Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.

Detalhes bibliográficos
Ano de defesa: 2011
Autor(a) principal: Corrêa, Juliana Moço lattes
Orientador(a): Fortes, Rita das Graças Felix lattes
Banca de defesa: Não Informado pela instituição
Tipo de documento: Dissertação
Tipo de acesso: Acesso aberto
Idioma: por
Instituição de defesa: Universidade Estadual do Oeste do Parana
Programa de Pós-Graduação: Programa de Pós-Graduação "Stricto Sensu" em Engenharia Agrícola
Departamento: Engenharia
País: BR
Palavras-chave em Português:
Caracterização enzimática
Agroindústria Resíduos
Palavras-chave em Inglês:
cloning
purification
lignocellulose
xylan
Área do conhecimento CNPq:
CNPQ::CIENCIAS AGRARIAS::ENGENHARIA AGRICOLA
Link de acesso: http://tede.unioeste.br:8080/tede/handle/tede/2821
Resumo: Lignocellulosic materials are abundant in agro-industrial residues and by-products of agroindustry and can be used for fuels and other chemicals of commercial interest. An alternative to physical and chemical methods for bioconversion of lignocellulosic material is the use of enzymes produced by micro-organisms. The aquatic bacterium Gram negative Caulobacter crescentus presents biotechnological potential for the use of these residues because it contains in its genome several gene coding for enzymes involved in the metabolism of lignocellulosic materials, including 5 genes to β-Xylosidases. In this study, the gene xynB2 (1.5 kb) coding the C. crescentus β-Xylosidase II was cloned into the vector pJet1.2 (Fermentas) and subcloned in frame in the sites EcoRI/XbaI of expression vector pPROEXHta (Invitrogen). A histidine tail fusion protein was obtained after induction and expression of gene xynB2 in E. coli (DH10B) with IPTG (1 mM). The recombinant β-Xylosidase II (β-Xylrec- II) was purified by chromatography using nickel-Sepharose resin and a pure enzyme was characterized by biochemical kinetics parameters. A single band of 65 kDa was obtained by SDS-PAGE 9% for C. crescentus β-Xyl-rec-II purified, which showed a specific activity of 215 U / mg, pH optimum equal to 6, the optimum temperature of 55 °C and half life of 4 h at 50 °C. After 24 h incubation at pH 6 the enzyme retained 95% of activity. Most of the ions inhibited the activity of β-Xylosidase II, but a 32% increase was observed in the presence of KCl (2mM). The kinetic parameters KM and VMáx were equal to 8.4 mM and 370 moles / min, respectively. The ability of C. crescentus β-Xyl-rec-II hydrolyse xylan and sugarcane bagasse residue was assessed after incubation with these Xylanase purified from Aspergillus alliaceus. The relative percentage of hydrolysis products of xylan and sugar cane bagasse, increased 2.5 and 6.5 times, respectively, after incubation for 18 hours with C. crescentus β- Xyl-rec-II pure, thus highlighting the possibility of using this enzyme in biotechnological processes. In addition, β-Xil-rec-II was also used for the production of a polyclonal antibody in rabbit that showed by "Western blot" assay a highly specific recognition of the purified protein. In order to investigate the role of xynB2 gene to C. crescentus, two mutants were obtained. The first one was constructed by insertion of a spectinomycin resistance cassette into the xynB2 gene by double homologous recombination, generating a null mutant strain named RSJU-2. The second one was obtained by cloning of xynB2 gene under the control of the inducible xylose promoter generating a strain denominated pMOA. β-Xylosidase activity was measured in the RSJU-2, pMOA and parental strain (NA1000) cells of C. crescentus which were grown in the absence and in the presence of different agro-industrial residues and others carbon sources. The xynB2 gene depletion made cells more able to produce high activities of other β-Xylosidases in the presence of different residues, for instance, β- Xylosidase activity produced by RSJU-2 cells was almost 15 times higher than the activity showed by NA1000 in the presence of sugarcane bagasse. These results indicate that the absence o xynB2 gene up-regulates the expression of other β-Xylosidases in C. crescentus. On the other hand, a decreased activity of β-Xylosidase was observed in the strain pMOA, suggesting that the overexpression of β-Xylosidase II down-regulates C. crescentus β - Xylosidases activities. To verify that the variation in activity levels of β -Xylosidase occur as a consequence of variations in the levels of transcription of β-Xylosidases genes in different strains, we constructed a lacZ- fusion transcription by cloning the E. coli lacZ gene under the control of xynB2 gene promoter. Thus, the β-Galactosidase activity was measured as a function of xynB2 promoter activity. Tests of promoter activity by measuring the activity of β- Galactosidase in different strains showed that the xynB2 gene is transcription-dependent.
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spelling Fortes, Rita das Graças FelixCPF:33171335620http://lattes.cnpq.br/8283870910527945CPF:04086432935http://lattes.cnpq.br/8316590839872267Corrêa, Juliana Moço2017-07-10T19:24:54Z2012-01-302011-01-20CORRÊA, Juliana Moço. Analysis of β-Xylosidase II expression of the aquatic bacterium Caulobacter crescentus and its role in the utilization of agro-industrial residues. 2011. 71 f. Dissertação (Mestrado em Engenharia) - Universidade Estadual do Oeste do Parana, Cascavel, 2011.http://tede.unioeste.br:8080/tede/handle/tede/2821Lignocellulosic materials are abundant in agro-industrial residues and by-products of agroindustry and can be used for fuels and other chemicals of commercial interest. An alternative to physical and chemical methods for bioconversion of lignocellulosic material is the use of enzymes produced by micro-organisms. The aquatic bacterium Gram negative Caulobacter crescentus presents biotechnological potential for the use of these residues because it contains in its genome several gene coding for enzymes involved in the metabolism of lignocellulosic materials, including 5 genes to β-Xylosidases. In this study, the gene xynB2 (1.5 kb) coding the C. crescentus β-Xylosidase II was cloned into the vector pJet1.2 (Fermentas) and subcloned in frame in the sites EcoRI/XbaI of expression vector pPROEXHta (Invitrogen). A histidine tail fusion protein was obtained after induction and expression of gene xynB2 in E. coli (DH10B) with IPTG (1 mM). The recombinant β-Xylosidase II (β-Xylrec- II) was purified by chromatography using nickel-Sepharose resin and a pure enzyme was characterized by biochemical kinetics parameters. A single band of 65 kDa was obtained by SDS-PAGE 9% for C. crescentus β-Xyl-rec-II purified, which showed a specific activity of 215 U / mg, pH optimum equal to 6, the optimum temperature of 55 °C and half life of 4 h at 50 °C. After 24 h incubation at pH 6 the enzyme retained 95% of activity. Most of the ions inhibited the activity of β-Xylosidase II, but a 32% increase was observed in the presence of KCl (2mM). The kinetic parameters KM and VMáx were equal to 8.4 mM and 370 moles / min, respectively. The ability of C. crescentus β-Xyl-rec-II hydrolyse xylan and sugarcane bagasse residue was assessed after incubation with these Xylanase purified from Aspergillus alliaceus. The relative percentage of hydrolysis products of xylan and sugar cane bagasse, increased 2.5 and 6.5 times, respectively, after incubation for 18 hours with C. crescentus β- Xyl-rec-II pure, thus highlighting the possibility of using this enzyme in biotechnological processes. In addition, β-Xil-rec-II was also used for the production of a polyclonal antibody in rabbit that showed by "Western blot" assay a highly specific recognition of the purified protein. In order to investigate the role of xynB2 gene to C. crescentus, two mutants were obtained. The first one was constructed by insertion of a spectinomycin resistance cassette into the xynB2 gene by double homologous recombination, generating a null mutant strain named RSJU-2. The second one was obtained by cloning of xynB2 gene under the control of the inducible xylose promoter generating a strain denominated pMOA. β-Xylosidase activity was measured in the RSJU-2, pMOA and parental strain (NA1000) cells of C. crescentus which were grown in the absence and in the presence of different agro-industrial residues and others carbon sources. The xynB2 gene depletion made cells more able to produce high activities of other β-Xylosidases in the presence of different residues, for instance, β- Xylosidase activity produced by RSJU-2 cells was almost 15 times higher than the activity showed by NA1000 in the presence of sugarcane bagasse. These results indicate that the absence o xynB2 gene up-regulates the expression of other β-Xylosidases in C. crescentus. On the other hand, a decreased activity of β-Xylosidase was observed in the strain pMOA, suggesting that the overexpression of β-Xylosidase II down-regulates C. crescentus β - Xylosidases activities. To verify that the variation in activity levels of β -Xylosidase occur as a consequence of variations in the levels of transcription of β-Xylosidases genes in different strains, we constructed a lacZ- fusion transcription by cloning the E. coli lacZ gene under the control of xynB2 gene promoter. Thus, the β-Galactosidase activity was measured as a function of xynB2 promoter activity. Tests of promoter activity by measuring the activity of β- Galactosidase in different strains showed that the xynB2 gene is transcription-dependent.Materiais lignocelulósicos são abundantes em resíduos agroindustriais e subprodutos da agroindústria e podem ser usados para produção de combustíveis e outros químicos de interesse comercial. Uma alternativa aos métodos físicos e químicos para bioconversão de material lignocelulósico é o uso de enzimas produzidas por micro-organismos. A bactéria aquática Gram negativa Caulobacter crescentus apresenta potencial biotecnológico para o uso destes resíduos por conter em seu genoma vários genes que codificam para enzimas envolvidas com o metabolismo de materiais lignocelulósicos, incluindo 5 genes para β- Xilosidases. No presente trabalho o gene xynB2 (1,5 kb), que codifica para a β-xilosidade II de C. crescentus, foi clonado no vetor pJet1.2 (Fermentas) e subclonado em fase de leitura nos sítios EcoRI/XbaI do vetor de expressão pPROEX-HTa (Invitrogen). Uma proteína de fusão com cauda de histidinas foi obtida após indução da expressão do gene xynB2 em E. coli (DH10B) com IPTG (1mM). A β-xilosidade II recombinante (β-Xil-II-rec) foi purificada por cromatografia usando resina de níquel-sepharose e a enzima pura caracterizada quanto a parâmetros cinéticos e bioquímicos. Uma banda única de 65 KDa foi obtida em gel SDSPAGE 9% para a β-Xil-rec-II purificada de C. crescentus, a qual mostrou uma atividade específica de 215 U/mg, pH ótimo igual a 6, temperatura ótima de 55°C e meia vida de 4 horas a 50°C. Após 24 h de incubação em pH 6 a enzima reteve 95% da atividade inicial. A maioria dos íons inibiu a atividade de β-xilosidade II, mas um aumento de 32% foi observado na presença de KCl (2mM). Os parâmetros cinéticos KM e VMáx foram iguais a 8,4 mM e 370 moles/min, respectivamente. A capacidade da β-Xilosidase II recombinante pura de C. crescentus hidrolisar xilano e o resíduo bagaço de cana foi avaliada após incubação prévia destes com a Xilanase purificada de Aspergillus alliaceus. As porcentagens relativas de produtos de hidrólise do xilano e bagaço de cana-de-açúcar aumentaram 2,5 e 6,5 vezes, respectivamente, após incubação por 18 horas com a β-Xil-II-rec pura de C. crescentus, ressaltando assim, a possibilidade de aplicação desta enzima em processos biotecnológicos. Em adição, a β-Xil-II-rec foi usada para a produção de um anticorpo policlonal em coelho que mostrou por ensaios de Western Blot uma elevada especificidade para reconhecimento da proteína purificada. Paralelamente, com o objetivo de investigar o papel do gene xynB2 para C. crescentus, dois mutantes foram obtidos. O primeiro foi construído pela inserção de um cassete de resistência a espectinomicina dentro do gene xynB2 por dupla recombinação homóloga, gerando uma linhagem mutante nula denominada RSJU-2. Os segundo foi obtido por clonagem do gene xynB2 sob o controle de um promotor indutível por xilose gerando uma linhagem denominada pMOA. A atividade de β-Xilosidase foi mensurada nas células das linhagens RSJU-2, pMOA e parental (NA1000) de C. crescentus, as quais cresceram na ausência e presença de diferentes resíduos agroindustriais. A depleção do gene xynB2 fez as células mais hábeis a produzirem altas atividades de outras β-Xilosidases na presença de diferentes resíduos ou fontes de carbono. Estes resultados indicam que a ausência do gene xynB2 regula positivamente a expressão de outras β-Xilosidases em C. crescentus. Por outro lado, um decréscimo na atividade de β- Xilosidases foi observado na linhagem pMOA, sugerindo que a superexpressão da β- XilosidaseII regula negativamente a atividade de β-Xilosidases. Para verificar se a variação nos níveis de atividade de β-Xilosidase ocorre como um reflexo de variações nos níveis de transcrição de genes de β-Xilosidases nas diferentes cepas, foi construído uma fusão de transcrição a partir da clonagem do promotor do gene xynB2 a frente do gene lacZ de E. coli. Assim, foi quantificada a atividade de β-Galactosidase como uma medida da atividade do promotor do gene xynB2, o que demonstrou que gene xynB2 é dependente de transcrição.Made available in DSpace on 2017-07-10T19:24:54Z (GMT). No. of bitstreams: 1 Juliana_Texto_completo.pdf: 2104939 bytes, checksum: ce60666190df07cee9975989d437d475 (MD5) Previous issue date: 2011-01-20application/pdfporUniversidade Estadual do Oeste do ParanaPrograma de Pós-Graduação "Stricto Sensu" em Engenharia AgrícolaUNIOESTEBREngenhariaCaracterização enzimáticaAgroindústria ResíduoscloningpurificationlignocellulosexylanCNPQ::CIENCIAS AGRARIAS::ENGENHARIA AGRICOLAAnálise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.Analysis of β-Xylosidase II expression of the aquatic bacterium Caulobacter crescentus and its role in the utilization of agro-industrial residuesinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisinfo:eu-repo/semantics/openAccessreponame:Biblioteca Digital de Teses e Dissertações do UNIOESTEinstname:Universidade Estadual do Oeste do Paraná (UNIOESTE)instacron:UNIOESTEORIGINALJuliana_Correa2017.pdfapplication/pdf2104939http://tede.unioeste.br:8080/tede/bitstream/tede/2821/1/Juliana_Correa2017.pdfce60666190df07cee9975989d437d475MD51tede/28212018-03-19 16:11:15.008oai:tede.unioeste.br:tede/2821Biblioteca Digital de Teses e Dissertaçõeshttp://tede.unioeste.br/PUBhttp://tede.unioeste.br/oai/requestbiblioteca.repositorio@unioeste.bropendoar:2018-03-19T19:11:15Biblioteca Digital de Teses e Dissertações do UNIOESTE - Universidade Estadual do Oeste do Paraná (UNIOESTE)false
dc.title.por.fl_str_mv Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
dc.title.alternative.eng.fl_str_mv Analysis of β-Xylosidase II expression of the aquatic bacterium Caulobacter crescentus and its role in the utilization of agro-industrial residues
title Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
spellingShingle Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
Corrêa, Juliana Moço
Caracterização enzimática
Agroindústria Resíduos
cloning
purification
lignocellulose
xylan
CNPQ::CIENCIAS AGRARIAS::ENGENHARIA AGRICOLA
title_short Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
title_full Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
title_fullStr Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
title_full_unstemmed Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
title_sort Análise da expressão da β-Xilosidade II da bactéria aquática Caulobacter crescentus e seu papel no aproveitamento de resíduos agroindustriais.
author Corrêa, Juliana Moço
author_facet Corrêa, Juliana Moço
author_role author
dc.contributor.advisor1.fl_str_mv Fortes, Rita das Graças Felix
dc.contributor.advisor1ID.fl_str_mv CPF:33171335620
dc.contributor.advisor1Lattes.fl_str_mv http://lattes.cnpq.br/8283870910527945
dc.contributor.authorID.fl_str_mv CPF:04086432935
dc.contributor.authorLattes.fl_str_mv http://lattes.cnpq.br/8316590839872267
dc.contributor.author.fl_str_mv Corrêa, Juliana Moço
contributor_str_mv Fortes, Rita das Graças Felix
dc.subject.por.fl_str_mv Caracterização enzimática
Agroindústria Resíduos
topic Caracterização enzimática
Agroindústria Resíduos
cloning
purification
lignocellulose
xylan
CNPQ::CIENCIAS AGRARIAS::ENGENHARIA AGRICOLA
dc.subject.eng.fl_str_mv cloning
purification
lignocellulose
xylan
dc.subject.cnpq.fl_str_mv CNPQ::CIENCIAS AGRARIAS::ENGENHARIA AGRICOLA
description Lignocellulosic materials are abundant in agro-industrial residues and by-products of agroindustry and can be used for fuels and other chemicals of commercial interest. An alternative to physical and chemical methods for bioconversion of lignocellulosic material is the use of enzymes produced by micro-organisms. The aquatic bacterium Gram negative Caulobacter crescentus presents biotechnological potential for the use of these residues because it contains in its genome several gene coding for enzymes involved in the metabolism of lignocellulosic materials, including 5 genes to β-Xylosidases. In this study, the gene xynB2 (1.5 kb) coding the C. crescentus β-Xylosidase II was cloned into the vector pJet1.2 (Fermentas) and subcloned in frame in the sites EcoRI/XbaI of expression vector pPROEXHta (Invitrogen). A histidine tail fusion protein was obtained after induction and expression of gene xynB2 in E. coli (DH10B) with IPTG (1 mM). The recombinant β-Xylosidase II (β-Xylrec- II) was purified by chromatography using nickel-Sepharose resin and a pure enzyme was characterized by biochemical kinetics parameters. A single band of 65 kDa was obtained by SDS-PAGE 9% for C. crescentus β-Xyl-rec-II purified, which showed a specific activity of 215 U / mg, pH optimum equal to 6, the optimum temperature of 55 °C and half life of 4 h at 50 °C. After 24 h incubation at pH 6 the enzyme retained 95% of activity. Most of the ions inhibited the activity of β-Xylosidase II, but a 32% increase was observed in the presence of KCl (2mM). The kinetic parameters KM and VMáx were equal to 8.4 mM and 370 moles / min, respectively. The ability of C. crescentus β-Xyl-rec-II hydrolyse xylan and sugarcane bagasse residue was assessed after incubation with these Xylanase purified from Aspergillus alliaceus. The relative percentage of hydrolysis products of xylan and sugar cane bagasse, increased 2.5 and 6.5 times, respectively, after incubation for 18 hours with C. crescentus β- Xyl-rec-II pure, thus highlighting the possibility of using this enzyme in biotechnological processes. In addition, β-Xil-rec-II was also used for the production of a polyclonal antibody in rabbit that showed by "Western blot" assay a highly specific recognition of the purified protein. In order to investigate the role of xynB2 gene to C. crescentus, two mutants were obtained. The first one was constructed by insertion of a spectinomycin resistance cassette into the xynB2 gene by double homologous recombination, generating a null mutant strain named RSJU-2. The second one was obtained by cloning of xynB2 gene under the control of the inducible xylose promoter generating a strain denominated pMOA. β-Xylosidase activity was measured in the RSJU-2, pMOA and parental strain (NA1000) cells of C. crescentus which were grown in the absence and in the presence of different agro-industrial residues and others carbon sources. The xynB2 gene depletion made cells more able to produce high activities of other β-Xylosidases in the presence of different residues, for instance, β- Xylosidase activity produced by RSJU-2 cells was almost 15 times higher than the activity showed by NA1000 in the presence of sugarcane bagasse. These results indicate that the absence o xynB2 gene up-regulates the expression of other β-Xylosidases in C. crescentus. On the other hand, a decreased activity of β-Xylosidase was observed in the strain pMOA, suggesting that the overexpression of β-Xylosidase II down-regulates C. crescentus β - Xylosidases activities. To verify that the variation in activity levels of β -Xylosidase occur as a consequence of variations in the levels of transcription of β-Xylosidases genes in different strains, we constructed a lacZ- fusion transcription by cloning the E. coli lacZ gene under the control of xynB2 gene promoter. Thus, the β-Galactosidase activity was measured as a function of xynB2 promoter activity. Tests of promoter activity by measuring the activity of β- Galactosidase in different strains showed that the xynB2 gene is transcription-dependent.
publishDate 2011
dc.date.issued.fl_str_mv 2011-01-20
dc.date.available.fl_str_mv 2012-01-30
dc.date.accessioned.fl_str_mv 2017-07-10T19:24:54Z
dc.type.status.fl_str_mv info:eu-repo/semantics/publishedVersion
dc.type.driver.fl_str_mv info:eu-repo/semantics/masterThesis
format masterThesis
status_str publishedVersion
dc.identifier.citation.fl_str_mv CORRÊA, Juliana Moço. Analysis of β-Xylosidase II expression of the aquatic bacterium Caulobacter crescentus and its role in the utilization of agro-industrial residues. 2011. 71 f. Dissertação (Mestrado em Engenharia) - Universidade Estadual do Oeste do Parana, Cascavel, 2011.
dc.identifier.uri.fl_str_mv http://tede.unioeste.br:8080/tede/handle/tede/2821
identifier_str_mv CORRÊA, Juliana Moço. Analysis of β-Xylosidase II expression of the aquatic bacterium Caulobacter crescentus and its role in the utilization of agro-industrial residues. 2011. 71 f. Dissertação (Mestrado em Engenharia) - Universidade Estadual do Oeste do Parana, Cascavel, 2011.
url http://tede.unioeste.br:8080/tede/handle/tede/2821
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language por
dc.rights.driver.fl_str_mv info:eu-repo/semantics/openAccess
eu_rights_str_mv openAccess
dc.format.none.fl_str_mv application/pdf
dc.publisher.none.fl_str_mv Universidade Estadual do Oeste do Parana
dc.publisher.program.fl_str_mv Programa de Pós-Graduação "Stricto Sensu" em Engenharia Agrícola
dc.publisher.initials.fl_str_mv UNIOESTE
dc.publisher.country.fl_str_mv BR
dc.publisher.department.fl_str_mv Engenharia
publisher.none.fl_str_mv Universidade Estadual do Oeste do Parana
dc.source.none.fl_str_mv reponame:Biblioteca Digital de Teses e Dissertações do UNIOESTE
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institution UNIOESTE
reponame_str Biblioteca Digital de Teses e Dissertações do UNIOESTE
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