Horticulture, Environment, and Biotechnology

, Volume 59, Issue 2, pp 167–177 | Cite as

Silicon application during vegetative propagation affects photosynthetic protein expression in strawberry

  • Yoo Gyeong Park
  • Sowbiya Muneer
  • Soohoon Kim
  • Seung Jae Hwang
  • Byoung Ryong Jeong
Research Report Cultivation Physiology


We examined the effect of source, concentration, and application method of silicon (Si) on the growth, development, and photosynthetic capacity of Fragaria × ananassa ‘Maehyang’ and ‘Seolhyang’. We applied 0, 35, or 70 mg L−1 Si in a potassium silicate (K2SiO3), sodium silicate (Na2SiO3), or calcium silicate (CaSiO3) solution to plants via subirrigational supply or foliar application. Plant height of ‘Maehyang’ was highest with the 70 mg L−1 Si Na2SiO3 foliar application, but it was not significantly different among treatments in ‘Seolhyang’. Crown size was not significantly affected by source, concentration, or application method in both cultivars. Elemental concentrations in the shoot and root of ‘Maehyang’ were the highest in the 35 mg L−1 Si Na2SiO3 treatment for both application methods. Elemental concentrations in the shoot and root of ‘Seolhyang’ were the highest in the 70 mg L−1 Si K2SiO3 foliar application. Photosynthetic proteins abundantly increased in both cultivars with the 35 or 70 mg L−1 Si K2SiO3 treatment, for both application methods. Moreover, two important photosynthetic proteins, viz. PsaA and PsbA, were expressed and their expressions were higher with the 35 or 70 mg L−1 Si K2SiO3 treatment, for both application methods. These results suggested that 35 or 70 mg L−1 Si, supplied in the form of K2SiO3, promoted photosynthetic protein expressions the greatest, regardless of the application method, in both ‘Maehyang’ and ‘Seolhyang’.


Foliar spray Fragaria × ananassa Potassium silicate Si Subirrigation 



This research was supported by Agrobio-Industry Technology Development Program, Ministry of Food, Agriculture, Forestry and Fisheries, Republic of Korea (Project No. 315004-5). Soohoon Kim was supported by a scholarship from the BK21 Plus Program, the Ministry of Education.


  1. Bae MJ, Park YG, Jeong BR (2010) Effect of a silicate fertilizer supplemented to the medium on rooting and subsequent growth of potted plants. Hortic Environ Biotechnol 51:355–359Google Scholar
  2. Bradford MM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72:248–254CrossRefPubMedGoogle Scholar
  3. Chen W, Yao X, Cai K, Chen J (2011) Silicon alleviates drought stress of rice plants by improving plant water status, photosynthesis and mineral nutrient absorption. Biol Trace Elem Res 142:67–76CrossRefPubMedGoogle Scholar
  4. Choi HG, Moon BY, Kang NJ, Kwon JK, Bekhzod K, Park KS, Lee SY (2014) Yield loss and quality degradation of strawberry fruits cultivated under the deficient insolation conditions by shading. Hortic Environ Biotechnol 55:263–270CrossRefGoogle Scholar
  5. Drew MC, Biddulph O (1971) Effect of metabolic inhibitors and temperature on uptake and translocation of 45Ca and 42K by intact been plants. Plant Physiol 48:427–443CrossRefGoogle Scholar
  6. Epstein E (1999) Silicon. Annu Rev Plant Physiol Plant Mol Biol 50:641–664CrossRefPubMedGoogle Scholar
  7. Hattori TC, Shinobu I, Eiichi T, Alexander L, Miroslava L, Yukihiro S (2003) Silicon-induced changes in viscoelastic properties of sorghum root cell walls. Plant Cell Physiol 44:743–749CrossRefPubMedGoogle Scholar
  8. Hwang SJ, Jeong BR, Park HM (2005) Effects of potassium silicate on the growth of miniature rose ‘Pinocchio’ grown on rockwool and its cut flower quality. J Jpn Soc Hortic Sci 74:242–247CrossRefGoogle Scholar
  9. Islam A (1964) The yield and chemical composition of soybeans as affected by three levels of complementary nutrients associated with live levels of phosphorus. Pak J Soil Sci 1:32–47Google Scholar
  10. Islam A, Saha RC (1969) Effect of silicon on the chemical composition of rice plants. Plant Soil 30:446–458CrossRefGoogle Scholar
  11. Jana S, Jeong BR (2013) Silicon: the most under-appreciated element in horticultural crops. Trends Hortic Res 4:1–19Google Scholar
  12. Jeong KJ, Chon YS, Ha SH, Kang HK, Yun JG (2012) Silicon application on standard chrysanthemum alleviates damages induced by disease and aphid insect. Korean J Hortic Sci Technol 30:21–26CrossRefGoogle Scholar
  13. Lee HS, Choi JM, Kim DY, Kim SY (2016a) Influence of application rates of dolomitic lime in the acid substrate on the reduction of bicarbonate injury during vegetative growth of the ‘Seolhyang’ strawberry. Korean J Hortic Sci Technol 34:220–227Google Scholar
  14. Lee HS, Choi JM, Kim TI, Kim HS, Jang WS, Lee HC, Lee IH, Nam MH (2016b) Influence of various acids added to irrigation water on the reduction of bicarbonate injury during vegetative propagation of ‘Seolhyang’ strawberry. Korean J Hortic Sci Technol 34:607–615Google Scholar
  15. Liang YC, Sun WC, Romheld V (2005) Effects of foliar and root-applied silicon on the enhancement of induced resistance to powdery mildew in Cucumis sativus. Plant Pathol 54:678–685CrossRefGoogle Scholar
  16. Ma JF, Takahashi E (1993) Interaction between calcium and silicon in water-cultured rice plants. Plant Soil 148:107–113CrossRefGoogle Scholar
  17. Ma JF, Yamaji N (2006) Silicon uptake and accumulation in higher plants. Trends Plant Sci 11:392–393CrossRefPubMedGoogle Scholar
  18. Mateos-Naranjo E, Andrades-Moreno L, Davy AJ (2013) Silicon alleviates deleterious effects of high salinity on the halophytic grass Spartina densiflora. Plant Physiol Biochem 63:115–121CrossRefPubMedGoogle Scholar
  19. Mattson NS, Leatherwood WR (2010) Potassium silicate drenches increased leaf silicon content and affect morphological traits of several floricultural crops grown in a peat-based substrate. HortScience 45:43–47Google Scholar
  20. Menzies J, Bowen P, Ehret D, Glass ADM (1992) Foliar applications of potassium silicate reduce severity of powdery mildew on cucumber, muskmelon, and zucchini squash. J Am Soc Hortic Sci 117:902–905Google Scholar
  21. Moon HH, Bae MJ, Jeong BR (2008) Effect of silicate supplemented to medium on rooting of cutting and growth of chrysanthemum. Flower Res J 16:93–169Google Scholar
  22. Morgan L (1999) Silica in hydroponics. Pract Hydroponics Greenh 1:51–66Google Scholar
  23. Muneer S, Jeong BR (2015) Silicon decreases Fe deficiency responses by improving photosynthesis and maintaining composition of thylakoid multiprotein complex proteins in soybean plants (Glycine max L.). J Plant Growth Regul 34:485–498CrossRefGoogle Scholar
  24. Muneer S, Ko CH, Wei H, Chen Y, Jeong BR (2016) Physiological and proteomic investigations to study the response of tomato graft unions under temperature stress. PLoS ONE 11:e0157439CrossRefPubMedPubMedCentralGoogle Scholar
  25. Na YW, Jeong HJ, Lee SY, Choi HG, Kim SH, Roh IR (2014) Chlorophyll fluorescence as a diagnostic tool for abiotic stress tolerance in wild and cultivated strawberry species. Hortic Environ Biotechnol 55:280–286CrossRefGoogle Scholar
  26. Park YG, Sivanesan I, Jeong BR (2013) Effect of silicon source and application method on growth and development, and incidence of powdery mildew (Sphaerotheca pannosa var. rosae) in potted Rosa hybrida ‘Apollo’ and ‘Remata’. Flower Res J 21:56–62CrossRefGoogle Scholar
  27. Rodrigues FA, Vale FXR, Komdorfer GH, Prabhu AS, Datnoff LE, Oliveira AMA, Zambolim L (2003) Influence of silicon on sheath blight of rice in Brazil. Crop Prot 22:23–29CrossRefGoogle Scholar
  28. Shi G, Cai Q, Liu C, Wu L (2010) Silicon alleviates cadmium toxicity in peanut plants in relation to cadmium distribution and stimulation of antioxidative enzymes. Plant Growth Regul 61:45–52CrossRefGoogle Scholar
  29. Singh K, Singh R, Singh JP, Singh Y, Singh KK (2006) Effect of level and time of silicon application on growth, yield and its uptake by rice (Oryza sativa). Indian J Agric Sci 76:410–413Google Scholar
  30. Sivanesan I, Son MS, Lim CS, Jeong BR (2011) Effect of soaking of seeds in potassium silicate and uniconazole on germination and seedling growth of tomato cultivars, Seogeon and Seokwang. Afr J Biotechnol 10:6743–6749Google Scholar
  31. Sivanesan I, Son MS, Song JY, Jeong BR (2013a) Silicon supply through the subirrigation system affects growth of three chrysanthemum cultivars. Hortic Environ Biotechnol 57:371–377Google Scholar
  32. Sivanesan I, Son MS, Soundararajan P, Jeong BR (2013b) Growth of chrysanthemum cultivars as affected by silicon source and application method. Korean J Hortic Sci Technol 31:544–551CrossRefGoogle Scholar
  33. Sivanesan I, Son MS, Soundararajan P, Jeong BR (2014) Effect of silicon on growth and temperature stress tolerance of Nephrolepis exaltata ‘Corditas’. Korean J Hortic Sci Technol 32:142–148CrossRefGoogle Scholar
  34. Son MS, Park YG, Sivanesan I, Ko CH, Jeong BR (2015) Silicon supply through subirrigation system alleviates high temperature stress in poinsettia by enhancing photosynthetic rate. Korean J Hortic Sci Technol 33:860–868CrossRefGoogle Scholar
  35. Soundararajan P, Sivanesan I, Jana S, Jeong BR (2014) Influence of silicon supplementation on the growth and tolerance to high temperature in Salvia splendens. Hortic Environ Biotechnol 55:271–279CrossRefGoogle Scholar
  36. Voogt W, Sonneveld C (2001) Silicon in horticultural crops grown in soilless culture. In: Datnoff LE, Snyder GH, Korndorfer GH (eds) Silicon in agriculture. Elsevier, Amsterdam, pp 115–131CrossRefGoogle Scholar
  37. Yamazaki K (1982) Nutrient solution culture. Pak-kyo Co., TokyoGoogle Scholar

Copyright information

© Korean Society for Horticultural Science and Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  • Yoo Gyeong Park
    • 1
  • Sowbiya Muneer
    • 1
  • Soohoon Kim
    • 2
  • Seung Jae Hwang
    • 1
    • 2
    • 3
  • Byoung Ryong Jeong
    • 1
    • 2
    • 3
  1. 1.Institute of Agriculture and Life ScienceGyeongsang National UniversityJinjuSouth Korea
  2. 2.Division of Applied Life Science (BK21 Plus), Graduate SchoolGyeongsang National UniversityJinjuSouth Korea
  3. 3.Research Institute of Life ScienceGyeongsang National UniversityJinjuSouth Korea

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