Effects of Alkali Stress and Growing Media on Growth and Physiological Characteristics of Gerbera Plants

Authors
M. Manzari Tavakkoli 1
H. R. Roosta 1
M. Hamidpour 2
1 Department of Horticultural Sciences, Faculty of Agriculture, Vali-e-Asr University of Rafsanjan, Rafsanjan, Islamic Republic of Iran.
2 Department of Soil Sciences, Faculty of Agriculture, Vali-e-Asr University of Rafsanjan, Rafsanjan, Islamic Republic of Iran.
Abstract
In order to determine the best growing media for Gerbera jamesonii under alkaline conditions, a factorial experiment was conducted with two factors, namely: (i) Growing medium, and (ii) Concentrations of bicarbonate (NaHCO3) in nutrient solution. Results showed that increasing the concentration of NaHCO3 from 0 to 40 mM in nutrient solution significantly decreased plant growth, maximal quantum yield of PSII photochemistry (Fv/Fm), photosynthesis Performance Index (PI), Glutamine Synthetase (GS) activity, Leaf Relative Water Content (LRWC), Chlorophylls (Chl a, b and total Chl) and carotenoids. Under alkalinity stress, reduction in vegetative growth, Fv/Fm, PI, LRWC, GS activity and photosynthesis pigments content was the lowest in Coconut Fiber (CF) substrate compared to the other substrates. Furthermore, plants grown in CF substrate had higher soluble sugars and proline content than those in other substrates. On the other hand, plants grown on Perlite (P) substrate had the highest reduction in growth and physiological characteristic in alkaline conditions. The alleviation of alkalinity-induced growth inhibition of plants by CF substrate may be related to improvement of photosynthesis, enhancement of GS enzyme activity and osmotic regulation. It is concluded that the use of CF substrate could provide a useful tool to improve alkalinity tolerance of gerbera plants under NaHCO3 stress.

Keywords

1. Abad, M., Noguera, P. and Bures, S. 2001. National Inventory of Organic Wastes for Use as Growing Media for Ornamental Potted Plant Production: Case Study in Spain. Bioresour. Technol., 77: 197–200.
2. Abadıa, J. and Abadıa, A. 1993. Iron and Pigments. In: “Iron Chelation in Plantsand Soil Microorganisms”, (Eds.): Barton, L. L. and Hemming, B. C.. Academic Press, San Diego, CA, USA, PP. 327–343.
3. Ahmad, P. and Sharma, S. 2008. Salt Stress and Phyto-biochemical Responses of Plants. Plant Soil Environ., 54: 89-99.
4. Ahmad, P. and Sharma, S. 2010. Physio-biochemical Attributes in Two Cultivars of Mulberry (Morusalba L.) under NaHCO3 Stress. Int. J. Plant Prod., 4(2): 1735-6814.
5. Alhendawi, R. A., Römheld, V. E., Kirkby, A. and Marschner, H. 1997. Influence of Increasing Bicarbonate Concentrations on Plant Growth, Organic Acid Accumulation in Roots and Iron Uptake by Barley, Sorghum and Maize. J. Plant Nutr., 20: 1731-1753.
6. Arnon, D. I. 1949. Copper Enzymes in Isolated Chloroplasts Polyphenol Oxidase in Beta Vulgaris. Plant Physiol., 24: 1-15.
7. Baker, N. R. and Rosenqvist, E. 2004. Applications of Chlorophyll Fluorescence Can Improve Crop Production Strategies: An Examination of Future Possibilities. J. Exp. Bot., 55(403): 1607–1621.
8. Balaguer, L., Pugnaire F. I., Martinez-Ferri, E., Armas, C., Valladares, F. and Manrique, E. 2002. Ecophysiological Significance of Chlorophyll Loss and Reduced Photochemical Efficiency under Extreme Aridity in Stipatenacissima L. Plant Soil, 240: 343-352.
9. Bates, L. S., Waldren, R. P. and Teare, I. D. 1973. Rapid Determination of Free Proline for Water Stress Studies. Plant Soil, 39: 205-207.
10. Bloom, P. R. 2000. Soil pH and pH Buffering. In: “Handbook of Soil Science”, (Ed.): Sumner, M.. CRC Press, Boca Raton, pp: 333-352.
11. Briat, J. F. 2007. Iron Dynamics in Plants. In: “Incorporating Advances in Plant Pathology. Advances in Botanical Research”, (Ed.): Delseny, M.. Academic Press, London, PP. 138- 169.
12. Campbell, S. A. and Nishio, J. N. 2000. Iron Deficiency Studies of Sugar Beet Using an Improved Sodium Bicarbonate-buffered Hydroponic Growth System. J. Plant Nutr., 23: 741-757.
13. Cartmill, A. D., Alarcón, A. and Valdez-Aguilar, L. A. 2007. Arbuscular Mycorrhizal Fungi Enhance Tolerance of Rosa multiflora cv. Burr to Bicarbonate in Irrigation Water. J. Plant Nutr., 30: 1517-1540.
14. Chen, W., Feng, C., Guo, W., Shi, D. and Yang, C. 2011. Comparative Effects of Osmotic, Salt and Alkali Stress on Growth, Photosynthesis, and Osmotic Adjustment of Cotton Plants. Photosynthetica, 49: 417-425.
15. Clark, A. J., Landolt, W., Bucher, J. B. and Strasser, R. J. 2000. Beech (Fagussyl vatica) Response to Ozone Exposure Assessed with a Chlorophyll a Fluorescence Performance Index. Environ. Pollut., 109: 501-507.
16. Colla, G., Rouphael, Y., Cardarelli, M., Salerno, A., and Rea, E. 2010. The Effectiveness of Grafting to Improve Alkalinity Tolerance in Watermelon. Environ. Exp. Bot., 68:283-291.
17. Corti, C., Crippa, L., Genevini, P. L. and Centemero, M. 1998. Compost Use in Plant Nurseries: Hydrological and Physicochemical Characteristics. Compost Sci. Util., 6: 35-45.
18. De Ell, J. R. and Toivonen, P. M. A. 2003. Use of Chlorophyll Fluorescence in Postharvest Quality Assessments of Fruits and Vegetables. In: “Practical Applications of Chlorophyll Fluorescence in Plant Biology”. Kluwer Academic Publishers, Boston, PP. 201-242.
19. De la Guardia, M. D. and Alcántara, E. 2002. Bicarbonate and Low Iron Level Increase Root to Total Plant Weight Ratio in Olive and Peach Rootstock. J. Plant Nutr., 25: 1021-1032.
20. Deng, C. N., Zhang, G. X., Pan, X. L. and Zhao, K. Y. 2010. Chlorophyll Fluorescence and Gas Exchange Responses of Maize Seedlings to Saline-alkaline Stress. Bulgarian J. Agric. Sci., 16(1): 49-58.
21. Elstner, E. F. 1982. Oxygen Activation and Oxygen Toxicity. Annu. Rev. Plant Physiol., 33: 73-96.
22. Finnemann, J. and Schjoerring, J. 1998. Ammonium and Soluble Amide-bound Nitrogen in Leaves of Brassica napus as Related to Glutamine Synthetase Activity and External N Supply. Plant Physiol. Biochem., 36 (5): 339–346.
23. Ganege Don, K. K., Xia, Y. P., Zhu, Z., Le, C. and Wijeratne, A. W. 2010. Some Deleterious Effects of Long-term Salt Stress on Growth, Nutrition, and Physiology of Gerbera (Gerbera Jamesonii L.) and Potential Indicators of Its Salt Tolerance. J. Plant Nutr., 33: 2010-2027.
24. Hernandez-Apaolaza, L. and Guerrero, F. 2008. Comparison between Pine Bark and Coconut Husk Sorption Capacity of Metals and Nitrate When Mixed with Sewage Sludge. Bioresour. Technol., 99: 1544–1548.
25. 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. Physiol. Plantarum, 84: 67-72.
26. Jain, D. and Chattopadhyay, D. 2010. Analysis of Gene Expression in Response to Water Deficit of Chickpea (Cicer arietinum L.) Varieties Differing in Drought Tolerance. BMC Plant Biol., 10: 10-24.
27. James, R. A., Munns, R., Von Caemmerer, S., Trejo, C., Miller, C. and Condou, T. 2006. Photosynthetic Capacity Is Related to the Cellular and Sub Cellular Partitioning of Na+, K+ and Cl– in Salt Affected Barley and Durum Wheat. Plant Cell Environ., 29: 2185-2197.
28. Jeong, J. and Guerinot, M. L. 2009. Homing in on Iron Homeostasis in Plants. Trend. Plant Sci., 14: 280-285.
29. Jiang, C. D., Shi, L., Gao, H. Y., Schansker, G., Tóth S. Z. and Strasser, R. J. 2006. Development of Photosystems 2 and 1 during Leaf Growth in Grapevine Seedlings Probed by Chlorophyll a Fluorescence Transient and 820 nm Transmission In vivo. Photosynthetica, 44: 454-463.
30. Katerji, N., Van Hoorn, J. W., Hamdy, A., Mastrorilli, M. and Mou-Karzel, E. 1997. Osmotic Adjustment of Sugar Beets in Response to Soil Salinity and Its Influence on Stomatal Conductance, Growth and Yield. Agric. Water Manage., 34: 57-69.
31. Kertez, S., Fabian, A., Zsoldos, F., Vashegyi, A., Labadi, I., Bona, L. and Pecsvaradi, A. 2002. Changes in Glutamine Synthetase Activity in Presence of Aluminium Complexes. Acta Biol. Szeged, 46: 103–104.
32. Kessler, J. R. 1999. Water Quality Management for Greenhouse Production. Alabama Cooperative Extension System, ANR-1158, Auburn, AL.
33. Krause, G. H. and Weis, E. 1991. Chlorophyll Fluorescence and Photosynthesis: The Basics. Ann. Rev. Plant Physiol. Plant. Mol. Biol., 42: 313-349.
34. Molassiotis, A., Tanou, G., Diamantidis, G., Patakas, A. and Therios, L. 2006. Effects of 4-month Fe Deficiency Exposure on Fe Reduction Mechanism, Photosynthetic Gas Exchange, Chlorophyll Fluorescence and Antioxidant Defense in Two Peach Rootstocks Differing in Fe Deficiency Tolerance. Plant Physiol., 163: 176-185.
35. Marschner, H. 1995. Mineral Nutrition of Higher Plants. IIth Edition, Press, London, 889 PP.
36. Mehta, P., Jajoo, A., Mathur, S. and Bharti, S. 2010. Chlorophyll a Fluorescence Study Revealing Effects of High Salt Stress on Photosystem II in Wheat Leaves. Plant Physiol. Biochem., 48: 16-20.
37. Mohsenian, Y., Roosta, H. R., Karimi, H. R. and Esmaeilizade, M. 2012. Investigation of the Ameliorating Effects of Eggplant, Datura, Orange Nightshade, Local Iranian Tobacco, and Field Tomato as Rootstocks on Alkali Stress in Tomato Plants. Photosynthetica, 50: 411-421.
38. Morales, F., Abadıa, A. and Abadıa, J. 1998. Photosynthesis, Quenching of Chlorophyll Fluorescence and Thermal Energy Dissipation in Iron-deficient Sugar Beet Leaves. Aust. J. Plant Physiol., 25: 402–412.
39. Munns, R. and Tester, M. 2008. Mechanisms of Salinity Tolerance. Annu. Rev. Plant Biol., 59: 651–681.
40. Nedunchezhian, N., Morales, F., Abadía, A. and Abadía, J. 1997. Decline in Photosynthetic Electron Transport Activity and Changes in Thylakoid Protein Pattern in Field Grown Iron Deficient Peach (Prunus persica L.). Plant Sci., 129: 29–38
41. Perez-Garcıa, A., Pereira, S., Pissarra, J., Garcıa Gutierrez, A., Cazorla, F. M., Salema, R., De Vicente, A. and Canovas, F. M. 1998. Cytosolic Localization in Tomato Mesophyll Cells of a Novel Glutamine Synthetase Induced in Response to Bacterial Infection or Phosphinothricin Treatment. Planta, 206: 426– 434.
42. Petersen, F. H. 1996. Water Testing and Interpretation. In: “Water, Media and Nutrition”, (Eds.): Reed, D. W.. E-Publishing Inc., Batavia, PP. 31-49.
43. Pissaloux, A., Morarad, P. and Bertoni, G. 1995. Alkalinity-bicarbonate Calcium Effects on Iron Chlorosis in White Lupine in Soilless Culture. In: “Development in Plant and Soil Science. Iron Nutrition in Soils and Plants”, (Ed.): Abadia, J.. Seventh International Symposium on Iron Nutrition and Interactions in Plants, Zaragoza, Spain, June 27–July 2, 1993. Kluwer Academic Publishers, Dordrecht, 59: 127-133.
44. Qun, H. Z., Ru, T. H., Xiu, L. H., Xing, H. C., Bin, Z. Z. and Song, W. H. 2010. Arbuscular Mycorrhizal Alleviated Ion Toxicity, Oxidative Damage and Enhanced Osmotic Adjustment in Tomato Subjected to NaCl Stress. American Eurasian J. Agric. Environ. Sci., 7: 676-683.
45. Raviv, M. and Lieth, J. H. 2008. Soilless Culture: Theory and Practice. 84 Theobald’s Road, London WC1X 8RR, UK, 625 PP.
46. Reddy, M. P. and Vora, A. B. 1986. Changes in Pigment Composition, Hill Reaction Activity and Saccharides Metabolism in Bajra (Pennisetum typhoides) Leaves under NaCl Salinity. Photosynthetica, 20: 50-55.
47. Römheld, V. 2000. The Chlorosis Paradox: Fe Inactivation as a Secondary Event in Chlorotic Leaves of Grapevine. J. Plant Nutr., 23: 1629-1643.
48. Roosta, H. R. and Schjoerring J. K. 2008. Effects of Nitrate and Potassium on Ammonium Toxicity in Cucumber Plants. J. Plant Nutr., 31: 1270-1283.
49. Santos, C., Pinto, G., Loureiro, J., Oliveira, H. and Costa, A. 2002. Response of Sunflower Cells under Na2SO4. I. Osmotic Adjustment and Nutrient Responses and Proline Metabolism in Sunflower Cells under Na2SO4 Stress. J. Plant Nut. Soil Sci., 165 (3): 366–372.
50. Shannon, M. A., Bohn, P. W., Elimelech, M., Georgiadis, J. G., Marinas, B. J. and Mayes, A. M. 2008. Science and Technology for Water Purification in the Coming Decades. Nature, 452: 301-310.
51. Shi, D. C. and Zhao, K. F. 1997. Effects of NaCl and Na2CO3 on Growth of Puccinellia tenuiflora and on Present State of Mineral Elements in Nutrient Solution. Acta Pratacu. Sin., 6: 51-61.
52. Strasser, R. J., Srivastava, A. and Tsimilli-Michael, M. 2000. The Fluorescence Transient as a Tool to Characterize and Screen Photosynthetic Samples. In: “Probing Photosynthesis: Mechanisms, Regulation and Adaptation”, (Eds.): Yunus, M., Pathre, U. and Mohanty, P.. Taylor and Francis, London, PP. 445-483.
53. Strauss, A. J., Krüger, G. H. J., Strasser, R. J. and Van Heerden, P. D. R. 2006. Ranking of Dark Chilling Tolerance in Soybean Genotypes Probed by the Chlorophyll a Fluorescence. Trans. OJIP Environ. Exp. Bot., 56: 147-157.
54. Sultana, N., Ikeda, T. and Itoh, R. 1999. Effect of NaCl Salinity on Photosynthesis and Dry Matter Accumulation in Developing Rice Grains. Environ. Exp. Bot., 42: 211-220.
55. Teixeira, J., Pereira, S., Canovas, F. and Salema, R. 2005. Glutamine Synthetase of Potato (Solanum tuberosum L. cv. Desiree) Plants: Cell- and Organ-specific Expression and Differential Developmental Regulation Reveal Specific Roles in Nitrogen Sssimilation and Mobilization. J. Exp. Bot., 56: 663–671.
56. Teixeira, T. and Pererira, S. 2007. High Salinity and Drought Act on an Organ-dependent Manner on Potato Glutamine Synthetase Expression and Accumulation. J. Exp. Bot., 60: 121–126.
57. Valdez-Aguilar, L. A. and Reed, D. W. 2007. Response of Selected Greenhouse Ornamental Plants to Alkalinity in Irrigation Water. J. Plant Nutr., 30: 441-452.
58. Wang, X., Geng, S., Ri, Y. J., Cao, D., Liu, J., Shi, D. C. and Yang, C. W. 2011. Physiological Responses and Adaptive Strategies of Tomato Plants to Salt and Alkali Stresses. Sci. Horti., 130: 248–255.
59. Weatherley, P. E. 1950. Studies in Water Relations of Cotton Plants. I. The Field Measurement of Water Deficits in Leaves. New Phytol., 49: 81-97.
60. Whipker, B. E., Bailey, D. A., Nelson, P. V., Fonteno, W. C. and Hammer, P. A. 1996. A Novel Approach to Calculate Acid Additions for Alkalinity Control in Greenhouse Irrigation Water. Commun. Soil Sci. Plant Anal., 27: 959-976.
61. Yang, C. W., Wang P., Li, C. Y., Shi, D. C. and Wang, D. L. 2008. Comparison of Effects of Salt and Alkali Stresses on the Growth and Photosynthesis of Wheat. Photosynthetica, 46: 107-114.
62. Yang, C. W., Xu, H. H., Wang, L. L., Liu, J., Shi, D. C. and Wang, D. L. 2009. Comparative Effects of Salt-stress and Alkali-stress on the Growth, Photosynthesis, Solute Accumulation, and Ion Balance of Barley Plants. Photosynthetica, 47: 79-86.
63. Yang, J. Y., Zheng, W., Tian, Y., Wu, Y. and Zhou, D. W. 2011. Effects of Various Mixed Salt-alkaline Stresses on Growth, Photosynthesis, and Photosynthetic Pigment Concentrations of Medicago ruthenica Seedlings. Photosynthetica, 49: 275- 284.
Journal of Agricultural Science and Technology
Volume 18, Issue 2
March and April 2016
Pages 453-466