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OJIP曲線(xiàn)和JIP-test在植物干旱脅迫研究中的應(yīng)用歡迎關(guān)注「漢莎科學(xué)儀器」微信公眾號(hào)! 1 總述 1.1 干旱脅迫對(duì)光系統(tǒng)PSII的影響 1.2 干旱脅迫和熱脅迫的關(guān)系
2 干旱脅迫對(duì)植物OJIP曲線(xiàn)和JIP-test參數(shù)的影響 2.1 L&K峰 2.2 性能指數(shù)PI(performance index) PI與干旱因子指數(shù)(DFI)密切相關(guān),能夠顯示不同基因型植物對(duì)干旱反應(yīng)的巨大差異。DFI是指在任意干旱脅迫時(shí)間內(nèi),干旱引起的PI相對(duì)降低量。Strauss等人于2006年即運(yùn)用相似定義CFI(Chill Factor Index)檢測(cè)不同大豆基因型的耐寒性。DFI還用于10個(gè)大麥品種(圖2)[42]和21個(gè)芝麻突變體種質(zhì)[48]在干旱脅迫下的特性鑒定。利用性能指數(shù)PI和OJIP曲線(xiàn)確定了埃及雙色大麥和高粱**耐性和最敏感的地方品種[49]。這些研究證明在PSII水平上區(qū)分耐旱品種和敏感品種是可能的。
2.4 延遲熒光
本文內(nèi)容源自《Emerging Technologies and Management of Crop Stress Tolerance A Sustainable Approach》Volume 2,Edited by Parvaiz Ahmad and Saiema Rasool. 參考文獻(xiàn): [1] Monteiro,J., Prado, C., 2006. Apparent carboxylation efficiency and relative stomataland mesophyll limitations of photosynthesis in an evergreen cerrado speciesduring water stress. Photosynthetica 44 (1), 39 - 45. [2] Rampino,P., Pataleo, S., Gerardi, C., Mita, G., Perrotta, C., 2006. Drought stressresponse in wheat: physiological and molecular analysis of resistant andsensitive genotypes. Plant Cell Environ. 29 (12), 2143 - 2152. [3] Yin, C.,Berninger, F., Li, C., 2006. Photosynthetic responses of Populus przewalskisubjected to drought stress. Photosynthetica 44 (1), 62 - 68. [4] Hura,T., Grzesiak, S., Hura, K., Thiemt, E., Tokarz, K., We˛dzony, M., 2007.Physiological and biochemical tools useful in drought - tolerance detection ingenotypes of winter triticale: accumulation of ferulic acid correlates withdrought tolerance. Ann. Bot. 100 (4), 767 - 775. [5] Zhou,Y., Lam, H.M., Zhang, J., 2007. Inhibition of photosynthesis and energydissipation induced by water and high light stresses in rice. J. Exp. Bot. 58(5), 1207 - 1217. [6] Medrano,H., Escalona, J., Bota, J., Gulias, J., Flexas, J., 2002. Regulation ofphotosynthesis of C3 plants in response to progressive drought: stomatalconductance as a reference parameter. Ann. Bot. 89 (7), 895 - 905. [7] Chaves,M., Oliveira, M., 2004. Mechanisms underlying plant resilience to waterdeficits: prospects for water - saving agriculture. J. Exp. Bot. 55 (407), 2365- 2384. [8] Matorin,D., Ortoidze, T., Nikolaev, G., Venediktov, P., Rubin, A., 1982. Effects ofdehydration on electron transport activity in chloroplasts [peas].Photosynthetica 16 (2), 226 - 233. [9] Cornic,G., Massacci, A., 1996. Leaf photosynthesis under drought stress. In: Baker,N.R. (Ed.), Photosynthesis and the Environment. Kluwer Academic Publishers, pp.347 - 366. [10] Mullet,J.E., Whitsitt, M.S., 1996. Plant cellular responses to water deficits. PlantGrowth Regulator 20, 119 - 124. [11] Wright,H., DeLong, J., Lada, R., Prange, R., 2009. The relationship between waterstatus and chlorophyll a fluorescence in grapes (Vitis spp.). Postharvest Biol.Technol. 51 (2), 193 - 199. [12] Zheng,C., Jiang, D., Liu, F., Dai, T., Jing, Q., Cao, W., 2009. Effects of salt andwaterlogging stresses and their combination on leaf photosynthesis, chloroplastATP synthesis, and antioxidant capacity in wheat. Plant Sci. 176 (4), 575 -582. [13] Hussein,M.M., Abd El - Kader, A.A., Mona, A.M.S., 2009. Mineral status of plant shootsand grains of barley under foliar fertilization and water stress. Res. J.Agric. Biol. Sci. 5, 108 - 115. [14] Liu, W.- J., Chen, Y. - E., Tian, W. - J., Du, J. - B., Zhang, Z. - W., Xu, F., etal., 2009. Dephosphorylation of photosystem II proteins and phosphorylation ofCP29 in barley photosynthetic membranes as a response to water stress. Biochim.Biophys. Acta 1787 (10), 1238 - 1245. [15] VanRensburg, L., Krüger, G.,1993. Differential inhibition of photosynthesis (in vivo and in vitro), andchanges in chlorophyll a fluorescence induction kinetics of four tobaccocultivars under drought stress. J. Plant Physiol. 141 (3), 357 - 365. [16] Souza,R.P., Machado, E.C., Silva, J.A.B., Lagaa, A.M.M.A.,Silveira, J.A.G., 2004. Photosynthetic gas exchange, chlorophyll fluorescenceand some associated metabolic changes in cowpea (Vigna unguiculata)during water stress and recovery. Environ. Exp. Bot. 51 (1), 45 - 56. [17] Lauriano,J.A., Ramalho, J.C., Lidon, F.C., C′eu matos, M., 2006. Mechanisms of energydissipation in peanut under water stress. Photosynthetica 44 (3), 404 - 410. [18] Gomes,F.P., Oliva, M.A., Mielke, M.S., de Almeida, A - AF, Leite, H.G., Aquino, L.A.,2008. Photosynthetic limitations in leaves of young Brazilian Green Dwarfcoconut (Cocos nucifera L. “nana”) palm under well - watered conditions orrecovering from drought stress. Environ. Exp. Bot. 62 (3), 195 - 204. [19] Guha,A., Sengupta, D., Reddy, A.R., 2013. Polyphasic chlorophyll a fluorescencekinetics and leaf protein analyses to track dynamics of photosyntheticperformance in mulberry during progressive drought. J. Photochem. Photobiol. B,Biol. 119, 71 - 83. [20] Paknejad,F., Nasri, M., Moghadam, H.R.T., Zahedi, H., Alahmadi, M.J., 2007. Effects ofdrought stress on chlorophyll fluorescence parameters, chlorophyll content andgrain yield of wheat cultivars. J. Biol. Sci. 7, 841 - 847. [21] Guóth, A.,Tari, I., Gall′e, A′., Csisz′ar, J., Horv′ath, F., P′ecsv′aradi, A., Cseuz, L.,Erdei, L., 2009a. Chlorophyll a fluorescence induction parameters of flagleaves characterize genotypes and not the drought tolerance of wheat duringgrain filling under water deficit. Acta Biol. Szeged. 53, 1 - 7. [22] Guóth,A., Tari, I., Gall′e, A′., Csisz′ar, J., P′ecsv′aradi, A., Cseuz, L., Erdei,L., 2009b. Comparison of the drought stress responses of tolerant and sensitivewheat cultivars during grain filling: changes in flag leaf photosyntheticactivity, ABA levels, and grain yield. J. Plant Growth Regul. 28 (2), 167 -176. [23] Sofo,A., Dichio, B., Montanaro, G., Xiloyannis, C., 2009. Photosynthetic performanceand light response of two olive cultivars under different water and lightregimes. Photosynthetica 47 (4), 602 - 608. [24] Hamerlynck,E.P., Huxman, T.E., 2009. Ecophysiology of two Sonoran Desert evergreen shrubsduring extreme drought. J. Arid Environ. 73 (4 - 5), 582 - 585. [25] Peeva,V., Cornic, G., 2009. Leaf photosynthesis of Haberlea rhodopensis before andduring drought. Environ. Exp. Bot. 65 (2 - 3), 310 - 318. [26] Ohashi,Y., Nakayama, N., Saneoka, H., Fujita, K., 2006. Effects of drought stress onphotosynthetic gas exchange, chlorophyll fluorescence and stem diameter ofsoybean plants. Biol. Plant. 50 (1), 138 - 141. [27] Zivcak,M., Olsovska, K., Brestic, M., Slabbert, M.M., 2013. Critical temperaturederived from the selected chlorophyll a fluorescence parameters of indigenousvegetable species of South Africa treated with high temperature. PhotosynthesisResearch for Food, Fuel and the Future. Springer, Berlin Heidelberg, pp. 628 -632. [28] Zivcak,M., Brestic, M., Balatova, Z., Drevenakova, P., Olsovska, K., Kalaji, H.M., etal., 2013. Photosynthetic electron transport and specific photoprotectiveresponses in wheat leaves under drought stress. Photosynth. Res. 117, 529 -546. [29] Dobra,J., Motyka, V., Dobrev, P., Malbeck, J., Prasil, I.T., Haisel, D., et al.,2010. Comparison of hormonal responses to heat, drought and combined stress intobacco plants with elevated proline content. J. Plant Physiol. 167 (16), 1360- 1370. [30] Silva,E.N., Ferreira - Silva, S.L., Fontenele, A.d.V., Ribeiro, R.V., Vi′egas, R.A.,Silveira, J.A.G., 2010. Photosynthetic changes and protective mechanismsagainst oxidative damage subjected to isolated and combined drought and heatstresses in Jatropha curcas plants. J. Plant Physiol. 167 (14), 1157 - 1164. [31] Oukarroum,A., El Madidi, S., Strasser, R., 2012. Exogenous glycine betaine and proline playa protective role in heat - stressed barley leaves (Hordeum vulgare L.): achlorophyll a fluorescence study. Plant Biosyst. 146 (4), 1037 - 1043. [32] Havaux,M., 1992. Stress tolerance of photosystem II in vivo antagonistic effects ofwater, heat, and photoinhibition stresses. Plant Physiol. 100 (1), 424 - 432. [33] Lu, C.,Zhang, J., 1999. Effects of water stress on photosystem II photochemistry andits thermostability in wheat plants. J. Exp. Bot. 50 (336), 1199 - 1206. [34] Ashraf,M., Foolad, M., 2007. Roles of glycine betaine and proline in improving plantabiotic stress resistance.Environ. Exp. Bot. 59 (2), 206 - 216. [35] Bolhàr -Nordenkampf, H., Ö quist, G., 1993. Chlorophyllfluorescence as a tool in photosynthesis research. In: Hall, D.O., Scurlock,J.M.O., Bolhàr - Nordenkampf, H.R., Leegood, R.C., Long, S.P. (Eds.),Photosynthesis and Production in a Changing Environment: A Field and LaboratoryManual. Chapman and Hall, London, UK, pp. 193 - 206. [36] Schweiger,J., Lang, M., Lichtenthaler, H.K., 1996. Differences in fluorescence excitationspectra of leaves between stressed and non - stressed plants. J. Plant Physiol.148 (5), 536 - 547. [37] Yordanov,I., Tsonev, T., Goltsev, V., Kruleva, L., Velikova, V., 1997. Interactiveeffect of water deficit and high temperature on photosynthesis of sunflower andmaize plants. 1. Changes in parameters of chlorophyll fluorescence inductionkinetics and fluorescence quenching. Photosynthetica 33 (3 - 4), 391 - 402. [38] Munné -Bosch, S., Falara, V., Pateraki, I., Lo′pez - Carbonell, M., Cela, J.,Kanellis, A.K., 2009. Physiological and molecular responses of the isoprenoidbiosynthetic pathway in a drought - resistant Mediterranean shrub, Cistuscreticus exposed to water deficit. J. Plant Physiol. 166 (2), 136 - 145. [39] VanRensburg, L., Kruger, G., Eggenberg, P., Strasser, R., 1996. Can screeningcriteria for drought resistance in Nicotiana tabacum L be derived from thepolyphasic rise of the chlorophyll a fluorescence transient (OJIP)? S. Afr. J.Bot. 62 (6), 337 - 341. [40] Oukarroum,A., El Madidi, S., Strasser, R.J., 2006. Drought stress induced in barleycultivars (Hordeurn vulgare L.) by polyethylene glycol, probed bygermination, root length and chlorophyll a fluorescence rise (OJIP). Arch. Sci.59 (1), 65 - 74. [41] Gomes,M.T.G., da Luz, A.C., dos Santos, M.R., do Carmo Pimentel Batitucci, M., Silva,D.M., Falqueto, A. R., 2012. Drought tolerance of passion fruit plants assessedby the OJIP chlorophyll a fluorescence transient. Sci. Hortic. 142, 49 - 56. [42] Oukarroum,A., Madidi, S.E., Schansker, G., Strasser, R.J., 2007. Probing the responses ofbarley cultivars (Hordeum vulgare L.) by chlorophyll a fluorescenceOLKJIP under drought stress and re - watering. Environ. Exp. Bot. 60 (3), 438 -446. [43] Strasser,R.J., Stirbet, A.D., 1998. Heterogeneity of photosystem II probed by thenumerically simulated chlorophyll a fluorescence rise (O - J - I - P). Math.Comput. Simul. 48 (1), 3 - 9. [44] Guissé,B., Srivastava, A., Strasser, R., 1995. The polyphasic rise of the chlorophylla fluorescence (OKJIP) in heat stressed leaves. Arch. Sci. Geneve 48, 147 -160. [45] Strasser,R.J., Tsimilli - Michael, M., Srivastava, A., 2004. Analysis of the chlorophylla fluorescence transient. In: Papageorgiou, G., Govindjee (Eds.), Advances inPhotosynthesis and Respiration. Chlorophyll a Fluorescence: A Signature ofPhotosynthesis. Springer, Dordrecht, The Netherlands, pp. 321 - 362. [46] Zivcak,M., Brestic, M., Olsovska, K., Slamka, P., 2008. Performance Index as asensitive indicator of water stress in Triticum aestivum. Plant Soil Environ.54, 133 - 139. [47] Zivcak,M., Brestic, M., Olsovska, K., 2008. Physiological parameters useful inscreening for improved tolerance to drought in winter wheat (Triticum aestivumL.). Cereal Res. Commun. 36, 1943 - 1946. [48] Boureima,S., Oukarroum, A., Diouf, M., Cisse, N., Van Damme, P., 2012. Screening fordrought tolerance in mutant germplasm of sesame (Sesamum indicum) probing bychlorophyll a fluorescence. Environ. Exp. Bot. 81, 37 - 43. [49] Jedmowski,C., Ashoub, A., Bru¨ggemann, W., 2013. Reactions of Egyptian landraces ofHordeum vulgare and Sorghum bicolor to drought stress, evaluated by the OJIPfluorescence transient analysis. Acta Physiol. Plant. 35 (2), 345 - 354. [50] VanHeerden, P.D.R., Swanepoel, J.W., Kru¨ger, G.H.J., 2007. Modulation ofphotosynthesis by drought in two desert scrub species exhibiting C3- mode CO2 assimilation. Environ. Exp. Bot. 61 (2), 124 - 136. [51] Schreiber,U., Neubauer, C., Klughammer, C., 1989. Devices and methods for room -temperature fluorescence analysis. Philos. Trans. R. Soc. Lond., B, Biol. Sci.323 (1216), 241 - 251. [52] Schansker,G., Srivastava, A., Govindjee, Strasser, R.J., 2003. Characterization of the820 - nm transmission signal paralleling the chlorophyll a fluorescence rise (OJIP)in pea leaves. Funct. Plant Biol. 30 (7), 785 - 796. [53] Ceppi,M.G., Oukarroum, A., C¸ ic¸ek, N., Strasser, R.J., Schansker, G., 2012. The IPamplitude of the fluorescence rise OJIP is sensitive to changes in thephotosystem I content of leaves: a study on plants exposed to magnesium andsulfate deficiencies, drought stress and salt stress. Physiol. Plant. 144 (3),277 - 288. [54] Oukarroum,A., Schansker, G., Strasser, R.J., 2009. Drought stress effects on photosystemI content and photosystem II thermotolerance analyzed using Chl a fluorescencekinetics in barley varieties differing in their drought tolerance. Physiol.Plant. 137 (2), 188 - 199. [55] Goltsev,V., Zaharieva, I., Chernev, P., Strasser, R.J., 2009. Delayed chlorophyllfluorescence as a monitor for physiological state of photosynthetic apparatus.Biotechnol. Biotechnol. Equip. 23, 452 - 457 (special edition). [56] Strasser,R.J., Tsimilli - Michael, M., Qiang, S., Goltsev, V., 2010. Simultaneous invivo recording of prompt and delayed fluorescence and 820 - nm reflectionchanges during drying and after rehydration of the resurrection plant Haberlearhodopensis. Biochim. Biophys. Acta 1797, 1313 - 1326. [57] Kalaji,H.M., Carpentier, R., Allakhverdiev, S.I., Bosa, K., 2012. Fluorescenceparameters as early indicators of light stress in barley. J. Photochem.Photobiol. B, Biol. 112, 1 - 6. [58] Goltsev,V., Gurmanova, M., Kouzmanova, M., Yordanov, I., Qiang, S., Pentland, A., etal., 2010. Analysis of dark drops, dark - induced changes in chlorophyllfluorescence during the recording of the OJIP transient. In: Kuang, T., Lu, C.,Zhang, L. (Eds.), Photosynthesis Research for Food, Fuel and Future. Springer -Verlag, Berlin, Heidelberg, pp. 179 - 183. [59] Goltsev,V., Zaharieva, I., Chernev, P., Kouzmanova, M., Kalaji, H.M., Yordanov, I., etal., 2012. Drought - induced modifications of photosynthetic electron transportin intact leaves: analysis and use of neural net - works as a tool for a rapidnon - invasive estimation. Biochim. Biophys. Acta 1817 (8), 1490 - 1498. [60] Goltsev,V., Chernev, P., Zaharieva, I., Lambrev, P., Strasser, R.J., 2005. Kinetics ofdelayed chlorophyll a fluorescence registered in milliseconds time range.Photosynth. Res. 84, 209 - 215. [61] Zaharieva,I., Taneva, S.G., Goltsev, V., 2001. Effect of temperature on the luminescentcharacteristics in leaves of Arabidopsis mutants with decreased unsaturation ofthe membrane lipids. Bulg J. Plant Physiol. 27, 3 - 19. |