Your search keyword '"Tangherlini, Michael"' showing total 4 results

1. Metabolic Adaptations to Marine Environments: Molecular Diversity and Evolution of Ovothiol Biosynthesis in Bacteria.

Author

Brancaccio M, Tangherlini M, Danovaro R, and Castellano I

Subjects

Aquatic Organisms, Evolution, Molecular, Gene Transfer, Horizontal, Bacteria genetics, Bacteria metabolism, Methylhistidines chemistry, Methylhistidines metabolism

Abstract

Ovothiols are sulfur-containing amino acids synthesized by marine invertebrates, protozoans, and bacteria. They act as pleiotropic molecules in signaling and protection against oxidative stress. The discovery of ovothiol biosynthetic enzymes, sulfoxide synthase OvoA and β-lyase OvoB, paves the way for a systematic investigation of ovothiol distribution and molecular diversification in nature. In this work, we conducted genomic and metagenomics data mining to investigate the distribution and diversification of ovothiol biosynthetic enzymes in Bacteria. We identified the bacteria endowed with this secondary metabolic pathway, described their taxonomy, habitat and biotic interactions in order to provide insight into their adaptation to specific environments. We report that OvoA and OvoB are mostly encountered in marine aerobic Proteobacteria, some of them establishing symbiotic or parasitic relationships with other organisms. We identified a horizontal gene transfer event of OvoB from Bacteroidetes living in symbiosis with Hydrozoa. Our search within the Ocean Gene Atlas revealed the occurrence of ovothiol biosynthetic genes in Proteobacteria living in a wide range of pelagic and highly oxygenated environments. Finally, we tracked the evolutionary history of ovothiol biosynthesis from marine bacteria to unicellular eukaryotes and metazoans. Our analysis provides new conceptual elements to unravel the evolutionary and ecological significance of ovothiol biosynthesis., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2021

2. High potential for temperate viruses to drive carbon cycling in chemoautotrophy-dominated shallow-water hydrothermal vents.

Author

Rastelli E, Corinaldesi C, Dell'Anno A, Tangherlini M, Martorelli E, Ingrassia M, Chiocci FL, Lo Martire M, and Danovaro R

Subjects

Carbon, Carbon Cycle, Ecosystem, Mediterranean Sea, Water Microbiology, Bacteria virology, Chemoautotrophic Growth physiology, Geologic Sediments virology, Hydrothermal Vents microbiology, Seawater microbiology

Abstract

Viruses are the most abundant life forms in the world's oceans and they are key drivers of biogeochemical cycles, but their impact on the microbial assemblages inhabiting hydrothermal vent ecosystems is still largely unknown. Here, we analysed the viral life strategies and virus-host interactions in the sediments of a newly discovered shallow-water hydrothermal field of the Mediterranean Sea. Our study reveals that temperate viruses, once experimentally induced to replicate, can cause large mortality of vent microbes, significantly reducing the chemoautotrophic carbon production, while enhancing the metabolism of microbial heterotrophs and the re-cycling of the organic matter. These results provide new insights on the factors controlling primary and secondary production processes in hydrothermal vents, suggesting that the inducible provirus-host interactions occurring in these systems can profoundly influence the functioning of the microbial food web and the efficiency in the energy transfer to the higher trophic levels., (© 2017 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2017

3. Drivers of Bacterial α- and β-Diversity Patterns and Functioning in Subsurface Hadal Sediments.

Author

Rastelli, Eugenio, Corinaldesi, Cinzia, Dell'Anno, Antonio, Tangherlini, Michael, Lo Martire, Marco, Nishizawa, Manabu, Nomaki, Hidetaka, Nunoura, Takuro, and Danovaro, Roberto

Subjects

SEDIMENTS, SUBMARINE trenches, ELECTRON donors, BACTERIAL diversity, WATER depth

Abstract

Oceanic trenches at hadal (>6,000 m) depths are hot spots of organic matter deposition and mineralization and can host abundant and active bacterial assemblages. However, the factors able to shape their biodiversity and functioning remain largely unexplored, especially in subsurface sediments. Here, we investigated the patterns and drivers of benthic bacterial α- and β-diversity (i.e., OTU richness and turnover diversity) along the vertical profile down to 1.5 m sediment depth in the Izu-Bonin Trench (at ~10,000 m water depth). The protease and glucosidase enzymatic activity rates were also determined, as a proxy of organic matter degradation potential in the different sediment layers. Molecular fingerprinting based on automated ribosomal intergenic spacer analysis (ARISA) indicated that the α-diversity of bacterial assemblages remained high throughout the vertical profile and that the turnover (β-) diversity among sediment horizons reached values up to 90% of dissimilarity. Multivariate distance-based linear modeling (DISTLM) pointed out that the diversity and functioning of the hadal bacterial assemblages were influenced by the variability of environmental conditions (including the availability of organic resources and electron donors/acceptors) and of viral production rates along the sediment vertical profile. Based on our results, we can argue that the heterogeneity of physical-chemical features of the hadal sediments of the Izu-Bonin Trench contribute to increase the niches availability for different bacterial taxa, while viruses contribute to maintain high levels of bacterial turnover diversity and to enhance organic matter cycling in these extremely remote and isolated ecosystems. [ABSTRACT FROM AUTHOR]

Published

2019

4. Metabolic Adaptations to Marine Environments: Molecular Diversity and Evolution of Ovothiol Biosynthesis in Bacteria

Author

Michael Tangherlini, Mariarita Brancaccio, Immacolata Castellano, Roberto Danovaro, Brancaccio, Mariarita, Tangherlini, Michael, Danovaro, Roberto, and Castellano, Immacolata

Subjects

AcademicSubjects/SCI01140, Aquatic Organisms, marine environment, Gene Transfer, Horizontal, enzyme evolution, ovothiol, natural products, 010402 general chemistry, 01 natural sciences, Evolution, Molecular, 03 medical and health sciences, Marine bacteriophage, Genetics, 14. Life underwater, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Bacteria, biology, AcademicSubjects/SCI01130, Bacteroidetes, Marine invertebrates, Methylhistidines, biology.organism_classification, 0104 chemical sciences, Metabolic pathway, Evolutionary biology, Metagenomics, Horizontal gene transfer, enzyme evolution, ovothiol, bacteria, marine environment, secondary metabolic pathways, natural products, Adaptation, Proteobacteria, secondary metabolic pathways, Research Article

Abstract

Ovothiols are sulfur-containing amino acids synthesized by marine invertebrates, protozoans, and bacteria. They act as pleiotropic molecules in signaling and protection against oxidative stress. The discovery of ovothiol biosynthetic enzymes, sulfoxide synthase OvoA and β-lyase OvoB, paves the way for a systematic investigation of ovothiol distribution and molecular diversification in nature. In this work, we conducted genomic and metagenomics data mining to investigate the distribution and diversification of ovothiol biosynthetic enzymes in Bacteria. We identified the bacteria endowed with this secondary metabolic pathway, described their taxonomy, habitat and biotic interactions in order to provide insight into their adaptation to specific environments. We report that OvoA and OvoB are mostly encountered in marine aerobic Proteobacteria, some of them establishing symbiotic or parasitic relationships with other organisms. We identified a horizontal gene transfer event of OvoB from Bacteroidetes living in symbiosis with Hydrozoa. Our search within the Ocean Gene Atlas revealed the occurrence of ovothiol biosynthetic genes in Proteobacteria living in a wide range of pelagic and highly oxygenated environments. Finally, we tracked the evolutionary history of ovothiol biosynthesis from marine bacteria to unicellular eukaryotes and metazoans. Our analysis provides new conceptual elements to unravel the evolutionary and ecological significance of ovothiol biosynthesis.

Published

2021