Abstract
Success of ex situ storage of germplasm for trade and conservation essentially depends upon the precision of the protocol employed for the assessment of germination potential. Active oxygen species and antioxidative enzymes during natural ageing (NA) and controlled deterioration (CD) was monitored during the loss of seed vigour and germination potential in neem seeds showing intermediate seed storage behaviour. Higher levels of SOD, CAT and APX were strongly and positively associated with germination and vigour. The loss of CAT and APX activity estimated quantitatively and number of isoenzymes were closely accompanied with the simultaneous increase in the amounts of H2O2 and OH-radical. The decline in germination and vigour was negatively related with the levels of H2O2 and OH-radical and enhanced electrolyte leakage. The amounts of OH-radical were positively correlated with the decline in DNA content and DNA damage. The levels of SOD isoenzymes initially increased as the germination index of seeds declined from 5250 to 762 and 882 under NA and CD conditions, respectively. Increasing activity of SOD in the ageing seeds were associated with the accumulation of H2O2. The role of antioxidative enzymes in maintaining signalling and damaging amounts of AOS as well as revelations of different pathways of ageing during NA and CD in the ageing neem seeds were discussed.
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References
Arc E, Galland M, Cueff G, Godin B, Lounifi I, Job D, Rajjou L (2011) Reboot the system thanks to protein post-translational modifications and proteome diversity: how quiescent seeds restart their metabolism to prepare seedling establishment. Proteomics 11:1606–1618
Ashtamker C, Kiss V, Sagi M, Davydov O, Fluhr R (2007) Diverse subcellular locations of cryptogenin-induced reactive oxygen species production in tobacco bright yellow-2 cells. Plant Physiol 143:1817–1826
Bailly C (2004) Active oxygen species and antioxidants in seed biology. Seed Sci Res 14:93–107
Beauchamp C, Fridovich I (1971) Superoxide dismutase: improved assay and an assay applicable to acrylamide gels. Anal Biochem 44:276–287
Berjak P, Farrant JM, Pammenter NW (2007) Seed desiccation-tolerance mechanisms. In: Jenks MA, Wood AJ (eds) Plant desiccation tolerance. Blackwell, Ames, pp 151–192
Bradford MM (1976) A rapid and sensitive method for the quantification of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72:248–254
Bray CM, West CHE (2005) DNA repair mechanisms in plants: crucial sensors and effectors for the maintenance of genome integrity. New Phytol 168:511–528
Chance B, Maehly AC (1955) Assay of catalase and peroxidase. In: Colowick SP, Kaplan NO (eds) Methods in enzymology. Academic Press, New York, pp 764–775
Chen H, Osuna D, Colville L, Lorenzo O, Graeber K, Kuster H, Lubner-Metzger G, Kranner I (2013) Transcriptome-wide mapping of pea seed ageing reveals a pivotal role for genes related to oxidative stress and programmed cell death. PLoS One 8(10):e78471
Doyle JF, Doyle JL (1990) Isolation of plant DNA from fresh tissue. Focus 12:13–15
Ellis RH, Hong TD, Roberts EH (1991) An intermediate category of seed storage behaviour. Effects of provenance, immaturity and imbibition on desiccation-tolerance in coffee. J Exp Bot 42:653–657
El-Maarouf-Bouteau H, Mazuy C, Corbineau F, Bailly C (2011) DNA Alteration and programmed cell death during ageing of sunflower seed. J Exp Bot 62:5003–5011
Faria JMR, Buitink J, van Lammeren AAM, Hilhorst HWM (2005) Changes in DNA and microtubules during loss and re-establishment of desiccation tolerance in germinating Medicago truncatula seeds. J Exp Bot 56:2119–2130
Farrant JM, Berjak P, Pammenter NW (1985) The effect of drying rate on viability retention of recalcitrant propagules of Avicennia marina seeds. S Afr J Bot 51(6):432–438
Garnczarska M, Bednarski W, Jancelewicz M (2009) Ability of lupine seeds to germinate and to tolerate desiccation as related to changes in free radical level and antioxidants in freshly harvested seeds. Plant Physiol Biochem 47:56–62
Gutierrez G, Cruz F, Moreno J, Gonzalez-Hernandez VA, Vazquez Ramos JM (1993) Natural and artificial seed ageing in maize: germination and DNA synthesis. Seed Sci Res 3:279–285
Hendry GAF, Finch-Savage WE, Thorpe PC, Atherkon NM, Buckland SH, Nilsson KA, Seel WE (1992) Free radical processes and loss of seed viability during desiccation in the recalcitrant species Quercus robur L. New Phyto l122:273–299
Hu D, Ma G, Wang Q, Yao JH, Wang Y, Pritchard H, Wang X (2012) Spatial and temporal nature of reactive oxygen species production and programmed cell death in elm (Ulmus pumila L.) seeds during controlled deterioration. Plant, Cell Environ 35:2045–2059
Ishibashi Y, Koda Y, Zheng SH, Yuasa T, Iwaya-Inoue M (2013) Regulation of soybean seed germination through ethylene production in response to reactive oxygen species. Ann Bot 1:1–8
Job C, Rajjou L, Lovigny Y, Belghazi M, Job D (2005) Patterns of protein oxidation in Arabidopsis seeds and during germination. Plant Physiol 138:790–802
Kibinza S, Vinel D, Côme D, Bailly C, Corbineau F (2006) Sunflower seed deterioration as related to moisture content during ageing, energy metabolism and active oxygen species scavenging. Physiol Plant 128:496–506
Kibinza S, Bazina J, Bailly C, Farrant JM, Corbineaua O, Bouteaua H (2011) Catalase is a key enzyme in seed recovery from ageing during priming. Plant Sci 181:309–315
Kranner I, Birtic F (2005) A modulating role for antioxidants in desiccation tolerance. Integr Comp Biol 45:734–740
Kranner I, Birtić S, Anderson KM, Pritchard HW (2006) Glutathione half-cell reduction potential: a universal stress marker and modulator of programmed cell death? Free Radical Bio Med 40:2155–2165
Kranner I, Chen HY, Pritchard HW, Pearce SR, Birtić S (2011) Inter-nucleosomal DNA fragmentation and loss of RNA integrity during seed ageing. Plant Growth Regul 63:63–72
Laemmli UK (1970) Cleavage of structural proteins during the assembly of head bacteriophage T4. Nature 227:680–685
Langfinger D, Von Sonntag C (1985) γ-radiolysis of 2-deoxyguanosine. The structure of malonaldehyde like products. Z Naturforsch C 40(5–6):446–448
Li G, Quiros CF (2001) Sequence-related amplified polymorphism (SRAP) a new marker system based on a simple PCR reaction: its application to mapping and gene tagging in Brassica. Theor Appl Genet 103:455–461
Marklund S, Marklund G (1974) Involvement of superoxide anion radical in the autoxidation of pyrogallol and a convenient assay of superoxide dismutase. Eur J Biochem 47:469–474
McDonald MB (1999) Seed deterioration: physiology, repair and assessment. Seed Sci Technol 27(1):177–237
Messenger DJ, McLeod AR, Fry SC (2009) The role of ultraviolet radiation, photosensitizers, reactive oxygen species and ester groups in mechanisms of methane formation from pectin. Plant, Cell Environ 32:1–9
Mittler R, Zilinskas B (1993) Detection of ascorbate peroxidase activity in native gels by inhibition of ascorbate-dependent reduction of nitro blue tetrazolium. Anal Biochem 212:540–546
Moller IM, Jensen PE, Hansson A (2007) Oxidative modifications to cellular components in plants. Annu Rev Plant Biol 58:459–481
Müller K, Linkies A, Vreeburg RAM, Fry SC, Krieger-Liszkay A, Luebner-Metzger G (2009) In vivo cell wall loosening by hydroxyl radicals during cress seed germination and elongation growth. Plant Physiol 150:1855–1865
Murata M, Roos EE, Tsuchiya T (1981) Chromosome damage induced by artificial seed ageing in barley. I. Germinability and frequency of aberrant anaphases at first mitosis. Can J Genet Cytol 23:267–280
Murthy UMN, Kumar PP, Sun WQ (2003) Mechanisms of seed ageing under different storage conditions for Vigna radiate (L.)Wilczek:lipid peroxidation, sugar hydrolysis. J Exp Bot 54:1057–1067
Nakano Y, Asada K (1981) Hydrogen peroxide is scavenged by ascorbate specific peroxidase in spinach chloroplast. Plant Cell Physiol 22(5):867–880
National Research Council (1992) Neem: a tree for solving global problems. In: Report of an adhoc panel of the Board on Science and Technology for International development, National Academy Press, D.C. Washington
Nozoe M, Yoshitaka H, Yasuaki K, Yoji S, Takuya K, John FE, Kenji S (2007) Inhibition of Rac1-derived reactive oxygen species in nucleus tractus solitarius decreases blood pressure and heart rate in stroke-prone spontaneously hypertensive rats. Hypertension 50:62–68
Osborne DJ (2000) Hazards of a germinating seed: available water and the maintenance of genomic integrity. Isr J Plant Sci 48:173–179
Provost C, Choufani Faten, Avedanian Levon, Bkaily Ghassan, Gobeil Fernand, Jacques Danielle (2010) Nitric oxide and reactive oxygen species in the nucleus revisited. Can J Physiol Pharmacol 88(3):296–304
Pukacka S, Ratajczak E (2005) Production and scavenging of reactive oxygen species in Fagus sylvatica seeds during storage at varied temperature and humidity. J Plant Physiol 162:873–885
Pukacka S, Ratajczak E (2007) Age-related biochemical changes during storage of beech (Fagus sylvatica L.) seeds. Seed Sci Res 17:45–53
Rajjou L, Lovigny Y, Groot SP, Belghazi M, Job C, Job D (2008) Proteome-wide characterization of seed aging in Arabidopsis: a comparison between artificial and natural aging protocols. Plant Physiol 148:620–641
Rajjou L, Duval M, Gallardo K, Catusse J, Bally J, Job C, Job D (2012) Seed Germination and Vigor. Annu Rev Plant Biol 63(1):507–533
Rastogi A, Pospíšil P (2012) Production of hydrogen peroxide and hydroxyl radical in potato tuber during the necrotrophic phase of hemibiotrophic pathogen Phytophthora infestans infection. J Photochem Photobiol, B 117:202–206
Ratajczak E, Małecka A, Bagniewska-Zadworna A, Kalemba EM (2015) The production, localization and spreading of reactive oxygen species contributes to the low vitality of long-term stored common beech (Fagus sylvatica L.) seeds. J Plant Physiol 174:147–156
Richards SL, Wilkins KA, Swarbreck SM, Anderson AA, Habib N, Smith AG, McAinsh M, Davies JM (2015) The hydroxyl radical in plants: from seed to seed. J Exp Bot 66:37–46
Roach T, Beckett RP, Minibayeva FV, Minibayeva FV, Colville L, Whitaker C, Chen H, Bailly C, Kranner I (2010) Extracellular superoxide production, viability and redox poise in response to desiccation in recalcitrant Castanea sativa seeds. Plant Cell Environ 33:59–75
Sahu B, Sahu AK, Chennareddy SR, Soni A, Naithani SC (2017) Insights on germinability and desiccation tolerance in developing neem seeds (Azadirachta indica): role of AOS, antioxidative enzymes and dehydrin-like protein. Plant Physiol Biochem 112:64–73
Schopfer P (2001) Hydroxyl radical-induced cell-wall loosening in vitro and in vivo: implications for the control of elongation growth. Plant J 28:679–688
Schopfer P, Plachy C, Frahry G (2001) Release of reactive oxygen intermediates (superoxide radicals, hydrogen peroxide, and hydroxyl radicals) and peroxidase in germinating radish seeds controlled by light, gibberellin, and abscisic acid. Plant Physiol 125:1591–1602
Schwember AR, Bradford KJ (2010) Quantitative trait loci associated with longevity of lettuce seeds under conventional and controlled deterioration storage conditions. J Exp Bot 61:4423–4436
Tesnier K, Strookman-Donkers HM, Van Pijlen JG, Van der Geest AHM, Bino RJ, Groot SPC (2002) A controlled deterioration test for Arabidopsis thaliana reveals genetic variation in seed quality. Seed Sci Technol 30(1):149–166
Tommasi F, Paciolla C, de Pinho MC, De Gara L (2006) Effects of storage temperature on viability, germination and antioxidant metabolism in Ginkgo biloba L. seeds. Plant Physiol Bioch 44:359–368
Varghese B, Naithani SC (2002) Desiccation-induced changes in lipid peroxidation, superoxide level and antioxidant enzyme activity in neem (Azadirachta indica A. Juss.) seeds. Act Physiol Plant 24:79–87
Varghese B, Naithani SC (2008) Oxidative metabolism related changes in cryogenically stored neem (Azadirachta indica A. Juss.) seeds. J Plant Physiol 165:755–765
Woodbury W, Spencer AK, Stahman MA (1971) An improved procedure using ferricyanide for detecting catalase isozyme. Anal Biochem 44(1):301–305
Xin X, Tian Q, Yin G, Chen X, Zhang J, Ng S et al (2014) Reduced mitochondrial and ascorbate–glutathione activity after artificial ageing in soybean seed. J Plant Physiol 171:140–147
Zivy M, Thiellement H, de Vienne D, Hofmann JP (1983) Study on nuclear and cytoplasmic genome expression in wheat by two-dimensional electrophoresis: 1. First results on 18 alloplasmic lines. Theor Appl Genet 66:1–7
Acknowledgements
Present work was supported by DST, Delhi, India funded Project (No. SERB/SR/SO/43/2010). AKS and BS gratefully acknowledge to the DST, Delhi, India (Project; No. SERB/SR/SO/43/2010) and UGC, Delhi, India [Project; F.No 41-381/2012 (SR)] for providing financial assistance, respectively. The E-Gel Image Analyzer System (Invitrogen) used for gel analysis was granted by UGC 12th Five year plan to Pt. Ravishankar Shukla University, Raipur (Chhattisgarh), India.
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Communicated by A. Gniazdowska-Piekarska.
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Fig. S1. Density graph of SOD isoenzymes detected by Native-PAGE in NA and CD seeds. Fig. S2. Density graph of CAT isoenzymes detected by Native-PAGE in NA and CD seeds. Fig. S3. Density graph of APX isoenzymes detected by Native-PAGE in NA and CD seeds. (DOCX 189 kb)
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Sahu, A.K., Sahu, B., Soni, A. et al. Active oxygen species metabolism in neem (Azadirachta indica) seeds exposed to natural ageing and controlled deterioration. Acta Physiol Plant 39, 197 (2017). https://doi.org/10.1007/s11738-017-2494-6
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DOI: https://doi.org/10.1007/s11738-017-2494-6