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The secretory pathway of baculovirus infected insect cells : tissue plasminogen activator as a model proteinCox, Helen M. January 1997 (has links)
No description available.
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Estudos das interações da septina 4 humana / Study of Human Septin 4 interactionsSilva, Nayara Cavalcante 09 September 2009 (has links)
Septinas são proteínas ligantes a GTP encontradas desde fungos até metazoários. A primeira função identificada para septinas foi o seu papel central na organização e dinâmica do septo de divisão de leveduras. Uma das características marcantes é que septinas se organizam em heterofilamentos de 7 a 9 nm de espessura que foram purificados de diversos organismos tais como Saccharomyces cerevisiae, Drosophila e cérebro de camundongos. Hoje se sabe que septinas não estão envolvidas apenas nos processos de divisão celular, mas em uma variedade de processos como tráfico de vesículas, exocitose, interação com proteínas do citoesqueleto e com a membrana plasmática, o que resulta em alterações da morfologia celular. Neste trabalho foram desenvolvidos estudos da septina 4 humana (SEPT4) nos quais foi realizado a expressão e purificação da SEPT4 pelo uso do sistema de expressão heteróloga em E. coli e em células de insetos (Sf-9) via baculovírus. A tentativa de expressão usando o vetor pETTEV em E.coli não obteve sucesso, pois a proteína não foi expressa na forma solúvel. A construção do baculovírus recombinante AcSept4 e expressão da SEPT4 nas células de insetos foi realizada com êxito, mas o processo de purificação não foi satisfatório. Com o intuito de obter informações sobre possíveis proteínas que interagem com a SEPT4 e conseqüentemente sobre as funções desempenhadas por ela na célula, a SEPT4 foi utilizada como isca para ensaios de interação proteína-proteína pela técnica de duplo híbrido. Para isso, o gene da SEPT4 foi clonado fusionado ao domínio de ligação ao DNA Lex-A. A realização do ensaio de duplo híbrido com a proteína completa não foi possível, pois a mesma provocou a auto ativação do sistema, por isso uma nova construção foi realizada com a região GTPase e C-terminal SEPT4GC (124-478) como isca. Dentre as interações identificadas, foram encontradas apenas septinas do grupo II (SEPT6, SEPT8, SEPT10 e SEPT11) e quatro novas interações, que ainda precisam ser confirmadas. Por outro lado, uma interação já descrita na literatura envolve a proteína α-sinucleína, que é uma proteína abundantemente expressa no cérebro e associada à doença de Parkinson. O foco do estudo dessa interação foi realizar ensaios com os diferentes domínios da SEPT4 para comprovar uma interação direta e com isso tentar mapear o sítio de interação com a α-sinucleína. Os resultados obtidos pela ressonância plasmônica de superfície (SPR) indicam que o domínio C-terminal participa da interação com baixa afinidade (K,D=390 µM) e sugerem que o domínio GTPase também pode estar envolvido. Já os dados obtidos com os experimentos de RMN e anisotropia de fluorescência mostram indícios que a interação é dependente da conformação da α-sinucleína por que a interação aconteceria com maior afinidade quando a α-sinucleína está na presença de SDS. / Septins are a family of GTP binding proteins found in a great diversity of organisms. These proteins have been identified as having a central role in septum organization during yeast division. Septins are organized into heterofilaments which are 7 to 9 nm wide and these have been purified from yeast, Drosophila and mice brain. Septins are not only required for cell division, but seem to play a role also in vesicle trafficking and in the formation of diffusion barriers within cells, since they interact with cytoskeleton proteins and the plasma membrane causing changes in cell morphology. In the present work, the aim was investigate human Septin 4 (SEPT4), a septin highly expressed in the brain. One objective of this work was to find a suitable expression system and purification method for SEPT4. The protein was expressed in both E.coli and insect cells (Sf-9). Expression in E. coli with the vector pETTEV was unsuccessful because the protein was insoluble. Expression in insect cells using the recombinant baculovirus AcSept4, was obtained successfully, but the purification was difficult. Important information concerning SEPT4 function might be acquired, if interactions partners involved in cellular process were identified. With this goal in mind, a yeast two hybrid assays were performed. The sept4 gene was fused to the Lex-A DNA binding domain and used as bait in the yeast two hybrid essays. However, full length SEPT4 showed autonomous activation of reporter genes. A second construct was prepared including only GTPase domain and the carboxy terminus domain, (residues 124 to 478) and the screen of interactions were carried out only with SEPT4GC. All of the group II septins (SEPT6, SEPT8, SEPT10 and SEPT11) were identified together with four new interactions. The latter still need be confirmed. In addition, another interaction already described in the literature is between SEPT4 and α-synuclein, which is a protein highly expressed in brain and related to Parkinson\'s disease. Different spectroscopic methods and SPR were used to identify which domain of SEPT4 interacts directly with α-synuclein and in which region. The surface plasmon resonance (SPR) results indicate that the carboxy terminus participates in the interaction with low affinity (KD = 390 µM) and suggests that the GTPase domain may also be involved. The results obtained by fluorescence anisotropy and NMR studies provide evidence that the interaction is dependent on the α-synuclein conformation, because the affinity of SEPT4 and α-synuclein seemed to be higher in the presence of SDS.
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Estudos das interações da septina 4 humana / Study of Human Septin 4 interactionsNayara Cavalcante Silva 09 September 2009 (has links)
Septinas são proteínas ligantes a GTP encontradas desde fungos até metazoários. A primeira função identificada para septinas foi o seu papel central na organização e dinâmica do septo de divisão de leveduras. Uma das características marcantes é que septinas se organizam em heterofilamentos de 7 a 9 nm de espessura que foram purificados de diversos organismos tais como Saccharomyces cerevisiae, Drosophila e cérebro de camundongos. Hoje se sabe que septinas não estão envolvidas apenas nos processos de divisão celular, mas em uma variedade de processos como tráfico de vesículas, exocitose, interação com proteínas do citoesqueleto e com a membrana plasmática, o que resulta em alterações da morfologia celular. Neste trabalho foram desenvolvidos estudos da septina 4 humana (SEPT4) nos quais foi realizado a expressão e purificação da SEPT4 pelo uso do sistema de expressão heteróloga em E. coli e em células de insetos (Sf-9) via baculovírus. A tentativa de expressão usando o vetor pETTEV em E.coli não obteve sucesso, pois a proteína não foi expressa na forma solúvel. A construção do baculovírus recombinante AcSept4 e expressão da SEPT4 nas células de insetos foi realizada com êxito, mas o processo de purificação não foi satisfatório. Com o intuito de obter informações sobre possíveis proteínas que interagem com a SEPT4 e conseqüentemente sobre as funções desempenhadas por ela na célula, a SEPT4 foi utilizada como isca para ensaios de interação proteína-proteína pela técnica de duplo híbrido. Para isso, o gene da SEPT4 foi clonado fusionado ao domínio de ligação ao DNA Lex-A. A realização do ensaio de duplo híbrido com a proteína completa não foi possível, pois a mesma provocou a auto ativação do sistema, por isso uma nova construção foi realizada com a região GTPase e C-terminal SEPT4GC (124-478) como isca. Dentre as interações identificadas, foram encontradas apenas septinas do grupo II (SEPT6, SEPT8, SEPT10 e SEPT11) e quatro novas interações, que ainda precisam ser confirmadas. Por outro lado, uma interação já descrita na literatura envolve a proteína α-sinucleína, que é uma proteína abundantemente expressa no cérebro e associada à doença de Parkinson. O foco do estudo dessa interação foi realizar ensaios com os diferentes domínios da SEPT4 para comprovar uma interação direta e com isso tentar mapear o sítio de interação com a α-sinucleína. Os resultados obtidos pela ressonância plasmônica de superfície (SPR) indicam que o domínio C-terminal participa da interação com baixa afinidade (K,D=390 µM) e sugerem que o domínio GTPase também pode estar envolvido. Já os dados obtidos com os experimentos de RMN e anisotropia de fluorescência mostram indícios que a interação é dependente da conformação da α-sinucleína por que a interação aconteceria com maior afinidade quando a α-sinucleína está na presença de SDS. / Septins are a family of GTP binding proteins found in a great diversity of organisms. These proteins have been identified as having a central role in septum organization during yeast division. Septins are organized into heterofilaments which are 7 to 9 nm wide and these have been purified from yeast, Drosophila and mice brain. Septins are not only required for cell division, but seem to play a role also in vesicle trafficking and in the formation of diffusion barriers within cells, since they interact with cytoskeleton proteins and the plasma membrane causing changes in cell morphology. In the present work, the aim was investigate human Septin 4 (SEPT4), a septin highly expressed in the brain. One objective of this work was to find a suitable expression system and purification method for SEPT4. The protein was expressed in both E.coli and insect cells (Sf-9). Expression in E. coli with the vector pETTEV was unsuccessful because the protein was insoluble. Expression in insect cells using the recombinant baculovirus AcSept4, was obtained successfully, but the purification was difficult. Important information concerning SEPT4 function might be acquired, if interactions partners involved in cellular process were identified. With this goal in mind, a yeast two hybrid assays were performed. The sept4 gene was fused to the Lex-A DNA binding domain and used as bait in the yeast two hybrid essays. However, full length SEPT4 showed autonomous activation of reporter genes. A second construct was prepared including only GTPase domain and the carboxy terminus domain, (residues 124 to 478) and the screen of interactions were carried out only with SEPT4GC. All of the group II septins (SEPT6, SEPT8, SEPT10 and SEPT11) were identified together with four new interactions. The latter still need be confirmed. In addition, another interaction already described in the literature is between SEPT4 and α-synuclein, which is a protein highly expressed in brain and related to Parkinson\'s disease. Different spectroscopic methods and SPR were used to identify which domain of SEPT4 interacts directly with α-synuclein and in which region. The surface plasmon resonance (SPR) results indicate that the carboxy terminus participates in the interaction with low affinity (KD = 390 µM) and suggests that the GTPase domain may also be involved. The results obtained by fluorescence anisotropy and NMR studies provide evidence that the interaction is dependent on the α-synuclein conformation, because the affinity of SEPT4 and α-synuclein seemed to be higher in the presence of SDS.
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Cloning and expression of human recombinant isoform a of glycine-N-acyltransferaseGrundling, Daniel Andries January 2012 (has links)
Awareness of detoxification, nowadays known as biotransformation, has become an integral part of our daily lives. It is a modern buzz word that is used to promote anything from health food to enhancement of performance in sports. Another lesser known application for detoxification is as a therapy for alleviating symptoms of inborn errors of metabolism.
Detoxification is the process where endogenous and xenobiotic metabolites are transformed to less harmful products, in the liver and kidneys, in two phases. Phase 1 detoxification includes oxidation, hydroxylation, dehydrogenation metabolic reduction and hydrolysis.
Phase 2 detoxification uses conjugation reactions to increase hydrophillicty of metabolites for excretion in bile and urine. Glycine N-acyltransferse (GLYAT; EC 2.3.1.13) is one of the amino acid conjugation enzymes. There are two variants of human GLYAT. I focused on the full-length mRNA human GLYAT isoform a, with a long term view of using it as a viable therapeutic enzyme for enhanced detoxification of harmful metabolites. I investigated if it is possible to clone and express a biologically active GLYAT. To achieve this goal I used three expression systems: traditional bacterial expression using the pET system; second generation cold shock bacterial expression using the pCOLDTF expression vector to improve solubility of the recombinant protein; and baculovirus expression in insect cells since therein some form of post translation glycosylation of the recombinant protein can occur which might improve solubility and ensure biological activity. The recombinant GLYAT expressed well in all three expression systems but was aggregated and no enzyme activity could be detected.
A denature and renature system was also used to collect aggregated recombinant GLYAT and used to try to refold the recombinant protein in appropriate refolding buffers to improve solubility and obtain biological activity. The solubility of the recombinant GLYAT was improved but it remained biologically inactive. / Thesis (MSc (Biochemistry))--North-West University, Potchefstroom Campus, 2013.
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Cloning and expression of human recombinant isoform a of glycine-N-acyltransferaseGrundling, Daniel Andries January 2012 (has links)
Awareness of detoxification, nowadays known as biotransformation, has become an integral part of our daily lives. It is a modern buzz word that is used to promote anything from health food to enhancement of performance in sports. Another lesser known application for detoxification is as a therapy for alleviating symptoms of inborn errors of metabolism.
Detoxification is the process where endogenous and xenobiotic metabolites are transformed to less harmful products, in the liver and kidneys, in two phases. Phase 1 detoxification includes oxidation, hydroxylation, dehydrogenation metabolic reduction and hydrolysis.
Phase 2 detoxification uses conjugation reactions to increase hydrophillicty of metabolites for excretion in bile and urine. Glycine N-acyltransferse (GLYAT; EC 2.3.1.13) is one of the amino acid conjugation enzymes. There are two variants of human GLYAT. I focused on the full-length mRNA human GLYAT isoform a, with a long term view of using it as a viable therapeutic enzyme for enhanced detoxification of harmful metabolites. I investigated if it is possible to clone and express a biologically active GLYAT. To achieve this goal I used three expression systems: traditional bacterial expression using the pET system; second generation cold shock bacterial expression using the pCOLDTF expression vector to improve solubility of the recombinant protein; and baculovirus expression in insect cells since therein some form of post translation glycosylation of the recombinant protein can occur which might improve solubility and ensure biological activity. The recombinant GLYAT expressed well in all three expression systems but was aggregated and no enzyme activity could be detected.
A denature and renature system was also used to collect aggregated recombinant GLYAT and used to try to refold the recombinant protein in appropriate refolding buffers to improve solubility and obtain biological activity. The solubility of the recombinant GLYAT was improved but it remained biologically inactive. / Thesis (MSc (Biochemistry))--North-West University, Potchefstroom Campus, 2013.
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