Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2023 |
| Tipo de documento: | Dissertação |
| Idioma: | eng |
| Título da fonte: | Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) |
| Texto Completo: | http://hdl.handle.net/10362/161535 |
Resumo: | Unspecific peroxygenases (UPO) have recently gained attention for their capability to catalyse oxidative reactions, a challenging task in organic chemistry. These enzymes offer higher activity, enhanced stability, and a broad substrate scope. Nonetheless, a significant limitation is their inactivation under high H2O2 concentrations. To address this, strategies like in situ H2O2 generation systems, have been explored, such as the novel approach employing water radiolysis for H2O2 generation. In a prior study, a major hurdle was encountered, with the enzyme becoming inactivated after only 30 minutes of direct radiation exposure. Thus, the goal of this project was to overcome this limitation through the application of flow chemistry. To achieve this, a suitable setup was assembled, using a non-reactive plastic column to ensure H2O2 stability inside. To retain the enzyme in the column and separate it from the radiation source, enzyme immobilisation was employed. Surprisingly, this study revealed that a neutral pH is better for immobilisation, contrary to the literature. At pH 7, the immobilisation yield was 58.8%, compared to 55.1% at pH 8. The activity of the immobilised enzyme was also slightly higher at neutral pH (0.041 U µL-1), compared to pH 8 (0.036 U µL-1). Enzyme stability studies, in flow chemistry, were performed using supplemented H2O2 and the radiation source (radiolytic H2O2). The supplemented H2O2 strategy demonstrated higher enzyme stability, maintaining constant substrate conversion for several days and, even, extending to weeks. However, with the introduction of the radiolytic H2O2, stability was reduced to only 7 days, possibly due to H2O2 generation within the radiation source. Notably, the enzyme's stability was reduced to 24 hours when directly exposed to the radiation source. Consequently, it was deduced that the physical separation of the enzyme from the radiation source provided the solution to overcome the stability challenges encountered in previous study. |
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Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysisUnspecific PeroxygenaseRadioactivityPhysical separationFlow BiotransformationRadiolytic H2O2Enzyme stabilityDomínio/Área Científica::Engenharia e Tecnologia::Outras Engenharias e TecnologiasUnspecific peroxygenases (UPO) have recently gained attention for their capability to catalyse oxidative reactions, a challenging task in organic chemistry. These enzymes offer higher activity, enhanced stability, and a broad substrate scope. Nonetheless, a significant limitation is their inactivation under high H2O2 concentrations. To address this, strategies like in situ H2O2 generation systems, have been explored, such as the novel approach employing water radiolysis for H2O2 generation. In a prior study, a major hurdle was encountered, with the enzyme becoming inactivated after only 30 minutes of direct radiation exposure. Thus, the goal of this project was to overcome this limitation through the application of flow chemistry. To achieve this, a suitable setup was assembled, using a non-reactive plastic column to ensure H2O2 stability inside. To retain the enzyme in the column and separate it from the radiation source, enzyme immobilisation was employed. Surprisingly, this study revealed that a neutral pH is better for immobilisation, contrary to the literature. At pH 7, the immobilisation yield was 58.8%, compared to 55.1% at pH 8. The activity of the immobilised enzyme was also slightly higher at neutral pH (0.041 U µL-1), compared to pH 8 (0.036 U µL-1). Enzyme stability studies, in flow chemistry, were performed using supplemented H2O2 and the radiation source (radiolytic H2O2). The supplemented H2O2 strategy demonstrated higher enzyme stability, maintaining constant substrate conversion for several days and, even, extending to weeks. However, with the introduction of the radiolytic H2O2, stability was reduced to only 7 days, possibly due to H2O2 generation within the radiation source. Notably, the enzyme's stability was reduced to 24 hours when directly exposed to the radiation source. Consequently, it was deduced that the physical separation of the enzyme from the radiation source provided the solution to overcome the stability challenges encountered in previous study.Os enzimas Unspecific Peroxygenases (UPO) têm recebido atenção nos últimos anos devido à sua capacidade de realizar oxidações, sendo estas complexas em química orgânica. Estes enzimas apresentam elevada capacidade catalítica, estabilidade e um amplo substrate scope. Contudo, a sua maior limitação é a inativação por elevadas concentrações de H2O2. Para ultrapassar este problema, várias estratégias foram exploradas, incluindo os in situ generation systems of H2O2. Recentemente, a radiólise da água começou a ser estudada, dado o produto final ser maioritariamente H2O2. No estudo anterior, o maior obstáculo foi a inativação do enzima, após 30 minutos de exposição direta à radiação. Pelo que, o objetivo deste projeto é ultrapassar esta limitação, aplicando flow chemistry. Assim, um setup foi desenvolvido, utilizando um reator tubular de plástico para estabilidade do H2O2 no seu interior. Para reter o enzima no reator, procedeu-se à sua imobilização. Contrariamente à literatura, este estudo revelou que o pH neutro é melhor para a imobilização, tendo um immobilisation yield de 58.8% versus 55.1% a pH 8. A atividade do enzima imobilizado a pH 7 também era superior (0.041 U µL-1) comparativamente ao pH 8 (0.036 U µL-1). Posteriormente, foram realizados estudos de estabilidade do enzima no setup através de suplementação do meio com H2O2 e da utilização da fonte de radiação. A primeira estratégia demonstrou a robusta estabilidade do enzima, mantendo a conversão constante do substrato durante dias, chegando a semanas. Porém, com a introdução da fonte de radiação no sistema, a estabilidade do enzima reduz para 7 dias, possivelmente devido à formação de H2O2 na fonte de radiação. Salienta-se ainda que a estabilidade do enzima diminui para 24 horas quando é exposto diretamente à radiação. Concluiu-se, que a separação física do enzima da fonte de radiação é a solução para ultrapassar problemas de estabilidade encontrados no estudo anterior.Hollmann, FrankDjanashvili, KristinaRUNGil, Inês de Oliveira2023-12-112025-01-01T00:00:00Z2023-12-11T00:00:00Zinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisapplication/pdfhttp://hdl.handle.net/10362/161535enginfo:eu-repo/semantics/embargoedAccessreponame:Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos)instname:Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãoinstacron:RCAAP2024-03-11T05:44:28Zoai:run.unl.pt:10362/161535Portal AgregadorONGhttps://www.rcaap.pt/oai/openaireopendoar:71602024-03-20T03:58:34.815680Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) - Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãofalse |
| dc.title.none.fl_str_mv |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis |
| title |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis |
| spellingShingle |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis Gil, Inês de Oliveira Unspecific Peroxygenase Radioactivity Physical separation Flow Biotransformation Radiolytic H2O2 Enzyme stability Domínio/Área Científica::Engenharia e Tecnologia::Outras Engenharias e Tecnologias |
| title_short |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis |
| title_full |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis |
| title_fullStr |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis |
| title_full_unstemmed |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis |
| title_sort |
Towards robust radiobiocatalytic transformations combining radiolytic H2O2 generation and selective peroxygenasecatalysis |
| author |
Gil, Inês de Oliveira |
| author_facet |
Gil, Inês de Oliveira |
| author_role |
author |
| dc.contributor.none.fl_str_mv |
Hollmann, Frank Djanashvili, Kristina RUN |
| dc.contributor.author.fl_str_mv |
Gil, Inês de Oliveira |
| dc.subject.por.fl_str_mv |
Unspecific Peroxygenase Radioactivity Physical separation Flow Biotransformation Radiolytic H2O2 Enzyme stability Domínio/Área Científica::Engenharia e Tecnologia::Outras Engenharias e Tecnologias |
| topic |
Unspecific Peroxygenase Radioactivity Physical separation Flow Biotransformation Radiolytic H2O2 Enzyme stability Domínio/Área Científica::Engenharia e Tecnologia::Outras Engenharias e Tecnologias |
| description |
Unspecific peroxygenases (UPO) have recently gained attention for their capability to catalyse oxidative reactions, a challenging task in organic chemistry. These enzymes offer higher activity, enhanced stability, and a broad substrate scope. Nonetheless, a significant limitation is their inactivation under high H2O2 concentrations. To address this, strategies like in situ H2O2 generation systems, have been explored, such as the novel approach employing water radiolysis for H2O2 generation. In a prior study, a major hurdle was encountered, with the enzyme becoming inactivated after only 30 minutes of direct radiation exposure. Thus, the goal of this project was to overcome this limitation through the application of flow chemistry. To achieve this, a suitable setup was assembled, using a non-reactive plastic column to ensure H2O2 stability inside. To retain the enzyme in the column and separate it from the radiation source, enzyme immobilisation was employed. Surprisingly, this study revealed that a neutral pH is better for immobilisation, contrary to the literature. At pH 7, the immobilisation yield was 58.8%, compared to 55.1% at pH 8. The activity of the immobilised enzyme was also slightly higher at neutral pH (0.041 U µL-1), compared to pH 8 (0.036 U µL-1). Enzyme stability studies, in flow chemistry, were performed using supplemented H2O2 and the radiation source (radiolytic H2O2). The supplemented H2O2 strategy demonstrated higher enzyme stability, maintaining constant substrate conversion for several days and, even, extending to weeks. However, with the introduction of the radiolytic H2O2, stability was reduced to only 7 days, possibly due to H2O2 generation within the radiation source. Notably, the enzyme's stability was reduced to 24 hours when directly exposed to the radiation source. Consequently, it was deduced that the physical separation of the enzyme from the radiation source provided the solution to overcome the stability challenges encountered in previous study. |
| publishDate |
2023 |
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2023-12-11 2023-12-11T00:00:00Z 2025-01-01T00:00:00Z |
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info:eu-repo/semantics/publishedVersion |
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info:eu-repo/semantics/masterThesis |
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eng |
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