Metagenoma do microbioma do rúmen de ovinos e prospecção de genes degradadores de biomassa vegetal / Metagenome of the sheep rumen microbiome and prospection of plant biomass degrading genes

Kmit, Maria Carolina Pezzo

10 April 2018

O material lignocelulósico, presente na biomassa vegetal, representa uma importante fonte de energia, entretanto necessita da ação das enzimas lignocelulolíticas para sua degradação. A busca por novas enzimas que atuam na quebra da parede celular da planta em comunidades microbianas evoluídas naturalmente em um ambiente de degradação de biomassa como o rúmen oferece uma estratégia promissora para a prospecção de genes. Com isso, o projeto teve como objetivo a identificação de genes degradarores de biomassa vegetal em microrganismos do rúmen de ovinos usando a abordagem metagenômica. Para tanto, foram coletadas amostras da fase sólida do rúmen de 6 animais fistulados (Ovis aries) divididos em dois grupos e submetidos a duas dietas por 60 dias: tratamento controle e tratamento com dieta contendo bagaço de cana-de-açúcar. O DNA metagenômico total das amostras foi extraído e sequenciado na plataforma MiSeq Personal Sequencer (Illumina®). A análise dos dados para a anotação taxônomica e funcional foi realizada no software MG-RAST. A caracterização dos genes degradadores de biomassa vegetal foi feita na plataforma CLC Genomic Workbench v.5.5.1(CLC Bio, Denmark) e a anotação de 4,68 gigabases de dados foi feita no banco de dados CAZy. A análise taxonômica mostrou uma predominância do domínio Bacteria compondo mais de 96% de todas as amostras, sendo os filos mais abundantes Bacteroidetes, Firmicutes, seguido de Proteobacteria. Entre todos os filos anotados, cinco tiveram a abundância aumentada no tratamento com adição de bagaço de cana-de-açúcar na dieta, Firmicutes, Proteobacteria, Actinobacteria, Spirochaetes e Verrucomicrobia, e dois filos foram mais abundantes no tratamento controle, Bacteroidetes e Synergistetes. De modo geral, a análise de ordenação não mostrou correlação entre a composição do microbioma e o tipo de dieta, porém, na análise funcional, essa correlação foi observada uma vez que houve separação entre os tratamentos. A abundância relativa das famílias de enzimas relacionadas à degradação de carboidratos segue um padrão similar em todas as amostras metagenômicas. O módulo catalítico da família de Glycoside Hydrolases (GH), o qual foi anotado em 129 subfamílias diferentes, foi o mais abundante em todas as amostras (45,5%), seguido da família GT (Glicosyl Tranferase), anotada em 97 subfamílias diferentes e CBM (Carbohydrete-Bining Module), em 78 subfamílias. A montagem do metagenoma resultou em aproximadamente 110.000 contigs e possibilitou a identificação de 15 diferentes genes completos codificados nas subfamílias GH1, GH2, GH3, GH16, GH20, GH25, GH32, GH97 e GH127. A análise comparativa dos diferentes tratamentos mostrou uma maior abundância dessas enzimas no rúmen dos animais alimentados com a dieta enriquecida com bagaço de cana-de-açúcar. Em conclusão, a manipulação da dieta de ovinos por meio da substituição de parte da fração fibrosa da dieta por bagaço de cana-de-açúcar promove o enriquecimento de enzimas que degradam a biomassa vegetal no rúmem, favorecendo a prospecção e identificação de genes ativos em carboidratos. / The lignocellulose present in the plant biomass is a promising source of energy generation. However, the breakdown of plant biomass into simple sugars for bioethanol production is still inefficient and costly due to the recalcitrant nature of the plant fiber. The sheep rumen microbiome is specialized in degradation of plant material, but most members of this complex community are uncultured in the laboratory. Therefore, the search for new lignocellulolytic enzymes in microbial communities naturally evolved in biomass degradation environments, such as the rumen, using the exploration of the metagenome, is a promising strategy for identifying new genes. In this context, this study aimed to prospect plant biomass-degrading genes, selected from the sheep rumen microorganisms. The rumen samples were collected from 6 fistulated animals (Ovis aries), divided into two groups and subjected to two diets: control treatment and a treatment with a diet amended with sugarcane bagasse. The animals were fed for 60 days before sampling. To characterize the composition and functions of the rumen microbiome followed by the search of biomass-degrading genes, the metagenomic DNA was extracted from the solid contents of rumen and sequenced in MiSeq Personal Sequencer platform (Illumina®). The taxonomic and functional data were performed using MG-RAST software. For the characterization of the plant biomass degrading genes, they were analyzed on the CLC platform Genomic Workbench v.5.5.1 (CLC Bio, Denmark) and 4.68 gigabases of data was annotated against the CAZy database. The taxonomic analysis showed a predominance of the Bacteria domain composing more than 96% of all the samples, being the most abundant phyla Bacterioidetes, Firmiutes, followed by Proteobacteria. Five bacterial phyla were significantly more abundant in the treatment were sugarcane bagasse was added, Firmicutes, Proteobacteria, Actinobacteria, Spirochaetes and Verrucomicrobia, and two phyla were more abundant in the control treatment, Bacteroidetes and Synergistetes. In general, the ordination analysis did not show correlation between diet type and rumen microbiota, but in the functional analysis, this correlation was observed since there was separation between the treatments. The relative abundance of enzyme families related to carbohydrate degradation follows a similar pattern of abundance across all metagenomic samples. The catalytic module of the GH (Glycoside Hydrolases) family, which was annotated in 129 different subfamilies, was the most abundant in all samples (45.5%), followed by the GT family (Glycosyltransferase), annotated in 97 different subfamilies and CBM (Carbohydre-Bining Module) in 78 sub-families. Metagenome assembly resulted in ~110,000 contigs enabled the retrieval of 15 complete different genes encoded in the subfamilies GH1, GH2, GH3, GH16, GH20, GH25, GH32, GH97 and GH127. A comparative analysis between the groups of animals in the different treatments showed a greater abundance of enzymes, with no metagenome of the fiber proven from the group of animals fed a diet enriched with sugarcane bagasse. These results show the sheep rumen microbiome as an untapped source of potential new fibrolytic enzymes. Using a diet amended with sugarcane bagasse increases the abundance of CAE and provide a substantially expanded catalog of genes participating in the deconstruction of plant biomass.

Biotechnology

Biotecnologia

Carbohydrate-Active enzymes

Ecologia microbiana

Enzimas ativas em carboidrato

Enzimas lignogelulolíticas

Lignocellulolytic enzymes

Microbial ecology

Sequenciamento metagenômico

Shotgun metagenomics sequencing

Metagenoma do microbioma do rúmen de ovinos e prospecção de genes degradadores de biomassa vegetal / Metagenome of the sheep rumen microbiome and prospection of plant biomass degrading genes

Maria Carolina Pezzo Kmit

10 April 2018

O material lignocelulósico, presente na biomassa vegetal, representa uma importante fonte de energia, entretanto necessita da ação das enzimas lignocelulolíticas para sua degradação. A busca por novas enzimas que atuam na quebra da parede celular da planta em comunidades microbianas evoluídas naturalmente em um ambiente de degradação de biomassa como o rúmen oferece uma estratégia promissora para a prospecção de genes. Com isso, o projeto teve como objetivo a identificação de genes degradarores de biomassa vegetal em microrganismos do rúmen de ovinos usando a abordagem metagenômica. Para tanto, foram coletadas amostras da fase sólida do rúmen de 6 animais fistulados (Ovis aries) divididos em dois grupos e submetidos a duas dietas por 60 dias: tratamento controle e tratamento com dieta contendo bagaço de cana-de-açúcar. O DNA metagenômico total das amostras foi extraído e sequenciado na plataforma MiSeq Personal Sequencer (Illumina®). A análise dos dados para a anotação taxônomica e funcional foi realizada no software MG-RAST. A caracterização dos genes degradadores de biomassa vegetal foi feita na plataforma CLC Genomic Workbench v.5.5.1(CLC Bio, Denmark) e a anotação de 4,68 gigabases de dados foi feita no banco de dados CAZy. A análise taxonômica mostrou uma predominância do domínio Bacteria compondo mais de 96% de todas as amostras, sendo os filos mais abundantes Bacteroidetes, Firmicutes, seguido de Proteobacteria. Entre todos os filos anotados, cinco tiveram a abundância aumentada no tratamento com adição de bagaço de cana-de-açúcar na dieta, Firmicutes, Proteobacteria, Actinobacteria, Spirochaetes e Verrucomicrobia, e dois filos foram mais abundantes no tratamento controle, Bacteroidetes e Synergistetes. De modo geral, a análise de ordenação não mostrou correlação entre a composição do microbioma e o tipo de dieta, porém, na análise funcional, essa correlação foi observada uma vez que houve separação entre os tratamentos. A abundância relativa das famílias de enzimas relacionadas à degradação de carboidratos segue um padrão similar em todas as amostras metagenômicas. O módulo catalítico da família de Glycoside Hydrolases (GH), o qual foi anotado em 129 subfamílias diferentes, foi o mais abundante em todas as amostras (45,5%), seguido da família GT (Glicosyl Tranferase), anotada em 97 subfamílias diferentes e CBM (Carbohydrete-Bining Module), em 78 subfamílias. A montagem do metagenoma resultou em aproximadamente 110.000 contigs e possibilitou a identificação de 15 diferentes genes completos codificados nas subfamílias GH1, GH2, GH3, GH16, GH20, GH25, GH32, GH97 e GH127. A análise comparativa dos diferentes tratamentos mostrou uma maior abundância dessas enzimas no rúmen dos animais alimentados com a dieta enriquecida com bagaço de cana-de-açúcar. Em conclusão, a manipulação da dieta de ovinos por meio da substituição de parte da fração fibrosa da dieta por bagaço de cana-de-açúcar promove o enriquecimento de enzimas que degradam a biomassa vegetal no rúmem, favorecendo a prospecção e identificação de genes ativos em carboidratos. / The lignocellulose present in the plant biomass is a promising source of energy generation. However, the breakdown of plant biomass into simple sugars for bioethanol production is still inefficient and costly due to the recalcitrant nature of the plant fiber. The sheep rumen microbiome is specialized in degradation of plant material, but most members of this complex community are uncultured in the laboratory. Therefore, the search for new lignocellulolytic enzymes in microbial communities naturally evolved in biomass degradation environments, such as the rumen, using the exploration of the metagenome, is a promising strategy for identifying new genes. In this context, this study aimed to prospect plant biomass-degrading genes, selected from the sheep rumen microorganisms. The rumen samples were collected from 6 fistulated animals (Ovis aries), divided into two groups and subjected to two diets: control treatment and a treatment with a diet amended with sugarcane bagasse. The animals were fed for 60 days before sampling. To characterize the composition and functions of the rumen microbiome followed by the search of biomass-degrading genes, the metagenomic DNA was extracted from the solid contents of rumen and sequenced in MiSeq Personal Sequencer platform (Illumina®). The taxonomic and functional data were performed using MG-RAST software. For the characterization of the plant biomass degrading genes, they were analyzed on the CLC platform Genomic Workbench v.5.5.1 (CLC Bio, Denmark) and 4.68 gigabases of data was annotated against the CAZy database. The taxonomic analysis showed a predominance of the Bacteria domain composing more than 96% of all the samples, being the most abundant phyla Bacterioidetes, Firmiutes, followed by Proteobacteria. Five bacterial phyla were significantly more abundant in the treatment were sugarcane bagasse was added, Firmicutes, Proteobacteria, Actinobacteria, Spirochaetes and Verrucomicrobia, and two phyla were more abundant in the control treatment, Bacteroidetes and Synergistetes. In general, the ordination analysis did not show correlation between diet type and rumen microbiota, but in the functional analysis, this correlation was observed since there was separation between the treatments. The relative abundance of enzyme families related to carbohydrate degradation follows a similar pattern of abundance across all metagenomic samples. The catalytic module of the GH (Glycoside Hydrolases) family, which was annotated in 129 different subfamilies, was the most abundant in all samples (45.5%), followed by the GT family (Glycosyltransferase), annotated in 97 different subfamilies and CBM (Carbohydre-Bining Module) in 78 sub-families. Metagenome assembly resulted in ~110,000 contigs enabled the retrieval of 15 complete different genes encoded in the subfamilies GH1, GH2, GH3, GH16, GH20, GH25, GH32, GH97 and GH127. A comparative analysis between the groups of animals in the different treatments showed a greater abundance of enzymes, with no metagenome of the fiber proven from the group of animals fed a diet enriched with sugarcane bagasse. These results show the sheep rumen microbiome as an untapped source of potential new fibrolytic enzymes. Using a diet amended with sugarcane bagasse increases the abundance of CAE and provide a substantially expanded catalog of genes participating in the deconstruction of plant biomass.

Biotecnologia

Ecologia microbiana

Enzimas ativas em carboidrato

Enzimas lignogelulolíticas

Sequenciamento metagenômico

Biotechnology

Carbohydrate-Active enzymes

Lignocellulolytic enzymes

Microbial ecology

Shotgun metagenomics sequencing

Heterotrophic Protists as Useful Models for Studying Microbial Food Webs in a Model Soil Ecosystem and the Universality of Complex Unicellular Life

Thompson, Andrew Robert

01 July 2019

Heterotrophic protists, consisting largely of the Cercozoa, Amoebozoa, Ciliophora, Discoba and some Stramenopiles, are a poorly characterized component of life on Earth. They play an important ecological role in soil communities and provide key insights into the nature of one of life’s most enigmatic evolutionary transitions: the development of the complex unicell. Soil ecosystems are crucial to the functioning of global biogeochemical cycles (e.g. carbon and nitrogen) but are at risk of drastic change from anthropogenic climate change. Heterotrophic protists are the primary regulators of bacterial diversity in soils and as such play integral roles in biogeochemical cycling, nutrient mobilization, and trophic cascades in food webs under stress. Understanding the nature of these changes requires examining the rates, diversity, and resiliency of interactions that occur between soil organisms. However, soils are the most taxonomically diverse ecosystems on Earth and disentangling the complexities of dynamic and varied biotic interactions in them requires a unique model system. The McMurdo Dry Valleys of Antarctica, one of the harshest terrestrial environments on Earth, serve as a model soil ecosystem owing to their highly reduced biological diversity. Exploring the functioning of heterotrophic protists in these valleys provides a way to test the applicability of this model system to other soil food webs. However, very little is known about their taxonomic diversity, which is a strong predictor of function. Therefore, I reviewed the Antarctic literature to compile a checklist of all known terrestrial heterotrophic protists in Antarctica. I found significant geographical, methodological, and taxonomic biases and outlined how to address these in future research programs. I also conducted a molecular survey of whole soil communities using 18 shotgun metagenomes representing major landscape features of the McMurdo Dry Valleys. The results revealed the dominance of Cercozoa and point to an Antarctic heterotrophic protist soil community that is taxonomically diverse and reflects the structure and composition of communities at lower latitudes. To investigate whether biotic interactions or abiotic factors were a larger driver for Antarctic heterotrophic protists, I conducted variation partitioning using environmental data (e.g. moisture, pH and electrical conductivity). Biotic variables were more significant and accounted for more of the variation than environmental variables. Taken together, it is clear that heterotrophic protists play key ecological roles in this ecosystem. Deeper insights into the ecology of these organisms in the McMurdo Dry Valleys also have implications for the search for complex unicellular life in our universe. I discuss the theoretical underpinnings of searching for these forms of life outside of Earth, conclude that they are likely to occur, and postulate how future missions could practically search for complex unicells.

heterotrophic soil protists

McMurdo Dry Valleys

shotgun metagenomics

network analysis

life on Mars

key evolutionary innovations

universal complex unicellular life

Life Sciences

Microbiology