Variable silicon accumulation in plants affects terrestrial carbon cycling by controlling lignin synthesis

Klotzbücher, Thimo; Klotzbücher, Anika; Kaiser, Klaus; Vetterlein, Doris; Jahn, Reinhold; Mikutta, Robert

doi:10.1111/gcb.13845

Cited by 80 publications

(79 citation statements)

References 41 publications

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“…For references of the wave numbers for the different compounds see Table 1. This relative decrease in contribution of carbohydrates is not necessarily in contradiction with the reported reduction of absolute carbohydrate concentration due to increased Si content (Schoelynck et al 2010;Schaller et al 2012a;Klotzbücher et al 2018). It was already suggested that Si accumulation leads to a decrease in cellulose, lignin and phenol concentrations in plants (Schoelynck et al 2010;Schaller et al 2012a;Klotzbücher et al 2018).…”

Section: Discussionmentioning

confidence: 54%

“…It was shown that Si content is negatively related to carbon contents in aboveground biomass of plants (Neu et al 2017;Klotzbücher et al 2018). It was also found that Si content affects the carbon quality of aboveground plant biomass.…”

Section: Introductionmentioning

confidence: 99%

“…It was also found that Si content affects the carbon quality of aboveground plant biomass. Silicon content seems to be negatively related to plant phenol content (Schaller et al 2012a), is both either increasing or decreasing plant cellulose content (Schoelynck et al 2010;Schaller et al 2012a), depending on species, and has negative or no obvious effect on plant lignin content (Schoelynck et al 2010;Schaller et al 2012a;Klotzbücher et al 2018).…”

Section: Introductionmentioning

confidence: 99%

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Silicon accumulation in rice plant aboveground biomass affects leaf carbon quality

et al. 2019

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Background and aim Silicon is known to be able to substitute carbon in plant biomass, especially in cellulose, lignin and phenols. However, a more comprehensive picture regarding the effect of silicon accumulation on plant carbon quality (cellulose, lignin, phenol, wax, lipids, and free organic acids content) with regard to potential decomposability is still missing. Methods Two different rice varieties (French brown and red rice cultivars) were cultivated under five different soil silicon availabilities. After maturity we harvested the plants and analyzed them regarding carbon quality by FTIR spectroscopy and regarding plant silicon concentrations. Results Silicon accumulation was found to be dependent on silicon availability and on the specific rice cultivar. The lowering of carbon compounds content by silicon was found not to be restricted to cellulose, lignin and phenol. Silicon accumulation was able to decrease other carbon compounds such as fat, wax, lipids, and free organic acids, too. Conclusions Consequently, silicon is important for the carbon quality of silicon accumulating plants. Furthermore, silicon accumulation in plants is interfering with a large range of different carbon compounds potentially altering the leaf economic spectra, decomposability, and thus potentially interfering with the whole performance of ecosystems dominated by silicon accumulating plant species.

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Section: Discussionmentioning

confidence: 54%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Silicon accumulation in rice plant aboveground biomass affects leaf carbon quality

et al. 2019

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“…Secondly, several studies have found negative correlations between silicon and total carbon, phenolics and lignin, indicating a consistent carbon–silicon trade‐off in plants (Frew, Powell, Sallam, Allsopp, & Johnson, 2016; Klotzbücher et al, 2018). The proposed mechanism for this trade‐off is that grasses can use Si as a substitute for more energetically costly carbon‐based compounds (e.g.…”

Section: Discussionmentioning

confidence: 98%

Elevated atmospheric CO₂ suppresses jasmonate and silicon‐based defences without affecting herbivores

et al. 2020

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1. Elevated atmospheric CO 2 (eCO 2 ) not only increases plant growth but can also interfere with defence against insect herbivory through the disruption of the jasmonic acid (JA) pathway. Silicon (Si) plays an important role in plant stress tolerance and resistance to herbivory, particularly in grasses, many of which accumulate high amounts of Si. Activation of the JA pathway has been reported to stimulate Si uptake, while Si supplementation can alter both constitutive and induced phytohormone levels. A reduction in JA concentration under eCO 2 has the potential to reduce Si uptake in plants. Using both Si supplemented (Si+) and control (Si−) plants (Brachypodium distachyon)grown under ambient (400 ppm) and elevated (640 ppm) CO 2 concentrations, we tested how plant growth, foliar Si concentration and endogenous JA responded to methyl jasmonate (MeJA) application and the subsequent effects on insect herbivore performance (Helicoverpa armigera). Elevated CO2 reduced Si concentration by 19% and endogenous JA by 70% on average. MeJA significantly increased Si concentration in Si+ plants. Si+ plants had higher baseline JA levels compared to Si− plants under control conditions (i.e. no stress), however, when plants were chemically induced with MeJA, the JA response was on average 84% lower in Si+ plants compared to Si− plants. Plants without MeJA treatment showed the opposite response, that is, Si+ plants had higher baseline JA levels compared to Si− plants. Si significantly reduced herbivore consumption and growth rate. Despite eCO 2 significantly reducing both Si and endogenous JA, no effect was seen on herbivores feeding on eCO 2 plants. 4. Collectively our results suggest that Si alters the JA response of plants. We show that JA induces Si uptake, however, Si then reduces the JA response of plants under induced stress conditions. However, predicted increases in CO 2 levels within this century may significantly reduce Si-based mechanical defences against herbivory via a reduction of endogenous JA. K E Y W O R D S elevated CO 2 , herbivory, jasmonic acid, plant defence, silica S U PP O RTI N G I N FO R M ATI O N Additional supporting information may be found online in the Supporting Information section. How to cite this article: Hall CR, Mikhael M, Hartley SE, Johnson SN. Elevated atmospheric CO 2 suppresses jasmonate and silicon-based defences without affecting herbivores. Funct

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“…Hashemi, Abdolzadeh, and Sadeghipour () showed that Si prevents an increased cell wall lignification in plants under salinity stress. In addition, there is evidence for a trade‐off between carbon‐based compounds and Si‐based defences in some Si‐accumulator plants, in which Si‐treated plants may exhibit reduced carbon compounds (Cooke & Leishman, ; Frew, Powell, Sallam, Allsopp, & Johnson, ; Klotzbücher et al, ; Schaller, Brackhage, & Dudel, ). However, in relation to lignin, hemicellulose and cellulose contents, collard was not influenced by Si fertilization under different conditions of soil moisture.…”

Section: Discussionmentioning

confidence: 99%

Combined effects of soil silicon and drought stress on host plant chemical and ultrastructural quality for leaf‐chewing and sap‐sucking insects

Teixeira

Valim

Oliveira

et al. 2019

J Agronomy Crop Science

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It was postulated that Si‐mediated plant resistance to herbivory changes with soil water status, increasing when plants are under drought stress. We subjected collard (Brassica oleracea) to such soil variables and assessed plant responses and effects on the leaf‐chewing larvae of Plutella xylostella and the sap‐sucking aphid Brevicoryne brassicae. Silicon accumulated in collard leaves independently of soil water conditions, but it influenced mainly drought‐stressed plants. Silicon suppressed harmful effects of drought on leaf and root length and raised leaf water content and stomatal size to the same conditions of well‐watered plants. Drought stress reduced hemicellulose and cellulose, but Si did not influence them or lignin. Combination of drought and Si increased total and soluble leaf nitrogen. Drought decreased total glucosinolates, but Si increased such defence metabolites to similar concentrations that were found in well‐watered plants. Nutritional changes mediated by drought and Si in fibre, leaf water content, soluble nitrogen and glucosinolates did not increase insect performance in any feeding guild. Instead, caterpillars performed worse in drought‐stressed or Si‐treated collards, mainly in plants under combined conditions. Silicon improved plant resistance to drought and herbivore stresses.

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Variable silicon accumulation in plants affects terrestrial carbon cycling by controlling lignin synthesis

Cited by 80 publications

References 41 publications

Silicon accumulation in rice plant aboveground biomass affects leaf carbon quality

Silicon accumulation in rice plant aboveground biomass affects leaf carbon quality

Elevated atmospheric CO₂ suppresses jasmonate and silicon‐based defences without affecting herbivores

Combined effects of soil silicon and drought stress on host plant chemical and ultrastructural quality for leaf‐chewing and sap‐sucking insects

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Variable silicon accumulation in plants affects terrestrial carbon cycling by controlling lignin synthesis

Cited by 80 publications

References 41 publications

Silicon accumulation in rice plant aboveground biomass affects leaf carbon quality

Silicon accumulation in rice plant aboveground biomass affects leaf carbon quality

Elevated atmospheric CO2 suppresses jasmonate and silicon‐based defences without affecting herbivores

Combined effects of soil silicon and drought stress on host plant chemical and ultrastructural quality for leaf‐chewing and sap‐sucking insects

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Elevated atmospheric CO₂ suppresses jasmonate and silicon‐based defences without affecting herbivores