A interação entre os tratamentos de alta pressão de CO2 e salinidade se mostrou
complexa, refletindo num inicio do processo de aclimatação, pela menor fotossíntese e alteração no metabolismo oxidativo.
REFERÊNCIAS
AINSWORTH, E.A.; ROGERS, A. The response of photosynthesis and stomacal conductance to rising (CO2): mechanisms and environmental interactions. Plant, Cell & Environment v. 30, p. 258-270, 2007.
ARANJUELO, I.; ERICE, G.; NOGUÉS, S; MORALES , F.; IRIGOYEN, J. J.; SÁNCHEZ- DIAZ, M. The mechanism involted in the photoprotection of PSII at elevates CO2 in
nodulated alfafa plants. Envirom. and Experimental Botany, 64:295-306, 2008.
ARAYA, T.; NOGUCHI, K. & TERASHIMA, I. Effects of carbohydrate accumulation on photosynthesis differ between sink and source leaves of Phaseolus vulgaris L. Plant
and Cell Physiology, v..47, p. 644-652, 2006.
ASADA, K. The water-water cycle in chloroplasts: scavenging of active oxygen and dissipation of excess photons. Annual Review of Plant Physiology and Plant Molecular
Biology. v. 50, p. 601-639, 1999.
ASHRAF, M. Some important physiological selection criteria for salt tolerance in plants.
Flora, 199: 361-376, 2004.
ATHANASIOU, K.; DYSON, B.C..; WEBSTER, R. E.; JOHNSON, N. Dynamic Acclimation of Photosynthesis Increases Plant Fitness in Changing Environments. Plant
Physiology_, v. 152, pp. 366–373, 2012.
BADGER, M.R.; LORIMER, G.H. Evidence for the existence of
discrete activator and substrate sites for CO2 on ribulose-1,5-bisphosphate carboxylase. Journal Biol Chem v. 254, p. 5599-5601, 1979.
BAKER, N.R. Chlorophyll Fluorescence: a probe of photosynthesis in vivo. Annual
Review of Plant Biology, v.59, p. 89-113, 2008.
BAKER, A.L.; TOLBERT, N.E. Methods in Enzymology IX, 339-340, 1966
BAKER, N., ROSENQVIST, E. Applications of chlorophyll fluorescence can improve crop production strategies: an examination of future possibilities. Journal of Experimental
Botany, v. 55, p. 1607-1621, 2004.
BAETHGEN W.E.; ALLEY M.M. A manual colorimetric procedure for measuring
ammonium nitrogen in soil and plant. Comm Soil Sci Plant Anal, v. 20 p. 961–969, 1989. BALL, M.C.; MUNNS, R. Plant responses to salinity under elevated atmospheric
concentrations of CO2. Australian Journal Botany, v. 40, p. 515- 525, 1992.
BATES, L.S.; WALDREN, R.P.; TEARE, I.D. Rapid determination of free proline for water stress studies. Plant and Soil,v.39, n.1, p.205-209, 1973.
BEAUCHAMP, C.; FRIDOVICH, I. Superoxide dismutase: improved assays and an assay applicable to acrylamide gels. Analytical Biochemistry. V, 44(1):276-287, 1971.
BECKMANN, K.; DZUIBANY , C.; BIEHLER, K.; FOCK, H.; HELL, R.; MIGE, BECKER, T.W. Photosynthesis and ¯ uorescence quenching, and the mRNA levels of plastidic glutamine synthetase or of mitochondrial serine hydroxymethyltransferase (SHMT) in the leaves of the wild-type and of the SHMT.de®cient stm mutant of Arabidopsis thaliana in relation to the rate of photorespiration. Planta v. 202, p. 379-386.
BJÖRKMAN, O.; DEMMIG-ADAMS, B. Photon yield of O2 evolution and chlorophyll
fluorescence characteristics at 77 K among vascular plants of diverse origins. Planta, v.170, p.489-504, 1987.
BOLHÀR-NORDENKAMPF, H.R., LONG, S.P.; BAKER, N.R.; OQUIST, G.; SCHREIBERS, U; LECHNER, E.G. Functional Ecology, 3:497. 1989.
BRADFORD, M.M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analitical
Biochememistry, v.72, p. 248-254, 1976.
BRAY, E.A.; BAILEY-SERRES, J.; WERETILNYK, E. Responses to abiotic stress. In: BUCHANAN, B., GRUISSEM, W., JONES, R. Biochemistry & Molecular Biology of
Plants. 3◦ Impressão. American Society of Plant Physiologists, Rockville, Maryland, USA.
Cap.22, p.1167-1168, 2000.
BRENNAN, T.; FRENKEL, C. Involvement of Hydrogen Peroxide in the Regulation of Senescence in Pear, Plant Physiology, v. 59, p. 411-416. 1977.
CENTRITO, M., MAGNANI, F., LEE, H.S.J., JARVIS, P.J. Interactive effects of elevated [CO2] and drought on cherry (Prunus avium) seedlings. II. Photosynthetic capacity and water
relations. New Phytol. v. 141, p. 141–153, 1999.
CHENG, S.H.; MOORE, B.D.; SEEMANN, J.R. Effects of short- and long-term elevated CO2 on the expression of Ribulose-1,5-bisphosphate carboxylase/oxygenase genes and
carbohydrate accumulation in leaves of Arabidopsis thaliana. Plant Physiology. v. 116, p. 715–723, 1998.
CLOSE, D.C.; BLADLE, C.L. The ecophysiology of foliar anthociyanin. The botanical
Review, v. 69, p. 149-161, 2003.
CUSHMAN, J.C.; BOHNERT, H.J. Molecular genetics of crassulaceae acid metabolism.
Plant Physiology. v. 113, p. 667-676, 1997.
DAEPP, M., SUTER, D., ALMEIDA, J.P.F., ISOPP, H., HARTWIG, U.A., FREHNER, M., BLUM, H., NOSBERGER, J. AND LUSCHER, A. Yield response of Lolium perenne swards to free air CO2 enrichment increased over 6 years in a high N input system on fertile
DEMIRAL, T., TÜRKAN, I. Comparative lipid peroxidation, antioxidant defense systems and proline content in roots of two rice cultivars differing in salt tolerance. Environmental
and Experimental Botany, v. 53, p. 247–257, 2005.
DIETZ, K,J.; SCHREIBER. U.; HEBER, U. The relationship between the redox state of QA and photosynthesis in leaves at various carbon dioxide, oxygen and light regimes. Planta166, 219–226, 1985.
DRAKE, B.G.; AZCON-BIETO, J., BERRY, J.; BUNCE, J.; DIJKSTRA, P. et al. Does elevated atmospheric CO2 concentration inhibit mitochondrial respiration in green plants? Plant, Cell & Environment 22 :649-57, 1997.
DUBOIS, M.; GILLES, K.A.; HAMILTON, J.K., P.A., SMITH, F. Colorimetric method for determination of sugars and related substances. Analytical Chemistry, v. 28, p. 350-356, 1956.
ELLIOTT, W.H. Isolation of glutamine synthetase and glutamotransferase from green peas.
Journal of Biological Chemistry, v. 201, p. 661-672, 1953.
EVANS, J.R.; KALDENHOFF, R.; GENTY.B.; TERASHIMA, I.. Resistances along the CO2
diffusion pathway inside leaves. Journal Experimental Botany, v. 60, n. 8, p. 2235-3348, 2009.
FERREIRA-SILVA S.L., SILVA, E.N., CARVALHO, F.E.L., LIMA, C.S., ALVES, F.A.L., SILVEIRA, J.A.G. Physiological alterations modulated by rootstock and scion combination in cashew under salinity. Scientia Horticulturae. v.127, p. 39–45, 2010.
FERREIRA-SILVA, S.L.; SILVA, E.N.; CARVALHO, F.E.L.; DE LIMA, C.S. ; ALVES, F.A.L. ; SILVEIRA, J.A.G. Physiological alterations modulated by rootstock and scion combination in cashew under salinity. Scientia Horticulturae v. 127, p. 39-45, 2010. FERREIRA- SILVA, S. L. Mecanismos de proteção oxidativa contra estresses isolados e combinados de seca, salinidade e Temperatura elevada em cajueiro, 2008, Ceará, 2008, 175p.
Tese (Doutorado em Bioquímica), Universidade Federal do Ceará, 2008.
FIDALGO, F., SANTOS, A., SANTOS, I.; SALEMA. R. Effects of long-term salt stress on antioxidant defence systems, leaf water relations and chloroplast ultra structure of potato plants. Ann. Appl. Biol., v. 145, p. 185-192. 2004.
FOYER, C.H.; HARBINSON, J.C. Oxygen metabolism and the regulation of photosynthetic electron transport. In: Foyer, C.H., Mullineaux, P.M. (Eds.), Causes of Photooxidative
Stress and Amelioration of Defence Systems in Plant. CRC, Boca Raton,,pp. 1–42, 1994.
FOYER , C.H.; NOCTOR, G. REDOX. Homeostasis and antioxidant signaling: a metabolic interface between stress perception and physiological responses. Plant Cell v.17, p. 1866– 1875, 2005.
FOYER, C. H.; BLOOM, A. J.; QUEVAL, G.; NOCTOR, GRAHAM. Photorespiratory Metabolism:Genes, Mutants, Energetics, and Redox Signaling. Annu. Rev. Plant Biol. v. 60, p. 455–84, 2009.
GEISSLER, N.; HUSSIN, S.; KOYRO, H.W. Interactive effects of NaCl salinity and elevated atmospheric CO2 concentration on growth, photosynthesis, water relations and chemical
composition of the potential cash crop halophyte Aster tripolium L. Environmental and
Experimental Botany, v. 65, p. 220- 231, 2009.
GEISSLER, N.; HUSSIN S.; KOYRO, H.W. Elevated atmospheric CO2 concentration
enchances salinity tolerance in Aster tripolium L. Planta, v. 231, p. 583- 594, 2010. GIANOPOLITICS, C.N.; S.K. RIES. Superoxide dismutase occurrence in higher plants.
Plant Physiol., 59 : 309-314, 1977.
GILMORE, A.M. Mechanistic aspects of xanthopyll cycle-dependent photoprotection in higher plant chloroplasts and leaves. Physiol. Plantarum v. 99, p. 197–209, 1997.
GRUB, A.; MACHLER, F. Photosynthesis and light activation of Rubisco in the presence of starch. J. Experimental Botany. v. 41, p. 1293-1301, 1990.
HERNANDEZ J.A.; JIMÉNEZ, A.; MULLINEAUX, P.; SEVILLA, F. Tolerance of pea (Pisun sativum L.) to long- term salt stress is associated with induction of antioxidant defenses. Plant Cell Enviroment. V. 23. V. 853-862, 2000.
HIKOSAKA, K.; ONODA, Y.; KINUGASA, K.; ANTEN, N.P.R.; NAGASHIMA, H.; HIROSE, T. Plant responses to elevated CO2 concentration at different scales: leaf, whole
plant, canopy, and population. Ecological Research, v.20, p. 243-253, 2005. HALLIWELL, B., GUTTERIDGE, J.C. Free Radicals in Biology and Medicine. 3.ed.Oxford, New York, 1989.
HAUSLER, R.E., BAILEY, K.J., LEA, P.J., LEEGOOD, R.C. Control of photosynthesis in barley mutants with reduced activities of glutamine synthetase and glutamate
synthase. Planta, v.200, p.388-396, 1996.
HEATH R.L.; PACKER, L.Photoperoxidation in isolated chloroplasts. I. Kinetics and stoichiometry of fatty acid peroxidation. Archives in Biochemistry and Biophysics, v. 125, p.189–198, 1968.
HERRIDGE, D. F. Effects of nitrate and plant development on the abundance of nitrogenous solutes in root- bluding and vacuum- extracted exudates of soybean. Crop Science, v. 25, p. 173- 179, 1984.
HERNÁNDEZ J.A.; JIMÉNEZ A.; MULLINEAUX, P.; SEVILLA F. Tolerance of pea (Pisun sativun) to long- term salt stress is associated with induction of antioxidant defenses.
Plant Cell Enviroment, v. 23, p. 853- 863, 2000.
HIREL B, GADAL P. Glutamine synthetase in rice: A comparative study of the enzymes from roots and leaves. Plant Physiol v. 66, p. 619–623, 1980.
HOSHIDA, H.; TANAKA, Y.; HIBINO, Y.; HAYASHI, Y.; TANAKA, A.; TAKABE, T.; TAKABE, T. Enhanced tolerance to salt stress in transgenic rice that overexpresses
chloroplast glutamine synthetase. Plant Molecular Biology v. 43, p. 103–111, 2000. IPCC - Climate change 2007 – The physical science basis. In: SOLOMON S.; QIN, D; MANNING, M; CHEN, Z.; MARQUIS, M.; AVERYT, K.B.; TIGNOR, M.; MILLER, H.L. (eds) Contribution of Working Group I to the Fourth Assessment Report of the
Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge and New York, p. 21–90, 2007, disponivel em
http://www.ipcc.ch/publications_and_data/ar4/wg1/en/contents.html, acesso 30/05/2012. IZUMI, M., TSUNODA, H., SUZUKI, Y., MAKINO, A., ISHIDA, H. RBCS1A and RBCS3B, two major members within the Arabidopsis RBCS multigene family, function to yield sufficient Rubisco content for leaf photosynthetic capacity. Journal of Experimental
Botany, v. 63, n°. 5, pp. 2159–2170, 2012.
JALEEL, C. A.; MANIVANNAN, P.; KISHOREKUMAR, A.; SANKAR, B. GOPI, R.; SOMASUNDARAM, R.; PANEERSELVAM, R. Alterations in osmoregulations, antioxidant enzymes and indole alkaloid levels in Catharanthus roseus exposed to water defict. Colloids
and Surfaces B: Biointerfaces, v. 59, n. 2, p. 150-157, 2007.
JAMIL, M. et al. Salinity reduced growth PS2 photochemistry and chlorophyll content in radish. Scientia Agricola. v. 64, n. 2, p. 111-118, 2007.
KOSHIBA, T. Cytosolic ascorbato peroxidase in seedlings and leaves of maize (Zea mays).
Plant Cell Physiology, v.34, p. 713-721. 1993.
KOCH, K.E. Carbohydrate-modulated gene expression in plants. Annu Rev. Plant Physiolo.
Plant Mol. Biol. v. 47, p. 509–540, 1996.
KRAPP A, QUICK WP, STITT M. Ribulose-1,5-bisphosphate carboxylase-oxygenase, other photosynthetic enzymes and chlorophyll decrease when glucose is supplied to mature spinach leaves via the transpiration stream. Planta, v. 186, p.58–69, 1991.
KRAPP A, HOFMANN B, SHAFER C, STITT M. Regulation of the expression of rbcS and other photosynthetic genes by carbohydrates: a mechanism for the ‘sink’ regulation of photosynthesis. The Plant Journal, v.3, p.817–828, 1993
LARIOS, B.; AGUÉRA, E.; CABELLO, P.; MALDONADO, J.M.; HABAL, L. The rate of CO2 assimilation controls the expression and activity of glutamine synthetase through sugar
formation in sunflower (Helianthus annuus L.) leaves Journal of Experimental Botany, Vol. 55, N. 394, pp. 69-75, 2004.
LEAKEY A.D.B., BERNACCHI C.J., ORT D.R., LONG S.P. Long-term growth of soybean at elevated [CO2] does not cause acclimation of stomatal conductance under fully open air
conditions. Plant, Cell & Environment, v. 29, p.1794–1800, 2006.
LEEGOOD, R.C.; LEA, P.J.; ADCOCK, M.D,; HAUSLER, R.E. The regulation and control of photorespiration. Journal Experimental Botany; v. 46, p. 1397-414, 1995.
LEES, D.H., FRANCIS, F J. Standardization of pigment analyses in cranberries.
Horticulturae Science, v.7, n.1, p.83-84, 1972.
LICHTENTHALER, H.K. Chlorophyll and carotenoids: pigments of photosynthetic
biomembranes. In: COLOWICK, S.P.; KAPLAN, N.O. (Eds.) Methods in Enzymology , v. 148 p.350-382, 1987.
MACNEVIN, W. M.; URONE, P. F.Separation of Hydrogen Peroxide from Organic
Hydroperoxides Application to Polarographic Analysis of Mixtures. Analytical chemistry, v. 35, p. 1760-1761, 1953.
MAATHUIS, F. J. M.; AMTMANN, A. K+Nutrition and Na+toxicity: the basis of cellular K+/Na+ratios. Annals of Botany, v.84, p.123–133, 1999.
MASSACCI, A, NABIEV, S M, PIETROSANTI, L, NEMATOV, S. K., CHERNIKOVA, T. N., THOR, K., LEIPNER, J. Response of the photosynthetic apparatus of cotton
(Gossypium hirsutum) to the onset of drought stress under field conditions studied by gas- exchange analysis and chlorophyll fluorescence imaging. Plant Physiology and
Biochemistry v. 46, p.189-195, 2008
MATROS, A.; AMME, S.; KETTIG, B.; BUCK-SORLIN, G.H.; SONNEWALD U, M. H-P. Growth at elevated CO2 concentrations leads to modified profiles of secondary metabolites in
tobacco cv. Samsun N and to increased resistance against infection with potato virus Y.
Plant, Cell & Environment, v. 29: p.126–137, 2006.
MAXWELL, K. & JOHNSON, G.N. Chlorophyll fluorescence: a practical guide. Journal of
Experimental Botany, v. 51: p. 659-668, 2000.
MENEGUZZO, S.; NAVARI-IZZO, F.; IZZO, R. Antioxidative responses of shoots and roots of wheat to increasing NaCl concentrations. Journal of Plant Physiology v. 155, p. 274-280, 1999.
MIGGE, A.; CARRAYOL, E.; KUNZ, C.; HIREL, B.; FOCK, H.; BECKER, T. The
expression of tobacco genes encoding plastidic glutamine synthetase or ferredoxin-dependent glutamate synthase does not depend on the rate of nitrate reduction, and is unaffected by suppression of photorespiration. Journal of Experimental Botany v. 48, p. 1175-1184, 1997. MORGAN J.A., PATAKI D.E., KÖRNER C.Water relations in grassland and desert ecosystems exposed to elevated atmospheric CO2. Oecologia, v.140, 11–25, 2004.
MORIN,F.; ANDRE,M.; BETSCHE, T. Growth Kinetics, Carbohydrate, and Leaf Phosphate Content of Clover (Trifolium subterraneum L.) after Transfer to a High CO2 Atmosphere or to
High Light and Ambient Air', Plant Physiology., v. 99, p. 89-95, 1992.
MUNNS, R. Comparative physiology of salt and water stress. Plant, Cell and Environment, Oxford, v. 25, p. 239-250, 2002.
MUNNS, R.; TESTER, M. Mechanism of salinity tolerance. Annual Review of Plant
NAKANO, Y.; ASADA, K. Hydrogen peroxide is scavenged by ascorbato-specific peroxidase in spinach chloroplasts. Plant Cell Physiology, v. 22, n. 1068-1072, p. 1981. NETONDO, G.W.; ONYANGO, J.C.; BECK, E. Sorghum and salinity: I. Response of growth, water relations and ion accumulation to NaCl salinity. Crop Scince, v. 44, p. 797- 805, 2004.
NOWAK R.S., ELLSWORTH D.S. SMITH S.D. Functional responses of plants to elevated atmospheric CO2 – do photosynthetic and productivity data from FACE experiments support
early predictions? New Phytologist, v. 162, p. 253–280, 2004.
OOSTEN, J.J.V.; WILKINS, D.; BESFORD R.T. Acclimation of tomato to different carbon dioxide concentrations. Relationships between biochemistry and gas exchange during leaf development. New Phytologist. v. 130 p 357-367, 1995.
PANG, C-H. WANG, B.S. Oxidative Stress and Salt Tolerance in Plants. Progress in
Botany, v. 69, n. 03, p. 231-245, 2008.
PARIDA, A. K.; DAS, A. B. Salt tolerance and salinity effects on plants: a review.
Ecotoxicology and Environmental Safety, v. 60, n. 3, p. 324-349, 2005.
PEOPLES, M.B.; FAIZAH, A.W.; RERKASEM, B.G.; HERRIDGE, D.F. Methods for evaluating nitrogen fixation by nodulated legumes in the field. Australian Center for
International agricultural research Camberra, 76.p, 1989.
PÉREZ-LÓPEZ, U., ROBREDO, A., LACUESTA,M., SGHERRI, C., MUNOZ-RUEDA, A., NAVARI-IZZO, F., MENA-PETITE, A. The oxidative stress caused by salinity in two barley cultivars is mitigated by elevated CO2. Plant Physiology. v.135, p. 29–42, 2009.
PÉREZ-LÓPEZ, U., ROBREDO, A., LACUESTA, M., MENA-PETITE, A. MUÑOZ- RUEDA, A. Elevated CO2 reduces stomatal and metabolic limitations in photosynthesis
caused by salinity in Hordeum vulgare. Photosynth Research. v. 111, p. 269–283, 2012. POLLE, A. Protection from oxidative stress in trees as affected by elevated CO2 and
environmental stress. In: Koch G, Mooney H (eds) Terrestrial Ecosystem Response to
Elevated CO2. Academic Press, New York, pp 299–315, 1996.
POZO, A.D., PÉREZ, P., GUTIÉRREZ, D., ALONSO, A., MORCUENDE, R., MARTÍNEZ- CARRASCO, R. 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. Environmental and Experimental Botany. v. 59, p 371–380, 2007.
RAE, A.M.; TRICKER, P.J.; BUNN SM, TAYLOR, G. Adaptation of tree growth to elevated CO2: quantitative trait loci for biomass in Populus. New Phytol, v. 175, p. 59–69, 2007.
ROBREDO, A.; PÉREZ-LÓPEZ, U.; SAINZ DE LA MAZA, H.; GONZÁLEZ-MORO, B.; LACUESTA, M.; MENA-PETITE, A.; MUNOZ-RUEDA, A. Elevated CO2 alleviates the
impact of drought on barley improving water status by lowering stomatal conductance and delaying its effects on photosynthesis. Environ. Experimental Botany v. 59, p. 252–263, 2007.
ROBREDO, A.; LÓPEZA- PÉREZ, U.; MIRANDA- APODACAA, J.; LACUESTAB, M.; PETITEA- MENA, A.; MUÑOZ- RUEDA, A. Elevated CO2 reduces the drought effect on
nitrogen metabolism in barley plants during drought and subsequent recovery.
Environmental and Experimental Botany. V. 71, P. 399- 408, 2011.
ROGERS, A.; GIBON, Y.; STITT, M.; MORGAN, P.B.; BERNACCHI, C.J.,; ORTD,.R.; LONG, S.P. Increased C availability at elevated carbon dioxide concentration improves N assimilation in a legume. Plant, Cell & Environment v. 29, p. 1651–1658, 2006.
SALAZAR -PARRA,C.; AGUIRREOLEA, J.; SÁNCHEZ-DÍAZ, M.; IRIGOYEN,J.J.; MORALES, F. Effects of climate change scenarios on Tempranillo grapevine ( Vitis vinifera L.) ripening: response to a combination of elevated CO 2 and temperature, and moderate drought. Plant and Soil - Plant soil , v. 337, n. 1, pp. 179-191, 2010.
SCHABERG, P.G.; MURAKAMI, P.F,; TURNER, M.R; HEITZ, H.K,; HAWLEY, G.J. Association of red coloration with senescence of sugar maple leaves inautumn. Trees v. 22, p. 573–578, 2008.
SCHWANZ, P.; PICON, C.; VIVIN, P.; DREYER, D.; GUEHL, J.; POLLE, A. Responses of antioxidative systems to drought stress in pendunculate oak and maritime pine as
modulated by elevated CO2. Plant Physiology v. 110, p. 393–402, 1996.
SAGE, R.F., MCKOWN, A.D. Is C4 photosynthesis less phenotypically plastic than C3
photosynthesis? Journal of Experimental Botany, v. 57, n. 2, p. 303–317, 2006.
SASAKI, H. T.; HARA, S.; ITO, S. ; MIURA, M.; HOQUE, M.; LIEFFERING, H. KIM, M.; OKADA K.; KOBAYASHI. Seasonal changes in canopy photosynthesis and respiration, and partitioning of photosynthate, in rice (Oryza sativa L.) grown under free-air CO2
enrichment. Plant Cell Physiology. v. 46, p. 1704-1712, 2005.
SICHER, R.C.; BARNABABY, J.Y. Impact of carbon dioxide enrichment on the responses of maize leafy transcriptis and metabolites to water stress. Physiologia Plantarum, v. 144, p. 228-253, 2012.
SILVA, M. M. P.; VASQUEZ, H.M.; SMITH –BRESSON, R.; SILVA, J.F.;
ERBESDABLER, E.D.; JUNIOR ANDRADE, P.S.C. Eficiência fotoquímica de gramínias forrageiras tropicais submetidas a deficiência hídrica. Revista brasileira de Zootecnia, v. 35, p. 67-74, 2006.
SILVA, E. N.; RIBEIRO, R.V.; FERREIRA-SILVA, S.L.; VIÉGAS, R.A.; SILVEIRA, J. A. G. Salt stress induced damages on the photosynthesis of physic nut young plants. Sci. agric. v.68 n.11, 2011.
SILVEIRA J.A.G.; VIÉGAS R.A.; ROCHA, I.M.A.; MONTEIRO-MOREIRA, A.C.O.; MOREIRA, R.M.; OLIVEIRA J.T.A. Proline accumulation and glutamine synthetase are increased by salt-induced proteolysis in cashew leaves. Journal of Plant Physiology, v.160, n.2, p.115-123, 2003.
SILVEIRA, J.A.G.; ARAÚJO, S.A.; LIMA, J.P.M.S; VIÉGAS, R.A. Roots and leaves display contrasting osmotic adjustment mechanisms in response to NaCl-salinity in Atriplex numularia. Environ Experimental Botany v. 66, p. 1–8, 2009.
SILVEIRA, J. A. G. ; JÚNIOR, J. M. ; SILVA, E. N. ; FERREIRA-SILVA, S. L. ;
ARAGÃO, R. M. ; VIÉGAS, R. A. Salt resistance in two cashew species is associated with accumulation of organic and inorganic solutes. Acta Physiologiae Plantarum, v. 34, p. xx, 2012.
SIMS, R.E.H.; HASTINGS, A.; SCHLAMADINGER, B.; TAYLOR, G.; SMITH, P. Energy crops: curresnt status and future prospects. Global Change Biology, v. 12, p. 2054- 2076, 2006.
STITT, M.; HUBER, S.C.; KERR, P. Control of photosynthetic sucrose synthesis. In: The biochemistry of Plants. London: Academic Press, v. 10, p. 327- 409, 1987.
STITT M. Rising CO2 levels and their potential significance for carbon flow in photosynthetic
cells. Plant, Cell and Environmentv. 14, p. 741–762, 1991.
SULPICE, R.; TRENKAMP, S.; STEINFATH, M.;, USADEL, B.; GIBON, Y.; WITUCKA- WALL, H.; PYL, E., TSCHOEP, H.; STEINHAUSER, M.C.; GUENTHER, M.; HOEHNE, M., ROHWER, J.M.; ALTMANN, T.;. FERNIE, A.R.; STITT, M. Network Analysis of Enzyme Activities and Metabolite Levels and Their Relationship to Biomass in a Large Panel of Arabidopsis Accessions . The Plant Cell, V.. 22, p. 2872–2893, 2010.
SUDHAKAR, C.; LAKSHMI, A.; GIRIDARAKUMAR, S. Changes in the antioxidant enzyme efficacy in two high yielding genotypes of mulberry (Morus alba L.) under NaCl salinity. Plant Science, v. 161, p. 613-619, 2001.
SZABADOS, L.; SAVOURE, A. Proline: a multifunctional amino acid. Trends in Plant
Science. V.15, n.2, p. 89-97, 2010.
TAIZ, L.; ZEIGER, E. Fisiologia vegetal. 4. ed. Porto Alegre: Artmed, 2008. p.819. MTALLIS, . J. ; LIN, Y.; ROGERS, A.; ZHANG, J.; STREET, , N. R. ; MIGLIETTA, F.;X KARNOSKY, F.; ANGELIS, , P. DE; CALFAPIETRA, V; TAYLOR, G. The transcriptome of Populus in elevated CO2 reveals increased anthocyanin biosynthesis during delaye
autumnal senescence. New phytologist. v.186, p. 415–428 , 2010.
TEZARA, W.; MARÍN, O.; RENGIFO, E.; MARTÍNEZ, D. Photosynthesis e photoinhibition in two xerophytic shrubs drought. Photosynthetica, v. 43, n. 1, p. 37-45, 2005.
TUBA, Z.; LICHTENTHALER, H.K.; Long-term acclimation of plants to elevated CO2 and
its interaction with stresses. Annals of New York Academy of Sciences. v. 46, p. 1113- 1135, 2007.
WEATHERBURN, M. W. Phenol-hypochlorite reaction for determination of ammonia. Anal
VIÉGAS, R.A.; SILVEIRA, J.A.G.; JÚNIOR, A.R.L.; QUEIROZ, J.E.; FAUSTO, M.J.M. Effects of NaCl-salinity on growth and inorganic solute accumulation in young cashew plants.
R. Bras Eng. Agríc. Ambi. 5(2):216-222, 2001.
VAN HANDEL, E. Direct microdetermination of sucrose. Anal biochem. v. 22, p. 280-283, 1968.
YEMM, E. W.; COCKING, E.F. The determination of amino acids with ninhydrin. Analyst., v. 80, p. 209-213, 1955.