Species‐specific differences in nitrogen uptake and utilization by six European tree species

Schulz, Horst; Härtling, Sigrid; Stange, Claus Florian

doi:10.1002/jpln.201000004

Cited by 35 publications

(32 citation statements)

References 29 publications

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“…These values were within the range of previous reports (Eddy et al 2008;Uscola et al 2017), although the experimental conditions varied. Our results suggest that low fine root biomass but high specific N-uptake rate, which maximizes whole-plant growth rates (Osone and Tateno, 2005;Schulz et al 2011), would contribute to the suppression of N loss on Oxisols. In contrast, plants on Ultisols would invest more in root formation in the O horizon to capture N before leaching down to the mineral horizon.…”

Section: Roles and Controls On Fine Rootsmentioning

confidence: 78%

Nitrogen flux patterns through Oxisols and Ultisols in tropical forests of Cameroon, Central Africa

Shibata

Sugihara

Mvondo-Zé

et al. 2017

Soil Science and Plant Nutrition

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We lack an understanding of nitrogen (N) cycles in tropical forests of Africa, although the environmental conditions in this region, such as soil type, vegetation, and climate, are distinct when compared with other tropical forests. Herein, we simultaneously quantified N fluxes through precipitation, throughfall, and 0-, 15-, and 30-cm soil solutions, as well as litterfall, in two forests with different soil acidity (Ultisols at the MV village (exchangeable Al 3+ in 0-30 cm, 126 kmol c ha -1 ) and Oxisols at the AD village (exchangeable Al 3+ in 0-30 cm, 59.8 kmol c ha -1 )) over 2 years in Cameroon. The N fluxes to the O horizon via litterfall plus throughfall were similar for both sites (MV and AD, 243 and 273 kg N ha -1 yr -1 , respectively). Those values were remarkably large relative to other tropical forests, reflecting the dominance of legumes in this region. The total dissolved N flux from the O horizon at the MV was 28 kg N ha -1 yr -1 , while it was 127 kg N ha -1 yr -1 mainly as NO 3 --N (~80%) at the AD. The distinctly different pattern of N cycles could be caused by stronger soil acidity at the MV, which was considered to promote a superficial root mat formation in the O horizon despite the marked dry season (fine root biomass in the O horizon and its proportion to the 1-m-soil profile: 1.5 Mg ha -1 and 31% at the MV; 0.3 Mg ha -1 and 9% at the AD). Combined with the published data for N fluxes in tropical forests, we have shown that Oxisols, in combination with N-fixing species, have large N fluxes from the O horizon; meanwhile, Ultisols do not have large fluxes because of plant uptake through the root mat in the O horizon. Consequently, our results suggest that soil type can be a major factor influencing the pattern of N fluxes from the O horizon via the effects of soil acidity, thereby determining the contrasting plant-soil N cycles in the tropical forests of Africa. ARTICLE HISTORY

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Section: Roles and Controls On Fine Rootsmentioning

confidence: 78%

Nitrogen flux patterns through Oxisols and Ultisols in tropical forests of Cameroon, Central Africa

Shibata

Sugihara

Mvondo-Zé

et al. 2017

Soil Science and Plant Nutrition

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“…). As fits with a nitrophilous species, Schulz, Härtling & Stange () found that the N uptake of 2‐year‐old seedlings was greatest in ash ( F. excelsior > Tilia cordata > Pinus sylvestris > Picea abies > Fagus sylvatica > Quercus petraea ) although relative growth rate in ash was similar to the other species (0.375 g fresh mass day −1 in ash). Ash can react well to fertilizers on poor soils (Bulíř ), but they have little effect on already rich soils (Culleton, Murphy & McLoughlin ).…”

Section: Structure and Physiologymentioning

confidence: 88%

Biological Flora of the British Isles:Fraxinus excelsior

Thomas

2016

Journal of Ecology

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Summary1. This account presents information on all aspects of the biology of Fraxinus excelsior L. (Ash) that are relevant to understanding its ecological characteristics and behaviour. The main topics are presented within the standard framework of the Biological Flora of the British Isles: distribution, habitat, communities, responses to biotic factors, responses to environment, structure and physiology, phenology, floral and seed characters, herbivores and disease, history, and conservation. 2. Fraxinus excelsior is a large forest tree, native throughout the main islands of Britain and much of mainland Europe. Seedlings are shade tolerant, but adults are not so it tends to be an intermediate successional species, invading gaps in mixed stands rather than forming extensive pure stands. Ash grows on a wide range of soils but is commonest on nutrient-rich soils with a high base status and pH > 4.2, and is at its best on dry calcareous screes and fertile alluvial soils. 3. Fraxinus excelsior is trioecious or subdioecious with male, hermaphrodite and female flowers and trees. Seed production is prolific with periodic higher producing mast years. Seeds are primarily wind-dispersed, but they can float and be moved considerable distances along waterways. Germination is delayed by dormancy until usually the second spring after being shed. 4. Ash is tolerant of drought, but intolerant of spring frosts and so is predicted to fare well under current climate change scenarios, and indeed has recently been expanding in range in Europe. However, ash health and survival is currently seriously compromised by ash dieback caused by the fungus Hymenoscyphus fraxineus (Chalara fraxinea) that has the potential to kill all but a very few resistant trees. Moreover, the emerald ash borer beetle Agrilus planipennis, a serious pest of ash species in N. America, has reached Europe (though not yet the British Isles) and poses an equally if not more serious long-term threat to ash.

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“…N uptake is calculated on an annual time step as

N_{uptake} (t) = N_{\min} (1 - \exp (- k_{r} B_{r} (t))),

where k r (m 2 g −1 C) is a species trait that describes root N uptake efficiency (analogous to the light extinction coefficient). An increase in the value of k r increases the N uptake per unit root biomass (Zerihun & Bassirirad ; Schulze, Härtling & Stange ).…”

Section: Methodsmentioning

confidence: 99%

A trait‐based ecosystem model suggests that long‐term responsiveness to rising atmospheric CO₂ concentration is greater in slow‐growing than fast‐growing plants

et al. 2013

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Summary1. Atmospheric carbon dioxide concentration (C a ) has a direct and measurable effect on plant growth. However, it does not affect all plant species equally, which could lead to shifts in competitive dominance of species in ecosystems. 2. We used a dynamic plant carbon-nitrogen model to systematically examine how species traits affect the long-term C a responsiveness of C 3 plants when growing as established monocultures in the field. The model was tested against responses of 7 C 3 herbaceous species growing in a free-air C a enrichment (FACE) experiment (BioCON) in Minnesota, USA. 3. Model simulations showed that several species traits affected the C a response strongly, giving rise to a number of testable hypotheses about interspecific differences in responsiveness to C a . The largest responses to rising C a were obtained for species with low carbon-use efficiency (net primary production: gross primary production ratio), low foliar carbon allocation, low stomatal conductance, low instantaneous photosynthetic nitrogen use efficiency and low specific leaf area. 4. In general, our model predicted that, for established plants growing in resource-limited field conditions, species with slow growth rates would be most responsive to elevated C a . This prediction was supported by data from the BioCON experiment. 5. Our model also predicts that, for young plants growing in non-resource-limited conditions, species with high growth rates will be most responsive to elevated C a . This difference in species ranking under different resource availabilities is largely explained by the indirect effects of C a on leaf area. Leaf-area feedbacks favour fast-growing species the most during leaf-area expansion, but following stand maturation they favour slow-growing species the most. 6. These results imply that species that respond strongly to elevated C a in short-term (nonresource-limited) glasshouse experiments are unlikely to also be the most responsive in resource-limited field conditions, and therefore that we cannot directly extrapolate from glasshouse experiments to predict which species will be most responsive to elevated C a in the long term.

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Species‐specific differences in nitrogen uptake and utilization by six European tree species

Cited by 35 publications

References 29 publications

Nitrogen flux patterns through Oxisols and Ultisols in tropical forests of Cameroon, Central Africa

Nitrogen flux patterns through Oxisols and Ultisols in tropical forests of Cameroon, Central Africa

Biological Flora of the British Isles:Fraxinus excelsior

A trait‐based ecosystem model suggests that long‐term responsiveness to rising atmospheric CO₂ concentration is greater in slow‐growing than fast‐growing plants

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Species‐specific differences in nitrogen uptake and utilization by six European tree species

Cited by 35 publications

References 29 publications

Nitrogen flux patterns through Oxisols and Ultisols in tropical forests of Cameroon, Central Africa

Nitrogen flux patterns through Oxisols and Ultisols in tropical forests of Cameroon, Central Africa

Biological Flora of the British Isles:Fraxinus excelsior

A trait‐based ecosystem model suggests that long‐term responsiveness to rising atmospheric CO2 concentration is greater in slow‐growing than fast‐growing plants

Contact Info

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A trait‐based ecosystem model suggests that long‐term responsiveness to rising atmospheric CO₂ concentration is greater in slow‐growing than fast‐growing plants