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24 results on '"Schindlbacher, Andreas"'

1. Kapitel 2. Auswirkungen der Landnutzung und -bewirtschaftung sowie naturnaher Ökosysteme auf den Klimawandel: Biophysikalische Effekte, Treibhausgasemissionen und Kohlenstoffspeicher

Author

Anderl, Michael, Bruckner, Martin, Díaz-Pinés, Eugenio, Gingrich, Simone, Hörtenhuber, Stefan, Kitzler, Barbara, Schindlbacher, Andreas, Schöner, Wolfgang, Weiss, Peter, Wenzel, Walter, Jandl, Robert, editor, Tappeiner, Ulrike, editor, Foldal, Cecilie Birgitte, editor, and Erb, Karlheinz, editor

Published
2024
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6. Long‐term soil warming changes the profile of primary metabolites in fine roots of Norway spruce in a temperate montane forest.

Author

Liu, Xiaofei, Heinzle, Jakob, Tian, Ye, Salas, Erika, Kwatcho Kengdo, Steve, Borken, Werner, Schindlbacher, Andreas, and Wanek, Wolfgang

Subjects
GLOBAL warming, SOIL heating, MOUNTAIN forests, TEMPERATE forests, OLD growth forests, ORGANIC acids
Abstract

Climate warming poses major threats to temperate forests, but the response of tree root metabolism has largely remained unclear. We examined the impact of long‐term soil warming (>14 years, +4°C) on the fine root metabolome across three seasons for 2 years in an old spruce forest, using a liquid chromatography‐mass spectrometry platform for primary metabolite analysis. A total of 44 primary metabolites were identified in roots (19 amino acids, 12 organic acids and 13 sugars). Warming increased the concentration of total amino acids and of total sugars by 15% and 21%, respectively, but not organic acids. We found that soil warming and sampling date, along with their interaction, directly influenced the primary metabolite profiles. Specifically, in warming plots, concentrations of arginine, glycine, lysine, threonine, tryptophan, mannose, ribose, fructose, glucose and oxaloacetic acid increased by 51.4%, 19.9%, 21.5%, 19.3%, 22.1%, 23.0%, 38.0%, 40.7%, 19.8% and 16.7%, respectively. Rather than being driven by single compounds, changes in metabolite profiles reflected a general up‐ or downregulation of most metabolic pathway network. This emphasises the importance of metabolomics approaches in investigating root metabolic pathways and understanding the effects of climate change on tree root metabolism. Summary statement: Soil warming increases the content of amino acids and sugars in mature Norway spruce (Picea abies) fine roots, but not of organic acids. Moreover, we found that the changes in metabolite profiles were not driven by individual compounds but by a general up‐ or downregulation of most primary metabolites. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Long‐term soil warming decreases soil microbial necromass carbon by adversely affecting its production and decomposition.

Author

Liu, Xiaofei, Tian, Ye, Heinzle, Jakob, Salas, Erika, Kwatcho‐Kengdo, Steve, Borken, Werner, Schindlbacher, Andreas, and Wanek, Wolfgang

Subjects
SOIL heating, TEMPERATE forest ecology, GLOBAL warming, EXTRACELLULAR enzymes, TEMPERATE forests, TUNDRAS
Abstract

Microbial necromass carbon (MNC) accounts for a large fraction of soil organic carbon (SOC) in terrestrial ecosystems. Yet our understanding of the fate of this large carbon pool under long‐term warming is uncertain. Here, we show that 14 years of soil warming (+4°C) in a temperate forest resulted in a reduction in MNC by 11% (0–10 cm) and 33% (10–20 cm). Warming caused a decrease in the content of MNC due to a decline in microbial biomass carbon and reduced microbial carbon use efficiency. This reduction was primarily caused by warming‐induced limitations in available soil phosphorus, which, in turn, constrained the production of microbial biomass. Conversely, warming increased the activity of soil extracellular enzymes, specifically N‐acetylglucosaminidase and leucine aminopeptidase, which accelerated the decomposition of MNC. These findings collectively demonstrate that decoupling of MNC formation and decomposition underlie the observed MNC loss under climate warming, which could affect SOC content in temperate forest ecosystems more widespread. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Does long-term soil warming affect microbial element limitation? A test by short-term assays of microbial growth responses to labile C, N and P additions

Author

Shi, Chupei, Urbina‐Malo, Carolina, Tian, Ye, Heinzle, Jakob, Kwatcho Kengdo, Steve, Inselsbacher, Erich, Borken, Werner, Schindlbacher, Andreas, Wanek, Wolfgang, Shi, Chupei, Urbina‐Malo, Carolina, Tian, Ye, Heinzle, Jakob, Kwatcho Kengdo, Steve, Inselsbacher, Erich, Borken, Werner, Schindlbacher, Andreas, and Wanek, Wolfgang

Abstract

Increasing global temperatures have been reported to accelerate soil carbon (C) cycling, but also to promote nitrogen (N) and phosphorus (P) dynamics in terrestrial ecosystems. However, warming can differentially affect ecosystem C, N and P dynamics, potentially intensifying elemental imbalances between soil resources, plants and soil microorganisms. Here, we investigated the effect of long-term soil warming on microbial resource limitation, based on measurements of microbial growth (18O incorporation into DNA) and respiration after C, N and P amendments. Soil samples were taken from two soil depths (0–10, 10–20 cm) in control and warmed (>14 years warming, +4°C) plots in the Achenkirch soil warming experiment. Soils were amended with combinations of glucose-C, inorganic/organic N and inorganic/organic P in a full factorial design, followed by incubation at their respective mean field temperatures for 24 h. Soil microbes were generally C-limited, exhibiting 1.8-fold to 8.8-fold increases in microbial growth upon C addition. Warming consistently caused soil microorganisms to shift from being predominately C limited to become C-P co-limited. This P limitation possibly was due to increased abiotic P immobilization in warmed soils. Microbes further showed stronger growth stimulation under combined glucose and inorganic nutrient amendments compared to organic nutrient additions. This may be related to a prolonged lag phase in organic N (glucosamine) mineralization and utilization compared to glucose. Soil respiration strongly positively responded to all kinds of glucose-C amendments, while responses of microbial growth were less pronounced in many of these treatments. This highlights that respiration–though easy and cheap to measure—is not a good substitute of growth when assessing microbial element limitation. Overall, we demonstrate a significant shift in microbial element limitation in warmed soils, from C to C-P co-limitation, with strong repercussions on the linkage

Published
2023

21. Effects of long-term soil warming on soil organic and inorganic nitrogen cycling in a temperate forest soil as assessed by measurements of natural 15N abundances of soil N pools

Author

Wanek, Wolfgang, primary, Bachmann, Michaela, additional, Inselsbacher, Erich, additional, Heinzle, Jakob, additional, Tian, Ye, additional, Kwatcho-Kengdo, Steve, additional, Shi, Chupei, additional, Borken, Werner, additional, and Schindlbacher, Andreas, additional

Published
2022
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24. Long‐term soil warming alters fine root dynamics and morphology, and their ectomycorrhizal fungal community in a temperate forest soil.

Author

Kwatcho Kengdo, Steve, Peršoh, Derek, Schindlbacher, Andreas, Heinzle, Jakob, Tian, Ye, Wanek, Wolfgang, and Borken, Werner

Subjects
SOIL heating, TEMPERATE forests, FOREST soils, FUNGAL communities, COMMUNITY forests, SOIL composition, SOIL depth
Abstract

Climate warming is predicted to affect temperate forests severely, but the response of fine roots, key to plant nutrition, water uptake, soil carbon, and nutrient cycling is unclear. Understanding how fine roots will respond to increasing temperature is a prerequisite for predicting the functioning of forests in a warmer climate. We studied the response of fine roots and their ectomycorrhizal (EcM) fungal and root‐associated bacterial communities to soil warming by 4°C in a mixed spruce‐beech forest in the Austrian Limestone Alps after 8 and 14 years of soil warming, respectively. Fine root biomass (FRB) and fine root production were 17% and 128% higher in the warmed plots, respectively, after 14 years. The increase in FRB (13%) was not significant after 8 years of treatment, whereas specific root length, specific root area, and root tip density were significantly higher in warmed plots at both sampling occasions. Soil warming did not affect EcM exploration types and diversity, but changed their community composition, with an increase in the relative abundance of Cenoccocum at 0–10 cm soil depth, a drought‐stress‐tolerant genus, and an increase in short‐ and long‐distance exploration types like Sebacina and Boletus at 10–20 cm soil depth. Warming increased the root‐associated bacterial diversity but did not affect their community composition. Soil warming did not affect nutrient concentrations of fine roots, though we found indications of limited soil phosphorus (P) and potassium (K) availability. Our findings suggest that, in the studied ecosystem, global warming could persistently increase soil carbon inputs due to accelerated fine root growth and turnover, and could simultaneously alter fine root morphology and EcM fungal community composition toward improved nutrient foraging. [ABSTRACT FROM AUTHOR]

Published
2022
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