Gaseous NO2 effects on stomatal behavior, photosynthesis and respiration of hybrid poplar leaves

• Autorzy: Hu Y. , Bellaloui N. , Tigabu N. , Wang J. , Diao J. , Wang K. , Yang R. , Sun G.
• Języki publikacji: EN

Abstrakty

EN

In this study, we used poplar as a model plant and investigated the effects of gaseous nitrogen dioxide (NO2, 4 ll 1-1) on stomatal conductance, photosynthesis, dark- and photorespiration of Populus alba 9 Populus berolinensis hybrid leaves using the photosynthesis system and scanning electron microscope technique. The results showed that net photosynthetic rates were significantly reduced in leaves exposed to 4 ll 1-1 NO2 for 48 h as compared with leaves exposed to ambient carbon dioxide 380 ll 1-1 and ambient NO2\0.1 ll 1-1 (the control) and the leaves exposed for 14 h. The decline of net photosynthetic rate was caused mainly by NO2 treatment. Dark respiration rates were dependent on co-action of the two factors (leaf temperature and NO2 treatment time). Postillumination carbon dioxide burst in the exposed leaves occurred at 13–15 s after turning the light off, whereas this phenomenon was absent in the control leaves.

• Wydawca: -
• Czasopismo: Acta Physiologiae Plantarum
• Rocznik: 2015
• Tom: 37
• Numer: 02
• Opis fizyczny: Article 39 [8 p.], fig.,ref.

Twórcy

autor

Hu Y.

• College of Life Science, Northeast Forestry University, 26 Hexing Road, P.O.Box 123, Harbin 150040, China

autor

Bellaloui N.

• USDA-ARS, Crop Genetics Research Unit, Stoneville, USA

autor

Tigabu N.

• Southern Swedish Forest Research Centre, Swedish University of Agricultural Sciences, P.O.Box 49, SE 230 50, Alnarp, Sweeden

autor

Wang J.

• College of Landscape, Northeast Forestry University, Harbin 150040, China

autor

Diao J.

• College of Life Science, Northeast Forestry University, 26 Hexing Road, P.O.Box 123, Harbin 150040, China

autor

Wang K.

• College of Life Science, Northeast Forestry University, 26 Hexing Road, P.O.Box 123, Harbin 150040, China

autor

Yang R.

• College of Life Science, Northeast Forestry University, 26 Hexing Road, P.O.Box 123, Harbin 150040, China

autor

Sun G.

• College of Life Science, Northeast Forestry University, 26 Hexing Road, P.O.Box 123, Harbin 150040, China

Bibliografia

• Azcon-Bieto J, Osmond CB (1983) Relationship between photosynthesis and respiration: the effect of carbohydrate status on the rate of CO2 production by respiration in darkened and illuminated wheat leaves. Plant Physiol 71:574–581
• Breuninger C, Meixner FX, Kesselmeier J (2013) Field investigations of nitrogen dioxide (NO2) exchange between plants and the atmosphere. Atmos Chem Phys 13:773–790
• Carlson RW (1983) Interaction between SO2 and NO2 and their effects on photosynthetic properties of soybean Glycine max. Environ Pollut Ecol Biol 32:11–38
• Chaparro-Suarez IG, Thielmann A, Meixner FX, Kesselmeier J (2006) Re-investigation of the nitrogen dioxide (NO2) uptake by tree species. Geophys Res Abstr 8:706–716
• Chaparro-Suarez IG, Meixner FX, Kesselmeier J (2011) Nitrogen dioxide (NO2) uptake by vegetation controlled by atmospheric concentrations and plant stomatal aperture. Atmos Environ 45:5742–5750
• Decker JP (1955) A rapid, post-illumination deceleration of respiration in green leaves. Plant Physiol 30:82–84
• Dochinger LS, Jensen KF (1985) Effect of acid mist and air pollutants on yellow-poplar seedling height and leaf growth. Research Paper. NE-572. U.S. Department of Agriculture, Forest Service, Northeastern Forest Experiment Station, Broomall, 4 p
• Eastham AM, Ormrod DP (1986) Visible injury and growth responses of young cuttings of Populus Canadensis and P. nigra to nitrogen dioxide and sulphur dioxide. Can J Forest Res 16:1289–1292
• Eller ASD, McGuire KL, Sparks JP (2011) Responses of sugar maple and hemlock seedlings to elevated carbon dioxide under altered above- and belowground nitrogen sources. Tree Physiol 31:391–401
• Furukawa A (1991) Inhibition of photosynthesis of Populus euramericana and Helianthus annuus by SO2, NO2, O3. Ecol Res 6:79–86
• Gebler A, Rienks M, Rennenberg H (2000) NH3 and NO2 fluxes between beech trees and the atmosphere—correlation with climatic and physiological parameters. New Phytol 147:539–560
• Holopainen T, Anttonen S, Wulff A, Palomäki V, Kärentampi L (1992) Comparative evaluation of effects of gaseous pollutants, acidic deposition and mineral deficiencies: structural changes in the cells of forest plants. Agric Ecosyst Environ 42:365–398
• Hu YB, Sun GY (2010) Leaf nitrogen dioxide uptake coupling apoplastic chemistry, carbon/sulfur assimilation, and plant nitrogen status. Plant Cell Rep 29:1069–1077
• Hu YB, Bellaloui N, Sun GY, Tigabu M, Wang JH (2014a) Exogenous sodium sulfide improves morphological and physiological responses of a hybrid Populus species to nitrogen dioxide. J Plant Physiol 171:868–875
• Hu YB, Fernández V, Ma L (2014b) Nitrate transporters in leaves and their potential roles in foliar uptake of nitrogen dioxide. Front Plant Sci 5:360. doi:10.3389/fpls.2014.00360
• Jetter R, Riederer M, Lendzian KJ (1996) The effects of dry O3, SO2 and NO2 on reconstituted epicuticular wax tubules. New Phytol 133:207–216
• Kaše M, Čatský J (1983) Post-illumination burst of carbon dioxide in Phaseolus vulgaris L. as affected by leaf temperature. Biol Plant 25:225–230
• Kondo K, Yamada K, Nakagawa A, Takahashi M, Morikawa H, Sakamoto A (2008) Molecular characterization of atmospheric NO2-responsive germin-like proteins in azalea leaves. Biochem Biophys Res Commun 377:857–861
• Laisk A, Sumberg A (1994) Partitioning of the leaf CO2 exchange into components using CO2 exchange and fluorescence measurements. Plant Physiol 106:689–695
• Layne DR, Flore JA, Hanover JW, Mebrahtu T (1991) Leaf temperature effects on net photosynthesis, dark respiration, and photorespiration of seedlings of black locust families with contrasting growth rates. Can J For Res 21:161
• Lendzian KJ, Kerstiens G (1988) Interactions between plant cuticles and gaseous air pollutants. Asp Appl Biol 17:97–104
• Lin JX, Jach ME, Ceulemans R (2001) Stomatal density and needle anatomy of Scots pine (Pinus sylvestris) are affected by elevated CO2. New Phytol 150:665–674
• Mazarura U (2012) Effect of sequences of ozone and nitrogen dioxide on plant dry matter and stomatal diffusive resistance in radish. Afr Crop Sci J 20:371–384
• Morikawa H, Higaki A, Nohno M, Takahashi M, Kamada M, Nakata M, Toyohara G, Okamura Y, Matsui K, Kitani S, Fujita K, Irifune K, Goshima N (1998) More than a 600-fold variation in nitrogen dioxide assimilation among 217 plant taxa. Plant Cell Environ 21:180–190
• Okano K, Machida T, Totsuka T (1989) Differences in ability of NO2 absorption in various broad-leaved tree species. Environ Pollut 58:1–17
• Oleksyn J (1984) Effects of SO2, HF and NO2 on net photosynthetic and dark respiration rates of Scots pine needles of various ages. Photosynthetica 18:259–262
• Pallardy SG (2007) Physiology of Woody Plants, 3rd edn. Academic Press, San Diego 480
• Parys E, Romanowska E (2000) Relationship between postillumination burst of CO2 and enhancement of respiration in tall fescue leaves. Acta Physiol Plant 22:135–142
• Ramge P, Badeck FW, Plöchl M, Kohlmaier GH (1993) Apoplastic antioxidants as decisive elimination factors within the uptake process of nitrogen dioxide into leaf tissues. New Phytol 125:771–785
• Rantanen L, Palomakp V, Harrison AF, Lucas PW, Mansfield TA (1994) Interactions between combined exposure to SO2 and NO2 and nutrient status of trees: effects on nutrient content and uptake, growth, needle ultrastructure and pigments. New Phytol 128:689–701
• Rennenberg H, Gessler A (1999) Consequences of N deposition to forest ecosystems-recent results and future research needs. Water Air Soil Pollut 116:47–64
• Sabaratnam S, Gupta G, Mulchi C (1988) Nitrogen dioxide effects on photosynthesis in soybean. J Environ Qual 17:143–146
• Schiffgens-Gruber A, Lutz C (1992) Ultrastructure of mesophyll cell chloroplasts of spruce needles exposed to O3, SO2 and NO2 alone and in combination. Environ Exp Bot 32:243–254
• Schmutz P, Tarjan D, Günthardt-Goerg MS, Matyssek R, Bucher JB (1995) Nitrogen dioxide- a gaseous fertilizer of poplar trees. Phyton 35:219–232
• Sharkey TD (1988) Estimating the rate of photorespiration in leaves. Physiol Plant 73:147–152
• Siegwolf RTW, Matyssek R, Saurer M, Maurer S, Günthardt-Goerg MS, Schmutz P, Bucher JB (2001) Stable isotope analysis reveals differential effects of soil nitrogen and nitrogen dioxide on the water use efficiency in hybrid poplar leaves. New Phytol 149:233–246
• Silim SN, Ryan N, Kubien DS (2010) Temperature responses of photosynthesis and respiration in Populus balsamifera L.: acclimation versus adaptation. Photosynth Res 104:19–30
• Sparks JP (2009) Ecological ramifications of the direct foliar uptake of nitrogen. Oecologia 159:1–13
• Srivastava HS, Jolliffe PA, Runeckles VC (1974a) Inhibition of gas exchange in bean leaves by NO2. Can J Bot 53:466–474
• Srivastava HS, Jolliffe PA, Runeckles VC (1974b) The effects of environmental conditions on the inhibition of leaf gas exchange by NO2. Can J Bot 53:475–482
• Takagi M, Gyokusen K (2004) Light and atmospheric pollution affect photosynthesis of street trees in urban environments. Urban For Urban Green 2:167–171
• Takahashi M, Higaki A, Nohno M, Kamada M, Okamura U, Matsui K, Kitani S, Morikawa H (2005) Differential assimilation of nitrogen dioxide by 70 taxa of roadside trees at an urban pollution level. Chemosphere 61:633–639
• Tjoelker MG, Boratynski A, Bugala W (2007) Biology and Ecology of Norway Spruce. In: Werner A (ed) Effects of Pollutants on needle and wood anatomy. Springer, Netherlands, pp 325–327. ISBN 978-83-60247-62-4
• Vallano DM, Selmants PC, Zavaleta ES (2012) Simulated nitrogen deposition enhances the performance of an exotic grass relative to native serpentine grassland competitors. Plant Ecol 213:1015–1026
• Van Hove LWA, Bossen ME, Mensink MGJ, Van Kooten O (1992) Physiological effects of a long term exposure to low concentrations of ammonia, nitrogen dioxide, sulfur dioxide on douglas fir (Pseudotsuga menziesii). Physiol Plant 86:559–567
• Wellburn AR (1990) Why are atmospheric oxides of nitrogen usually phytotoxic and not alternative fertilizers? NewPhytol 115:395–429
• Yoneyama T, Sasakawa H (1979) Transformation of atmospheric NO2 absorbed in spinach leaves. Plant Cell Physiol 20:263–266

Identyfikatory

DOI

10.1007/s11738-014-1749-8