Characterization of Medicago arborea L. response to water and salt stress

Characterization of Medicago arborea L. response to water and salt stress

Автор: Aissat Amal, Mehdadi Zoheir, Leogrande Rita, Stellacci Anna Maria

Журнал: Журнал стресс-физиологии и биохимии @jspb

Статья в выпуске: 4 т.15, 2019 года.

Бесплатный доступ

Medicago arborea L. is a Mediterranean leguminous fodder shrub, regarded as a promising species in arid and semi-arid lands where it can play an important role in the elaboration of a durable pastoral system. The aim of this paper is to investigate and characterize the response of M. arborea plants to water and salt stress at the early growth stage. Seedlings of the species derived from seeds collected in the Djelfa province, Algeria, were grown in pots under greenhouse conditions and separately submitted to water stress, restoring 20%,40%,60%,80% and 100% of substrate field capacity, and salt stress, supplying irrigation water with 0, 50, 100, 150 and 200 meql-1 of NaCl+CaCl2. Stress effects were determined on fresh and dry-matter biomass, relative water content, leaf pigment content (chlorophyll and carotenoids), proline and total soluble sugars amount. Results showed that both water and salt stress affected seedlings growth. In particular, the lowest water regime (20% of field capacity) significantly reduced fresh and dry-biomass and relative water content, whereas seedlings under salinity maintained a good water content (>70%).Chlorophyll a and b , and carotenoids content did not show significant differences among treatments, while proline and total soluble sugars amounts, major osmolytes involved in osmotic adjustment, significantly increased according to salt and water stress intensity...

Еще

Growth, medicago arborea, salinity, tolerance, water deficit

Короткий адрес: https://sciup.org/143168568

IDR: 143168568

Список литературы Characterization of Medicago arborea L. response to water and salt stress

  • Agastian P., Kingsley S. J., and Vivekanandan M. (2000) Effect of salinity on photosynthesis and biochemical characteristics in mulberry genotypes. Photosynthetica., 38, 287-290
  • Aisset A., and Mehdadi, Z. (2016) Effect of Salinity and water Stress on the Germination of Medicago arborea L. Seeds. J. Appl. Environ. Biol. Sci., 6, 113-121
  • Ait Said S., Torre F., and Derridi A. (2013) Gender, Mediterranean drought, and seasonality: photosystem II photochemistry in Pistacia lentiscus. Photosynthetica., 51, 552-564
  • Amato G., Stringi L., and Giambalvo D. (2004) Productivity and canopy modification of Medicago arborea as affected by defoliation management and genotype in a Mediterranean environment. Grass. Forage. Sci., 59, 20-28
  • Ashraf M. (2002) Salt tolerance of cotton: some new advances. Crit. Rev. Plant. Sci., 21, 1-30
  • Ashraf M., and Harris P.J.C. (2013) Photosynthesis under stressful environments: An overview. Photosynthetica., 51, 163-190
  • Ashraf M.Y., and Foolad M.R. (2007) Roles of glycine betaine and proline in improving plant abiotic stress resistance. Environ. Exp. Bot., 59, 206-216
  • Barrs H.D., and Weatherley P.E. (1962) A re-examination of the relative turgidity technique for estimating water deficits in leaves. Aust. J. Biol. Sci., 15, 413-428
  • Bartels D., and Sunkar R. (2005) Drought and Salt Tolerance in Plants: Critical Review. Plant. Sci., 24, 23-58
  • Bissati S., Djerroudi O., Mehani M., and Belkhodja M. (2011) Effet du stress salin sur deux paramètres hydriques (turgescence et transpiration) de jeunes plants de Atriplex halimus et Atriplex canescens. Rev. BioRes., 1, 31-38
  • Chaves M.M. (1991) Effect of water deficits on carbon assimilation. J. Exp. Bot., 42, 1-16
  • Chen M., Tang H., Ma H., Holland T.C., Ng KYS., Salley S.O. (2011) Effect of nutrients on growth and lipid accumulation in the green algae Dunaliella tertiolecta. Bio. Technol. 102, 1649-1655
  • De Koning C.T., and Duncan A.J. (2000) Medicago arborea - a leguminous fodder shrub for low rainfall farming systems. In: Sulas L. (ed.). Legumes for Mediterranean forage crops, pastures and alternative uses. Zaragoza: CIHEAM, p. 435-438. (Cahiers Options Méditerranéennes; n. 45). 10. Meeting of the Mediterranean Sub-Network of the FAO-CIHEAM Inter-Regional Cooperative Research and Development Network on Pastures and Fodder Crops, 2000/04/04-09,Sassari, Italy
  • Dreier W., and Goring M. (1974) Der Einfluss hoher Salzkonzentration auf verschiedene physiologische Parameters von Maiswurzeln. Humboldt University. Reihe/Math, Naturwiss, Berlin
  • Durand J. (2007) Les effets du déficit hydrique sur la plante: aspects physiologiques. Fourrages., 190, 181-195
  • lboutahiri N., Thami Alami I., Ibriz M., and Alfaiz C. (2008) The effect of salinity and high temperature on biomass production of some alfalfa landraces. In: Porqueddu C. (ed.), Tavares de Sousa M.M. (ed.). Sustainable Mediterranean grasslands and their multi-functions. Zaragoza: CIHEAM / FAO / ENMP / SPPF, p. 293-297. (Options Méditerranéennes: Série A. Séminaires Méditerranéens; n. 79). 12. Meeting of the Sub-Network on Mediterranean Forage Resources of the FAO-CIHEAM Inter-regional Cooperative Research and Development Network on Pastures and Fodder Crop, 2008/04/09-12, Elvas, Portugal
  • Farooq M., Wahid A., Kobayashi N., Fujita D., and Basra S.M.A. (2009) Plant drought stress: effects, mechanisms and management. Agron. Sustain. Dev., 29, 185-212
  • Flexas J., Bota J., Loreto F., Cornic G., and Sharkey T.D. (2004) Diffusive and metabolic limitations to photosynthesis under drought and salinity in C3 plants. Plant. Biol., 6, 269-279
  • Hajiboland R., Norouzi F., and Poschenrieder C. (2014) Growth, physiological, biochemical and ionic responses of pistachio seedlings to mild and high salinity. Trees., 28, 1065-1078
  • Hickman SC. (1993) The Jepson Manual: Higher Plants of California. University of California Press, Berkeley, USA
  • Hoagland D.R., and Arnon D.I. (1938) The water-culture method for growing plants without soil. University of California Press, Berkeley, USA
  • Hopkins W. G. (2003) Physiologie végétale. De Boeck, Paris
  • Huang G.T., Ma S.L., Bai L.P., Zhang L., Ma H., Jia P., Liu J., Zhong M., and Guo Z.F. (2012) Signal transduction during cold, salt, and drought stresses in plants. Mol. Biol. Rep., 39, 969-987
  • Irigoyen J.J., Emerich D.W., and Sanchez-Diaz M. (1992) Water stress induced changes in concentrations of proline and total soluble sugars in nodulated alfalfa (Medicago sativa) plants. Plant. Physiol., 84, 55-60
  • Kameli A., and Losel D.M. (1996) Growth and sugar accumulation in durum wheat plants under water stress. New. Phytol., 132, 57-62
  • Kavi Kishor P.B., and Sreenivasulu N. (2014) In proline accumulation per se correlated with stress tolerance or is proline homeostasis a more critical issue. Plant. Cell. Environ., 37, 300-311
  • Kebbas S., Lutts S., and Aid F. (2015) Effect of drought stress on the photosynthesis of Acacia tortilis subsp. raddiana at the young seedling stage. Photosynthetica., 53, 1-11
  • Kicheva M.I., Tsonev T.D., and Popova, L.P. (1994) Stomatal and non-stomatal limitations to photosynthesis in two wheat cultivars subjected to water stress. Photosynthetica., 30, 107-116
  • Kurban H., Saneoka H., Nehira K., Adilla R., Premachandra G.S., and Fujita K. (1999) Effect of salinity on growth, photosynthesis and mineral composition in leguminous plant Alhagi pseudoalhagi (Bieb.). Soil. Sci. Plant. Nutr., 45, 851-862
  • Laouar M., Kies N., Abdellaoui K., Bennour A., Bettahar N., Kadi S., Bouzza L., and Abdelguerfi A. (2001) Effet du stress hydrique sur le comportement physiologique de dix populations de Medicago intertexta. In: Delgado I. (ed.), Lloveras J. (ed.). Quality in lucerne and medics for animal production. Zaragoza: CIHEAM, p. 167-171
  • Lawlor D.W., and Cornic G. (2002) Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants. Plant. Cell. Environ., 25, 275-294
  • Le Houérou H.N. (1995) Bioclimatologie et biogéographie des steppes arides du Nord de l'Afrique: diversité biologique, développement durable et désertisation. In: Le Houérou H.-N. (ed.). Bioclimatologie et biogéographie des steppes arides du Nord de l'Afrique: diversité biologique, développement durable et désertisation. Montpellier: CIHEAM, p. 1-396. (Options Méditerranéennes: Série B. Etudes et Recherches; n. 10)
  • Lefi E., Gulias J., Ribas-Carbó M., and Medrano H. (2004) Soil water deficit effects on photosynthesis, water use efficiency and growth of three Mediterranean shrubs: Medicago arborea, Medicago citrina and Medicago strasseri. In: Ferchichi A. (comp.), Ferchichi A. (collab.). Réhabilitation des pâturages et des parcours en milieux méditerranéens. Zaragoza: CIHEAM, p. 65-68. (Cahiers Options Méditerranéennes; n. 62). 11. Réunion du Sous-Réseau Ressources Fourragères Méditerranéennes du Réseau Coopératif Interrégional FAO-CIHEAM de Recherche et Développement sur les Pâturages et les Cultures Fourragères, 2002/10/29-2002/11/01, Djerba, Tunisia
  • Lichtenthaler H.K. (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. Methods. Enzymol., 148, 350-382
  • Liu N., Shen Y., and Huang B. (2015) Osmoregulants Involved in Osmotic Adjustment for Differential Drought Tolerance in Different Bentgrass Genotypes. J. Amer. Soc. Hort. Sci., 140, 605-613
  • Medrano H., Chaves M.M., Porqueddu C., and Caredda S. (1998) Improving forage crops for semi-arid areas. Outlook. Agr., 27, 89-94
  • Mehdadi Z., (2016) Effect of Salinity and water Stress on the Germination of Medicago arborea L. Seeds. J. Appl. Environ. Biol. Sci., 6, 113-121
  • Munns R. (2002) Comparative physiology of salt and water stress. Plant. Cell. Environ., 25, 239-250
  • Munns R., James R.A., and Lauchli A. (2006) Approches to increasing the salt tolerance of wheat and other cereals. J. Exp. Bot., 57, 1025-1043
  • Papanastasis V.P., Platis P.D., and Dini-Papanastasiou O. (1998) Effects of age and frequency of cutting on productivity of Mediterranean deciduous fodder tree and shrub plantations. For. Ecol. Manag., 110, 283-292
  • Per T.S., Khan N.A., Reddy P.S., Masood A., Hasanuzzaman M., Khan M.I.R., and Anjum N.A. (2017) Approaches in modulating proline metabolism in plants for salt and drought stress tolerance: Phytohormones, mineral nutrients and transgenics. Plant. Physiol. Biochem., 115, 126-140
  • Rosa M., Prado C., Podazza G., Interdonato R., González J.A., Hilal M., and Prado F.E. (2009) Soluble sugars-Metabolism, sensing and abiotic stress: A complex network in the life of plants. Plant. Signal. Behav., 4, 388-393
  • Sanchez F.J., Manzanares M., De Andres E.F., Tenorio J.L., and Ayerbe L. (1998) Turgor maintenance, osmotic adjustment and soluble sugar and proline accumulation in 49 pea cultivars in response to water stress. Field. Crop. Res., 59, 225-235
  • Shabala S.N., Shabala S.I., Martynenko A.I., Babourina O., and Newman I.A. (1998) Salinity effect on bioelectric activity, growth, Na+ and chlorophyll fluorescence of maize leaves-a comparative and prospects for screening. Aust. J. Plant. Physiol., 25, 609-616
  • Szabados, L., and Savourée, A. (2010) Proline: a multifunctional amino acid. Trends. Plant. Sci. 15, 89-97
  • Taiz L., and Zeiger E. (2006) Plant Physiology. Sinauer Associates Inc Publishers, Massachusetts, USA
  • Tewari T.N., and Singh B.B. (1991) Stress studies in lentil (Lens esculenta Moench). Sodicity-induced changes in chlorophyll, nitrate and nitrite reductase, nucleic acids, proline, yield and yield components in lentil. Plant. Soil., 136, 225-230
  • Troll W., and Lindsley J. (1955) A photometric method for the determination of proline. J. Biochem., 215, 655-660
  • Tuteja N. (2010) Cold, salinity, and drought stress. In plant stress biology. Hirt H., Wiley-Blackwell
  • Ventura M.R., Flores M.P., and Castañón J.I.R. (1999) Nutritive value of forage shrubs: Bituminaria bituminosa, Acacia salicina and Medicago arborea. In: Etienne M. (ed.). Dynamics and sustainability of Mediterranean pastoral systems. Zaragoza: CIHEAM, p. 171-173. (Cahiers Options Méditerranéennes; n. 39). 9. Meeting of the Mediterranean Sub-Network of the FAO-CIHEAM Inter-Regional Cooperative Research and Development Network on Pastures and Fodder Crops, 1997/11/26-29, Badajoz, Spain
  • Verbruggen N., and Hermans C. (2008) Proline accumulation in plants: a review. Amino. Acids., 35, 753-759
  • Zhu J.K. (2002) Salt and drought stress signal transduction in plants. Annu. Rev. Plant. Biol., 53, 247-273
  • Zhu J.K. (2007) Plant salt stress. Encyclopedia of life sciences, John Wiley and Sons
Еще
Статья научная
SciUp 2024 © 2024 ©