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2. Considering Forest and Grassland Carbon in Land Management

Author

Janowiak, M., primary, Connelly, W.J., additional, Dante-Wood, K., additional, Domke, G.M., additional, Giardina, C., additional, Kayler, Z., additional, Marcinkowski, K., additional, Ontl, T., additional, Rodriguez-Franco, C., additional, Swanston, C., additional, Woodall, C.W., additional, and Buford, M., additional

Published
2017
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3. On the contributions of photorespiration and compartmentation to the contrasting intramolecular2H profiles of C3and C4plant sugars

Author

Zhou, Y., Zhang, B., Stuart-Williams, H., Grice, Kliti, Hocart, C., Gessler, A., Kayler, Z., Farquhar, G., Zhou, Y., Zhang, B., Stuart-Williams, H., Grice, Kliti, Hocart, C., Gessler, A., Kayler, Z., and Farquhar, G.

Abstract

© 2017 Elsevier Ltd Compartmentation of C 4 photosynthetic biochemistry into bundle sheath (BS) and mesophyll (M) cells, and photorespiration in C 3 plants is predicted to have hydrogen isotopic consequences for metabolites at both molecular and site-specific levels. Molecular-level evidence was recently reported (Zhou et al., 2016), but evidence at the site-specific level is still lacking. We propose that such evidence exists in the contrasting 2 H distribution profiles of glucose samples from naturally grown C 3 , C 4 and CAM plants: photorespiration contributes to the relative 2 H enrichment in H 5 and relative 2 H depletion in H 1 & H 6 (the average of the two pro-chiral Hs and in particular H 6, pro-R ) in C 3 glucose, while 2 H-enriched C 3 mesophyll cellular (chloroplastic) water most likely contributes to the enrichment at H 4 ; export of (transferable hydrogen atoms of) NADPH from C 4 mesophyll cells to bundle sheath cells (via the malate shuttle) and incorporation of 2 H-relatively unenriched BS cellular water contribute to the relative depletion of H 4 & H 5 respectively; shuttling of triose-phosphates (PGA: phosphoglycerate dand DHAP: dihydroacetone phosphate) between C 4 bundle sheath and mesophyll cells contributes to the relative enrichment in H 1 & H 6 (in particular H 6, pro-R ) in C 4 glucose.

Published
2018

4. Does circadian regulation lead to optimal gas exchange regulation?

Author

Resco de Dios, Josu G. Alday, Mark G. Tjoelker, Kayler Z, Michael Bahn, Clément Piel, del Castillo J, Sonia García-Muñoz, Karin Pirhofer-Walzl, Juan Pedro Ferrio, Alexandru Milcu, Serajis Salekin, Jacques Roy, Arthur Gessler, David T. Tissue, Damien Landais, Jordi Voltas, Paula Martín-Gómez, Sébastien Devidal, and Olivier Ravel

Subjects
0106 biological sciences, 2. Zero hunger, 0303 health sciences, Stomatal conductance, Vapour Pressure Deficit, Circadian clock, 15. Life on land, Biology, 01 natural sciences, 03 medical and health sciences, Circadian regulation, Photosynthetically active radiation, Botany, Plant species, Circadian rhythm, 030304 developmental biology, 010606 plant biology & botany, Transpiration
Abstract

SummaryOptimal stomatal theory is an evolutionary model proposing that leaves trade-off Carbon (C) for water to maximise C assimilation (A) and minimise transpiration (E), thereby generating a marginal water cost of carbon gain (λ) that remains constant over short temporal scales. The circadian clock is a molecular timer of metabolism that controls A and stomatal conductance (gs), amongst other processes, in a broad array of plant species. Here, we test whether circadian regulation contributes towards achieving optimal stomatal behaviour. We subjected bean (Phaseolus vulgaris) and cotton (Gossypium hirsutum) canopies to fixed, continuous environmental conditions of photosynthetically active radiation, temperature and vapour pressure deficit over 48 hours. We observed a significant and self-sustained circadian oscillation in A and in stomatal conductance (gs) which also led to a circadian oscillation in λ. The lack of constant marginal water cost indicates that circadian regulation does not directly lead to optimal stomatal behaviour. However, the temporal pattern in gas exchange, indicative of either maximizing A or of minimizing E, depending upon time of day, indicates that circadian regulation could contribute towards optimizing stomatal responses. More broadly, our results add to the emerging field of plant circadian ecology and show that molecular controls may partially explain leaf-level patterns observed in the field.

Published
2017

5. Top canopy nitrogen allocation linked to increased grassland carbon uptake in stands of varying species richness

Author

Milcu, A., Gessler, A., Roscher, Christiane, Rose, L., Kayler, Z., Bachmann, D., Pirhofer-Walzl, K., Zavadlav, S., Galiano, L., Buchmann, Tina, Scherer-Lorenzen, M., Roy, J., Milcu, A., Gessler, A., Roscher, Christiane, Rose, L., Kayler, Z., Bachmann, D., Pirhofer-Walzl, K., Zavadlav, S., Galiano, L., Buchmann, Tina, Scherer-Lorenzen, M., and Roy, J.

Abstract

Models predict that vertical gradients of foliar nitrogen (N) allocation, increasing from bottom to top of plant canopies, emerge as a plastic response to optimise N utilisation for carbon assimilation. While this mechanism has been well documented in monocultures, its relevance for mixed stands of varying species richness remains poorly understood. We used 21 naturally assembled grassland communities to analyse the gradients of N in the canopy using N allocation coefficients (K N ) estimated from the distribution of N per foliar surface area (KN-F) and ground surface area (KN-G). We tested whether: 1) increasing plant species richness leads to more pronounced N gradients as indicated by higher K N -values, 2) K N is a good predictor of instantaneous net ecosystem CO2 exchange and 3) functional diversity of leaf N concentration as estimated by Rao’s Q quadratic diversity metric is a good proxy of K N . Our results show a negative (for KN-G) or no relationship (for KN-F) between species richness and canopy N distribution, but emphasize a link (positive relationship) between more foliar N per ground surface area in the upper layers of the canopy (i.e. under higher KN-G) and ecosystem CO2 uptake. Rao’s Q was not a good proxy for either K N .

Published
2017

6. Application of δ13C and δ15N isotopic signatures of organic matter fractions sequentially separated from adjacent arable and forest soils to identify carbon stabilization mechanisms

Author

Kayler, Z. E., Kaiser, M., Gessler, A., Ellerbrock, R. H., and Sommer, M.

Subjects
lcsh:Geology, lcsh:QH501-531, lcsh:QH540-549.5, lcsh:QE1-996.5, lcsh:Life, lcsh:Ecology
Abstract

Identifying the chemical mechanisms behind soil carbon bound in organo-mineral complexes is necessary to determine the degree to which soil organic carbon is stabilized belowground. Analysis of δ13C and δ15N isotopic signatures of stabilized OM fractions along with soil mineral characteristics may yield important information about OM-mineral associations and their processing history. We anlayzed the δ13C and δ15N isotopic signatures from two organic matter (OM) fractions along with soil mineral proxies to identify the likely binding mechanisms involved. We analyzed OM fractions hypothesized to contain carbon stabilized through organo-mineral complexes: (1) OM separated chemically with sodium pyrophosphate (OM(PY)) and (2) OM occluded in micro-structures found in the chemical extraction residue (OM(ER)). Because the OM fractions were separated from five different soils with paired forest and arable land use histories, we could address the impact of land use change on carbon binding and processing mechanisms. We used partial least squares regression to analyze patterns in the isotopic signature of OM with established mineral and chemical proxies indicative for certain binding mechanisms. We found different mechanisms predominate in each land use type. For arable soils, the formation of OM(PY)-Ca-mineral associations was identified as an important OM binding mechanism. Therefore, we hypothesize an increased stabilization of microbial processed OM(PY) through Ca2+ interactions. In general, we found the forest soils to contain on average 10% more stabilized carbon relative to total carbon stocks, than the agricultural counter part. In forest soils, we found a positive relationship between isotopic signatures of OM(PY) and the ratio of soil organic carbon content to soil surface area (SOC/SSA). This indicates that the OM(PY) fractions of forest soils represent layers of slower exchange not directly attached to mineral surfaces. From the isotopic composition of the OM(ER) fraction, we conclude that the OM in this fraction from both land use types have undergone a different pathway to stabilization that does not involve microbial processing, which may include OM which is highly protected within soil micro-structures.

Published
2011

9. Allocate carbon for a reason: Priorities are reflected in the 13C/12C ratios of plant lipids synthesized via three independent biosynthetic pathways

Author

Zhou, Youping, Stuart-Williams, H., Grice, Kliti, Kayler, Z., Zavadlav, S., Vogts, A., Rommerskirchen, F., Farquhar, G., Gessler, A., Zhou, Youping, Stuart-Williams, H., Grice, Kliti, Kayler, Z., Zavadlav, S., Vogts, A., Rommerskirchen, F., Farquhar, G., and Gessler, A.

Abstract

It has long been theorized that carbon allocation, in addition to the carbon source and to kinetic isotopic effects associated with a particular lipid biosynthetic pathway, plays an important role in shaping the carbon isotopic composition (13C/12C) of lipids (Park and Epstein, 1961). If the latter two factors are properly constrained, valuable information about carbon allocation during lipid biosynthesis can be obtained from carbon isotope measurements. Published work of Chikaraishi et al. (2004) showed that leaf lipids isotopic shifts from bulk leaf tissue Δδ13Cbk−lp (defined as δ13Cbulkleaftissue − δ13Clipid) are pathway dependent: the acetogenic (ACT) pathway synthesizing fatty lipids has the largest isotopic shift, the mevalonic acid (MVA) pathway synthesizing sterols the lowest and the phytol synthesizing 1-deoxy-d-xylulose 5-phosphate (DXP) pathway gives intermediate values. The differences in Δδ13Cbk−lp between C3 and C4 plants Δδ13Cbk-lp,C4-C3Δδ13Cbk-lp,C4-C3 are also pathway-dependent: View the MathML sourceΔδ13Cbk-lp,C4-C3ACT > View the MathML sourceΔδ13Cbk-lp,C4-C3DXP > View the MathML sourceΔδ13Cbk-lp,C4-C3MVA.These pathway-dependent differences have been interpreted as resulting from kinetic isotopic effect differences of key but unspecified biochemical reactions involved in lipids biosynthesis between C3 and C4 plants. After quantitatively considering isotopic shifts caused by (dark) respiration, export-of-carbon (to sink tissues) and photorespiration, we propose that the pathway-specific differences Δδ13Cbk-lp,C3-C4Δδ13Cbk-lp,C3-C4 can be successfully explained by C4 − C3 carbon allocation (flux) differences with greatest flux into the ACT pathway and lowest into the MVA pathways (when flux is higher, isotopic shift relative to source is smaller). Highest carbon allocation to the ACT pathway appears to be tied to the most stringent role of water-loss-minimization by leaf waxes (composed mainly of fatty lipids) while the lowest carbon allocation to th

Published
2015

10. Application of delta C-13 and delta N-15 isotopic signatures of organic matter fractions sequentially separated from adjacent arable and forest soils to identify carbon stabilization mechanisms

Author

Kayler, Z. E., Kaiser, Michael, Gessler, A., Ellerbrock, Ruth H., and Sommer, Michael

Subjects
Institut für Biochemie und Biologie
Abstract

Identifying the chemical mechanisms behind soil carbon bound in organo-mineral complexes is necessary to determine the degree to which soil organic carbon is stabilized belowground. Analysis of delta C-13 and delta N-15 isotopic signatures of stabilized OM fractions along with soil mineral characteristics may yield important information about OM-mineral associations and their processing history. We anlayzed the delta C-13 and delta N-15 isotopic signatures from two organic matter (OM) fractions along with soil mineral proxies to identify the likely binding mechanisms involved. We analyzed OM fractions hypothesized to contain carbon stabilized through organo-mineral complexes: (1) OM separated chemically with sodium pyrophosphate (OM(PY)) and (2) OM occluded in micro-structures found in the chemical extraction residue (OM(ER)). Because the OM fractions were separated from five different soils with paired forest and arable land use histories, we could address the impact of land use change on carbon binding and processing mechanisms. We used partial least squares regression to analyze patterns in the isotopic signature of OM with established mineral and chemical proxies indicative for certain binding mechanisms. We found different mechanisms predominate in each land use type. For arable soils, the formation of OM(PY)-Ca-mineral associations was identified as an important OM binding mechanism. Therefore, we hypothesize an increased stabilization of microbial processed OM(PY) through Ca2+ interactions. In general, we found the forest soils to contain on average 10% more stabilized carbon relative to total carbon stocks, than the agricultural counter part. In forest soils, we found a positive relationship between isotopic signatures of OM(PY) and the ratio of soil organic carbon content to soil surface area (SOC/SSA). This indicates that the OM(PY) fractions of forest soils represent layers of slower exchange not directly attached to mineral surfaces. From the isotopic composition of the OM(ER) fraction, we conclude that the OM in this fraction from both land use types have undergone a different pathway to stabilization that does not involve microbial processing, which may include OM which is highly protected within soil micro-structures.

Published
2011

15. Desiccation of sediments affects assimilate transport within aquatic plants and carbon transfer to microorganisms.

Author

Rein, I., Kayler, Z. E., Premke, K., Gessler, A., and Rennenberg, H.

Subjects
*DROUGHT tolerance, *AQUATIC plants, *PLANT nutrition, *NUTRIENT cycles, *CARBON content of plants, *AQUATIC ecology
Abstract

With the projected increase in drought duration and intensity in future, small water bodies, and especially the terrestrial-aquatic interfaces, will be subjected to longer dry periods with desiccation of the sediment. Drought effects on the plant-sediment microorganism carbon continuum may disrupt the tight linkage between plants and microbes which governs sediment carbon and nutrient cycling, thus having a potential negative impact on carbon sequestration of small freshwater ecosystems. However, research on drought effects on the plant-sediment carbon transfer in aquatic ecosystems is scarce. We therefore exposed two emergent aquatic macrophytes, Phragmites australis and Typha latifolia, to a month-long summer drought in a mesocosm experiment., We followed the fate of carbon from leaves to sediment microbial communities with 13 CO2 pulse labelling and microbial phospholipid-derived fatty acid ( PLFA) analysis., We found that drought reduced the total amount of carbon allocated to stem tissues but did not delay the transport. We also observed an increase in accumulation of 13C-labelled sugars in roots and found a reduced incorporation of 13C into the PLFAs of sediment microorganisms., Drought induced a switch in plant carbon allocation priorities, where stems received less new assimilates leading to reduced starch reserves whilst roots were prioritised with new assimilates, suggesting their use for osmoregulation. There were indications that the reduced carbon transfer from roots to microorganisms was due to the reduction of microbial activity via direct drought effects rather than to a decrease in root exudation or exudate availability. [ABSTRACT FROM AUTHOR]

Published
2016
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16. Progress and challenges in using stable isotopes to trace plant carbon and water relations across scales

Author

Werner, C., primary, Schnyder, H., additional, Cuntz, M., additional, Keitel, C., additional, Zeeman, M. J., additional, Dawson, T. E., additional, Badeck, F.-W., additional, Brugnoli, E., additional, Ghashghaie, J., additional, Grams, T. E. E., additional, Kayler, Z. E., additional, Lakatos, M., additional, Lee, X., additional, Máguas, C., additional, Ogée, J., additional, Rascher, K. G., additional, Siegwolf, R. T. W., additional, Unger, S., additional, Welker, J., additional, Wingate, L., additional, and Gessler, A., additional

Published
2012
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17. Carbon allocation and carbon isotope fluxes in the plant-soil-atmosphere continuum: a review

Author

Brüggemann, N., primary, Gessler, A., additional, Kayler, Z., additional, Keel, S. G., additional, Badeck, F., additional, Barthel, M., additional, Boeckx, P., additional, Buchmann, N., additional, Brugnoli, E., additional, Esperschütz, J., additional, Gavrichkova, O., additional, Ghashghaie, J., additional, Gomez-Casanovas, N., additional, Keitel, C., additional, Knohl, A., additional, Kuptz, D., additional, Palacio, S., additional, Salmon, Y., additional, Uchida, Y., additional, and Bahn, M., additional

Published
2011
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19. Linking carbon and water cycles using stable isotopes across scales: progress and challenges

Author

Werner, C., primary, Badeck, F., additional, Brugnoli, E., additional, Cohn, B., additional, Cuntz, M., additional, Dawson, T., additional, Gessler, A., additional, Ghashghaie, J., additional, Grams, T. E. E., additional, Kayler, Z., additional, Keitel, C., additional, Lakatos, M., additional, Lee, X., additional, Máguas, C., additional, Ogée, J., additional, Rascher, K. G., additional, Schnyder, H., additional, Siegwolf, R., additional, Unger, S., additional, Welker, J., additional, Wingate, L., additional, and Zeeman, M. J., additional

Published
2011
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21. Increasing addition of autochthonous to allochthonous carbon in nutrient-rich aquatic systems stimulates carbon consumption but does not alter bacterial community composition.

Author

Attermeyer, K., Hornick, T., Kayler, Z. E., Bahr, A., Zwirnmann, E., Grossart, H.-P., and Premke, K.

Subjects
CARBON compounds, INDIGENISM, AQUATIC biodiversity, INLAND water transportation, BIODEGRADATION, ORGANIC compounds, BIOTIC communities
Abstract

Dissolved organic carbon (DOC) concentrations -- mainly of terrestrial origin -- are increasing worldwide in inland waters. The biodegradability of the DOC varies depending on quantity and chemical quality. Heterotrophic bacteria are the main consumers of DOC and thus determine DOC temporal dynamics and availability for higher trophic levels. It is therefore crucial to understand the processes controlling the bacterial turnover of additional allochthonous and autochthonous DOC in aquatic systems. Our aim was to study bacterial carbon (C) turnover with respect to DOC quantity and chemical quality using both allochthonous and autochthonous DOC sources. We incubated a natural bacterial community with allochthonous C (13C-labeled beech leachate) and increased concentrations and pulses (intermittent occurrence of organic matter input) of autochthonous C (algae lysate). We then determined bacterial carbon consumption, activities, and community composition together with the carbon flow through bacteria using stable C isotopes. The chemical analysis of single sources revealed differences in aromaticity and fractions of low and high molecular weight substances (LMWS and HMWS, respectively) between allochthonous and autochthonous C sources. In parallel to these differences in chemical composition, we observed a higher availability of allochthonous C as evidenced by increased DOC consumption and bacterial growth efficiencies (BGE) when solely allochthonous C was provided. In treatments with mixed sources, rising concentrations of added autochthonous DOC resulted in a further, significant increase in bacterial DOC consumption from 52 to 68% when nutrients were not limiting. This rise was accompanied by a decrease in the humic substances (HS) fraction and an increase in bacterial biomass. Stable C isotope analyses of phospholipid fatty acids (PLFA) and respired dissolved inorganic carbon (DIC) supported a preferential assimilation of autochthonous C and respiration of the allochthonous C. Changes in DOC concentration and consumption in mixed treatments did not affect bacterial community composition (BCC), but BCC differed in single vs. mixed incubations. Our study highlights that DOC quantity affects bacterial C consumption but not BCC in nutrient-rich aquatic systems. BCC shifted when a mixture of allochthonous and autochthonous C was provided simultaneously to the bacterial community. Our results indicate that chemical quality rather than source of DOC per se (allochthonous vs. autochthonous) determines bacterial DOC turnover. [ABSTRACT FROM AUTHOR]

Published
2013
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22. Application of δ13C and δ15N isotopic signatures of organic matter fractions sequentially separated from adjacent arable and forest soils to identify carbon stabilization mechanisms.

Author

Kayler, Z. E., Kaiser, M., Gessler, A., Ellerbrock, R. H., Sommer, M., and Bahn, M.

Subjects
FOREST soils, CARBON in soils, CARBON isotopes, SOIL mineralogy, SODIUM pyrophosphate, HUMUS, SURFACE area
Abstract

Identifying the chemical mechanisms behind soil carbon bound in organo-mineral complexes is necessary to determine the degree to which soil organic carbon is stabilized belowground. Analysis of δ13C and δ15N isotopic signatures of stabilized OM fractions along with soil mineral characteristics may yield important information about OM-mineral associations and their processing history. We anlayzed the δ13C and δ15N isotopic signatures from two organic matter (OM) fractions along with soil mineral proxies to identify the likely binding mechanisms involved. We analyzed OM fractions hypothesized to contain carbon stabilized through organo-mineral complexes: (1) OM separated chemically with sodium pyrophosphate (OM(PY)) and (2) OM occluded in micro-structures found in the chemical extraction residue (OM(ER)). Because the OM fractions were separated from five different soils with paired forest and arable land use histories, we could address the impact of land use change on carbon binding and processing mechanisms. We used partial least squares regression to analyze patterns in the isotopic signature of OM with established mineral and chemical proxies indicative for certain binding mechanisms. We found different mechanisms predominate in each land use type. For arable soils, the formation of OM(PY)-Ca-mineral associations was identified as an important OM binding mechanism. Therefore, we hypothesize an increased stabilization of microbial processed OM(PY) through Ca 2+ interactions. In general, we found the forest soils to contain on average 10% more stabilized carbon relative to total carbon stocks, than the agricultural counter part. In forest soils, we found a positive relationship between isotopic signatures of OM(PY) and the ratio of soil organic carbon content to soil surface area (SOC/SSA). This indicates that the OM(PY) fractions of forest soils represent layers of slower exchange not directly attached to mineral surfaces. From the isotopic composition of the OM(ER) fraction, we conclude that the OM in this fraction from both land use types have undergone a different pathway to stabilization that does not involve microbial processing, which may include OM which is highly protected within soil micro-structures. [ABSTRACT FROM AUTHOR]

Published
2011
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23. Linking carbon and water cycles using stable isotopes across scales: progress and challenges.

Author

Werner, C., Badeck, F., Brugnoli, E., Cohn, B., Cuntz, M., Dawson, T., Gessler, A., Ghashghaie, J., Grams, T. E. E., Kayler, Z., Keitel, C., Lakatos, M., Lee, X., Máguas, C., Ogée, J., Rascher, K. G., Schnyder, H., Siegwolf, R., Unger, S., and Welker, J.

Subjects
CARBON cycle, WATER bikes, STABLE isotopes, HEAT flux, HYDROGEN, OXYGEN
Abstract

Stable isotope analysis is a powerful tool for tracing biogeochemical processes in the carbon and water cycles. One particularly powerful approach is to employ multiple isotopes where the simultaneous assessment of the D/H,18O/16O and/or 13C/12C in different compounds provide a unique means to investigate the coupling of water and 5 carbon fluxes at various temporal and spatial scales. Here, we present a research update on recent advances in our process-based understanding of the utilization of carbon, oxygen and hydrogen isotopes to lend insight into carbon and water cycling. We highlight recent technological developments and approaches, their strengths and methodological precautions with examples covering scales from minutes to centuries and from the leaf to the globe. [ABSTRACT FROM AUTHOR]

Published
2011
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24. Toward using δ13C of ecosystem respiration to monitor canopy physiology in complex terrain.

Author

Pypker, T. G., Hauck, M., Sulzman, E. W., Unsworth, M. H., Mix, A. C., Kayler, Z., Conklin, D., Kennedy, A. M., Barnard, H. R., Phillips, C., and Bond, B. J.

Subjects
DOUGLAS fir, CARBON, OXYGEN, ECOLOGY, PLANT canopies, PLANT physiology
Abstract

In 2005 and 2006, air samples were collected at the base of a Douglas-fir watershed to monitor seasonal changes in the δ13CO2 of ecosystem respiration (δ13CER). The goals of this study were to determine whether variations in δ13CER correlated with environmental variables and could be used to predict expected variations in canopy-average stomatal conductance ( G s). Changes in δ13CER correlated weakly with changes in vapor pressure deficit (VPD) measured 0 and 3–7 days earlier and significantly with soil matric potential (ψm) ( P value <0.02) measured on the same day. Midday G s was estimated using sapflow measurements (heat-dissipation method) at four plots located at different elevations within the watershed. Values of midday G s from 0 and 3–7 days earlier were correlated with δ13CER, with the 5-day lag being significant ( P value <0.05). To examine direct relationships between δ13CER and recent G s, we used models relating isotope discrimination to stomatal conductance and photosynthetic capacity at the leaf level to estimate values of stomatal conductance (“ G s–I”) that would be expected if respired CO2 were derived entirely from recent photosynthate. We compared these values with estimates of G s using direct measurement of transpiration at multiple locations in the watershed. Considering that the approach based on isotopes considers only the effect of photosynthetic discrimination on δ13CER, the magnitude and range in the two values were surprisingly similar. We conclude that: (1) δ13CER is sensitive to variations in weather, and (2) δ13CER potentially could be used to directly monitor average, basin-wide variations in G s in complex terrain if further research improves understanding of how δ13CER is influenced by post-assimilation fractionation processes. [ABSTRACT FROM AUTHOR]

Published
2008
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25. Genotypic variability enhances the reproducibility of an ecological study.

Author

Milcu A, Puga-Freitas R, Ellison AM, Blouin M, Scheu S, Freschet GT, Rose L, Barot S, Cesarz S, Eisenhauer N, Girin T, Assandri D, Bonkowski M, Buchmann N, Butenschoen O, Devidal S, Gleixner G, Gessler A, Gigon A, Greiner A, Grignani C, Hansart A, Kayler Z, Lange M, Lata JC, Le Galliard JF, Lukac M, Mannerheim N, Müller MEH, Pando A, Rotter P, Scherer-Lorenzen M, Seyhun R, Urban-Mead K, Weigelt A, Zavattaro L, and Roy J

Subjects
Brachypodium growth & development, Environment, Europe, Medicago truncatula growth & development, Reproducibility of Results, Brachypodium genetics, Genotype, Medicago truncatula genetics, Research Design statistics & numerical data
Abstract

Many scientific disciplines are currently experiencing a 'reproducibility crisis' because numerous scientific findings cannot be repeated consistently. A novel but controversial hypothesis postulates that stringent levels of environmental and biotic standardization in experimental studies reduce reproducibility by amplifying the impacts of laboratory-specific environmental factors not accounted for in study designs. A corollary to this hypothesis is that a deliberate introduction of controlled systematic variability (CSV) in experimental designs may lead to increased reproducibility. To test this hypothesis, we had 14 European laboratories run a simple microcosm experiment using grass (Brachypodium distachyon L.) monocultures and grass and legume (Medicago truncatula Gaertn.) mixtures. Each laboratory introduced environmental and genotypic CSV within and among replicated microcosms established in either growth chambers (with stringent control of environmental conditions) or glasshouses (with more variable environmental conditions). The introduction of genotypic CSV led to 18% lower among-laboratory variability in growth chambers, indicating increased reproducibility, but had no significant effect in glasshouses where reproducibility was generally lower. Environmental CSV had little effect on reproducibility. Although there are multiple causes for the 'reproducibility crisis', deliberately including genetic variability may be a simple solution for increasing the reproducibility of ecological studies performed under stringently controlled environmental conditions.

Published
2018
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26. Top canopy nitrogen allocation linked to increased grassland carbon uptake in stands of varying species richness.

Author

Milcu A, Gessler A, Roscher C, Rose L, Kayler Z, Bachmann D, Pirhofer-Walzl K, Zavadlav S, Galiano L, Buchmann T, Scherer-Lorenzen M, and Roy J

Abstract

Models predict that vertical gradients of foliar nitrogen (N) allocation, increasing from bottom to top of plant canopies, emerge as a plastic response to optimise N utilisation for carbon assimilation. While this mechanism has been well documented in monocultures, its relevance for mixed stands of varying species richness remains poorly understood. We used 21 naturally assembled grassland communities to analyse the gradients of N in the canopy using N allocation coefficients (K N ) estimated from the distribution of N per foliar surface area (K N-F ) and ground surface area (K N-G ). We tested whether: 1) increasing plant species richness leads to more pronounced N gradients as indicated by higher K N -values, 2) K N is a good predictor of instantaneous net ecosystem CO 2 exchange and 3) functional diversity of leaf N concentration as estimated by Rao's Q quadratic diversity metric is a good proxy of K N . Our results show a negative (for K N-G ) or no relationship (for K N-F ) between species richness and canopy N distribution, but emphasize a link (positive relationship) between more foliar N per ground surface area in the upper layers of the canopy (i.e. under higher K N-G ) and ecosystem CO 2 uptake. Rao's Q was not a good proxy for either K N .

Published
2017
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27. Variation in short-term and long-term responses of photosynthesis and isoprenoid-mediated photoprotection to soil water availability in four Douglas-fir provenances.

Author

Junker LV, Kleiber A, Jansen K, Wildhagen H, Hess M, Kayler Z, Kammerer B, Schnitzler JP, Kreuzwieser J, Gessler A, and Ensminger I

Subjects
Adaptation, Physiological, Droughts, Light, Pseudotsuga metabolism, Pseudotsuga radiation effects, Biological Variation, Population, Photosynthesis, Pigments, Biological metabolism, Pseudotsuga physiology, Soil chemistry, Terpenes metabolism, Water analysis
Abstract

For long-lived forest tree species, the understanding of intraspecific variation among populations and their response to water availability can reveal their ability to cope with and adapt to climate change. Dissipation of excess excitation energy, mediated by photoprotective isoprenoids, is an important defense mechanism against drought and high light when photosynthesis is hampered. We used 50-year-old Douglas-fir trees of four provenances at two common garden experiments to characterize provenance-specific variation in photosynthesis and photoprotective mechanisms mediated by essential and non-essential isoprenoids in response to soil water availability and solar radiation. All provenances revealed uniform photoprotective responses to high solar radiation, including increased de-epoxidation of photoprotective xanthophyll cycle pigments and enhanced emission of volatile monoterpenes. In contrast, we observed differences between provenances in response to drought, where provenances sustaining higher CO 2 assimilation rates also revealed increased water-use efficiency, carotenoid-chlorophyll ratios, pools of xanthophyll cycle pigments, β-carotene and stored monoterpenes. Our results demonstrate that local adaptation to contrasting habitats affected chlorophyll-carotenoid ratios, pool sizes of photoprotective xanthophylls, β-carotene, and stored volatile isoprenoids. We conclude that intraspecific variation in isoprenoid-mediated photoprotective mechanisms contributes to the adaptive potential of Douglas-fir provenances to climate change.

Published
2017
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28. Circadian rhythms have significant effects on leaf-to-canopy scale gas exchange under field conditions.

Author

Resco de Dios V, Gessler A, Ferrio JP, Alday JG, Bahn M, Del Castillo J, Devidal S, García-Muñoz S, Kayler Z, Landais D, Martín-Gómez P, Milcu A, Piel C, Pirhofer-Walzl K, Ravel O, Salekin S, Tissue DT, Tjoelker MG, Voltas J, and Roy J

Subjects
Circadian Clocks, Ecosystem, Gossypium physiology, Phaseolus physiology, Photosynthesis, Plant Stomata metabolism, Carbon Dioxide analysis, Circadian Rhythm, Plant Leaves metabolism, Water analysis
Abstract

Background: Molecular clocks drive oscillations in leaf photosynthesis, stomatal conductance, and other cell and leaf-level processes over ~24 h under controlled laboratory conditions. The influence of such circadian regulation over whole-canopy fluxes remains uncertain; diurnal CO 2 and H 2 O vapor flux dynamics in the field are currently interpreted as resulting almost exclusively from direct physiological responses to variations in light, temperature and other environmental factors. We tested whether circadian regulation would affect plant and canopy gas exchange at the Montpellier European Ecotron. Canopy and leaf-level fluxes were constantly monitored under field-like environmental conditions, and under constant environmental conditions (no variation in temperature, radiation, or other environmental cues)., Results: We show direct experimental evidence at canopy scales of the circadian regulation of daytime gas exchange: 20-79 % of the daily variation range in CO 2 and H 2 O fluxes occurred under circadian entrainment in canopies of an annual herb (bean) and of a perennial shrub (cotton). We also observed that considering circadian regulation improved performance by 8-17 % in commonly used stomatal conductance models., Conclusions: Our results show that circadian controls affect diurnal CO 2 and H 2 O flux patterns in entire canopies in field-like conditions, and its consideration significantly improves model performance. Circadian controls act as a 'memory' of the past conditions experienced by the plant, which synchronizes metabolism across entire plant canopies.

Published
2016
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29. Douglas-fir seedlings exhibit metabolic responses to increased temperature and atmospheric drought.

Author

Jansen K, Du B, Kayler Z, Siegwolf R, Ensminger I, Rennenberg H, Kammerer B, Jaeger C, Schaub M, Kreuzwieser J, and Gessler A

Subjects
Acclimatization, Biomass, Carbon Isotopes analysis, Carbon Isotopes metabolism, Climate, Droughts, Pseudotsuga growth & development, Seedlings growth & development, Temperature, Water metabolism, Pseudotsuga physiology, Seedlings physiology
Abstract

In the future, periods of strongly increased temperature in concert with drought (heat waves) will have potentially detrimental effects on trees and forests in Central Europe. Norway spruce might be at risk in the future climate of Central Europe. However, Douglas-fir is often discussed as an alternative for the drought and heat sensitive Norway spruce, because some provenances are considered to be well adapted to drier and warmer conditions. In this study, we identified the physiological and growth responses of seedlings from two different Douglas-fir provenances to increased temperature and atmospheric drought during a period of 92 days. We analysed (i) plant biomass, (ii) carbon stable isotope composition as an indicator for time integrated intrinsic water use efficiency, (iii) apparent respiratory carbon isotope fractionation as well as (iv) the profile of polar low molecular metabolites. Plant biomass was only slightly affected by increased temperatures and atmospheric drought but the more negative apparent respiratory fractionation indicated a temperature-dependent decrease in the commitment of substrate to the tricarboxylic acid cycle. The metabolite profile revealed that the simulated heat wave induced a switch in stress protecting compounds from proline to polyols. We conclude that metabolic acclimation successfully contributes to maintain functioning and physiological activity in seedlings of both Douglas-fir provenances under conditions that are expected during heat waves (i.e. elevated temperatures and atmospheric drought). Douglas-fir might be a potentially important tree species for forestry in Central Europe under changing climatic conditions.

Published
2014
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30. Drought response of mesophyll conductance in forest understory species--impacts on water-use efficiency and interactions with leaf water movement.

Author

Hommel R, Siegwolf R, Saurer M, Farquhar GD, Kayler Z, Ferrio JP, and Gessler A

Subjects
Acer radiation effects, Adaptation, Physiological, Allium radiation effects, Droughts, Euphorbiaceae radiation effects, Forests, Fraxinus radiation effects, Impatiens radiation effects, Light, Oxygen metabolism, Photosynthesis physiology, Plant Leaves physiology, Plant Leaves radiation effects, Plant Stomata physiology, Plant Stomata radiation effects, Plant Transpiration physiology, Acer physiology, Allium physiology, Carbon Dioxide metabolism, Euphorbiaceae physiology, Fraxinus physiology, Impatiens physiology, Water physiology
Abstract

Regulation of stomatal (gs ) and mesophyll conductance (gm ) is an efficient means for optimizing the relationship between water loss and carbon uptake in plants. We assessed water-use efficiency (WUE)-based drought adaptation strategies with respect to mesophyll conductance of different functional plant groups of the forest understory. Moreover we aimed at assessing the mechanisms of and interactions between water and CO2 conductance in the mesophyll. The facts that an increase in WUE was observed only in the two species that increased gm in response to moderate drought, and that over all five species examined, changes in mesophyll conductance were significantly correlated with the drought-induced change in WUE, proves the importance of gm in optimizing resource use under water restriction. There was no clear correlation of mesophyll CO2 conductance and the tortuosity of water movement in the leaf across the five species in the control and drought treatments. This points either to different main pathways for CO2 and water in the mesophyll either to different regulation of a common pathway., (© 2014 Scandinavian Plant Physiology Society.)

Published
2014
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