Effects of Sequential Hydrogen Peroxide Applications on Salt Stress Tolerance in Bread Wheat Varieties

Elif Saadet Arıcan; Sefer Demirbaş

doi:10.15832/ankutbd.896112

Research Article

Year 2022, Volume: 28 Issue: 4, 592 - 602, 17.10.2022

Elif Saadet Arıcan Sefer Demirbaş

https://doi.org/10.15832/ankutbd.896112

Cited By: 1

Abstract

References

Ahanger M A & Agarwal R M (2017). Salinity stress induced alterations in antioxidant metabolism and nitrogen assimilation in wheat (Triticum aestivum L.) as influenced by potassium supplementation. Plant Physiology and Biochemistry 115: 449–460
Ali Q, Daud M K, Haider M Z, Ali S, Rizwan M, Aslam N, Noman A, Iqbal N, Shahzad F, Deeba F, Ali I & Zhu S J (2017). Seed priming by sodium nitroprusside improves salt tolerance in wheat (Triticum aestivum L.) by enhancing physiological and biochemical parameters. Plant Physiology and Biochemistry 119: 50–58
Arora D & Bhatla S C (2017). Melatonin and nitric oxide regulate sunflower seedling growth under salt stress accompanying differential expression of Cu/Zn SOD and Mn SOD. Free Radical Biology and Medicine, 106: 315–328
Asensio A C, Gil-Monreal M, Pires L, Gogorcena Y, Aparicio-Tejo P M & Moran J F (2012). Two Fe-superoxide dismutase families respond differently to stress and senescence in legumes. Journal of Plant Physiology 169(13): 1253–1260
Ashfaque F (2014). Exogenously applied H2O2 promotes proline accumulation, water relations, photosynthetic efficiency and growth of wheat (Triticum aestivum L.) under salt stress. Annual Research & Review in Biology 4(1): 105–120
Ashraf M (2009). Biotechnological approach of improving plant salt tolerance using antioxidants as markers. In Biotechnology Advances 27(1): 84-93
Ashraf M & Harris P J C (2004). Potential biochemical indicators of salinity tolerance in plants. Plant Science 166(1): 3–16
Athar H ur R, Khan A & Ashraf M (2008). Exogenously applied ascorbic acid alleviates salt-induced oxidative stress in wheat. Environmental and Experimental Botany, 63(1–3): 224–231
Baxter A, Mittler R & Suzuki N (2014). ROS as key players in plant stress signalling. Journal of Experimental Botany 65(5): 1229–1240
Beauchamp C & Fridovich I (1971). Superoxide dismutase: Improved assays and an assay applicable to acrylamide gels. Analytical Biochemistry 44(1): 276–287
Beauchamp C O & Fridovich I (1973). Isozymes of superoxide dismutase from wheat germ. BBA - Protein Structure 317(1): 50–64
Bradford M M (1976). A rapid and sensitive method for the quantition of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry, 72: 248–254
Bruce T J A, Matthes M C, Napier J A & Pickett J A (2007). Stressful “memories” of plants: Evidence and possible mechanisms. Plant Science 173(6): 603–608
Demirbas S & Balkan A (2020). The effect of H2O2 pre-Treatment on Antioxidant Enzyme Activities of Triticale Under Salt Stress. JOTAF 8: 1169–1178
Farooq S, Hussain M, Jabran K, Hassan W, Rizwan M S & Yasir T A (2017). Osmopriming with CaCl2 improves wheat (Triticum aestivum L.) production under water-limited environments. Environmental Science and Pollution Research 24(15): 13638–13649
Giannipolities N & Ries S K (1977). Superoxide dismutase occurance in higher plants. Plant Physiology 59: 309–314
He L H, Gao Z Q & Li R Z (2009). Pretreatment of seed with H2O2 enhances drought tolerance of wheat (Triticum aestivum L.) seedlings. African Journal of Biotechnology 8(22): 6151–6157
He Y & Li Z (2018). Epigenetic Environmental memories in plants: establishment, maintenance, and reprogramming. Trends in Genetics 34(11): 856-866
Jia M, Guan J, Zhai Z, Geng S, Zhang X, Mao L & Li A (2018). Wheat functional genomics in the era of next generation sequencing : An update. The Crop Journal, 6(1): 7–14
Jisha K C, Vijayakumari K, Puthur J T (2013). Seed priming for abiotic stress tolerance: an overview. Acta Physiologie Plantarum 35: 1381-1396
Madhava Rao K V & Sresty T V S (2000). Antioxidative parameters in the seedlings of pigeonpea (Cajanus cajan (L.) Millspaugh) in response to Zn and Ni stresses. Plant Science 157(1): 113–128
Parida A K & Das A B (2005). Salt tolerance and salinity effects on plants: A review. Ecotoxicology and Environmental Safety 60(3): 324-349
Radoglou K M & Jarvis P G (1990). Effects of CO2 enrichment on four poplar clones. I. growth and leaf anatomy. Annals of Botany 65(6): 617–626
Savvides A, Ali S, Tester M & Fotopoulos V (2016). Chemical priming of plants against multiple abiotic stresses: mission possible? Trends in Plant Science 21(4): 329–340
Saxena I, Srikanth S & Chen Z (2016). Cross talk between H2O2 and interacting signal molecules under plant stress response. Frontiers in Plant Science 7: 1–16
Shi X & Ling H (2018). Current advances in genome sequencing of common wheat and its ancestral species. The Crop Journal 6(1): 15–21
Smart R E & Bingham G E (1974). Rapid estimates of relative water content. Plant Physiology 53: 258–260
Tabassum T, Farooq M, Ahmad R, Zohaib A & Wahid A (2017). Seed priming and transgenerational drought memory improves tolerance against salt stress in bread wheat. Plant Physiology and Biochemistry 118: 362–369
Vitória A P, Lea P J & Azevedo R A (2001). Antioxidant enzymes responses to cadmium in radish tissues. Phytochemistry 57(5): 701–710
Wani S H, Kumar V, Shriram V & Sah S K (2016). Phytohormones and their metabolic engineering for abiotic stress tolerance in crop plants. The Crop Journal 4(3): 162-176

Effects of Sequential Hydrogen Peroxide Applications on Salt Stress Tolerance in Bread Wheat Varieties

Year 2022, Volume: 28 Issue: 4, 592 - 602, 17.10.2022

Elif Saadet Arıcan Sefer Demirbaş

https://doi.org/10.15832/ankutbd.896112

Cited By: 1

Abstract

Salinity is affecting plant growth and development. Low concentration of hydrogen peroxide (H2O2) has shown to be effective against various stress factors. In this study, effect of different H2O2 priming methods on growth, physiological and biochemical parameters in three wheat varieties (NKÜ Lider, Sultan-95, and Tosunbey) under salt stress were investigated. Salt stress (0 and 160 mM NaCl) was applied gradually to 100 μM H2O2 applied (-H2O2: negative control, no application; H2O2: positive control, 100 μM H2O2 applied; 1xH2O2: 100 μM H2O2 applied one year ago; 2xH2O2: 100 μM H2O2 applied second time after one year) wheat seedlings. Biochemical results showed that the lowest H2O2 level was in NKÜ Lider variety and in -H2O2 and 1xH2O2 groups. The lowest thiobarbituric acid reactive substances (TBARS) level was in Tosunbey variety and 2xH2O2 group. The highest superoxide dismutase (SOD) activity was in NKÜ Lider variety, all H2O2 pre-treatment caused an increase in SOD activity and 2xH2O2 pre-treatment caused the highest SOD activity. However, H2O2 and TBARS levels increased in all application groups except 2xH2O2 group, while the H2O2 amount increased and TBARS level decreased in 2xH2O2 group. MnSOD was not detected in any groups. CuZnSOD increased in all groups except 2xH2O2 groups under salt stress in Sultan-95 variety compared to FeSOD. H2O2 pre-treatment better tolerated salt stress, and second-applied H2O2 pre-treatment eliminated the stress and improved plant growth. In conclusion, it was determined that H2O2 re-pre-treatment to wheat seeds resulted in improvement of plant growth in tolerant varieties exposed to salt stress.

Keywords

Priming, Stress biomarkers, wheat cultivars, superoxide dismutase activity

References

Ahanger M A & Agarwal R M (2017). Salinity stress induced alterations in antioxidant metabolism and nitrogen assimilation in wheat (Triticum aestivum L.) as influenced by potassium supplementation. Plant Physiology and Biochemistry 115: 449–460
Ali Q, Daud M K, Haider M Z, Ali S, Rizwan M, Aslam N, Noman A, Iqbal N, Shahzad F, Deeba F, Ali I & Zhu S J (2017). Seed priming by sodium nitroprusside improves salt tolerance in wheat (Triticum aestivum L.) by enhancing physiological and biochemical parameters. Plant Physiology and Biochemistry 119: 50–58
Arora D & Bhatla S C (2017). Melatonin and nitric oxide regulate sunflower seedling growth under salt stress accompanying differential expression of Cu/Zn SOD and Mn SOD. Free Radical Biology and Medicine, 106: 315–328
Asensio A C, Gil-Monreal M, Pires L, Gogorcena Y, Aparicio-Tejo P M & Moran J F (2012). Two Fe-superoxide dismutase families respond differently to stress and senescence in legumes. Journal of Plant Physiology 169(13): 1253–1260
Ashfaque F (2014). Exogenously applied H2O2 promotes proline accumulation, water relations, photosynthetic efficiency and growth of wheat (Triticum aestivum L.) under salt stress. Annual Research & Review in Biology 4(1): 105–120
Ashraf M (2009). Biotechnological approach of improving plant salt tolerance using antioxidants as markers. In Biotechnology Advances 27(1): 84-93
Ashraf M & Harris P J C (2004). Potential biochemical indicators of salinity tolerance in plants. Plant Science 166(1): 3–16
Athar H ur R, Khan A & Ashraf M (2008). Exogenously applied ascorbic acid alleviates salt-induced oxidative stress in wheat. Environmental and Experimental Botany, 63(1–3): 224–231
Baxter A, Mittler R & Suzuki N (2014). ROS as key players in plant stress signalling. Journal of Experimental Botany 65(5): 1229–1240
Beauchamp C & Fridovich I (1971). Superoxide dismutase: Improved assays and an assay applicable to acrylamide gels. Analytical Biochemistry 44(1): 276–287
Beauchamp C O & Fridovich I (1973). Isozymes of superoxide dismutase from wheat germ. BBA - Protein Structure 317(1): 50–64
Bradford M M (1976). A rapid and sensitive method for the quantition of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry, 72: 248–254
Bruce T J A, Matthes M C, Napier J A & Pickett J A (2007). Stressful “memories” of plants: Evidence and possible mechanisms. Plant Science 173(6): 603–608
Demirbas S & Balkan A (2020). The effect of H2O2 pre-Treatment on Antioxidant Enzyme Activities of Triticale Under Salt Stress. JOTAF 8: 1169–1178
Farooq S, Hussain M, Jabran K, Hassan W, Rizwan M S & Yasir T A (2017). Osmopriming with CaCl2 improves wheat (Triticum aestivum L.) production under water-limited environments. Environmental Science and Pollution Research 24(15): 13638–13649
Giannipolities N & Ries S K (1977). Superoxide dismutase occurance in higher plants. Plant Physiology 59: 309–314
He L H, Gao Z Q & Li R Z (2009). Pretreatment of seed with H2O2 enhances drought tolerance of wheat (Triticum aestivum L.) seedlings. African Journal of Biotechnology 8(22): 6151–6157
He Y & Li Z (2018). Epigenetic Environmental memories in plants: establishment, maintenance, and reprogramming. Trends in Genetics 34(11): 856-866
Jia M, Guan J, Zhai Z, Geng S, Zhang X, Mao L & Li A (2018). Wheat functional genomics in the era of next generation sequencing : An update. The Crop Journal, 6(1): 7–14
Jisha K C, Vijayakumari K, Puthur J T (2013). Seed priming for abiotic stress tolerance: an overview. Acta Physiologie Plantarum 35: 1381-1396
Madhava Rao K V & Sresty T V S (2000). Antioxidative parameters in the seedlings of pigeonpea (Cajanus cajan (L.) Millspaugh) in response to Zn and Ni stresses. Plant Science 157(1): 113–128
Parida A K & Das A B (2005). Salt tolerance and salinity effects on plants: A review. Ecotoxicology and Environmental Safety 60(3): 324-349
Radoglou K M & Jarvis P G (1990). Effects of CO2 enrichment on four poplar clones. I. growth and leaf anatomy. Annals of Botany 65(6): 617–626
Savvides A, Ali S, Tester M & Fotopoulos V (2016). Chemical priming of plants against multiple abiotic stresses: mission possible? Trends in Plant Science 21(4): 329–340
Saxena I, Srikanth S & Chen Z (2016). Cross talk between H2O2 and interacting signal molecules under plant stress response. Frontiers in Plant Science 7: 1–16
Shi X & Ling H (2018). Current advances in genome sequencing of common wheat and its ancestral species. The Crop Journal 6(1): 15–21
Smart R E & Bingham G E (1974). Rapid estimates of relative water content. Plant Physiology 53: 258–260
Tabassum T, Farooq M, Ahmad R, Zohaib A & Wahid A (2017). Seed priming and transgenerational drought memory improves tolerance against salt stress in bread wheat. Plant Physiology and Biochemistry 118: 362–369
Vitória A P, Lea P J & Azevedo R A (2001). Antioxidant enzymes responses to cadmium in radish tissues. Phytochemistry 57(5): 701–710
Wani S H, Kumar V, Shriram V & Sah S K (2016). Phytohormones and their metabolic engineering for abiotic stress tolerance in crop plants. The Crop Journal 4(3): 162-176

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Details

Primary Language	English
Subjects	Engineering
Journal Section	Makaleler
Authors	Elif Saadet Arıcan 0000-0003-2969-8724 Sefer Demirbaş 0000-0001-7201-3888
Publication Date	October 17, 2022
Submission Date	March 13, 2021
Acceptance Date	October 29, 2021
Published in Issue	Year 2022 Volume: 28 Issue: 4

Cite

APA	Arıcan, E. S., & Demirbaş, S. (2022). Effects of Sequential Hydrogen Peroxide Applications on Salt Stress Tolerance in Bread Wheat Varieties. Journal of Agricultural Sciences, 28(4), 592-602. https://doi.org/10.15832/ankutbd.896112

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Hydrogen peroxide priming promotes salinity tolerance in plants—A comprehensive review

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