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Protection Against Schistosoma Mansoni Infection With a Recombinant Baculovirus-Expressed Subunit of CalpainHota-Mitchell, Sheela, Siddiqui, Afzal A., Dekaban, Gregory A., Smith, Jana, Tognon, Cristina, Podesta, Ronald B. 01 October 1997 (has links)
Infections by human schistosomes, in particular Schistosoma mansoni, account for significant morbidity and mortality every year in tropical and sub-tropical areas. The eggs of the parasite induce pathological changes in the infected host; in chronic and heavy infections, these changes may lead to death. A well-designed anti-schistosomal vaccine, alone or in concert with existing control measures such as chemotherapy, may prove to be a safe, inexpensive and effective means of reducing the occurrence of severe disease and death in S. mansoni infection. Previous studies have demonstrated the importance of the syncytial layer containing the apical plasma membrane (APM) of S. mansoni in both the survival of the parasite in the mammalian host and as a potential source of immunogens which may be utilized as vaccine candidates. In this paper we present evidence for the protective capacity of several schistosomal antigen preparations, including a calcium binding protein of the APM, S. mansoni calpain (GenBnnk accession no. M74233). We have constructed and characterized expression of a recombinant baculovirus expressing the large subunit of S. mansoni calpain, Sm-p80. This recombinant Sm-p80 is recognized by IgA, IgM, IgG1, and IgG3 isotype antibodies found in S. mansoni-infected human sera and partially-purified recombinant Sm-p80 provided a 29-39% reduction in worm burden in immunized mice challenged with S. mansoni. Our data indicate that Sm-p80 may be a useful vaccine antigen for the reduction of the morbidity associated with S. mansoni infections of mammalian hosts.
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Development of Engineered Extracellular Vesicle-Liposome Hybrid Using Baculovirus-Expression System / バキュロウイルス発現系を用いて機能化された細胞外ベシクル-リポソームハイブリッドの開発Ishikawa, Raga 23 March 2021 (has links)
京都大学 / 新制・課程博士 / 博士(工学) / 甲第23225号 / 工博第4869号 / 新制||工||1760(附属図書館) / 京都大学大学院工学研究科高分子化学専攻 / (主査)教授 秋吉 一成, 教授 跡見 晴幸, 教授 大塚 浩二 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM
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Structural Molecular Biology of Human TFIID Complexes / Biologie moléculaire et structurale de complexes TFIID de l'hommeNie, Yan 14 December 2012 (has links)
Les complexes multi-protéiques jouent un rôle crucial dans les cellules vivantes en catalysant et servant d'intermédiaires entre pratiquement toutes les activités cellulaires essentielles. Cependant, un grand nombre de ces machines se trouvent en très faibles quantités dans les cellules en particulier en ce qui concernent les complexes eucaryotes. Ceci est réfractaire à leur extraction à grande échelle et empêche sévèrement l'élucidation de leur structure et fonction. Dans le but de rendre les complexes multi protéiques accessibles par la voie de production recombinante, le groupe Berger a mis au point un ensemble de systèmes d'expression sur mesure pour la surproduction de complexes multi protéiques dans différents organismes hôtes incluant E. coli, les cellules d'insectes et les cellules de mammifères. Ces systèmes et en particulier le système MultiBac baculovirus/cellules d'insecte ont d'ors et déjà grandement contribués à l'étude de l'assemblage structural et fonctionnel à l'échelle moléculaire et atomique de nombreux complexes multi protéiques importants. Cela inclut en particulier le facteur général humain de transcription TFIID, un complexe de ~1.5 MDa qui constitue le sujet de recherche du laboratoire Berger. Mes contributions dans le développement de la technologie pour la production et dans l'élucidation des complexes TFIID humains sont discutées en détails dans cette thèse. / Multiprotein complexes play a crucial role in living cells by catalyzing and mediating virtually all essential cellular activities. However, many of these essential machines exist in very low endogenous amount in cells, in particular for eukaryotic complexes. This is refractory to large-scale extraction from native source material, severely impeding the elucidation of their structure and function. In order to make multiprotein complexes accessible by means of recombinant production, the Berger laboratory has developed an array of advanced expression systems tailor-made for overproducing multiprotein complexes in various host organisms including E. coli, insect cells and mammalian cells. Those systems, in particular the MultiBac baculovirus/insect cell system have already greatly contributed to studying the structural and functional assemblies of numerous important multiprotein complexes in molecular and atomic detail. Notably, this includes also the human general transcription factor TFIID, a ~1.5 MDa complex, which is the research focus of the Berger laboratory. My contributions to the expression technology development and to the structural elucidation of human TFIID complexes are discussed in details in this thesis.
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The engineering and optimization of expression of rotavirus-like particles in insect cells using a South African G9P[6] rotavirus strain / by Maria J. van der Westhuizen.Van der Westhuizen, Maria Jacoba January 2012 (has links)
Rotavirus infection causes gastroenteritis, specifically severe gastroenteritis, affecting children younger than five globally, regardless of hygiene and water quality. Current licensed, live, attenuated vaccines do not contain the G9 genotype, which is a prevalent rotavirus strain circulating in sub-Saharan Africa, a region that carries a high rotavirus disease burden. Rotavirus-like particles (RV-VLPs) is an attractive non-live vaccine candidate, which has shown promising results in animal studies. Previously, dsRNA was extracted from a stool sample containing a South African human G9P[6] neonatal strain, and amplified cDNA using a sequence-independent procedure. The consensus sequence was obtained for the genome segments using 454® pyrosequencing. The insect-cell-codon-optimized genome segments 2 (VP2), 4 (VP4), 6 (VP6) and 9 (VP7) were cloned into a modified pFASTBACquad vector (pFBq). Several combinations of the genome segments were cloned to produce double-layered particles (DLP; pFBqVP2VP6) or triple-layered particles (TLP; pFBqVP2VP6VP7). In the current study, a ΔTLP (pFBqdVP2-VP8*VP6VP7) construct was generated. The first 92 amino acids of VP2 are not necessary for the conformation of recombinant RV-VLPs. The ORF of VP8*, which contains immune important epitopes, was fused to the 5’ end of the dVP2 coding region resulting in a dVP2-VP8* fused protein which was expressed in the presence of VP6 and VP7 to produce ΔTLPs. The Bac-to-Bac® Baculovirus Expression System and Spodoptera frugiperda (Sf) 9 insect cells were used for expression. All the proteins were successfully expressed. VP2, VP6, VP4 and the dVP2-VP8* fused protein were visible on Coomassie stained SDS-PAGE. Expression of VP7 could only be confirmed with western blot analysis. Particle formation, as assessed by transmission electron microscopy (TEM), was observed for DLPs. No TLPs of dVP2-8*/6/7 or VP2/6/7 were visualized due to the lower expression level of VP7 and the lack of calcium supplements during the assembly process. In conclusion, it was possible to produce RV-DLPs derived from the consensus sequence determined for a G9P[6] rotavirus directly from stool without prior propagation in cell culture or virus isolation. This strain contains both the G9 and P[6] genotypes that are currently prevalent in sub-Saharan Africa. / Thesis (MSc (Biochemistry))--North-West University, Potchefstroom Campus, 2013.
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The engineering and optimization of expression of rotavirus-like particles in insect cells using a South African G9P[6] rotavirus strain / by Maria J. van der Westhuizen.Van der Westhuizen, Maria Jacoba January 2012 (has links)
Rotavirus infection causes gastroenteritis, specifically severe gastroenteritis, affecting children younger than five globally, regardless of hygiene and water quality. Current licensed, live, attenuated vaccines do not contain the G9 genotype, which is a prevalent rotavirus strain circulating in sub-Saharan Africa, a region that carries a high rotavirus disease burden. Rotavirus-like particles (RV-VLPs) is an attractive non-live vaccine candidate, which has shown promising results in animal studies. Previously, dsRNA was extracted from a stool sample containing a South African human G9P[6] neonatal strain, and amplified cDNA using a sequence-independent procedure. The consensus sequence was obtained for the genome segments using 454® pyrosequencing. The insect-cell-codon-optimized genome segments 2 (VP2), 4 (VP4), 6 (VP6) and 9 (VP7) were cloned into a modified pFASTBACquad vector (pFBq). Several combinations of the genome segments were cloned to produce double-layered particles (DLP; pFBqVP2VP6) or triple-layered particles (TLP; pFBqVP2VP6VP7). In the current study, a ΔTLP (pFBqdVP2-VP8*VP6VP7) construct was generated. The first 92 amino acids of VP2 are not necessary for the conformation of recombinant RV-VLPs. The ORF of VP8*, which contains immune important epitopes, was fused to the 5’ end of the dVP2 coding region resulting in a dVP2-VP8* fused protein which was expressed in the presence of VP6 and VP7 to produce ΔTLPs. The Bac-to-Bac® Baculovirus Expression System and Spodoptera frugiperda (Sf) 9 insect cells were used for expression. All the proteins were successfully expressed. VP2, VP6, VP4 and the dVP2-VP8* fused protein were visible on Coomassie stained SDS-PAGE. Expression of VP7 could only be confirmed with western blot analysis. Particle formation, as assessed by transmission electron microscopy (TEM), was observed for DLPs. No TLPs of dVP2-8*/6/7 or VP2/6/7 were visualized due to the lower expression level of VP7 and the lack of calcium supplements during the assembly process. In conclusion, it was possible to produce RV-DLPs derived from the consensus sequence determined for a G9P[6] rotavirus directly from stool without prior propagation in cell culture or virus isolation. This strain contains both the G9 and P[6] genotypes that are currently prevalent in sub-Saharan Africa. / Thesis (MSc (Biochemistry))--North-West University, Potchefstroom Campus, 2013.
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USING RECOMBINANT HUMAN CARBAMOYL PHOSPHATE SYNTHETASE 1 (CPS1) FOR STUDYING THIS ENZYME'S FUNCTION, REGULATION, PATHOLOGY AND STRUCTUREDíez Fernández, Carmen 09 July 2015 (has links)
Tesis por compendio / [EN] Carbamoyl phosphate synthetase 1 (CPS1), a 1462-residue mitochondrial enzyme, catalyzes the entry of ammonia into the urea cycle, which converts ammonia, the neurotoxic waste product of protein catabolism, into barely toxic urea. The urea cycle inborn error and rare disease CPS1 deficiency (CPS1D) is inherited with mendelian autosomal recessive inheritance, being due to CPS1 gene mutations (>200 mutations reported), and causing life-threatening hyperammonemia.
We have produced recombinantly human CPS1 (hCPS1) in a baculovirus/insect cell expression system, isolating the enzyme in active and highly purified form, in massive amounts. This has allowed enzyme crystallization for structural studies by X-ray diffraction (an off-shoot of the present studies). This hCPS1 production system allows site-directed mutagenesis and enzyme characterization as catalyst (activity, kinetics) and as protein (stability, aggregation state, domain composition). We have revealed previously unexplored traits of hCPS1 such as its domain composition, the ability of glycerol to replace the natural and essential CPS1 activator N-acetyl-L-glutamate (NAG), and the hCPS1 protection (chemical chaperoning) by NAG and by its pharmacological analog N-carbamyl-L-glutamate (NCG).
We have exploited this system to explore the effects on the activity, kinetic parameters and stability/folding of the enzyme, and to test the disease-causing nature, of mutations identified in patients with CPS1 deficiency (CPS1D). These results, supplemented with those obtained with other non-clinical mutations, have provided novel information on the functions of three non-catalytic domains of CPS1.
We have introduced three CPS1D-associated mutations and one trivial polymorphism in the glutaminase-like domain of CPS1, supporting a stabilizing and an activity-enhancing function of this non-catalytic domain. Two mutations introduced into the bicarbonate phosphorylation domain have shed light on bicarbonate binding and have directly confirmed the importance of this domain for NAG binding to the distant (in the sequence) C-terminal CPS1 domain. The introduction of 18 CPS1D-associated missense mutations mapping in a clinically highly eloquent central non-catalytic domain have proven the disease-causing nature of most of these mutations while showing that in most of the cases they trigger enzyme misfolding and/or destabilization. These results, by proving an important role of this domain in the structural integration of the multidomain CPS1 protein, have led us to call this domain the Integrating Domain.
Finally, we have examined the effects of eight CPS1D-associated mutations, of one trivial polymorphism and of five non-clinical mutations, all of them mapping in the C-terminal domain of the enzyme where NAG binds, whereas we have re-analyzed prior results with another four clinical and five non-clinical mutations affecting this domain. We have largely confirmed the pathogenic nature of the clinical mutations, predominantly because of decreased activity, in many cases due to hampered NAG binding. A few mutations had substantial negative effects on CPS1 stability/folding. Our analysis reveals that NAG activation begins with a movement of the final part of the ß4-¿4 loop of the NAG site. Transmission of the activating signal to the phosphorylation domains involves helix ¿4 from this domain and is possibly transmitted by the mutually homologous loops 1313-1332 and 778-787 (figures are residue numbers) belonging, respectively, to the carbamate and bicarbonate phosphorylation domains. These two homologous loops are called from here on Signal Transmission Loops. / [ES] La carbamil fosfato sintetasa 1 (CPS1), una enzima mitocondrial, cataliza la entrada del amonio en el ciclo de la urea, que convierte esta neurotoxina derivada del catabolismo de las proteínas en urea, mucho menos tóxica. El déficit de CPS1 (CPS1D) es un error innato del ciclo de la urea, una enfermedad rara autosómica recesiva, que se debe a mutaciones en el gen CPS1 (>200 mutaciones descritas) y que cursa con hiperamonemia.
Hemos producido CPS1 humana recombinante (hCPS1) en un sistema de expresión de células de insecto y baculovirus, y la hemos aislado en forma activa, muy pura y en cantidad elevada. Este sistema de producción de hCPS1 permite la realización de mutagénesis dirigida y la caracterización de la enzima como catalizador (actividad, cinética) y como proteína (estabilidad, estado de agregación y composición de dominios). Hemos revelado características de la hCPS1 antes no exploradas como es la composición de dominios, la capacidad que tiene el glicerol para reemplazar al activador natural y esencial de la CPS1, N-acetil-L-glutamato (NAG), y la protección de la hCPS1 por NAG y por su análogo farmacológico N-carbamil-L-glutamato (NCG) (chaperonas químicas).
Hemos utilizado este sistema para explorar los efectos en actividad, parámetros cinéticos y estabilidad/plegamiento de la enzima, y para comprobar la naturaleza patogénica de mutaciones identificadas en pacientes con CPS1D. Estos resultados, junto con los obtenidos con otras mutaciones no clínicas, han aportado información novedosa sobre tres de los dominios no catalíticos de CPS1.
Las observaciones realizadas tras introducir en el dominio de tipo glutaminasa de la enzima tres mutaciones asociadas a CPS1D y un polimorfismo trivial, apoyan la contribución de este dominio no catalítico a la estabilidad y a aumentar la actividad de la enzima. Dos mutaciones introducidas en el dominio de fosforilación de bicarbonato han arrojado luz sobre el modo de unión del bicarbonato (un sustrato). Los resultados de estas mutaciones también han confirmado la contribución de este dominio para la unión de NAG, cuyo sitio de unión se encuentra en el dominio C-terminal de CPS1, bastante alejado (en la secuencia) del dominio de fosforilación de bicarbonato. Además, hemos introducido 18 mutaciones de cambio de sentido asociadas a CPS1D, las cuales están localizadas en un dominio no catalítico, central y de elevada elocuencia clínica. Estos resultados han demostrado la naturaleza patogénica de estas mutaciones, ya que en la mayoría de los casos estas mutaciones producen un mal plegamiento o/y desestabilización de la enzima. Debido a que estos resultados han puesto de manifiesto el importante papel de este dominio en la integración estructural de la proteína multidominio CPS1, lo hemos llamado Dominio Integrador.
Finalmente, hemos examinado los efectos de 8 mutaciones asociadas a CPS1D, de un polimorfismo trivial y de 5 mutaciones no clínicas, todas localizadas en el dominio C-terminal de la enzima, donde se une NAG. Además, hemos reanalizado resultados anteriores con otras 4 mutaciones clínicas y 5 no clínicas afectando a este dominio. Hemos confirmado el carácter patogénico de las mutaciones clínicas, las cuales predominantemente causan una disminución en la actividad enzimática, en muchos casos debida a que la unión de NAG se encuentra obstaculizada. Unas pocas mutaciones mostraron efectos negativos en la estabilidad/plegamiento de CPS1. Nuestros análisis revelan que la activación por el NAG empieza con un movimiento de la parte final del bucle ß4-¿4 del sitio de NAG. La transmisión de la señal activadora a los dominios de fosforilación implica a la hélice ¿4 de este dominio y posiblemente se transmite a través de los bucles homólogos 1313-1332 y 778-787 (numeración de residuos) pertenecientes, respectivamente, a los dominios de fosforilación de carbamato y bicarbonato. Por ello, hemos llamado a ambos bucles Bucles de / [CA] La carbamil fosfat sintetasa 1 (CPS1), un enzim mitocondrial, catalitza l'entrada d'amoni en el cicle de la urea, que convertix l'amoni, producte neurotòxic del catabolisme de les proteïnes, en urea, una molècula molt poc tòxica. El dèficit de CPS1 (CPS1D) és un error innat del cicle de la urea, una malaltia rara autosòmica recessiva, que es deu a mutacions en el gen CPS1 (>200 mutacions descrites) i que cursa amb hiperamonièmia.
Hem produït CPS1 humana recombinant (hCPS1) en un sistema d'expressió de cèl·lules d'insecte i baculovirus, i l'hem aïllada en forma activa, molt pura i en gran quantitat. Això ha permés la cristal·lització de l'enzim per a estudis estructurals amb difracció de raios-X (treball no inclòs en esta tesi Aquest sistema de producció de hCPS1 permet la realització de mutagènesi dirigida i la caracterització de l'enzim com a catalitzador (activitat, cinètica) i com a proteïna (estabilitat, estat d'agregació i composició de dominis). Hem revelat característiques de la hCPS1 no explorades abans com és la composició de dominis, la capacitat que té el glicerol per a reemplaçar l'activador natural i essencial de CPS1, N-acetil-L-glutamat (NAG), i la protecció de la hCPS1 per NAG i pel seu anàleg farmacològic N-carbamil-L-glutamat (NCG) (xaperones químiques) .
Hem utilitzat aquest sistema per a explorar els efectes en l'activitat, els paràmetres cinètics i l'estabilitat/plegament de l'enzim, i per a comprovar la naturalesa patogènica de mutacions identificades en pacients amb CPS1D. Aquestos resultats, junt amb els obtinguts amb altres mutacions no clíniques, han aportat informació nova sobre tres dels dominis no catalítics de la CPS1.
Les observacions, després d'introduir tres mutacions associades a CPS1D i un polimorfisme trivial en el domini tipus glutaminasa de CPS1, recolzen la contribució d'aquest domini no catalític a l'estabilitat i a l'optimització de l'activitat enzimàtica. Dues mutacions introduïdes en el domini de fosforilació de bicarbonat han esclarit el mode d'unió de bicarbonat. Els resultats d'aquestes mutacions també han confirmat la contribució d'aquest domini per a la unió de NAG, el lloc d'unió de la qual es troba en el domini C-terminal de CPS1, prou allunyat (en la seqüència) del domini de fosforilació de bicarbonat. A més, hem introduït 18 mutacions de canvi de sentit associades a CPS1D, les quals estan localitzades en un domini no catalític, central i d'elevada eloqüència clínica. Aquestos resultats han demostrat la naturalesa patogènica d'aquestes mutacions, ja que, en la majoria dels casos produïxen un mal plegament o/i desestabilització de l'enzim. Pel fet que aquestos resultats han posat de manifest l'important paper d'aquest domini en la integració estructural de la proteïna multidomini CPS1, l'hem anomenat Domini Integrador.
Finalment, hem examinat els efectes de huit mutacions associades a CPS1D, un polimorfisme trivial i cinc mutacions no clíniques, totes elles localitzades en el domini C-terminal de l'enzim, on s'unix NAG. A més, hem reanalitzat resultats anteriors amb altres quatre mutacions clíniques i cinc no clíniques que afecten aquest domini. Hem confirmat el caràcter patogènic de les mutacions clíniques, les quals predominantment causen una disminució en l'activitat enzimàtica, en molts casos pel fet que la unió de NAG es troba obstaculitzada. Unes poques mutacions van mostrar efectes negatius substancials en l'estabilitat/plegament de CPS1. Les nostres anàlisis revelen que l'activació de NAG comença amb un moviment de la part final del bucle ß4-¿4 del lloc de NAG. La transmissió del senyal activadora als dominis de fosforilació involucra l'hèlix ¿4 d'aquest domini i es transmet, possiblement, a través dels bucles homòlegs 1313-1332 i 778-787 (numeració dels residus), pertanyents, respectivament, als dominis de fosforilació de carbamato i bicarbonat. Per això, hem anomenat a ambd / Díez Fernández, C. (2015). USING RECOMBINANT HUMAN CARBAMOYL PHOSPHATE SYNTHETASE 1 (CPS1) FOR STUDYING THIS ENZYME'S FUNCTION, REGULATION, PATHOLOGY AND STRUCTURE [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/52855 / Compendio
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