Proteomic analysis of salinity stress-responsive proteins in plants

Asian Journal of Plant Sciences

Volumn 9, Issue 6, 2010, Pages 307-313

  Joseph, Baby ^a   Jini, D ^a  

^a MALANKARA CATHOLIC COLLEGE   (India)

Author keywords

Heat shock proteins; Plants; Salinity; Salt stress; Stress proteins

Indexed keywords

EID: 77957711051     PISSN: 16823974     EISSN: 18125697     Source Type: Journal    
DOI: 10.3923/ajps.2010.307.313     Document Type: Review

References (72)

1. Abdul-Jaleel, C, R. Gopi, G.M.A. Lakshmanan and R. Panneerselvam, 2006. Triadimefon induced changes in the antioxidant metabolism and ajmalicine production in Catharanthus roseus (L.) G. Don. Plant Sci., 171: 271-276.
2. Allakhverdiev, S.I., A. Sakamoto, Y. Nishiyama, M. Inaba and N. Murata, 2000. Ionic and osmotic effects of NaCl-induced inactivation of photosystems I and II in Synechococcus sp. Plant Physiol., 123: 1047-1056.
3. Apel, K. and H. Hirt, 2004. Reactive oxygen species: Metabolism, oxidative stress and signal transduction. Ann. Rev. Plant Biol., 55: 373-399.
4. Ashraf, M. and P. J.C. Harris, 2004. Potential biochemical indicators of salinity tolerance in plants. Plant Sci., 166: 3-16.
5. Ashraf, M., 2002. Salt tolerance of cotton: some new advances. Critical Rev. Plant Sci., 21: 1-31.
6. Ashraf, M., 2009. Biotechnological approach of improving plant salt tolerance using antioxidants as markers. Biotechnol. Adv., 27: 84-93.
7. Athar, H., A. Khan and M. Ashraf, 2008. Exogenously applied ascorbic acid alleviates salt-induced oxidative stress in wheat. Environ. Exp. Bot, 63: 224-231.
8. Aydi, S., S. Sassi and C. Abdelly, 2008. Growth, nitrogen fixation and ion distribution in Medicago truncatula subjected to salt stress. Plant Soil, 312: 59-67.
9. Boston, R.S., P.V. Vntanen and E. Vierlmg, 1996. Molecular chaperones and protein folding in plants. Plant Mol. Biol, 32: 191-222.
10. Breusegem, F.V., E. Vranova, J.F. Dat and D. Inze, 2001. The role of active oxygen species in plant signal transduction. Plant Sci., 161: 405-414.
11. Bukau, B., E. Deuerling, C. Pfund and E. Craig, 2000. Getting newly synthesized proteins into shape. Cell, 101: 119-122.
12. Caruso, G., C. Cavaliere, C. Guarino, R. Gubbiotti, P. Foglia and A. Lagana, 2008. Identification of changes in Triticum durum L. leaf proteome in response to salt stress by two-dimensional electrophoresis and MALDI-TOF mass spectrometry. Anal. Bioanal. Chem., 391: 381-390.
13. Chan, N.C., V.A. Likic, R.F. Waller, T.D. Mulhern and T. Lithgow, 2006. The C-terminal TPR domain of Tom70 defines a family of mitochondrial protein import receptors found only in animals and fungi. J. Mol. Biol., 358: 1010-1022.
14. Chitteti, B.R. and Z.H. Peng, 2007. Proteome and phosphor proteome differential expression under salinity stress in rice (Oryza sativa) roots. J. Proteome Res., 6: 1718-1727.
15. De Souza Filho, G.A., B.S. Foreiraa, J.M. Diasa, K.S. Queiroza and A.T. Brancoa et al., 2003. Accumulation of SALT protein in rice plants as a response to environmental stresses. Plant Sci., 164: 623-628.
16. Dionisio-Sese, M.L. and S. Tobita, 1998. Antioxidant responses of rice seedlings to salinity stress. Plant Sci., 135: 1-9.
17. Flom, G., J. Weekes, J.J. Williams and J.L. Johnson, 2006. Effect of mutation of the tetratricopeptide repeat and aspartate-proline 2 domains of Stil on Hsp90 signaling and interaction in Saccharomyces cerevisiae. Genetics, 172: 41-51.
18. Flowers, T.J. and A.R. Yeo, 1995. Breeding for salinity resistance in crop plants: Where next? Aust. J. Plant Physiol, 22: 875-884.
19. Gehlot, H.S., A. Purohit and N.S. Shekhawat, 2005. Metabolic changes and protein patterns associated with adaptation tosalinity in Sesamum indicum cultivars. J. Cell Mol. Biol, 4: 31-39.
20. Gomathi, R. and S. Vasantha, 2006. Change in nucleic acid content and expression of salt shock proteins in relation to salt tolerance in sugarcane. Sugar Tech., 8: 124-127.
21. Guyomarch, S., T. Vernoux, J. Traas, D.X. Zhou and M. Delarue, 2004. MGOUN3, an Arabidopsis gene with tetratrico peptide-repeat-related motifs, regulates meristem cellular organization. J. Exp. Bot., 55: 673-684.
22. Harti, F.U., 1996. Molecular chaperones in cellular protein folding. Nature, 381: 571-579.
23. Hasegawa, P.M., R.A. Bressan, J.K. Zhu and H. J. Bohnert, 2000. Plant cellular and molecular responses to high salinity. Ann. Rev. Plant Physiol. Plant Mol. Biol, 51: 463-499.
24. Heikal, M.M., A.M. Ismail and M.M. Azooz, 2000. Interactive effects of salinity and vitamin B6 on some metabolic processes in two broad bean lines. Acta Agron. Hungarica, 48: 327-336.
25. 2 production in the apoplast of pea leaves: Its relation with salt-induced necrotic lesions in minor veins. Plant Physiol, 127: 817-831.
26. Hernandez, J.A. and M.S. Almansa, 2002. Short term effects of salt stress on antioxidant systems and leaf water relations of pea leaves. Physiol. Plant, 115: 251-257.
27. Hurkman, W.J., C.K. Tanaka and F.M. Dupont, 1988. The effects of salt stress on polypeptides in membrance fractions from barley roots. Plant Physiol, 88: 1263-1273.
28. Hurkman, W.J., C.S. Fornari and C.K. Tanaka, 1989. A comparison of the effect of salt on polypeptide and translatable mRNA in roots of a salt tolerant and salt sensitive cultivar of barley. Plant Physiol, 90: 1444-1456.
29. Igarashi, Y., Y. Yoshiba, Y. Sananda, K. Yamaguchishinozaki, K. Wada and K. Shinozaki, 1997. Characterization of the gene for delta (1)-pyrroline-5-carboxylate synthetase and correlation between the expression of the gene and salt tolerance in (Oryza sativa L.). Plant Mol. Biol, 33: 857-865.
30. Ireland, H.E., S.J. Harding, G.A. Bonwick, M. Jones, C.J. Smith and J.H. Williams, 2004. Evaluation of heat shock protein 70 as a biomarker of environmental stress in Fucus serratus and Lemna minor. Biomarkers, 9: 139-155.
31. Ismail, A.M. and M.M. Azooz, 2002. Response of Vicia faba to salinity and vitamins. Indian J. Plant Physiol, 7: 298-301.
32. Izhaki, A., S.M. Swain, T.S. Tseng, A. Borochov, N.E. Olszewski and D. Weiss, 2001. The role of SPY and its TPR domain in the regulation of gibberellin action throughout the life cycle of Petunia hybrid plants. Plant J., 28: 181-190.
33. Jaleel, C.A., P. Kishorekumar, A. Manivannan, B. Sankar, M. Gomathinayagam and R. Panneerselvam, 2008. Salt stress mitigation by calcium chloride in Phyttanthus amarus. ActaBot. Croat, 67: 53-62.
34. Jiang, Y., B. Yang, N.S. Harris and M.K. Deyholos, 2007. Comparative proteomic analysis of NaCl stress-responsive proteins in Arabidopsis roots. J. Exp. Bot.,58: 3591-3607.
35. Joseph, B., D. Jini and S. Sujatha, 2010. Biological and physiological perspectives of specificity in abiotic salt stress response from various rice plants. Asian J. Agnc. Sci., 2: 99-105.
36. Kirst, G.O., 1989. Salinity tolerance of eu-karyotic marine algae. Ann. Rev. Plant Physiol. Plant Mol. Biol., 40: 21-53.
37. Koca, H., M. Bor, F. Ozdemir and I. Turkan, 2007. The effect of salt stress on lipid peroxidation, antioxidative enzymes andproline content of sesame cultivars. Environ. Exp. Bot, 60: 344-351.
38. Kurek, I., R Dulberger, A. Azem, B.B. Tzvi, D. Sudhakar, P. Christou and A. Beriman, 2002. Deletion of the C-terminal 138 amino acids of the wheat FKBP73 abrogates calmodulin binding, dimerization and male fertility in transgenic rice. Plant Mol. Biol., 48: 369-381.
39. Lauchli, A. and E. Epstein, 1990. Plant Responses to Saline and Sodic Conditions. In: Agricultural Salinity Assessment and Management, Tanji, K.K. (Ed.). American Society of Civil Engineering, New York, pp: 113-137.
40. Lee, D.H., Y.S. Kim and C.B. Lee, 2001. The inductive responses of the antioxidant enzymes by salt stress in the rice (Oryza sativa L.). J. Plant Physiol., 158: 737-745.
41. Lin, C.C. and C.H. Kao, 2001a. Cell wall peroxidase activity, hydrogen peroxide level and NaCl-inhibited root growth of rice seedlings. Plant Soil, 230: 135-143.
42. +, C1G and abscisic acid in NaCl induced inhibition of root growth of rice seedlings. Plant Soil, 237: 165-171.
43. Meot-Duros, L. and C. Magne, 2008. Effect of salinity and chemical factors on seed germination in the halophyte Crithmum maritimum L. Plant Soil, 313: 83-87.
44. Mittler, R., 2002. Oxidative stress, antioxidants and stress tolerance. Trends Plant Sci., 7: 405-410.
45. Morsy, M.R., L. Jouve, J.F. Hausman, L. Hoffmann and J.M. Stewart, 2006. Alteration of oxidative and carbohydrate metabolism under abiotic stress in two rice (Oryza sativa L.) genotypes contrasting in chilling tolerance. J. Plant Physiol., 164: 157-167.
46. Munns, R., 1993. Physiological responses limiting plant growth in saline soils: Some dogma and hypothesis. Plant Cell Environ., 16: 15-24.
47. Munns, R., S. Husain, A.R. Rivelli, T. Condon and A.G. Lindsay, etal, 2002. Avenues for increasing salt tolerance of crops and the role of physiologically based selection traits. Plant Soil, 247: 93-105.
48. Naqvi, S.M.S., S.Q. Raza, M.Z. Hyder, C.V. Ozalp, H.A. Oktem and M. Yucel, 2009. Sub-cellular distribution of two salt-induced peptides in roots of Oryza sativa L. varNonabokra. Afr. J. Biotech., 8: 4613-4617.
49. Nohzadeh, MS., M.H. Rezaei, M. Heidari and G.H. Salekdeh, 2007. Proteomic reveals new salt responsive proteins associated with rice plasma membrane. Biosci. Biotechnol. Biochem., 71: 2144-2154.
50. Noreen, S. and M. Ashraf, 2008. Alleviation of adverse effects of salt stress on sunflower (Helianthus annus L.) by exogenous application of salicylic acid: Growth and photosynthesis. Pak. J. Bot, 40: 1657-1663.
51. Pareek, A., S.L. Singla and A. Grover, 1997. Salt Responsive Proteins/genes in Crop Plants. In: Strategies for Improving Salt Tolerance in Higher Plants, Jaiwal, P.K., R.P. Singh and A. Gulati (Eds.). Oxford and IBH publ. Co., New Delhi, pp: 365-391.
52. Parida, A.K., A.B. Das, B. Mirtra and P. Mohanty, 2004. Salt-stress induced alterations in protein profile and protease activity in the mangrove (Bruguiera parviflora). Z. Narurforsch, 59: 408-414.
53. Parida, A.K. and A.B. Das, 2005. Salt tolerance and salinity effects on plants: A review. Ecotoxicol. Environ. Safety, 60: 324-349.
54. Parker, R, T.J. Flowers, A.L. Moore and N.V.J. Harpham, 2006. An accurate and reproducible method for proteome profiling of the effects of salt stress in the rice leaf lamina. J. Exp. Bot, 57: 1109-1118.
55. Qureshi, M.I., S. Qadir and L. Zolla, 2007. Proteomics-based dissection of stress-responsive pathways inplants. J. Plant Physiol, 164: 1239-1260.
56. Rani, R.U. and A.R. Reddy, 1994. Salt stress responsive polypeptides in germinating seeds and young seedlings of Indica rice Oryza sativa L. J. Plant Physiol, 143: 250-253.
57. Raskin, I., 1992. Role of salicylic acid in plants. Ann. Rev. Plant Physiol. Plant Mol. Biol, 43: 439-463.
58. Salekdeh, G.H., J. Siopongco, L.J. Wade, B. Ghareyazie and J. Bennett, 2002. Proteomic analysis of rice leaves during drought stress and recovery. Proteomics, 2: 1131-1145.
59. Sanders, D., 2000. Plant biology: The salty tale of Arabidopsis. Curr. Biol, 10: 486-488.
60. Silva, C, V. Martinez and M. Carvajal, 2008. Osmotic versus toxic effects of NaCl on pepper plants. Biol. Plantarum., 52: 72-79.
61. Singh, N.K., A.K. Handa, P.M. Hasegawa and R. Be-San, 1985. Proteins associated with adaptation of cultured tobacco cells toNaCl. Plant Physiol., 79: 126-137.
62. Sreenivasulu, N., R. Grimm, U. Wobus and W. Weachke, 2000. Differential response of antioxidant compounds to salinity stress in salt tolerant and salt sensitive seedlings of foxtail millet (Setaria italica). Physiol. Plant, 109: 435-442.
63. Sudhakar C, A. Lakshmi and S. Giridarakumar, 2001. Changes in the antioxidant enzyme efficacy in two high yielding genotypes of mulberry (Moms alba L.) under NaCl salinity. Plant Sci., 161: 613-619.
64. Tsai, Y.C., C.Y. Hong, L.F. Liu and C.H. Kao, 2004. Relative importance of Na+ and Cl- in NaCl-induced antioxidant systems in roots of rice seedlings. Physiol. Plant 122: 86-94.
65. Valderrama, R., F.J. Corpas, A. Carreras, F. Luque and A. Fernandez-Ocana et al, 2007. Nitrosative stress in plants. FEBSLett, 581: 453-461.
66. Wang, H., S. Miyazaki, K. Kawai, M. Deyholos, D.W. Galbraith and H.J. Bohnert, 2003. Temporal progression of gene expression responses to salt shock in maize roots. Plant Mol. Biol., 52: 873-891.
67. Yan, S., Z. Tang, W. Su and W. Sun, 2005. Proteomic analysis of salt stress responsive proteins in rice root. Proteomics, 5: 235-244.
68. Zhang, L., L.H. Tian, J.F. Zhao, Y. Song, C.J. Zhang and Y. Guo, 2009. Identification of an apoplastic protein involved in the initial phase of salt stress response in rice root by two-dimensional electrophoresis. Plant Physiol, 149: 916-928.
69. Zhu, J.K., 2001. Plant salt tolerance. Trends Plant Sci., 6: 66-71.
70. Zhu, J.K., 2000. Genetic analysis of plant salt tolerance using Arabidopsis. Plant Physiol, 124: 941-948.
71. Zhu, J.K., 2002. Salt and drought stress signal transduction in plants. Ann. J. Plant Biol, 53: 247-273.
72. Zorb, C., S. Schmitt, A. Neeb, S. Karl, M. Linder and S. Schubert, 2004. The biochemical reaction of maize (Zea mays L.) to salt stress is characterized by a mitigation of symptoms and not by a specific 21adaptation. Plant Sci., 167: 91-100.