Foliar application of 28-homobrassinolide mitigates salinity stress by increasing the efficiency of photosynthesis in Brassica juncea

Alyemeni, Mohammed Nasser; Hayat, Shamsul; Wijaya, Leonard; Anaji, Abdullah

doi:10.1590/S0102-33062013000300007

Abstract

Prior to sowing, seeds of Brassica juncea Czern and Coss cv. Varuna were soaked in water (controls) or in 50, 100 or 150 mM of sodium chloride (NaCl) for 6 h. The resulting plants, at 15, 30 and 45 days after sowing (DAS) were either not treated (controls) or were treated with aqueous solutions of the hormone 28-homobrassinolide (HBL), which was applied to their foliage in concentrations of 10-10, 10-8 or 10-6 M. The concentration of NaCl showed an inverse correlation with the activity of nitrate reductase (EC 1.6.6.1), the activity of carbonic anhydrase (EC 4.2.1.1), chlorophyll content at 60 DAS, the rate of photosynthesis at 60 DAS, and seed yield at 140 DAS (at harvest), all of which decreased in parallel with increases in NaCl concentration. However, treatment with HBL attenuated those decreases and neutralized the ill effects of salinity stress, completely at the lowest NaCl concentration and partially at the higher NaCl concentrations. The seed yield of the crop can be increased by the foliar application of HBL, even under conditions of salinity stress.

Carbonic anhydrase; chlorophyll; homobrassinolide; nitrate reductase; seed yield

ARTICLES

Foliar application of 28-homobrassinolide mitigates salinity stress by increasing the efficiency of photosynthesis in Brassica juncea

Mohammed Nasser Alyemeni; Shamsul Hayat^* * Author for correspondence: hayat_68@yahoo.co.in ; Leonard Wijaya; Abdullah Anaji

King Saud University, Department of Botany & Microbiology, Saudi Arabia

ABSTRACT

Prior to sowing, seeds of Brassica juncea Czern and Coss cv. Varuna were soaked in water (controls) or in 50, 100 or 150 mM of sodium chloride (NaCl) for 6 h. The resulting plants, at 15, 30 and 45 days after sowing (DAS) were either not treated (controls) or were treated with aqueous solutions of the hormone 28-homobrassinolide (HBL), which was applied to their foliage in concentrations of 10^-10, 10^-8 or 10^-6 M. The concentration of NaCl showed an inverse correlation with the activity of nitrate reductase (EC 1.6.6.1), the activity of carbonic anhydrase (EC 4.2.1.1), chlorophyll content at 60 DAS, the rate of photosynthesis at 60 DAS, and seed yield at 140 DAS (at harvest), all of which decreased in parallel with increases in NaCl concentration. However, treatment with HBL attenuated those decreases and neutralized the ill effects of salinity stress, completely at the lowest NaCl concentration and partially at the higher NaCl concentrations. The seed yield of the crop can be increased by the foliar application of HBL, even under conditions of salinity stress.

Key words: Carbonic anhydrase, chlorophyll, homobrassinolide, nitrate reductase, seed yield

Introduction

Soil salinity is a major environmental problem and poses an ever-increasing threat to the growth of plants and their productivity (Koca et al. 2007). In the affected plants, soil salinity reduces the photosynthesis rate by decreasing the level of chlorophyll (Chaves et al. 2009), as well as inhibiting Rubisco activity and causing the closure of stomata, thereby decreasing partial pressure of CO₂ (Soussi et al. 1998). Even NaCl alone decreases the level of nitrate reductase (Aslam et al. 1984), which is the primary enzyme involved in the assimilation of nitrate (Solomonson & Barber 1990). All these and other related processes will naturally lead to poor plant growth and productivity.

Among the various compounds employed in order to alleviate plant stress, the brassinosteroids (BRs) are recognized as a novel group for regulating plant growth and productivity. Studies conducted to date have revealed that BRs elicit a wide range of various morphological and physiological responses in plants (Hayat et al. 2010a; Bajguz & Hayat 2009). In addition, BRs are recognized as regulators of transcription and translation (Bajguz 2000), mechanisms by which they improve the levels of total proteins and enzymes (Fariduddin et al. 2004; Hasan et al. 2008), as well as increasing the seed yield at harvest (Fariduddin et al. 2004). The BRs not only play a regulatory role in plant growth but are also involved in establishing defense mechanisms to counter various biotic and abiotic stresses (Hayat et al. 2010a). However, it would be premature to assign specificity to their effects, under such conditions, before additional work is undertaken within this line of research.

Brassica juncea is an oil seed crop whose susceptibility to disease, salinity and drought results in poor growth and productivity. Therefore, the aim of this study was to explore one of those aspects: to identify remedial measures for overcoming the negative effects of salinity stress through BR treatment.

Materials and methods

The seeds of Brassica juncea Czern and Coss cv. Varuna, were surface sterilized with 5% sodium hypochlorite solution and washed repeatedly with double-distilled water. The seeds were immersed in water (controls) or in 50, 100 or 150 mM of sodium chloride (NaCl) for 6 h (duration based on the experience gained in earlier experiments). These treated seeds were subsequently sown in earthen pots (25 cm diameter) filled with sandy loam and farmyard manure mixed in a ratio of 9:1. Pots were irrigated regularly with tap water. Aqueous solutions of 10^-6, 10^-8 or 10^-10 M of the BR 28-homobrassinolide (HBL) were applied to the leaves at 15, 30 or 45 days after sowing (DAS). The plants were sampled at 60 DAS to assess leaf chlorophyll content, activities of carbonic anhydrase and nitrate reductase, rate of photosynthesis and leaf proline content. Mature plants were harvested at 140 DAS to assess seed yield. Each treatment was applied in quintuplicate. Chlorophyll content was estimated according to Mackinney (1941). Carbonic anhydrase and nitrate reductase activities were determined following the procedure of Dwivedi & Randhawa (1974) and Jaworski (1971), respectively. The photosynthesis rate was measured in fully expanded leaves by a portable photosynthesis system (LI-6200; LI-COR, Lincoln, NE, USA). Leaf proline content was estimated following the method of Bates et al. (1973). The data were analyzed by ANOVA. Mean differences were compared by the least significant difference test, at a significance level of 5% (Gomez & Gomez 1984).

Results and discussion

At 60 DAS, the plants raised from the seeds exposed to pre-sowing soaking in NaCl (at 50, 100 or 150 mM), in comparison with those raised from the control seeds, showed lower chlorophyll content (Fig. 1), a lower photosynthesis rate (Fig. 1), less carbonic anhydrase activity (Fig. 2), less nitrate reductase activity (Fig. 2), and lower seed yield (Fig. 3), and higher proline content (Fig. 3). Moreover, the impact of the salinity stress became more pronounced as the concentration of NaCl was increased from 50 to 150 mM.

The activity of the enzyme chlorophyllase, which brings about the degradation of chlorophyll pigments, increases during salinity stress (Reddy & Vora 1986). Therefore, the contents of the pigments exhibit a sharp decline as the salinity stress intensity increase (Zhao et al. 2007), as depicted in Fig. 1. The other enzyme, carbonic anhydrase, which determines the reversible interconversion of CO₂ and HCO₃^-, is regulated by photon flux density, CO₂ concentration, availability of zinc (Tiwari et al. 2005) and the transcriptional state of the genes encoding its protein (Kim et al. 1994). In addition to other factors, salinity stress brings about the closure of stomata, thereby decreasing the partial pressure of CO₂ (Soussi et al. 1998), as well as a drop in the activity of carbonic anhydrase (Fig. 2). The reported decrease in the activity of carbonic anhydrase by NaCl is in agreement with Hayat et al. (2010b). All of these restrictions (i.e., light harvesting centers and lower CO₂) imposed by salinity stress have a direct impact on photosynthesis, the rate of which declines (Fig. 1). Nitrate (NO₃), the inorganic form of nitrogen that makes its way into the plants through the roots, has to be converted to its organic form (NH₃) before being incorporated into a keto acid. The nitrate reductase enzyme initiates the process of reducing NO₃ to NO₂, the very first step, which is found to be the limiting factor for the rest of the process. The nitrate reductase is induced to be synthesized by the substrate, which is NO₃ (Solomonson & Barber 1990), and its level is also affected by a number of internal and external factors (Campbell 1999). In the present study, the plants have been exposed to stress at the seed stage; therefore, the following are factors that could have changed the pattern of the inducibility of nitrate reductase in the plants: the competitive nature of the relationship between chloride ions and nitrate ions, which reduces the level of the inducer of nitrate reductase at the site of action; the fact that chloride ions act at the level of the membrane bound proteins to change the integrity of the plasma membrane (Cramer et al. 1985), imposing certain restrictions on the nitrate flux, resulting in the loss of the inducer and the enzyme protein (Solomonson & Barber 1990); and the fact that stress-generated signals might act directly on the degradation or inactivation of the existing proteins or the repression of gene expression (Ferrario et al. 1998). The observed decrease (Fig. 2) in the level of nitrate reductase is, therefore, an expression of any one of those factors or a combination of multiple factors.

The stress-induced marker protein (proline) is produced from glutamate, catalyzed by Δ¹-pyrroline-5-carboxylate synthase (Δ¹P₅CS) to Δ¹-proline-5-carboxylate (P₅C), which is subsequently converted to proline by the enzyme Δ¹-pyrroline-5-carboxylate reductase (Δ¹-P₅CR). However, as the situation demands, proline may undergo degradation to P₅C by proline dehydrogenase (ProDH) and finally to glutamate by pyrroline-5-carboxylate dehydrogenase (P₅-CDH) (Hong et al. 2000). A direct relationship between the metabolic and catabolic enzymes of the proline has been reported by Sumithra & Reddy (2004s) in cowpeas grown under water stress. They observed that the activity of the two enzymes (Δ¹P₅CS and Δ¹P₅CR) responsible for the synthesis of proline increased and that of ProDH simultaneously decreased. This relationship has been further explored, in transgenic plants, by Kishor et al. (1995), who identified a relationship between the increased activity of P₅CS and a decrease in that of ProDH, with the overexpression of genes for the former and suppression for the latter. Proline accumulation is, therefore, a highly regulated phenomenon, determined by the genes. In the present study, the physiological drought caused by exposing the plants to NaCl (Hopkins 1995) activated the synthesis of proline and inhibited its degradation, resulting in higher proline levels in the tissues (Fig. 3). Similar observations were previously reported for Brassica juncea under salinity stress (Hayat et al. 2010a). This higher proline level is somehow involved in the regulation of plant mechanisms of protection against the stress by restoring cell volume and turger; controlling damage by free radicals; and protecting/stabilizing enzymes and membrane structure (Timasheff & Arakawa 1989).

Spraying the leaves of the plants with HBL improved the values for all of the parameters studied-in those raised from the seeds subjected to NaCl stress and in those raised from control seeds. This gives the impression that the hormone overrode the inhibitory effect of NaCl, albeit to a limited extent, as determined by the concentration of NaCl and that of HBL. The best interaction between the HBL and the plants, if supplemented with either of the two higher concentrations (10^-8 or 10^-6 M), was observed at 60 DAS. Other plants have also been found to exhibit a similar response to BRs (Eleiwa et al. 2011; Yu et al. 2004). To improve the values for certain proteins, such as Rubisco (Yu et al. 2004), nitrate reductase (Fig. 2), carbonic anhydrase (Fig. 2), and proline (Fig. 3), BRs involve transcription, translation, or both (Bajguz 2000). It is of note that HBL and NaCl had a synergistic effect on proline content, thereby making the plants more tolerant to stress.

The productivity of any crop is determined by a number of factors borne within and without the plants, in particular water balance; nutrient availability; assimilation and translocation rates; hormonal balance; and life span of physiologically active photosynthesizing organs. In the present study, it was evident that certain physiological activities of the foliage have been retarded by the salinity stress (Fig. 1-3). In addition, stress is known to induce the synthesis of additional quantities of abscisic acid and ethylene (Nilsen & Orcutt 1996), which disrupts the translocation of assimilates (Sultana et al. 1999) leading to plant senescence. However, as was observed here, the use of BRs, with or without salinity stress, not only has a constructive effect on the physiological activities of the plants but also extends the life span of the organs and facilitates the translocation of assimilates (Hayat et al. 2010a), thereby ameliorating the detrimental effect of salinity stress on the seed yield (Fig. 3). Our findings are in agreement with those of Eleiwa et al. (2011), who demonstrated that the seed yield of wheat and chickpea grown under NaCl stress was improved by BRs.

Conclusion

On the basis of our results, we can conclude that the foliar application of HBL improves crop performance and increases seed yield under salinity stress.

Acknowledgments

The authors would like to express their appreciation to the Deanship of Scientific Research at King Saud University for the funding provided (Group Research Project Grant no. RGP-VPP-199).

Received: 4 November, 2012.

Accepted: 29 June, 2013

Aslam, M.; Huffaker, R.C. & Rains, D.W. 1984. Early effects of salinity on nitrate assimilation in barley seedlings. Plant Physiology 76(2):321-325.
Bajguz, A. 2000. Effect of brassinosteroids on nucleic acid and protein content in cultured cells of Chlorella vulgaris Plant Physiology Biochemistry 38:797-801.
Bajguz, A. & Hayat, S. 2009. Effects of brassinosteroids on the plant responses to environmental stresses. Plant Physiology Biochemistry 47(1):1-8.
Bates, L.S.; Waldeen, R.P. & Teare, I.D. 1973. Rapid determination of free proline for water stress studies. Plant Soil 39:205-207.
Campbell, H.W. 1999. Nitrate reductase structure, function and regulation. Bridging the gap between biochemistry and physiology. Annual Review of Plant Physiology and Plant Molecular Biology 50:277-303.
Chaves, M.M.; Flexas, J. & Pinheiro, C. 2009. Photosynthesis under drought and salt stress: Regulation mechanism of whole plant to cell. Annals of Botany 103:551-568.
Cramer, G.R.; Lauchli, A. & Polito, V.S. 1985. Displacement of Ca²⁺ by Na²⁺ from the plasmalemma of root cells. A primary response of salt stress. Plant Physiology 79:207-277.
Dwivedi, R.S. & Randhawa, N.S. 1974. Evaluation of a rapid test for the hidden hunger of zinc in plants. Plant Soil 40:445-451.
Eleiwa, M.E.; Bafeel, S.O. & Ibrahim, S.A. 2011. Influence of brassinosteroids on wheat plant (Triticum aestivum L.). Australian Journal of Basic and Applied Sciences 5(5):49-57.
Fariduddin, Q.; Ahmad, A. & Hayat, S. 2004. Response of Vigna radiata to foliar application of 28-homobrassinolide and kinetin. Biologia Plantarum 48:465-468.
Ferrario, S.; Valadier, M. & Foyer, C.H. 1998. Overexpression of nitrate reductase in tobacco delays drought-induced decreases in nitrate reductase activity and mRNA. Plant Physiology 117:293-302.
Gomez, K.A. & Gomez, A.A. 1984. Statistical procedures for agricultural research 2nd ed. New York, John Wiley and Sons.
Hasan, S.A.; Hayat, S.; Ali, B. & Ahmad, A. 2008. 28-Homobrassinolide protects chickpea (Cicer arietinum) from cadmium toxicity by stimulating antioxidant. Environmental Pollution 151:60-66.
Hayat, S.; Mori, M.; Fariduddin, Q.; Bajguz, A. & Ahmad, A. 2010a. Physio- logical role of brassinosteroids: An update. Indian Journal of Plant Physiology 15(2):99-109.
Hayat, S.; Yadav, S.; Wani, A.S.; Irfan, M. & Ahmad, A. 2010b. Response of tomato to two possible modes of salinity stress-a comparative analysis. Journal of Soil Salinity and Water Quality 2(2):84-90.
Hong, Z.; Kakkineni, K.; Zhang, Z. & Verma, D.P. 2000. Removal of feedback inhibition of D¹-pyrroline-5-carboxylate synthetase results in increased accumulation and protection of plants from osmotic stress. Plant Physiology 122:1129-1136.
Hopkins, W.J. 1995. Introduction to Plant Physiology New York, John Wiley and Sons Inc
Jaworski, E.G. 1971. Nitrate reductase assay in intact plant tissues. Biochemistry Biophysics Research Communication 43:1274-1279.
Kim, H.J.; Bracey, M.H. & Barlett, S.G. 1994. Nucleotide sequence of a gene encoding carbonic anhydrase in Arabidopsis thaliana Plant Physiology 105:449.
Kishor, P.; Hong, Z.; Miao, G.H.; Hu, C. & Verma, D. 1995. Overexpression of [delta]-Pyrroline-5-Carboxylate Synthetase Increases Proline Production and Confers Osmotolerance in Transgenic Plants. Plant Physiology 108(4):1387-1394.
Koca, M.; Bor, M.; Ozdemir, F. & Turkan, I. 2007. The effect of salt stress on lipid peroxidation antioxidative enzymes and proline content of sesame cultivars. Environmental and Experimental Botany 60:344-351.
Mackinney, G. 1941. Absorption of light by chlorophyll solutions. Journal of Biological Chemistry 140:315-322.
Nilsen, E.T. & Orcutt, D.M. 1996. Phytohormones and plant responses to stress. Pp.83-198. In: Nilsen, E.T. & Orcutt, D.M. (Eds.), Physiology of plant under stress New York, John Wiley and Sons, Inc.
Reddy, M.P. & Vora, A.B. 1986. Changes in pigment composition, hill reaction activity and saccharide metabolism in bajra (Pennisetum typhoides S&H) leaves under NaCl salinity. Photosynthetica 20:50-55.
Solomonson, L.P. & Barber, M.J. 1990. Assimilatory nitrate reductase. Functional properties and regulation. Annual Review of Plant Physiology and Plant Molecular Biology 41:225-253.
Soussi, M.; Ocana, A. & Lluch, C. 1998. Effect of salt stress on growth, photosynthesis and nitrogen fixation in chickpea (Cicer arietinum L.) Journal of Experimental Botany 49:1329-1337.
Sultana, N.; Ikeda, T. & Itoh, R. 1999. Effect of NaCl salinity on photosynthesis and dry matter accumulation in developing rice grains. Environmental and Experimental Botany 42:211-220.
Sumithra, K. & Reddy, A.R. 2004. Changes in proline metabolism of cowpea seedlings under water deficit. Journal of Plant Biology 31:201-204.
Timasheff, S.N. & Arakawa, T. 1989. Stabilization of protein structure by solvents. Pp. 331-334. In: Creigton, T.E. (Ed.), Protein structure. A practical approach Oxford, IRL Press.
Tiwari, A.; Kumar, P.; Singh, S. & Ansari, S.A. 2005. Carbonic anhydrase in relation to higher plants. Photosynthetica 43:1-9.
Yu, J.Q.; Huang, L.F.; Hu, W.H.; Zhou, Y.H.; Mao, W.H.; Ye, S.F. & Nogues, S. 2004. A role of brassinosteroids in the regulation of photosynthesis in Cucumis sativus Journal of Experimental Botany 55:1135-1143.
Zhao, J.; Ren, W.; Zhi, D.; Wang, L. & Xia, G. 2007. Arabidopsis DREB1A/CBF3 bestowed transgenic tall rescue increased tolerance to drought stress. Plant Cell Reports 26:1521-1528.

*

Author for correspondence:

hayat_68@yahoo.co.in

Publication Dates

Publication in this collection
02 Sept 2013
Date of issue
Sept 2013

History

Received
04 Nov 2013
Accepted
29 June 2013

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Aslam, M.; Huffaker, R.C. & Rains, D.W. 1984. Early effects of salinity on nitrate assimilation in barley seedlings. Plant Physiology 76(2):321-325.

[2] Bajguz, A. 2000. Effect of brassinosteroids on nucleic acid and protein content in cultured cells of Chlorella vulgaris Plant Physiology Biochemistry 38:797-801.

[3] Bajguz, A. & Hayat, S. 2009. Effects of brassinosteroids on the plant responses to environmental stresses. Plant Physiology Biochemistry 47(1):1-8.

[4] Bates, L.S.; Waldeen, R.P. & Teare, I.D. 1973. Rapid determination of free proline for water stress studies. Plant Soil 39:205-207.

[5] Campbell, H.W. 1999. Nitrate reductase structure, function and regulation. Bridging the gap between biochemistry and physiology. Annual Review of Plant Physiology and Plant Molecular Biology 50:277-303.

[6] Chaves, M.M.; Flexas, J. & Pinheiro, C. 2009. Photosynthesis under drought and salt stress: Regulation mechanism of whole plant to cell. Annals of Botany 103:551-568.

[7] Cramer, G.R.; Lauchli, A. & Polito, V.S. 1985. Displacement of Ca²⁺ by Na²⁺ from the plasmalemma of root cells. A primary response of salt stress. Plant Physiology 79:207-277.

[8] Dwivedi, R.S. & Randhawa, N.S. 1974. Evaluation of a rapid test for the hidden hunger of zinc in plants. Plant Soil 40:445-451.

[9] Eleiwa, M.E.; Bafeel, S.O. & Ibrahim, S.A. 2011. Influence of brassinosteroids on wheat plant (Triticum aestivum L.). Australian Journal of Basic and Applied Sciences 5(5):49-57.

[10] Fariduddin, Q.; Ahmad, A. & Hayat, S. 2004. Response of Vigna radiata to foliar application of 28-homobrassinolide and kinetin. Biologia Plantarum 48:465-468.

[11] Ferrario, S.; Valadier, M. & Foyer, C.H. 1998. Overexpression of nitrate reductase in tobacco delays drought-induced decreases in nitrate reductase activity and mRNA. Plant Physiology 117:293-302.

[12] Gomez, K.A. & Gomez, A.A. 1984. Statistical procedures for agricultural research 2nd ed. New York, John Wiley and Sons.

[13] Hasan, S.A.; Hayat, S.; Ali, B. & Ahmad, A. 2008. 28-Homobrassinolide protects chickpea (Cicer arietinum) from cadmium toxicity by stimulating antioxidant. Environmental Pollution 151:60-66.

[14] Hayat, S.; Mori, M.; Fariduddin, Q.; Bajguz, A. & Ahmad, A. 2010a. Physio- logical role of brassinosteroids: An update. Indian Journal of Plant Physiology 15(2):99-109.

[15] Hayat, S.; Yadav, S.; Wani, A.S.; Irfan, M. & Ahmad, A. 2010b. Response of tomato to two possible modes of salinity stress-a comparative analysis. Journal of Soil Salinity and Water Quality 2(2):84-90.

[16] Hong, Z.; Kakkineni, K.; Zhang, Z. & Verma, D.P. 2000. Removal of feedback inhibition of D¹-pyrroline-5-carboxylate synthetase results in increased accumulation and protection of plants from osmotic stress. Plant Physiology 122:1129-1136.

[17] Hopkins, W.J. 1995. Introduction to Plant Physiology New York, John Wiley and Sons Inc

[18] Jaworski, E.G. 1971. Nitrate reductase assay in intact plant tissues. Biochemistry Biophysics Research Communication 43:1274-1279.

[19] Kim, H.J.; Bracey, M.H. & Barlett, S.G. 1994. Nucleotide sequence of a gene encoding carbonic anhydrase in Arabidopsis thaliana Plant Physiology 105:449.

[20] Kishor, P.; Hong, Z.; Miao, G.H.; Hu, C. & Verma, D. 1995. Overexpression of [delta]-Pyrroline-5-Carboxylate Synthetase Increases Proline Production and Confers Osmotolerance in Transgenic Plants. Plant Physiology 108(4):1387-1394.

[21] Koca, M.; Bor, M.; Ozdemir, F. & Turkan, I. 2007. The effect of salt stress on lipid peroxidation antioxidative enzymes and proline content of sesame cultivars. Environmental and Experimental Botany 60:344-351.

[22] Mackinney, G. 1941. Absorption of light by chlorophyll solutions. Journal of Biological Chemistry 140:315-322.

[23] Nilsen, E.T. & Orcutt, D.M. 1996. Phytohormones and plant responses to stress. Pp.83-198. In: Nilsen, E.T. & Orcutt, D.M. (Eds.), Physiology of plant under stress New York, John Wiley and Sons, Inc.

[24] Reddy, M.P. & Vora, A.B. 1986. Changes in pigment composition, hill reaction activity and saccharide metabolism in bajra (Pennisetum typhoides S&H) leaves under NaCl salinity. Photosynthetica 20:50-55.

[25] Solomonson, L.P. & Barber, M.J. 1990. Assimilatory nitrate reductase. Functional properties and regulation. Annual Review of Plant Physiology and Plant Molecular Biology 41:225-253.

[26] Soussi, M.; Ocana, A. & Lluch, C. 1998. Effect of salt stress on growth, photosynthesis and nitrogen fixation in chickpea (Cicer arietinum L.) Journal of Experimental Botany 49:1329-1337.

[27] Sultana, N.; Ikeda, T. & Itoh, R. 1999. Effect of NaCl salinity on photosynthesis and dry matter accumulation in developing rice grains. Environmental and Experimental Botany 42:211-220.

[28] Sumithra, K. & Reddy, A.R. 2004. Changes in proline metabolism of cowpea seedlings under water deficit. Journal of Plant Biology 31:201-204.

[29] Timasheff, S.N. & Arakawa, T. 1989. Stabilization of protein structure by solvents. Pp. 331-334. In: Creigton, T.E. (Ed.), Protein structure. A practical approach Oxford, IRL Press.

[30] Tiwari, A.; Kumar, P.; Singh, S. & Ansari, S.A. 2005. Carbonic anhydrase in relation to higher plants. Photosynthetica 43:1-9.

[31] Yu, J.Q.; Huang, L.F.; Hu, W.H.; Zhou, Y.H.; Mao, W.H.; Ye, S.F. & Nogues, S. 2004. A role of brassinosteroids in the regulation of photosynthesis in Cucumis sativus Journal of Experimental Botany 55:1135-1143.

[32] Zhao, J.; Ren, W.; Zhi, D.; Wang, L. & Xia, G. 2007. Arabidopsis DREB1A/CBF3 bestowed transgenic tall rescue increased tolerance to drought stress. Plant Cell Reports 26:1521-1528.

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Foliar application of 28-homobrassinolide mitigates salinity stress by increasing the efficiency of photosynthesis in Brassica juncea

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