Simulating the effects of different potassium and water supply regimes on soil water content and water table depth over a rotation of a tropical Eucalyptus grandis plantation

Christina, Mathias; Maire, Guerric le; Nouvellon, Yann; Vezy, Rémi; Bordon, Bruno; Battie-Laclau, Patricia; Gonçalves, José Leonardo de Moraes; Delgado-Rojas, Juan Sinforiano; Bouillet, Jean‐Pierre; Laclau, Jean-Paul

doi:10.1016/j.foreco.2017.12.048

Cited by 42 publications

(30 citation statements)

References 65 publications

(114 reference statements)

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“…In another Eucalyptus grandis stand, Germon et al 2019showed a negative correlation between the amount of extractable water in the topsoil and the flushes of fine root growth in very deep soil layers. In those plantations, fine root growth in deep soil layers seems to be related to the overall water demand of the whole tree and controlled by the need to use increasingly deeper water resources when water becomes scarce in the topsoil, which is consistent with modeling studies (Christina et al, 2017(Christina et al, , 2018. Vertical growth rates of trees were almost symmetrical above-and below-ground in Eucalyptus plantations, reaching 10.4 and 19.2 m in height and a maximum rooting depth of 9.2 and 15.8 m at 1.5 and 3.5 years after planting, respectively (Christina et al, 2011).…”

Section: Phenology Of Deep Fine Rootssupporting

confidence: 84%

Tamm Review: Deep fine roots in forest ecosystems: Why dig deeper?

Germon

Laclau

Robin

et al. 2020

Forest Ecology and Management

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While the number of studies dealing with fine root dynamics in deep soils layers (depth > 1 m) has increased sharply recently, the phenology, the morphology, the anatomy and the role of deep fine roots are still poorly known in forest ecosystems. This review summarizes the current knowledge on fine root production, mortality and longevity in deep soil layers, mycorrhizal association with deep roots, and the role of deep fine roots on carbon, water and nutrient cycling in forest ecosystems. Plant species are known to be more deeply rooted in tropical ecosystems than in temperate and boreal ecosystems, but deep-rooted species are common in a wide range of climates. Deep fine roots are highly plastic in response to changes in environmental conditions and soil resources. Recent studies show that functional traits can be different for deep and shallow roots, with a possible functional specialization of deep fine roots to take up nutrients. With higher vessel diameter and larger tracheid, the anatomy of deep fine roots is also oriented toward water acquisition and transport by increasing the hydraulic conductivity. Deep fine roots can have a great impact on the biogeochemical cycles in many forests (in particular in tropical areas where highly weathered soils are commonly very deep), making it possible to take up water and nutrients over dry periods and contributing to store carbon in the soil. The biogeochemical models in forest ecosystems need to consider the specificity of deep root functioning to better predict carbon, water and nutrient cycling as well as net ecosystem productivity.

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Section: Phenology Of Deep Fine Rootssupporting

confidence: 84%

Tamm Review: Deep fine roots in forest ecosystems: Why dig deeper?

Germon

Laclau

Robin

et al. 2020

Forest Ecology and Management

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“…This finding is consistent with previous physiological studies showing that at the end of the dry season, K‐fertilized trees reached a higher level of water stress than K‐deficient trees (Battie‐Laclau et al ., ,b, ). This drought‐induced effect of K‐fertilization was linked to the enhancement of tree growth rate causing a faster decrease in soil water stocks during dry periods (Christina et al ., ). This was particularly true in our study because of the exceptionally low amount of rainfall during the months preceding sampling (Fig.…”

Section: Discussionmentioning

confidence: 97%

A systems biology view of wood formation in Eucalyptus grandis trees submitted to different potassium and water regimes

et al. 2019

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Summary Wood production in fast‐growing Eucalyptus grandis trees is highly dependent on both potassium (K) fertilization and water availability but the molecular processes underlying wood formation in response to the combined effects of these two limiting factors remain unknown. E. grandis trees were submitted to four combinations of K‐fertilization and water supply. Weighted gene co‐expression network analysis and MixOmics‐based co‐regulation networks were used to integrate xylem transcriptome, metabolome and complex wood traits. Functional characterization of a candidate gene was performed in transgenic E. grandis hairy roots. This integrated network‐based approach enabled us to identify meaningful biological processes and regulators impacted by K‐fertilization and/or water limitation. It revealed that modules of co‐regulated genes and metabolites strongly correlated to wood complex traits are in the heart of a complex trade‐off between biomass production and stress responses. Nested in these modules, potential new cell‐wall regulators were identified, as further confirmed by the functional characterization of EgMYB137. These findings provide new insights into the regulatory mechanisms of wood formation under stressful conditions, pointing out both known and new regulators co‐opted by K‐fertilization and/or water limitation that may potentially promote adaptive wood traits.

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“…Water use efficiency results did not show any advantage in applying more K than strictly needed for growth needs, but, as previously mentioned, the experimental bias linked to the delay in plant development did not allow us to form a conclusion. Hence, although K nutrition did partially compensate for water shortage in terms of leaf area and biomass, this may represent a real risk in terms of water mass balance whenever irrigation is not sufficient [65]. Our overall findings suggest that there was no significant advantage to over-fertilizing water-stressed plants with K. The highest level of K fertilization applied to the water-stressed plants did not allow the main plant growth components (green leaf area, leaf lifespan, root biomass, and shoot biomass) to be as high as the well-watered plants fertilized with a non-excessive quantity of K. From a practical point of view, we recommend that farmers should identify their soil-limiting parameters by obtaining soil analysis, and by adapting mineral inputs to the irrigation water facilities.…”

Section: Finally What Didmentioning

confidence: 99%

How Does Water-Stressed Corn Respond to Potassium Nutrition? A Shoot-Root Scale Approach Study under Controlled Conditions

et al. 2018

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Potassium (K) is generally considered as being closely linked to plant water dynamics. Consequently, reinforcing K nutrition, which theoretically favors root growth and specific surface, extends leaf lifespan, and regulates stomatal functioning, is often used to tackle water stress. We designed a greenhouse pot-scale device to test these interactions on corn (Zea mays L.), and to analyze their links to plant transpiration. Three levels of K nutrition were combined with two water-supply treatments. Shoot and root development and growth were continuously measured during a 60-day-long experiment. Individual plant transpiration was measured by weighing pots and by calculating water mass balances. The results showed that, although K deficiency symptoms resembled those caused by water shortage, there was no advantage to over-fertilizing water-stressed plants. K failed to decrease either the transpiration per unit leaf surface or to improve water use efficiency. The link between K nutrition and plant transpiration appears solely attributable to the effect of K on leaf area. We conclude that K over-fertilization could ultimately jeopardize crops by enhancing early-stage water transpiration to the detriment of later developmental stages.

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Simulating the effects of different potassium and water supply regimes on soil water content and water table depth over a rotation of a tropical Eucalyptus grandis plantation

Cited by 42 publications

References 65 publications

Tamm Review: Deep fine roots in forest ecosystems: Why dig deeper?

Tamm Review: Deep fine roots in forest ecosystems: Why dig deeper?

A systems biology view of wood formation in Eucalyptus grandis trees submitted to different potassium and water regimes

How Does Water-Stressed Corn Respond to Potassium Nutrition? A Shoot-Root Scale Approach Study under Controlled Conditions

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