Analysis and studies of inhibition of the two divergent thymidine biosynthesis pathways in Mycobacterium tuberculosis /

Ulmer, Jonathan Edward,

January 2007

Thesis (Ph. D.)--University of Washington, 2007. / Vita. Includes bibliographical references (leaves 186-200).

Folding And Stability Of Thymidylate Synthase : Studies Involving The Dimer Interface

Prasanna, V

10 1900

No description available.

Protein Folding

Protein Binding

Polypeptide Chains

Thymidylate Synthase (TS)

Dimer Interface

Biochemistry

Studies on the hydride transfer and other aspects of several thymidylate synthase variants

Gurevic, Ilya

01 December 2018

The nucleotide 2'-deoxythymidine 5'-monophosphate (thymidylate, dTMP) is phosphorylated twice to become a substrate for DNA polymerases, which copy a cell’s genetic information in advance of cell division. The main route to dTMP is mediated by the enzyme thymidylate synthase (TSase) and goes through 2'-deoxyuridine 5'-monophosphate (dUMP); dUMP’s heterocyclic aromatic pyrimidine ring loses a proton from its C5 position and gains a methylene and a hydride from the other reactant, methylene tetrahydrofolate (MTHF). In general, intricate knowledge of an enzyme’s mechanism can yield insight that leads to the development of precision-targeted inhibitors tailored exactly to thymidylate synthase. In fact, even more careful targeting could be achievable: Although E. coli TSase has served as a model system, investigators have increasingly been directing their lines of inquiry toward human TSase. A general enzymatic catalytic cascade is complex, comprising substrate binding, the chemical steps and product release; typically, the product release step is rate-limiting. TSase, however, is partially rate-limited by the chemistry portion of the process. The enzymatic mechanism has been considered for decades, yet recently has undergone a reassessment. After substrate binding – for which there is strong evidence for preference to dUMP as the first ligand in the wild-type E. coli enzyme – the important events are methylene transfer from MTHF to dUMP, proton abstraction and hydride transfer. The last of these – hydride transfer – is irreversible and rate-limiting (to a large degree without Mg2+, and to a small but noticeable degree with Mg2+). The studies described here are aimed at three therapeutically relevant questions: (a) determining the extent of negative charge accumulation at the O4 position of the hydride transfer acceptor; (b) expanding knowledge of the differential properties of E. coli and human TSase; and (c) gaining insight into the molecular origin of the drug resistance seen in a clinically relevant human TSase mutant. The properties touched on in this work include steady-state kinetics; inhibition constants toward 5-fluoro dUMP, substrate binding sequence and the temperature dependency of intrinsic hydride transfer kinetic isotope effects (KIEs). Intrinsic KIEs are a specialized measurement that permits the investigator to examine a particular hydrogen transfer step in isolation; it is achieved by labeling the bond to hydrogen broken in the reaction with protium (1H, also written as H), deuterium (2H, also written as D) or tritium (3H, also written as T). The latter is radioactive. The reaction is conducted with a mixture of two hydrogen isotopes at a time, and the extent to which the heavier isotope is disfavored against reaction is assessed; this covers multiple steps. Heavier isotopes directly participating in a chemical step react slower both because of zero-point vibrational energies if a semi-classical view is taken and because of the mass-dependence of tunneling probabilities if a quantum-mechanical view is taken. Each of the two-way isotopic comparisons mentioned above furnishes an observed KIE for that competition between two isotopes. Mathematical combination of two isotopic comparisons cancels out the effect of isotopically insensitive steps and provides rich insight into the hydride transfer alone. The ultimate result is the ratio of rate constants for the isotopologues; this ratio’s magnitude and variation with temperature report on the compactness of the active site and its resistance to thermal fluctuation, respectively. Our results reveal a possible role for E. coli asparagine 177 (N177) in the hydride transfer transition state (TS) stabilization, as revealed by its disruption in the aspartate mutant, N177D. This disruption was found to be alleviated to a high extent when the substrate was changed to dCMP, consistent with the N177 stabilizing partial negative charge at the TS for hydride transfer. This has drug design implications. Our work on human TSase underscores slightly weaker substrate binding preference, insensitivity to Mg2+ and mild alteration of hydride transfer TS when compared with E. coli TSase. Finally, analysis of the Y33H mutant of human TSase – the affected residue being remote from the active site – indicated the drug resistance was because of a higher inhibition constant for 5F-dUMP and that the hydride transfer step is disrupted, with a wider variation among donor-acceptor distances (between the two carbons involved in the hydride transfer at the TS for that step). Other researchers’ crystallographic evidence reveals greater positional uncertainty for a set of active-site side chains in the E. coli equivalent mutant. In totality, the data available implicate enzyme motions as relevant to drug binding and to catalysis for human TSase. In summary, the research described herein enriches the understanding of several aspects of the behavior of multiple TSase variants – the overall performance as seen via steady-state kinetics; the pattern of substrate binding as seen with observed KIEs for the proton abstraction step; and the efficiency of active site preparation for hydride transfer as evidenced in the temperature dependency of intrinsic hydride transfer KIEs.

enzymology

kinetic isotope effects

mutation

radiochemistry

reaction mechanisms

thymidylate synthase

Chemistry

Synthèse d'analogues nucléotidiques visant l'inhibition de la Thymidylate Synthase Flavine-Dépendante / Synthesis of nucleotides analogs targeting the inhibition of Flavin-Dependent Thymidylate Synthase

Chevrier, Florian

24 October 2018

Ces dernières années, l’OMS a émis un signal d’alarme à propos de l’occurrence majeure de résistance bactérienne qui constitue un problème de santé publique global. A ce titre, la recherche de nouvelles cibles enzymatiques et le développement de nouveaux antibactériens ciblant ces dernières de manière sélective constitue alors un enjeu actuel impératif. La mise en évidence d’une nouvelle enzyme de la famille des thymidylates synthases par l’équipe de Myllykallio en 2002 et son étude a permis de faire de cette dernière une cible de choix pour la conception de nouveaux antibactériens par sa présence exclusive chez des bactéries pathogènes pour l’Homme, sa non-similarité structurelle avec l’enzyme thymidylate synthase classique et son mécanisme particulier mettant en jeu un couple de cofacteurs oxydo-réducteurs(NADPH/FAD). Ce manuscrit, divisé en trois grandes parties, s’intéresse dans un premier temps à la synthèse métallo-catalysé de nouveaux analogues nucléotidiques du FAD substitué sur l’azote centrale par une chaîne acyclique de type alkényle phosphonate. Dans un second temps, le manuscrit traite de la translation de cette même chaîne latérale sur l’azote N1 couplée à un large panel de base hétéroaromatiquebicyliques ou tricycliques par deux réactions clés : une alkylation régiosélective en conditions deVorbrüggen et une étape de métathèse croisée. Enfin, la troisième partie porte sur la préparation d’acyclonucléosides comportant un motif d’intérêt de type gem-difluoromethylphosphonate connu comme étant un mime isostérique et isoélectronique du groupement phosphate. L’incorporation de ce motif a permis la synthèse de petite librairie d’ANPs inédits à visée anti-FDTS et anti-virales. / In recent years, WHO has warned against the major occurrence of bacterial resistance as a global public health problem. As such, the search for new enzymatic targets and the development of new antibacterials targeting them selectively is therefore an imperative challenge. The discovery of a new enzyme among the family of thymidylate synthases by Myllykallio’s team in 2002 and its study has made it a prime target for the design of new antibacterials by its sole presence in pathogenic bacteria, its structural dissimilarity with the classical thymidylate synthase enzyme and its singular mechanism involving a pair of oxido-reducingcofactors (NADPH / FAD).This manuscript, divided into three main parts, is initially interested in the metallocatalytic synthesis of new nucleotide analogues of FAD substituted on the central nitrogen by analkenyl phosphonate acyclic chain. In the second part, the manuscript deals with the translation of this same side chain on nitrogen N1 on a large panel of bicylic or tricyclic heteroaromatic base through two keyreactions: a regioselective alkylation under Vorbrüggen conditions and a cross metathesis step. Finally, th ethird part relates to the preparation of acyclonucleosides comprising a gem-difluoromethylphosphonatefunctional group which is known to be an isosteric and isoelectronic mimic of the phosphate group. The incorporation of this moeitie has allowed the synthesis of a small library of novel ANPs for anti-FDTS andanti-viral purposes.

Résistance bactérienne

Antibactériens

FDTS

Thymidylate synthase

Flavine

5-déazaflavine

Phosphononucléosides

Alkényles phosphonates

Métathèse

Difluorométhylphosphonates

Bacterial resistance

Antibacterials

FDTS

Thymidylate synthase

Flavin

5-deazaflavin

Phosphonucleosides

Alkenyl phosphonates

Metathesis

Difluoromethylphosphonates

547

Protein Engineering Studies Of The Dimeric Enzymes Thymidylate Synthase And Triosephosphate Isomerase

Gokhale, Rajesh S

01 1900

No description available.

Enzymes

Thymidylate Synthase (TS)

Trisephosphate Isomerase (TIM)

Protein Engineering

Protein Folding

Mutagenesis

Protein Stability

Dimeric Proteins

Biochemistry

Optimisation of Chemotherapy Treatment in Advanced Colorectal Cancer

Berglund, Åke

January 2002

<p>Colorectal cancer is one of the most common malignant diseases in Sweden – more than 5000 new cases are diagnosed each year. The overall five-year survival is about 60% and in cases of recurrence the prognosis is poor.</p><p>In a phase III study in advanced colorectal cancer the response rate was doubled when 5-FU was given as a bolus injection versus as a short infusion. The toxicity was similar and time to progression was longer in the injection group. However, overall survival was not significantly different. Dose-effect relationships of 5-FU were studied in another phase III study recruiting 312 patients. A decrease from 500 mg/m² to 400 mg/m² worsened the treatment results. A low incidence of severe toxicity was seen in both groups. An increase to 600 mg/m² worsened the toxicity without any improvement of the results.</p><p>A cytotoxic drug sensitivity test in different tumour types, mainly gastrointestinal cancer, poorly predicted treatment outcome in a phase II study.</p><p>The conventional Nordic Flv regimen was split in a phase I/II trial. An escalation of dose was possible and the response rate was 20%.</p><p>Thymidylate synthase (TS) and the gene expression of p53 were investigated by immunohistochemical technique in the primary tumours of 132 patients. None of the markers predicted the later palliative chemotherapy result. However, TS significantly predicted time to recurrence.</p><p>Serum markers were analysed before and during FLv treatment to early predict outcomes among 87 patients. TPS is promising, both as a predictive marker before start of treatment and after a short period of treatment. In the same setting, CEA had lower predictive value. S-VEGF and S-bFGF did not yield any prognostic information of later outcome. In all studies B-haemoglobin values, performance status and subjective response were strong markers, both for prediction of objective response and for survival.</p>

Oncology

Colorectal cancer

chemotherapy

5-fluorouracil

dose-effect relationship

ex vivo assay

thymidylate synthase

p53

CEA

TPS

VEGF

bFGF.

Onkologi

Oncology

Onkologi

Optimisation of Chemotherapy Treatment in Advanced Colorectal Cancer

Berglund, Åke

January 2002

Colorectal cancer is one of the most common malignant diseases in Sweden – more than 5000 new cases are diagnosed each year. The overall five-year survival is about 60% and in cases of recurrence the prognosis is poor. In a phase III study in advanced colorectal cancer the response rate was doubled when 5-FU was given as a bolus injection versus as a short infusion. The toxicity was similar and time to progression was longer in the injection group. However, overall survival was not significantly different. Dose-effect relationships of 5-FU were studied in another phase III study recruiting 312 patients. A decrease from 500 mg/m2 to 400 mg/m2 worsened the treatment results. A low incidence of severe toxicity was seen in both groups. An increase to 600 mg/m2 worsened the toxicity without any improvement of the results. A cytotoxic drug sensitivity test in different tumour types, mainly gastrointestinal cancer, poorly predicted treatment outcome in a phase II study. The conventional Nordic Flv regimen was split in a phase I/II trial. An escalation of dose was possible and the response rate was 20%. Thymidylate synthase (TS) and the gene expression of p53 were investigated by immunohistochemical technique in the primary tumours of 132 patients. None of the markers predicted the later palliative chemotherapy result. However, TS significantly predicted time to recurrence. Serum markers were analysed before and during FLv treatment to early predict outcomes among 87 patients. TPS is promising, both as a predictive marker before start of treatment and after a short period of treatment. In the same setting, CEA had lower predictive value. S-VEGF and S-bFGF did not yield any prognostic information of later outcome. In all studies B-haemoglobin values, performance status and subjective response were strong markers, both for prediction of objective response and for survival.

Oncology

Colorectal cancer

chemotherapy

5-fluorouracil

dose-effect relationship

ex vivo assay

thymidylate synthase

p53

CEA

TPS

VEGF

bFGF.

Onkologi

Oncology

Onkologi

Prädiktives und prognostisches Potential der Thymidylatsynthase als Biomarker im multimodalen Therapiekonzept 5-FU-basierter Radiochemotherapie des lokal fortgeschrittenen Rektumkarzinoms / Immunhistochemische Analyse prätherapeutischer Biopsien und korrespondierenden residuellen Tumorgewebes / Predictive and prognostic significance of thymdylate synthase as biomarker in multimodal treatment of 5-FU-based radiochemotherapy of locally advanced rectal cancer / Immunhistochemical analyses of pre-treatment biopsies and corresponding residual tumor tissue

Conradi, Lena-Christin

16 November 2010

No description available.

610 Medizin, Gesundheit

Medicine

Rektumkarzinom

Biomarker

multimodale Therapie

Thymidylatsynthase

rectal cancer

biomarker

multimodale Therapie

thymidylate synthase

44.64

44.47

Docking de compostos da família das ariloxazinas em enzimas relacionadas com a malária / Docking of arilloxazines in enzymes related to malaria

Corrêa, Denis da Silva

06 August 2010

Made available in DSpace on 2016-08-17T18:39:34Z (GMT). No. of bitstreams: 1 3220.pdf: 7184046 bytes, checksum: d31437c1aa1937336c7b8cb91918b19b (MD5) Previous issue date: 2010-08-06 / Universidade Federal de Minas Gerais / Malaria disease, caused mainly by Plasmodium falciparum parasite, afflicts about 500 million people and causes nearly one million deaths every year. For the development of new drugs against this disease, one possible approach is to identify an enzyme that plays a key role in P. falciparum development and presents significantly different properties from the corresponding human one. These differences can be exploited in the design of specific inhibitors of the parasite s protein, thus, three different enzymes were selected as possible targets. As there are evidences suggesting that increasing oxidative stress can effectively inhibit the growth of the malarial parasite the enzyme Glutathione Reductase of P. falciparum (PfGR), responsible for the parasite s antioxidant defense, has become a potential target for the design and development of inhibitors. The second target was the P. falciparum Dihydrofolate Reductase-Thymidylate Synthase (PfDHFR-TS), and in this case blocking its action stops the dTMP production and DNA synthesis in the parasite. The third chosen target was the P. falciparum Lactate Dehydrogenase (PfLDH), whose inhibition interrupts the ATP formation and thus causing the death of the parasite. So that a family of arilloxazines compounds, together with chloroquine and methylene blue, were studied by means of docking simulations in the binding sites of these enzymes and also in the corresponding human enzymes for comparison. The three-dimensional structures of the enzymes and of chloroquine and methylene blue were obtained from the Protein Data Bank (PDB). The structures of the arilloxazines compounds, in turn, were obtained by molecular modeling with HyperChem 6.01 and MOPAC2009 programs, using as starting models similar crystallographic structures deposited in the Cambridge Structural Database. Docking simulations were performed using GOLD 4.0.1. The docking results showed that the enzymes PfGR and PfDHFR-TS are not the preferential targets of chloroquine. For the methylene blue it was possible to elucidate its binding mode in hGR and PfGR. Regarding the arilloxazines it was possible to show that they present their higher affinity for hGR, followed by PfGR, hDHFR, PfDHFR-TS, PfLDH and hLDH. In the case of GRs, the interface site was the preferred binding site. The results suggest that if arilloxazines compounds with higher affinity for PfGR are desirable then a pentafluorophenyl should be attached at the N10 position, as in the 2e compound. When searching for arilloxazines with higher affinity for PfLDH, it seems to be desirable a carboxymethyl group at the N3 position (as in 5b) and a pentafluorophenyl group at N10 (as in 2e). Finally, the results suggest that in general the studied arilloxazines probably will present a higher affinity for hDHFR than PfDHFR-TS. All these results are an important starting point for the design of new arilloxazines ligands so that they can be used as lead compounds in the search for new drugs against malaria. / A malária, causada principalmente pelo Plasmodium falciparum, atinge cerca de 500 milhões de pessoas e causa aproximadamente um milhão de mortes todos os anos. Para o desenvolvimento de novos fármacos contra esta doença, uma das abordagens possível é identificar uma enzima que desempenhe papel vital no desenvolvimento do P. falciparum e apresente propriedades significantemente diferentes das enzimas humanas correspondentes, de modo que tais diferenças possam ser exploradas no design de inibidores específicos à proteína do parasita. Existem evidências sugerindo que aumentar o estresse oxidativo pode inibir eficientemente o crescimento do parasita causador da malária e, portanto, a enzima Glutationa Redutase do P. falciparum (GRPf), responsável por sua defesa antioxidante, tornou-se um alvo em potencial para o desenvolvimento de inibidores. Também, o bloqueio da ação da Diidrofolato Redutase-Timidilato Sintase do P. falciparum (DHFR-TSPf) interrompe a produção de dTMP e a síntese de DNA no parasita. Ainda, espera-se que a inibição da Lactato Desidrogenase do P. falciparum (LDHPf) interrompa a produção de ATP no parasita e, consequentemente, cause sua morte. Portanto, estudou-se o comportamento de compostos da família das ariloxazinas, da cloroquina e do azul de metileno nos sítios de ligação destas enzimas, além das enzimas humanas correspondentes para fins de comparação, por meio de cálculos de docking. As estruturas tridimensionais das enzimas foram obtidas no Protein Data Bank (PDB). As estruturas dos inibidores da família das ariloxazinas, por sua vez, foram obtidas por meio de modelagem molecular, utilizando os programas HyperChem 6.01 e MOPAC2009, a partir de estruturas cristalográficas semelhantes obtidas no Cambridge Structural Database; já as estruturas da cloroquina e do azul de metileno foram obtidas também no PDB. Os cálculos de docking destes compostos nos sítios de ligação das enzimas estudadas foram realizados utilizando o programa GOLD 4.0.1. Com base nos resultados de docking, sugere-se que as enzimas GRPf e DHFR-TSPf não são alvos preferenciais da cloroquina. Também, pôde-se elucidar o possível modo de ligação do azul de metileno nas enzimas GRh e GRPf. No geral, foi possível sugerir ainda que as ariloxazinas devam apresentar maior afinidade pela GRh, seguida por GRPf, DHFRh, DHFR-TSPf, LDHPf e LDHh, nesta ordem. Nas GRs, o sítio da interface foi o sítio preferencial de ligação. Para se buscar inibidores da família das ariloxazinas com maior afinidade pela GRPf, sugere-se considerar um pentafluorfenil como substituinte na posição N10, como no composto 2e. Ainda, na busca por ariloxazinas com maior afinidade pela LDHPf, sugere-se considerar um carboximetil na posição N3 (como o de 5b) e um pentafluorfenil na posição N10 (como em 2e). Por fim, foi obtido que as ariloxazinas estudadas possivelmente apresentarão, em geral, uma maior afinidade pela DHFRh do que pela DHFR-TSPf. Estes dados podem ser tomados como ponto de partida para o design de novos compostos da família das ariloxazinas, a fim de que possam atuar como compostos líderes na busca por novos fármacos contra a malária.

Biotecnologia

Glutationa redutase

Bioinformática

Biologia molecular

Ariloxazinas

Plasmodium falciparum

Malária

Docking

Arilloxazines

Glutathione reductase

Lactate dehydrogenase

Plasmodium falciparum

Malaria

OUTROS

Structural Characterization Of Protein Folding Intermediates

Bhattacharjya, Surajit

10 1900

No description available.

Protein Folding

Proteins

Hen Egg-white Lysozyme (HEWL)

Antigenic Peptides

Riboflavin Carrier Protein (RCP)

Thymidylate Synthase (TS)

Beta Hairpin

Synthetic Peptides

Biochemistry