Variation in Morphological and Physiological Characteristics of Wild <i>Elymus nutans</i> Ecotypes from Different Altitudes in the Northeastern Tibetan Plateau

Qi, Juan; Liu, Wenhui; Jiao, Ting; Hamblin, Ann

doi:10.1155/2020/2869030

Cited by 19 publications

(13 citation statements)

References 36 publications

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“…The altitudes and associated temperature, rainfall, slope and aspect of mountain as well as wind directions are important ecological factors that affect plants morphology, physiology and biochemistry of plants including nutrients compositions. Crops have obvious adaptation strategies by modifying their morphological and physiological characters (Royer et al 2005;Qi et al 2020). The average Ca increased by 0.21% and by 0.26% at higher altitude revealed increase of 0.11% and 0.21% of Fe due to the variation in soil characteristics and climate which determine the uptake of soil nutrients by plants (Begum et al 2015).…”

Section: Nutrient Altitude and Climate Correlationmentioning

confidence: 99%

Nutrients in finger millet and soil at different elevation gradients in Central Nepal

2020

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Background Finger millet, a subsistence food crop, is a unique cereal with high nutritional quality particularly in hilly regions in Nepal. Hence, grain nutrients (protein, calcium, and iron percent) of ten different landraces of finger millet and soil quality (SOC, N, P and K) at different altitudes in central Nepal were analyzed. Methods Triplicate finger millet grain samples were collected from ten local landraces cultivated in randomized complete block design (RCBD) experiments at three different elevations (365 m, 1040 m and 1856 m) under the farmer management system for 2 years 2016 and 2017. Similarly, triplicate soil samples were collected from each experiment plot of different elevation. Kjeldahl method was used to determine grain protein and atomic absorption spectrophotometry method was used to determine calcium and iron. Soil nitrogen (N) was estimated by Kjeldahl method, the available phosphorous (P) by a modified Olsen’s method, potassium by Hanway and Heidel method and pH by using digital pH meter. Results The protein calcium and iron content in finger millet grain was significantly different (P < 0.05) among the local landraces and elevation levels. In all landraces of finger millet, the grain protein, calcium and iron content was found to increase along the increasing altitude. An average increase of 3.13% protein was found when altitude increased from 365 to 1856 m. However, only 2.04% and 1.09% of average grain protein increased as elevation increased from 365 m to 1040 m and 1040 m to 1856 m, respectively. The average Ca content increased by 0.47% when altitude increased from 365 to 1856 m. Similarly, the average Ca increased by 0.21% and by 0.26% as altitude increased from 365 m to 1040 m, and 1040 m to 1856 m, respectively and an average 0.33% Fe increase was found from 365 to 1856 m altitude. An increase of 0.11% and 0.21% of Fe was found from 365 to 1040 m and from 1040 to 1856 m, respectively. Soils at all experimental sites were acidic. The SOC, P, K of soil also increased with increasing altitude. Conclusions This study demonstrated the relationship among nutrients in finger millet (proteins, Ca and Fe), soil components (SOC, N, P and K), and altitudes, with respect to ambient climate. The grain nutrients (Nitrogen, Ca and Fe) of finger millet at higher altitudes were found higher than lower altitudes. Similarly, the temperature and grain nutrients showed strong negative correlation with growing season temperature. This study reveals relations of finger millet nutrients with climatic and soil conditions which are crucial to design the promotion policies of nutrient rich local crops in Nepal.

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Section: Nutrient Altitude and Climate Correlationmentioning

confidence: 99%

Nutrients in finger millet and soil at different elevation gradients in Central Nepal

2020

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“…Elymus nutans is a dominant and constructive grass of meadow steppe, and it is characterized by strong drought, cold and pest resistance. It is widely distributed and survives at elevations ranging from 450 m to 4,500 m. E. nutans is better suited to low altitudes and warmer habitats than K. pygmaea, and an increase in temperature from high to low elevations promotes the growth of E. nutans ( Qi et al, 2020 ). K. pygmaea primarily grows at high altitudes in humid and cold habitats ( Wu et al, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

New insight into the divergent responses of plants to warming in the context of root endophytic bacterial and fungal communities

Wei

Jiang

Han

et al. 2021

PeerJ

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Plant adaptation under climate changes is critical to the maintenance of terrestrial ecosystem structure and function. Studying the response of the endophytic community to climate warming is a novel way to reveal the mechanism of host environmental adaptability because of the prominent role endophytes play in host nutrient acquisition and stress tolerance. However, host performance was generally neglected in previous relevant research, which limits our understanding of the relationships between the endophytic community and host responses to climate warming. The present study selected two plants with different responses to climate warming. Elymus nutans is more suitable for growing in warm environments at low altitude compared to Kobresia pygmaea. K. pygmaea and E. nutans were sampled along an altitude gradient in the natural grassland of Qinghai-Tibet Plateau, China. Root endophytic bacterial and fungal communities were analyzed using high throughput sequencing. The results revealed that hosts growing in more suitable habitats held higher endophytic fungal diversity. Elevation and host identity significantly affected the composition of the root endophytic bacterial and fungal community. 16S rRNA functional prediction demonstrated that hosts that adapted to lower temperatures recruited endophytic communities with higher abundance of genes related to cold resistance. Hosts that were more suitable for warmer and drier environments recruited endophytes with higher abundance of genes associated with nutrient absorption and oxidation resistance. We associated changes in the endophytic community with hosts adaptability to climate warming and suggested a synchronism of endophytic communities and hosts in environmental adaptation.

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“…Abiotic conditions influenced photosynthetic activity and plant nitrogen concentrations thereby regulating non-structural carbohydrate production. The interplay of factors were expressed in the various ways of partitioning assimilates into structural components in plants (Millard et al 2007, Qi et al 2020. The assessment of photosynthetic activity of giant bamboo in varying elevations, therefore should be further assessed in future research.…”

Section: Abiotic Effects On Plant Morphologymentioning

confidence: 99%

Influence of Abiotic Factors on Growth and Development of Giant Bamboo (Dendrocalamus Asper) in Bukidnon, Philippines

Aribal¹,

Parlucha²,

Gelaga³

et al. 2022

JTFS

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The study examines the gross morphology of giant bamboo (Dendrocalamus asper) relative to varying elevation, temperature, and relative humidity in five forest areas of Bukidnon province in the Philippines. Results revealed that variations in leaf sizes and the number of nodes and internodes among elevation ranges were not significant. However, the culm length of giant bamboo was significantly higher in the mid-elevation range (644–892 m asl) and lower elevation range (344–447 m asl) compared to culms in higher elevations. In addition, differences in culm diameter and culm thickness were significant showing larger diameter and thicker culms in the mid-elevation range (644–892 m asl) as compared to the higher (1117–1124 m asl) and lower (344–347 m asl) elevation range. The level of phosphorus and nitrogen was the highest in the mid and lower elevation range while potassium level was abundant in the highest elevations. Correlation analysis showed a negative relationship between culm lengths to elevation and relative humidity while mid and top section diameters were negatively correlated to temperature until 892 m asl. Leaf area and leaf width were strongly influenced by phosphorus level. The canonical correspondence analysis showed culm lengths were affected by relative humidity and elevation while the number of nodes and internodes, top and mid-section culm thickness, average diameter and basal section diameters were affected by temperature. Non-metric multidimensional scaling revealed that variation in bamboo morphology occured at the lowest and highest elevation while overall similarity was observed at 600–900 m asl elevation, suggesting an optimal growth for giant bamboo might be within the range.

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Variation in Morphological and Physiological Characteristics of Wild Elymus nutans Ecotypes from Different Altitudes in the Northeastern Tibetan Plateau

Cited by 19 publications

References 36 publications

Nutrients in finger millet and soil at different elevation gradients in Central Nepal

Nutrients in finger millet and soil at different elevation gradients in Central Nepal

New insight into the divergent responses of plants to warming in the context of root endophytic bacterial and fungal communities

Influence of Abiotic Factors on Growth and Development of Giant Bamboo (Dendrocalamus Asper) in Bukidnon, Philippines

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