Abstract
The normal value of leaf longevity for a species reflects functional relationships at the foliar and whole-plant level, but longevity can be both prolonged and shortened by environmental conditions. From first principles, leaf longevity is expected to increase in environments where critical resources are scarce. This generalization is rooted in a cost–benefit analysis of leaf longevity arguing that the nature of leaves in resource-limited environments imposes a long payback period on the cost of their construction (Chabot and Hicks 1982; Kikuzawa 1991). In this view, selection pressure is expected to act to prolong leaf longevity in light-, water-, or nutrient-limited environments. This expectation is consistent with observations among species and plants in differing resource environments, but not within individual plants. The expectation applies to conditions of resource limitation, not stress conditions that near or exceed the limits to a species’ survival and reproduction. Stress events such as deep drought, unseasonal frost and freezing, lengthy flooding, salinity, air pollutants, and attack by herbivores or pathogens each impose qualitatively different challenges to leaf function (Kozlowski and Pallardy 2002), which we also address in this chapter.
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References
Ackerly D (2004) Functional strategies of chaparral shrubs in relation to seasonal water deficit and disturbance. Ecological Monographs 74:25–44
Balster NJ, Marshall JD (2000) Decreased needle longevity of fertilized Douglas-fir and grand fir in the northern Rockies. Tree Physiology 20:1191–1197
Bussotti F (2008) Functional leaf traits, plant communities and acclimation processes in relation to oxidative stress in trees: a critical overview. Global Change Biology 14:363–373
Casper BB, Forseth IN, Kempenich H, Seltzer S, Xavier K (2001) Drought prolongs leaf life span in the herbaceous desert perennial Cryptantha flava. Functional Ecology 15:740–747
Chabot BF, Hicks DJ (1982) The ecology of leaf life spans. Annual Review of Ecology and Systematics 13:229–259
Comstock J, Ehleringer J (1986) Canopy dynamics and carbon gain in response to soil water availability in Encelia frutescens gray, a drought-deciduous shrub. Oecologia 68:271–278
Cordell S, Goldstein G, Meinzer FC, Vitousek PM (2001) Regulation of leaf life-span and nutrient-use efficiency of Metrosideros polymorpha trees at two extremes of a long chronosequence in Hawaii. Oecologia 127:198–206
Field CB (1991) Ecological scaling of carbon gain to stress and resource availability. In: Mooney HA, Winner WE, Pell EJ (eds) Response of plants to multiple stresses. Academic, New York, pp 35–65
Field C, Mooney HA (1986) The photosynthesis–nitrogen relation in wild plants. In: Givnish TJ (ed) On the economy of plant form and function. Cambridge University Press, Cambridge, pp 25–56
Gill AM, Tomlinson PB (1971) Studies on the growth of red mangrove (Rhizophora mangle L.) 3. Phenology of the shoot. Biotropica 3:109–124
Herbert DA, Fownes JH (1999) Forest productivity and efficiency of resource use across a chronosequence of tropical montane soils. Ecosystems 2:242–254
Imai N, Takyu M, Nakamura Y (2009) Growth, crown architecture and leaf dynamics of saplings of five mangrove tree species in Ranong, Thailand. Marine Ecology Progress Series 377:139–148
Jonasson S, Medrano H, Flexas J (1997) Variation in leaf longevity of Pistacia lentiscus and its relationship to sex and drought stress inferred from leaf ∂13C. Functional Ecology 11:282–289
Kai K, Horiuchi T, Nomoto N (1991) Seasonal behavior of leaves of the semideciduous shrub Ligustrum obtusifolium. Japanese Journal of Ecology 41:73–82
Kayama S, Sasa K, Koike T (2002) Needle life span, photosynthetic rate and nutrient concentration of Picea glehnii, P. jezoensis and P. abies planted on serpentine soil in northern Japan. Tree Physiology 22:707–716
Kikuzawa K (1978) Emergence, defoliation and longevity of alder (Alnus hirsuta Turcz.) leaves in a deciduous hardwood forest stand. Japanese Journal of Ecology 28:299–306
Kikuzawa K (1982) Leaf survival and evolution in Betulaceae. Annals of Botany 50:345–353
Kikuzawa K (1983) Leaf survival of woody plants in deciduous broad-leaved forests. 1. Tall trees. Canadian Journal of Botany 61:2133–2139
Kikuzawa K (1984) Leaf survival of woody plants in deciduous broad-leaved forests. 2. Small trees and shrubs. Canadian Journal of Botany 62:2551–2556
Kikuzawa K (1988) Leaf survival of tree species in deciduous broad-leaved forests. Plant Species Biology 3:67–76
Kikuzawa K (1989) Ecology and evolution of phenological pattern, leaf longevity and leaf habit. Evolutionary Trends in Plants 3:105–110
Kikuzawa K (1991) A cost-benefit analysis of leaf habit and leaf longevity of trees and their geographical pattern. American Naturalist 138:1250–1263
Kikuzawa K (1995a) The basis for variation in leaf longevity of plants. Vegetatio 121:89–100
Kikuzawa K (1995b) Leaf phenology as an optimum strategy for carbon gain in plants. Canadian Journal of Botany 73:158–163
Kikuzawa K, Ackerly D (1999) Significance of leaf longevity in plants. Plant Species Biology 14:39–46
Koike T (1988) Leaf structure and photosynthetic performance as related to the forest succession of deciduous broad-leaved trees. Plant Species Biology 3:778–799
Kozlowski TT, Pallardy SG (2002) Acclimation and adaptive responses of woody plants to environmental stresses. Botanical Review 68:270–334
Lajtha K, Whitford WG (1989) The effect of water and nitrogen amendments on photosynthesis, leaf demography, and resource-use efficiency in Larrea tridentata, a desert evergreen shrub. Oecologia 80:341–348
Lei TT, Koike T (1998) Some observations of phenology and ecophysiology of Daphne kamtscatica Maxi var. jezoensis (Maxim.) Ohwi, a shade deciduous shrub, in the forest of northern Japan. Journal of Plant Research 111:207–212
Leuzinger S, Zotz G, Asshoff R, Körner C (2005) Responses of deciduous forest trees to severe drought in Central Europe. Tree Physiology 25:641–650
Lovelock CE, Kursar TA, Skillman JB, Winter K (1998) Photoinhibition in tropical forest understorey species with short- and long-lived leaves. Functional Ecology 12:553–560
Mommer L, Lenssen JPM, Huber H, Visser EJW, de Kroon H (2006) Ecophysiological determinants of plant performance under flooding: a comparative study of seven plant families. Journal of Ecology 94:1117–1129
Newcombe G, Chastagner GA (1993) A leaf rust epidemic of hybrid poplar along the lower Columbia River caused by Melampsora medusae. Plant Disease 77:528–531
Nilsen ET (1986) Quantitative phenology and leaf survivorship of Rhododendron maximum in contrasting irradiance environments of the Southern Appalachian Mountains. American Journal of Botany 73:822–831
Nunez-Farfan J, Fornoni J, Valverde PL (2007) The evolution of resistance and tolerance to herbivores. Annual Review of Ecology, Evolution and Systematics 38:541–566
Osada N, Takeda H, Kitajima K, Pearcy RW (2003) Functional correlates of leaf demographic response to gap release in saplings of a shade-tolerant tree, Elateriospermum tapos. Oecologia 137:181–187
Parolin P (2009) Submerged in darkness: adaptations to prolonged submergence by woody species of the Amazonian floodplains. Annals of Botany 103:359–376
Poorter L, Bongers F (2006) Leaf traits are good predictors of plant performance across 53 rain forest species. Ecology 87:1733–1743
Reich PB, Uhl C, Walters MB, Ellsworth DS (1991) Leaf lifespan as a determinant of leaf structure and function among 23 tree species in Amazonian forest communities. Oecologia 86:16–24
Reich PB, Walters MB, Ellsworth DS (1992) Leaf life-span in relation to leaf, plant and stand characteristics among diverse ecosystems. Ecological Monographs 62:365–392
Reich PB, Walters MB, Ellsworth DS, Uhl C (1994) Photosynthesis–nitrogen relations in Amazonian tree species. I. Patterns among species and communities. Oecologia 97:62–72
Reich PB, Uhl C, Walters MB, Prugh L, Ellsworth D (2004) Leaf demography and phenology in Amazonian rain forest: a census of 40 000 leaves of 23 tree species. Ecological Monographs 74:3–23
Sandquist DR, Ehleringer JR (1998) Intraspecific variation of dryout adaptation in brittlebush: leaf pubescence and timing of leaf loss vary with rainfall. Oecologia 113:162–169
Shaver GR (1981) Mineral nutrition and leaf longevity in an evergreen shrub, Ledum palustre ssp. decumbens. Oecologia 49:362–365
Sterck FJ (1999) Crown development in tropical rain forest trees in gaps and understorey. Plant Ecology 143:89–98
Suarez N (2003) Leaf longevity, construction, and maintenance costs of three mangrove species under field conditions. Photosynthetica 41:373–381
Suarez N, Medina E (2005) Salinity effect on plant growth and leaf demography of the mangrove, Avicennia germinans L. Trees – Structure and Function 19:721–727
Sunose T, Yukawa J (1979) Interrelationship between the leaf longevity of the evergreen spindle tree, Euonymus japonicus Thunb. and the Euonymus gall midge, Masakimyia pustulae in different environments. Japanese Journal of Ecology 29:29–34
Terazawa K, Kikuzawa K (1994) Effects of flooding on leaf dynamics and other seedling responses in flood-tolerant Alnus japonica and flood-intolerant Betula platyphylla var. japonica. Tree Physiology 14:251–261
Tobin MF, Lopez OR, Kursar TA (1999) Responses of tropical understory plants to a severe drought: tolerance and avoidance of water stress. Biotropica 31:570–578
Tomlinson PB (1986) The botany of mangroves. Cambridge University Press, Cambridge
Tsuchiya T (1989) Growth and biomass turnover of Hydrocharis dubia L. cultured under different nutrient conditions. Ecological Research 4:157–166
Tsuchiya T, Iwakuma T (1993) Growth and leaf life-span of a floating-leaved plant, Trapa natans L., as influenced by nitrogen flux. Aquatic Botany 46:317–324
Williams AG, Whitham TG (1986) Premature leaf abscission: an induced plant defense against gall aphids. Ecology 67:1619–1627
Wright IJ, Reich PB, Westoby M, Ackerly DD, Baruch Z, Bongers F, Cavender-Bares J, Chapin FS, Cornelissen JHC, Diemer M, Flexas J, Garnier E, Groom PK, Gulias J, Hikosaka K, Lamont BB, Lee T, Lee W, Lusk C, Midgley JJ, Navas M-L, Niinemets Ü, Oleksyn J, Osada N, Poorter H, Poot P, Prior L, Pyankov VI, Roumet C, Thomas SC, Tjoelker MG, Veneklaas EJ, Villar R (2004) The world-wide leaf economics spectrum. Nature 428:821–827
Yukawa J, Tsuda K (1986) Leaf longevity of Quercus glauca Thunb., with reference to the influence of gall formation by Contarinia sp. (Diptera: Cecidomyiidae) on the early mortality of fresh leaves. Memoirs of the Faculty of Agriculture, Kagoshima University 22:73–77
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Kikuzawa, K., Lechowicz, M.J. (2011). Exogenous Influences on Leaf Longevity. In: Ecology of Leaf Longevity. Ecological Research Monographs. Springer, Tokyo. https://doi.org/10.1007/978-4-431-53918-6_8
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DOI: https://doi.org/10.1007/978-4-431-53918-6_8
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