Abstract
Dense moss cushions of different size are distributed across the bare limestone pavements on Øland, SE Sweden. Increasing cushion size is predicted to physically protect and improve performance and colonization by vascular plants. Therefore, we tested water balance, phosphorus supply, and species richness, and evaluated duration of plant activity during desiccation as a function of ground area, for a large collection of moss cushions. We found that lower evaporation and higher water storage contributed equally to extending the desiccation period with increasing cushion size. Evaporation rates declined by the −0.36 power of cushion diameter, and were not significantly different from −0.50 for the square root function previously predicted for the increasing thickness of the boundary layer, with greater linear dimensions for smooth flat objects at low wind velocities. Size dependence vanished under stagnant conditions. One moss species was added to the species pool for every nine-fold increase in cushion area. Vascular plants were absent from the smallest cushions, whereas one or two species, on average, appeared in 375- and 8,500-cm2 cushions with water available for 6 and 10 days during desiccation. Phosphorus concentrations increased stepwise and four-fold from detritus to surface mosses and to vascular plants, and all three pools increased with cushion size. We conclude that cushion mosses and cushion size play a critical role in this resource-limited limestone environment by offering an oasis of improved water and nutrient supply to colonization and growth of plants.
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References
Alpert P (1988) Survival of desiccation-tolerant moss, Grimmia laevigata, beyond its observed microdistributional limit. J Bryol 15:219–227
Andersen JM (1976) Ignition method for determination of total phosphorus in lake sediments. Wat Res 10:329–331
Bates JW (1998) Is “life-form” a useful concept in bryophyte ecology? Oikos 82:223–237
Callaway RM, Brooker RW, Choler P et al (2002) Positive interactions among alpine plants increase with stress. Nature 417:844–848
Cavieres LA, Arroyo MTK, Molina-Montenegro MA, Torres C, Penalosa A (2002) Nurse effect of Bolax gummifera (Apiaceae) cushion plants in the alpine vegetation of the Chilean Patagonian Andes. J Veg Sci 13:547–554
Cavieres LA, Badano EI, Sierra-Almeida A, Gómez-Gonzáles S, Molina-Montenegro MA (2006) Positive interactions between alpine plant species and the nurse cushion plant Laretia acaulis do not increase with elevation in the Andes of central Chile. New Phytol 169:59–69
Coulianos C–C (1973) Seed-bugs (Het., Lygaeidae) from the Great Alvar of Öland, Southern Sweden. Some observations on their distribution in relation to food and microclimate. Zoon Suppl 1:115–122
Ekstam U, Forshed N (2002) Swedish alvar—history and ecology. Naturvårdsverket, Stockholm
Körner C (2003) Alpine plant life, 2nd edn. Springer, Berlin
Nobel PS (1991) Physicochemical and environmental plant physiology. Academic, New York
Proctor MCF (1980) Diffusion resistance in bryophytes. In: Grace J, Ford ED, Jarvis PG (eds) Plants and their atmospheric environment. Blackwell, Oxford, pp 219–229
Proctor MCF (2000) The bryophyte paradox: tolerance of desiccation, evasion of drought. Plant Ecol 151:41–49
Proctor MCF (2004) How long must a desiccation-tolerant moss tolerate desiccation? Some results of 2 years’ data logging on Grimmia pulvinata. Physiol Plantarum 122:21–27
Proctor MCF, Oliver MJ, Wood AJ, Alpert P, Stark LR, Cleavitt NL, Mishler BD (2007) Desiccation tolerance in bryophytes: a review. Bryologist 110:595–621
Rice SK, Schneider N (2004) Cushion size, surface roughness, and the control of water balance and carbon flux in the cushion moss Leucobryum glaucum (Leucobryaceae). Am J Bot 91:1164–1172
Rosenzweig ML (1995) Species diversity in space and time. Cambridge University Press, Cambridge
Sand-Jensen K, Jespersen TS (2011) Tolerance of the colonial cyanobacterium, Nostoc commune to extreme temperature variations (−269 to 105 °C), pH and salt stress. Oecologia (in press)
Sand-Jensen K, Madsen T (1992) Patch dynamics of the stream macrophye Callitriche cophocarpa. Freshwat Biol 48:271–283
Sand-Jensen K, Baastrup-Spohr L, Winkel A, Møller CL, Borum J, Brodersen C, Lindell T, Staehr P (2010) Plant distribution patterns and adaptation in a limestone quarry on Øland. Svensk Bot Tidskr 1:23–31
Schuepp PH (1993) Leaf boundary layers. New Phytol 125:477–507
Ström L, Owen AG, Godbold DL, Jones DC (2005) Organic acid behaviour in a calcareous soil—implications for rhizosphere nutrient cycling. Soil Biol Biochem 37:2046–2054
Tuba Z, Csintalan Z, Proctor MCF (1996) Photosynthetic response of a moss, Tortula ruralis, spp. ruralis, and the lichens Cladonia convoluta and C. furcata to water deficit and short periods of desiccation, and their ecophysiological significance: a baseline study at present-day CO2 concentration. New Phytol 133:353–361
Zotz G, Schweikert A, Jetz W, Westerman H (2000) Water relations and carbon gain are closely related to cushion size in the moss Grimmia pulvinata. New Phytol 148:59–67
Acknowledgments
This work was supported by a grant from the Carlsberg Foundation to K.S.J. We thank Hans Henrik Bruun for valuable comments to the manuscript and Brian Sorrell for comments and linguistic corrections.
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Communicated by Allan Green.
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Sand-Jensen, K., Hammer, K.J. Moss cushions facilitate water and nutrient supply for plant species on bare limestone pavements. Oecologia 170, 305–312 (2012). https://doi.org/10.1007/s00442-012-2314-z
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DOI: https://doi.org/10.1007/s00442-012-2314-z