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Advances in the Concept and Methods of Seed Priming

  • Muhammad Waqas
  • Nicholas Emmanuel Korres
  • Muhammad Daud Khan
  • Abdul-Sattar Nizami
  • Farah Deeba
  • Iftikhar Ali
  • Haziq Hussain
Chapter

Abstract

The critical stages during the growth of crops are the uniform seed germination, early seedling growth, and uniform plant stand. Low crop yield is attributed to uneven seed germination and seedling growth. Therefore, the quality of seed can be improved through priming in addition to the field management techniques for better seed germination. Priming is a physiological technique of seed hydration and drying to enhance the pregerminative metabolic process for rapid germination, seedling growth, and final yield under normal as well as stressed conditions. The primed seeds show faster and uniform seed germination due to different enzyme activation, metabolic activities, biochemical process of cell repair, protein synthesis, and improvement of the antioxidant defense system as compared to unprimed seeds. There are many techniques of seed priming which are broadly divided into conventional methods (hydro-priming, osmo-priming, nutrient priming, chemical priming, bio-priming, and priming with plant growth regulators) and advanced methods (nano-priming and priming with physical agents). However, priming is strongly affected by various factors such as temperature, aeration, light, priming duration, and seed characteristics. This chapter highlights the priming mechanism and the available technologies as a tool for superficial seed germination and crop stand. An experiment with reference to the importance of priming toward vigor seed germination and seedling growth was conducted, and its results have been added in this chapter.

Keywords

Seed priming Germination Antioxidant defense system Metabolic activities Crop growth 

References

  1. Abu-Muriefah SS (2017) Phytohormonal priming improves germination and antioxidant enzymes of soybean (Glycine max) seeds under lead (Pb) stress. Biosci Res 14(1):42–56Google Scholar
  2. Adhikari T, Kundu S, Rao AS (2013) Impact of SiO2 and Mo nano particles on seed germination of rice (Oryza sativa L.). Int J Agric Food Sci Technol 4(8):809–816Google Scholar
  3. Afzal I, Rehman HU, Naveed M, Basra SMA (2016) Recent advances in seed enhancements. In New challenges in seed biology-basic and translational research driving seed technology. InTech, pp 47–74Google Scholar
  4. Ahmad I, Basra SMA, Akram M, Wasaya A, Ansar M, Hussain S, Iqbal A, Hussain SA (2017) Improvement of antioxidant activities and yield of spring maize through seed priming and foliar application of plant growth regulators under heat stress conditions. Semina: Ciências Agrárias 38:47–56Google Scholar
  5. Ahmadvand G, Soleimani F, Saadatian B, Pouya M (2012) Effect of seed priming with potassium nitrate on germination and emergence traits of two soybean cultivars under salinity stress conditions. Am Eurasian J Agric Environ Sci 12:769–774Google Scholar
  6. Ajouri A, Asgedom H, Becker M (2004) Seed priming enhances germination and seedling growth of barley under conditions of P and Zn deficiency. J Plant Nutr Soil Sci 167(5):630–636CrossRefGoogle Scholar
  7. Amos D (2017) Aerated compost tea (ACT) to improve soil biology and to act as a biofertiliser/biofungicide, pp 1–2. http://orgprints.org/31042/. Accessed 2 June 2017
  8. Ansari O, Chogazardi H, Sharifzadeh F, Nazarli H (2012) Seed reserve utilization and seedling growth of treated seeds of mountain rye (Secale montanum) as affected by drought stress. Cercetari Agronomice in Moldova 45(2):43–48CrossRefGoogle Scholar
  9. Araujo SDS, Paparella S, Dondi D, Bentivoglio A, Carbonera D, Balestrazzi A (2016) Physical methods for seed invigoration: advantages and challenges in seed technology. Front Plant Sci 7:646PubMedCentralCrossRefPubMedGoogle Scholar
  10. Arif M, Waqas M, Nawab K, Shahid M (2007) Effect of seed priming in Zn solutions on chickpea and wheat. Afr. Crop Sci Conf Proc 8:237–240Google Scholar
  11. Arif M, Jan MT, Marwat KB, Khan MA (2008) Seed priming improves emergence and yield of soybean. Pak J BotPak J Bot 40(3):1169–1177Google Scholar
  12. Asgedom H, Becker M (2001) Effects of seed priming with nutrient solutions on germination, seedling growth and weed competitiveness of cereals in Eritrea. In: Proceedings of Deutscher Tropentag. University of Bonn & ATSAF, Margraf Pub. Press, Weickersheim, p 282Google Scholar
  13. Assefa MK, Hunje R, Koti RV (2010) Enhancement of seed quality in soybean following priming treatment. Karnataka J Agric Sci 23:787–789Google Scholar
  14. Awan IU, Baloch MS, Sadozai NS, Sulemani MZ (1999) Stimulatory effect of GA3 and IAA on ripening process, kernel development and quality of rice. Pakistan J Biol Sci(Pakistan) 2:410–412CrossRefGoogle Scholar
  15. Bagheri MZ (2014) The effect of maize priming on germination characteristics, catalase and peroxidase enzyme activity and total protein content under salt stress. Int J Biosci 4(2):104–112Google Scholar
  16. Bahrani A, Pourreza J (2012) Gibberellic acid and salicylic acid effects on seed germination and seedlings growth of wheat (Triticum aestivum L.) under salt stress condition. World Appl Sci J 18(5):633–641Google Scholar
  17. Basra SMA, Farooq M, Tabassam R, Ahmad N (2005) Physiological and biochemical aspects of pre-sowing seed treatments in fine rice (Oryza sativa L.). Seed Sci Technol 33(3):623–628CrossRefGoogle Scholar
  18. Baxter A, Mittler R, Suzuki N (2013) ROS as key players in plant stress signalling. J Exp Bot 65(5):1229–1240PubMedCrossRefGoogle Scholar
  19. Benavides-Mendoza A, Ramirez-Rodriguez H, Robledo-Torres V, Hernandez-Davila J, Ramirez-Mezquitic JG, Bacopulos-Te-llez E, Bustamante-Garcia MA (2002) Seed treatment with salicylates modifies stomatal distribution, stomatal density and the tolerance to cold stress in pepper seedlings. In: Proceedings of the 16th international pepper conference (Tampico, Tamaulipas, Mexico (Vol. 2), NovemberGoogle Scholar
  20. Bennett AJ, Whipps JM (2008) Dual application of beneficial microorganisms to seed during drum priming. Appl Soil Ecol 38(1):83–89CrossRefGoogle Scholar
  21. Berrie AMM, Drennan DSH (1971) The effect of hydration-dehydration on seed germination. New Phytol 70(1):135–142CrossRefGoogle Scholar
  22. Bhardwaj J, Anand A, Nagarajan S (2012) Biochemical and biophysical changes associated with magnetopriming in germinating cucumber seeds. Plant Physiol Biochem 57:67–73PubMedCrossRefGoogle Scholar
  23. Bhowmick MK (2013) Seed priming and foliar nutrition towards enhancing Lathyrus productivity under rice-utera system. In: Proceedings of the Centenary Session, 100th Indian Science Congress, Section of Agriculture and Forestry Sciences, 3–7 Jan 2013, Kolkata, West Bengal, India, p 219Google Scholar
  24. Bhowmick M K, Biswas PK, Sen P, Bhattacharyya P (2010) Studies on seed priming, row spacing and foliar nutrition in chickpea under rainfed conditions in West Bengal, India. In: Proceedings of the international seminar on climate change and environmental challenges of 21st century, December, pp 7–9Google Scholar
  25. Bilalis DJ, Katsenios N, Efthimiadou A, Karkanis A, Efthimiadis P (2012) Investigation of pulsed electromagnetic field as a novel organic pre-sowing method on germination and initial growth stages of cotton. Electromagn Biol Med 31(2):143–150PubMedCrossRefPubMedCentralGoogle Scholar
  26. Bradford KJ (1986) Manipulation of seed water relations via osmotic priming to improve germination under stress conditions. HortScience (USA)Google Scholar
  27. Bradford KJ (1995) Water relations in seed germination. Seed Dev Germination 1(13):351–396Google Scholar
  28. Brinton W, Storms P, Evans E, Hill J (2004) Compost teas: microbial hygiene and quality in relation to method of preparation. Biodynamics. 249:36–45Google Scholar
  29. Bujalski W, Nienow AW (1991) Large-scale osmotic priming of onion seeds: a comparison of different strategies for oxygenation. Sci Hortic 46(1–2):13–24CrossRefGoogle Scholar
  30. Bujalski W, Nienow AW, Gray D (1989) Establishing the large scale osmotic priming of onion seeds by using enriched air. Ann Appl Biol 115(1):171–176CrossRefGoogle Scholar
  31. Cakmak I (2005) The role of potassium in alleviating detrimental effects of abiotic stresses in plants. J Plant Nutr Soil Sci 168(4):521–530CrossRefGoogle Scholar
  32. Callan NW, Mathre D, Miller JB (1990) Bio-priming seed treatment for biological control of Pythium ultimum pre-emergence damping-off in sh-2 sweet corn. Plant Dis 74:368–372CrossRefGoogle Scholar
  33. Cantliffe DJ (1987) Priming of lettuce for early and uniform emergence under conditions of environmental stress. Acta Hortic 122:29–38Google Scholar
  34. Cantliffe DJ (2003) Seed enhancements. Acta Hortic 607:53–59CrossRefGoogle Scholar
  35. Capron I, Corbineau F, Dacher F, Job C, Côme D, Job D (2000) Sugar beet seed priming: effects of priming conditions on germination, solubilization of 11-S globulin and accumulation of LEA proteins. Seed Sci Res 10(3):243–254CrossRefGoogle Scholar
  36. Chakraborthy GS, Aeri V, Verma P, Singh S (2014) Phytochemical and antimicrobial studies of Chlorophytum borivilianum. Pharmacophore 5:258–261Google Scholar
  37. Chen K, Fessehaie A, Arora R (2012) Dehydrin metabolism is altered during seed osmopriming and subsequent germination under chilling and desiccation in Spinaciaoleracea L. cv. Bloomsdale: possible role in stress tolerance. Plant Sci 183:27–36PubMedPubMedCentralCrossRefGoogle Scholar
  38. Côme D, Thévenot C (1982) Environmental control of embryo dormancy and germination. In: The physiology and biochemistry of seed development, dormancy and germination, pp 271–298Google Scholar
  39. Corbineau F, Côme D (2006) Priming: a technique for improving seed quality. Seed testing international. ISTA News Bulletin No 132:38–40Google Scholar
  40. Darwin C (1855) Effect of salt-water on the germination of seeds. Gardeners Chron Agric Gaz 47:773Google Scholar
  41. Dawood MG (2018) Stimulating plant tolerance against abiotic stress through seed priming. In: Advances in seed priming. Springer, Singapore, pp 147–183CrossRefGoogle Scholar
  42. Dawood MG, El-Awadi ME, El-Rokiek KG (2012) Physiological impact of fenugreek, guava and lantana on the growth and some chemical parameters of sunflower plants and associated weeds. J Ame Sci 8(6):166–174Google Scholar
  43. Demir I, Ozuaydın I, Yasar F, Van Staden J (2012) Effect of smoke-derived butenolide priming treatment on pepper and salvia seeds in relation to transplant quality and catalase activity. S Afr J Bot 78:83–87CrossRefGoogle Scholar
  44. Dey S, Pramanik K, Mukherjee S, Poddar S, Barik K (2014) Effect of seed priming and straw mulching on growth and productivity of chickpea (Cicer arietinum L.) under rainfed condition. SATSA Mukhaptra Annu Tech Issue 18:126–131Google Scholar
  45. Di Girolamo G, Barbanti L (2012) Treatment conditions and biochemical processes influencing seed priming effectiveness. Ital J Agron 7(2):25CrossRefGoogle Scholar
  46. Diver S (2002) Notes on compost teas: a supplement to the ATTRA publication: compost teas for plant disease control. Appropriate Technology Transfer for Rural Areas (ATTRA), National Sustainable Agriculture Information Service, AR. (National Center for Appropriate Technology, Montana). Retrieved March, 5, 2012Google Scholar
  47. Dubrovsky JG (1996) Seed hydration memory in Sonoran Desert cacti and its ecological implication. Am J Bot 83(5):624–632CrossRefGoogle Scholar
  48. Dutta P (2018) Seed priming: new vistas and contemporary perspectives. In: Advances in seed priming. Springer, Singapore, pp 3–22CrossRefGoogle Scholar
  49. Ells JE (1963) The influence of treating tomato seed with nutrient solutions on emergence rate and seedling growth. In Proc Amer Soc Hort Sci 83:684–687Google Scholar
  50. Evenari M (1984) Seed physiology: its history from antiquity to the beginning of the 20th century. Bot Rev 50(2):119–142CrossRefGoogle Scholar
  51. Farahbakhsh H (2012) Germination and seedling growth in un-primed and primed seeds of Fenel as affected by reduced water potential induced by NaCl. Int Res J Appl Basic Sci 3(4):737–744Google Scholar
  52. Farooq M, Basra SM, Rehman H, Mehmood T (2006) Germination and early seedling growth as affected by pre-sowing ethanol seed treatments in fine rice. Int J Agric BiolInt J Agric Biol 8:19–22Google Scholar
  53. Farooq M, Basra SMA, Rehman H, Saleem BA (2008) Seed priming enhances the performance of late sown wheat (Triticum aestivum L.) by improving chilling tolerance. J Agron Crop Sci 194(1):55–60CrossRefGoogle Scholar
  54. Farooq M, Wahid A, Lee DJ (2009) Exogenously applied polyamines increase drought tolerance of rice by improving leaf water status, photosynthesis and membrane properties. Acta Physiol Plant 31(5):937–945CrossRefGoogle Scholar
  55. Farooq M, Basra SM, Wahid A, Ahmad N (2010) Changes in nutrient-homeostasis and reserves metabolism during rice seed priming: consequences for seedling emergence and growth. Agric Sci China 9(2):191–198CrossRefGoogle Scholar
  56. Fedoroff NV, Battisti DS, Beachy RN, Cooper PJ, Fischhoff DA, Hodges CN et al (2010) Radically rethinking agriculture for the 21st century. Science 327(5967):833–834PubMedPubMedCentralCrossRefGoogle Scholar
  57. Finch-Savage WE, Gray D, Dickson GM (1991) The combined effects of osmotic priming with plant growth regulator and fungicide soaks on the seed quality of five bedding plant species. Seed Sci Technol 19(2):495–503Google Scholar
  58. Fraceto LF, Grillo R, de Medeiros GA, Scognamiglio V, Rea G, Bartolucci C (2016) Nanotechnology in agriculture: which innovation potential does it have? Front Environ Sci 4:20CrossRefGoogle Scholar
  59. Gaius PS (1949) Naturalishistoria, vol. IV–VII, Books 12–27 (trans: Rackham H, Jones WHS, Eichholz DE). Harvard University Press, Massachussets and William Heinemann, LondonGoogle Scholar
  60. Ghafari H, Razmjoo J (2013) Effect of foliar application of nano-iron oxidase, iron chelate and iron sulphate rates on yield and quality of wheat. Int JAgron Plant Prod 4(11):2997–3003Google Scholar
  61. Guan YJ, Hu J, Wang XJ, Shao CX (2009) Seed priming with chitosan improves maize germination and seedling growth in relation to physiological changes under low temperature stress. J Zhejiang Univ Sci B 10(6):427–433PubMedPubMedCentralCrossRefGoogle Scholar
  62. Halmer P (2004) Methods to improve seed performance in the field. In: Handbook of seed physiology, pp 125–65Google Scholar
  63. Harris D (2006) Development and testing of “on-farm” seed priming. Adv Agron 90:129–178CrossRefGoogle Scholar
  64. Harris D, Rashid A, Miraj G, Arif M, Yunas M (2008) ‘On-farm’seed priming with zinc in chickpea and wheat in Pakistan. Plant Soil 306(1–2):3–10CrossRefGoogle Scholar
  65. Heydecker W, Coolbear P (1977) Seed treatments for improved performance-survey and attempted prognosis. Seed Sci Technol 5:353–425Google Scholar
  66. Heydecker W, Gibbins BM (1977) The‘priming’of seeds. In: Symposium on seed problems in horticulture, vol 83, pp 213–224Google Scholar
  67. Heydecker W, Higgins J, Gulliver RL (1973) Accelerated germination by osmotic seed treatment. Nature 246(5427):42CrossRefGoogle Scholar
  68. Hill H, Bradford KJ, Cunningham J, Taylor AG (2008) Primed lettuce seeds exhibit increased sensitivity to moisture during aging. Acta Hortic 782:135–141CrossRefGoogle Scholar
  69. Ilyas S (2006) Seed treatments using matriconditioning to improve vegetable seed quality. J Agronomi Indonesia 34(2)Google Scholar
  70. Jaleel CA, Gopi R, Manivannan P, Panneerselvam R (2007) Responses of antioxidant defense system of Catharanthus roseus (L.) G. Don. Topaclobutrazol treatment under salinity. Acta Physiol Plant 29(3):205–209CrossRefGoogle Scholar
  71. Jett LW, Welbaum GE, Morse RD (1996) Effects of matric and osmotic priming treatments on broccoli seed germination. J Am Soc Hortic Sci 121(3):423–429CrossRefGoogle Scholar
  72. Jisha KC, Vijayakumari K, Puthur JT (2013) Seed priming for abiotic stress tolerance: an overview. Acta Physiol Plant 35(5):1381–1396CrossRefGoogle Scholar
  73. Kaur S, Gupta AK, Kaur N (2002) Effect of osmo-and hydropriming of chickpea seeds on seedling growth and carbohydrate metabolism under water deficit stress. Plant Growth Regul 37(1):17–22CrossRefGoogle Scholar
  74. Kester ST, Geneve RL, Houtz RL (1997) Priming and accelerated ageing affect L-isoaspartyl methyltransferase activity in tomato (Lycopersicon esculentum Mill.) seed. J Exp Bot 48(4):943–949CrossRefGoogle Scholar
  75. Khaliq A, Aslam F, Matloob A, Hussain S, Geng M, Wahid A, ur Rehman H (2015) Seed priming with selenium: consequences for emergence, seedling growth, and biochemical attributes of rice. Biol Trace Elem Res 166(2):236–244PubMedCrossRefGoogle Scholar
  76. Khan A, Khalil SK, Khan AZ, Marwat KB, Afzal A (2008) The role of seed priming in semi-arid area for mung bean phenology and yield. Pak J Bot 40(6):2471–2480Google Scholar
  77. Kibinza S, Bazin J, Bailly C, Farrant JM, Corbineau F, El-Maarouf-Bouteau H (2011) Catalase is a key enzyme in seed recovery from ageing during priming. Plant Sci 181(3):309–315PubMedCrossRefGoogle Scholar
  78. Kim MJ, Shim CK, Kim YK, Hong SJ, Park JH, Han EJ, Kim JH, Kim SC (2015) Effect of aerated compost tea on the growth promotion of lettuce, soybean, and sweet corn in organic cultivation. Plant Pathol J 31(3):259–268PubMedPubMedCentralCrossRefGoogle Scholar
  79. Koehler DE (1967) Thesis. Purdue University, USAGoogle Scholar
  80. Korkmaz A, Korkmaz Y (2009) Promotion by 5-aminolevulenic acid of pepper seed germination and seedling emergence under low-temperature stress. Sci Hortic 119(2):98–102CrossRefGoogle Scholar
  81. Kumar S, Arya MC, Sinfh R (2010) Management of sweet pepper diseases and growth promotion by Pseudomonas fluorescens and Trichoderma harzianum in mid hills of Central Himalayas, India. Indian Phytopathol 63(2):181–186Google Scholar
  82. Lara TS, Lira JMS, Rodrigues AC, Rakocevic M, Alvarenga AA (2014) Potassium nitrate priming affects the activity of nitrate reductase and antioxidant enzymes in tomato germination. J Agric Sci 6(2):72Google Scholar
  83. MacDonald H (1997) Auxin perception and signal transduction. Physiol Plant 100:423–430CrossRefGoogle Scholar
  84. Mahajan G, Sarlach RS, Japinder S, Gill MS (2011) Seed priming effects on germination, growth and yield of dry direct-seeded rice. J Crop Improv 25(4):409–417CrossRefGoogle Scholar
  85. Marschner H (1995) Mineral nutrition of higher plants, 2nd edn. Academic, San Diego. Mineral nutrition of high plant. Academic Press, pp: 330–355Google Scholar
  86. Mavi K (2014) Use of extract from dry marigold (Tagatesspp.) flowers to prime eggplant (Solanum melongenaL.) seeds. Acta Sci Pol-Hortorumcultus 13:3–12Google Scholar
  87. Mavi K (2016) The effect of organic priming with Marigold herbal tea on seeds quality in Aji pepper (Capsicum baccatum var. pendulum Willd.). Mustafa Kemal Üniversitesi Ziraat Fakültesi Dergisi 21(1):31–39Google Scholar
  88. May LH, Milthorpe EJ, Milthorpe FL (1962) Pre-sowing hardening of plants to drought. In: Field crop abstracts, vol 15, pp 93–98Google Scholar
  89. McDonald MB (2000) Seed priming. In: Black M, Bewley JD (eds) Seed technology and its biological basis. Sheffield Academic Press, Sheffield, pp 287–325Google Scholar
  90. Mengesha WK, Powell SM, Evans KJ, Barry KM (2017) Diverse microbial communities in non-aerated compost teas suppress bacterial wilt. World J Microbiol Biotechnol 33(3):49–55PubMedCrossRefGoogle Scholar
  91. Miransari M, Smith DL (2014) Plant hormones and seed germination. Environ Exp Bot 99:110–121CrossRefGoogle Scholar
  92. Mirshekari B, Baser S, Allahyari S, Hamedanlu N (2012) On-farm seed priming with Zn+ Mn is an effective way to improve germination and yield of marigold. Afr J Microbiol Res 6(28):5796–5800Google Scholar
  93. Mohd Din ARJ, Cheng KK, Sarmidi MR (2017) Assessment of compost extract on yield and phytochemical contents of Pak Choi (Brassica Rapa cv. Chinensis) grown under different fertilizer strategies. Commun Soil Sci Plant Anal 48(3):274–284CrossRefGoogle Scholar
  94. Moradi A, Younesi O (2009) Effects of osmo-and hydro-priming on seed parameters of grain sorghum (Sorghum bicolor L.). Aust J Basic Appl Sci 3(3):1696–1700Google Scholar
  95. Naeem M, Bhatti IRAM, Ahmad RH, Ashraf MY (2004) Effect of some growth hormones (GA3, IAA and kinetin) on the morphology and early or delayed initiation of bud of lentil (Lens culinaris Medik). Pak J Bot 36(4):801–809Google Scholar
  96. Narwal SS (1994) Allelopathy in crop production. Scientific Publishers, Jodhpur, p 288Google Scholar
  97. Nayban G, Mandal AK, De BK (2017) Seed priming: a low-cost climate-resilient tool for improving germination, growth and productivity of mungbean. SATSA Mukhaptra Annu Tech Issue 21:162–172Google Scholar
  98. Niinemets Ü (2009) Mild versus severe stress and BVOCs: thresholds, priming and consequences. Trends Plant Sci 15(3):145–153PubMedCrossRefGoogle Scholar
  99. O’Sullivan JOHN, Bouw WJ (1984) Pepper seed treatment for low-temperature germination. Can J Plant Sci 64(2):387–393CrossRefGoogle Scholar
  100. Ozbay N, Susluoglu Z (2016) Assessment of growth regulator prohexadione calcium as priming agent for germination enhancement of pepper at low temperature. JAPS: J Anim Plant Sci 26(6):1652–1658Google Scholar
  101. Pame AR, Kreye C, Johnson D, Heuer S, Becker M (2015) Effects of genotype, seed P concentration and seed priming on seedling vigor of rice. Exp Agric 51(03):370–381CrossRefGoogle Scholar
  102. Passam HC, Karavites PI, Papandreou AA, Thanos CA, Georghiou K (1989) Osmo-conditioning of seeds in relation to growth and fruit yield of aubergine, pepper, cucumber and melon in unheated greenhouse cultivation. Sci Hortic 38(3–4):207–216CrossRefGoogle Scholar
  103. Patanè C, Cavallaro V, D’Agosta G, Cosentino SL (2008) Plant emergence of PEG-osmoprimed seeds under suboptimal temperatures in two cultivars of sweet sorghum differing in seed tannin content. J Agron Crop Sci 194(4):304–309CrossRefGoogle Scholar
  104. Pereira MD, Dias DCFDS, Dias LADS, Araújo EF (2009) Primed carrot seeds performance under water and temperature stress. Sci Agric 66(2):174–179CrossRefGoogle Scholar
  105. Pill WG (1995) Low water potential and presowing germination treatments to improve seed quality. In: Seed quality, pp 319–359Google Scholar
  106. Pozo MJ, Azcón-Aguilar C (2007) Unraveling mycorrhiza-induced resistance. Curr Opin Plant Biol 10(4):393–398PubMedCrossRefPubMedCentralGoogle Scholar
  107. Prabha D, Negi S, Kumari P, Negi YK, Chauhan JS (2016) Effect of seed priming with some plant leaf extract on seedling growth characteristics and root rot disease in tomato. Int J Agric Syst 4(1):46–51Google Scholar
  108. Prasad TNVKV, Sudhakar P, Sreenivasulu Y, Latha P, Munaswamy V, Reddy KR et al (2012) Effect of nanoscale zinc oxide particles on the germination, growth and yield of peanut. J Plant Nutr 35(6):905–927CrossRefGoogle Scholar
  109. Qi W, Zhang L, Wang L, Xu H, Jin Q, Jiao Z (2015) Pretreatment with low-dose gamma irradiation enhances tolerance to the stress of cadmium and lead in Arabidopsis thaliana seedlings. Ecotoxicol Environ Saf 115:243–249PubMedCrossRefPubMedCentralGoogle Scholar
  110. Raj SN, Shetty NP, Shetty HS (2004) Seed bio-priming with Pseudomonas fluorescens isolates enhances growth of pearl millet plants and induces resistance against downy mildew. Int J Pest Manag 50(1):41–48CrossRefGoogle Scholar
  111. Rakshit A, Pal S, Rai S, Rai A, Bhowmick MK, Singh HB (2013) Micronutrient seed priming: a potential tool in integrated nutrient management. SATSA Mukhaptra Annu Tech Issue 17:77–89Google Scholar
  112. Rakshit A, Sunita K, Pal S, Singh A, Singh HB (2015) Bio-priming mediated nutrient use efficiency of crop species. In: Nutrient use efficiency: from basics to advances. Springer, New Delhi, pp 181–191CrossRefGoogle Scholar
  113. Rangaswamy A, Purushothaman S, Devasenapathy P (1993) Seed hardening in relation to seedling quality characters of crops. Madras Agric J 80(9):535–537Google Scholar
  114. Raphael E (2012) Phytochemical constituents of some leaves extract of Aloe vera and Azadirachta indica plant species. Glob Adv Res J Environ Sci Toxicol 1(2):014–017Google Scholar
  115. Reddy PP (2012) Bio-priming of seeds. In: Recent advances in crop protection. Springer, New Delhi, pp 83–90CrossRefGoogle Scholar
  116. Reddy MVB, Arul J, Angers P, Couture L (1999) Chitosan treatment of wheat seeds induces resistance to Fusarium graminearum and improves seeds quality. J Agric Food Chem 47:67–72CrossRefGoogle Scholar
  117. Rehman H, Nawaz Q, Basra SMA, Afzal I, Yasmeen A (2014) Seed priming influence on early crop growth, phenological development and yield performance of linola (Linum usitatissimum L.). J Integr Agric 13(5):990–996CrossRefGoogle Scholar
  118. Renugadevi J, Vijayageetha V (2006) Organic seed fortification in cluster bean (Cyamopsistetra gonoloba L.) TAUB. In: International conference on indigenous vegetables and legumes. Prospectus for fighting poverty, hunger and malnutrition, vol 752, December, pp 335–337)Google Scholar
  119. Rowse HR (1991) Methods of priming seeds. UK Patent, 2(192), 781Google Scholar
  120. Ruan SL, Xue QZ (2002) Effects of chitosan coating on seed germination and salt-tolerance of seedlings in hybrid rice (Oryza sativa L.). Acta Agron Sin 28:803–808Google Scholar
  121. Sajedi NA, Ardakani MR, Madani H, Naderi A, Miransari M (2011) The effects of selenium and other micronutrients on the antioxidant activities and yield of corn (Zea mays L.) under drought stress. Physiol Mol Biol Plants 17(3):215–222PubMedPubMedCentralCrossRefGoogle Scholar
  122. Salehi M, Tamaskani F (2008) Pretreatment effect of nanosilver on germination and seedling growth of wheat under salt stress. In: Proceeding of 11th Iranian congress in seed sciences and echnology. Gorgan, IranGoogle Scholar
  123. Satish S, Mohana DC, Ranhavendra MP, Raveesha KA (2007) Antifungal activity of some plant extracts against important seed borne pathogens of Aspergillus sp. Int J Agric Technol 3(1):109–119Google Scholar
  124. Scheuerell SJ, Mahaffee WF (2006) Variability associated with suppression of graymold (Botrytis cinerea) on geranium by foliar applications of nonaerated and aerated compost teas. Plant Dis 90:1201–1208PubMedCrossRefGoogle Scholar
  125. Schwember AR, Bradford KJ (2005) Drying rates following priming affect temperature sensitivity of germination and longevity of lettuce seeds. Hort Sci 40(3):778–781CrossRefGoogle Scholar
  126. Shahrokhi M, Tehranifar A, Hadizadeh H, Selahvarzi Y (2011) Effect of drought stress and paclobutrazol-treated seeds on physiological response of Festuca arundinacea L. Master and Lolium perenne L. Barrage. J Biol Environ Sci 5(14):77–85Google Scholar
  127. Shao CX, Hu J, Song WJ, Hu WM (2005) Effects of seed priming with chitosan solutions of different acidity on seed germination and physiological characteristics of maize seedling. J Zhejiang Univ (Agric Life Sci) 31(6):705–708Google Scholar
  128. Shivay YS, Singh U, Prasad R, Kaur R (2016) Agronomic interventions for micronutrient biofortification of pulses. Indian J Agron 61(4th IAC Special Issue):161–172Google Scholar
  129. Singh MV (2007) Efficiency of seed treatment for ameliorating zinc deficiency in crops. Zinc Crops 24–26Google Scholar
  130. Singh A, Dahiru R, Musa M, Sani Haliru B (2014) Effect of Osmopriming duration on germination, emergence, and early growth of Cowpea (Vigna unguiculata (L.) Walp.) in the Sudan Savanna of Nigeria. Int J Agron 2014:1–4Google Scholar
  131. Singh H, Jassal RK, Kang JS, Sandhu SS, Kang H, Grewal K (2015a) Seed priming techniques in field crops-a review. Agric Rev 36(4):251–264Google Scholar
  132. Singh U, Praharaj CS, Shivay YS, Kumar L, Singh SS (2015b) Ferti-fortification: an agronomic approach for micronutrient enrichment of pulses. In Pulses: challenges and opportunities under changing climatic scenario, In: Proceedings of the national conference on “Pulses: challenges and opportunities under changing climatic scenario, vol. 29, pp 208–222Google Scholar
  133. Slaton NA, Wilson CE, Ntamatungiro S, Norman RJ, Boothe DL (2001) Evaluation of zinc seed treatments for rice. Agron J 93(1):152–157CrossRefGoogle Scholar
  134. Sliwinska E, Jendrzejczak E (2002) Sugar-beet seed quality and DNA synthesis in the embryo in relation to hydration-dehydration cycles. Seed Sci Technol 30(3):597–608Google Scholar
  135. Srivastava AK, Bose B (2012) Effect of nitrate seed priming on phenology, growth rate and yield attributes in rice (Oryza sativa L.). Vegetos Int J Plant Res 25(2):174–181Google Scholar
  136. Steel RGD, Torrie JH, Dickey D (1997) Principles and procedures of statistics: a biometrical approach, 3rd edn. McGraw Hill Book Company, New York, pp 172–177Google Scholar
  137. Sung JM, Chiu KY (1995) Hydration effect on seedling emergence strength of watermelon seeds differing in ploidy. Plant Sci 110(1):21–26CrossRefGoogle Scholar
  138. Tavili A, Zare S, Enayati A (2009) Hydropriming, ascorbic and salicylic acid influence on germination of Agropyro nelongatum host. Seeds under salt stress. Res J Seed Sci 2(1):16–22CrossRefGoogle Scholar
  139. Taylor AG, Allen PS, Bennett MA, Bradford KJ, Burris JS, Misra MK (1998) Seed enhancements. Seed Sci Res 8(2):245–256CrossRefGoogle Scholar
  140. Thakur P, Kumar S, Malik JA, Berger JD, Nayyar H (2010) Cold stress effects on reproductive development in grain crops: an overview. Environ Exp Bot 67(3):429–443CrossRefGoogle Scholar
  141. Tonelli ML, Furlan A, Taurian T, Castro S, Fabra A (2011) Peanut priming induced by biocontrol agents. Physiol Mol Plant Pathol 75(3):100–105CrossRefGoogle Scholar
  142. Uchida A, Jagendorf AT, Hibino T, Takabe T, Takabe T (2002) Effects of hydrogen peroxide and nitric oxide on both salt and heat stress tolerance in rice. Plant Sci 163(3):515–523CrossRefGoogle Scholar
  143. Umair A, Ali S, Hayat R, Ansar M, Tareen MJ (2011) Evaluation of seed priming in mung bean (Vigna radiata) for yield, nodulation and biological nitrogen fixation under rainfed conditions. Afr J Biotechnol 10(79):18122–18129Google Scholar
  144. Umair A, Ali S, Sarwar M, Bashir K, Tareen MJ, Malik MA (2013) Assessment of some priming techniques in mungbean (Vigna radiata): a green house study. Pak J Agric Res 26:4Google Scholar
  145. Upadhyaya H, Begum L, Dey B, Nath PK, Panda SK (2017) Impact of calcium phosphate nanoparticles on rice plant. J Plant Sci Phytopathol 1:1–10CrossRefGoogle Scholar
  146. Van Hulten M, Pelser M, Van Loon LC, Pieterse CM, Ton J (2006) Costs and benefits of priming for defense in Arabidopsis. Proc Natl Acad Sci 103(14):5602–5607PubMedCrossRefGoogle Scholar
  147. Varier A, Vari AK, Dadlani M (2010) The subcellular basis of seed priming. Curr Sci 99:450–456Google Scholar
  148. Wahid A, Noreen A, Basra SM, Gelani S, Farooq M (2008) Priming-induced metabolic changes in sunflower (Helianthus annuus) achenes improve germination and seedling growth. Bot Stud 49(4):343–350Google Scholar
  149. Waqas M, Nizami AS, Aburiazaiza AS, Barakat MA, Ismail IMI, Rashid MI (2017) Optimization of food waste compost with the use of biochar. J Environ Manag.  https://doi.org/10.1016/j.jenvman.2017.06.015PubMedCrossRefGoogle Scholar
  150. Warren JE, Bennett MA (1997) Seed hydration using the drum priming system. Hort Sci 32(7):1220–1221CrossRefGoogle Scholar
  151. Weltzien HC (1991) Biocontrol of foliar fungal disease with compost extracts. In: Andrews JH, Hirano SS (eds) Microbial ecology of leaves. Springer-Verlag, New York, pp 430–450CrossRefGoogle Scholar
  152. Wright B, Rowse H, Whipps JM (2003) Microbial population dynamics on seeds during drum and steeping priming. Plant Soil 255(2):631–640CrossRefGoogle Scholar
  153. Xu S, Hu J, Li Y, Ma W, Zheng Y, Zhu S (2011) Chilling tolerance in Nicotiana tabacum induced by seed priming with putrescine. Plant Growth Regul 63(3):279–290CrossRefGoogle Scholar
  154. Yadav PV, Kumari M, Ahmed Z (2011) Seed priming mediated germination improvement and tolerance to subsequent exposure to cold and salt stress in capsicum. Res J Seed Sci 4(3):125–136CrossRefGoogle Scholar
  155. Yan M (2015) Seed priming stimulate germination and early seedling growth of Chinese cabbage under drought stress. S Afr J Bot 99:88–92CrossRefGoogle Scholar
  156. Yogananda DK, Vyakarnahal BS, Shekhargouda M (2004) Effect of seed invigoration with growth regulations and micronutrients on germination and seedling vigour of bell pepper cv. California Wonder. Karnataka J Agri Sci 17(4):811–813Google Scholar
  157. Zhou ZS, Guo K, Elbaz AA, Yang ZM (2009) Salicylic acid alleviates mercury toxicity by preventing oxidative stress in roots of Medicago sativa. Environ Exp Bot 65(1):27–34CrossRefGoogle Scholar
  158. Zhou J, Wang Y, Jahufer Z (2013) Location and chemical composition of semi-permeable layer of forage seeds. Bangladesh J Bot 42(1):23–30CrossRefGoogle Scholar

Copyright information

© Springer Nature Singapore Pte Ltd. 2019

Authors and Affiliations

  • Muhammad Waqas
    • 1
  • Nicholas Emmanuel Korres
    • 2
  • Muhammad Daud Khan
    • 3
  • Abdul-Sattar Nizami
    • 4
  • Farah Deeba
    • 3
  • Iftikhar Ali
    • 5
  • Haziq Hussain
    • 3
  1. 1.Department of Botanical and Environmental SciencesKohat University of Science and TechnologyKohatPakistan
  2. 2.Department of Crop, Soil, and Environmental SciencesUniversity of ArkansasFayettevilleUSA
  3. 3.Department of Biotechnology and Genetic EngineeringKohat University of Science and TechnologyKohatPakistan
  4. 4.Center of Excellence in Environmental Studies (CEES)King Abdulaziz UniversityJeddahSaudi Arabia
  5. 5.Institute of Soil and Environmental SciencesGomal UniversityDera Ismael KhanPakistan

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