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Journal of Plant Research

, Volume 129, Issue 6, pp 1041–1049 | Cite as

Relative importance of habitat filtering and limiting similarity on species assemblages of alpine and subalpine plant communities

  • Koichi Takahashi
  • Saeka Tanaka
Regular Paper

Abstract

This study examined how habitat filtering and limiting similarity affect species assemblages of alpine and subalpine plant communities along a slope gradient on Mt. Norikura in central Japan. Plant traits (plant height, individual leaf area, specific leaf area (SLA), leaf linearity, leaf nitrogen and chlorophyll concentrations) and abiotic environmental factors (elevation, slope inclination, ground surface texture, soil water, soil pH, soil nutrient concentrations of NH4-N and NO3-N) were examined. The metrics of variance, range, kurtosis and the standard deviation of neighbor distance divided by the range of traits present (SDNDr) were calculated for each plant trait to measure trait distribution patterns. Limiting similarity was detected only for chlorophyll concentration. By contrast, habitat filtering was detected for individual leaf area, SLA, leaf linearity, chlorophyll concentration. Abiotic environmental factors were summarized by the principal component analysis (PCA). The first PCA axis positively correlated with elevation and soil pH, and negatively correlated with sand cover, soil water, NH4-N and NO3-N concentrations. High values of the first PCA axis represent the wind-exposed upper slope with lower soil moisture and nutrient availabilities. Plant traits changed along the first PCA axis. Leaf area, SLA and chlorophyll concentration decreased, and leaf linearity increased with the first PCA axis. This study showed that the species assemblage of alpine and subalpine plants was determined mainly by habitat filtering, indicating that abiotic environmental factors are more important for species assemblage than interspecific competition. Therefore, only species adapting to abiotic environments can distribute to these environments.

Keywords

Alpine plants Community structure Environmental conditions Functional traits Niche Species assemblage 

Notes

Acknowledgments

We are grateful to the Norikura Observatory, Institute for Cosmic Ray Research, The University of Tokyo, for logistical support of field research, to Prof. F. Kumon and Ms. Y. Takizawa for support of nitrogen analysis, and to Dr. M. Katabuchi for advice on statistical analysis. This study was partially supported by grants from the Ministry of Education, Culture, Sports, Science and Technology, Japan.

Supplementary material

10265_2016_852_MOESM1_ESM.docx (8.8 mb)
Supplementary material 1 (DOCX 9012 kb)
10265_2016_852_MOESM2_ESM.xlsx (16 kb)
Supplementary material 2 (XLSX 16 kb)

References

  1. Aiba M, Katabuchi M, Takafumi H, Matsuzaki SS, Sasaki T, Hiura T (2013) Robustness of trait distribution metrics for community assembly studies under the uncertainties of assembly processes. Ecology 94:2873–2885CrossRefPubMedGoogle Scholar
  2. Araki M (1995) Forest meteorology. Kawashima Shoten, Tokyo (in Japanese) Google Scholar
  3. Atkin OK (2006) Phenotypic plasticity and growth temperature: understanding interspecific variability. J Exp Bot 57:267–281CrossRefPubMedGoogle Scholar
  4. Baker WL, Weisberg PJ (1995) Landscape analysis of the forest-tundra ecotone in Rocky Mountain National Park, Colorado. Prof Geogr 47:361–375CrossRefGoogle Scholar
  5. Bertness MD, Callaway R (1994) Positive interactions in communities. Trends Ecol Evol 9:191–193CrossRefPubMedGoogle Scholar
  6. Billings WD, Bliss LC (1959) An alpine snowbank environment and its effects on vegetation, plant development, and productivity. Ecology 40:388–397CrossRefGoogle Scholar
  7. Billings WD, Mooney HA (1968) The ecology of arctic and alpine plants. Biol Rev 43:481–529CrossRefGoogle Scholar
  8. Bliss LC (1962) Adaptation of arctic and alpine plants to environmental condition. Arctic 15:117–144CrossRefGoogle Scholar
  9. Bliss LC, Henry GHR, Svoboda J, Bliss DI (1994) Patterns of plant distribution within two polar desert landscapes. Arc Alp Res 26:46–55CrossRefGoogle Scholar
  10. Callaway RW, Walker LW (1997) Competition and facilitation: a synthetic approach to interactions in plant communities. Ecology 78:1958–1965CrossRefGoogle Scholar
  11. Callaway RM, Brooker RW, Choler P, Kikvidze Z, Lortiek CJ, Michalet R, Paolini L, Pugnaireq FI, Newingham B, Aschehoug ET, Armas C, Kikodze D, Cook BJ (2002) Positive interactions among alpine plants increase with stress. Nature 417:844–848CrossRefPubMedGoogle Scholar
  12. Chapin FS III (1980) The mineral nutrition of wild plants. Ann Rev Ecol Syst 11:233–260CrossRefGoogle Scholar
  13. Choler P, Michalet R, Callaway RM (2001) Facilitation and competition on gradients in alpine plant communities. Ecology 82:3295–3308CrossRefGoogle Scholar
  14. Cornwell WK, Ackerly DD (2009) Community assembly and shifts in plant trait distributions across an environmental gradient in coastal California. Ecol Monogr 79:109–126CrossRefGoogle Scholar
  15. Cornwell WK, Ackerly DD (2010) A link between plant traits and abundance: evidence from coastal California woody plants. J Ecol 98:814–821CrossRefGoogle Scholar
  16. Cornwell WK, Schwilk DW, Ackerly DD (2006) A trait-based test for habitat filtering: convex hull volume. Ecology 87:1465–1471CrossRefPubMedGoogle Scholar
  17. de Bello F, Vandewalle M, Reitalu T, Lepš J, Prentice HC, Lavorel S, Sykes MT, Vesk P (2013) Evidence for scale- and disturbance-dependent trait assembly patterns in dry semi-natural grasslands. J Ecol 101:1237–1244CrossRefGoogle Scholar
  18. Díaz S, Cabido M, Casanoves F (1998) Plant functional traits and environmental filters at a regional scale. J Veg Sci 9:113–122CrossRefGoogle Scholar
  19. Dullinger S, Kleinbauer I, Pauli H, Gottfried M, Brooker R, Nagy L, Theurillat JP, Holten JI, Abdaladze O, Benito JL, Borel JL, Coldea G, Ghosn D, Kanka R, Merzouki A, Klettner C, Moiseev P, Molau U, Reiter K, Rossi G, Stanisci A, Tomaselli M, Unterlugauer P, Vittoz P, Grabherr G (2007) Weak and variable relationships between environmental severity and small-scale co-occurrence in alpine plant communities. J Ecol 95:1284–1295CrossRefGoogle Scholar
  20. Ellsworth DS, Reich PB (1992) Leaf mass per area, nitrogen content and photosynthetic carbon gain in Acer saccharum seedlings in contrasting forest light environments. Funct Ecol 6:423–435CrossRefGoogle Scholar
  21. Ellsworth DS, Reich PB (1993) Canopy structure and vertical patterns of photosynthesis and related leaf traits in a deciduous forest. Oecologia 96:169–178CrossRefGoogle Scholar
  22. Gotelli NJ (2000) Null model analysis of species co-occurrence patterns. Ecology 81:2606–2621CrossRefGoogle Scholar
  23. Gotteli NJ, Graves GR (1996) Null models in ecology. Smithsonian Institution Press, Washington DCGoogle Scholar
  24. Grime JP (2006) Trait convergence and trait divergence in herbaceous plant communities: mechanisms and consequences. J Veg Sci 17:255–260CrossRefGoogle Scholar
  25. Hadley JL, Smith WK (1983) Influence of wind exposure on needle desiccation and mortality for timberline conifers in Wyoming, USA. Arc Alp Res 15:127–135CrossRefGoogle Scholar
  26. Hadley JL, Smith WK (1986) Wind effects on needles of timberline conifers: seasonal influence on mortality. Ecology 67:12–19CrossRefGoogle Scholar
  27. Hukusima T (1972) Der monsuneffekt auf die vegetationen in hochgebirgen Japans. Jpn J Ecol 22:62–68 (in Japanese) Google Scholar
  28. Ingram T, Shurin JB (2009) Trait-based assembly and phylogenetic structure in northeast Pacific rockfish assemblages. Ecology 90:2444–2453CrossRefPubMedGoogle Scholar
  29. Katabuchi M, Kurokawa H, Davies SJ, Tan S, Nakashizuka T (2012) Soil resource availability shapes community trait structure in a species-rich dipterocarp forest. J Ecol 100:643–651CrossRefGoogle Scholar
  30. Kembel SW, Cowan PD, Helmus MR, Cornwell WK, Morlon H, Ackerly DD, Blomberg SP, Webb CO (2010) Picante: R tools for integrating phylogenies and ecology. Bioinformatics 26:1463–1464CrossRefPubMedGoogle Scholar
  31. Kikvidze Z, Michalet R, Brooker RW, Cavieres LA, Lortie CJ, Pugnaire FI, Callaway RM (2011) Climatic drivers of plant–plant interactions and diversity in alpine communities. Alpine Botany 121:63–70CrossRefGoogle Scholar
  32. Kira T (1948) On the altitudinal arrangement of climatic zones in Japan. Kanti Nogaku 2:143–173 (in Japanese) Google Scholar
  33. Koizumi T (1979) Periglacial processes and alpine plant communities on the high mountains in Japan, in relation to lithology I. Alpine stony desert vegetation on the windward slope of the Shirouma Mountain region in the northern Japan Alps. Jpn J Ecol 29:71–81 (in Japanese) Google Scholar
  34. Koizumi T (1989) Slope development and wind-exposed plant communities on Mt. Yakushidake, the northern Japan Alps. Jpn J Ecol 39:127–137 (in Japanese) Google Scholar
  35. Körner C (2001) Alpine plant life. Springer, BerlinGoogle Scholar
  36. Körner C, Diemer M (1987) In situ photosynthetic responses to light, temperature and carbon dioxide in herbaceous plants from low and high altitude. Funct Ecol 1:179–194CrossRefGoogle Scholar
  37. Körner C, Bannister P, Mark AF (1986) Altitudinal variation in stomatal conductance, nitrogen content and leaf anatomy in different plant life forms in New Zealand. Oecologia 69:577–588CrossRefGoogle Scholar
  38. Kraft NJB, Valencia R, Ackerly DD (2008) Functional traits and niche-based tree community assembly in an Amazonian forest. Science 322:580–582CrossRefPubMedGoogle Scholar
  39. Kudo G, Ito K (1992) Plant distribution in relation to the length of the growing season in a snow-bed in the Taisetsu Mountains, northern Japan. Vegetatio 98:165–174CrossRefGoogle Scholar
  40. Lavergne S, Garnier E, Debussche M (2003) Do rock endemic and widespread plant species differ under the Leaf–Height–Seed plant ecology strategy scheme? Ecol Let 6:398–404CrossRefGoogle Scholar
  41. Löffler J (2007) The influence of micro-climate, snow cover, and soil moisture on ecosystem functioning in high mountains. J Geogr Sci 17:3–19CrossRefGoogle Scholar
  42. Mason NWH, de Bello F, Doležal J, Lepš J (2011) Niche overlap reveals the effects of competition, disturbance and contrasting assembly processes in experimental grassland communities. J Ecol 99:788–796CrossRefGoogle Scholar
  43. Masuzawa T (1997) Ecology of the alpine plants. University of Tokyo Press, Tokyo (in Japanese) Google Scholar
  44. Michalet R, Gandoy C, Joud D, Pages JP (2002) Plant community composition and biomass on calcareous and siliceous substrates in the northern French Alps: comparative effects of soil chemistry and water status. Arc Antarc Alp Res 34:102–113CrossRefGoogle Scholar
  45. Mizuno K (1990) Distribution of plant communities in relation to environments in the cirques of the Northern Japan Alps. Geogr Rev Japan 63A:127–153 (in Japanese) Google Scholar
  46. Mizuno K (1991) Alpine vegetation pattern in relation to environmental factors in Japanese high mountains. Geogr Rep Tokyo Metropolitan Univ 26:167–218Google Scholar
  47. Nakano S, Otsuka T, Adachi M, Harayama S, Yoshioka T (1995) Geology of the Norikuradake district, quadrangle series with geological sheet map at 1:50,000. Geol Surv Japan (in Japanese)Google Scholar
  48. Niklas KJ (1996) Differences between Acer saccharum leaves from open and wind-protected sites. Ann Bot 78:61–66CrossRefGoogle Scholar
  49. Ordoñez JC, van Bodegom PM, Witte JPM, Wright IJ, Reich PB, Aerts R (2009) A global study of relationships between leaf traits, climate and soil measures of nutrient fertility. Glob Ecol Biogeogr 18:137–149CrossRefGoogle Scholar
  50. Poorter H, de Jong R (1999) A comparison of specific leaf area, chemical composition and leaf construction costs of field plants from 15 habitats differing in productivity. New Phytol 143:163–176CrossRefGoogle Scholar
  51. Poorter H, Remkes C (1990) Leaf area ratio and net assimilation rate of 24 wild species differing in relative growth rate. Oecologia 83:553–559CrossRefGoogle Scholar
  52. Poorter H, Niinemets Ü, Poorter L, Wright IJ, Villar R (2009) Causes and consequences of variation in leaf mass per area (LMA): a meta-analysis. New Phytol 182:565–588CrossRefPubMedGoogle Scholar
  53. Porra RJ, Thompson WA, Kriedemann PE (1989) 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. Biochim Biophys Acta 975:384–394CrossRefGoogle Scholar
  54. Reich PB, Uhl C, Walters MB, Ellsworth DS (1991) Leaf lifespan as a determinant of leaf structure and function among 23 amazonian tree species. Oecologia 86:16–24CrossRefGoogle Scholar
  55. Reich PB, Walters MB, Ellsworth DS (1992) Leaf life-span in relation to leaf, plant, and stand characteristics among diverse ecosystems. Ecol Monogr 62:365–392CrossRefGoogle Scholar
  56. Saito M, Irie M (2002) Meteorological observations at Norikura Solar Observatory. Rep Nat Astronom Observ Japan 6:37–47 (in Japanese) Google Scholar
  57. Scheepens JF, Frei ES, Stöcklin J (2010) Genotypic and environmental variation in specific leaf area in a widespread alpine plant after transplantation to different altitudes. Oecologia 164:141–150CrossRefPubMedGoogle Scholar
  58. Scherrer D, Körner C (2011) Topographically controlled thermal-habitat differentiation buffers alpine plant diversity against climate warming. J Biogeogr 38:406–416CrossRefGoogle Scholar
  59. Schöb C, Butterfield BJ, Pugnaire FI (2012) Foundation species influence trait-based community assembly. New Phytol 196:824–834CrossRefPubMedGoogle Scholar
  60. Shimizu T (1997) Flora of Nagano Prefecture. Shinano Mainichi Shinbunsha, Nagano (in Japanese)Google Scholar
  61. Soliveres S, Eldridge DJ, Maestre FT, Bowker MA, Tighe M, Escudero A (2011) Microhabitat amelioration and reduced competition among understorey plants as drivers of facilitation across environmental gradients: towards a unifying framework. Persp Plant Ecol Evol Syst 13:247–258CrossRefGoogle Scholar
  62. Spasojevic MJ, Suding KN (2012) Inferring community assembly mechanisms from functional diversity patterns: the importance of multiple assembly processes. J Ecol 100:652–661CrossRefGoogle Scholar
  63. Stubbs WJ, Wilson JB (2004) Evidence for limiting similarity in a sand dune community. J Ecol 92:55–567CrossRefGoogle Scholar
  64. Takahashi K (1996) Plastic response of crown architecture to crowding in understorey trees of two co-dominating conifers. Ann Bot 77:159–164CrossRefGoogle Scholar
  65. Takahashi K (2014) Effects of wind and thermal conditions on timberline formation in central Japan: a lattice model. Ecol Res 29:121–131CrossRefGoogle Scholar
  66. Takahashi K, Murayama Y (2014) Effects of topographic and edaphic conditions on alpine plant species distribution along a slope gradient on Mount Norikura, central Japan. Ecol Res 29:823–833CrossRefGoogle Scholar
  67. Takahashi K, Hirosawa T, Morishima R (2012) How the timberline formed: altitudinal changes in stand structure and dynamics around the timberline in central Japan. Ann Bot 109:1165–1174CrossRefPubMedPubMedCentralGoogle Scholar
  68. Thomas SC, Weiner J (1989) Including competitive asymmetry in measures of local interference in plant populations. Oecologia 80:349–355CrossRefGoogle Scholar
  69. Tielbörger K, Kadmon R (2000) Temporal environmental variation tips the balance between facilitation and interference in deseart plants. Ecology 81:1544–1553CrossRefGoogle Scholar
  70. Watanabe T (1986) Vegetation landscape and related alpine environmental factors of the Kuranosuke Cirque, Tateyama Range, northern Japanese Alps. Geogr Rev Japan 59A:404–425 (in Japanese) Google Scholar
  71. Webb CO, Ackerly DD, McPeek MA, Donoghue MJ (2002) Phylogenies and community ecology. Ann Rev Ecol Syst 33:475–505CrossRefGoogle Scholar
  72. Weiher E, Keddy PA (1995) Assembly rules, null models, and trait dispersion: new questions from old patterns. Oikis 74:159–164CrossRefGoogle Scholar
  73. Westoby M (1998) A leaf-height-seed (LHS) plant ecology strategy scheme. Plant Soil 199:213–227CrossRefGoogle Scholar
  74. Wieser G (2007) Climate at the upper timberline. In: Wieser G, Tausz M (eds) Trees at their upper limit. Springer, DordrechtCrossRefGoogle Scholar

Copyright information

© The Botanical Society of Japan and Springer Japan 2016

Authors and Affiliations

  1. 1.Department of Biology, Faculty of ScienceShinshu UniversityNaganoJapan
  2. 2.Institute of Mountain ScienceShinshu UniversityNaganoJapan

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