Estudos cristalográficos em macromoléculas biológicas: Aplicações em calgranulina C de granulócitos porcinos, tripanotiona redutase deTrypanosoma cruzi e fosfolipase A2 extraída do veneno da serpente Bothrops moojeni. / Crystallographic studies on biological macromolecules: applications on calgranulin C from porcine granulocytes, trypanotione reductase from Trypanosoma cruzi and Phospholipase A2 extracted from the venom of Bothrops moojeni snake.

Costa, Maria Cristina Nonato

21 March 1997

A cristalografia de raios-X e um método de singular importância para a determinação da estrutura de macromoléculas. A importância em resolver estruturas de proteínas continua a crescer em campos variando desde a bioquímica e biofísica básicas ate o desenvolvimento farmacêutico e biotecnologia. o presente trabalho esta relacionado com os estudos cristalográficos de três diferentes moléculas biológicas. Calgranulina C de granulócitos porcinos, uma proteína que liga cálcio, supostamente envolvida em processos celulares regulados, foi cristalizada com parâmetros de rede a=b=54.35 e c=141.32&#197, grupo espacial P3121 ou seu enantiomorfo P3221. Várias tentativas foram feitas no sentido de se determinar a estrutura por substituição molecular, mas a alta flexibilidade entre os motivos \"EF-hands\" quando da ligação ao íon cálcio podem ser responsáveis pelo insucesso dos resultados. Tripanotiona redutase de T. cruzi e um excelente alvo para modelagem de inibidores e potenciais drogas contra a doença de Chagas. O complexo mutante TR + GSPD foi cristalizado com parâmetros de rede a=b=92.7 e c=156.2&#197, grupo espacial P43. Um conjunto preliminar de fases foi obtido por refinamento de corpo rígido contra as coordenadas da TR nativa. O modelo foi refinado a 2.4&#197 de resolução, Rfactor=19.8%. Fosfolipase A2 extraída do veneno da serpente Bothrops moojeni foi cristalizada com parâmetros de rede a=63.1, b=90.5 e c=40.2&#197 e &#946=125.1&#176, grupo espacial C2. A estrutura foi resolvida por substituição molecular usando o dímero da fosfolipase A2 de Crotalus atrox como modelo. A analise de sua seqüência de aminoácidos e necessária para posteriores ciclos de refinamento. / X-ray crystallography is a essential method for determination of the structure of macromolecules. The importance of solving protein structures continues to grow in fields ranging from basic biochemistry and biophysics to pharmaceutical development and biotechnology. The current work is concerned to the crystallographic studies of three different biological molecules. Calgranulin C from pig granulocytes, a calcium binding protein though to be involved in regulation of cell process, was crystallized with cell parameters a=b=54.35 and c=141.32&#197, space group P3121 or its enantiomorph P3221. Several attempts were made in order to solve the structure, but the high flexibility between its EF-hands motives while binding the ion calcium may be responsible for the lack of success in the results. Trypanothione reductase (TR) from T. cruzi is a target enzyme for modeling an inhibitor for Chagas´ disease. The C58S TR + GSPD mutant complex was crystallized with a=b=92.7 and c=156.2&#197, space group P43. A preliminary set of phases was obtained by rigid body refinement against the coordinates for the native TR. The model was refined to 2.4&#197 resolution, Rfactor=19.8%. Phospholipase A2 extracted from the venon of the snake Bothrops moojen; was crystallized with cell parameters a=63.1, b=90.5, c=40.2&#197 and &#946=125.1&#176, space group C2. The structure was solved by molecular replacement techniques using the dimer of phospholipase A2 from Crotalus atrox as a model. The aminoacid sequence analysis is needed for further refinement cycles.

Calgranulin C

Calgranulina C

Cristalografia de proteínas

Fosfolipase A2

Phospholipase A2

Protein crystallography

Tripanotiona redutase

Trypanothione reductase

Estudos estruturais do domínio GTPase isolado da septina humana SEPT4 e estrutura cristalográfica da Glutationa -S- Transferase de Xylella fastidiosa / Structural Studies of the GTPase domain from human SEPT4 and Crystallography Structure of Glutathione S-transferase from Xylella fastidiosa

Rodrigues, Nathalia de Campos

31 October 2008

As septinas constituem uma conservada família de proteínas de ligação a nucleotídeos de guanina e formação de heterofilamentos. Em mamíferos, tais proteínas estão envolvidas em uma variedade de processos celulares tais como citocinese, exocitose e tráfego de vesículas. A SEPT4 tem sido identificada em depósitos filamentosos e inclusões citoplasmáticas em Alzheimer e doença de Parkinson, respectivamente. A SEPT4 é a única proteína em associação com proteínas aberrantes em depósitos em ambos os tipos de doenças Assim, estudos adicionais de propriedades bioquímicas estruturais e funções fisiológicas para a SEPT4 podem promover importantes insights em relação ao mecanismo das doenças neurodegenerativas citadas acima. O desenovelamento térmico do domínio GTPase do SEPT4-G revelou um intermediário que agrega rapidamente na forma de fibras tipo amilóide em condições fisiológicas. Neste estudo a análise cinética da agregação do SEPT4-G foi monitorada utilizando fluorescência extrínseca e dicroísmo circular. Com os resultados e análises realizados durante este trabalho de mestrado foi possível compreender com mais detalhes a cinética de formação de agregados tipo amilóide do domínio SEPT4-G. Este trabalho também descreve a cristalização, coleta de dados, resolução e refinamento do modelo cristalográfico para a enzima Glutationa-S-Transferase de Xylella fastidiosa. Tal enzima está associada à patogenicidade da bactéria X. fastidiosa, responsável por várias doenças em plantas economicamente importantes, incluindo a Clorose Variegada dos Citros (CVC) ou Amarelinho. Algumas análises também foram realizadas após a obtenção do modelo cristalográfico demonstrando as diferenças estruturais entre GSTs bacterianas. / The septins are a conserved family of guanine nucleotides-binding and hetero-filament forming. proteins. In mammals they are involved in a variety of cellular processes, such as cytokinesis, exocytosis, and vesicle trafficking. SEPT4 has been reported to accumulate in tau-based filamentous deposits and cytoplasmic inclusions in Alzheimers and Parkinsons diseases respectively. Sept4 is unique in its association with the aberrant protein depositions in both types of diseases. Further studies on the biochemical, structural properties and physiological functions of Sept4 may therefore provide important insights into the common mechanism underlying diverse neurodegenerative disorders. Thermal unfolding of the GTPase domain of SEPT4 (SEPT4-G) revealed an unfolding intermediary which rapidly aggregates into amyloid-like fibers under physiological conditions. In this study, the kinetic analysis of aggregation of SEPT4-G was monitored using extrinsic fluorescence and circular dichroism spectroscopy. The aggregates have the ability to bind specific dyes such as Thioflavin-T (ThT), suggesting that they are amyloid in nature. Fibrils formation was monitored by the increase in ThT emission and electron microscopy as a function of temperature, pH, metal ions and protein concentration. Glutathione S-transferases (GSTs) form a group of multifunctional isoenzymes that catalyze the glutathione-dependent conjugation and reduction reactions involved in the cellular detoxification of xenobiotic and endobiotic compounds. GST from Xylella fastidiosa (XfGST) was crystallized by the vapour-diffusion method and its crystallography structure was solved for molecular replacement and refined. Afterwards, sequential and structural analyses were carried out for XfGST and others GSTs.

Cristalografia de proteínas

espectroscopia

Espectroscopy

Glutathione-S-transferase

Glutationa-S-transferase

Protein Crystallography

septinas

Septins

Estudos estruturais e funcionais das oxidoredutases de pontes dissulfeto da familía DsbA de Xylella fastidiosa / Structural and functional studies of the disulfide oxidorecdutases DsbA from Xylella fastidiosa

Rinaldi, Fabio Cupri

26 March 2008

Orientadores: Beatriz Gomes Guimarães, Jose Antonio Brum / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin / Made available in DSpace on 2018-09-27T18:06:10Z (GMT). No. of bitstreams: 1 Rinaldi_FabioCupri_D.pdf: 8466921 bytes, checksum: 8a88bf7cf4ccef10efbca8ec0412db74 (MD5) Previous issue date: 2008 / Resumo: As oxidoredutases de pontes dissulfeto da família DsbA são responsáveis pela catálise da formação de pontes dissulfeto em proteínas secretadas para o periplasma, participando do processo de enovelamento de fatores de virulência de diversos organismos. É a proteína com maior potencial de oxidação atualmente caracterizada e tal propriedade é associada às interações eletrostáticas envolvendo resíduos de seu sítio ativo, que apresenta um arranjo Cys-Pro-His-Cys altamente conservado. A bactéria fitopatogênica Xylella fastidiosa possui dois genes adjacentes que codificam duas oxidoredutases pertencentes à família das DsbAs (XfDbsA e XfDbsA2). Embora a XfDbsA conserve o arranjo CPHC, a XfDbsA2 possui a substituição do resíduo histidina, descrito como essencial à atividade da enzima, por alanina (CPAC). Visando a caracterização estrutural e funcional destas proteínas, a estrutura cristalográfica da XfDsbA foi determinada a 1,9 Å de resolução e um modelo por homologia da XfDsbA2 foi construído. Além disso os potenciais de oxidação das enzimas foram determinados por medidas de fluorescência. A estrutura da XfDsbA revelou a presença de um peptídeo ligado próximo a região do sítio ativo em um dos monômeros mostrando, pela primeira vez em uma estrutura a alta resolução, o provável modo de interação da DsbA com um substrato. Os ensaios funcionais revelaram que as DsbAs de X. fastidiosa apresentam potenciais redox similares e ligeiramente superiores ao da homóloga de Escherichia coli. Embora trabalhos sobre a importância do arranjo CPHC têm associado o alto potencial redox das DsbAs à presença do resíduo histidina no sítio ativo, os resultados obtidos para a XfDsbA2 mostraram que a substituição do resíduo de histidina por alanina não afeta seu potencial redox. A análise das interações envolvendo resíduos do sítio ativo mostrou diferenças importantes entre XfDsbA, XfDsbA2 e suas homólogas de E. coli e Vibrio cholerae. Ensaios funcionais com mutantes foram realizados em busca da identificação dos resíduos que possam compensar a ausência da histidina em XfDsbA2. Os resultados obtidos fornecem novas informações sobre o mecanismo molecular dessa família de enzimas / Abstract: Disulfide oxidoreductase DsbA catalyzes disulfide-bond formation in proteins secreted to the periplasm and has been related to the folding process of virulence factors in many organisms. It is the most oxidizing of the thioredoxin-like proteins and DsbA redox power is understood in terms of the electrostatic interactions involving the active site motif CPHC. The plant pathogen Xylella fastidiosa has two chromosomal genes encoding two oxidoreductases belonging to the DsbA family and, in one of them, the canonical motif CPHC is replaced by CPAC. Aiming at the structural and functional characterization of X. fastidiosa DsbAs, the crystal structure of XfDsbA was solved at 1.9 Å resolution and the XfDsbA2 homology model was calculated. We also determined the redox potential of both enzymes by means of fluorescence experiments. The crystal structure of the XfDsbA revealed an electron density corresponding to an 8-mer peptide interacting with the hydrophobic groove on the surface of the monomer C next to the active site. This modeled peptide shows at first time in a high-resolution crystal structure the probable mode of interaction between DsbA and a substrate. Furthermore, the results presented in this work surprisingly show that, despite the absence of the active site histidine in XfDsbA2, both proteins have similar redox potentials. In addition, the structure of XfDsbA revealed critical differences in the interactions involving the active site residues. Biochemical assays with XfDsbA mutants were performed in order to investigate the residues which may be responsible for compensate for the lack of the conserved histidine in XfDsbA2. The results presented contribute to the understanding of DsbA molecular mechanism / Doutorado / Física da Matéria Condensada / Doutor em Ciências

Oxidoredutases de pontes dissulfeto

Cristalografia de proteínas

Fluorescência

Xylella fastidiosa

Disulfide bond oxidoreductases

Protein crystallography

Fluorescence

Xylella fastidiosa

Caracterização estrutural e avaliação de aspectos funcionais de galectinas humanas do grupo tandem-repeat / Structural characterization and evaluation of functional aspects of human galectins from tandem-repeat group

Joane Kathelen Rustiguel Bonalumi

12 November 2014

As galectinas, proteínas que compartilham características como afinidade por ?-galactosídeos e a presença de um domínio de reconhecimento ao carboidrato (CRD), tem como importante papel a decodificação de mensagens moleculares. As galectinas são encontradas em uma grande variedade de células e tecidos animais e estão envolvidas em diversos processos celulares relacionados a resposta imune e inflamatória. O grupo tandem-repeat das galectinas é formado por proteínas que apresentam dois CRDs distintos (CRD1 e CRD2) conectados por um peptídeo de ligação, ao qual pertencem as galectinas-4 e -12 humanas, alvos de nosso estudo. Durante o desenvolvimento do presente projeto foram utilizadas abordagens multidisciplinares através de técnicas biofísicas, cristalográficas, computacionais e imunoquímicas. Foi iniciado o estudo de caracterização estrutural da galectina-4 humana (hGal4) e seus domínios hGal4-CRD1 e hGal4-CRD2, de forma independente, através da produção heteróloga das proteínas e ensaios de estabilidade térmica e cristalização. As estruturas cristalográficas dos domínios foram determinadas a 1,48 e 2,46 Å de resolução, respectivamente e utilizadas para a construção de um modelo para a hGal4. Com base nos estudos de dinâmica molecular e estabilidade térmica foi possível propor um modelo de interação entre os CRDs através do peptídeo de ligação. Ensaios de dinâmica da hGal4 com LacNAc sugeriram uma diferença de plasticidade dos CRDs no reconhecimento do ligante. Foram também realizadas incessantes tentativas de desenvolver um protocolo de expressão heteróloga para as isoformas e domínios da galectina-12 humana (hGal12). Como resultado, observamos uma alta tendência à formação de corpos de inclusão e agregados resistentes a desnaturação, além da susceptibilidade ao ataque proteolítico. Os modelos estruturais dos domínios da hGal12 não permitiram identificar nenhuma característica que justificasse o comportamento das proteínas. Foram realizados estudos de localização celular em células HL-60 e foi possível identificar a presença da hGal12 na superfície das gotas de lipídio, organelas responsáveis pelo armazenamento de energia e o processo de catabolismo celular. A alta insolubilidade observada para as isoformas e domínios da hGal12, a sua localização em gotas de lipídeos, a divergência evolutiva da hGal12 quando comparada com outras galectinas do mesmo grupo e incluindo o fato de um dos CRDs não apresentar os requerimentos estruturais básicos para ligar ?-galactosídeos, nos leva a especular se essa proteína estaria, na verdade, sendo expressa como parte de um heterocomplexo proteico, que estabilizaria a estrutura da hGal12 e a endereçaria para as gotas de lipídeo. Em nossa hipótese, o domínio hGal12-CRD2 poderia ter evoluído para favorecer a interação com outros parceiros macromoleculares. Devido ao importante papel desempenhado pelas galectinas em inúmeros processos celulares, os resultados aqui obtidos representam uma importante contribuição no entendimento do papel que as galectinas hGal4 e hGal12 exercem nos diferentes eventos celulares, além de fornecem ferramentas experimentais para desenvolvimento de futuros estudos funcionais. / Galectins are proteins that share characteristics such as affinity for ?-galactosides and the presence of a carbohydrate recognition domain (CRD). They belong to a family of proteins that display the important role of decoding molecular messages. Galectins are found in a variety of cell types and are involved in several biological phenomena related to immune response and inflammation. The tandem-repeat group of galectins consists of proteins with two distinct CRDs (CRD1 and CRD2) connected by a peptide linker, in which belong galectins-4 and -12, targets of our study. During the development of the present project a multidisciplinary approach was used including the use of biophysical, crystallographic, computational and immunochemical techniques. The structural characterization of human galectin-4 (hGal4) and its hGal4-CRD1 and hGal4-CRD2 independent domains was initiated by their heterologous protein production, thermal stability and crystallization assays. The crystallographic structure of domains were determined at 1.48 e 2.46 Å resolution, respectively, and used for constructing a model for hGal4. Based on molecular dynamics and thermal stability studies we propose a model of interaction between CRDs mediated by linker peptide. Dynamics simulation of hGal4 with LacNAc suggested a difference in plasticity between CRDs and ligand recognition. In addition, several attempts have been made towards the development of a protocol for expression of isoforms and independent domains from human galectin-12 (hGal12). As result, we observed a high tendency to body inclusion formation and denaturing resistant aggregates, besides high susceptibility to proteolytic attack. Structural models for the hGal12 domains did not allow the identification of any feature to justify proteins behavior. Cell location studies in HL-60 cells were performed and hGal12 was found to be located on the surface of lipid droplets, organelles responsible for energy storage and catabolism. The high insolubility displayed by isoforms and domains from hGal12, together with its location on lipid droplets, the evolutionary divergence of hGal12 compared to tandem-repeat proteins, and the fact that hGal12-CRD2 does not present the structural requirements for ?-galactosides binding, suggest that hGal12 is, in fact, expressed as part of a protein complex that could both stabilize hGal12 structure and guide it to the lipid droplets. In our hypothesis, the hGal12-CRD2 could have evolved in order to favor the interaction with other macromolecular partners. Due to crucial roles displayed by galectins in innumerous biological process, we believe that our results represent an important contribution for the understanding of hGal4 e hGal12 proteins roles within the cell, besides providing experimental tools for the development of further functional studies.

Cristalografia de proteínas

Galectinas

Carbohydrate recognition domains

Galectins

Protein crystallography

Estrutura cristalográfica da N-acetilglicosamina 6-fosfato desacetilase de Escherichia coli / Crystallographic structure of the N-acetylglicosamine 6-phosphate deacetylase from Escherichia coli

Ferreira, Frederico Moraes

23 October 2004

O objetivo do presente trabalho é a elucidação da estrutura cristalográfica da proteína N-acetilglicosamina 6-fosfato desacetilase (desacetilase) da bactéria Escherichia coli. A desacetilase é um tetrãmero de subunidades idênticas de 382 aminoácidos e massa molecular de 41 kDa. Esta é uma enzima da via de catabolismo de açúcares aminados e cataliza a conversão do N-acetilglicosamina 6-fosfato em glicosamina 6-fosfato. Nesta via a bactéria dedica cinco genes organizados em um regulon, o nagE-nagBACD, com propósitos de obtenção de energia e de reciclagem de componentes de parede celular. A reciclagem de componentes de parede celular é a via de maior atividade metabólica de E. coli, na qual aproximadamente 40% dos peptidoglicanos de parede celular são quebrados a cada geração, sendo o N-acetilglicosamina (GlcNAc) reutilizado para a síntese de novo de peptidoglicanos e lipopolissacarídeos de membrana externa. O GlcNAc exerce funções multi-regulatórias na via de catabolismo de aminoaçúcares e a desacetilase é o maior fator controlador da sua concentração intracelular. Foi demonstrado que a desacetilase é a enzima mais importante da via e que sem ela a E. coli não é capaz de reciclar o GlcNAc. A desacetilase é encontrada em outros organismos desempenhando funções igualmente importantes, estando relacionada à captura e o armazenamento de carboidratos em hepatócitos e células sinusiais de fígado de camundongo, à morfogênese e à diminuição da patogenicidade e da adesão da Candida albicans a tecidos endoteliais, chegando também a ser estudada para desenvolvimento de inibidores contra o parasita da malária o Plasmodzum falciparum. Neste trabalho foram descritos os procedimentos desde a subclonagem do gene codificador da desacetilase de E. coli até a interpretação da sua estrutura quaternária, incluindo a expressão, a purificação, a cristalização, a produção de cristas derivados de átomos pesados, a estimativa de fases e a construção e refinamento do modelo cristalográfico. A estrutura foi resolvida por espalhamento anômalo de iodo de baixa resolução (2,9 angstron), em comprimento de onda único, sendo refinada a resolução de 2,0 angstron. Na unidade assimétrica encontram-se dois monômeros relacionados por um eixo de ordem 2 não cristalográfico aproximadamente a 15° da direção do eixo cristalográfico c. A simetria do cristal aplicada à unidade assimétrica leva a formação de um tetrâmero cuja área da superfície de tetramerização é de 5.343 angstron2, correspondente a 18,4% da área do dímero. A área de superfície de acessibilidade da interface dimerização é de 1.053 angstron2, correspondente a 6,8 % da área do monômero. O monômero da desacetilase é constituído por dois domínios: o beta, um pequeno sanduíche beta; e o alfa, um pseudo barril (beta/alfa)8 comum aos membros da super família da Amidohidrolases. O domínio-beta é constituído por duas folhas beta mistas e uma hélice alfa. O domínio- alfa é constituído por 11 hélices alfa e por três folhas beta, uma paralela e as outras duas anti paralelas. No domínio- beta, oito das onze hélices alfa formam ligações cruzadas com as oito fitas da folha beta paralela para formar o \"barril\" onde encontra-se o sítio ativo. No sitio ativo foi observada a presença de um íon fosfato. Os resíduos do sítio ativo que participam da ligação ao fosfato são Gln59, Glu131, His195, His216 e Asp273, dos quais pelo menos uma histidina e um ácido aspártico têm se conservado em membros da super família das Amidohidrolases / The goal of the present work is to elucidate the crystallographic structure of the protein N-acetylglucosamine Bphosphate deacetylase (deacetylase) from Escherichia coli. The deacetylase is a tetramer of identical subunits with 382 aminoacids and molecular weight of 41 kDa. It is an euzyme of the amino sugar catabolism pathway and it catalyzes the conversion of the N-acetylglucosamine Gphosphate in to glucosamine 6-phosphate. In this pathway the bacteria dedicates five genes organized in the nagE-nagBACD regulon for purposes of cell wall component recycling and energy production. The cell wall component recycling is the major E. coli metabolic pathway in which aproximately 40% of the cellular wall peptidoglicans is broken in each generation. Its degradation product, the amino sugar N-acetylglucosamine (GlcNAC) is reused for the peptidoglican and for the lipopolysacharide de novo synthesis. The GlcNAC plays several regulatory roles in the amino sugar catabolism pathway and deacetylase is its major intra cellular concentration controlling factos. It was demonstrated that without the deacetylase, E. coli is uncapable of recycling the GlcNAc. The deacetylase plays important roles in the other organisms in which it has been found. It is related to the carbohydrate up-take and storage in hepatocytes and sinusoidal cells from rat liver and to the Candida albicans morphogenesis, pathogenicity and adherence to the endothelial tissues. Deacetylase has also been studied in the development of inhibitors against the malaria parasite Plasmodzum falciparum. This work describes all the approaches from the nagA subcloning to the crystallographic structure analysis, including deacetylase expression, purification, crystallization, heavy atoms derivatives production, phasing, model building and model refinement. The E. coli deacetylase structure was solved by Single Anomalous Dispersion using low resolution (2,0 angstron) iodine anomalous scattering. The structure was refined to 2,0 angstron resolution. The contends of the asymmetric unit is a dimer related by a non-crystallographic 2-fold symmetry axis about 15° from the crystallographic axis c. The crystallographic symmetry applied to the asymmetric unit produces a tetramer, whose the surface accessibility of the buried area is 5.343 angstron, corresponding to 18.4 % of the dimer total area. The dimer surface accessibility of the buried area is 1.053 angstron2, corresponding to 6.8 % of the monomer total area. The deacetylase monomer folds into two domains, a pseudo (beta/alfa)8 barrel enclosing the catalytic site of the enzyme and a small beta sandwich made up from secondary structure elements contributed by the N and C termini. The beta domain is composed of two mixt beta sheets and one alfa helice. The alfa domain is composed of 11 alfa helices and 3 beta sheets, one of them parallel and the other two anti parallel. In the alfa domain, 8 alfa helices are cross linked to 8 beta strands to form the pseudo barrel which encloses the active site. A phosphate ion was found into the catalytic site. The catalytic residues that bind the phosphate ion are Gln59, Glu131, Hisl95, His216 and Asp273, from which at least one histidine and one aspartic acid are conserved amongst the Amidrohydrolases super family members

Açúcares aminados

Aminated sugars

Cristalografia de proteínas

Difração de raios-x

Protein crystallography

X-ray diffraction

Structural studies of Erwinia carotovora L-Asparaginase by X-ray crystallography

Andersson, Charlotta

January 2006

<p>Bacterial L-asparaginases (E.C.3.5.1.1) are enzymes that catalyze the hydrolysis of L-asparagine to aspartic acid. For the past 30 years these enzymes have been used as therapeutic agents in the treatment of acute childhood lymphoblastic leukemia. The presence of a low rate glutaminase activity however causes serious side-effects to patients in treatment, as glutamine depletion give rise to neurotoxicity, anaphylaxis, and other hypersensitivity reactions. The interest in the enzyme from Erwinia carotovora originates from the fact that it shows a decreased glutaminase activity, and therefore the enzyme is expected to exhibit fewer side effects when used in therapy.</p><p>The main focus of this thesis is the crystal structure determination of L-asparaginase from Erwinia carotovora in the presence of aspartic acid at 2.5 Å resolution. The structure was refined to an R/Rfree factor of 19.9/28.6 with good stereochemistry.</p><p>L-Asparaginases are homotetrameric enzymes with a known 222 symmetry and an identical fold. The Erwinia carotovora asparaginase consists of eight monomers of 330 amino acid residues each. In this case the enzyme is active as a dimer of tetramers. The two tetramers have an inner twofold non-crystallographic symmetry. Each monomer forms two identifiable domains a large N-domain and a small C-domain. The active sites are found at a topological switch-point between those domains.</p>

Protein crystallography

enzyme

crystal structure determination

asparaginase

leukemia treatment

TECHNOLOGY

TEKNIKVETENSKAP

Structural Study of the WH2 Family and Filamin: Implications for Actin Cytoskeleton Regulation

Aguda, Adeleke H.

January 2006

<p>Cellular processes like motility, chemotaxis, phagocytosis and morphogenesis are dependent on the dynamic regulation of the actin cytoskeleton. This cytoskeleton system is tightly controlled by a number of diverse actin-binding proteins (ABPs) by various mechanisms described as nucleation, polymerization, capping, severing, depolymerization and sequestration. The ABPs are grouped based on sequence identity as in the Wiskott-Aldrich Syndrome protein homology domain 2 (WH2), and the calponin homology domain (CH) containing proteins.</p><p>In this work, we elucidate the crystal structures of hybrids of gelsolin domain 1 with thymosin β4, ciboulot domain 2, and the second WH2 domain of N-WASP each bound to actin. We show that the single WH2 motif containing protein thymosin β4 in part sequesters actin by binding its pointed end via a C-terminal helix. This interaction prevents the addition of bound actin protomers to the barbed end of the filament. We propose that sequence variations in some WH2 motifs conferred F-actin binding ability to multiple repeat-containing proteins. These F-actin binding domains interact with the barbed end of a filament and the adjacent WH2 motifs are then freed to add their bound actin to the growing filament end. We demonstrate the binding of ciboulot domains 2 and 3 to both G- and F-actin and that full length ciboulot is capable of binding two actin monomers simultaneously. </p><p>We have also cloned, expressed, purified and crystallized rod domains 14-16 from the actin crosslinking protein a-filamin. Preliminary X-ray crystallography data gives us hope that we shall be able to solve the structure of this triple domain repeat.</p>

Biochemistry

Actin

Thymosin

Ciboulot

N-WASP

Filamin

Calponin homology domain

WH2

Protein Crystallography

Biokemi

Structural Study of the WH2 Family and Filamin: Implications for Actin Cytoskeleton Regulation

Aguda, Adeleke H.

January 2006

Cellular processes like motility, chemotaxis, phagocytosis and morphogenesis are dependent on the dynamic regulation of the actin cytoskeleton. This cytoskeleton system is tightly controlled by a number of diverse actin-binding proteins (ABPs) by various mechanisms described as nucleation, polymerization, capping, severing, depolymerization and sequestration. The ABPs are grouped based on sequence identity as in the Wiskott-Aldrich Syndrome protein homology domain 2 (WH2), and the calponin homology domain (CH) containing proteins. In this work, we elucidate the crystal structures of hybrids of gelsolin domain 1 with thymosin β4, ciboulot domain 2, and the second WH2 domain of N-WASP each bound to actin. We show that the single WH2 motif containing protein thymosin β4 in part sequesters actin by binding its pointed end via a C-terminal helix. This interaction prevents the addition of bound actin protomers to the barbed end of the filament. We propose that sequence variations in some WH2 motifs conferred F-actin binding ability to multiple repeat-containing proteins. These F-actin binding domains interact with the barbed end of a filament and the adjacent WH2 motifs are then freed to add their bound actin to the growing filament end. We demonstrate the binding of ciboulot domains 2 and 3 to both G- and F-actin and that full length ciboulot is capable of binding two actin monomers simultaneously. We have also cloned, expressed, purified and crystallized rod domains 14-16 from the actin crosslinking protein a-filamin. Preliminary X-ray crystallography data gives us hope that we shall be able to solve the structure of this triple domain repeat.

Biochemistry

Actin

Thymosin

Ciboulot

N-WASP

Filamin

Calponin homology domain

WH2

Protein Crystallography

Biokemi

Amorphous Silicon Based Large Area Detector for Protein Crystallography

Sultana, Afrin

January 2009

Proteins are commonly found molecules in biological systems: our fingernails, hair, skin, blood, muscle, and eyes are all made of protein. Many diseases simply arise because a protein is not folded properly. Therefore, knowledge of protein structure is considered a prerequisite to understanding protein function and, by extension, a cornerstone for drug design and for the development of therapeutic agents. Protein crystallography is a tool that allows structural biologists to discern protein structures to the highest degree of detail possible in three dimensions. The recording of x-ray diffraction data from the protein crystal is a central part of protein crystallography. As such, an important challenge in protein crystallography research is to design x-ray detectors to accurately determine the structures of proteins. This research presents the design and evaluation of a solid-state large area at panel detector for protein crystallography based on an amorphous selenium (a-Se) x-ray sensitive photoconductor operating in avalanche mode integrated with an amorphous silicon (a-Si:H) charge storage and readout pixel. The advantages of the proposed detector over the existing imaging plate (IP) and charge coupled device (CCD) detectors are large area, high dynamic range coupled to single x-ray detection capability, fast readout, high spatial resolution, and inexpensive manufacturing process. The requirement of high dynamic range is crucial for protein crystallography since both weak and strong diffraction spots need to be imaged. The main disadvantage of a-Si:H thin film transistor (TFT) array is its high electronic noise which prohibits quantum noise limited operation for the weak diffraction spots. To overcome the problem, the x-ray to charge conversion gain of a-Se is increased by using its internal avalanche multiplication gain. Since the detector can be made approximately the same size as the diffraction pattern, it eliminates the need for image demagnification. The readout time of the detector is usually within the ms range, so it is appropriate for crystallographic application. The optimal detector parameters (such as, detector size, pixel size, thickness of a-Se layer), and operating parameters (such as, electric field across the a-Se layer) are determined based on the requirements for protein crystallography. A complete model of detective quantum efficiency (DQE) of the detector is developed to predict and optimize the performance of the detector. The performance of the detector is evaluated in terms of readout time (< 1 s), dynamic range (~10^5), and sensitivity (~ 1 x-ray photon), thus validating the detector's efficacy for protein crystallography. The design of an in-house a-Si:H TFT pixel array for integration with an avalanche a-Se layer is detailed. Results obtained using single pixel are promising and highlight the feasibility of a-Si:H pixels coupled with avalanche a-Se layer for protein crystallography application.

Electrical and Computer Engineering

Structural studies of Erwinia carotovora L-Asparaginase by X-ray crystallography

Andersson, Charlotta

January 2006

Bacterial L-asparaginases (E.C.3.5.1.1) are enzymes that catalyze the hydrolysis of L-asparagine to aspartic acid. For the past 30 years these enzymes have been used as therapeutic agents in the treatment of acute childhood lymphoblastic leukemia. The presence of a low rate glutaminase activity however causes serious side-effects to patients in treatment, as glutamine depletion give rise to neurotoxicity, anaphylaxis, and other hypersensitivity reactions. The interest in the enzyme from Erwinia carotovora originates from the fact that it shows a decreased glutaminase activity, and therefore the enzyme is expected to exhibit fewer side effects when used in therapy. The main focus of this thesis is the crystal structure determination of L-asparaginase from Erwinia carotovora in the presence of aspartic acid at 2.5 Å resolution. The structure was refined to an R/Rfree factor of 19.9/28.6 with good stereochemistry. L-Asparaginases are homotetrameric enzymes with a known 222 symmetry and an identical fold. The Erwinia carotovora asparaginase consists of eight monomers of 330 amino acid residues each. In this case the enzyme is active as a dimer of tetramers. The two tetramers have an inner twofold non-crystallographic symmetry. Each monomer forms two identifiable domains a large N-domain and a small C-domain. The active sites are found at a topological switch-point between those domains.

Protein crystallography

enzyme

crystal structure determination

asparaginase

leukemia treatment

TECHNOLOGY

TEKNIKVETENSKAP