Bryophytes as Predictors of Climate Change

doi:10.1017/CBO9780511779701.024

23 - Bryophytes as Predictors of Climate Change

Published online by Cambridge University Press: 05 October 2012

Edited by

Nancy G. Slack and

L. Dennis Gignac: Affiliation:
University of Alberta, Canada
Nancy G. Slack: Affiliation:
Sage Colleges, New York
Lloyd R. Stark: Affiliation:
University of Nevada, Las Vegas

Book contents

Get access

Summary

Introduction

Increases in atmospheric greenhouse gases that produce positive radiative forcings are having large-scale impacts on the global climate system, such as increases in temperatures, changes in precipitation patterns, and changes in the frequency of severe weather events. The greatest impact is occurring at high latitudes in the northern hemisphere, at high altitudes throughout the world, and in Antarctica and the sub-Antarctic Islands. Because of their efficient long-distance dispersal mechanisms and their high fidelity to climatically sensitive habitats, bryophytes should react quickly to changes to their environment and thus have the potential of being effective predictors of current climate change.

Since the beginning of the industrial era approximately 200 years ago, carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) concentrations have been increasing exponentially in the atmosphere (IPCC 2001). Concentrations of other greenhouse gases such as halocarbons and perfluorocarbons that are produced by anthropogenic activities are also increasing in the atmosphere. As a result of greenhouse gas enrichment, global mean surface air temperatures have risen by about 0.3–0.6 °C since the nineteenth century and by 0.2–0.3 °C over the past 40 years (IPCC 2001). The largest temperature increases have occurred over the northern hemisphere land mass north of 40° latitude (Serreze et al. 2000), on widespread high-altitude mountains throughout the world (Böhm et al. 2001), and in the Antarctic (Nyakatya & McGeoch 2008). Temperature increases have also been observed at low latitudes, although to a lesser extent than at high latitudes (Dash et al. 2007; Malhi et al. 2008).

Information

Type: Chapter
Information: Bryophyte Ecology and Climate Change , pp. 461 - 482

DOI: https://doi.org/10.1017/CBO9780511779701.024 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Book purchase

Temporarily unavailable

References

Aerts, R., Wallén, B. & Malmer, N. (1992). Growth-limiting nutrients in Sphagnum-dominated bogs subject to low and high atmospheric nitrogen supply. Journal of Ecology 80: 131–40.Google Scholar

Aerts, R., Wallén, B., Malmer, N. & Caluwe, H. D. (2001). Nutritional constraints on Sphagnum growth and potential decay in northern peatlands. Journal of Ecology 80: 292–9.Google Scholar

Aldous, A. R. (2002). Nitrogen retention by Sphagnum mosses: responses to atmospheric nitrogen deposition and drought. Canadian Journal of Botany 80: 721–31.Google Scholar

Bates, J. W., Thompson, K. & Grime, J. P. (2005). Effects of simulated long-term climatic change on the bryophytes of a limestone grassland community. Global Change Biology 11: 757–69.Google Scholar

Beilman, D. W. (2001). Plant community and diversity change due to localized permafrost dynamics in bogs of western Canada. Canadian Journal of Botany 79: 983–93.Google Scholar

Berendse, F., Breeman, N., Rydin, H.et al. (2001). Raised atmospheric CO2 and increased N deposition cause shifts in plant species composition and production in Sphagnum bogs. Global Change Biology 7: 591–8.Google Scholar

Birks, H. J. B. (1982). Quaternary bryophyte paleo-ecology. In Bryophyte Ecology, ed. Smith, A. J. E., pp. 273–490. New York: Chapman & Hall.

Böhm, R., Auer, I., Brunetti, M.et al. (2001). Regional temperature variability in the European Alps: 1760–1998 from homogenized instrumental time series. International Journal of Climatology 21: 1779–801.Google Scholar

Bragazza, L., Tahvanainen, T., Kutnar, L.et al. (2004). Nutritional constraints in ombrotrophic Sphagnum plants under increasing atmospheric nitrogen deposition in Europe. New Phytologist 163: 609–16.Google Scholar

Brooker, R. W. (2006). Plant-plant interactions and environmental change. New Phytologist 171: 271–89.Google Scholar

Callaghan, T. V., Carlsson, B. Å., Sonnesson, M. & Temesváry, A. (1997). Between-year variation in climate-related growth of circumarctic populations of the moss Hylocomium splendens. Functional Ecology 11: 157–65.Google Scholar

Camill, P. (1999). Patterns of boreal permafrost peatland vegetation across environmental gradients sensitive to climate warming. Canadian Journal of Botany 77: 721–33.Google Scholar

Camill, P. (2005). Permafrost thaw accelerates in boreal peatlands during late-20th century climate warming. Climatic Change 68: 135–52.Google Scholar

Camill, P. & Clark, J. S. (1998). Climate change disequilibrium of boreal permafrost peatlands caused by local processes. American Naturalist 151: 207–22.Google Scholar

ChapinIII, F. S., Shaver, G. R., Giblin, A. E., Nadelhoffer, K. J. & Laundre, J. A. (1995). Responses of arctic tundra to experimental and observed changes in climate. Ecology 76: 694–711.Google Scholar

Christensen, T. R., Johansson, T., Åkerman, H. J.et al. (2004). Thawing sub-arctic permafrost: effects on vegetation and methane emissions. Geophysical Research Letters 31: 1–4.Google Scholar

Chylek, P., Box, J. E. & Lesins, G. (2004). Global warming and the Greenland Ice Sheet. Climatic Change 63: 201–21.Google Scholar

Convey, P., Frenot, Y., Gremmen, N. & Bergstrom, D. M. (2006). Biological invasions. In Trends in Antarctic Terrestrial and Limnetic Ecosystems, ed. Bergstrom, D. M., Convey, P. & Huiskes, A. L., pp. 193–220. Dordrecht, The Netherlands: Springer.CrossRef

Cornelissen, J. H. C., Callaghan, T. V., Alatalo, J. M.et al. (2001). Global change and Arctic ecosystems: is lichen decline a function of increases in vascular plant biomass? Journal of Ecology 89: 984–94.Google Scholar

Dash, S. K., Jenamani, R. K., Kalsi, S. R. & Panda, S. K. (2007). Some evidence of climate change in twentieth-century India. Climatic Change 85: 299–321.Google Scholar

Dirkse, G. M. & Martakis, G. F. P. (1992). Effects of fertilizer on bryophytes in Swedish experiments on forest fertilization. Biological Conservation 59: 155–61.Google Scholar

Dorrepaal, E., Aerts, R., Cornelissen, J. H. C., Callaghan, T. V. & Logtestijn, R. S. P. (2003). Summer warming and increased winter snow cover affect Sphagnum fuscum growth, structure and production in a sub-arctic bog. Global Change Biology 10: 93–104.Google Scholar

Frahm, J.-P. (2007). Moose als Indikatoren des Klimawandels. Gefahrstofee-Reinhaltung der Luft-Ausgabe 6: 269–73.Google Scholar

Frahm, J.-P. (2008). Diversity, dispersal and biogeography of bryophytes (mosses). Biodiversity Conservation 17: 277–84.Google Scholar

Frahm, J. -P. & Klaus, D. (2001). Bryophytes as indicators of recent climate fluctuations in Central Europe. Lindbergia 26: 97–104.Google Scholar

Gerdol, R., Petraglia, A., Bragazza, L., Iacumin, P. & Brancaleoni, L. (2007). Nitrogen deposition interacts with climate in affecting production and decomposition rates in Sphagnum mosses. Global Change Biology 13: 1810–21.Google Scholar

Giannini, A., Biasutti, M., Held, I. M. & Sobel, A. H. (2008). A global perspective on African climate. Climatic Change 90: 359–83.Google Scholar

Gordon, C., Wynn, J. M. & Woodin, S. J. (2001). Impacts of increased nitrogen supply on high Arctic heath: the importance of bryophytes and phosphorus availability. New Phytologist 149: 461–71.Google Scholar

Graglia, E., Jonasson, S., Michelsen, A.et al. (2001). Effects of environmental perturbations on abundance of subarctic plants after three, seven and ten years of treatments. Ecography 24: 5–12.Google Scholar

Gunnarsson, U. & Flodin, L-Å. (2007). Vegetation shifts towards wetter site conditions on oceanic ombrotrophic bogs in southwestern Sweden. Journal of Vegetation Science 18: 595–604.Google Scholar

Gunnarsson, U. & Rydin, H. (2000). Nitrogen fertilization reduces Sphagnum production in bog communities. New Phytologist 147: 527–37.Google Scholar

Gunnarsson, U., Granberg, G. & Nilsson, M. (2004). Growth, production and interspecific competition in Sphagnum: effects of temperature, nitrogen and sulphur treatments on a boreal mire. New Phytologist 163: 349–59.Google Scholar

Gunnarsson, U., Malmer, N. & Rydin, H. (2002). Dynamics or constancy in Sphagnum dominated mire ecosystems? A 40 year old study. Ecography 25: 685–704.Google Scholar

Gunnarsson, U., Rydin, H. & Sjörs, H. (2000). Diversity and pH changes after 50 years on the boreal mire Skattlösbergs Stormosse, Central Sweden. Journal of Vegetation Science 11: 277–86.Google Scholar

Hedenäs, L., Bisang, I., Tehler, A.et al. (2002). A herbarium-based method for estimates of temporal frequency changes: mosses in Sweden. Biological Conservation 105: 321–31.Google Scholar

Heijmans, M. M. P. D., Berendse, F., Arp, W. J.et al. (2001). Effects of elevated carbon dioxide and increased nitrogen deposition on bog vegetation in the Netherlands. Journal of Ecology 89: 268–79.Google Scholar

Heijmans, M. M. P. D., Klees, H. & Berendse, F. (2002). Competition between Sphagnum magellanicum and Eriophorum angustifolium as affected by raised CO2 and increased N deposition. Oikos 97: 415–25.Google Scholar

Hobbie, S. E., Shevtsova, A. & Chapin, F. S. (1999). Plant response to species removal and experimental warming in Alaskan tussock tundra. Oikos 84: 417–34.Google Scholar

Hohenwallner, D., Zechmeister, H. G. & Grabherr, G. (2002). Bryophyten und ihre Eignung als Indikatoren für den Klimawandel im Hochgebirge – erste Ergebnisse. Österreichisches Botanikertreffen 10: 19–21.Google Scholar

Hogg, P., Squires, P. & Fitter, A. H. (1995). Acidification, nitrogen deposition and rapid vegetational change in a small valley mire in Yorkshire. Biological Conservation 71: 143–53.Google Scholar

Hollister, R. D., Webber, P. J. & Tweedie, C. E. (2005). The response of Alaskan arctic tundra to experimental warming: differences between short- and long-term responses. Global Change Biology 11: 525–36.Google Scholar

Hoosbeek, M. R., Breemen, N., Berendse, F.et al. (2001). Limited effect of increased atmospheric CO2 concentration on ombrotrophic bog vegetation. New Phytologist 150: 459–63.Google Scholar

Hoosbeek, M. R., Breemen, N., Vasander, H., Buttler, A. & Berendse, F. (2002). Potassium limits potential growth of bog vegetation under elevated atmospheric CO2 and N deposition. Global Change Biology 8: 1130–8.Google Scholar

,IPCC (Intergovernmental Panel on Climate Change). (2001). Climate Change 2001: The Scientific Basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change. New York: Cambridge University Press.

,IPCC (Intergovernmental Panel on Climate Change). 2007. Climate Change (2007): The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. New York: Cambridge University Press.

Jägerbrand, A. K., Lindblad, K. E. M., Björk, R. G., Alatalo, J. M. & Molau, U. (2006). Bryophyte and lichen diversity under simulated environmental change compared with observed variation in unmanipulated alpine tundra. Biodiversity and Conservation 15: 4453–75.Google Scholar

Jägerbrand, A. K., Molau, U. & Alatalo, J. M. (2003). Responses of bryophytes to simulated environmental change at Latnjajaure, northern Sweden. Journal of Bryology 25: 163–8.Google Scholar

Jauhiainen, J., Vasander, H. & Silvola, J. (1994). Response of Sphagnum fuscum to N deposition and increased CO2. Journal of Bryology 18: 183–95.Google Scholar

Jauhiainen, J., Vasander, H. & Silvola, J. (1998a). Nutrient concentration in Sphagna at increased N-deposition rates and raised atmospheric CO2 concentrations. Plant Ecology 138: 149–60.Google Scholar

Jauhiainen, J., Wallén, B. & Malmer, N. (1998b). Potential NH4+ and NO3− uptake in seven Sphagnum species. New Phytologist 138: 287–93.Google Scholar

Jones, M. L. M., Oxley, E. R. B. & Ashenden, T. W. (2002). The influence of nitrogen deposition, competition and desiccation on growth and regeneration of Racomitrium lanuginosum (Hedw.) Brid. Environmental Pollution 120: 371–8.Google Scholar

Jónsdóttir, I. S., Magnússon, B., Gudmundsson, J., Elmarsdóttir, Á. & Hjartarson, H. (2005). Variable sensitivity of plant communities in Iceland to experimental warming. Global Change Biology 11: 553–63.Google Scholar

Jorgenson, M. T., Racine, C. H., Walters, J. C. & Osterkamp, T. E. (2001). Permafrost degradation and ecological changes associated with a warming climate in central Alaska. Climatic Change 48: 551–79.Google Scholar

Lamers, L. P. M., Bobbink, R. & Roelofs, J. G. M. (2000). Natural nitrogen filter fails in raised bog. Global Change Biology 6: 583–6.Google Scholar

Roux, P. & McGeoch, M. A. (2008). Changes in climate extremes, variability and signature on sub-Antarctic Marion Island. Climatic Change 86: 309–29.Google Scholar

Lewis Smith, R. I. (2005). Bryophyte diversity and ecology of two geologically contrasting Antarctic islands. British Bryophyte Society 25: 195–206.Google Scholar

Limpens, J., Berendse, F. & Klees, H.. (2004). How phosphorus availability affects the impact of nitrogen deposition on Sphagnum and vascular plant bogs. Ecosystems 7: 793–804.Google Scholar

Limpens, J., Tomassen, H. B. M. & Berendse, F. (2003). Expansion of Sphagnum fallax in bogs: striking the balance between N and P availability. Journal of Bryology 25: 83–90.Google Scholar

Malhi, Y., Roberts, T., Betts, R. A.et al. (2008). Climate change, deforestation, and the fate of the Amazon. Science 319: 169–72.Google Scholar

Malmer, N., Albinsson, C., Svensson, B. M. & Wallén, B. (2003). Interferences between Sphagnum and vascular plants: effects on plant community structure and peat formation. Oikos 100: 469–82.Google Scholar

Malmer, N., Johansson, T., Olsrud, M. & Christensen, T. R. (2005). Vegetation, climatic changes and net carbon sequestration in a North-Scandinavian subarctic mire over 30 years. Global Change Biology 11: 1895–909.Google Scholar

Miller, N. G. (1980). Fossil mosses of North America and their significance. In The Mosses of North America, ed. Taylor, R. J. & Leviton, A. E., pp. 9–36. San Francisco, CA:Pacific Division of the American Association for the Advancement of Science.

Molau, U. & Alatalo, J. M. (1998). Responses of subarctic-alpine plant communities to simulated environmental change: biodiversity of bryophytes, lichens and vascular plants. Ambio 27: 322–9.Google Scholar

Nyakatya, M. J. & McGeoch, M. A. (2008). Temperature variation across Marion Island associated with a keystone plant species (Azorella selago Hook. (Apiaceae)). Polar Biology 31: 139–51.Google Scholar

Osterkamp, T. E. & Jorgenson, M. T. (2005). Response of boreal ecosystems to varying modes of permafrost degradation. Canadian Journal of Forest Research 35: 2100–11.Google Scholar

Osterkamp, T. E., Viereck, L., Shur, Y.et al. (2000). Observations of thermokarst and its impact on boreal forests in Alaska, U.S.A. Arctic, Antarctic, and Alpine Research 32: 303–15.Google Scholar

Paeth, H, Scholten, A., Friederichs, P. & Hense, A. (2008). Uncertainties in climate change predictions: El Niño-Southern Oscillation and monsoons. Global and Planetary Change 60: 265–88.Google Scholar

Payette, S., Delwaide, A., Caccianiga, M. & Beauchemin, M. (2004). Accelerated thawing of sub-arctic peatland permafrost over the last 50 years. Geophysical Research Letters 31: 1–4.Google Scholar

Pearce, I. S. K. & Wal, R. (2002). Effects of nitrogen deposition on growth and survival of montane Racomitrium lanuginosum heath. Biological Conservation 104: 83–9.Google Scholar

Phuyal, M., Artz, R. R. E., Sheppard, L., Leith, I. D. & Johnson, D. (2008). Long-term nitrogen deposition increases phosphorus limitation of bryophytes in an ombrotrophic bog. Plant Ecology 196: 111–21.Google Scholar

Potter, J. A., Press, M. C., Callaghan, T. V. & Lee, J. A. (1995). Growth responses of Polytrichum commune and Hylocomium splendens to simulated environmental change in the sub-arctic. New Phytologist 131: 533–41.Google Scholar

Press, M. C., Potter, J. A., Burke, M. J. W., Callaghan, T. V. & Lee, J. A. (1998). Responses of a subarctic dwarf shrub heath community to simulated environmental change. Journal of Ecology 86: 315–27.Google Scholar

Robinson, C. H., Wookey, P. A., Lee, J. A., Callaghan, T. V. & Press, M. C. (1998). Plant community responses to simulated environmental change at a high arctic site. Ecology 79: 856–66.Google Scholar

Robroek, B. J. M., Limpens, J., Breeuwer, A., Crushell, P. H. & Schouten, M. G. C. (2007). Interspecific competition between Sphagnum mosses at different water tables. Functional Ecology 21: 805–12.Google Scholar

Root, L. T., Price, J. T., Hall, K. H.et al. (2003). Fingerprints of global warming on wild animals and plants. Nature 421: 57–60.Google Scholar

Sandvik, M. & Heegaard, E. (2003). Effects of simulated environmental changes on growth and growth form in a late snowbed population of Pohlia wahlenbergii (Web. et Mohr) Andr. Arctic, Antarctic, and Alpine Research 35: 341–8.Google Scholar

Schipperges, B. & Rydin, H. (1998). Response of photosynthesis of Sphagnum species from contrasting microhabitats to tissue water content and repeated desiccation. New Phytologist 140: 677–84.Google Scholar

Schuur, E. A. G., Crummer, K. G., Vogel, J. G. & Mack, M. C. (2007). Plant species composition and productivity following permafrost thaw and thermokarst in Alaskan tundra. Ecosystems 10: 280–92.Google Scholar

Serreze, M. C., Walsh, J. E., Chapin, F. S., et al. (2000). Observational evidence of recent change in the northern high-latitude environment. Climatic Change 46: 159–207.Google Scholar

Shaver, G. R., Bret-Harte, M. S., Jones, M. H.et al. (2001). Species competition interacts with fertilizer to control long-term change in tundra productivity. Ecology 82: 3163–81.Google Scholar

Söderström, L. & During, H. J. (2005). Bryophyte rarity viewed from the perspectives of life history strategy and metapopulation dynamics. Journal of Bryology 27: 261–8.Google Scholar

Soja, A. J., Tchebakova, N. M., French, N. H. F., et al. (2007). Climate-induced boreal forest change: predictions versus current observations. Global and Planetary Change 56: 274–96.Google Scholar

Sollid, J. L. & Sørbell, L. (1998). Palsa bogs as climate indicators – examples from Doorefjell, southern Norway. Ambio 27: 287–91.Google Scholar

Sonesson, M., Carlsson, B. Å., Callaghan, T. V., et al. (2002). Growth of two peat-forming mosses in subarctic mires: species interactions and effects of simulated climate change. Oikos 99: 151–60.Google Scholar

Stapper, N. J. & Kricke, R. (2004). Epiphytische Moose und Flechten als Bioindikatoren von städtischer Überwärmung, Standorteutrophierung und verkehrsbedingten Immissionen. Limprichtia 24: 187–208.Google Scholar

Sturm, M., Racine, C. & Tape, K. (2001). Increasing shrub abundance in the Arctic. Nature 411: 546–7.Google Scholar

Toet, S., Cornelissen, J. H. C., Aerts, R., et al. (2006). Moss responses to elevated CO2 and variations in hydrology in a temperature lowland peatland. Plant Ecology 182: 27–40.Google Scholar

Turetsky, M. R., Wieder, R. K., Vitt, D. H., Evans, R. J. & Scott, K. D. (2007). The disappearance of relict permafrost in boreal north America: effects on peatland carbon storage and fluxes. Global Change Biology 13: 1922–34.Google Scholar

Heijden, E., Verbeek, S. K. & Kuiper, P. J. C. (2000). Elevated atmospheric CO2 and increased nitrogen deposition: effects on C and N metabolism and growth of the peat moss Sphagnum recurvum P. Beauv. var. mucronatum (Russ.) Warnst. Global Change Biology 6: 201–12.Google Scholar

Wal, R., Pearce, I., Brooker, R., et al. (2003). Interplay between nitrogen deposition and grazing causes habitat degradation. Ecology Letters 6: 141–6.Google Scholar

Wijk, M. T., Clemmensen, K. E., Shaver, G. R., et al. (2003). Long-term ecosystem level experiments at Toolik Lake, Alaska, and at Abisko, northern Sweden: generalizations and differences in ecosystem and plant type responses to global change. Global Change Biology 10: 105–23.Google Scholar

Vitt, D. H. (1990). Growth and production dynamics of boreal mosses over climatic, chemical and topographic gradients. Botanical Journal of the Linnean Society 104: 35–59.Google Scholar

Vitt, D. H. & Halsey, L. A. (1994). The bog landforms of continental Western Canada in relation to climate and permafrost patterns. Arctic and Alpine Research 26: 1–13.Google Scholar

Vitt, D. H., Halsey, L. A. & Zoltai, S. C. (2000a). The bog landforms of continental western Canada in relation to climate and permafrost patterns. Arctic and Alpine Research 26: 1–13.Google Scholar

Vitt, D. H., Halsey, L. A. & Zoltai, S. C. (2000b). The changing landscape of Canada's western boreal forest: the current dynamics of permafrost. Canadian Journal of Forest Research 30: 283–7.Google Scholar

Vitt, D. H., Wieder, K., Halsey, L. A. & Turetsky, M. (2003). Response of Sphagnum fuscum to nitrogen deposition: a case study of ombrogenous peatlands in Alberta, Canada. Bryologist 106: 235–45.Google Scholar

Wahren, C.-H. A., Walker, M. D. & Bret-Harte, M. S. (2005). Vegetation responses in Alaskan arctic tundra after 8 years of a summer warming and winter snow manipulation experiment. Global Change Biology 11: 537–52.Google Scholar

Wasley, J., Robinson, S. A., Lovelock, C. E. & Popp, M. (2006). Climate change manipulations show Antarctic flora is more strongly affected by elevated nutrients than water. Global Change Biology 12: 1800–12.Google Scholar

Weltzin, J. F., Harth, C., Bridgham, S. D., Pastor, J. & Vonderharr, M. (2001). Production and microtopograhy of bog bryophytes: response to warming and water-table manipulations. Oecologia 128: 557–65.Google Scholar

Whinam, J. & Copson, G. (2006). Sphagnum moss: an indicator of climate change in the sub-Antarctic. Polar Record 42: 43–9.Google Scholar

Wiedermann, M. M., Nordin, A., Gunnarsson, U., Nilsson, M. B. & Ericson, L. (2007). Global change shifts vegetation and plant-parasite interactions in a boreal mire. Ecology 88: 454–64.Google Scholar

Zechmeister, H. G. (1995). Growth rates of five pleurocarpous moss species under various climatic conditions. Journal of Bryology 18: 455–68.Google Scholar

Accessibility standard: Unknown

Accessibility compliance for the PDF of this book is currently unknown and may be updated in the future.