δ13C of organic matter transported from the leaves to the roots in Eucalyptus delegatensis: short-term variations and relation to respired CO2

Geßler, Arthur; Keitel, Claudia; Kodama, Nobuhiro; Weston, Christopher J.; Winters, Anthony J.; Keith, Heather; Grice, Kliti; Leuning, R.; Farquhar, Graham D.

doi:10.1071/fp07064

Cited by 113 publications

(176 citation statements)

References 64 publications

Supporting

Mentioning

149

Contrasting

Order By: Relevance

“…Both 13 C values of respiratory substrates and the relative contribution of different metabolic pathways to CO 2 evolution may change within a day, therefore 13 C fractionation during plant respiration can change significantly on a diurnal basis, as shown in previous studies on 13 C fractionation during leaf respiration (Gessler et al 2007;Sun et al 2009;Wegener et al 2010). Diurnal variations in 13 C fractionation during root respiration and rhizosphere respiration are probable, but direct experimental evidence is not yet available.…”

Section: Comparison With Previous Studiesmentioning

confidence: 84%

“…Most published studies on 13 C fractionation during root respiration were based on snapshot measurements (minutes to hours) of the δ 13 C value of respiratory CO 2 from excised roots (Gessler et al 2007;Wegener et al 2010) or roots grown in sand or nutrient solution without the presence of soil microorganisms (Bathellier et al 2008;Klumpp et al 2005), and thus did not include the rhizomicrobial respiration by rhizosphere microorganisms utilizing materials released from live roots. In order to partition total soil respiration into rhizosphere respiration that includes both root respiration and rhizomicrobial respiration (root-derived, autotrophic respiration) and microbial decomposition of soil organic matter (soilderived, heterotrophic respiration) using a two endmember isotope mixing model (Cheng 1996), we need to know δ 13 C values of rhizosphere respiration integrated over days or seasons.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

13C isotope fractionation during rhizosphere respiration of C3 and C4 plants

Zhu

Cheng

2011

Plant Soil

View full text Add to dashboard Cite

Stable carbon isotopes are used extensively to partition total soil CO 2 efflux into root-derived rhizosphere respiration or autotrophic respiration and soil-derived heterotrophic respiration. However, it remains unclear whether CO 2 from rhizosphere respiration has the same δ 13 C value as root biomass. Here we investigated the magnitude of 13 C isotope fractionation during rhizosphere respiration relative to root biomass in six plant species. Plants were grown in a carbon-free sand-perlite medium inoculated with microorganisms from a farm soil for 62 days inside a greenhouse. We measured the δ 13 C value of rhizosphere respiration using a closed-circulation 48-hour CO 2 trapping method during 40~42 and 60~62 days after sowing. We found a consistent depletion in 13 C (0.9~1.7‰) of CO 2 from rhizosphere respiration relative to root biomass in three C 3 species (Glycine max L. Merr., Helianthus annuus L. and Triticum aestivum L.), but a relatively large depletion in 13 C (3.7~7.0‰) in three C 4 species (Amaranthus tricolor L., Sorghum bicolor (L.) Moench and Zea mays L. ssp. mays). Overall, our results indicate that CO 2 from rhizosphere respiration is more 13 C-depleted than root biomass. Therefore, accounting for this 13 C fractionation is required for accurately partitioning total soil CO 2 efflux into root-derived and soil-derived components using natural abundance stable carbon isotope methods.

show abstract

Section: Comparison With Previous Studiesmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

13C isotope fractionation during rhizosphere respiration of C3 and C4 plants

Zhu

Cheng

2011

Plant Soil

View full text Add to dashboard Cite

show abstract

“…However, these variations in the fast-turnover organic matter pool in leaves had a much lower day-night amplitude than the observed diel changes in respired δ 13 CO 2 (Brandes et al, 2006(Brandes et al, , 2007Gessler et al, 2007Gessler et al, , 2008Kodama et al, 2008;Werner et al, 2009, see Table 1) and were also phase-shifted compared to δ 13 C res (Kodama et al, 2008, see also Fig. 1).…”

Section: M12mentioning

confidence: 96%

“…(Farquhar et al, 1982), which determines the δ 13 C of primary respiratory substrate, varies over the diurnal course (e.g. Gessler et al, 2007;Wingate et al, 2010) as a result of changes in light intensity, air temperature, vapour pressure deficit (VPD) and other environmental factors, which affect assimilation, stomatal (g s ) and mesophyll conductance (g m ) as well as photorespiration and dark respiration (see Fig. 2 (M1.1), reviewed by Brugnoli and Farquhar, 2000).…”

Section: Substrate Driven Variations (M1)mentioning

confidence: 99%

Diel variations in the carbon isotope composition of respired CO<sub>2</sub> and associated carbon sources: a review of dynamics and mechanisms

Werner

Geßler

2011

Biogeosciences

View full text Add to dashboard Cite

Abstract. Recent advances have improved our methodological approaches and theoretical understanding of postphotosynthetic carbon isotope fractionation processes. Nevertheless we still lack a clear picture of the origin of shortterm variability in δ 13 C of respired CO 2 (δ 13 C res ) and organic carbon fractions on a diel basis. Closing this knowledge gap is essential for the application of stable isotope approaches for partitioning ecosystem respiration, tracing carbon flow through plants and ecosystems and disentangling key physiological processes in carbon metabolism of plants. In this review we examine the short-term dynamics in δ 13 C res and putative substrate pools at the plant, soil and ecosystem scales and discuss mechanisms, which might drive diel δ 13 C res dynamics at each scale. Maximum reported variation in diel δ 13 C res is 4.0, 5.4 and 14.8 ‰ in trunks, roots and leaves of different species and 12.5 and 8.1 ‰ at the soil and ecosystem scale in different biomes. Temporal variation in post-photosynthetic isotope fractionation related to changes in carbon allocation to different metabolic pathways is the most plausible mechanistic explanation for observed diel dynamics in δ 13 C res . In addition, mixing of component fluxes with different temporal dynamics and isotopic compositions add to the δ 13 C res variation on the soil and ecosystem level. Understanding short-term variations in δ 13 C res is particularly important for ecosystem studies, since δ 13 C res contains information on the fate of respiratory substrates, and may, therefore, provide a non-intrusive way to identify changes in carbon allocation patterns.

show abstract

“…Steady-state respiratory CO2 release in the dark is typically correlated with sucrose concentrations (e.g. Gessler et al 2007) and is greater after a period of illumination than after an extended period of darkness, both of which have been taken as evidence of dependence on carbohydrate concentrations (Azcón-Bieto & Osmond 1983; Atkin et al 1997). This may result at least partly from the ATP costs of sucrose export.…”

Section: The Role Of Variation In Anabolic Demandsmentioning

confidence: 99%

An analytical model of non‐photorespiratory CO₂ release in the light and dark in leaves of C₃ species based on stoichiometric flux balance

Buckley

Adams

2010

Plant Cell & Environment

View full text Add to dashboard Cite

Leaf respiration continues in the light but at a reduced rate. This inhibition is highly variable, and the mechanisms are poorly known, partly due to the lack of a formal model that can generate testable hypotheses. We derived an analytical model for non-photorespiratory CO2 release by solving steady-state supply/demand equations for ATP, NADH and NADPH, coupled to a widely used photosynthesis model. We used this model to evaluate causes for suppression of respiration by light. The model agrees with many observations, including highly variable suppression at saturating light, greater suppression in mature leaves, reduced assimilatory quotient (ratio of net CO2 and O2 exchange) concurrent with nitrate reduction and a Kok effect (discrete change in quantum yield at low light). The model predicts engagement of non-phosphorylating pathways at moderate to high light, or concurrent with processes that yield ATP and NADH, such as fatty acid or terpenoid synthesis. Suppression of respiration is governed largely by photosynthetic adenylate balance, although photorespiratory NADH may contribute at sub-saturating light. Key questions include the precise diel variation of anabolism and the ATP : 2e -ratio for photophosphorylation. Our model can focus experimental research and is a step towards a fully process-based model of CO2 exchange.Key-words: alternative oxidase; carbon metabolism; Kok effect; photorespiration; photosynthesis; respiration.Abbreviations: A, net CO2 assimilation rate; Ao, net O2 evolution rate; AOX, alternative oxidase; Bn, net anabolic NADH supply; Bp, net anabolic NADPH demand; Bt, net anabolic ATP demand; ci, intercellular CO2 partial pressure; COX, cytochrome oxidase; fm, fraction of photorespiratory NADH that remains in mitochondria; fx, fraction of excess thylakoid reducing potential dissipated as NADPH export; G6PDH, glucose-6-phosphate dehydrogenase; I, incident PPFD; J, potential thylakoid e -transport rate; J′, Vc in RuBP-limiting conditions; Ja, actual thylakoid e -transport rate; Jm, max potential thylakoid e -transport rate; M, maintenance ATP demand; mETC, mitochondrial e -transport chain; O, ambient O2 partial pressure; OPPP, oxidative pentose phosphate pathway; pe, ATP : 2e -ratio, ADP phosphorylated per 2 e -transported to ferredoxin; po, P : O ratio, ratio of ADP phosphorylation to O2 reduction in mitochondria; pom, overall max P : O ratio; pom,ana, max P : O ratio for NADH generated in anabolic C flow; pom,cat, max P : O ratio for NADH derived from catabolic substrate oxidation; pom,cyt, max P : O ratio for cytosol derived NADH; pom,mtx, max P : O ratio for matrix derived NADH; PPFD, photosynthetic photon flux density; QY, quantum yield of CO2 from incident PPFD; Rc, rate of non-photorespiratory CO2 release; Ro, rate of O2 reduction by mitochondria; RuBP, ribulose-1,5-bisphosphate; S, net conversion of TP to sucrose and/or starch; t, net ATP demand resulting from S; TP, triose phosphate; Vana, rate of C flow into C skeletons for biosynthesis; Vby, rate of CO2 release due to ana...

show abstract

δ13C of organic matter transported from the leaves to the roots in Eucalyptus delegatensis: short-term variations and relation to respired CO2

Cited by 113 publications

References 64 publications

13C isotope fractionation during rhizosphere respiration of C3 and C4 plants

13C isotope fractionation during rhizosphere respiration of C3 and C4 plants

Diel variations in the carbon isotope composition of respired CO<sub>2</sub> and associated carbon sources: a review of dynamics and mechanisms

An analytical model of non‐photorespiratory CO₂ release in the light and dark in leaves of C₃ species based on stoichiometric flux balance

Contact Info

Product

Resources

About

δ13C of organic matter transported from the leaves to the roots in Eucalyptus delegatensis: short-term variations and relation to respired CO2

Cited by 113 publications

References 64 publications

13C isotope fractionation during rhizosphere respiration of C3 and C4 plants

13C isotope fractionation during rhizosphere respiration of C3 and C4 plants

Diel variations in the carbon isotope composition of respired CO&lt;sub&gt;2&lt;/sub&gt; and associated carbon sources: a review of dynamics and mechanisms

An analytical model of non‐photorespiratory CO2 release in the light and dark in leaves of C3 species based on stoichiometric flux balance

Contact Info

Product

Resources

About

Diel variations in the carbon isotope composition of respired CO<sub>2</sub> and associated carbon sources: a review of dynamics and mechanisms

An analytical model of non‐photorespiratory CO₂ release in the light and dark in leaves of C₃ species based on stoichiometric flux balance