Responses of leaf photosynthesis, pigments and chlorophyll fluorescence within canopy position in a boreal grass (Phalaris arundinacea L.) to elevated temperature and CO2 under varying water regimes

The effects of elevated growth temperature (ambient + 3.5°C) and CO2 (700 μmol mol−1) on leaf photosynthesis, pigments and chlorophyll fluorescence of a boreal perennial grass (Phalaris arundinacea L.) under different water regimes (well watered to water shortage) were investigated. Layer-specific measurements were conducted on the top (younger leaf) and low (older leaf) canopy positions of the plants after anthesis. During the early development stages, elevated temperature enhanced the maximum rate of photosynthesis (Pmax) of the top layer leaves and the aboveground biomass, which resulted in earlier senescence and lower photosynthesis and biomass at the later periods. At the stage of plant maturity, the content of chlorophyll (Chl), leaf nitrogen (NL), and light response of effective photochemical efficiency (ΦPSII) and electron transport rate (ETR) was significantly lower under elevated temperature than ambient temperature in leaves at both layers. CO2 enrichment enhanced the photosynthesis but led to a decline of NL and Chl content, as well as lower fluorescence parameters of ΦPSII and ETR in leaves at both layers. In addition, the down-regulation by CO2 elevation was significant at the low canopy position. Regardless of climate treatment, the water shortage had a strongly negative effect on the photosynthesis, biomass growth, and fluorescence parameters, particularly in the leaves from the low canopy position. Elevated temperature exacerbated the impact of water shortage, while CO2 enrichment slightly alleviated the drought-induced adverse effects on Pmax. We suggest that the light response of ΦPSII and ETR, being more sensitive to leaf-age classes, reflect the photosynthetic responses to climatic treatments and drought stress better than the fluorescence parameters under dark adaptation.

[1]  J. Araus,et al.  Photosynthetic Gas Exchange Characteristics of Wheat Flag Leaf Blades and Sheaths during Grain Filling: The Case of a Spring Crop Grown under Mediterranean Climate Conditions. , 1987, Plant physiology.

[2]  U. Pérez-López,et al.  Elevated CO2 alleviates the impact of drought on barley improving water status by lowering stomatal conductance and delaying its effects on photosynthesis , 2007 .

[3]  M. Loik,et al.  Effects of extreme high temperature, drought and elevated CO2 on photosynthesis of the Mojave Desert evergreen shrub, Larrea tridentata , 2000, Plant Ecology.

[4]  K Maxwell,et al.  Chlorophyll fluorescence--a practical guide. , 2000, Journal of experimental botany.

[5]  Q. Lu,et al.  Photoinhibition and photoprotection in senescent leaves of field-grown wheat plants , 2003 .

[6]  G. Erice,et al.  Effect of elevated CO2, temperature and drought on photosynthesis of nodulated alfalfa during a cutting regrowth cycle , 2006 .

[7]  K. Korhonen,et al.  Adaptation of forest ecosystems, forests and forestry to climate change. FINADAPT Working Paper 4 , 2005 .

[8]  T. Tschaplinski,et al.  Plant water relations at elevated CO2 -- implications for water-limited environments. , 2002, Plant, cell & environment.

[9]  J. Briantais,et al.  The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence , 1989 .

[10]  O. H. Sayed Chlorophyll Fluorescence as a Tool in Cereal Crop Research , 2003, Photosynthetica.

[11]  Zita,et al.  Elevated CO 2 and temperature differentially affect photosynthesis and resource allocation in flag and penultimate leaves of , 2009 .

[12]  Osborne,et al.  Does leaf position within a canopy affect acclimation of photosynthesis to elevated CO2?. Analysis Of a wheat crop under free-air co2 enrichment , 1998, Plant physiology.

[13]  K. Satoh,et al.  Temperature Acclimation of Photosynthesis and Related Changes in Photosystem II Electron Transport in Winter Wheat1 , 2002, Plant Physiology.

[14]  B. Demmig‐Adams,et al.  Photoprotection and Other Responses of Plants to High Light Stress , 1992 .

[15]  S. Kellomäki,et al.  Controlled Environment Chambers for Investigating Tree Response to Elevated CO2 and Temperature Under Boreal Conditions , 2000, Photosynthetica.

[16]  T. Koike,et al.  Interaction of drought and elevated CO2 concentration on photosynthetic down-regulation and susceptibility to photoinhibition in Japanese white birch seedlings grown with limited N availability. , 2007, Tree physiology.

[17]  Jianhua Zhang,et al.  Inhibition of photosynthesis and energy dissipation induced by water and high light stresses in rice. , 2007, Journal of experimental botany.

[18]  J. Flexas,et al.  Is photosynthesis limited by decreased Rubisco activity and RuBP content under progressive water stress? , 2004, The New phytologist.

[19]  N. Wu,et al.  Effects of water stress and nitrogen supply on leaf gas exchange and fluorescence parameters of Sophora davidii seedlings , 2008, Photosynthetica.

[20]  Mark Stitt,et al.  The interaction between elevated carbon dioxide and nitrogen nutrition: the physiological and molecular background , 1999 .

[21]  Bryant,et al.  Acclimation of photosynthesis to elevated CO2 under low-nitrogen nutrition is affected by the capacity for assimilate utilization. Perennial ryegrass under free-Air CO2 enrichment , 1998, Plant physiology.

[22]  Bingru Huang,et al.  Diffusion limitations and metabolic factors associated with inhibition and recovery of photosynthesis from drought stress in a C perennial grass species. , 2010, Physiologia plantarum.

[23]  Guangsheng Zhou,et al.  Combined effects of water stress and high temperature on photosynthesis, nitrogen metabolism and lipid peroxidation of a perennial grass Leymus chinensis , 2006, Planta.

[24]  T. Rees,et al.  Higher Plant Cell Respiration , 1985, Encyclopedia of Plant Physiology.

[25]  O. Urban,et al.  Response of Photosynthetic Apparatus of Spring Barley (Hordeum vulgare L.) to Combined Effect of Elevated CO2 Concentration and Different Growth Irradiance , 2003, Photosynthetica.

[26]  J. Berry,et al.  Photosynthetic Response and Adaptation to Temperature in Higher Plants , 1980 .

[27]  H. Lambers Respiration in Intact Plants and Tissues: Its Regulation and Dependence on Environmental Factors, Metabolism and Invaded Organisms , 1985 .

[28]  L. Jauhiainen,et al.  Characterization of development and stem elongation of reed canary grass under northern conditions , 2003 .

[29]  R. Morcuende,et al.  Diurnal changes of Rubisco in response to elevated CO2, temperature and nitrogen in wheat grown under temperature gradient tunnels. , 2005 .

[30]  J. Flexas,et al.  Decreased Rubisco activity during water stress is not induced by decreased relative water content but related to conditions of low stomatal conductance and chloroplast CO2 concentration. , 2006, The New phytologist.

[31]  R. Morcuende,et al.  Gas exchange acclimation to elevated CO2 in upper-sunlit and lower-shaded canopy leaves in relation to nitrogen acquisition and partitioning in wheat grown in field chambers , 2007 .

[32]  M. Salvucci,et al.  Rubisco activase constrains the photosynthetic potential of leaves at high temperature and CO2. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[33]  R. Morcuende,et al.  Interactive effects of elevated CO2, temperature and nitrogen on photosynthesis of wheat grown under temperature gradient tunnels , 2005 .

[34]  P. J. Andralojc,et al.  Rubisco activity: effects of drought stress. , 2002, Annals of botany.

[35]  P. Martikainen,et al.  Effects of elevated CO2 and temperature on leaf characteristics, photosynthesis and carbon storage in aboveground biomass of a boreal bioenergy crop (Phalaris arundinacea L.) under varying water regimes , 2011 .

[36]  S. Long,et al.  Growth in elevated CO(2) can both increase and decrease photochemistry and photoinhibition of photosynthesis in a predictable manner. Dactylis glomerata grown in two levels of nitrogen nutrition. , 2001, Plant physiology.

[37]  H. Lichtenthaler CHLOROPHYLL AND CAROTENOIDS: PIGMENTS OF PHOTOSYNTHETIC BIOMEMBRANES , 1987 .

[38]  B. Drake,et al.  MORE EFFICIENT PLANTS: A Consequence of Rising Atmospheric CO2? , 1997, Annual review of plant physiology and plant molecular biology.