[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.7747/JFES.2022.38.4.256

Variation of Seed Viability among Cone Harvest Times at Two Clonal Seed Orchards of Chamaecyparis obtusa

Da-Eun, Gu (Department of Seed and Seedling Management, National Forest Seed and Variety Center, Korea Forest Service)
Ji-Hee, Jeong (Department of Seed and Seedling Management, National Forest Seed and Variety Center, Korea Forest Service)
Ye-Ji, Kim (Department of Agriculture, Forestry and Bioresources, College of Agriculture and Life Sciences, Seoul National University)
Kyu-Suk, Kang (Department of Agriculture, Forestry and Bioresources, College of Agriculture and Life Sciences, Seoul National University)

Publication Information

Journal of Forest and Environmental Science / v.38, no.4, 2022 , pp. 256-262 More about this Journal

Abstract

The timing of seed harvesting is an important decision in the management of seed orchards because it affects seed quality and yield. To investigate the effect of cone harvest time on seed quality and determine the optimal harvesting time, cones were regularly collected in seven times and germination tests were performed at each harvest time in two clonal seed orchards of Chamaecyparis obtusa. As cones developed, the percentage of seed germination increased before cone moisture content began to decrease significantly. The moisture contents of cones were highest at the first collection as 68.3% and 67.3% in Jeju and Gochang seed orchards respectively. At this time, germination speed was slowest, indicating poor seed vigour. The highest germination was found at the second stage in Jeju (36.5%) and at the seventh stage in Gochang (28.6%) seed orchard. The germination speed increased as cone moisture content decreased. Additionally, changes of seed vigour differed among the developmental stages in both seed orchards. Consequently, the optimal cone harvest time of C. obtusa seed orchards in Jeju was early September when high germination percentage was obtained. In Gochang seed orchards, late October was optimal cone harvest time when the germination speed was fast and the cone moisture content decreased.

Keywords

cone moisture content; seed maturation; seed viability; seed vigour; hinoki;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Probert R, Adams J, Coneybeer J, Crawford A, Hay F. 2007. Seed quality for conservation is critically affected by pre-storage factors. Aust J Bot 55: 326-335. DOI
2	Rao NK, Rao SA, Mengesha MH, Ellis RH. 1991. Longevity of pearl millet (Pennisetum glaucum) seeds harvested at different stages of maturity. Ann Appl Biol 119: 97-103. DOI
3	Shaw RH, Loomis WE. 1950. Bases for the prediction of corn yields. Plant Physiol 25: 225-244. DOI
4	Soltani E, Ghaderi-Far F, Baskin CC, Baskin JM. 2015. Problems with using mean germination time to calculate rate of seed germination. Aust J Bot 63: 631-635. DOI
5	Tak WS, Choi CH, Kim TS. 2006. Change in the Seed Characteristics and Germination Properties of Ulmus davidiana var. Japonica According to Seed Collection Time. J Korean For Soc 95: 316-323.
6	Tanaka Y. 1984. Assuring seed quality for seedling production: cone collection and seed processing, testing, storage, and stratification. In: Forest Nursery Manual: Production of Bareroot Seedlings (Duryea ML, Landis TD, Perry CR, eds). Springer, Dordrecht, pp 27-39.
7	Viglas JN, Brown CD, Johnstone JF. 2013. Age and size effects on seed productivity of northern black spruce. Can J For Res 43: 534-543. DOI
8	Williams CG. 2009. Conifer Reproductive Biology. Springer, Dordrecht. DOI
9	Wilson Jr DO, Trawatha SE. 1991. Physiological Maturity and Vigor in Production of 'Florida Staysweet' Shrunken-2 Sweet Corn Seed. Crop Sci 31: 1640-1647. DOI
10	Marcos-Filho J. 2015. Seed vigor testing: an overview of the past, present and future perspective. Sci Agric 72: 363-374. DOI
11	Bae SW, Lee CY, Kim KW, Park BW, Kwon KW, Kang KS, Lee WY, Hong SC, Lee KJ, Song TY, Seo KW, Kim KH, Moon IS, Son YM, Jeon CH, Park JH, Lee HJ, Park MJ, Lim JH, Kim SJ. 2012. Creating and cultivating forest. In: Chamaecyparis obtusa (Bae SW, Lee CY, Kim KW, Park BW, Kwon KW, Kang KS, Lee WY, Hong SC, Lee KJ, Song TY, Seo KW, Kim KH, Moon IS, Son YM, Jeon CH, Park JH, Lee HJ, Park MJ, Lim JH, Kim SJ, eds). Korea Forest Research Institute, Seoul, pp 55-97.
12	Bewley JD, Bradford KJ, Hilhorst HWM, Nonogaki H. 2013. Development and maturation. In: Seeds: Physiology of Development, Germination and Dormancy (Bewley JD, Bradford KJ, Hilhorst HWM, Nonogaki H, eds). 3rd ed. Springer, New York, pp 27-84.
13	Black M, Bewley D, Halmer P. 2006. The Encyclopedia of Seeds: Science, Technology and Uses. CABI, Wallingford.
14	Coolbear P, Francis A, Grierson D. 1984. The Effect of Low Temperature Pre-Sowing Treatment on the Germination Performance and Membrane Integrity of Artificially Aged Tomato Seeds. J Exp Bot 35: 1609-1617. DOI
15	Ellis RH. 2019. Temporal patterns of seed quality development, decline, and timing of maximum quality during seed development and maturation. Seed Sci Res 29: 135-142. DOI
16	Espahbodi K, Hosseini SM, Mirzaie-Nodoushan H, Tabari M, Akbarinia M, Dehghan-Shooraki Y. 2007. Tree age effects on seed germination in Sorbus torminalis. Gen Appl Plant Physiol 33: 107-119.
17	Farooq M, Basra SMA, Ahmad N, Hafeez K. 2005. Thermal Hardening: A New Seed Vigor Enhancement Tool in Rice. J Integr Plant Biol 47: 187-193. DOI
18	Finch-Savage WE, Bassel GW. 2016. Seed vigour and crop establishment: extending performance beyond adaptation. J Exp Bot 67: 567-591.
19	Harrington JF. 1972. Seed storage and longevity. In: Seed Biology (Kozlowski TT, ed). Academic Press, New York, pp 145-245.
20	Hay FR, Probert RJ, Smith RD. 1997. The effect of maturity on the moisture relations of seed longevity in foxglove (Digitalis purpurea L.). Seed Sci Res 7: 341-350. DOI
21	Hay FR, Smith RD, Ellis RH, Butler LH. 2010. Developmental changes in the germinability, desiccation tolerance, hardseededness, and longevity of individual seeds of Trifolium ambiguum. Ann Bot 105: 1035-1052. DOI
22	ISTA. 2020. International Rules for Seed Testing 2020. International Seed Testing Association (ISTA), Bassersdorf.
23	Kang KS, Bilir N. 2021. Seed Orchards - Establishment, Management and Genetics. CRN Promotions and Press, Ankara, pp 1-37.
24	Kang YM, Min JY, Choi MS. 2014. Essential Oil Yields and Chemical Compositions of Chamaecyparis obtuse Obtained from Various Populations and Environmental Factors. J For Environ Sci 30: 285-292.
25	Karrfalt RP. 2008. Seed harvesting and conditioning. In: The Woody Plant Seed Manual: Agriculture Handbook 727 (Bonner FT, Karrfalt RP, eds). USDA, Washington, D.C., pp 58-83.
26	Kelly AF, George RAT. 1998. Encyclopaedia of Seed Production of World Crops. John Wiley and Sons, Chichester.
27	Korea Forest Service. 2021. Statistical Yearbook of Forestry No 51. Korea Forest Service, Daejeon.
28	Leprince O, Pellizzaro A, Berriri S, Buitink J. 2017. Late seed maturation: drying without dying. J Exp Bot 68: 827-841. DOI
29	Likoswe MG, Njoloma JP, Mwase WF, Chilima CZ. 2008. Effect of seed collection times and pretreatment methods on germination of Terminalia sericea Burch. ex DC. Afr J Biotechnol 7: 2840-2846.
30	Mao P, Han G, Wang G, Yu J, Shao H. 2014. Effects of age and stand density of mother trees on early Pinus thunbergii seedling establishment in the coastal zone, China. ScientificWorldJournal 2014: 468036.
31	Matsuda O, Hara M, Tobita H, Yazaki K, Nakagawa T, Shimizu K, Uemura A, Utsugi H. 2015. Determination of Seed Soundness in Conifers Cryptomeria japonica and Chamaecyparis obtusa Using Narrow-Multiband Spectral Imaging in the Short-Wavelength Infrared Range. PLoS One 10: e0128358.