The carboxylate‐releasing phosphorus‐mobilizing strategy can be proxied by foliar manganese concentration in a large set of chickpea germplasm under low phosphorus supply

Pang, Jiayin; Bansal, Ruchi; Zhao, Hongxia; Bohuon, Emilien; Lambers, Hans; Ryan, Megan H.; Ranathunge, Kosala; Siddique, Kadambot H. M.

doi:10.1111/nph.15200

Cited by 137 publications

(96 citation statements)

References 55 publications

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“…Acacia rostellifera foliar Mn increased with soil age in all soil treatments, and this trend was particularly strong in the “field soil” as soil P declined. Increase in foliar Mn is consistent with greater reliance on carboxylates for P acquisition in P‐poor soils (Abrahão, Ryan, Laliberté, Oliveira, & Lambers, ; Lambers et al., ; Pang et al., ). Interestingly, this trend remained in the average and specific inoculum soil treatments suggesting that specific fungi may have led to increased carboxylate exudation.…”

Section: Discussionmentioning

confidence: 74%

Plasticity in root symbioses following shifts in soil nutrient availability during long‐term ecosystem development

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Laliberté

2018

Journal of Ecology

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The vast majority of terrestrial plants form root symbioses with arbuscular mycorrhizal (AM) fungi to enhance nutrient (particularly phosphorus, P) acquisition. However, some plant species also form dual symbioses involving ectomycorrhizal (ECM) fungi, with a subset of those also forming triple symbioses also involving dinitrogen (N2)‐fixing bacteria. It has been suggested that these plants show plasticity in root symbioses to optimise nutrient acquisition depending on the type and strength of soil nutrient limitation (e.g., N vs. P), yet empirical evidence remains limited. Alternatively, the degree of investment or “preference” in particular root symbioses might simply reflect differences in inoculum potential among soils of contrasting nutrient availability, reflecting adaptations of root symbionts to different edaphic conditions. Here, we grew two co‐occurring plant species forming triple (AM/ECM/N2‐fixing; Acacia rostellifera) or dual (AM/ECM; Melaleuca systena) symbioses in soils of increasing age and contrasting nutrient availability from an Australian long‐term soil chronosequence to disentangle the relative importance of abiotic factors (e.g., soil nutrient availability and stoichiometry) and biotic factors (e.g., soil inoculum potential) in determining root colonisation patterns and functional outcomes of these multiple root symbioses. For both plant species, we found clear hump‐shaped plant growth patterns along the pedogenesis‐driven gradient in soil nutrient availability, with peak growth in intermediate‐aged soils, while high levels of mycorrhizal colonisation by the “preferred” root symbionts were maintained across all soils. We found large increases (540%) in foliar manganese concentrations with increasing soil age and declining P availability, suggesting that plants may be relying on the release of carboxylates to help acquire P in the most P‐impoverished soils. Finally, we found that soil abiotic properties, such as strong differences in soil nutrient availability, are generally more important than soil inoculum potential in explaining these shifts in our plant and root responses. Synthesis. Our study suggests that plants capable of forming multiple root symbioses show plasticity in their nutrient‐acquisition strategies following shifts in soil nutrients during long‐term ecosystem development, yet maintain a preference for certain root symbionts despite changes in soil microbial inoculum.

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Section: Discussionmentioning

confidence: 74%

Plasticity in root symbioses following shifts in soil nutrient availability during long‐term ecosystem development

Teste

Laliberté

2018

Journal of Ecology

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“…Typical root morphological strategies include vigorous root branching, high specific root length, and increased frequency and length of root hairs; together, these result in a larger volume of soil being explored (Vance et al ., ; Postma et al ., ; Haling et al ., ). Additionally, plants can also employ root physiological or P‐mining strategies such as increased carboxylate, phosphatase and proton release (termed P‐mobilizing exudates here) into the rhizosphere to mobilize sparingly soluble inorganic and organic P (Hinsinger et al ., ; Richardson et al ., ; Pang et al ., ). Furthermore, P deficiency can also induce establishment of symbioses with arbuscular mycorrhizal fungi (AMF); the external hyphae of AMF can access P from the labile inorganic soil P pool beyond root P‐depletion zones, and explore micropores that roots or even root hairs cannot enter (Clark & Zeto, ; Smith et al ., ; van der Heijden et al ., ).…”

Section: Introductionmentioning

confidence: 97%

Tradeoffs among root morphology, exudation and mycorrhizal symbioses for phosphorus‐acquisition strategies of 16 crop species

et al. 2019

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Summary Plant roots exhibit diverse root functional traits to enable soil phosphorus (P) acquisition, including changes in root morphology, root exudation and mycorrhizal symbioses. Yet, whether these traits are differently coordinated among crop species to enhance P acquisition is unclear. Here, eight root functional traits for P acquisition were characterized in 16 major herbaceous crop species grown in a glasshouse under limiting and adequate soil P availability. We found substantial interspecific variation in root functional traits among species. Those with thinner roots showed more root branching and less first‐order root length, and had consistently lower colonization by arbuscular mycorrhizal fungi (AMF), fewer rhizosheath carboxylates and reduced acid phosphatase activity. In response to limiting soil P, species with thinner roots showed a stronger response in root branching, first‐order root length and specific root length of the whole root system, Conversely, species with thicker roots exhibited higher colonization by AMF and/or more P‐mobilizing exudates in the rhizosheath. We conclude that, at the species level, tradeoffs occur among the three groups of root functional traits we examined. Root diameter is a good predictor of the relative expression of these traits and how they change when P is limiting.

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“…Community‐weighted manganese concentrations [Mn] in mature leaves can be used as a proxy for nutrient‐acquisition strategies (Lambers, Hayes, Laliberté, Oliveira, & Turner, ), because carboxylates release both soil P and soil‐bound Mn (Lambers, Chapin, & Pons, ; Lambers et al, ). As a result, carboxylate‐releasing plants accumulate Mn in leaves (Gardner & Boundy, ; Lambers et al, ; Pang et al, ). Conversely, AM fungi intercept Mn, decreasing leaf [Mn] in host plants (Kothari, Marschner, & Römheld, ).…”

Section: Introductionmentioning

confidence: 99%

Vellozioid roots allow for habitat specialization among rock‐ and soil‐dwelling Velloziaceae in campos rupestres

et al. 2019

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1. Plant growth on harsh substrates (habitat specialization) requires specific traits to cope with stressful conditions. 2. We tested whether traits related to nutrient acquisition (root colonization by fungal symbionts, and plant morphological and physiological specializations), and nutrient use (leaf nitrogen (N) and phosphorus (P) concentrations and N-and P-remobilization efficiency), were related to habitat specialization for 27 species of Velloziaceae growing either in soil or on rocks in extremely P-impoverished campos rupestres habitats. If habitat specialization were to drive trait sorting, then we expect traits to differ between those substrates.3. Both soil and rock-dwelling species presented a very low proportion of root length colonized by arbuscular mycorrhizal and dark-septate fungi. However, rhizosheaths were only observed in soil-dwelling species, and vellozioid roots, a specialization that allows for mining P and dissolving quartzite rock, were mostly found in rock-dwelling species. We did not observe differences in nutrient-use traits between rock-and soil-dwelling species.4. Root specializations are strongly correlated with microhabitats, and the presence of vellozioid roots seems to mediate bare rock specialization. There is an overall P limitation of plant productivity both on rock and in soil of campos rupestres, which does not drive the sorting of traits related to above-ground nutrient use and symbiotic P acquisition. Therefore, nutrient impoverishment is indeed a very strong environmental filter in campos rupestres as a whole, but habitat specialization plays an important role in the spatial distribution of Velloziaceae between contrasting substrates.

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The carboxylate‐releasing phosphorus‐mobilizing strategy can be proxied by foliar manganese concentration in a large set of chickpea germplasm under low phosphorus supply

Cited by 137 publications

References 55 publications

Plasticity in root symbioses following shifts in soil nutrient availability during long‐term ecosystem development

Plasticity in root symbioses following shifts in soil nutrient availability during long‐term ecosystem development

Tradeoffs among root morphology, exudation and mycorrhizal symbioses for phosphorus‐acquisition strategies of 16 crop species

Vellozioid roots allow for habitat specialization among rock‐ and soil‐dwelling Velloziaceae in campos rupestres

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