Distinct effect of pH on N uptake and assimilation in two conifer species

Meng, Sen; Zhang, Chunxia; Су, Ли; Li, Yiming; Cao, Yang; Zhong, Zhao

doi:10.1007/s00468-016-1394-5

Cited by 9 publications

(6 citation statements)

References 45 publications

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“…This result was different from the results reported by Huang et al [34]. Different forms of nitrogen have significant impacts on the pH of the plant root environment [35]; alkaline medium is conducive to the absorption of NH4 + by plant roots and reduces the content of NH4 + -N in soil [36]. Therefore, the high concentration of NH4 + -N in the rhizosphere soil reduced the pH, and some microbiomes could not adapt to the acidic environment, resulting in a decrease in diversity.…”

Section: Effects Of Different Soil Environments On the Rhizosphere Ba...contrasting

confidence: 72%

Soil Type Influences Rhizosphere Bacterial Community Assemblies of Pecan Plantations, a Case Study of Eastern China

Tang

Liu

Bao

et al. 2022

Forests

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The rhizosphere microbiome is closely related to forest health and productivity. However, whether soil type affects pecan (Carya illinoinensis) rhizosphere microbiomes is unclear. We aimed to explore the diversity and structural characteristics of rhizosphere bacteria associated with pecan plantations grown in three soil types (Luvisols, Cambisols, Solonchaks) in Eastern China and analyze their potential functions through high-throughput sequencing. The results showed that the diversity and community structure of rhizosphere bacteria in pecan plantations were significantly affected by soil type and the pH, available phosphorus content, electrical conductivity, soil moisture, and ammonium nitrogen contents were the main factors. At the phylum level, the rhizosphere bacterial community composition was consistent, mainly included Actinobacteria, Proteobacteria, Acidobacteria, and Chloroflexi. At the family level, the pecan plantations formed different rhizosphere enriched biomarkers due to the influence of soil type, with functional characteristics such as plant growth promotion and soil nutrient cycling. In addition, there existed low abundance core species such as Haliangiaceae, Bryobacteraceae, and Steroidobacteraceae. They played important roles in the rhizosphere environments through their functional characteristics and community linkages. Overall, this study provides a basis for the study of the rhizosphere microbiome in different soil types of pecan plantations, and plays an important role in the sustainable management of forest soil.

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Section: Effects Of Different Soil Environments On the Rhizosphere Ba...contrasting

confidence: 72%

Soil Type Influences Rhizosphere Bacterial Community Assemblies of Pecan Plantations, a Case Study of Eastern China

Tang

Liu

Bao

et al. 2022

Forests

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“…This was also found for other plants such as Picea abies (Peuke and Tischner, 1991), wheat (Zsoldos et al, 1999), Chinese fir (Meng et al, 2016), Douglas fir, Pinus contorta and soybean (Hawkins and Robbins, 2010). Furthermore, P. asperata, regardless of N availability and pH, always exhibited a greater uptake of NH þ 4 in compare to that of NO À 3 , which is in line with previous results that the preference of conifers would be NH þ 4 (Lucash et al, 2005;Meng et al, 2016). This result might be partly explained by the fact that the NH þ 4 preference of P. asperata may be an adaptive strategy to the greater availability of NH þ 4 in forest soils.…”

Section: The Physiological Regulation In Spruce Tosupporting

confidence: 65%

“…5a, d), because NO À 3 uptake is directly associated with the reduction rate of NO À 3 to nitrite (Calatayud et al, 2008). This was also found for other plants such as Picea abies (Peuke and Tischner, 1991), wheat (Zsoldos et al, 1999), Chinese fir (Meng et al, 2016), Douglas fir, Pinus contorta and soybean (Hawkins and Robbins, 2010). Furthermore, P. asperata, regardless of N availability and pH, always exhibited a greater uptake of NH þ 4 in compare to that of NO À 3 , which is in line with previous results that the preference of conifers would be NH þ 4 (Lucash et al, 2005;Meng et al, 2016).…”

Section: The Physiological Regulation In Spruce Tomentioning

confidence: 60%

Morphological and physiological responses of Picea asperata to different nitrogen availability and pH

Man

Jia

Yin

et al. 2019

J. Plant Nutr. Soil Sci.

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Soil nitrogen (N) availability and pH are two determinants affecting plant growth, both of which are influenced by long‐term N deposition. However, the physiological mechanism of plants response to the changes in soil N availability and pH are not fully understood. To investigate the response of Picea asperata to both factors, seedlings of P. asperata were exposed to 50 or 1000 µM NH4NO3 with pH 5 or pH 7. In the current study, P. asperata, regardless of N availability and pH in growth medium, exhibited invariably a NH4 + preference. Lower root biomass, root : shoot mass ratio, total root length and area, and root vitality were detected in high N condition compared to those in low N supply, corresponding well to lower net influxes of NH4 + and NO3 - at the root surface in both pH treatments. These results indicate that P. asperata may employ an active‐forge strategy to exploit nutrient resources for growth under low N availability, probably by increased below‐ground carbon allocation and net influxes of NH4 + and NO3 - . Although low pH, to some extent may generate more malondialdehyde, P. asperata would enhance pH tolerance by increased detoxification, i.e., antioxidant enzymes (peroxidase), free proline and soluble protein as well as improved carbohydrate status (i.e., soluble sugar and starch).

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“…A non-invasive micro-test technique (NMT), a powerful tool in the investigation of in situ ion fluxes, has been widely used to explore the electrophysiological processes of nitrogen acquisition at the root surface [ 16 ]. Spatial and temporal dynamics of net ion fluxes and influences of environmental factors such as pH in the media on net ion fluxes have been reported for roots of maize, barley, rice, poplar, and species of eucalyptus and coniferous [ 3 , 17 , 18 , 19 ]. Additionally, many studies assume that 15 N at natural abundance levels acts as a tracer, and significant discrimination has been observed for plants [ 20 ].…”

Section: Introductionmentioning

confidence: 99%

Distinct Carbon and Nitrogen Metabolism of Two Contrasting Poplar Species in Response to Different N Supply Levels

Meng

Wang

Quan

et al. 2018

IJMS

Self Cite

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Poplars have evolved various strategies to optimize acclimation responses to environmental conditions. However, how poplars balance growth and nitrogen deficiency remains to be elucidated. In the present study, changes in root development, carbon and nitrogen physiology, and the transcript abundance of associated genes were investigated in slow-growing Populus simonii (Ps) and fast-growing Populus euramericana (Pe) saplings treated with low, medium, and high nitrogen supply. The slow-growing Ps showed a flourishing system, higher δ15N, accelerated C export, lower N uptake and assimilation, and less sensitive transcriptional regulation in response to low N supply. The slow-growing Ps also had greater resistance to N deficiency due to the transport of photosynthate to the roots and the stimulation of root development, which allows survival. To support its rapid metabolism and growth, compared with the slow-growing Ps, the fast-growing Pe showed greater root development, C/N uptake and assimilation capacity, and more responsive transcriptional regulation with greater N supply. These data suggest that poplars can differentially manage C/N metabolism and photosynthate allocation under different N supply conditions.

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Distinct effect of pH on N uptake and assimilation in two conifer species

Cited by 9 publications

References 45 publications

Soil Type Influences Rhizosphere Bacterial Community Assemblies of Pecan Plantations, a Case Study of Eastern China

Soil Type Influences Rhizosphere Bacterial Community Assemblies of Pecan Plantations, a Case Study of Eastern China

Morphological and physiological responses of Picea asperata to different nitrogen availability and pH

Distinct Carbon and Nitrogen Metabolism of Two Contrasting Poplar Species in Response to Different N Supply Levels

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