Light intensity modulates plant nitrogen uptake preference: Evidence from Ligustrum compactum seedlings in simulated canopy gaps of coastal shelterbelt forests

Hongtao Xie , Wei Wang , Binghui Bao , Xiaoyu Wang , Sheng-I Yang , Deliang Lu

Journal of Forestry Research ›› 2025, Vol. 36 ›› Issue (1) : 91

PDF
Journal of Forestry Research ›› 2025, Vol. 36 ›› Issue (1) : 91 DOI: 10.1007/s11676-025-01885-0
Original Paper

Light intensity modulates plant nitrogen uptake preference: Evidence from Ligustrum compactum seedlings in simulated canopy gaps of coastal shelterbelt forests

Author information +
History +
PDF

Abstract

Nitrogen (N) deficiency is a critical factor limiting natural regeneration in coastal shelterbelt forests, but the influence of different N forms on seedling establishment under varying light conditions remains poorly understood. This study investigated the effects of N forms and N concentrations on Ligustrum compactum seedlings under simulated canopy gap conditions using a three-factor design: N form (NO₃-N, NH₄⁺-N, mixed N), N concentration (30 and 60 kg ha⁻1 a⁻1), and light intensity (30%, 60%, and 90% full sunlight). Results showed that N addition significantly promoted seedling growth, net photosynthesis rate, and water use efficiency; however, the effects varied among N forms and concentrations. Overall, NO3-N or mixed N were more favored by L. compactum seedlings; however, the N preference was altered by light intensity and N concentration. For instance, L. compactum showed greater NO3-N or mixed N preference under low and medium light intensities, while displaying more NH4+-N preference under high light intensity. N concentration also affected the growth and N preference of L. compactum seedlings, but the variance explained by N concentration was lower than that of light intensity. Leaf C, N, P stoichiometry exhibited stronger correlations with seedling’s morphological trait plasticity than those of leaf gas exchange, and further analysis demonstrated that leaf C:P and N:P were the top two critical factors affecting seedling growth, indicating that the coordination and balance among C, N, P elements were more important in explaining the seedling growth under N addition. Therefore, our results clarified that the N preference of L. compactum seedlings could be altered by light intensity and revealed that leaf C, N, P ratios were stronger predictors than leaf gas exchange parameters for explaining the N effects on seedling performance. These findings demonstrated the mechanisms of light-N interactions affecting seedling performance, providing practical guidance for optimizing N fertilization and improving natural regeneration in canopy gaps of degraded coastal shelterbelt forests.

Keywords

Nitrogen form / Light intensity / Seedling performance / Leaf C, N, P / Leaf gas exchange / Coastal forest

Cite this article

Download citation ▾
Hongtao Xie, Wei Wang, Binghui Bao, Xiaoyu Wang, Sheng-I Yang, Deliang Lu. Light intensity modulates plant nitrogen uptake preference: Evidence from Ligustrum compactum seedlings in simulated canopy gaps of coastal shelterbelt forests. Journal of Forestry Research, 2025, 36(1): 91 DOI:10.1007/s11676-025-01885-0

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Alboukadel K, Fabian M (2020) Factoextra: Extract and visualize the results of multivariate data analyses. https://doi.org/10.32614/CRAN.package.factoextra
[2]

AndrewsM, RavenJA, LeaPJ. Do plants need nitrate? The mechanisms by which nitrogen form affects plants. Ann Appl Biol, 2013, 163: 174-199

[3]

BrittoDT, KronzuckerHJ. Ecological significance and complexity of N-source preference in plants. Ann Bot, 2013, 112(6): 957-963

[4]

DongXM, ZhangW, HuH, GaoTY, WangXQ, ShiQ, HeB, ZhangSB. Physiological and transcriptome analysis reveal the nitrogen preference and regulatory pathways of nitrogen metabolism in an epiphytic orchid. Cymbidium Tracyanum Environ Exp Bo, 2024, 219, ArticleID: 105618
[5]

Finch-SavageWE, FootittS. Seed dormancy cycling and the regulation of dormancy mechanisms to time germination in variable field environments. J Exp Bot, 2017, 68(4): 843-856

[6]

FinziAC, AustinAT, ClelandEE, FreySD, HoultonBZ, WallensteinMD. Responses and feedbacks of coupled biogeochemical cycles to climate change: examples from terrestrial ecosystems. Front Ecol Environ, 2011, 9: 61-67

[7]

FootittS, WalleyPG, LynnJR, HambidgeAJ, PenfieldS, Finch-SavageWE. Trait analysis reveals DOG1 determines initial depth of seed dormancy, but not changes during dormancy cycling that result in seedling emergence timing. New Phytol, 2020, 225(5): 2035-2047

[8]

GengQH, MaXC, PengFX, ZhuZ, LiQ, XuDD, RuanHH, XuX. Consistent responses of the C:N:P stoichiometry of green leaves and fine roots to N addition in poplar plantations in eastern coastal China. Plant Soil, 2023, 485: 377-394

[9]

HeXX, ChiQD, CaiZC, ChengY, ZhangJB, MüllerC. 15N tracing studies including plant N uptake processes provide new insights on gross N transformations in soil-plant systems. Soil Biol Biochem, 2020, 141, ArticleID: 107666
[10]

HessiniK, IssaouiK, FerchichiS, SaifT, AbdellyC, SiddiqueKH, CruzC. Interactive effects of salinity and nitrogen forms on plant growth, photosynthesis and osmotic adjustment in maize. Plant Physiol Biochem, 2019, 139: 171-178

[11]

HouMT, ZhangGQ, LiYL, XieJQ, ZangLP, LiuQF, ChenDM, SuiMZ, HeYJ. The effects of canopy gaps on soil nutrient properties: a meta-analysis. Eur J Forest Res, 2024, 143: 861-873

[12]

HuYK, LiuXY, HeNP, PanX, LongSY, LiW, ZhangMY, CuiLJ. Global patterns in leaf stoichiometry across coastal wetlands. Global Ecol Biogeogr, 2021, 30: 852-869

[13]

JiangLL, WangSP, ZheP, WangCS, KardolP, ZhouXQ, RuiYC, LanZC, WangYF, XuXL. Grazing modifies inorganic and organic nitrogen uptake by coexisting plant species in alpine grassland. Biol Fertil Soils, 2016, 52(2): 211-221

[14]

KermavnarJ, ElerK, MarinšekA, KutnarL. Initial understory vegetation responses following different forest management intensities in Illyrian beech forests. App Veg Sci, 2019, 22(1): 48-60

[15]

KurjakD, PetríkP, KonôpkováAS, LinkRM, GömöryD, HajekP, LiesebachM, LeuschnerC, SchuldtB. Inter-provenance variability and phenotypic plasticity of wood and leaf traits related to hydraulic safety and efficiency in seven European beech (Fagus sylvatica L.) provenances differing in yield. Ann for Sci, 2024, 81: 11

[16]

LiZL, TianDS, WangBX, WangJS, WangS, ChenHYH, XuXF, WangCH, HeNP, NiuSL. Microbes drive global soil nitrogen mineralization and availability. Glob Change Biol, 2019, 25: 1078-1088

[17]

LiCH, et al.. Close linkages between leaf functional traits and soil and leaf C:N: P stoichiometry under altered precipitation in a desert steppe in northwestern China. Plant Ecol, 2022, 223: 407-421

[18]

LiBL, et al.. Study on N application and N reduction potential of farmland in China. Environ Monit Assess, 2023, 195: 1156

[19]

LiuQQ, HuangZJ, WangZN, ChenYF, WenZM, LiuB, TigabuM. Responses of leaf morphology, NSCs contents and C:N:P stoichiometry of Cunninghamia lanceolata and Schima superba to shading. BMC Plant Biol, 2020, 20: 354

[20]

LiuXJ, ZhangY, XiaoTQ, LiP, ZhangL, LiuYQ, DengWP. Runoff velocity controls soil nitrogen leaching in subtropical restored forest in southern China. For Ecol Manage, 2023, 548, ArticleID: 121412
[21]

LuLZ, WuCY, DiLP. Exploring the spatial characteristics of typhoon-induced vegetation damages in the southeast coastal area of China from 2000 to 2018. Remote Sens, 2020, 12(10): 1692

[22]

LuXK, VitousekPM, MaoQQ, GilliamFS, LuoYQ, TurnerBL, ZhouGY, MoJM. Nitrogen deposition accelerates soil carbon sequestration in tropical forests. PNAS, 2021, 118(16) e2020790118
[23]

LuoL, ZhaoCZ, ZhengDH, WangET, LiangJ, YinCY. Nitrogen uptake preference and allocation in Populus cathayana in response to drought stress. Environ Exp Bot, 2023, 213, ArticleID: 105415
[24]

NeedhamJF, ArellanoG, DaviesSJ, FisherRA, HammerV, KnoxRG, MitreD, Muller-LandauHC, ZuletaD, KovenCD. Tree crown damage and its effects on forest carbon cycling in a tropical forest. Glob Chang Biol, 2022, 28 18): 5560-5574

[25]

OktaviaD, JinGZ. Variations in leaf morphological and chemical traits in response to life stages, plant functional types, and habitat types in an old-growth temperate forest. Basic Appl Ecol, 2020, 49: 22-33

[26]

PeeremanJ, HoganJA, LinTC. Intraseasonal interactive effects of successive typhoons characterize canopy damage of forests in Taiwan: A remote sensing-based assessment. For Ecol Manage, 2022, 521, ArticleID: 120430
[27]

Petek-Petrik A, Húdoková H, Fleischer Jr. P, Jamnická G, Kurjak D, Sliacka Konôpková AS, Petrík P (2023) The combined effect of branch position, temperature, and VPD on gas exchange and water-use efficiency of Norway spruce. Biol plant 67:136–141. https://doi.org/10.32615/bp.2023.017
[28]

PetríkP, Petek-PetrikA, MukarramM, SchuldtB, LamarqueLJ. Leaf physiological and morphological constraints of water use efficiency in C3 plants. AoB Plants, 2023, 15: plad047

[29]

PradoJJ, SchiaviniI, ValeV, LopesS, ArantesC, OliveiraAP. Functional leaf traits of understory species: strategies to different disturbance severities. Braz J Biol, 2015, 75: 339-346

[30]

Quassi de CastroSG, CostaVE, Quassi de CastroSA, CarvalhoJLN, BorgesCD, Araldi de CastroRA, KöllnOT, FrancoHCJ. Fertilizer application method provides an environmental-friendly nitrogen management option for sugarcane. J Soil Sci Plant Nutr, 2024, 24: 3195-3208

[31]

RabarijaonaA, PontonS, BertD, DucoussoA, RichardB, LevillainJ, BrendelO. Provenance differences in water-use efficiency among sessile oak populations grown in a mesic common garden. Front for Global Change, 2022, 5, ArticleID: 914199
[32]

RawatM, ArunachalamK, ArunachalamA, AlataloJM, PandeyR. Assessment of leaf morphological, physiological, chemical and stoichiometry functional traits for understanding the functioning of Himalayan temperate forest ecosystem. Sci Rep, 2021, 11: 23807

[33]

Rossiter-RachorNA, SetterfieldSA, DouglasMM, HutleyLB, CookGD, SchmidtS. Invasive Andropogon gayanus (gamba grass) is an ecosystem transformer of nitrogen relations in Australian savanna. Ecol Appl, 2009, 19(6): 1546-1560

[34]

SatheeL, SuriyaprakashR, DipankarB, SandeepBA, ShailendraKJ, ViswanathanC. Nitrogen at the crossroads of light: integration of light signalling and plant nitrogen metabolism. J Exp Bo, 2024, 76(3): 803-818

[35]

SchelhasJ, BrandeisTJ, RudelTK. Planted forests and natural regeneration in forest transitions: patterns and implications from the U.S. South. Reg Environ Change, 2021, 21(8): 1

[36]

SebastienL, JulieJ, FrancoisH. FactoMineR: an R package for multivariate analysis. J Stat Softw, 2008, 25(1): 1
[37]

SimonA, KatzensteinerK, GratzerG. Drivers of forest regeneration patterns in drought prone mixed-species forests in the Northern Calcareous Alps. For Ecol Manage, 2019, 453, ArticleID: 117589
[38]

SongQF, Van RieJ, Den BoerB, GalleA, ZhaoH, ChangT, HeZH, ZhuXG. Diurnal and seasonal variations of photosynthetic energy conversion efficiency of field grown wheat. Front Plant Sci, 2022, 13, 817654
[39]

SotoDP, JacobsDF, SalasC, DonosoPJ, FuentesC, PuettmannKJ. Light and nitrogen interact to influence regeneration in old-growth Nothofagus-dominated forests in south-central Chile. For Ecol Manage, 2017, 384: 303-313

[40]

TakabatakeT, EstebanM, ShibayamaT. Simulated effectiveness of coastal forests on reduction in loss of lives from a tsunami. Int J Disaster Risk Reduct, 2022, 74, ArticleID: 102954
[41]

TakaragawaH, WakayamaM. Responses of leaf gas exchange and metabolites to drought stress in different organs of sugarcane and its closely related species Erianthus arundinaceus. Planta, 2024, 260(4): 90

[42]

TaylorBN, StedmanE, Van BloemSJ, WhitmireSL, DeWaltSJ. Widespread stem snapping but limited mortality caused by a category 5 hurricane on the Caribbean Island of Dominica. For Ecol Manage, 2023, 532, ArticleID: 120833
[43]

VillagraM, CampanelloPI, MonttiL, GoldsteinG. Removal of nutrient limitations in forest gaps enhances growth rate and resistance to cavitation in subtropical canopy tree species differing in shade tolerance. Tree Physiol, 2013, 33(3): 285-296

[44]

WangYT, ChangYCA. Effects of nitrogen and the various forms of nitrogen on phalaenopsis orchid-a review. HortTechnology, 2017, 27(2): 144-149

[45]

WangLY, LiuJL, WangWX, SunY. Exogenous melatonin improves growth and photosynthetic capacity of cucumber in salinity-induced stress. Photosynthetica, 2016, 54: 19-27

[46]

WuTG, YuMK, WangGG, DongY, ChengXR. Leaf nitrogen and phosphorus stoichiometry across forty-two woody species in Southeast China. Biochem Syst Ecol, 2012, 44: 255-263

[47]

XiNX, ZhuBR, ZhangDY. Contrasting grass nitrogen strategies reflect interspecific trade-offs between nitrogen acquisition and use in a semi-arid temperate grassland. Plant Soil, 2017, 418: 267-276

[48]

XieHT, WangGG, YuMK. Ecosystem multifunctionality is highly related to the shelterbelt structure and plant species diversity in mixed shelterbelts of eastern China. Glob Ecol Conserv, 2018, 16, ArticleID: e00470
[49]

XieKL, LuZF, PanYH, GaoLM, HuP, WangM, GuoSW. Leaf photosynthesis is mediated by the coordination of nitrogen and potassium: the importance of anatomical-determined mesophyll conductance to CO2 and carboxylation capacity. Plant Sci, 2020, 290, 110267
[50]

XieHT, KnappLSP, YuMK, WangGG. Solidago canadensis invasion destabilizes the understory plant community and soil properties of coastal shelterbelt forests of subtropical China. Plant Soil, 2023, 484: 65-77

[51]

XieHT, ChangMY, BaoBH, LiXQ, WangGG. Linking canopy gap features and microhabitat heterogeneity with seedling regeneration in a mixed coastal shelterbelt forest of eastern China. For Ecol Manage, 2024, 571, ArticleID: 122259
[52]

YeJY, TianWH, JinCW. Nitrogen in plants: from nutrition to the modulation of abiotic stress adaptation. Stress Biol, 2022, 2(1): 4

[53]

YinJ, LinF, LombaerdeED, MaoZK, LiuSF, YeJ, FangS, WangXG. The effects of light, conspecific density and soil fungi on seedling growth of temperate tree species. For Ecol Manage, 2023, 529, ArticleID: 120683
[54]

ZhangLX, ShiL, YangF. Assessing ecosystem service dynamics in China's coastal shelterbelt: implications for ecosystem restoration. Environ Impact Assess Rev, 2024, 106, ArticleID: 107515
[55]

ZhangLQ, ZhaoZH, JiangBL, BaoyinB, CuiZG, WangHY, LiQZ, CuiJH. Effects of long-term application of nitrogen fertilizer on soil acidification and biological properties in China: a meta-analysis. Microorganisms, 2024, 12(8): 1683

[56]

ZhouWY, TaoY, PengL, ZhengHW, ZhouXB, YinBF, ZhangJ. Balancing the nutrient needs: optimising growth in Malus sieversii seedlings through tailored nitrogen and phosphorus effects. Plant Cell Environ, 2024, 47: 5280-5296

[57]

ZhuJJ, ZhangGQ, WangGG, YanQL, LuD, LiXF, ZhengX. On the size of forest gaps: can their lower and upper limits be objectively defined?. Agric for Meteorol, 2015, 213: 64-76

[58]

ZhuJJ, ZhuCY, LuDL, WangGG, ZhengX, CaoJS, ZhangJX. Regeneration and succession: a 50-year gap dynamic in temperate secondary forests, Northeast China. For Ecol Manage, 2021, 484, ArticleID: 118943

RIGHTS & PERMISSIONS

Northeast Forestry University

AI Summary AI Mindmap
PDF

202

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/