Your search keyword '"van Haren, Joost"' showing total 4 results

1. Chiral monoterpenes reveal forest emission mechanisms and drought responses

Author

Byron, Joseph, Kreuzwieser, Juergen, Purser, Gemma, van Haren, Joost, Ladd, S. Nemiah, Meredith, Laura K., Werner, Christiane, and Williams, Jonathan

Abstract

Monoterpenes (C10H16) are emitted in large quantities by vegetation to the atmosphere (>100 TgC year−1), where they readily react with hydroxyl radicals and ozone to form new particles and, hence, clouds, affecting the Earth’s radiative budget and, thereby, climate change1–3. Although most monoterpenes exist in two chiral mirror-image forms termed enantiomers, these (+) and (−) forms are rarely distinguished in measurement or modelling studies4–6. Therefore, the individual formation pathways of monoterpene enantiomers in plants and their ecological functions are poorly understood. Here we present enantiomerically separated atmospheric monoterpene and isoprene data from an enclosed tropical rainforest ecosystem in the absence of ultraviolet light and atmospheric oxidation chemistry, during a four-month controlled drought and rewetting experiment7. Surprisingly, the emitted enantiomers showed distinct diel emission peaks, which responded differently to progressive drying. Isotopic labelling established that vegetation emitted mainly de novo-synthesized (−)-α-pinene, whereas (+)-α-pinene was emitted from storage pools. As drought progressed, the source of (−)-α-pinene emissions shifted to storage pools, favouring cloud formation. Pre-drought mixing ratios of both α-pinene enantiomers correlated better with other monoterpenes than with each other, indicating different enzymatic controls. These results show that enantiomeric distribution is key to understanding the underlying processes driving monoterpene emissions from forest ecosystems and predicting atmospheric feedbacks in response to climate change.

Published

2022

2. Rainforest-to-pasture conversion stimulates soil methanogenesis across the Brazilian Amazon

Author

Kroeger, Marie E, Meredith, Laura K, Meyer, Kyle M, Webster, Kevin D, de Camargo, Plinio Barbosa, de Souza, Leandro Fonseca, Tsai, Siu Mui, van Haren, Joost, Saleska, Scott, Bohannan, Brendan J M, Rodrigues, Jorge L Mazza, Berenguer, Erika, Barlow, Jos, and Nüsslein, Klaus

Abstract

The Amazon rainforest is a biodiversity hotspot and large terrestrial carbon sink threatened by agricultural conversion. Rainforest-to-pasture conversion stimulates the release of methane, a potent greenhouse gas. The biotic methane cycle is driven by microorganisms; therefore, this study focused on active methane-cycling microorganisms and their functions across land-use types. We collected intact soil cores from three land use types (primary rainforest, pasture, and secondary rainforest) of two geographically distinct areas of the Brazilian Amazon (Santarém, Pará and Ariquemes, Rondônia) and performed DNA stable-isotope probing coupled with metagenomics to identify the active methanotrophs and methanogens. At both locations, we observed a significant change in the composition of the isotope-labeled methane-cycling microbial community across land use types, specifically an increase in the abundance and diversity of active methanogens in pastures. We conclude that a significant increase in the abundance and activity of methanogens in pasture soils could drive increased soil methane emissions. Furthermore, we found that secondary rainforests had decreased methanogenic activity similar to primary rainforests, and thus a potential to recover as methane sinks, making it conceivable for forest restoration to offset greenhouse gas emissions in the tropics. These findings are critical for informing land management practices and global tropical rainforest conservation.

Published

2021

3. Rainforest-to-pasture conversion stimulates soil methanogenesis across the Brazilian Amazon

Author

Kroeger, Marie E., Meredith, Laura K., Meyer, Kyle M., Webster, Kevin D., de Camargo, Plinio Barbosa, de Souza, Leandro Fonseca, Tsai, Siu Mui, van Haren, Joost, Saleska, Scott, Bohannan, Brendan J. M., Rodrigues, Jorge L. Mazza, Berenguer, Erika, Barlow, Jos, and Nüsslein, Klaus

Abstract

The Amazon rainforest is a biodiversity hotspot and large terrestrial carbon sink threatened by agricultural conversion. Rainforest-to-pasture conversion stimulates the release of methane, a potent greenhouse gas. The biotic methane cycle is driven by microorganisms; therefore, this study focused on active methane-cycling microorganisms and their functions across land-use types. We collected intact soil cores from three land use types (primary rainforest, pasture, and secondary rainforest) of two geographically distinct areas of the Brazilian Amazon (Santarém, Pará and Ariquemes, Rondônia) and performed DNA stable-isotope probing coupled with metagenomics to identify the active methanotrophs and methanogens. At both locations, we observed a significant change in the composition of the isotope-labeled methane-cycling microbial community across land use types, specifically an increase in the abundance and diversity of active methanogens in pastures. We conclude that a significant increase in the abundance and activity of methanogens in pasture soils could drive increased soil methane emissions. Furthermore, we found that secondary rainforests had decreased methanogenic activity similar to primary rainforests, and thus a potential to recover as methane sinks, making it conceivable for forest restoration to offset greenhouse gas emissions in the tropics. These findings are critical for informing land management practices and global tropical rainforest conservation.

Published

2021

4. Floral CO2 emission may indicate food abundance to nectar-feeding moths

Author

Guerenstein, Pablo G., A.Yepez, Enrico, van Haren, Joost, Williams, David G., and Hildebrand, John G.

Abstract

Abstract As part of a study of the roles of the sensory subsystem devoted to CO2 in the nectar-feeding moth Manduca sexta, we investigated CO2 release and nectar secretion by flowers of Datura wrightii, a preferred hostplant of Manduca. Datura flowers open at dusk and wilt by the following noon. During the first hours after dusk, when Manduca feeds, the flowers produce considerable amounts of nectar and emit levels of CO2 that should be detectable by moths nearby. By midnight, however, both nectar secretion and CO2 release decrease significantly. Because nectar production requires high metabolic activity, high floral CO2 emission may indicate food abundance to the moths. We suggest that hovering moths could use the florally emitted CO2 to help them assess the nectar content before attempting to feed in order to improve their foraging efficiency.

Published

2004