Effect of alpine treeline conditions on the response of the stem radial variation of Picea meyeri Rebd. et Wils to environmental factors / Manyu Dong [et al.]

• Autorzy: Dong M. , Jiang Y. , Zhang W. , Yang Y. , Yang H.
• Języki publikacji: EN

Abstrakty

EN

Alpine treeline is an important ecological boundary, marked by a change in site conditions and plant communities when crossing the forest limit, and tree growth at treeline is strongly constrained by the harsh environment. Finer resolution studies of tree radial variation on short temporal scales can be useful to explore the main physical variables that trigger the radial growth. From 19th Oct. 2008 to 25th Oct. 2009, we continuously monitored the stem radial variation of Picea meyeri Rebd. Et Wils trees using point dendrometers, at the treeline of Luya Mountains (altitude 2700 m a.s.l.), North China. Our results showed that there were two reverse daily variation patterns in the warm and cold seasons, which were related to the daily transpiration course and daily stem freeze-thaw cycles, respectively. Annual stem radial growth of Picea meyeri was divided into the four distinct periods: 1) spring stem rehydration, 2) summer stem rapid growth, 3) autumn stem dehydration contraction and 4) winter stem stagnation. The stem radial variation of Picea meyeri at the alpine treeline was closely dependent on climate conditions. Soil temperature was the most important factor affecting radial growth, which determined the initiation of radial growth and the cambial activity during the growing season.

Słowa kluczowe

EN

dendrometer; growth-climate relationship; Picea meyeri; stem radial growth; treeline

PL

granica drzew; klimat; świerk; wzrost; związek

• Wydawca: Museum and Institute of Zoology, Polish Academy of Sciences
• Czasopismo: Polish Journal of Ecology
• Rocznik: 2011
• Tom: Vol. 59, nr 4
• Strony: 729--739
• Opis fizyczny: Bibliogr. 50 poz.,Rys., tab.,

Twórcy

autor

Dong M.

autor

Jiang Y.

autor

Zhang W.

autor

Yang Y.

autor

Yang H.

• State Key Laboratory of Earth Surface Process and Resource Ecology, College of Resource Science and Technology, Beijing Normal University, Beijing 100875, China ; College of Life Science, Beijing Normal University, Beijing 100875 China,

Bibliografia

• 1. Ameglio T., Cochard H., Ewers F.W. 2001 – Stem diameter variations and cold hardiness in walnut trees – J. Exp. Bot. 52: 2135–2142.
• 2. Biondi F., Hartsough P.C., Estrada I.G. 2005 – Daily weather and tree growth at the tropical treeline of North America – Arct. Antarct. Alp. Res. 37: 16–24.
• 3. Campbell G.S., Norman J.M. 1998 – An introduction to environmental biophysics – Springer-Verlag Press, New York, pp. 40–45.
• 4. Carrer M., Nola P., Eduard J.L., Motta R., Urbinati C. 2007 – Regional variability of climate-growth relationships in Pinus cembra high elevation forests in the Alps – J. Ecol. 95: 1072–1083.
• 5. Deslauriers A., Anfodillo T., Rossi S., Carraro V. 2007a – Using simple causal modeling to understand how water and temperature affect daily stem radial variation in trees – Tree Physiol. 27: 1125–1136.
• 6. Deslauriers A., Morin H. 2005 – Intra-annual tracheid production in balsam fir stems and the effect of meteorological variables – Trees, 19: 402–408.
• 7. Deslauriers A., Morin H., Urbinati C., Carrer M. 2003 – Daily weather response of balsam fir (Abies balsamea (L.) Mill.) stem radius increment from dendrometer analysis in the boreal forests of Québec (Canada) – Trees, 17: 477–484.
• 8. Deslauriers A., Rossi S., Anfodillo T. 2007b – Dendrometer and intra-annual tree growth: What kind of information can be inferred? – Dendrochronologia, 25: 113–124.
• 9. Domisch T., Finér L., Lehto T. 2001 – Effects of soil temperature on biomass and carbohydrate allocation in Scots pine (Pinus sylvestris) seedlings at the beginning of the growing season – Tree Physiol. 21: 465–472.
• 10. Downes G., Beadle C., Worledge D. 1999 – Daily stem growth patterns in irrigated Eucalyptus globulus and E. nitens in relation to climate – Trees, 14: 102–111.
• 11. Drew M.D., Downes G.M. 2009 – The use of precision dendrometers in research on daily stem and wood property variation: A review – Dendrochronologia, 27: 159–172.
• 12. Fritts H.C., Smith D.G., Cardis J.W., Budelsky C.A. 1965 – Tree-ring characteristics along a vegetation gradient in northern Arizona – Ecology, 46: 393–401.
• 13. Funada R., Kubo T., Sugiyama T., Fushitani M. 2002 – Changes in levels of endogenous plant hormones in cambial regions of stems of Larix kaempferi at the onset of cambial activity in springtime – J. Wood Sci. 48: 75–80.
• 14. Gruber A., Zimmermann J., Wieser G., Oberhuber W. 2009 – Effects of climate variables on intra-annual stem radial increment in Pinus cembra (L.) along the alpine treeline ecotone – Ann. For. Sci. 66: 503–513.
• 15. Havranek W.M. 1972 – Über die bedeutung der bodentemperatur fürdie photosynthese und die transpiration junger forstpflanzen und für die stoffproduktion an der waldgrenze – J. Appl. Bot.-Angew. Bot. 46: 101–116.
• 16. Hofgaard A., Tardif J., Bergeron Y. 1999 – Dendroclimatic response of Picea mariana and Pinus banksiana along a latitudinal gradient in the eastern Canadian boreal forest – Can. J. For. Res. 29: 1333–1346.
• 17. Holtmeier F.K., Broll G. 2005 – Sensitivity and response of northern hemisphere altitudinal and polar treelines to environmental change at landscape and local scales – Global Ecol. Biogeogr. 14: 395–410.
• 18. James J., Grace J., Hoad S. 1994 – Growth and photosynthesis of Pinus sylvestris at its altitudinal limit in Scotland – J. Ecol. 82: 297–306.
• 19. Kirdyanov A.V., Hughes M.K., Vaganov E.A., Schweingruber F., Silkin P. 2003 – The importance of early summer temperature and date of snow melt for tree growth in the Siberian Subarctic – Trees, 17: 61–69.
• 20. Körner C. 1998 – A re-assessment of high elevation treeline positions and their explanation – Oecologia, 115: 445–459.
• 21. Körner C., Paulsen J. 2004 – A world-wide study of high altitude treeline temperatures – J. Biogeogr. 31: 713–732.
• 22. Kozłowska A., Raczkowska Z. 2006 – Effect of snow patches on the vegetation in the highmountain nival gullies (Tatra Mts. Poland) – Pol. J. Ecol. 54: 69–90.
• 23. Kozlowski T.T., Pallardy S.G. 2002 – Acclimatation and adaptive responses of woody plants to environmental stresses – Bot. Rev. 68: 270–234.
• 24. Lori D.D., Thomas T.V. 2004 – Spatiotemporal influences of climate on altitudinal treeline in northern Patagonia – Ecology, 85: 1284–1296.
• 25. Loris K., Havranek W.M., Wieser G. 1999 – The ecological significance of thickness changes in stem, branches and twigs of Pinus cembra L. during winter – Phyton, 39: 117–122.
• 26. Major J.E., Johnsen K.H. 2001 – Shoot water relations of mature black spruce families displaying a genotype×environmental interaction in growth rate. III. Diurnal patterns as influenced by vapor pressure deficit and internal water status – Tree Physiol. 21: 579–587.
• 27. Mäkinen H., Seo J.W., Nöjd P., Schmitt U., Jalkanen R. 2008 – Seasonal dynamics of wood formation: a comparison between pinning, microcoring and dendrometer measurements – Eur. J. For. Res. 127: 235–245.
• 28. Mayr S., Wieser G., Bauer H. 2006 – Xylem temperature during winter in conifer at the alpine timberline – Agr. For. Meteorol. 137: 81–88.
• 29. Oberhuber W. 2004 – Influence of climate on radial growth of Pinus cembra within the alpine timberline ecotone – Tree Physiol. 24: 291–301.
• 30. Oribe Y., Funada R., Kubo T. 2003 – Relationships between cambial activity, cell differentiation and the localization of starch in storage tissues around the cambium in locally heated stems of Abies sachalinensis (Schmidt) Masters – Trees, 17: 185–192.
• 31. Perämäki M., Nikinmaa E., Sevanto S., Ilvesniemi H., Siivola E., Hari P., Vesala T. 2001 – Tree stem diameter variations and transpiration in Scots pine: an analysis using a dynamic sap flow model – Tree Physiol. 21: 889–897.
• 32. Perez C.A., Carmona M.R., Aravena J.C., Farina J.M., Armesto J.J. 2009 – Environmental controls and patterns of cumulative radial increment of evergreen tree species in montane, temperate rainforests of Chiloe Island, southern Chile – Austral Ecol. 34: 259–271.
• 33. Pop E.W., Oberbauer S.F., Starr G. 2000 – Predicting vegetative bud break in two arctic deciduous shrub species, Salix pulcbra and Betula nana – Oecologia, 124: 176–184.
• 34. Proseus T.E., Boyer J.S. 2005 – Turgor pressure moves polysaccharides into growing cell walls of Chara coralline – Ann. Bot. 95: 967–979.
• 35. Rossi S., Deslauriers A., Anfodillo T. 2007 – Evidence of threshold temperatures for xylogenesis in conifers at high altitudes – Oecologia, 152: 1–12.
• 36. Rossi S., Deslauriers A., Anfodillo T., Morin H., Saracino A., Motta R., Borghetti M. 2006 – Conifers in cold environments synchronize maximum growth rate of tree-ring formation with day length – New Phytol. 170: 301–310.
• 37. Rozas V., Desoto R., Olano J.M. 2009 – Sex-specific, age-dependent sensitivity of treering growth to climate in the dioecious tree Juniperus thurifera – New Phytol. 182: 687–697.
• 38. Ryan D.A.J., McLaughlin D.L., Gordon A.M. 1994 – Interpretation of sugar maple (Acer saccharum) ring chronologies from central and southern Ontario using a mixed linear model – Can. J. For. Res. 24: 568–575.
• 39. Savidge R.A. 2000 – Intrinsic regulation of cambial growth – J. Plant Growth Regul. 20: 52–77.
• 40. Sevanto S., Suni T., Pumpanen J., Grönholm T., Kolari P., Nikinmaa E., Hari P., Vesala T. 2006 – Wintertime photosynthesis and water uptake in a boreal forest – Tree Physiol. 26: 749–757.
• 41. Steppe K., De Pauw D.I.W., Lemeur R., Vanrolleghem P.A. 2006 – A mathematical model linking tree sap dynamics to daily stem diameter fluctuations and radial stem growth – Tree Physiol. 26: 257–273.
• 42. Sun P., Zhao X.Q., Zhu W.Y., Xu S.X. 2005 – Effect of borrowing activity of root vole (Microtus oeconomus Pallas) on plant diversity in alpine meadow – Pol. J. Ecol. 53: 597–602.
• 43. Tardif J., Flannigan M., Bergeron Y. 2001 – An analysis of the daily radial activity of 7 boreal tree species, Northwestern Quebec – Environ. Monit. Assess. 67: 141–160.
• 44. Turcotte A., Morin H., Krause C., Deslauriers A., Martel M.T. 2009 – The timing of spring rehydration and its relation with the onset of wood formation in black spruce – Agr. For. Meteorol. 149: 1403–1409.
• 45. Vaganov E.A., Hughest M.K., Kirdyanov A.V., Schweingruber F.H., Silkin P.P. 1999 – Influence of snowfall and melt timing on tree growth in subarctic Eurasia – Nature, 400: 149–151.
• 46. Zahner R. 1963 – Internal moisture stress and wood formation in conifers – For. Prod. J. 13: 240–247.
• 47. Zhang J.T. 1989 – District of vegetation vertical zone in luya Mountain, Shanxi – Scientia Geographica Sinica. 4: 346–353 (in Chinese, English abstract).
• 48. Zweifel R., Häsler R. 2000 – Frost-induced reversible shrinkage of bark of mature subalpine conifers – Agr. For. Meteorol. 102: 213–222.
• 49. Zweifel R., Häsler R. 2001 – Dynamics of water storage in mature subalpine Picea abies: temporal and spatial patterns of change in stem radius – Tree Physiol. 21: 561–569.
• 50. Zweifel R., Zimmermann L., Zeugin F., Newber y D.M. 2006 – Intra-annual radial growth and water relations of trees: implications towards a growth mechanism – J. Exp. Bot. 57: 1445–1459.