Optimisation de l'usage des coproduits dans l'alimentation des porcs en croissance : impact du type de fibre et de la xylanase sur la digestion des nutriments

Dickner-Ouellet, Laurie

03 May 2018

L’augmentation du coût des ingrédients de base des aliments pour porcs a permis à certains ingrédients alternatifs de se tailler une place sur les marchés nord-américains de l’alimentation animale. En effet, leur utilisation judicieuse en production porcine peut représenter un atout économique important. Toutefois, l’usage d’ingrédients alternatifs est limité dans les aliments pour porcs, notamment à cause leur effet parfois négatif sur la qualité de la carcasse ainsi que de leur teneur élevée en fibres alimentaires, peu valorisées par les monogastriques. Ce projet avait comme objectif de mieux comprendre l’impact de l’usage des ingrédients alternatifs disponibles dans l’Est du Canada afin de diminuer les coûts d’alimentation, sans modifier les performances de croissance chez le porc. Plus précisément, le projet visait à évaluer l’impact de différents types de fibres (solubles et insolubles) et de la supplémentation en xylanase, une enzyme exogène, sur la digestibilité iléale apparente des composants nutritionnels ainsi que sur les performances de croissance et la composition corporelle chez le porc en croissance-finition. Pour ce faire, deux expérimentations ont été réalisées. La première était un essai de digestibilité réalisé à l’aide de porcs canulés chez lesquels la digestibilité iléale apparente a été mesurée pour différents aliments variant en leur teneur et leur type de fibres, et selon l’addition ou non de xylanase. La seconde expérimentation consistait en un essai de croissance chez le porc en finition afin de mesurer ces mêmes traitements sur les performances de croissance, la composition corporelle et la qualité du gras. Les résultats obtenus montrent que les niveaux élevés de fibres alimentaires utilisés n’ont pas eu d’effets majeurs sur la digestibilité iléale apparente des nutriments et de l’énergie, sur la composition corporelle et sur les performances de croissance des animaux. De plus, l’ajout de xylanase dans les aliments a eu peu d’effets sur les critères mesurés

S 405 UL 2018

Porcs -- Alimentation -- Efficacité

Porcs -- Croissance

Xylanases

Fibres dans l'alimentation des animaux

Compléments alimentaires

Digestion

Seleção de fungos filamentosos produtores de hidrolases e pré-otimização das condições de cultivo / The selection of filamentous fungi that produce hydrolases and the preoptimization of their growth conditions

Ascencio, Isabela Moraes

30 September 2016

A crescente demanda por energia e a necessidade de promover o desenvolvimento sustentável colocam em foco os combustíveis renováveis. Dentro de biocombustíveis, os 2G ou segunda geração, têm como objetivo a utilização da energia contida na biomassa vegetal. Muitos microorganismos são capazes de excretar enzimas que quebram a lignocelulose, o principal componente das paredes celulares da planta, em açúcares fermentáveis. Os objetivos deste trabalho foram selecionar fungos filamentosos que produzem enzimas que degradam a biomassa e otimizar suas condições de cultivo. Quatro isolados e duas linhagems padrão foram testadas para a produção de celulases e identificadas pelo sequencimaneto da região ITS (Internal Transcribed Spacer). Após a caracterização inicial, três linhagens foram selecionadas e testadas em diferentes fontes de nitrogênio e carbono, e agentes tamponantes, visando o cultivo ótimo para cada delas. As condições ideais foram escolhidas com base em critérios de atividade enzimática, proteínas totais liberadas e pH. Após o estabelecimento das condições ótimas, os sobrenadantes das culturas foram liofilizados e o teor de proteínas determinado. O mesmo extrato foi testado quanto à FPA (Filter Paper Activity), atividades de β-glicosidase e xilanases, e quanto sua capacidade hidrolitica na biomassa pré-tratada. As linhagens selecionadas foram identificadas como Phanerochaete chrysosporium (F88), Aspergillus brasiliensis (F811) e a linhagem padrão Trichoderma reesei QM9414. A melhor combinação de fontes de nitrogênio foi a razão 4:3:3; 5:3:2 e 6:3:1 (sulfato de amónio, ureia e extrato de levedura) para F88, F811 e T. reesei, respectivamente. O ácido cítrico foi selecionado como agente tamponante para F88 e T. reesei, e PIPES para F811. Bagaço pré-tratado por explosão a vapor (BPT), como fonte de carbono, foi o melhor para induzir a produção de celulases e xilanases por F88 e F811, enquanto, Solka-Floc® foi a melhor para T. reesei. As atividades de β-glicosidase e xilanase foram maiores em F811 do que para T. reesei. No entanto, para FPA, T. reesei apresentou o melhor rendimento. Nos ensaios de hidrólise, as conversões de glicana e xilana foram semelhantes para ambas as linhagens, mesmo havendo acúmulo de celobiose no ensaio de T. reesei. Comparando os dados obtidos para ambas linhagens, uma selvagem e outra que é considerada referência industrial, F811 se mostrou promissor para a produção de enzimas hidrolíticas e como consequência, a habilidade em transformar a biomassa em açúcares fermentáveis. / The increasing demand for energy and the necessity to promote sustainable development has focused on renewable fuels. Within the available biofuels, 2G or second generation, has the aim of releasing the energy contained in plant biomass. Many microorganisms are able to secret enzymes capable of breaking down lignocellulose, the main component of plant cell walls, into fermentable sugars. The objectives of this project was to select filamentous fungi that produce enzymes that degrade biomass and optimize the growth conditions for them. Four isolates and two standards strains were tested for the production of cellulases and identified by ITS (Internal Transcribed Spacer) sequencing. After initial characterization, three strains were selected and tested in different sources of nitrogen and carbon, and buffering agents for optimal growth. The ideal conditions were chosen based on the criteria of enzymatic activity, total proteins released and pH. After the ideal condition for each strain were established, cell free extracts from each culture were lyophilized and the total protein content determined. This extract was tested for FPA (Filter Paper Activity), β- glucosidase and xylanase activity and the hydrolysis assays were carried out using pretreated biomass. The selected strains were identified as Phanerochaete chrysosporium (F88), Aspergillus brasiliensis (F811) and the standard strain Trichoderma reesei QM9414. The best combination of nitrogen sources was the ratio 4:3:3; 5:3:2 and 6:3:1 (ammonium sulfate, urea and yeast extract) for F88, F811 and T. reesei, respectively. Citric acid was selected as buffering agent for F88 and T. reesei, and PIPES for F811. Steam exploded bagasse, as a carbon source, was the best to induce the cellulase and xylanase production for F88 e F811, while, Solka-floc® was better for T. reesei. The activities of β-glucosidase and xylanase were higher for F811 than for T. reesei. However, for FPA, T. reesei showed the best yield. In the hydrolysis assays, conversions of glucan and xylan were similar for both strains, even though there was an accumulation of celobiose in the T. reesei\'s assay. Comparing the data obteined for both strains, a wild type and an industrial reference, F811 showed as a promising strain to produce hydrolytic enzymes and as consequence, break down biomass into fermentable sugars.

Aspergillus brasiliensis

Aspergillus brasiliensis

Trichoderma reesei

Trichoderma reesei

Agentes tamponantes

Biomass

Biomassa

Buffers

Carbon source

Cellulases

Celulases

Fontes de carbono

Fontes de nitrogênio

Hidrólise

Hydrolysis

Nitrogen source

Xilanases

Xylanases

Estudos funcionais e estruturais de pectinases e xilanases com potencial para aplicações biotecnológicas / Functional and structural studies of pectinases and xylanases with potential for biotechnological applications

Evangelista, Danilo Elton

31 October 2017

O uso desenfreado dos recursos naturais durante as últimas décadas têm impactado drasticamente o meio ambiente, direcionando a humanidade a investir no desenvolvimento de tecnologias para produção sustentável e ecológica de novas fontes de energia renovável e de produtos verdes. Nesse âmbito, o uso de resíduos derivados da biomassa vegetal tem sido apresentado como uma promissora alternativa à substituição de combustíveis, componentes químicos e polímeros de origem fóssil. Esse material é barato, abundante e não compete direta ou indiretamente com a segurança alimentar. Hoje, mais de 200 compostos químicos e biopolímeros de valor agregado podem ser obtidos a partir do processamento de material lignocelulósico. Todavia, essa tecnologia ainda não é plenamente desenvolvida, afetando sua competitividade econômica, sendo que o maior custo atribui-se à despolimerização enzimática dos polissacarídeos que formam a parede celular vegetal (PCV). Essa etapa requer preparados enzimáticos compostos por diversas enzimas, que agem sinergicamente sobre a complexa estrutura da PCV. Dentre essas enzimas, as pectinases e xilanases desempenham um importante papel na desconstrução dos polímeros pécticos e da hemicelulose. O presente trabalho objetivou o estudo funcional e estrutural de diferentes classes de pectinases e xilanases com potencial biotecnológico, no intuito de contribuir para o desenvolvimento pleno da despolimerização enzimática da PCV. Dentro dessa perspectiva, foram estudadas: uma pectina metilesterase (Sl-PME) e uma endo-poligalacturonase (Sl-EndoPG) do inseto Sphenophorus levis; uma exo-poligalacturonase (Bl-ExoPG) de Bacillus licheniformis; uma xilanase GH10 (MT-Xyn10) e duas GH11 (MT-Xyn11a e MT-Xyn11b) identificadas no metatranscriptoma de um consórcio microbiótico derivado de compostagem de bagaço de cana-de-açúcar. A estrutura cristalográfica da Sl-PME evidenciou alta semelhança com outra PME de inseto. Também foi concluído que as PMEs de inseto são mais similares às bacterianas, quando comparadas às fúngicas e vegetais, principalmente em relação ao sulco catalítico. Além disso, PMEs de inseto, exclusivamente, apresentam uma permutação circular, possívelmente realcionada a um evento de transferência horizontal. A Bl-ExoPG apresentou-se monomérica em solução, com atividade ótima em pH neutro a 60°C, sendo estável em uma ampla faixa de pH (5-10) e com considerável termoestabilidade em elevadas temperaturas. Essa enzima, também, apresentou especificidade por pectina não-metilada, liberando unicamente monômeros de ácido galacturônico. As três xilanases estudadas apresentaram-se monoméricas em solução, com maior atividade entre 30 e 45°C e pHs de 6 a 9, retendo atividade acima de 50% nos pHs 5 e 10. Além disso, todas elas apresentam especificidade por xilano, sendo que a MT-Xyn10 apresentou, também, alta atividade sobre arabinoxilano. A MT-Xyn10 apresentou um conjunto de propriedades enzimáticas bastante atrativas às aplicações industriais, uma vez que é altamente estável em uma ampla faixa de pH (4-10), termoestável em temperaturas de até 50°C e sua ação catalítica produz diversos xilo-oligossacarídeos de alto valor agregado. A análise da estrutura cristalográfica da MT-Xyn11a revela três particularidades estruturais, compartilhadas com a MT-Xyn11b, mas não descritas para outras GH11. Dentre essas particularidades, um loop parece limitar o acesso do substrato ao sítio catalítico, contribuindo diretamente para a baixa afinidade ao substrato apresentada por essas duas enzimas. / Decades of unbridled use of natural resources have drastically affected the global environment, driving humanity to invest in the development of novel technologies for production of sustainable and ecofriendly renewable energy sources and green products. In this context, plant biomass residues have been presented as a promising alternative to fuels, chemicals and polymers derived from fossil reserves. This feedstock is abundant, cheap and does not compete directly or indirectly with food security. Today, more than 200 value-added chemicals and biopolymers can be generated by processing lignocellulosic material. However, this technology is not fully developed yet; its major costs stem from the enzymatic depolymerization of the polysaccharides that constitute the plant cell wall (PCW). This step requires enzymatic cocktails composed of several enzymes that synergistically deconstruct the complex PCW. Among these enzymes, pectinases and xylanases play an important role in the depolymerization of pectic polymers and hemicellulose. The present work is a functional and structural study of different classes of pectinase and xylanases with biotechnological potential. It intends to contribute to the full development of PCW enzymatic depolymerization. With this perspective, we studied a pectin methylesterase (Sl-PME) and an endo-polygalacturonase (Sl-EndoPG) from the insect Sphenophorus levis; an exo-polygalacturonase (Bl-ExoPG) from Bacillus licheniformis; a GH10 xylanase (MT-Xyn10); and two GH11 xylanases (MT-Xyn11a and MT-Xyn11b) from the metatranscriptome of sugarcane bagasse compost-derived microbial consortia. The Sl-PME crystallographic structure showed high similarity with other insect PME. It was also concluded that insect PMEs are more similar to bacterial PMEs than fungi or plant PMEs, especially in relation to the catalytic groove. Moreover, insect PMEs exclusively presented a circular permutation that is possibly related to an event of horizontal gene transfer. Bl-ExoPG is monomeric in solution, with optimal activity on neutral pH and 60°C, being stable in a wide pH range (5-10) and with considerable thermostability at high temperatures. This enzyme, also presented specificity for non-methylated pectin substrates, releasing only monomers of galacturonic acid as catalytic product. All three xylanases studied here are monomeric in solution, with optimal activity between 30°C and 45°C and between pHs 6 and 9, retaining more than 50% of original activity in the pHs 5 and 10. Besides, they all showed specificity for xylan, and MT-Xyn10 also showed high activity on arabinoxylan. MT-Xyn10 revealed a set of enzymatic properties attractive for industrial applications, such as high stability in a wide pH range (4-10), thermostability up to 50°C and released products that are high value-added xilo-oligosaccharides. The MT-Xyn11a crystallographic structure revealed three structural particularities shared with MT-Xyn11b, but not previously described in other GH11. Among these particularities, a loop seems to limit the substrate access to the catalytic site, contributing to the low enzyme affinity presented by both MT-Xyn11a and MT-Xyn11b.

Caracterização enzimática

Cristalografia de proteínas

Despolimerização da biomassa vegetal

Enzymatic characterization

Pectinases and Xylanases

Pectinases e Xilanases

Plant biomass depolymerization

Protein X-ray crystallography

SAXS

SAXS

Seleção de fungos filamentosos produtores de hidrolases e pré-otimização das condições de cultivo / The selection of filamentous fungi that produce hydrolases and the preoptimization of their growth conditions

Isabela Moraes Ascencio

30 September 2016

A crescente demanda por energia e a necessidade de promover o desenvolvimento sustentável colocam em foco os combustíveis renováveis. Dentro de biocombustíveis, os 2G ou segunda geração, têm como objetivo a utilização da energia contida na biomassa vegetal. Muitos microorganismos são capazes de excretar enzimas que quebram a lignocelulose, o principal componente das paredes celulares da planta, em açúcares fermentáveis. Os objetivos deste trabalho foram selecionar fungos filamentosos que produzem enzimas que degradam a biomassa e otimizar suas condições de cultivo. Quatro isolados e duas linhagems padrão foram testadas para a produção de celulases e identificadas pelo sequencimaneto da região ITS (Internal Transcribed Spacer). Após a caracterização inicial, três linhagens foram selecionadas e testadas em diferentes fontes de nitrogênio e carbono, e agentes tamponantes, visando o cultivo ótimo para cada delas. As condições ideais foram escolhidas com base em critérios de atividade enzimática, proteínas totais liberadas e pH. Após o estabelecimento das condições ótimas, os sobrenadantes das culturas foram liofilizados e o teor de proteínas determinado. O mesmo extrato foi testado quanto à FPA (Filter Paper Activity), atividades de β-glicosidase e xilanases, e quanto sua capacidade hidrolitica na biomassa pré-tratada. As linhagens selecionadas foram identificadas como Phanerochaete chrysosporium (F88), Aspergillus brasiliensis (F811) e a linhagem padrão Trichoderma reesei QM9414. A melhor combinação de fontes de nitrogênio foi a razão 4:3:3; 5:3:2 e 6:3:1 (sulfato de amónio, ureia e extrato de levedura) para F88, F811 e T. reesei, respectivamente. O ácido cítrico foi selecionado como agente tamponante para F88 e T. reesei, e PIPES para F811. Bagaço pré-tratado por explosão a vapor (BPT), como fonte de carbono, foi o melhor para induzir a produção de celulases e xilanases por F88 e F811, enquanto, Solka-Floc® foi a melhor para T. reesei. As atividades de β-glicosidase e xilanase foram maiores em F811 do que para T. reesei. No entanto, para FPA, T. reesei apresentou o melhor rendimento. Nos ensaios de hidrólise, as conversões de glicana e xilana foram semelhantes para ambas as linhagens, mesmo havendo acúmulo de celobiose no ensaio de T. reesei. Comparando os dados obtidos para ambas linhagens, uma selvagem e outra que é considerada referência industrial, F811 se mostrou promissor para a produção de enzimas hidrolíticas e como consequência, a habilidade em transformar a biomassa em açúcares fermentáveis. / The increasing demand for energy and the necessity to promote sustainable development has focused on renewable fuels. Within the available biofuels, 2G or second generation, has the aim of releasing the energy contained in plant biomass. Many microorganisms are able to secret enzymes capable of breaking down lignocellulose, the main component of plant cell walls, into fermentable sugars. The objectives of this project was to select filamentous fungi that produce enzymes that degrade biomass and optimize the growth conditions for them. Four isolates and two standards strains were tested for the production of cellulases and identified by ITS (Internal Transcribed Spacer) sequencing. After initial characterization, three strains were selected and tested in different sources of nitrogen and carbon, and buffering agents for optimal growth. The ideal conditions were chosen based on the criteria of enzymatic activity, total proteins released and pH. After the ideal condition for each strain were established, cell free extracts from each culture were lyophilized and the total protein content determined. This extract was tested for FPA (Filter Paper Activity), β- glucosidase and xylanase activity and the hydrolysis assays were carried out using pretreated biomass. The selected strains were identified as Phanerochaete chrysosporium (F88), Aspergillus brasiliensis (F811) and the standard strain Trichoderma reesei QM9414. The best combination of nitrogen sources was the ratio 4:3:3; 5:3:2 and 6:3:1 (ammonium sulfate, urea and yeast extract) for F88, F811 and T. reesei, respectively. Citric acid was selected as buffering agent for F88 and T. reesei, and PIPES for F811. Steam exploded bagasse, as a carbon source, was the best to induce the cellulase and xylanase production for F88 e F811, while, Solka-floc® was better for T. reesei. The activities of β-glucosidase and xylanase were higher for F811 than for T. reesei. However, for FPA, T. reesei showed the best yield. In the hydrolysis assays, conversions of glucan and xylan were similar for both strains, even though there was an accumulation of celobiose in the T. reesei\'s assay. Comparing the data obteined for both strains, a wild type and an industrial reference, F811 showed as a promising strain to produce hydrolytic enzymes and as consequence, break down biomass into fermentable sugars.

Aspergillus brasiliensis

Trichoderma reesei

Agentes tamponantes

Biomassa

Celulases

Fontes de carbono

Fontes de nitrogênio

Hidrólise

Xilanases

Aspergillus brasiliensis

Trichoderma reesei

Biomass

Buffers

Carbon source

Cellulases

Hydrolysis

Nitrogen source

Xylanases

Estudos funcionais e estruturais de pectinases e xilanases com potencial para aplicações biotecnológicas / Functional and structural studies of pectinases and xylanases with potential for biotechnological applications

Danilo Elton Evangelista

31 October 2017

O uso desenfreado dos recursos naturais durante as últimas décadas têm impactado drasticamente o meio ambiente, direcionando a humanidade a investir no desenvolvimento de tecnologias para produção sustentável e ecológica de novas fontes de energia renovável e de produtos verdes. Nesse âmbito, o uso de resíduos derivados da biomassa vegetal tem sido apresentado como uma promissora alternativa à substituição de combustíveis, componentes químicos e polímeros de origem fóssil. Esse material é barato, abundante e não compete direta ou indiretamente com a segurança alimentar. Hoje, mais de 200 compostos químicos e biopolímeros de valor agregado podem ser obtidos a partir do processamento de material lignocelulósico. Todavia, essa tecnologia ainda não é plenamente desenvolvida, afetando sua competitividade econômica, sendo que o maior custo atribui-se à despolimerização enzimática dos polissacarídeos que formam a parede celular vegetal (PCV). Essa etapa requer preparados enzimáticos compostos por diversas enzimas, que agem sinergicamente sobre a complexa estrutura da PCV. Dentre essas enzimas, as pectinases e xilanases desempenham um importante papel na desconstrução dos polímeros pécticos e da hemicelulose. O presente trabalho objetivou o estudo funcional e estrutural de diferentes classes de pectinases e xilanases com potencial biotecnológico, no intuito de contribuir para o desenvolvimento pleno da despolimerização enzimática da PCV. Dentro dessa perspectiva, foram estudadas: uma pectina metilesterase (Sl-PME) e uma endo-poligalacturonase (Sl-EndoPG) do inseto Sphenophorus levis; uma exo-poligalacturonase (Bl-ExoPG) de Bacillus licheniformis; uma xilanase GH10 (MT-Xyn10) e duas GH11 (MT-Xyn11a e MT-Xyn11b) identificadas no metatranscriptoma de um consórcio microbiótico derivado de compostagem de bagaço de cana-de-açúcar. A estrutura cristalográfica da Sl-PME evidenciou alta semelhança com outra PME de inseto. Também foi concluído que as PMEs de inseto são mais similares às bacterianas, quando comparadas às fúngicas e vegetais, principalmente em relação ao sulco catalítico. Além disso, PMEs de inseto, exclusivamente, apresentam uma permutação circular, possívelmente realcionada a um evento de transferência horizontal. A Bl-ExoPG apresentou-se monomérica em solução, com atividade ótima em pH neutro a 60°C, sendo estável em uma ampla faixa de pH (5-10) e com considerável termoestabilidade em elevadas temperaturas. Essa enzima, também, apresentou especificidade por pectina não-metilada, liberando unicamente monômeros de ácido galacturônico. As três xilanases estudadas apresentaram-se monoméricas em solução, com maior atividade entre 30 e 45°C e pHs de 6 a 9, retendo atividade acima de 50% nos pHs 5 e 10. Além disso, todas elas apresentam especificidade por xilano, sendo que a MT-Xyn10 apresentou, também, alta atividade sobre arabinoxilano. A MT-Xyn10 apresentou um conjunto de propriedades enzimáticas bastante atrativas às aplicações industriais, uma vez que é altamente estável em uma ampla faixa de pH (4-10), termoestável em temperaturas de até 50°C e sua ação catalítica produz diversos xilo-oligossacarídeos de alto valor agregado. A análise da estrutura cristalográfica da MT-Xyn11a revela três particularidades estruturais, compartilhadas com a MT-Xyn11b, mas não descritas para outras GH11. Dentre essas particularidades, um loop parece limitar o acesso do substrato ao sítio catalítico, contribuindo diretamente para a baixa afinidade ao substrato apresentada por essas duas enzimas. / Decades of unbridled use of natural resources have drastically affected the global environment, driving humanity to invest in the development of novel technologies for production of sustainable and ecofriendly renewable energy sources and green products. In this context, plant biomass residues have been presented as a promising alternative to fuels, chemicals and polymers derived from fossil reserves. This feedstock is abundant, cheap and does not compete directly or indirectly with food security. Today, more than 200 value-added chemicals and biopolymers can be generated by processing lignocellulosic material. However, this technology is not fully developed yet; its major costs stem from the enzymatic depolymerization of the polysaccharides that constitute the plant cell wall (PCW). This step requires enzymatic cocktails composed of several enzymes that synergistically deconstruct the complex PCW. Among these enzymes, pectinases and xylanases play an important role in the depolymerization of pectic polymers and hemicellulose. The present work is a functional and structural study of different classes of pectinase and xylanases with biotechnological potential. It intends to contribute to the full development of PCW enzymatic depolymerization. With this perspective, we studied a pectin methylesterase (Sl-PME) and an endo-polygalacturonase (Sl-EndoPG) from the insect Sphenophorus levis; an exo-polygalacturonase (Bl-ExoPG) from Bacillus licheniformis; a GH10 xylanase (MT-Xyn10); and two GH11 xylanases (MT-Xyn11a and MT-Xyn11b) from the metatranscriptome of sugarcane bagasse compost-derived microbial consortia. The Sl-PME crystallographic structure showed high similarity with other insect PME. It was also concluded that insect PMEs are more similar to bacterial PMEs than fungi or plant PMEs, especially in relation to the catalytic groove. Moreover, insect PMEs exclusively presented a circular permutation that is possibly related to an event of horizontal gene transfer. Bl-ExoPG is monomeric in solution, with optimal activity on neutral pH and 60°C, being stable in a wide pH range (5-10) and with considerable thermostability at high temperatures. This enzyme, also presented specificity for non-methylated pectin substrates, releasing only monomers of galacturonic acid as catalytic product. All three xylanases studied here are monomeric in solution, with optimal activity between 30°C and 45°C and between pHs 6 and 9, retaining more than 50% of original activity in the pHs 5 and 10. Besides, they all showed specificity for xylan, and MT-Xyn10 also showed high activity on arabinoxylan. MT-Xyn10 revealed a set of enzymatic properties attractive for industrial applications, such as high stability in a wide pH range (4-10), thermostability up to 50°C and released products that are high value-added xilo-oligosaccharides. The MT-Xyn11a crystallographic structure revealed three structural particularities shared with MT-Xyn11b, but not previously described in other GH11. Among these particularities, a loop seems to limit the substrate access to the catalytic site, contributing to the low enzyme affinity presented by both MT-Xyn11a and MT-Xyn11b.

Caracterização enzimática

Cristalografia de proteínas

Despolimerização da biomassa vegetal

Pectinases e Xilanases

SAXS

Enzymatic characterization

Pectinases and Xylanases

Plant biomass depolymerization

Protein X-ray crystallography

SAXS

Crystal Structures Of Native And Xylosaccharides-Bound Alkali Thermostable Xylanase From An Alkalophilic Bacillus SP. NG-27: Structural Insights Into Alkalophilicity. Analysis Of C-H...O Hydrogen Bonds In Helices Of Globular Proteins

Manikandan, K

06 1900

Xylanases are xylan-degrading enzymes, belong to glycosyl hydrolases (GH). Xylanases from the two major families 10 (GH10) and 11 (GH11) catalyze the hydrolysis of internal β-, bonds of xylan backbone. Xylan is the second most abundant polysaccharide in nature. Nearly one third of the dry weight of the higher plants is xylan and therefore, xylanases have an important role in biomass conversions. Currently, the most effective application of xylanases is in prebleaching of kraft pulp to minimize the use of environmentally hazardous chemicals in the subsequent treatment stages. In recent years, therefore, attention is focused on to isolate and/or engineer the xylanases for the industrial requirements. The desirable roperties of xylanases in paper industry are stability and activity at high temperatures and alkaline pH. While he factors responsible for the thermal stability of GH10 xylanases have been analyzed, factors governing the alkaline stability of GH10 xylanases remain poorly understood. The present thesis reports the crystal structures of an alkali thermostable GH10 extracellular endo-xylanase (BSX) from an alkalophilic organism, Bacillus sp. NG-27 in free and xylosaccharides-bound form. The enzyme was purified from the native organism and crystallized. The structure was solved by molecular replacement method. The 2.2 Å crystal structure of the native BSX enzyme is the first structure of an alkali thermostable GH10 family xylanase from an alkalophilic organism. It has unveiled unique protein properties that can form the basis for improving the thermal, alkaline stability and activity by site directed mutagenesis. The comparative study, especially in relation to GH10 xylanases, deciphered important structural features which are likely to be responsible for the alkaline stability of the enzyme. The work exemplifies the mechanism of adaptation of enzymes to function under polyextreme conditions through changes in the nature and composition of solvent-exposed residues. As apparent from the comparative study, the enhanced stability of the protein can be attributed to the surface rich in acidic residues and less number of solvent-exposed Asn as seen in BSX. This situation which may be roughly described as “acidic residues outside and Asn inside”, is a notable feature of alkali-stable GH10 xylanases from alkalophilic organisms. In addition, the candidate has carried out the comprehensive database analysis of the occurrence of C-H…O hydrogen bonds in helices and helix termini of globular proteins. The study provides a compelling evidence that the main-chain Cα and the side-chains CH which participate in C-H…O hydrogen bonds collectively augment the cohesive energy and thereby contribute together with the classical N-H…O hydrogen bonds and other interactions to the overall stability of helix and therefore of proteins. Chapter 1 starts with a brief introduction of xylanases, their classifications and overall folds. At present, a little more than a dozen of crystal structures of GH10 xylanases are known and described in the literature. A brief mention about these structures and their optimum pH and temperature is outlined under a separate section. In view of the industrial importance of the study enzyme, the potential industrial and biotechnological applications of xylanases are detailed in this Chapter. A section is dedicated to describe the present study enzyme BSX, an alkali thermostable endo-xylanase from an alkalophilic bacterium, Bacillus sp. NG-27. BSX has a molecular mass of ~41 kDa and is optimally active at 343 K and at a pH of 8.4. The alkaline thermostability of the wild type BSX is likely to be industrially important. At the end, the scope of the present work is detailed. Chapter 2 presents the purification of xylanase (BSX) from Bacillus sp. NG-27, the crystallization of the native and xylosaccharides-bound BSX, the X-ray diffraction data collection on these crystals and processing of the data. Repeated attempts to crystallize the protein expressed in the chloroplast of transgenic tobacco plant were unsuccessful. However, crystallization was achieved with the protein sample purified from the native source by hanging drop vapour diffusion method. Crystals were grown at both acidic (4.6) and basic pH (8.5). The corresponding crystallization conditions are 0.2 M MgCl2, 0.1 M sodium acetate pH 4.6 and 20% PEG 550 MME and 0.1 M aCl, 0.01 M MgCl2, 0.1 M Tris-HCl pH 8.5 and 15% PEG 8000. Crystals grown at acidic pH were not suitable for X-ray diffraction study. Subsequently, crystal obtained at a basic pH of 8.5 was used for X-ray data collection and it diffracted X-rays to better than 2.2 Å at the home source at cryo-temperature (100 K). Native BSX crystals belong to monoclinic space group C2 with unit cell parameters a = 174.5 Å, b = 54.7 Å, c = 131.5 Å and β = 131.2°. Crystals of xylosaccharides-bound enzyme were grown in a slightly modified crystallization condition of native, 0.1 M NaCl, 0.2 M MgCl2, 0.1 M Tris-HCl pH 8.5 and 15% PEG 8000 and the enzyme was incubated with xylan prior to setting up the crystallization. Crystals belong to primitive orthorhombic space group P212121 with unit cell parameters a = 59.2 Å, b = 83.8 Å and c = 174.4 Å. A data set was collected using synchrotron radiation of wave length 1.0 Å from a cryo-cooled crystal at Spring-8 BL26B1 beam line, Japan. The Matthews coefficient VM for native and xylosaccharides- bound crystals was calculated to be 2.8 and 2.7 Å3 Da-1, respectively, suggesting two molecules in each crystal asymmetric unit. No twinning was detected in both the datasets and the overall quality of the data sets was found to be good. Chapter 3 details the application of molecular replacement method to the structure solution of native and xylosaccharides-bound BSX, the course of iterative model building and the refinement carried out, and the quality of the final protein structure models. The native-enzyme structure solution was obtained by the molecular replacement method using as a search model the crystal structure (PDB code 1hiz) of the closest homologous, extracellular xylanase (GSX) from Geobacillus stearothermophilus. No non- crystallographic symmetry (NCS) restraint was applied between the two independent molecules in the crystal asymmetric unit at the final round of refinement. The final positional refinement of native BSX converged to R factors of R = 19.4% and Rfree = 23.5% for data between 20.0 to 2.2 Å. The final native model consists of 5704 protein atoms, two Mg2+ ions and 721 solvent water molecules. The final native model was taken as the search structure for the xylosaccharides-bound BSX and a solution with a correlation coefficient of 70.7% and an R-factor of 32.1% was obtained from the molecular replacement calculation. Unlike the native structure refinement, NCS restraint was imposed at all stages of the refinement. Bound xylosaccharides were clearly visible inthe difference Fourier electron density maps. The last round of refinement gave a model with R and Rfree of 21.8% and 25.7%, respectively. The final xylosaccharides-bound model consists of 5766 protein atoms, four Mg2+ ions, 85 atoms belong to bound xylosaccharides and 523 solvent water molecules. No residues were found in the disallowed region of the Ramachandran (φ, ψ) map for both the structures. Chapter 4 describes the native and xylosaccharides-bound BSX crystal structures and the structural comparison of BSX with other GH10 family xylanase crystal structures for which the optimum temperature and pH are known in the literature. BSX folds as the ubiquitous (β/α)8-barrel, a common structural superfold characteristic of GH10 xylanases. The two active site glutamic acid residues, Glu149 and Glu259, are located on opposite sides of the active site cleft and their side-chains are at a distance of 5.5 Å apart suggesting the enzymatic reaction takes place by the retaining mechanism. From the structural superposition of other xylotriose-bound xylanase structures on to the xylosaccharides-bound BSX, structural plasticity in the xylotriose binding can be inferred, implying that the xylose recognition at the subsite -3 displays plasticity and is less specific as opposed to that at -1 and -2 subsites. The stacking interaction of one of the xylose moieties of the xylobiose with the Trp235 seen in BSX provides, for the first time, a structural evidence for the direct involvement of Trp235 in xylosaccharides binding. The crystal structure revealed a metal binding site, found at the C-terminal end of catalytic domain. The presence of metal binding site was not anticipated from earlier theoretically modeled structure and biochemical studies. Further, we have shown experimentally the requirement of Mg2+ ion for the enzyme activity. We havedescribed a novel WP sequence-structure-interaction motif which is present in the (+) side of the active site region and presumably helps in the efficient binding of the carbohydrate moiety of the xylan in the active site cleft of BSX. The structural comparison of BSX with other GH10 xylanases solved to date and characterized to be active at a pH close to neutral was done for the first time. The comparative study revealed the essential structural features which may responsible for the alkaline stability of GH10 xylanases.Briefly, the alkalophilic GH10 xylanases from alkalophilic organisms have surface abundant in acidic residues, the heat and alkaline susceptible residue Asn depleted on the protein surface and increased number of salt bridges. Our study has unveiled the role of the nature and composition of protein surface amino acids in the adaptation of enzymes to polyextreme conditions. The observations reported in the thesis provide important lessons for engineering alkaline stability in xylanases for industrial applications and in general for the understanding of alkaline stability in related proteins. A comparison of the surface features of the BSX and of halophilic proteins allowed us to predict the activity of BSX at high salt concentrations, which we verified through experiments. This offered us important lessons in polyextremophilicity of proteins, where understanding structural features of a protein stable in one set of extreme conditions provided clues about the activity of the protein in other extreme conditions. Chapter 5 summaries the important findings of the present study from the crystal structural analysis of BSX and its comparison with non-alkalophilic GH10 xylanases. Separate sections are made on conclusions and future prospects for the study on BSX. Chapter 6 describes the comprehensive database analysis of C-H…O hydrogen bond in helices of globular proteins. The C-H…O hydrogen bonds found in helices are predominantly of type 5 → 1 or 4 → 1.Our analysis reveals that the Cγ and Cβ hydrogen atom(s) are frequently involved in such hydrogen bonds. A marked preference is noticed for aliphatic β-branched residue Ile to participate in 5 → 1 C- H…O hydrogen bonds involving methylene Cγ1 atom as donor in α-helices. In addition, C-H…O hydrogen bonds are present along with helix stabilizing salt bridges and to some extent compensate for the side-chain conformational entropy loss. Our analysis highlights that a multitude of local C-H…O hydrogen bondsformed by a variety of amino acid side-chains and Cα hydrogen atoms occur in helices and more so at the helix termini. A majority of the helix favouring residues, Met, Glu, Arg, Lys, Leu and Gln which also have large side-chains with more donatable CH groups, have significant propensity to form side-chain to main-chain C-H…O hydrogen bonds in helix. The large side-chains are marked by their ability to shield from the solvent the polar atoms of the peptide backbone and at the same time participate in weak cohesive C-H…O interactions in the helix. This chapter also details the identification for the first time a novel chain reversal motif stabilized by 1 → 5 Cα-H…O interactions. The importance of these hydrogen bonds with respect to helix stability is discussed in the final section of the chapter. Appendix A details the crystallographic and structural analyses oftwares used for the present thesis work. Appendix B describes, in addition to the crystal structure analysis of BSX, the work carried out by the candidate on a comparative study of a thermostable xylanase from Thermoascus aurantiacus, solved in our laboratory at atomic 1.11 Å (293 K) and ultrahigh 0.89 Å (100 K) resolutions. From the comparison, we have for the first time pointed out the possibility of plasticity of ion pairs in proteins with water molecules mediating some of the alternate arrangements. The αβ-loops are relatively less flexible than the βα-loops. The β-strands are least affected structurally with the increase in temperature. Thus the TIM barrel fold in the study enzyme, though having a single domain, may be dissected into parts based on the relative flexibility and described as having a rigid core constituted by the β-barrel and a less rigid exterior formed by the surrounding α-helices. Appendix C presents the crystallization and the preliminary X-ray characterization work done by the author of the thesis on an alkali thermostable cellulase enzyme from Thermomonospora sp. The protein is an extracellular enzyme with molecular mass of 14.2 kDa and interestingly, has the dual activity for both cellulose and xylan. The primary structure of the enzyme is not known. The enzyme was purified from the source organism and crystallized. A complete diffraction data set was collected and processed to 2.3 Å in an orthorhombic space group P212121. Appendix D contains tables which give details about the analysed 5 → 1 Cα- H…O hydrogen bonds in helices and a novel chain reversal motif with 1 → 5 Cα-H…O hydrogen bonds. Appendix E encloses reprints of publications which have resulted from the work reported in the thesis.

Xylanase

Bascillus Streptomyces

Protein - Hydrogen Bonds

Bacillus SP.Ng-27 Xylanase (BSX)

Xylanases - Purification

BSX Xylanase

Xylanase

Globular Proteins

Xylosaccharides-bound BSX

Alkali-thermostable Xylanase

Alkaline Thermostability

Biochemistry

Evaluation of the bleach-enhancing effects of xylanases on bagasse-soda pupil

Bissoon, Sadhvir

January 2002

Submitted in fulfillment of the requirements for the Degree of Doctor of Technology: Biological Sciences, M.L. Sultan Technikon, 2002. / The extent of diffusion and surface modification of a purified 23.6 kDa xylanase isolated from Thermomyces lanuginosus on bagasse pulp was evaluated. Polyclonal anti-xylanase antibodies were raised in two rabbits and in conjunction with immunogold labeling and microscopic studies enzyme diffusion and degradation studies were performed. The purity of the xylanase was confirmed by SDS-PAGE and western blots confirmed the antigen-antibody hybrid on the nitrocellulose membrane. / D

Wood-pulp--Bleaching.

Pulping

Soda pulping process

Soda pulping process

Soda pulping process

Xylanases

Enzymes--Industrial applications

Produção de celulas e xilanases pelo fungo termofílio Humicola grisea var. thermoidea em diferentes substratos lignocelulósicos / Production of cellulases and xylanases by thermophilic fungus Humicola grisea var, thermoidea in different lignocellulosic sustrates.

MELO, Guilhermar Ramos de

30 August 2010

Made available in DSpace on 2014-07-29T15:16:30Z (GMT). No. of bitstreams: 1 DISSERTACAO DE MESTRADO FINAL.pdf: 1117246 bytes, checksum: 91bcbcfc247218ffb970c121596f7b0c (MD5) Previous issue date: 2010-08-30 / The vegetal biomass consists mainly of cellulose, hemicellulose and lignin. Cellulose is the most abundant polymer and xylan is the main component of hemicellulose. The conversion of cellulose and xylan to glucose and xylose can be realized by an enzymatic complex found in secretions of microorganisms such as fungi and bacteria. Enzymatic hydrolysis is an important step to the bioconversion of cellulosic and hemicellulosic fraction from lignocellulosic wastes. The thermophilic fungus Humicola grisea var thermoidea produces an efficient complex of cellulolytic enzymes (endoglucanases, cellobiohydrolases and β-glucosidase) and xylanolytic (endoxylanase and β-xylosidase) with high thermostability when grown on different lignocellulosic substrates. The aim of this study was to analyze the kinetics of production of cellulases and xylanase by the fungus H. grisea cultivated on medium containing rice straw (RS), corncob (CC), crushed cane sugar bagasse (CSB) and wheat bran (WB) as carbon source and subsequently analyze the profile of proteins with cellulolytic and xylanolytic activity secreted by the fungus when grown in minimal medium, by liquid fermentation, containing the substrates at concentrations of 1, 2 and 3% and maintained at 42 ° C, 120 rpm for different times. The best results were obtained when the fungus was grown in 3% BCA and FT, the peaks of FPase (0.17 U / mL) and CMCase (3.54 U / mL) were observed after 192 h of growth with 3% BCA , peak avicelase (0,195 U / mL) after 48 h with 3% FT and peak xylanase (23.75 U / mL) after 216 h with 3% FT. The results showed that the best inducer of enzyme production with FPase and CMCase activity was the CSB and the best inducer of enzymes production with xylanase and avicelase activity was the WB. In profile analysis of proteins secreted by H. grisea by SDS-PAGE (216 h) and zymogram (144 h), no band was seen when the fungus was grown in the presence of glucose, suggesting catabolite repression. However, two very strong protein bands corresponding to HXYN2 (23 kDa) and CBH1.2 (47 kDa) were visualized in the gels containing CSB (2 to 3%) and WB (2 and 3%). These enzymes are the main xylanolytic and cellulolytic systems of the fungus, respectively. Were monitored by recombinant enzymes from H. grisea (in gels), an endoxylanase HXYN2r (23 kDa), an cellobiohydrolase CBH1.2r (47 kDa). The masses full profile of H. grisea can be seen in Figures 13, 14, 15, 16, 18 and 19. / A biomassa vegetal é constituída principalmente de celulose, hemicelulose e lignina. A celulose é o polímero mais abundante e a xilana o principal componente hemicelulósico. A conversão da celulose e da xilana à glicose e xilose pode ser realizada por um complexo enzimático encontrado nas secreções de microrganismos tais como fungos e bactérias. A hidrólise enzimática é um importante passo para a bioconversão da fração celulósica e hemicelulósica de resíduos lignocelulósicos. O fungo termofílico Humicola grisea var thermoidea produz um eficiente complexo de enzimas celulolíticas (endoglicanases, celobiohidrolases e β-glicosidases) e xilanolíticas (endoxilanases e β-xilosidase) com alta termoestabilidade quando cultivado em diferentes substratos lignocelulósicos. O objetivo desse trabalho foi analisar a cinética de produção de celulases e xilanases pelo fungo H. grisea cultivado em meio contendo palha de arroz (PA), sabugo de milho (SM), bagaço de cana-de-açúcar (BCA) e farelo de trigo (FT) como fonte de carbono e posteriormente analisar o perfil de proteínas com atividade celulolítica e xilanolítica secretadas pelo fungo quando cultivado em meio mínimo, por fermentação líquida, contendo os substratos nas concentrações de 1, 2 e 3%, e mantidos a 42 °C, 120 rpm por diferentes tempos. Os melhores resultados foram obtidos quando o fungo foi cultivado em 3% de BCA e FT, sendo que os picos de FPase (0.17 U/mL) e CMCase (3.54 U/mL) foram observados após 192 e 240 h respectivamente de crescimento com 3% de BCA, o pico de Avicelase (0.195 U/mL) após 48 h com 3% de FT e o pico de xilanase (23.75 U/mL) após 216 h com 3% de FT. Os resultados demonstraram que o melhor indutor da produção de enzimas com atividade de FPAse e CMCase foi o BCA e o melhor indutor da produção de enzimas com atividade de Avicelase e xilanase foi o FT. Na análise do perfil de proteínas secretadas pelo H. grisea por SDS-PAGE (216 h) e zimograma (144 h), nenhuma banda foi visualizada quando o fungo foi cultivado na presença de glicose, sugerindo repressão catabólica. Entretanto, duas bandas protéicas muito fortes, correspondentes à HXYN2 (23 kDa) e CBH1.2 (47 kDa) foram visualizadas nos géis contendo BCA (2 e 3%) e FT (2 e 3%); e representam as principais enzimas dos sistemas xilanolítico e celulolítico do fungo, respectivamente. Estas foram monitoradas pelas enzimas recombinantes do H. grisea (nos geis): uma endoxilanase HXYN2r (23 kDa) e uma celobiohidrolase CBH1.2r (47 kDa). As massas do perfil completo do H. grisea podem ser vistas nas Figuras 13-19.

Humicola griase

celulases

xilanases

substratos lignocelulósicos.

Humicola griasea

cellulases, xylanases, lignocellulosic

Étude de l'impact des enzymes exogènes sur la digestibilité des acides aminés chez le porc et le poulet : approche par méta-analyse

Zouaoui, Maroua

22 December 2018

Les phytates et les polysaccharides non amylacés (PNA) sont des facteurs antinutritionnels abondants dans l’alimentation des porcs et des poulets. Même si les phytates constituent un réservoir de phosphore (P), ce P est peu disponible pour le porc et le poulet à cause de la faible présence de phytases endogènes chez ces animaux. Pour cette raison la phytase microbienne a été incorporée dans les régimes alimentaires, ce qui a permis de mettre en évidence l’impact négatif des phytates sur la digestibilité des acides aminés (AA). De même, les PNA sont indigestibles et résistants à la digestion chez le porc et le poulet. De plus, ils limitent la digestibilité des constituants intracellulaires des graines diminuant ainsi la digestibilité des AA et de l’énergie d’où l’utilité du recours à des carbohydrases. La xylanase, une carbohydrase, pourrait améliorer la digestibilité des PNA menant possiblement à l’augmentation de la digestibilité des AA et du contenu en énergie métabolisable apparente (EMA). À cet égard, il est d’une grande importance de connaître les mécanismes et de quantifier l’action de ces deux enzymes dans l’élimination des facteurs antinutritionnels et l’amélioration de la digestibilité des AA, ainsi que de l’EMA. Une approche par méta-analyse a permis d’établir des modèles de prédiction de la digestibilité des AA sous l’effet de l’ajout de la phytase chez le porc et le poulet à partir de la teneur de la ration en AA alimentaires, la phytase incorporée, en plus de la fibre alimentaire NDF (Neutral Detergent Fibre) dans le cas du porc et du P phytique (PP) dans le cas du poulet. Des modèles de prédiction ont aussi été établis pour prédire la digestibilité des AA chez le poulet à partir de la xylanase incorporée et la fibre alimentaire (NDF et PNA). La xylanase incorporée, la fibre alimentaire (NDF et PNA) et l’énergie brute (EB) se sont révélé comme les meilleurs prédicteurs du contenu en EMA chez le poulet. Les modèles actuels établis dans cette étude permettent de quantifier l'effet de la phytase sur la digestibilité des AA chez le porc et le poulet ainsi que l’effet de la xylanase sur la digestibilité des AA et du contenu en EMA chez le poulet assurant l’utilisation précise de ces enzymes au moment de la formulation des régimes alimentaires. / Phytates and non-starch polysaccharides (NSP) are abundant antinutritional factors in pig and broiler diets. Although phytates constitute a phosphorus (P) reservoir, this P is not available because monogastric animals produce a small amount of endogenous phytase. Microbial phytases have been incorporated into diets and has revealed the negative effect of phytates on the digestibility of amino acids (AA). In addition to phytates, NSPs are also indigestible and resistant to the digestion process in monogastric animals. The NSPs encapsulate also nutrients, which decrease AA and energy digestibility. It is important to know the mechanisms of action of phytase and xylanase in the degradation of antinutritional factors and improving the digestibility of AA, as well as apparent metabolizable energy content (AME). A meta-analysis approach allowed to establish models for predicting the digestibility of AA from dietary AA, phytase and NDF (Neutral Detergent Fiber) concentrations in pigs, and from dietary AA, phytase and phytic phosphorus (PP) concentrations in broilers. A predictive model of AA digestibility in broilers has also been established from xylanase supplementation and dietary NDF/NSP concentrations. Finally, xylanase activity, gross dietary energy (GE) and NDF/NSP concentrations were the best predictors of AME. The current models allow quantifying the effect of phytase on AA in pigs and broilers and the effect of xylanase on AA and AME in broilers, which is important to use these enzymes accurately in diet formulation.

S 405 UL 2018

Porcs -- Alimentation

Poulets -- Alimentation

Acides aminés -- Métabolisme

Digestion

Acide phytique

Polysaccharides

Xylanases

Clonagem e estudos de expressão de enzimas do fungo filamentoso Trichoderma harzianum IOC-3844 envolvidas na degradação de biomassa

Malagó Junior, Wilson

06 July 2012

Made available in DSpace on 2016-06-02T20:20:34Z (GMT). No. of bitstreams: 1 4606.pdf: 10556895 bytes, checksum: debf5633a053f88ca7dd4618edef9175 (MD5) Previous issue date: 2012-07-06 / Universidade Federal de Minas Gerais / The plant biomass is a large-scale available resource and one of its more important applications is the second-generation ethanol production. However, the enzyme cost is one of the biggest barriers for economically viable ethanol from biomass. Therefore, it is important to identify fungal strains that can produce high concentrations of plant biomass-degrading enzymes. The aim of this work was to clone, study the gene expression and characterize the plant biomass-degrading transcript set of the filamentous fungus Trichoderma harzianum IOC-3844. A total of 1,543 highquality reads from the Trichoderma harzianum IOC-3844 cellulose induced cDNA library were organized into 1,002 transcripts representing 167 contigs and 835 singlets. Of these 1,002 transcripts 646 had unknown functions and 356 showed associated functions. Among the transcripts with associated functions, we found 20 transcripts related to plant biomass deconstruction. The real time PCR analysis of Trichoderma harzianum IOC-3844 mycelia grown for 36 and 60 hours in cellulose, revealed that the levels of the following mRNAs were induced by at least 2,000-fold when compared to uninduced mycelia: cbh1, cbh2, egl1, egl2, egl3, egl7 and swo1. In some cases, the values were higher than 100,000-fold. Among the transcripts analyzed by real time PCR, cbh1, cbh2 and egl7 exhibited the highest expression levels. The Trichoderma harzianum IOC-3844 exhibited a repertoire with high expression of plant biomassdegrading transcripts. The enzymes EGIII and Xyn2 were recombinantly expressed in Pichia pastoris, showing good quality purification and good enzymatic activity. The heterologous expression assays made possible future studies aiming at the industrial application of the enzymes. Therefore, this strain showed potencial to produce biomassdegrading enzymes for second-generation ethanol production and to be a source of enzymes for the paper industry / A biomassa vegetal é um recurso disponível em larga escala e uma das suas mais imporantes aplicações é a produção de etanol de segunda geração. No entanto, o custo das enzimas é um dos maiores entraves para a produção economicamente viável deste etanol. Neste contexto, é importante encontrar organismos produtores de grandes quantidades de enzimas que degradam a biomassa. Os objetivos deste estudo foram clonar, estudar a expressão gênica e caracterizar o conjunto de enzimas que degradam a biomassa vegetal, do fungo filamentoso Trichoderma harzianum IOC-3844. Um total de 1.543 seqüências de boa qualidade, geradas a partir de uma biblioteca de cDNA do Trichoderma harzianum IOC-3844, induzido por celulose, foi organizado em 1.002 transcritos, sendo 167 representados por mais de uma seqüência e 835 representados por apenas uma seqüência. Destes transcritos, 356 tiveram função associada e 646 não tiveram. Com isso, entre os transcritos com função associada, foram listados 20 transcritos envolvidos com degradação de biomassa vegetal. Análises de PCR em tempo real do micélio de Trichoderma harzianum IOC-3844, crescido por 36 e 60 horas em celulose, mostraram níveis de mRNA mais de 2.000 vezes mais representados para os transcritos cbh1, cbh2, egl1, egl2, egl3, egl7 e swo1, quando comparados com o micélio não induzido. Em alguns casos as maiores representatividades alcançaram valores superiores a 100.000 vezes. Entre os transcritos analisados o cbh1, o cbh2 e o egl7, mostraram os mais altos níveis de expressão. O Trichoderma harzianum IOC-3844 exibiu um repertório com alta expressão de transcritos envolvidas na degradação de biomassa vegetal. As enzimas EGIII e Xyn2 foram expressas em sistema recombinante com uso da levedura Pichia pastoris, apresentando facilidade de purificação e boa atividade enzimática. Os ensaios de expressão heteróloga viabilizaram estudos posteriores que visam a aplicação industrial das enzimas. Assim, esta cepa mostrou potencial para produzir enzimas que degradam a biomassa para a produção de etanol de segunda geração, e para ser fonte de enzimas para a indústria de papel.

Fungos

Trichoderma harzianum

Celulase

Hemicelulase

Transcriptoma

Expressão heteróloga

Biblioteca de cDNA

Etanol de segunda geração

Biomassa

Trichoderma harzianum

Transcriptome

Cellulases

Hemicellulases

Xylanases

Biomass

cDNA library

Second-generation ethanol

Heterologous expression

CIENCIAS BIOLOGICAS::GENETICA