Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy
Putra R, Waterman JM, Mathesius U, Wojtalewicz D, Powell JR, Hartley SE, Johnson SN (2022)
Plant and Soil 477: 201-217.
Zeitschriftenaufsatz
| Veröffentlicht | Englisch
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Autor*in
Putra, RockyUniBi ;
Waterman, Jamie M.;
Mathesius, Ulrike;
Wojtalewicz, Dominika;
Powell, Jeff R.;
Hartley, Susan E.;
Johnson, Scott N.
Einrichtung
Abstract / Bemerkung
**Aims**
Silicon (Si) uptake and accumulation improves plant resilience to environmental stresses, but most studies examining this functional role of Si have focussed on grasses (Poaceae) and neglected other important plant groups, such as legumes (Fabaceae). Legumes have evolved a symbiotic relationship with nitrogen-fixing bacteria (rhizobia) housed in root nodules. Our study determined the impacts of silicon (Si) supplementation onMedicago truncatulainoculated withEnsifer melilotirhizobial strains that differed in their capacity for nitrogen fixation: Sm1021 (‘low-efficiency’) or Sm1022 (‘high-efficiency’). **Methods**
We examined how Si and rhizobial efficacy influence nodule and plant functional traits, including their chemical aspects. These combinations were supplied with or without Si in a glasshouse experiment, where we quantified nodule flavonoids and foliar chemistry (free amino acids, soluble protein, elemental C, N and Si). **Results**
Si supply increased nodule number per plant, specific nodule flavonoid concentrations, contents of foliar nitrogenous compounds and foliar C, but not foliar Si. We also demonstrated that rhizobial efficacy altered the magnitude of Si effects on certain traits. For example, Si significantly promoted concentrations of foliar N and soluble protein in the plants associated with the ‘low-efficiency’ strain only, and this was not the case with the ‘high-efficiency’ one. **Conclusions**
Collectively, our study indicates that Si generates positive effects onM. truncatula, particularly when the association with rhizobia is relatively inefficient, and may play a more prominent role in rhizobial functionality than previously thought.
Silicon (Si) uptake and accumulation improves plant resilience to environmental stresses, but most studies examining this functional role of Si have focussed on grasses (Poaceae) and neglected other important plant groups, such as legumes (Fabaceae). Legumes have evolved a symbiotic relationship with nitrogen-fixing bacteria (rhizobia) housed in root nodules. Our study determined the impacts of silicon (Si) supplementation onMedicago truncatulainoculated withEnsifer melilotirhizobial strains that differed in their capacity for nitrogen fixation: Sm1021 (‘low-efficiency’) or Sm1022 (‘high-efficiency’). **Methods**
We examined how Si and rhizobial efficacy influence nodule and plant functional traits, including their chemical aspects. These combinations were supplied with or without Si in a glasshouse experiment, where we quantified nodule flavonoids and foliar chemistry (free amino acids, soluble protein, elemental C, N and Si). **Results**
Si supply increased nodule number per plant, specific nodule flavonoid concentrations, contents of foliar nitrogenous compounds and foliar C, but not foliar Si. We also demonstrated that rhizobial efficacy altered the magnitude of Si effects on certain traits. For example, Si significantly promoted concentrations of foliar N and soluble protein in the plants associated with the ‘low-efficiency’ strain only, and this was not the case with the ‘high-efficiency’ one. **Conclusions**
Collectively, our study indicates that Si generates positive effects onM. truncatula, particularly when the association with rhizobia is relatively inefficient, and may play a more prominent role in rhizobial functionality than previously thought.
Erscheinungsjahr
2022
Zeitschriftentitel
Plant and Soil
Band
477
Seite(n)
201 - 217
Urheberrecht / Lizenzen
ISSN
0032-079X
eISSN
1573-5036
Page URI
https://pub.uni-bielefeld.de/record/2961782
Zitieren
Putra R, Waterman JM, Mathesius U, et al. Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy. Plant and Soil. 2022;477:201-217.
Putra, R., Waterman, J. M., Mathesius, U., Wojtalewicz, D., Powell, J. R., Hartley, S. E., & Johnson, S. N. (2022). Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy. Plant and Soil, 477, 201-217. https://doi.org/10.1007/s11104-022-05358-9
Putra, Rocky, Waterman, Jamie M., Mathesius, Ulrike, Wojtalewicz, Dominika, Powell, Jeff R., Hartley, Susan E., and Johnson, Scott N. 2022. “Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy”. Plant and Soil 477: 201-217.
Putra, R., Waterman, J. M., Mathesius, U., Wojtalewicz, D., Powell, J. R., Hartley, S. E., and Johnson, S. N. (2022). Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy. Plant and Soil 477, 201-217.
Putra, R., et al., 2022. Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy. Plant and Soil, 477, p 201-217.
R. Putra, et al., “Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy”, Plant and Soil, vol. 477, 2022, pp. 201-217.
Putra, R., Waterman, J.M., Mathesius, U., Wojtalewicz, D., Powell, J.R., Hartley, S.E., Johnson, S.N.: Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy. Plant and Soil. 477, 201-217 (2022).
Putra, Rocky, Waterman, Jamie M., Mathesius, Ulrike, Wojtalewicz, Dominika, Powell, Jeff R., Hartley, Susan E., and Johnson, Scott N. “Benefits of silicon-enhanced root nodulation in a model legume are contingent upon rhizobial efficacy”. Plant and Soil 477 (2022): 201-217.
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