바로가기메뉴

본문 바로가기 주메뉴 바로가기

ACOMS+ 및 학술지 리포지터리 설명회

  • 한국과학기술정보연구원(KISTI) 서울분원 대회의실(별관 3층)
  • 2024년 07월 03일(수) 13:30
 

logo

  • ENGLISH
  • P-ISSN2287-8327
  • E-ISSN2288-1220
  • SCOPUS, KCI

Variation in leaf functional traits of the Korean maple (Acer pseudosieboldianum) along an elevational gradient in a montane forest in Southern Korea

Journal of Ecology and Environment / Journal of Ecology and Environment, (P)2287-8327; (E)2288-1220
2018, v.42 no.4, pp.278-284
https://doi.org/10.1186/s41610-018-0096-x
남기정 (경상대학교)
이은주 (경상대학교)

Abstract

Plant functional traits have been shown to be useful to understand how and why ecosystems and their components vary across environmental heterogeneity or gradients. This study investigated how plant functional (leaf) traits vary according to an elevation-associated environmental gradient. Environmental gradients (mean annual temperature and precipitation) were quantified, and leaf traits (leaf area, specific leaf area, leaf nitrogen, leaf phosphorus, leaf carbon, and leaf C/N ratio) of the understory woody plant species Acer pseudosieboldianum were examined across an elevational gradient ranging from 600 to 1200 m in a Baegunsan Mountain in Gwangyang-si, Jeollanam-do, South Korea. The results showed that mean annual temperature and precipitation decreased and increased along with elevation, respectively. Leaf area of the plant species decreased slightly with increasing elevation, while specific leaf area did not differ significantly. Leaf nutrients (nitrogen, phosphorus, and carbon concentrations) were higher at high elevations, but leaf C/N ratio decreased with elevation.

keywords
Altitudinal gradient, Environmental filtering, Functional traits, Leaf nitrogen, Specific leaf area

참고문헌

1.

Alvarez R, Lavado RS. Climate, organic matter and clay content relationships in the pampa and Chaco soils, Argentina. Geoderma. 1998;83:127–41.

2.

Atkin OK, Loveys BR, Atkinson LJ, Pons TL. Phenotypic plasticity and growth temperature: understanding interspecific variability. J Exp Bot. 2006;57:267–81.

3.

Bresson C, Vitasse Y, Kremer A, Delzon S. To what extent is altitudinal variation of functional traits driven by genetic adaptation in European oak and beech? Tree Physiol. 2011;31:1164–74.

4.

Choo GC, Kim GT. Vegetation structure of mountain ridge from Bubong to Poamsan in Baekdudaegan, Korea. Korean J Environ Ecol. 2005;19:83–9.

5.

Dai W, Huang Y. Relation of soil organic matter concentration to climate and altitude in zonal soils of China. Catena. 2006;65:87–94.

6.

Fowler D, Cape JN, Leith ID, Choularton TW, Gay MJ, Jones A. The influence of altitude on rainfall composition at Great Dun Fell. Atmos Environ. 1988;22:1355–62.

7.

Garnier E, Navas M. A trait-based approach to comparative functional plant ecology: concepts, methods and applications for agroecology. A review. Agron Sustain Dev. 2011;32:365–99.

8.

Hart SC, Perry DA. Transferring soils from high- to low-elevation forests increases nitrogen cycling rates: climate change implications. Glob Chang Biol. 1999;5:23–32.

9.

He X, Hou E, Liu Y, Wen D. Altitudinal patterns and controls of plant and soil nutrient concentrations and stoichiometry in subtropical China. Scientific Report. 2016;6:24261.

10.

Huber E, Wanek W, Gottfried M, Pauli H, Schweiger P, Arndt SK, Reiter K, Richter A. Shift in soil-plant nitrogen dynamics of an alpine-nival ecotone. Plant Soil. 2007;301:65–76.

11.

Hulshof C, Swenson NG. Variation in leaf functional trait values within and across individuals and species: an example from a Costa Rican dry forest. Funct Ecol. 2010;24:1365–2435.

12.

Kim IT, Jeong SH. 4th Natural Environmental Survey (Jeonnam01). Ministry of Environment of Korea: National Institute of Ecology; 2015.

13.

Korner C. The use of ‘altitude’ in ecological research. Trends Ecol Evol. 2007;22:569–74.

14.

Kunstler J, Falster D, Cooms DA, Hui F, Kooyman RM, Laughlin DC, Pooter L, Vanderwel M, Vieilledent G, Wright SJ, Aiba M, Baraloto C, Caspersen J, Cornelissen JHC, Gourlet-Fleury S, Hanewinkel M, Herault B, Kattge J, Kurokawa H, Onoda Y, Peñuelas J, Poorter H, Uriarte M, Richardson S, Ruiz-Benito PIFS, Ståhl G, Swenson NG, Thompson J, Westerlund B, Wirth C, Zavala ZA, Zeng H, Zimmerman JK, Zimmermann NE, Westoby M. Plant functional traits have globally consistent effects on competition. Nature. 2015;2:16476.

15.

Lee CB, Chun JH, Song HK, Cho HJ. Altitudinal patterns of plant species richness on Baekdudaegan Mountain, South Korea: mid-domain effect, area, climate, and Rapoport’ rule. Ecol Res. 2013;28:67–79.

16.

Leigh EG. Structure and climate in tropical rain forest. Annu Rev Ecol Syst. 1975;6:67–86.

17.

Minder JR, Mote PW, Lundquist JD. Surface temperature lapse rates over complex terrain: lessons from the Cascade Mountains. J Geophys Res Atmos. 2010;115:D14112.

18.

Morecroft MD, Woodward FI. Experiments on the causes of altitudinal differences in the leaf nutrient contents, size and δ13C of Alchemilla alpina. New Phytol. 1996;134:471–9.

19.

Mouillet D, Graham NAJ, Villeger S, Mason NWH, Bellood DR. A functional approach reveals community responses to disturbances. Trends Ecol Evol. 2010;28(3):167–77.

20.

Park IH, Seo YK, Choi YC. Forest structure in relation to slope aspect and altitude in valley forests at Baraebong, Jirisan National Park. Korean J Environ Ecol. 2003;16:449–56.

21.

Pérez-Harguindeguy N, Díaz S, Garnier E, Lavorel A, Poorter H, Jaureguiberry P, Bret-Harte MS, Cornwell WK, Craine JM, Gurvich DE, Urcelay C, Veneklaas EJ, Reich PB, Poorter L, Wright IJ, Ray P, Enrico L, Pausas JG, de Vos AC, Buchmann N, Funes G, Quétier F, Hodgson JG, Thompson K, Morgan HD, ter Steege H, van der Heijden MGA, Sack L, Blonder B, Poschlod P, Vaieretti MV, Conti G, Staver AC, Aquino S, Cornelissen JHC. New handbook for standardised measurement of plant functional traits worldwide. Aust J Bot. 2013;61:167–234.

22.

Pfennigwerth AA, Bailey JK, Schweitzer JA. Trait variation along elevation gradients in a dominant woody shrub is population-specific and driven by plasticity. AoB Plants. 2017;9:plx027.

23.

Poorter H, Niinemets U, Poorter L, Wright IJ, Villar R. Causes and consequences of variation in leaf mass per area (LMA): a meta-analysis. New Phytol. 2009;182:565–88.

24.

Pratt JD, Mooney KA. Clinal adaptation and adaptive plasticity in Artemisia californica: implications for the response of a foundation species to predicted climate change. Glob Chang Biol. 2013;19:2454–66.

25.

Qasba S, Masoodi TH, Bhat SJA, Paray PA, Bhat A, Khanday MUD. Effect of altitude and aspect on soil physico-chemical characteristics in Shankaracharya reserved forest. Int J Pure Appl Biosci. 2017;5:585–96.

26.

Quideau SA, Chadwick QA, Benesi A, Graham RC, Anderson MA. A direct link between forest vegetation type and soil organic matter composition. Geoderma. 2001;104:41–60.

27.

R Development Core Team. R: A language and environment for statistical computing. Vienna: R Foundation for Statistical Computing; 2011.

28.

Read QD, Moorhead LC, Swenson NG, Bailey JK, Sanders NJ. Convergent effects of elevation on functional leaf traits within and among species. Funct Ecol. 2014;28:37–45.

29.

Reich P, Walters MB, Ellsworth DS. From tropics to tundra: global convergence in plant functioning. Proc Natl Acad Sci, USA. 1997;94:13730–4.

30.

Rosbakh S, Romermann C, Psochlod P. Specific leaf area correlates with temperature: new evidence of trait variation at the population, species and community levels. Alp Bot. 2015;125:79–86.

31.

Roscher C, Schumacher J, Gubsch M, Lipowsky A, Weigelt A, Buchmann N, Schmid B, Schulze ED. Using plant functional traits to explain diversityproductivity relationships. PLoS One. 2012;7(5):e36760.

32.

Rueden CT, Schindelin J, Hiner MC, DeZonia BE, Walter AE, Arena ET, Eliceiri KW. ImageJ2: ImageJ for the next generation of scientific image data. BMC Bioinformatics. 2017;18:529.

33.

Schob C, Armas C, Guler M, Prieto I, Pugnaire FI. Variability in functional traits mediates plant interactions along stress gradients. J Ecol. 2013;101:753–62.

34.

Soethe N, Lehmann J, Engels C. Nutrient availability at different altitudes in a tropical montane forest in Ecuador. J Trop Ecol. 2008;24:397–406.

35.

Sokol Z, Bliznk V. Areal distribution and precipitation-altitudinal relationship of heavy short-term precipitation in the Czech Republic in the warm part of the year. Atmos Res. 2009;94:652–62.

36.

Tan ZX, lal R, Smeck NE, Calhoun FG. Relationships between surface soil organic carbon pool and site variables. Geoderma. 2004;121:185–7.

37.

Tanner EVJ, Vitousek PM, Cuevas E. Experimental investigation of nutrient limitation of forest growth on wet tropical mountains. Ecology. 1998;79:10–22.

38.

Tashi S, Singh B, Keitel C, Adams M. Soil carbon and nitrogen stock in forests along an altitudinal gradient in the eastern Himalayas and a meta-analysis of global data. Glob Chang Biol. 2016;22:2255–68.

39.

Velazquez-Rosas N, Meave J. Elevational variation of leaf traits in montane rain forest tree species at La Chinantla, Southern Mexico. Biotropica. 2002;34:534–46.

40.

West GB, Brown JH, Enquist BJ. A general model for the structure and allometry of plant vascular systems. Nature. 1999;400:664–7.

41.

Westoby M, Falster DS, Moles AT, Vesk PA, Wright IJ. Plant ecological strategies:some leading dimensions of variation between species. Annu Rev Ecol Syst. 2002;33:125–59.

42.

Zhao N, Yu G, He N, Xia F, Wang Q, Wang R, Xu Z, Jia Y. Invariant allometric scaling of nitrogen and phosphorus in leaves, stems, and fine roots of woody plants along an altitudinal gradient. J Plant Res. 2016;129:647–57

Journal of Ecology and Environment