Does nitrogen fertilization impact nonstructural carbohydrate storage in evergreen <i>Podocarpus macrophyllus</i> saplings?

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Does nitrogen fertilization impact nonstructural carbohydrate storage in evergreen Podocarpus macrophyllus saplings?

Renshan Li , Jianming Han , Liqiong Zhu , Lijun Zhao , Xiangling Huang , Mingyue Zhang , Qingpeng Yang , Weidong Zhang

Journal of Forestry Research ›› 2020, Vol. 32 ›› Issue (4) : 1653 -1661.

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Journal of Forestry Research ›› 2020, Vol. 32 ›› Issue (4) : 1653 -1661. DOI: 10.1007/s11676-020-01181-z

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Does nitrogen fertilization impact nonstructural carbohydrate storage in evergreen Podocarpus macrophyllus saplings?

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Abstract

Nonstructural carbon (NSC), which represents the relationship between the carbon source and carbon sink, is an important factor that reflects the functions and performance of a tree. However, little is known regarding the time-series responses of NSC storage in evergreen species to different nitrogen (N) fertilization regimes. This study, which was based on a pot experiment, examined the response of the NSC (soluble sugars and starch) storage to different N addition intensities [light N addition (LN): 6.5 g N m⁻² a⁻¹; moderate N addition (MN): 13.0 g N m⁻² a⁻¹; and heavy N addition (HN): 26.0 g N m⁻² a⁻¹)] in saplings of the evergreen species Podocarpus macrophyllus. Our results showed that the net photosynthetic rate (P _n) under MN was significantly higher than that under LN, but was comparable to that under HN. Moreover, saplings subject to MN had a significant higher leaf biomass than that to LN and HN. These results indicated that the C supply via photosynthesis under MN was greater than that under LN and HN. The NSCs reserve under MN was considerable with that under LN, which suggested that saplings in MN group consumed higher and stored lower properties of NSCs than those in LN group. However, saplings under HN stored higher properties of NSCs than those under MN considering that no difference in NSCs pools was found between the two treatments. The leaf N concentrations were found in the increasing sequence of LN < MN < HN, whilst the leaf chlorophyll concentration under HN was obviously lower than that under MN. The growth rate under MN was higher than that under LN and HN. We concluded that the NSCs allocation between consumption and reserve in P. macrophyllus saplings depended on soil N availability, and an excessive N addition to soil favors the storage rather than the consumption of NSCs by plants.

Keywords

Photosynthate / Allocation / Source-sink balance / Plant nutrient supply / Podocarpus macrophyllus saplings

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Renshan Li, Jianming Han, Liqiong Zhu, Lijun Zhao, Xiangling Huang, Mingyue Zhang, Qingpeng Yang, Weidong Zhang. Does nitrogen fertilization impact nonstructural carbohydrate storage in evergreen Podocarpus macrophyllus saplings?. Journal of Forestry Research, 2020, 32(4): 1653-1661 DOI:10.1007/s11676-020-01181-z

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Ai Z, Xue S, Wang G, Liu G. Responses of non-structural carbohydrates and C: N: P stoichiometry of Bothriochloa ischaemum to nitrogen addition on the Loess Plateau, China. J Plant Growth Regul, 2017, 36: 714-722.

[2]	Alderman PD, Boote KJ, Sollenberger LE, Coleman SW. Carbohydrate and nitrogen reserves relative to regrowth dynamics of ‘Tifton 85’ Bermuda grass as affected by nitrogen fertilization. Crop Sci, 2011, 51: 1727-1738.

[3]	Bansal S, Germino MJ. Carbon balance of conifer seedlings at timberline: relative changes in uptake, storage, and utilization. Oecologia, 2008, 158: 217-227.

[4]	Cheng L, Ma F, Ranwala D. Nitrogen storage and its interaction with carbohydrates of young apple trees in response to nitrogen supply. Tree Physiol, 2004, 24: 91-98.

[5]	Curtis PS, Vogel CS, Wang X, Pregitzer KS, Zak DR, Lussenhop J, Kubiske M, Teeri JA. Gas exchange, leaf nitrogen and growth efficiency of Populus tremuloides in a CO₂-enriched atmosphere. Ecol Appl, 2000, 10: 3-17.

[6]	Dietze MC, Sala A, Carbone MS, Czimczik CI, Mantooth JA, Richardson AD, Vargas R. Nonstructural carbon in woody plants. Annu Rev Plant Biol, 2014, 65: 667-687.

[7]	Dong T, Li J, Zhang Y, Korpelainen H, Niinemets Ü, Li C. Partial shading of lateral branches affects growth, and foliage nitrogen- and water-use efficiencies in the conifer Cunninghamia lanceolata growing in a warm monsoon climate. Tree Physiol, 2015, 35: 632-643.

[8]	Furze ME, Huggett BA, Aubrecht DM, Stolz CD, Carbone MS, Richardson AD. Whole-tree nonstructural carbohydrate storage and seasonal dynamics in five temperate species. New Phytol, 2019, 221: 1466-1477.

[9]	Hartmann H, Trumbore S. Understanding the roles of nonstructural carbohydrates in forest trees—from what we can measure to what we want to know. New Phytol, 2016, 211: 386-403.

[10]	Hasibeder R, Fuchslueger L, Richter A, Bahn M. Summer drought alters carbon allocation to roots and root respiration in mountain grassland. New Phytol, 2015, 205: 1117-1127.

[11]	Hoch G, Köner C. The mobile carbon supply of pines at the climatic treeline: a global comparison. Oecologia, 2003, 135: 10-21.

[12]	Huttunen L, Saravesi K, Markkola A, Niemelä P. Do elevations in temperature, CO₂, and nutrient availability modify belowground carbon gain and root morphology in artificially defoliated silver birch seedlings?. Ecol Evol, 2013, 3: 2783-2794.

[13]	Klein T, Hoch G. Tree carbon allocation dynamics determined using a carbon mass balance approach. New Phytol, 2015, 205: 147-159.

[14]	Knox K, Clarke P. Nutrient availability induces contrasting allocation and starch formation in resprouting and obligate seeding shrubs. Funct Ecol, 2005, 19: 690-698.

[15]	Kobe RK, Iyer M, Walters MB. Optimal partitioning theory revisited: nonstructural carbohydrates dominate root mass responses to nitrogen. Ecology, 2010, 91: 166-179.

[16]	Kozlowski TT. Carbohydrate sources and sinks in woody plants. Bot Rev, 1992, 58: 107-222.

[17]	Li R, Yang Q, Zhang W, Zheng W, Chi Y, Xu M, Fang Y, Gessler A, Li M, Wang S. Thinning effect on photosynthesis depends on needle ages in a Chinese fir (Cunninghamia lanceolata) plantation. Sci Total Environ, 2017, 580: 900-906.

[18]	Luo Z, Calfapietra C, Liberloo M, Scarascia-Mugnozza G, Polle A. Carbon partitioning to mobile and structural fractions in poplar wood under elevated CO2 (EUROFACE) and N fertilization. Global Change Biol., 2006, 12: 272-283.

[19]	Manter DK, Kavanagh KL, Rose CL. Growth response of Douglas-fir seedlings to nitrogen fertilization: importance of Rubisco activation state and respiration rates. Tree Physiol, 2005, 25: 1015-1021.

[20]	Mao Q, Lu X, Mo H, Gundersen P, Mo J. Effects of simulated N deposition on foliar nutrient status, N metabolism and photosynthetic capacity of three dominant understory plant species in a mature tropical forest. Sci Total Environ, 2018, 610–611: 555-562.

[21]	Martínez-Vilalta J, Sala A, Asensio D, Galiano L, Hoch G, Palacio S, Piper FI, Lloret F. Dynamics of non-structural carbohydrates in terrestrial plants: a global synthesis. Ecol Monogr, 2016, 86: 495-516.

[22]	Matson PA, Waring RH. Effects of nutrient limitation on mountain hemlock: susceptibility to laminated root rot. Ecology, 1984, 65: 1517-1524.

[23]	Ögren E. Relationship between temperature, respiratory loss of sugar and premature dehardening in dormant Scots pine seedlings. Tree Physiol, 1997, 17: 47-51.

[24]	Omondi JO, Lazarovitch N, Rachmilevitch S, Yermiyahu U, Sperling O. High nitrogen availability limits photosynthesis and compromises carbohydrate allocation to storage in roots of Manihot esculenta Crantz. Front Plant Sci, 2019, 10: 1041.

[25]	Paul MJ, Foyer CH. Sink regulation of photosynthesis. J Exp Bot, 2001, 52: 1383-1400.

[26]

Porra J, Thompson WA, Kriedemann PE. Determination of accurate extinction coefficients and simultaneous equations for assaying chlorophylls a and b extracted with four different solvents: verification of the concentration of chlorophyll standards by atomic absorption spectroscopy. Biochem Biophys Acta Bioenerg, 1989, 975: 384-394.

[27]	Sala A, Woodruff DR, Meinzer FC. Carbon dynamics in trees: feast or famine?. Tree Physiol, 2012, 32: 764-775.

[28]	Stockfors J, Linder S. Effect of nitrogen on the seasonal course of growth and maintenance respiration in stems of Norway spruce trees. Tree Physiol, 1998, 18: 155-166.

[29]	Tang X, Fan S, Qi L, Guan F, Liu G, Du M. Effects of understory removal on root production, turnover and total belowground carbon allocation in Moso bamboo forests. Forest, 2016, 9: 187-194.

[30]	Wang F, Chen F, Wang G, Mao R, Fang X, Wang H, Bu W. Effects of experimental nitrogen addition on nutrients and nonstructural carbohydrates of dominant understory plants in a Chinese fir plantation. Forests, 2019, 10: 155.

[31]	Würth MK, Peláez-Riedl S, Wright SJ. Non-structural carbohydrate pools in a tropical forest. Oecologia, 2005, 143: 11-24.

[32]	Xiao L, Liu G, Li P, Xue S. Nitrogen addition has a stronger effect on stoichiometries of non-structural carbohydrates, nitrogen and phosphorus in Bothriochloa ischaemum than elevated CO₂. J Plant Growth Regul, 2017, 83: 325-334.

[33]	Yan L, Xu X, Xia J. Different impacts of external ammonium and nitrate addition on plant growth in terrestrial ecosystems: A meta-analysis. Sci Total Environ, 2019, 686: 1010-1018.

[34]	Zhang H, Wang C, Wang X. Spatial variations in non-structural carbohydrates in stems of twelve temperate tree species. Trees-Struct Funct, 2014, 28: 77-89.

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