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2019 Vol.37, Issue 3 Preview Page

Research Article

Development of a Functional Plug Tray for Producing High-Quality Strawberry Transplants
Nepo Ndikumana Jean 1
Young Hun Lee1
Young Rog Yeoung1*
1Department of Plant Science, Gangneung-Wonju National University
* Corresponding Author
30 June 2019. pp. 345-353
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Abstract

This study was conducted to develop functional plug trays capable of optimizing the root growth environment and inducing early flowering in strawberry plants. Experimental treatments included trays with no drainage slit, two drainage slits, four drainage slits, and a control bottom drainage hole or commercial tray. The effect of the functional plug trays was studied on two strawberry (Fragaria × ananassa Duch.) cultivars (‘Seolhyang’ and ‘Maehyang’) and two different rooting media (commercial medium and peat moss wrapped in a paper pot). The experimental units were arranged in a completely randomized design, with five and four replications for nursery and post-transplanting studies, respectively. Shoot and root growth characteristics and rhizosphere temperature were measured in the nursery study and flowering and yield in the post-transplanting study. Growth parameter results showed that compared to the existing plug trays, the new trays with two and four slits produced transplants of significantly higher quality. These treatments induced lower root temperature in rooting media and plants generally flowered earlier, thus providing higher early and total yields regardless of the media or cultivars used. This effect was further enhanced as the number of drainage holes increased. Thus, an increase in the number of drainage slits in plug trays can lead to higher-quality transplants that can flower and produce fruits earlier than those with poor drainage.

Keywords
containers
drainage hole
flower initiation
root development
strawberry seedlings
References
1
Bowling BL (2000) The berry grower's companion. Timber Press Portland, OR, USA
2
Cocco C, Andriolo JL, Cardoso FL, Erpen L, Schmitt OJ (2011) Crown size and transplant type on the strawberry yield. Sci Agric (Piracicaba, Braz.) 68:489-493. doi:10.1590/S0103-90162011000400015
10.1590/S0103-90162011000400015
3
Ganmore-Neumann R, Kafkafi U (1985) The effect of root temperature and nitrate/ammonium ratio on strawberry plants. II. Nitrogen uptake, mineral ions, and carboxylate concentrations. Agron J 77:835-840. doi:10.2134/agronj1985.00021962007700060003x
10.2134/agronj1985.00021962007700060003x
4
Guttridge CG (1985) Fragaria ×ananassa. In AH Halevy, ed, The CRC Handbook of Flowering. Vol 3. CRC Press, Boca Raton, FL, USA, pp 16-33
5
He J, Chua NYA, Qin L (2008) Interaction between iron stress and root-zone temperature on physiological aspects of aeroponically grown Chinese broccoli. J Plant Nutr 31:173-192. doi:10.1080/01904160701742121
10.1080/01904160701742121
6
Heuver A, Lumis G (ed.) (2017) The Canadian Standard for Nursery Stock. Milton, Canda. https://cnla.ca/uploads/pdf/Canadian-Nursery- Stock-Standard-9th-ed-web.pdf accessed 30 May 2018
7
Hochmuth G, Cantliffe D, Chandler C, Stanley C, Bish E, Waldo E, Duval J (2006) Containerized strawberry transplants reduce establishment-period water use and enhance early growth and flowering compared with bare-root plants. HortTechnology 16:46-54. doi:10.21273/horttech.16.1.0046
10.21273/HORTTECH.16.1.0046
8
Huang BK, Ai F (1992) Air-pruned transplant production system for fully automated transplanting. Acta Hortic 319:523-528. doi: 10.17660/ActaHortic.1992.319.82
10.17660/ActaHortic.1992.319.82
9
Iwasaki Y (2008) Root zone aeration improves growth and yields of coir-cultured strawberry (Fragaria ananassa duch.) During summer. Acta Hortic 779:251-254. doi:10.17660/ActaHortic.2008.779.30
10.17660/ActaHortic.2008.779.30
10
Judd L, Jackson B, Fonteno W (2015) Advancements in root growth measurement technologies and observation capabilities for container-grown plants. Plants 4:369-392. doi:10.3390/plants4030369
10.3390/plants403036927135334PMC4844396
11
Landis TD, Service USF (1990) The container tree nursery manual. U.S. Department of Agriculture, Forest Service. https://books.google. co.kr/books?id=Kg4UAAAAYAAJ Accessed 20 June 2018
12
Malcolm P, Holford P, McGlasson B, Conroy J (2006) Root zone temperature influences growth, partitioning, leaf morphology and physiology of the peach rootstock, green leaf nemaguard. Aust J Exp Agric 46:689-696. doi:10.1071/EA05006
10.1071/EA05006
13
Massetani F, Gangatharan R, Neri D (2011) Plant architecture of strawberry in relation to abiotic stress, nutrient application and type of propagation system. Genes Genomes Genomics 2011;5:12-23
14
Moon JH, Kang YK, Suh HD (2007) Effect of root-zone cooling on the growth and yield of cucumber at supraoptimal air temperature. Acta Hortic 761:271-274. doi:10.17660/ActaHortic.2007.761.36
10.17660/ActaHortic.2007.761.36
15
Park SW, Kwack Y, Chun C (2018) Growth and propagation rate of strawberry transplants produced in a plant factory with artificial lighting as affected by separation time from stock plants. Hortic Environ Biotechnol 59:199-204. doi:10.1007/s13580-018-0027
10.1007/s13580-018-0027-x
16
Pregitzer KS, King JS (2005) Effects of soil temperature on nutrient uptake. In H BassiriRad ed, Nutrient acquisition by plants: an ecological perspective, vol. 181. Springer, Heidelberg, Germany. pp 277-310. doi:10.1007/3-540-27675-0
10.1007/3-540-27675-0
17
Robbins JA, Evans MR (2011) Growing Media for Container Production in a Greenhouse Or Nursery: Components and mixes. Cooperative Extension Service, University of Arkansas, USA
18
Sakamoto M, Uenishi M, Miyamoto K, Suzuki T (2016) Effect of root-zone temperature on the growth and fruit quality of hydroponically grown strawberry plants. J Agric Sci 8:1916-9760. doi:10.5539/jas.v8n5p122
10.5539/jas.v8n5p122
19
Steffens D, Hütsch B, Eschholz T, Lošák T, Schubert S, Liebig J (2005) Water logging may inhibit plant growth primarily by nutrient deficiency rather than nutrient toxicity. Plant Soil Environ 51:545-552. doi:10.17221/3630-PSE
10.17221/3630-PSE
20
Treder W, Tryngiel-Gac, A, Klamkowski K, Masny A (2014) Evaluation of efficiency of a nursery system for production of strawberry potted plants in protected conditions. Infrastructure and ecology of rural areas. No. IV/3:1333-1341
21
Wang H, Inukai Y, Yamauchi A (2006) Root development and nutrient uptake. Crit Rev Plant Sci 25:279-301. doi:10.1080/07352680600709917
10.1080/07352680600709917
22
Whitcomb, CE (1982) Air-root-pruning container. US Patent Application No. 309,085 filed Nov. 9, 1981. https://patents.google.com/ patent/US4510712. Accessed on 05 May 2018
23
Yamasaki A, Yano T (2009) Effect of supplemental application of fertilizers on flower bud initiation and development of strawberry - Possible role of nitrogen. Acta Hortic 842:765-768. doi:10.17660/ActaHortic.2009.842.167
10.17660/ActaHortic.2009.842.167
Information
  • Publisher :KOREAN SOCIETY FOR HORTICULTURAL SCIENCE
  • Publisher(Ko) :원예과학기술지
  • Journal Title :Horticultural Science and Technology
  • Journal Title(Ko) :원예과학기술지
  • Volume : 37
  • No :3
  • Pages :345-353
  • Received Date :2018. 11. 23
  • Revised Date :2019. 03. 27
  • Accepted Date : 2019. 04. 02
  • DOI :https://doi.org/10.7235/HORT.20190035
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