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New Phytologist Commentary these species and there are active breeding programmes around the world for these traits. Peach is particularly amenable for forward genetic studies because it has a small genome (approximately half the size of the P. trichocarpa genome) with little duplication history, is self-fertile, has a generation time as short as 2–4 yr and significant genomic resources are available (Shulaev et al., 2008). Recent work has demonstrated the utility of peach to map and sequence candidate genes for important winter-dormancy traits (Bielenberg et al., 2008; Fan et al., 2010). Apple, in turn, possesses a very robust transformation capability for reverse genetics (Shulaev et al., 2008). Research on several species will be needed to truly understand ecosystem-level phenological responses to climate change because induction of growth cessation, bud set and bud flush is regulated differently in different species. For example, in Malus and Pyrus spp. growth cessation and bud set appear to be regulated by low temperatures alone without the involvement of photoperiod (Heide & Prestrud, 2005). While trees dominate the discussion of perenniality, many herbaceous species also develop buds and enter winter dormancy, often from underground structures (Horvath et al., 2002). It is clear that parallel work on multiple plant systems will be important to incorporate the biological diversity of perennial species. The community of perennial biology researchers will need to continue to be adept at applying data and concepts gained from one system to another. Forum Horvath DP, Chao WS, Anderson JV. 2002. Molecular analysis of signals controlling dormancy and growth in underground adventitious buds of leafy spurge. Plant Physiology 128: 1439–1446. Lubbock J. 1899. On buds and stipules. London, UK: Kegan Paul, Trench, Trubner & Co. Ltd. Olsen JE. 2003. Molecular and physiological mechanisms of bud dormancy regulation. In: Tanino KK, ed. XXVI international horticultural congress – environmental stress. Toronto, Canada: ISHS, 437–453. Rohde A, Storme V, Jorge V, Gaudet M, Vitacolonna N, Fabbrini F, Ruttink T, Zaina G, Marron N, Dillen S et al. 2010. Bud set in poplar – genetic dissection of a complex trait in natural and hybrid populations. New Phytologist 189: 106–121. Shulaev V, Korban SS, Sosinski B, Abbott AG, Aldwinckle HS, Folta KM, Iezzoni A, Main D, Arus P, Dandekar AM et al. 2008. Multiple models for Rosaceae genomics. Plant Physiology 147: 985–1003. Tanino KK, Kalcsits L, Silim S, Kendall E, Gray GR. 2010. Temperaturedriven plasticity in growth cessation and dormancy development in deciduous woody plants: a working hypothesis suggesting how molecular and cellular function is affected by temperature during dormancy induction. Plant Molecular Biology 73: 49–65. Taylor G. 2002. Populus: Arabidopsis for forestry. Do we need a model tree? Annals of Botany 90: 681–689. Tuskan GA, DiFazio S, Jansson S, Bohlmann J, Grigoriev I, Hellsten U, Putnam N, Ralph S, Rombauts S, Salamov A et al. 2006. The genome of black cottonwood, Populus trichocarpa (Torr. & Gray). Science 313: 1596–1604. Velasco R, Zharkikh A, Troggio M, Cartwright DA, Cestaro A, Pruss D, Pindo M, FitzGerald LM, Vezzulli S, Reid J et al. 2007. A high quality draft consensus sequence of the genome of a heterozygous grapevine variety. PLoS ONE 2(12): e1326. doi:10.1371/journal.pone.0001326. Key words: bud, genome, perennial, photoperiod, seasonal, transcriptome, tree. Douglas G. Bielenberg Clemson University – Horticulture, 152 Poole Agricultural Center, Clemson, SC 29631-0319, USA (tel +1 864 656 4968; email [email protected]) References Battey NH. 2000. Aspects of seasonality. Journal of Experimental Botany 51: 1769–1780. Bielenberg DG, Wang Y, Li Z, Zhebentyayeva T, Fan S, Reighard GL, Scorza R, Abbott AG. 2008. Sequencing and annotation of the evergrowing locus in peach [Prunus persica (L.) Batsch] reveals a cluster of six MADS-box transcription factors as candidate genes for regulation of terminal bud formation. Tree Genetics and Genomes 4: 495–507. Fan S, Bielenberg DG, Zhebentyayeva TN, Reighard GL, Okie WR, Holland D, Abbott AG. 2010. Mapping quantitative trait loci associated with chilling requirement, heat requirement and bloom date in peach (Prunus persica). New Phytologist 185: 917–930. Heide OM, Prestrud AK. 2005. Low temperature, but not photoperiod, controls growth cessation and dormancy induction and release in apple and pear. Tree Physiology 25: 109–114. Horvath D. 2009. Common mechanisms regulate flowering and dormancy. Plant Science 177: 523–531. Horvath DP, Anderson JV, Jia Y, Chao WS. 2005. Cloning, characterization, and expression of growth regulator CYCLIN D3-2 in leafy spurge (Euphorbia esula). Weed Science 53: 431–437. 2011 The Authors New Phytologist 2011 New Phytologist Trust Solving the conundrum of plant species coexistence: water in space and time matters most Ecologists still wonder how so many competing plant species can coexist at the same site, defying the competitiveexclusion principle. All plants use and compete for the same basic resources (light, CO2, water, nutrients and space for growth); species with competitive advantage reduce resource availability for other species that will experience difficulties becoming established or remaining. However, if species sufficiently partition the abiotic and biotic environments, or if there are trade-offs in resource allocation (e.g. some species may allocate more resources to increase reproduction, whereas others might allocate more resources to survival or to growth), then different species can coexist by using different ranges and proportions of resources (Pacala & Tilman, 1994). The classical answer of this species coexistence conundrum states that stable coexistence between New Phytologist (2011) 189: 5–8 www.newphytologist.com 5 6 Forum Commentary competing species requires them to occupy different niches. But the niche concept, which was initially conceived by zoologists and emphasized the role of habitat and food in defining an animal’s niche (Chase & Leibold, 2002), does not offer an obvious explanation for coexistence among plants, because all plants use, and compete for, the same aforementioned resources and acquire them in similar ways. The question thus remains as to how competing plant species coexist apparently without the niche differences that classical theory predicts to be necessary. Apart from quantitative refinements (for instance, considering the differential resource consumption rate of species) and successional dynamics, two answers are possible: either the classical theory is wrong or incomplete and stabilizing mechanisms are unimportant (neutral models; Hubbell, 2001; de Aguiar et al., 2009), or there are niche differences between plants that have been overlooked (Silvertown, 2004). Plant ecologists keep trying to solve this question, most of them looking for the separation of niches and the quantification of the extent of the differences between two niches in order for corresponding species to coexist (Begon et al., 2006). In this issue of New Phytologist, Araya et al. (pp. 253–258) have elegantly shown separation of hydrological niches in two very different plant communities (in British wet meadows and in South African fynbos), quantified them and interestingly suggested the ecohydrological axis as potentially one of the most general drivers of niche differentiation for plants. ‘... the underlying mechanisms are ecophysiologically fundamental to plants and have the potential to govern niche segregation in many other communities.’ The ‘habitat’ niche of a plant species may be defined as a spatial and temporal function of the ranges of water, light, nutrient, temperature and competition with neighbours that the plant is able to live with. This definition is made within large gradients of availability for each resource – arid–humid (water), oligotrophic–eutrophic (nutrients), shade–sun (light) and cold–hot (temperature) – and also as a function of microsite heterogeneity, climatic variability and disturbance that further contribute to generate local diversity. However, altogether the mechanisms that stabilize communities through such niche segregation merit further explanation (Chesson, 2000; Adler et al., 2007). Many such mechanisms have been proposed, and more than one may function simultaneously in particular plant communities. A few years ago, Silvertown et al. (1999) showed that segregation on hydrological gradients occurs in European wet New Phytologist (2011) 189: 5–8 www.newphytologist.com New Phytologist meadows and that specialization of species into distinct niches is a result of a trade-off between tolerance of aeration stress and tolerance of drying stress. Araya et al. have now expanded this seminal work, testing this mechanism by quantifying the hydrological niches of floristically, functionally and phylogenetically distinct plants in fynbos communities in the Cape of South Africa. They have found this coinciding trade-off, supporting the existence of the same physiological constraints, and strengthening the generality of hydrological niche segregation. As pointed out by Araya et al., hydrological niche segregation occurs in a great variety of vegetation types across the entire spectrum of environments, from wet or mesic to arid. Araya et al.’s work connects such a single trade-off between aeration and water stress from a community (wet meadows), where aeration stress would be the limiting factor, to an ecologically and geographically distant one (South-African fynbos) where water stress is the rule. This result strongly suggests that the underlying mechanisms are ecophysiologically fundamental to plants and have the potential to govern niche segregation in many other communities. One probable mechanism is the competing demand of water conservation vs carbon acquisition along soil moisture gradients. Another mechanism is the need of nutrient acquisition along nutrient gradients that are correlated with soil moisture gradients. The first mechanism is a consequence of the fact that plants must regulate water loss through stomata while they acquire the CO2 required for photosynthesis and growth. Water use efficiency (WUE), the ratio of CO2 assimilated : stomatal conductance, should thus vary between species in a systematic manner along soil moisture gradients. Nutrient availability changes along soil moisture gradients, with a maximum in mesic soils and minima in waterlogged and very dry conditions (Araya, 2005). Plants must allocate resources to roots to compete successfully for nutrients, but to shoots to compete for light, and thus a nutrient gradient engenders a trade-off that forces plants to specialize. These fine-scale hydrological gradients are thus strongly linked to the ‘biogeochemical’ niche, defined as the species position in the multivariate space generated by their content, not only of macronutrients such as nitrogen (N), phosphorus (P) or potassium (K), but also of micronutrients such as molybdenum (Mo), magnesium (Mg) and calcium (Ca), and trace elements such as lead (Pb) and arsenic (As) (Peñuelas et al., 2008). Usually, there is a strong differentiation in the total and relative (stoichiometry) content of the different elements in coexisting plant species, and, there is, moreover, a differential species-specific plasticity in the response of this elemental composition to changes in environmental conditions (Peñuelas et al., 2008). Araya et al. define the hydrological niche segregation as partitioning of space on fine-scale soil-moisture gradients, and as partitioning of water as a resource through different acquisition strategies, such as different phenologies or root- 2011 The Authors New Phytologist 2011 New Phytologist Trust New Phytologist ing depths. By using the variable ‘sum of exceedance value’ relative to the threshold depths of each site for both aeration and water stress, they quantify the niche segregation and capture all three components of soil moisture variation in space, depth and time. Nevertheless, in order to capture more comprehensively this latter temporal component of niche partitioning, we propose that the variance in the intensity and seasonal distribution of both these aeration and water stress ‘exceedances’ should also be considered because such variances may play a significant additional or synergic niche segregation role. The ecological rationale for enhanced coexistence with increasing variances or fluctuations (‘fluctuation’ niche; Terradas et al., 2009) is based on the different growth response of species to water availability. If water availability fluctuates, the temporal advantage of one species becomes balanced by the advantage of the other species at another time, but if water availability remains constant, competitive exclusion is more likely to occur. A good example of the importance of the ‘fluctuation niche’ and of the presence of different syndromes is found in the Mediterranean environment (Fig. 1), which shows characteristic large seasonal and interannual rain fluctuations (Terradas et al., 2009). As a result, the depth of roots profoundly affects the variance of water availability, which in turn affects the variance of nutrient availability and the variances in the leaf water and nutrient status (Filella & Peñuelas, 2003). In fact, the main division in Mediterranean communities is established between species with deep roots, with more constant water and nutrient resources, and species with shallow roots, which use episodic rainwater and associated nutrient uptake. Plants develop several responses between the two extremes of this constant–episodic gradient. At one extreme there is a great, but slow, development of permanent vertical structure, both aboveground and belowground, to ensure minimum between-year and between-season fluctuation in availability Commentary Forum of resources. At the other extreme there is a high turnover of structural components, mostly leaves and roots, as a result of high growth rates in favourable periods, which is associated with the existence of short life cycles and small plants when water resources are persistently scarce or when disturbances preclude the development of continuous canopies by larger plants. Thus, there is a gradient from a conservative strategy, when fluctuations are scarce, to an opportunistic strategy, which withstands larger fluctuations with a more discontinuous activity. Thermodynamically, conservative species use the resources more efficiently with less energy dissipation, obtaining greater benefit at the end of succession (Margalef, 1997). However, disturbances allow different strategies to occur simultaneously and to configure complementarily the communities. There are other drivers of niche segregation linked to the temporal axis. Species could coexist even in temporally and spatially homogeneous environments, because the mechanisms of coexistence differ throughout the developing stages of the species’ life history (Nakashizuka, 2001). The socalled ‘life history’ basis for niche segregation considers the different developing stages of a species as well as the different species’ life span and size. Obviously, the interactions of the ‘habitat’ with the ‘fluctuation’ and the ‘life history’ components geometrically increase the number of possible niches enhancing segregation. Variation at the individual scale further explains why large numbers of intensely competing species coexist (Clark, 2010). In any case, as the authors comment, their results emphasize the well-known importance of soil moisture and hydrology for structuring plant communities through space and time, which therefore has implications for the conservation of plant communities that now face changing hydrological conditions caused by water extraction and climate change (IPCC, 2007). These results should thus be considered not only in niche ecological studies trying to disentangle the conundrum of plant species coexistence, but also in the risk assessment of climate and environmental change impacts on species richness. Of course, the main message of this interesting and elegant study of Araya et al. is to remind us once more of the fundamental role of water availability in space and time to shape life in Earth. Josep Peñuelas1*, Jaume Terradas2 and Francisco Lloret2 1 Fig. 1 Mediterranean shrubland in the Prades mountains (Catalonia, north-east Spain) with many competing plant species coexisting in the same site, thus defying the competitive-exclusion principle. 2011 The Authors New Phytologist 2011 New Phytologist Trust Global Ecology Unit CREAF-CEAB-CSIC, Edifici C, Universitat Autònoma de Barcelona, 08193 Bellaterra, Spain; 2 CREAF (Center for Ecological Research and Forestry Applications), Edifici C, Universitat Autònoma de Barcelona, 08193 Bellaterra, Spain (*Author for correspondence: tel +34935812199(1312); email [email protected]) New Phytologist (2011) 189: 5–8 www.newphytologist.com 7 8 Forum New Phytologist Commentary Acknowledgements The research conducted by the authors is supported by the Spanish Government projects CGL2006-04025 ⁄ BOS, CGC2010-17172 and Consolider Ingenio Montes (CSD2008-00040), by the European project NEU NITROEUROPE (GOCE017841), and by the Catalan Government project SGR 2009-458. The nexus of host and pathogen phenology: understanding the disease triangle with climate change References Adler PB, HilleRisLambers J, Levine JM. 2007. A niche for neutrality. Ecology Letters 10: 95–104. de Aguiar MAM, Baranger M, Baptestini EM, Kaufman L, Bar-Yam Y. 2009. Global patterns of speciation and diversity. Nature 460: 384–387. Araya YN. 2005. Influence of soil-water regime on nitrogen availability and plant competition in wet-meadows. PhD thesis, Open University, Milton Keynes, UK. Araya YN, Silvertown J, Gowing DJ, McConway KJ, Linder HP, Midgley G. 2010. A fundamental, eco-hydrological basis for niche segregation in plant communities. New Phytologist 189: 253–258. Begon M, Colin R, Townsend R, Harper JL. 2006. Ecology. From individuals to ecosystems. Oxford, UK: Blackwell Publishing. Chase JM, Leibold MA. 2002. Spatial scale dictates the productivitybiodiversity relationship. Nature 416: 427–430. Chesson P. 2000. Mechanisms of maintenance of species diversity. Annual Review of Ecology and Systematics 31: 343–366. Clark J. 2010. Individuals and the variation needed for high species diversity in forest trees. Science 327: 1129–1132. Filella I, Peñuelas J. 2003. Partitioning of water and nitrogen in co-occurring species of a mediterranean shrubland. Oecologia 137: 51–61. Hubbell SP. 2001. The unified neutral theory of biodiversity and biogeography. Princeton, NJ, USA: Princeton University Press. IPCC. 2007. Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL, eds. Climate change 2007: the physical science basis. Contribution of Working Group 1 to the fourth assessment report of the Intergovernmental Panel on climate change. Cambridge, UK & New York, NY, USA: Cambridge University Press. Margalef R. 1997. Our biosphere. D-21385 Oldendorf ⁄ Luhe, Germany: Ecology Institute. Nakashizuka T. 2001. Species coexistence in temperate, mixed deciduous forests. Trends in Ecology and Evolution 16: 205–210. Pacala SW, Tilman D. 1994. Limiting similarity in mechanistic and spatial models of plant competition in heterogeneous environments. The American Naturalist 143: 222–257. Peñuelas J, Sardans J, Ogaya R, Estiarte M. 2008. Nutrient stoichiometric relations and biogeochemical niche in coexisting plant species: effect of simulated climate change. Polish Journal of Ecology 56: 613–622. Silvertown J. 2004. Plant coexistence and the niche. Trends in Ecology and Evolution 19: 605–611. Silvertown J, Dodd ME, Gowing D, Mountford O. 1999. Hydrologically-defined niches reveal a basis for species-richness in plant communities. Nature 400: 61–63. Terradas J, Peñuelas J, Lloret F. 2009. The fluctuation niche in plants. International Journal of Ecology 2009: ID 959702, doi: 10.1155/2009/ 959702. Key words: diversity, fluctuation niche, hydrological niche, life history, niche, nutrients, species coexistence, sum of exceedance value. New Phytologist (2011) 189: 8–11 www.newphytologist.com We have observed a remarkable increase in large-scale, sudden onset of decline (unknown causes) and known disease (bacterial, fungal, viral) outbreaks in the last few decades, with more predicted globally (Ganley et al., 2009). Increases in temperature, changes in the timing and effectiveness of precipitation, the change in the frequency and intensity of other, catastrophic events (e.g. windthrows, tornadoes, bark beetle outbreaks) and invasions of both native and exotic pathogens have thrown unlikely combinations of host plants, plant pathogens and environmental variability together with unpredicted outcomes. A recent canker outbreak in Alnus tenuifolia in interior Alaska, associated with the hot, dry summer of 2004 (Ruess et al., 2009), has refocused attention on the role of temperature and drought in canker incidence (Schoeneweiss, 1975). In this issue of New Phytologist, Rohrs-Richey et al. (pp. 295–307) open a new line of research in host–pathogen relationships with clarity: an experimental test of the intersection of the phenology of host susceptibility (Alnus fruticosa), the life cycle of the pathogen (Valsa melanodiscus) and environmental variability (temperature, drought). ‘For the first time, Rohrs-Richey et al. quantified the reduction in transpiration directly attributable to a stem canker.’ Alnus is a circumpolar, dominant, deciduous broadleaf shrub in the boreal biome. It is the key genus responsible for nitrogen (N) fixation in floodplains of interior Alaska (Ruess et al., 2009). Alnus is an important food source for insect herbivores, microtines, rodents and ungulates. Warming at high latitudes, especially interior continental regions, has been twofold the global average (IPCC, 2007). Increased temperatures (both winter and summer) will favor an increase in deciduous woody species, but will probably increase plant drought stress (Chapin et al., 2010). 2011 The Author New Phytologist 2011 New Phytologist Trust