Your search keyword '"Tsai, Siu M."' showing total 5 results

1. Methane-cycling microbial communities from Amazon floodplains and upland forests respond differently to simulated climate change scenarios

Author

Gontijo, Júlia B., Paula, Fabiana S., Bieluczyk, Wanderlei, França, Aline G., Navroski, Deisi, Mandro, Jéssica A., Venturini, Andressa M., Asselta, Fernanda O., Mendes, Lucas W., Moura, José M. S., Moreira, Marcelo Z., Nüsslein, Klaus, Bohannan, Brendan J. M., Bodelier, Paul L. E., Rodrigues, Jorge L. Mazza, and Tsai, Siu M.

Published

2024

2. Increased soil moisture intensifies the impacts of forest-to-pasture conversion on methane emissions and methane-cycling communities in the Eastern Amazon

Author

Venturini, Andressa M, Dias, Naissa MS, Gontijo, Júlia B, Yoshiura, Caio A, Paula, Fabiana S, Meyer, Kyle M, Nakamura, Fernanda M, da França, Aline G, Borges, Clovis D, Barlow, Jos, Berenguer, Erika, Nüsslein, Klaus, Rodrigues, Jorge LM, Bohannan, Brendan JM, and Tsai, Siu M

Subjects

Life on Land, Climate Action, Climate, Forests, Methane, Soil, Soil Microbiology, Land-use change, Climate change, Microbial ecology, Methanogens, Methanotrophs, Metagenomics, Chemical Sciences, Environmental Sciences, Biological Sciences, Toxicology

Abstract

Climatic changes are altering precipitation patterns in the Amazon and may influence soil methane (CH4) fluxes due to the differential responses of methanogenic and methanotrophic microorganisms. However, it remains unclear if these climate feedbacks can amplify land-use-related impacts on the CH4 cycle. To better predict the responses of soil CH4-cycling microorganisms and emissions under altered moisture levels in the Eastern Brazilian Amazon, we performed a 30-day microcosm experiment manipulating the moisture content (original moisture; 60%, 80%, and 100% of field capacity - FC) of forest and pasture soils. Gas samples were collected periodically for gas chromatography analysis, and methanogenic archaeal and methanotrophic bacterial communities were assessed using quantitative PCR and metagenomics. Positive and negative daily CH4 fluxes were observed for forest and pasture, indicating that these soils can act as both CH4 sources and sinks. Cumulative emissions and the abundance of methanogenesis-related genes and taxonomic groups were affected by land use, moisture, and their interaction. Pasture soils at 100% FC had the highest abundance of methanogens and CH4 emissions, 22 times higher than forest soils under the same treatment. Higher ratios of methanogens to methanotrophs were found in pasture than in forest soils, even at field capacity conditions. Land use and moisture were significant factors influencing the composition of methanogenic and methanotrophic communities. The diversity and evenness of methanogens did not change throughout the experiment. In contrast, methanotrophs exhibited the highest diversity and evenness in pasture soils at 100% FC. Taken together, our results suggest that increased moisture exacerbates soil CH4 emissions and microbial responses driven by land-use change in the Amazon. This is the first report on the microbial CH4 cycle in Amazonian upland soils that combined one-month gas measurements with advanced molecular methods.

Published

2022

3. Not just a methane source: Amazonian floodplain sediments harbour a high diversity of methanotrophs with different metabolic capabilities

Author

Gontijo, Júlia B, Paula, Fabiana S, Venturini, Andressa M, Yoshiura, Caio A, Borges, Clovis D, Moura, José Mauro S, Bohannan, Brendan JM, Nüsslein, Klaus, Rodrigues, Jorge L Mazza, and Tsai, Siu M

Subjects

Microbiology, Biological Sciences, Archaea, Brazil, Euryarchaeota, Methane, RNA, Ribosomal, 16S, Soil Microbiology, 16S rRNA sequencing, methanogens, methanotrophs, quantitative PCR, tropical wetlands, Evolutionary Biology, Biological sciences

Abstract

The Amazonian floodplain forests are dynamic ecosystems of great importance for the regional hydrological and biogeochemical cycles and function as a significant CH4 source contributing to the global carbon balance. Unique geochemical factors may drive the microbial community composition and, consequently, affect CH4 emissions across floodplain areas. Here, we report the in situ composition of CH4 cycling microbial communities in Amazonian floodplain sediments. We considered how abiotic factors may affect the microbial community composition and, more specifically, CH4 cycling groups. We collected sediment samples during wet and dry seasons from three different types of floodplain forests, along with upland forest soil samples, from the Eastern Amazon, Brazil. We used high-resolution sequencing of archaeal and bacterial 16S rRNA genes combined with real-time PCR to quantify Archaea and Bacteria, as well as key functional genes indicative of the presence of methanogenic (mcrA) and methanotrophic (pmoA) microorganisms. Methanogens were found to be present in high abundance in floodplain sediments, and they seem to resist the dramatic environmental changes between flooded and nonflooded conditions. Methanotrophs known to use different pathways to oxidise CH4 were detected, including anaerobic archaeal and bacterial taxa, indicating that a wide metabolic diversity may be harboured in this highly variable environment. The floodplain environmental variability, which is affected by the river origin, drives not only the sediment chemistry but also the composition of the microbial communities. These environmental changes seem also to affect the pools of methanotrophs occupying distinct niches. Understanding these shifts in the methanotrophic communities could improve our comprehension of the CH4 emissions in the region.

Published

2021

4. Insights into the Genomic Potential of a Methylocystis sp. from Amazonian Floodplain Sediments.

Author

Gontijo, Júlia B., Paula, Fabiana S., Venturini, Andressa M., Mandro, Jéssica A., Bodelier, Paul L. E., and Tsai, Siu M.

Abstract

Although floodplains are recognized as important sources of methane (CH4) in the Amazon basin, little is known about the role of methanotrophs in mitigating CH4 emissions in these ecosystems. Our previous data reported the genus Methylocystis as one of the most abundant methanotrophs in these floodplain sediments. However, information on the functional potential and life strategies of these organisms living under seasonal flooding is still missing. Here, we described the first metagenome-assembled genome (MAG) of a Methylocystis sp. recovered from Amazonian floodplains sediments, and we explored its functional potential and ecological traits through phylogenomic, functional annotation, and pan-genomic approaches. Both phylogenomics and pan-genomics identified the closest placement of the bin.170_fp as Methylocystis parvus. As expected for Type II methanotrophs, the Core cluster from the pan-genome comprised genes for CH4 oxidation and formaldehyde assimilation through the serine pathway. Furthermore, the complete set of genes related to nitrogen fixation is also present in the Core. Interestingly, the MAG singleton cluster revealed the presence of unique genes related to nitrogen metabolism and cell motility. The study sheds light on the genomic characteristics of a dominant, but as yet unexplored methanotroph from the Amazonian floodplains. By exploring the genomic potential related to resource utilization and motility capability, we expanded our knowledge on the niche breadth of these dominant methanotrophs in the Amazonian floodplains. [ABSTRACT FROM AUTHOR]

Published

2022

5. Oxidative mitigation of aquatic methane emissions in large Amazonian rivers.

Author

Sawakuchi, Henrique O., Bastviken, David, Sawakuchi, André O., Ward, Nicholas D., Borges, Clovis D., Tsai, Siu M., Richey, Jeffrey E., Ballester, Maria Victoria R., and Krusche, Alex V.

Subjects

ATMOSPHERIC methane, OXIDATION, EMISSION exposure, GREENHOUSE gases, METHANOTROPHS

Abstract

The flux of methane ( CH4) from inland waters to the atmosphere has a profound impact on global atmospheric greenhouse gas ( GHG) levels, and yet, strikingly little is known about the dynamics controlling sources and sinks of CH4 in the aquatic setting. Here, we examine the cycling and flux of CH4 in six large rivers in the Amazon basin, including the Amazon River. Based on stable isotopic mass balances of CH4, inputs and outputs to the water column were estimated. We determined that ecosystem methane oxidation ( MOX) reduced the diffusive flux of CH4 by approximately 28-96% and varied depending on hydrologic regime and general geochemical characteristics of tributaries of the Amazon River. For example, the relative amount of MOX was maximal during high water in black and white water rivers and minimal in clear water rivers during low water. The abundance of genetic markers for methane-oxidizing bacteria ( pmoA) was positively correlated with enhanced signals of oxidation, providing independent support for the detected MOX patterns. The results indicate that MOX in large Amazonian rivers can consume from 0.45 to 2.07 Tg CH4 yr−1, representing up to 7% of the estimated global soil sink. Nevertheless, climate change and changes in hydrology, for example, due to construction of dams, can alter this balance, influencing CH4 emissions to atmosphere. [ABSTRACT FROM AUTHOR]

Published

2016