforms have the same fold, but despite the high sequence identity, significant differences are observed at the active site probably profoundly affecting enzyme activity. Whilst SmUPa presents an active site similar to that of other known UPs, smUPb is predicted to lack the ability to interact with the nucleoside base due to the presence of a leucine in place of a glutamine at position 201 and an aspartatic acid in place of glycine at position 126. These differences turn the smUPs into a unique case of UP isoforms. It is plausible that smUPb is unable to catalyze the reversible phosphorolysis of uridine and could be either a pseudogene or a different enzyme altogether of unknown catalytic activity. A complete functional characterization in vitro will be necessary in order to determine its real function.

Cristalografia

Criystallography

Schistosoma mansoni

Schistosoma mansoni

Uridina Fosforilase

Uridine Phosphorylase

Myocardial energy metabolism in ischemic preconditioning, role of adenosine catabolism

Kavianipour, Mohammad

January 2002

<p>Brief episodes of ischemia and reperfusion render the myocardium more resistant to necrosis from a subsequent, otherwise lethal ischemic insult. This phenomenon is called ischemic preconditioning(IP). Today, much is known about the signalling pathways involved in IP; however, the details of the final steps leading to cardioprotection, remain elusive. Adenosine (a catabolite of ATP) plays a major role in the signalling pathways of IP. Following IP there is an unexplained discrepancy between an increased adenosine production (evidenced by increased 5’-nucleotidase activity) and the successively lower adenosine levels observed in the interstitial space. We propose that this discrepancy in adenosine production vs. availability may be due to an increased metabolic utilisation of adenosine by the IP myocardium. According to our hypothesis, IP induces/activates a metabolic pathway involving deamination of adenosine to inosine. Inosine is further catalysed (in presence of Pi) to hypoxanthine and ribose-1-phosphate. Ribose-1-phosphate can be converted to ribose-5-phosphate in a phosphoribomutase reaction. Ribose-5-phosphate is an intermediate of the hexose monophosphate pathway also operative under anaerobic conditions. Hence the ribose moiety of adenosine can be utilised to generate pyruvate and ultimately ATP (via lactate formation) n.b. without any initial ATP investment. Such cost-effective adenosine utilisation may at least partly explain the cardioprotective effect of IP. Objectives & Methods: In the current studies we investigated the role of adenosine metabolism according to the suggested metabolic pathway by addition of adenosine and inhibition of its metabolism during IP as well as by comparing tissue and interstitial levels of key energy-metabolites following different protocols of IP. Furthermore, we studied the importance of the IP protocol with regard to the number of ischemia and reperfusion cycles for the cardioprotective effect of IP. In addition, the validity of the microdialysis technique for experimental in vivo studies of myocardial energy metabolism was evaluated. For these purposes the microdialysis technique, tissue biopsies, and planimetric infarct size estimation in an open chest porcine heart-model was used. Results: Addition of adenosine via microdialysis probes enhanced the interstitial release of inosine, hypoxanthine and lactate in the myocardium of IP-subjects during prolonged ischemia. This finding did not occur in non-preconditioned subjects. Similar addition of deoxyadenosine a non-metabolizable adenosine receptor-agonist, did not evoke the same metabolic response. Purine nucleoside phosphorylase (PNP) is responsible for the conversion of inosine to hypoxanthine being a key enzyme in the above mentioned metabolic pathway. Inclusion of 8' aminoguanosine (a competitive inhibitor of PNP) decreased interstitial hypoxanthine release (as a token of PNP inhibition) and increased the release of taurine (marker of cellular injury) in the ischemic IP myocardium. Addition of inosine (a natural substrate of PNP) reverted these changes. Four IP cycles protected the heart more than one IP cycle as evidenced by morphometric and energy-metabolic data.Proportionally more hypoxanthine was found in the myocardium of IP subjects during prolonged ischemia. The ratio of tissue levels of inosine/hypoxanthine (used as an indicator of PNP activity) was significantly smaller in the IP groups. In addition, myocardial interstitial levels of energy-related metabolites (lactate, adenosine, inosine, and hypoxanthine) obtained by the microdialysis technique correlated with tissue biopsy levels of corresponding metabolites. Conclusions: IP activated a metabolic pathway favouring metabolism of exogenous adenosine to inosine, hypoxanthine and eventually lactate. Inhibition of adenosine metabolism following IP (via inhibition of PNP-activity resulted in enhanced cellular injury.</p><p>PNP-activity is proportionally higher in IP-myocardium. Metabolic utilisation of adenosine in IP-myocardium (as outlined above) may represent a costeffective way to produce ATP and at least partly explain the cardioprotective effect of IP. IP protects the myocardium in a graded fashion. Furthermore, we confirmed the validity of the microdialysis technique (in the current setting) for studying dynamic changes of myocardial energy metabolism.</p>

Ischemic preconditioning

adenosine

purine nucleoside phosphorylase

microdialysis

pig

Ribosome Degradation in Escherichia coli

Zundel, Michael

09 September 2008

Upon termination of translation, the fate of ribosomes is determined largely by the rate at which cells are growing. During periods of exponential growth, ribosomes are rapidly recycled, translation is re-initiated, and the ribosomes are extremely stable. However, when nutrient sources become limiting, and ribosomes are not actively translating, they may become substrates for degradation. While this phenomenon is well known, details of how the process is initiated and what are the signals for degradation have, until now, remained elusive. Here, I present in vitro and in vivo data showing that free ribosome subunits are the targets of degradative enzymes, whereas 70S particles that remain associated are protected from such degradation. Conditions that increase the formation of subunits both in vitro and in vivo lead to enhanced degradation. Thus, the simple presence of free 50S and 30S subunits is sufficient to serve as the mechanism that initiates ribosome degradation. In order to identify RNases involved in ribosome degradation, both in vitro and in vivo assays were developed. Together, they have provided evidence for a multi-step degradation process involving both endo- and exoribonucleases. Examination of extracts from strains deficient in known RNases revealed that the endoribonucleases, RNase E and RNase G, may be involved in the initial cleavages. The resulting fragments, some of which are small enough oligoribonucleotides that they remain part of the acid-soluble fraction are degraded to mononucleotides primarily by the 3'-5' exoribonucleases, RNase R and polynucleotide phosphorylase.

PNPase

Polynucleotide Phosphorylase

RNase R

Endoribonuclease

Exoribonuclease

Degradation Of RRNA

Ribosomes

Myocardial energy metabolism in ischemic preconditioning, role of adenosine catabolism

Kavianipour, Mohammad

January 2002

Brief episodes of ischemia and reperfusion render the myocardium more resistant to necrosis from a subsequent, otherwise lethal ischemic insult. This phenomenon is called ischemic preconditioning(IP). Today, much is known about the signalling pathways involved in IP; however, the details of the final steps leading to cardioprotection, remain elusive. Adenosine (a catabolite of ATP) plays a major role in the signalling pathways of IP. Following IP there is an unexplained discrepancy between an increased adenosine production (evidenced by increased 5’-nucleotidase activity) and the successively lower adenosine levels observed in the interstitial space. We propose that this discrepancy in adenosine production vs. availability may be due to an increased metabolic utilisation of adenosine by the IP myocardium. According to our hypothesis, IP induces/activates a metabolic pathway involving deamination of adenosine to inosine. Inosine is further catalysed (in presence of Pi) to hypoxanthine and ribose-1-phosphate. Ribose-1-phosphate can be converted to ribose-5-phosphate in a phosphoribomutase reaction. Ribose-5-phosphate is an intermediate of the hexose monophosphate pathway also operative under anaerobic conditions. Hence the ribose moiety of adenosine can be utilised to generate pyruvate and ultimately ATP (via lactate formation) n.b. without any initial ATP investment. Such cost-effective adenosine utilisation may at least partly explain the cardioprotective effect of IP. Objectives &amp; Methods: In the current studies we investigated the role of adenosine metabolism according to the suggested metabolic pathway by addition of adenosine and inhibition of its metabolism during IP as well as by comparing tissue and interstitial levels of key energy-metabolites following different protocols of IP. Furthermore, we studied the importance of the IP protocol with regard to the number of ischemia and reperfusion cycles for the cardioprotective effect of IP. In addition, the validity of the microdialysis technique for experimental in vivo studies of myocardial energy metabolism was evaluated. For these purposes the microdialysis technique, tissue biopsies, and planimetric infarct size estimation in an open chest porcine heart-model was used. Results: Addition of adenosine via microdialysis probes enhanced the interstitial release of inosine, hypoxanthine and lactate in the myocardium of IP-subjects during prolonged ischemia. This finding did not occur in non-preconditioned subjects. Similar addition of deoxyadenosine a non-metabolizable adenosine receptor-agonist, did not evoke the same metabolic response. Purine nucleoside phosphorylase (PNP) is responsible for the conversion of inosine to hypoxanthine being a key enzyme in the above mentioned metabolic pathway. Inclusion of 8' aminoguanosine (a competitive inhibitor of PNP) decreased interstitial hypoxanthine release (as a token of PNP inhibition) and increased the release of taurine (marker of cellular injury) in the ischemic IP myocardium. Addition of inosine (a natural substrate of PNP) reverted these changes. Four IP cycles protected the heart more than one IP cycle as evidenced by morphometric and energy-metabolic data.Proportionally more hypoxanthine was found in the myocardium of IP subjects during prolonged ischemia. The ratio of tissue levels of inosine/hypoxanthine (used as an indicator of PNP activity) was significantly smaller in the IP groups. In addition, myocardial interstitial levels of energy-related metabolites (lactate, adenosine, inosine, and hypoxanthine) obtained by the microdialysis technique correlated with tissue biopsy levels of corresponding metabolites. Conclusions: IP activated a metabolic pathway favouring metabolism of exogenous adenosine to inosine, hypoxanthine and eventually lactate. Inhibition of adenosine metabolism following IP (via inhibition of PNP-activity resulted in enhanced cellular injury. PNP-activity is proportionally higher in IP-myocardium. Metabolic utilisation of adenosine in IP-myocardium (as outlined above) may represent a costeffective way to produce ATP and at least partly explain the cardioprotective effect of IP. IP protects the myocardium in a graded fashion. Furthermore, we confirmed the validity of the microdialysis technique (in the current setting) for studying dynamic changes of myocardial energy metabolism.

Ischemic preconditioning

adenosine

purine nucleoside phosphorylase

microdialysis

pig

The Effects of Purine Nucleoside Phosphorylase (PNP) Deficiency on Thymocyte Development

Papinazath, Taniya

27 July 2010

PNP is a crucial enzyme in purine metabolism, and its inherited defects result in severe T-lineage immune deficiency in humans. I hypothesized that PNP deficiency disrupts the development of late CD4-CD8- double negative (DN) thymocytes and induces mitochondrial-mediated apoptosis of CD4+CD8+ double positive (DP) thymocytes. By using PNP-deficient (PNP-/-) mice as well as an OP9-DL1 co-culture system simulating PNP-deficient conditions, I demonstrated that PNP deficiency interferes with the maturation of DN thymocytes at the transition from DN3 to DN4 stage. Although PNP deficiency does not affect the generation or proliferation of DP thymocytes, PNP-/- DP thymocytes were observed to undergo apoptosis at a higher rate. My results suggest that apoptosis is induced through a mitochondrial mediated pathway. Additionally, re-introduction of PNP into PNP-/- thymocytes protected the cells from the toxic effects of deoxyguanosine by preventing the formation of deoxyguanosine triphosphate, indicating that the toxic metabolite in PNP deficiency is deoxyguanosine.

Thymocyte development

immune deficiency

purine metabolism

Purine nucleoside phosphorylase

0982

The Effects of Purine Nucleoside Phosphorylase (PNP) Deficiency on Thymocyte Development

Papinazath, Taniya

27 July 2010

PNP is a crucial enzyme in purine metabolism, and its inherited defects result in severe T-lineage immune deficiency in humans. I hypothesized that PNP deficiency disrupts the development of late CD4-CD8- double negative (DN) thymocytes and induces mitochondrial-mediated apoptosis of CD4+CD8+ double positive (DP) thymocytes. By using PNP-deficient (PNP-/-) mice as well as an OP9-DL1 co-culture system simulating PNP-deficient conditions, I demonstrated that PNP deficiency interferes with the maturation of DN thymocytes at the transition from DN3 to DN4 stage. Although PNP deficiency does not affect the generation or proliferation of DP thymocytes, PNP-/- DP thymocytes were observed to undergo apoptosis at a higher rate. My results suggest that apoptosis is induced through a mitochondrial mediated pathway. Additionally, re-introduction of PNP into PNP-/- thymocytes protected the cells from the toxic effects of deoxyguanosine by preventing the formation of deoxyguanosine triphosphate, indicating that the toxic metabolite in PNP deficiency is deoxyguanosine.

Thymocyte development

immune deficiency

purine metabolism

Purine nucleoside phosphorylase

0982

Searching for the Binding Partners for the Novel PHKG1 Variant γ 181

Polireddy, Kishore

01 August 2009

No description available.

phosphorylase kinase

enzymes

Cell Biology

Computational Biology

Genetics

Caracterização estrutural da Uridina Fosforilase de Schistosoma mansoni / Structural characterization of Uridine Phosphorylase from Schistosoma mansoni

Antonio Marinho da Silva Neto

16 August 2013

A esquistossomose humana, doença causada pelo S. mansoni e com 6 milhões de infectados somente no Brasil, possui uma única estratégia terapêutica eficiente atualmente disponível. Esta se baseia na utilização de praziquantel e relatos de cepas resistentes à essa droga tem despertado o interesse da comunidade científica sobre o desenvolvimento de novas estratégias terapêuticas. Uma melhor caracterização dos processos metabólicos do parasita podem auxiliar nestas buscas. Diante desse contexto, nosso grupo tem trabalhado na caracterização estrutural e funcional das enzimas que compõem a via de salvação de purinas e pirimidinas deste parasita, com dez enzimas já caracterizadas. Uma das enzimas remanescentes é a uridina fosforilase (UP) (EC 2.4.2.3), cujo a qual o genoma do parasita apresenta duas isoformas, a smUPa e smUPb (92% de identidade entre elas). Com o objetivo de caracterizar estruturalmente estas enzimas, ambas foram obtidas via expressão heteróloga, purificadas e submetidas a ensaios de cristalização e co-cristalização (para obtenção das estruturas interagindo com diferentes ligantes). Após coleta de dados de difração de raio-x, processamento e refinamento adequado foram obtidas seis estruturas da smUPa (smUPaapo, smUPa+Timidina, smUPa+timina, smUPa+uracil, smUPa-5fluorouracil) e duas da smUPb (smUPbapo e smUPb+citrato). A análise das estruturas revela que as duas isoformas apresentam essencialmente a mesma estrutura, no entanto, apesar das poucas divergências em nível de sequência de aminoácidos, existem diferenças significativas entre os sítios ativos. A smUPa apresenta o sítio com as mesmas características de UPs conhecidas, em contrapartida a smUPb apresenta duas mudanças significativas que elimina a capacidade de interagir com a base nitrogenada (Q201L) e a cavidade que acomoda a base nitrogenada (G126D), o que torna as smUPs um caso único de isoformas de UP em um mesmo organismo conhecidas. É plausível que a smUPb não seja capaz de catalisar a fosforólise reversível da uridina, sendo ou um pseudogene ou alguma outra enzima com atividade catalítica diferente da UP. Para a completa caracterização destas enzimas, testes de atividade enzimática serão realizados e deverão auxiliar a determinar a real função da smUPb. / Human schistosomiasis, a disease caused by Schistosoma sp., is estimated to affect six million individuals in Brazil alone and there is currently only one therapeutic strategy available. This is based on the use of praziquantel and reports of the appearance of strains resistant to the drug has motivated the scientific community towards the search for new possible therapies. Biochemical characterization of the parasites metabolism is essential for the rational development of new therapeutic alternatives. Based on this,reasoning our group has been working on the structural and functional characterization of the enzymes involved in the pyrimidine and purine salvage pathways of S. mansoni. One of the remaining enzymes to be characterized is uridine phosphorylase (UP) (EC 2.4.2.3), for which there are two isoforms present in the parasite genome, smUPa and smUPb, which share 92% sequence identity. In order to structurally characterize these enzymes, both smUPs were produced by heterologous expression, purified and submitted to crystallization e co-crystallization assays, in the latter case in order to obtain the structure of different enzyme-ligand complexes. After data collection, processing and refinement, five structures of smUPa (smUPaapo, smUPa+Timidina, smUPa+timina, smUPa+uracil and smUPa+5fluorouracil) and two structures of smUPb (smUPbapo and smUPb+citrato) were obtained. Analysis of the structures revealed that the isoforms have the same fold, but despite the high sequence identity, significant differences are observed at the active site probably profoundly affecting enzyme activity. Whilst SmUPa presents an active site similar to that of other known UPs, smUPb is predicted to lack the ability to interact with the nucleoside base due to the presence of a leucine in place of a glutamine at position 201 and an aspartatic acid in place of glycine at position 126. These differences turn the smUPs into a unique case of UP isoforms. It is plausible that smUPb is unable to catalyze the reversible phosphorolysis of uridine and could be either a pseudogene or a different enzyme altogether of unknown catalytic activity. A complete functional characterization in vitro will be necessary in order to determine its real function.

Cristalografia

Schistosoma mansoni

Uridina Fosforilase

Criystallography

Schistosoma mansoni

Uridine Phosphorylase

Effects of acetylcholine on cyclic nucleotide levels, and on phosphorylase a and glycogen synthase I activities in perfused rat hearts

Gardner, Russell M.

January 1975

This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu).

Acetylcholine

Nucleotides, Cyclic

Glycogen Synthase

Myocardium

Rats

Glycogen Phosphorylase