Your search keyword '"Zampieri, Guido"' showing total 3 results

1. A unified compendium of prokaryotic and viral genomes from over 300 anaerobic digestion microbiomes

Author

Centurion, Victor Borin, Rossi, Alessandro, Orellana, Esteban, Ghiotto, Gabriele, Kakuk, Balázs, Morlino, Maria Silvia, Basile, Arianna, Zampieri, Guido, Treu, Laura, and Campanaro, Stefano

Published

2024

2. Integrating metagenomic binning with flux balance analysis to unravel syntrophies in anaerobic CO2 methanation.

Author

De Bernardini, Nicola, Basile, Arianna, Zampieri, Guido, Kovalovszki, Adam, De Diego Diaz, Beatrix, Offer, Elisabetta, Wongfaed, Nantharat, Angelidaki, Irini, Kougias, Panagiotis G., Campanaro, Stefano, and Treu, Laura

Subjects

METHANATION, BIOGAS, METAGENOMICS, CARBON fixation, CIRCULAR economy, BIOLOGICAL systems, ANAEROBIC reactors

Abstract

Background: Carbon fixation through biological methanation has emerged as a promising technology to produce renewable energy in the context of the circular economy. The anaerobic digestion microbiome is the fundamental biological system operating biogas upgrading and is paramount in power-to-gas conversion. Carbon dioxide (CO2) methanation is frequently performed by microbiota attached to solid supports generating biofilms. Despite the apparent simplicity of the microbial community involved in biogas upgrading, the dynamics behind most of the interspecies interaction remain obscure. To understand the role of the microbial species in CO2 fixation, the biofilm generated during the biogas upgrading process has been selected as a case study. The present work investigates via genome-centric metagenomics, based on a hybrid Nanopore-Illumina approach the biofilm developed on the diffusion devices of four ex situ biogas upgrading reactors. Moreover, genome-guided metabolic reconstruction and flux balance analysis were used to propose a biological role for the dominant microbes. Results: The combined microbiome was composed of 59 species, with five being dominant (> 70% of total abundance); the metagenome-assembled genomes representing these species were refined to reach a high level of completeness. Genome-guided metabolic analysis appointed Firmicutes sp. GSMM966 as the main responsible for biofilm formation. Additionally, species interactions were investigated considering their co-occurrence in 134 samples, and in terms of metabolic exchanges through flux balance simulation in a simplified medium. Some of the most abundant species (e.g., Limnochordia sp. GSMM975) were widespread (~ 67% of tested experiments), while others (e.g., Methanothermobacter wolfeii GSMM957) had a scattered distribution. Genome-scale metabolic models of the microbial community were built with boundary conditions taken from the biochemical data and showed the presence of a flexible interaction network mainly based on hydrogen and carbon dioxide uptake and formate exchange. Conclusions: Our work investigated the interplay between five dominant species within the biofilm and showed their importance in a large spectrum of anaerobic biogas reactor samples. Flux balance analysis provided a deeper insight into the potential syntrophic interaction between species, especially Limnochordia sp. GSMM975 and Methanothermobacter wolfeii GSMM957. Finally, it suggested species interactions to be based on formate and amino acids exchanges. AQaLxbUWFz91qWxiAB1_X5 Video Abstract [ABSTRACT FROM AUTHOR]

Published

2022

3. Strain-resolved metagenomics approaches applied to biogas upgrading.

Author

Ghiotto, Gabriele, Zampieri, Guido, Campanaro, Stefano, and Treu, Laura

Subjects

*SINGLE nucleotide polymorphisms, *BIOGAS, *CARBON dioxide fixation, *ANAEROBIC reactors, *GENETIC variation, *GENOMES

Abstract

Genetic heterogeneity is a common trait in microbial populations, caused by de novo mutations and changes in variant frequencies over time. Microbes can thus differ genetically within the same species and acquire different phenotypes. For instance, performance and stability of anaerobic reactors are linked to the composition of the microbiome involved in the digestion process and to the environmental parameters imposing selective pressure on the metagenome, shaping its evolution. Changes at the strain level have the potential to determine variations in microbial functions, and their characterization could provide new insight into ecological and evolutionary processes driving anaerobic digestion. In this work, single nucleotide variant dynamics were studied in two time-course biogas upgrading experiments, testing alternative carbon sources and the response to exogenous hydrogen addition. A cumulative total of 76,229 and 64,289 high-confidence single nucleotide variants were discerned in the experiments related to carbon substrate availability and hydrogen addition, respectively. By combining complementary bioinformatic approaches, the study reconstructed the precise strain count—two for both hydrogenotrophic archaea—and tracked their abundance over time, while also characterizing tens of genes under strong selection. Results in the dominant archaea revealed the presence of nearly 100 variants within genes encoding enzymes involved in hydrogenotrophic methanogenesis. In the bacterial counterparts, 119 mutations were identified across 23 genes associated with the Wood-Ljungdahl pathway, suggesting a possible impact on the syntrophic acetate-oxidation process. Strain replacement events took place in both experiments, confirming the trends suggested by the variants trajectories and providing a comprehensive understanding of the biogas upgrading microbiome at the strain level. Overall, this resolution level allowed us to reveal fine-scale evolutionary mechanisms, functional dynamics, and strain-level metabolic variation that could contribute to the selection of key species actively involved in the carbon dioxide fixation process. [Display omitted] • This is the first use of strain-resolved metagenomics in in-situ biogas upgrading. • A total of 97 high-quality metagenome assembled genomes were reconstructed. • The variants calling approach retrieved 140,518 variants in high abundance genomes. • Two strains were found in M. wolfeii and M. thermophilus at distinct time points. • Eight hydrogenotrophic methanogenesis genes were under selective pressure. [ABSTRACT FROM AUTHOR]

Published

2024