The effect of nitrogen source and levels on hybrid aspen tree physiology and wood formation

Renström, Anna; Choudhary, Shruti; Gandla, Madhavi Latha; Jönsson, Leif J.; Hedenström, Mattias; Jämtgård, Sandra; Tuominen, Hannele

doi:10.1111/ppl.14219

Physiologia Plantarum

2024

DOI: 10.1111/ppl.14219

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The effect of nitrogen source and levels on hybrid aspen tree physiology and wood formation

Anna Renström,

Shruti Choudhary,

Madhavi Latha Gandla

et al.

Abstract: Nitrogen can be taken up by trees in the form of nitrate, ammonium and amino acids, but the influence of the different forms on tree growth and development is poorly understood in angiosperm species like Populus. We studied the effects of both organic and inorganic forms of nitrogen on growth and wood formation of hybrid aspen trees in experimental conditions that allowed growth under four distinct steady‐state nitrogen levels. Increased nitrogen availability had a positive influence on biomass accumulation an… Show more

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Cited by 4 publications

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Unraveling the dynamics of lignin chemistry on decomposition to understand its contribution to soil organic matter accumulation

Thirunavukkarasu,

Hedenström,

Sparrman

et al. 2024

Plant Soil

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Aims Plant inputs are the primary organic carbon source that transforms into soil organic matter (SOM) through microbial processing. One prevailing view is that lignin plays a major role in the accumulation of SOM. This study investigated lignin decomposition using wood from different genotypes of Populus tremula as the model substrate. The genotypes naturally varied in lignin content and composition, resulting in high and low lignin substrates. Methods The wood was inoculated with fresh soil and decomposition was interpreted through mass loss and CO2 produced during a 12-month lab incubation. Detailed information on the decomposition patterns of lignin was obtained by Two-dimensional Nuclear magnetic resonance (2D NMR) spectroscopy on four occasions during the incubations. Results The lignin content per se did not affect the overall decomposition and ~ 60% of the mass was lost in both substrates. In addition, no differences in oxidative enzyme activity could be observed, and the rate of lignin decomposition was similar to that of the carbohydrates. The 2D NMR analysis showed the oxidized syringyl present in the initial samples was the most resistant to degradation among lignin subunits as it followed the order p-hydroxybenzoates > syringyl > guaiacyl > oxidized syringyl. Furthermore, the degradability of β–O–4 linkages in the lignin varied depending on the subunit (syringyl or guaiacyl) it is attached to. Conclusions Our study demonstrates that lignin contains fractions that are easily degradable and can break down alongside carbohydrates. Thus, the initial differences in lignin content per se do not necessarily affect magnitude of SOM accumulation.

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Unraveling the dynamics of lignin chemistry on decomposition to understand its contribution to soil organic matter accumulation

Thirunavukkarasu,

Hedenström,

Sparrman

et al. 2024

Plant Soil

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Wood formation in trees responding to nitrogen availability

Lu,

Zheng,

Zhang

et al. 2024

Industrial Crops and Products

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Impacts of nitrogen deposition on Zanthoxylum bungeanum and intercropped plants: assessing growth, chlorophyll fluorescence and yields across diverse cultivation systems

Li,

Pan,

et al. 2024

Journal of Plant Ecology

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The study aimed to thoroughly investigate the effects of nitrogen deposition on the growth, chlorophyll fluorescence, and yield of Zanthoxylum bungeanum Maxim. in both monoculture and intercropping systems with Capsicum annuum L. and Glycine max. The research provided a detailed evaluation of how nitrogen deposition influenced soil and plant parameters within these intercropping systems. Key findings include: (1) In the Z. bungeanum monoculture, nitrogen deposition led to a 346.51% increase in soil NO3- levels, significantly affecting chlorophyll fluorescence parameters and decreasing soil pH. (2) In the Z. bungeanum-C. annuum intercropping system, nitrogen deposition influenced the growth and chlorophyll fluorescence of both crops, and resulted in a 261.54% increase in the root length of C. annuum. (3) In the Z. bungeanum-G. max system, nitrogen deposition negatively impacted the chlorophyll fluorescence of G. max, reduced Z. bungeanum yields by 89.27%, and altered its chlorophyll fluorescence parameters. This changes likely hindered the nitrogen-fixing capacity of G. max due to altered soil conditions. Overall, the Z. bungeanum-C. annuum system showed superior performance by enhancing soil NO3--N content. In contrast, the Z. bungeanum-G. max system experienced reduced yields due to the adverse effcts of nitrogen deposition on symbiotic nitrogen fixation. These findings are crucial for developing agricultural strategies aimed at improving crop adaptability and yield in response to environmental changes.

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The effect of nitrogen source and levels on hybrid aspen tree physiology and wood formation

Cited by 4 publications

References 64 publications

Unraveling the dynamics of lignin chemistry on decomposition to understand its contribution to soil organic matter accumulation

Unraveling the dynamics of lignin chemistry on decomposition to understand its contribution to soil organic matter accumulation

Wood formation in trees responding to nitrogen availability

Impacts of nitrogen deposition on Zanthoxylum bungeanum and intercropped plants: assessing growth, chlorophyll fluorescence and yields across diverse cultivation systems

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