Abstract
The capacity of Mediterranean species to adapt to variable nutrient supply levels in a global change context can be a key factor to predict their future capacity to compete and survive in this new scenario. We aimed to investigate the capacity of a typical Mediterranean tree species, Pinus halepensis, to respond to sudden changes in N and P supply in different environmental conditions. We conducted a fertilisation, irrigation and removal of competing vegetation experiment in a calcareous post-fire shrubland with an homogeneous young (5 years old) population of P. halepensis in order to investigate the retranslocation and nutrient status for the principal nutrients (N, P, Mg, K, S, Ca and Fe), and the nutrient use efficiency (NUE) of the most important nutrients linked to photosynthetic capacity (N, P, Mg and K). P fertilisation increased P concentration in needles, P, N, Mg and K retranslocations, and NUE calculated as biomass production per unit of nutrient lost in the litterfall. The P fertilisation was able to increase the aboveground biomasses and P concentration 3 years after P fertiliser application. Those responses to P fertilisation were enhanced by the removal of competing vegetation. The N needle and litterfall concentration decreased after P fertilisation and this effect was greater when the P fertilisation was accompanied by removal of competing vegetation. The increase of P availability decreased the P-NUE and increased the N-NUE when these variables were calculated as aboveground biomass production per unit of P present in the biomass. Both P-NUE and N-NUE increased when calculated as total aboveground production per unit of nutrient loss. The results show that it is necessary to calculate NUE on a different basis to have a wider understanding of nutrient use. The irrigation did not change the needle nutrient concentrations and the litterfall production, but it significantly changed the nutrient litterfall concentrations and total aboveground contents (especially P and K). These results show a high capacity of P. halepensis to quickly respond to a limiting nutrient such as P in the critical phases of post-fire regeneration. The increase in P availability had a positive effect on growth and P concentrations and contents in aboveground biomass, thus increasing the capacity of growth in future periods and avoiding immediate runoff losses and leachate. This capacity also strongly depends on neighbour competition.
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References
Aarsen LW, Epp GA (1990) Neighbour manipulation in natural vegetation: a review. J Veg Sci 1:13–30
Adams MB, Campbell RG, Allen HL, Davey CB (1987) Root and foliar nutrients concentrations in Lobolly Pine: effects of season, site, and fertilisation. For Sci 33:984–996
Aerts R (1989) Aboveground biomass and nutrient dynamics of Calluna vulgaris and Molinia caerulea in a dry heathland. Oikos 56:31–38
Aerts R, Verhoeven JTA, Whigham DF (1999) Plant mediated controls on nutrient cycling in temperate fens and bogs. Ecology 80:2170–2182
Birk EM, Vitousek PM (1986) Nitrogen availability and nitrogen use efficiency in loblolly pine stands. Ecology 67:69–79
Björkman C, Larsson S, Gref R (1991) Effects of nitrogen fertilisation on pine needle chemistry and sawfly performance. Oecologia 86:202–209
Bradstreet RB (1991) The Kjeldahl method for nitrogen determination. Academic, New York
Bridgham SD, Pastor J, McClaugherty CA, Richardson CJ (1995) Nutrient-use efficiency: a litterfall index, a model and a test along a nutrient availability gradient in north Carolina peatlands. Am Nat 145:1–21
Bussotti F, Borghini F, Celesti C, Leonzio C, Bruschi P (2000) Leaf morphology and macronutrients in broadleaved trees in central Italy. Trees 14:361–368
Chapin FS III (1980) The mineral nutrition of wild plants. Annu Rev Ecol Syst 11:233–260
Chapin FS III, Kedrowski RA (1983) Seasonal changes in nitrogen and phosphorous fractions and autumn retranslocation in evergreen and deciduous taiga trees. Ecology 64:376–391
Chapin FS III, Molainen L (1991) Nutritional controls over nitrogen and phosphorous resorption from Alaskan birch leaves. Ecology 72:709–717
Chapin FS III, Vitousek PM, van Kleve K (1986) The nature of nutrient limitation in plant communities. Am Nat 127:48–58
Christiansen NL, Muller CH (1975) Effects of fire on factors controlling plant growth in Adenostoma chaparral. Ecol Monogr 45:29–55
Clarkson DT (1978) Phosphorus supply and growth rate in species of Agrostis L. J Ecol 55:111–118
Connell JH (1983) On the prevalence and the relative importance of the interspecific competition: evidence from field experiments: effect of direct interactions. Oikos 41:290–291
DeBano LF, Conrad CE (1978) The effect of fire on nutrients in a chaparral ecosystem. Ecology 59:489–497
Dell B, Jones S, Wilson SA (1987) Phosphorous nutrition of Jarrah (Eucalyptus marginata) seedlings. Plant Soil 97:369–379
Diego V, Rodà F (1992) Litterfall responses to increased availability of water, nitrogen and phosphorus in a holm oak forest. In: Teller A, Mathy P, Jeffers JNR (eds) Responses of forest ecosystems to environmental changes. Elsevier, London, pp 673–674
Escudero A, Del Arco JM, Garrido MV (1992) The efficiency of nitrogen retranslocation from leaf biomass in Quercus ilex. In: Romane F, Terradas J (eds) Ecosystems. Quercus ilex L. ecosystems: function, dynamics and management. Kluwer Academic, London, pp 69–76
Esteban-Parra MJ, Rodrigo FS, Castro-Díez Y (1998) Spatial and temporal patterns of precipitation in Spain for the period 1880–1992. Int J Climatol 18:1557–1574
European Environment Agency (1998) Europe’s environment: the second assessment. Elsevier, Oxford
Folk RS, Grossnicke SC (2000) Stock-type patterns of phosphorus uptake, retranslocation, net photosynthesis and morphological development in interior spruce seedlings. New For 19:27–49
García-Plé C, Vanrell P, Morey M (1995) Litter fall and decomposition in a Pinus halepensis forest on Mallorca. J Veg Sci 6:17–22
Harington CA, Wiermann CA (1989) Growth and foliar nutrient response to fertilization and precommercial thinning in coastal western red cedar stand. Can J For Res 20:764–773
Kitayama K, Majalap-Lee N, Aiba S (2000) Soil phosphorus fractionation and phosphorus-use efficiencies of tropical rainforest along altitudinal gradients of Mount Kinabalu, Borneo. Oecologia 123:342–349
Kloeppel DB, Gover TS, Vogel GJ, Reich BP (2000) Leaf-level resource use for evergreen and deciduous conifers along a resource availability gradient. Funct Ecol 14:281–292
Kruger FJ (1979) South African heathlands. In: Specht RL (ed) Ecosystems of the World. Heathlands and Related Shrublands. Descriptive studies. Elsevier, Amsterdam, pp 19–80
Lennon JM, Aber JD, Melillo JM (1985) Primary production and nitrogen allocation of field grown sugar maples in relation to nitrogen availability. Biogeochemistry 1:135–154
Leonardi S, Rapp M (1981) Rétour on sol d’elements minéraux par l’intermédiaire des litiéres dans un ecosystéme á Quercus ilex du M. Minardo Etna. Flora 171:329–327
Lüttge U, Ball E, Feteme M, Medina E (1991) Flexibility of CAM in Kalanchoe pinnata (Lam.) Pers. I. Response to irradiance and supply of nitrogen and water. J Plant Physiol 137:259–267
Mayor X, Rodà F (1992) Is primary production in holm oak forest nutrient limited? a correlation approach. Vegetatio 99–100:209–217
McMaster G, Jow W, Kummerow J (1982) Response of Adenostoma fasciculatum and Ceanothus greggii chaparral to nutrient additions. J Ecol 70:745–756
McNeill RC, Lea R, Ballard R, Allen HL (1988) Prediction fertiliser response of Loblolly pine using foliar and Needle-fall nutrients sampled in different seasons. For Sci 34:698–707
Miller MG, Miller JD (1976) Analysis of needle fall as a means as assessing nitrogen status in pine. Forestry 49:57–61
Mitchell AD, Smethurst P (2004) Surface soil changes in base cation concentrations in fertilised hardwood and softwood plantation in Australia. For Ecol Manage 191:253–265
Mugasha AG, Pluth DJ, Higginbotham KO, Takyi SK (1991) Foliar responses of black spruce to thinning and fertilisation on a drained shallow peat. Can J For Res 21:152–163
Nambiar EKS, Fife DN (1987) Growth and nutrient retranslocation in needles of radiata pine in relation to nitrogen supply. Ann Bot 60:147–156
Negi GSS, Singhi SP (1992) Leaf nitrogen dynamics with particular reference to retranslocation in evergreen and deciduous tree species of kumaun Himalaya. Can J For Res 23:349–357
Nuñez-Oliveira E, Martínez-Abaigar J, Escudero-García JC (1993) Litterfall and nutrient flux in Cistus ladanifer L. Shrubland in S.W. Spain. Acta Oecol 14:361–369
Oliveira G, Martins-Louçao MA, Carreira O, Catarino F (1996) Nutrient dynamics in crown tissues of cork-oak (Quercus suber L.). Trees 10:247–254
Ouimet R, Fortin JM (1992) Growth and foliar nutrient status of sugar maple: incidence of forest decline and reaction to fertilization. Can J For Res 22:699–706
Pardossi A, Malorgio F, Tognoni F, (1999) Salt tolerance and mineral relations for celery. J Plant Nutr 22:151–161
Peñuelas J, Filella I (2001) Herbaria century record of increasing eutrophication in Spanish terrestrial ecosystems. Global Change Biol 7:427–433
Peñuelas J, Filella I (2002) Metal pollution in Spanish terrestrial ecosystems during twentieth century. Chemosphere 46:501–505
Peñuelas J, Filella I, Comas P (2002) Changed plant and animal life cycles from 1952 to 2000 in the Mediterranean region. Global Change Biol 7:427–433
Piñol J, Terradas J, Lloret F (1998) Climate warming, wildfire hazard and wildfire occurrence in coastal eastern Spain. Clim Change 38:347–357
Pugnaire FI, FS Chapin III (1993) Controls over nutrient resorptionfrom leaves of evergreen Mediterranean species. Ecology, 74:124–129
Rapp M, Santa-Regina I, Rico M, Antonio-Gallego H (1999) Biomass nutrient content, litterfall and nutrient return to the soil in Mediterranean oak forest. For Ecol Manage 119:39–49
Rodà F, Retana J, Gracia CA, Bellot J (1999) Ecology of Mediterranean evergreen oak forest. Springer, Berlin Heidelberg New York
Rode MW (1993) Leak-nutrient accumulation and turn-over at three stages of succession from heathland to forest. J Veg Sci 4:263–268
Rosati A, Esparza G, DeJong TM, Pearcy RW (1999) Influence of canopy light environment and nitrogen availability on leaf photosynthetic characteristics and photosynthetic nitrogen-use-efficiency of field-grown nectarine trees. Tree Physiol 19:173–180
Sardans J (1997) Respostes de 4 espècies llenyoses Mediterrànies a diferent disponibilitat d’aigua I nutrients. PhD Thesis, University Autonomous of Barcelona, Bellaterra
Sardans J, Rodà F, Peñuelas J (2004) Phosphorus limitation and competitive capacities of Pinus halepensis and Quercus ilex subsp. rotundifolia on different soils. Plant Ecol 174:305–317
Seastedt TR, Briggs JM, Gibson DJ (1991) Controls of nitrogen limitation in tallgrass prairie. Oecologia 87:72–79
Sharma SC, Pande PK (1989) Patterns of litter nutrient concentration in some plantation ecosystems. For Ecol Manage 29:151–163
St John TV, Rundel PW (1976) The role of fire as a mineralising agent in a Sierran coniferous forest. Oecologia 25:35–45
Staff H, Berg B (1981) Plant litter input to soil. In: Clark FE, Rosswall T (eds) Terrestrial nitrogen cycles. Ecol Bull 33:147–162
Theodorou C, Bowen GD (1990) Effects of fertilizer on litterfall and N and P release from decomposition litter in a Pinus radiata plantation. For Ecol Manage 32:87–102
Thomas WA, Grigal DF (1976) Phosphorus conservation by evergreenness of mountain laurel. Oikos 27:19–26
Terradas J, Piñol J, Lloret F (1996) Importància dels aspectes socials i físics determinats del risc d’incendis forestals. Rev Catalunya 110:44–72
Vitousek PM (1982) Nutrient cycling and nutrient use efficiency. Am Nat 119:553–572
Vitousek PM, Aber JD, Howarth RW (1997) Human alteration of global nitrogen cycle: sources and consequences. Ecol Appl 7:737–750
Voght KA, Grier CC, Voght DJ (1986) Organic matter and nutrient dynamics of above-belowground detritus of world forest. Adv Ecol Res 15:139–157
Wang D, Bormann FH, Lugo AE, Bowden RD (1991) Comparison of nutrient-use efficiency and biomass production in five tropical tree taxa. For Ecol Manage 46:1–21
Wang W-Q, Wang M, Lin P (2003) Seasonal changes in element contents in mangrove element retranslocation during leaf senescence. Plant Soil 252:187–193
White RE (1972) Studies on mineral ion absorption by plants. I. The absorption and utilization of phosphates by Stylosanthes humilis, Phaseolus atropurpureus, and Desmodium intortum. Plant Soil 36:427–447
Witkowski ETF, Mitchell DT, Stock WD (1990) Response of Cape fynbos ecosystems to nutrient additions: shoot growth and nutrient contents of proteoid (Leucosperma parile) and the ericoid (Phylica cephalantha) evergreen shrub. Acta Oecol 11:311–326
Xu D, Dell B, Malajczuk N, Gong M (2002) Effects of P fertilisation on productivity and nutrient accumulation in a Eucalyptus grandis × E. urophylla plantation in southern China. For Ecol Manage 161:80–100
Acknowledgements
This research was supported by MCYT projects AMB 95-0247, REN2003-04871 CGL 2004-01402/BOS, and the European project ALARM (Contract 506675)
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Sardans, J., Peñuelas, J. & Rodà, F. Changes in nutrient use efficiency, status and retranslocation in young post-fire regeneration Pinus halepensis in response to sudden N and P input, irrigation and removal of competing vegetation. Trees 19, 233–250 (2005). https://doi.org/10.1007/s00468-004-0374-3
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DOI: https://doi.org/10.1007/s00468-004-0374-3