Browse > Article
http://dx.doi.org/10.5338/KJEA.2008.27.2.178

Effect of Long Term Waterlogging on the Growth and Nutrient Contents of 'Campbell Early' and 'Kyoho' Grapevine Cultivars  

Kang, Seok-Beom (National Horticultural Research Institute, RDA)
Lee, In-Bog (National Horticultural Research Institute, RDA)
Jang, Han-Ik (National Horticultural Research Institute, RDA)
Park, Jin-Myeon (National Horticultural Research Institute, RDA)
Moon, Doo-Khil (Faculty of Bioscience and Industry, Cheju National University)
Publication Information
Korean Journal of Environmental Agriculture / v.27, no.2, 2008 , pp. 178-184 More about this Journal
Abstract
This work was carried out to investigate the effect of waterlogging on the growth and nutrient contents of 'Campbell Early' and 'Kyoho' grapevines under the vinyl house condition from June 14 to July 20, 2005. For the trial, seedlings of two-year-old grapevine were transplanted to 40 L pot with a sandy loam soil. Irrigation point of non-waterlogging(control) treatment was controlled at -40 kPa of soil water tension using tensiometer and waterlogging treatments were imposed for 35 days at the water levels of above 10 cm from the soil surface using tap water. The growth of aerial(shoot length, leaf number and stem diameter) and underground(root) parts of 'Campbell Early' and 'Kyoho' grapevines tended to be wholly reduced by waterlogging, while the growth of aerial parts were more severely impaired in 'Kyoho' than in 'Campbell Early' cultivar. The different responses for waterlogging between two grapevines seem to be related with the capacity for absorbing mineral nutrients, because nitrogen content of 'Campbell Early' cultivar leaves was significantly higher than that of 'Kyoho' cultivar although the contents of phosphorus and potassium in leaves of two grapevine cultivars were similarly declined. There was no significant different of fruit quality, such as contents of soluble solid, titratable acidity and weight of berry in 'Campbell Early' between waterlogging and control. In 'Kyoho' cultivar, however, berry weight and titratable acidity were decreased and soluble solid content was increased by waterlogging. It was assumed that waterlogging stress for grapevines promotes maturation and coloring processes of berries by stimulating maturation hormone such as ethylene. In conclusion, 'Campbell Early' cultivar seems to be more tolerable than 'Kyoho' cultivar when comparing the growth responses and nutrient contents between two grapevine cultivars under waterlogging.
Keywords
waterlogging; growth; nutrient contents; grapevine;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Waldren, S., Etherington, J. R. and Davies, M. S. (1987) Comparative studies of plant growth and distribution in relation to waterlogging. X IV. Iron, manganese, calcium and phosphorus concentration in leaves and roots of Geum rivale L. and G. urbanum L. grown in waterlogged soil, New Phytol. 106:689-696   DOI   ScienceOn
2 Else, M. A., Hall, K. C., Amold, G. M. and Davies, W. J. (1995) Export of abscisic acid, 1-aminocyclopropane- 1-carboxylic acid, phosphate, and nitrate from roots to shoots of flooded tomato plants, Plant Physiol. 107, 377-384   DOI
3 Close, D. C. and Davidson, N. J. (2003) Long-term waterlogging: nutrient, gas exchange, photochemical and pigment characteristics of Eucalyptus nitens saplings, Russian Journal of Plant Physiology 50, 843-847   DOI
4 Hook, D. D., Brown, C. L. and Kormanik, P. P. (1971) Inductive flood tolerance in swamp tupelo (Nyssa sylvatica var. biflora (Walt.) Sarg.), J. Exp. Bot. 22, 78-89   DOI
5 Drew, M. C., Sisworo, E. J. and Saker, L. R. (1979) Alleviation of waterlogging damage to young barley plants by application of nitrate and a synthetic cytokinin, and comparison between the effects of waterlogging, nitrogen deficiency and root excision, New phytol. 82: 315-329   DOI   ScienceOn
6 Jones, R. (1974) Comparative studies of plant growth and distribution in relation to waterlogging. VIII. The uptake of phosphorus by dune and dune slack plants, J. Ecol. 62: 109-116
7 Zhou, W., Zhao, D. and Lin, X. (1997) Effects of waterlogging on nitrogen accumulation and alleviation of waterlogging damage by application of nitrogen fertilizer and Mixtalol in winter rape (Brassica napus L.), J. Plant Growth Regul. 16: 47-53   DOI
8 Bradfrod, K. J. and Yang, S. F. (1981) Physiological responses of plants to waterlogging. HortScience 16, 25-30
9 Kozlowski, T. T. (1984) Responses of woody plants to flooding. In T.T. Kozlowski (ed.). Flooding and Plant Growth, Academic Press, Orlando, FL, USA, p. 129-163
10 Domingo, R., Perez-Pastor, A. and Ruiz-Sanchez, M. C. (2002) Physiological responses of apricot plants grafted on two different rootstocks to flooding conditions, J. Plant Physiol. 159, 725-732   DOI   ScienceOn
11 Kozlowski, T. T. (1982) Water supply and tree growth, II. Flooding, For. 43, 145-161
12 Anderson, P. H. and Pezeshki. S. R. (1999) The effect of intermittent flooding on seedlings of three forest species, Photosynthetica 37, 543-552   DOI
13 Jackson, M. B. and Hall, K. C. (1987) Early stomatal closure in waterlogged pea plants is mediated by abscisic acid in the absence of foliar water deficits, Plant Cell Environ. 10, 121-130
14 Barrett-Lennard, E. G., Leighton, P. D., Buwalda, F., Gibbs, J., Armstrong, W., Thomson, C. J. and Greenway, H. (1988) Effects of growing wheat in hypoxic nutrient solutions and of subsequent transfer to aerated solutions. I. Growth and carbohydrate status of shoots and roots, Aust. J. Plant Physiol. 15, 585-598   DOI
15 Drew, M. C. (1983) Plant injury and adaptation to oxygen deficiency in the root environment, a review, Plant Soil 75, 179-199   DOI
16 Huck, M. G. (1970) Variation in taproot elongation rate as influenced by composition of the soil air. Agron. J. 62, 815-818   DOI
17 Kriedemann, P. E. and Sands, R. (1984) Salt resistance and adaptation to root-zone hypoxia in sunflower, Aust. J. Plant Physiol. 11, 287- 301   DOI
18 Moezel van der, P. G., Watson, L. E. and Bell, D. T. (1989) Gas exchange responses of two Eucalyptus species to salinity and waterlogging, Tree Physiol. 5, 251-257   DOI   ScienceOn
19 Gutierrez Boem, F. H., Lavado, R. S. and Porcelli, C. A. (1996) Note on the effects of winter and spring waterlogging on growth, chemical composition and yield of rapeseed. Field Crops Research 47, 175-179   DOI   ScienceOn
20 Rubio, G. and Lavado, R. (1997) Mechanism for the increase in phosphorus uptake of waterlogged plants: soil phosphorus availability, root morphology and uptake kinetics, Oecologia 112: 150-155   DOI
21 Smethurst C. F., Garnett, T. and Shabala, S. (2005) Nutritional and chlorophyll fluorescence response of lucerne (Medicago sativa) to waterlogging and subsequent recovery, Plant and Soil 270, 31-45   DOI
22 Rural Development Administration (RDA). (1988) Soil Chemical Analysis, RDA
23 De Witt, M. C. J. (1978) Morphology and function of roots and shoot growth of crop plants under oxygen deficiency, In Hook, D. D. and R. M. M. Crawford, (ed.). Plant Life in Anaerobic Environments, Ann Arbor Sci. Press, Ann Arbor, MI. p. 333-350
24 Bradford, K. J. and Yang, S. F. (1980) Xylem transport of 1-aminocyclopropane-l-carboxylic acid, and ethylene precursor, in waterlogged tomato plants, Plant Physiol. 65, 506-509   DOI   ScienceOn
25 Abeles, F. B. 1973. In Ethylene in Plant Physiology. Academic Press
26 Reid. D. M. and Bradford, K. J. (1984) Effect of flooding on hormone relations, In T. T. Kozlowski (ed.). Flooding and plant growth, Academic Press, Orlando, FL, USA, p 195-219
27 Barrett-Lennard, E. G., Leighton, P. D., McPharlin, I. R., Setter, T. and Greenway, H. (1986) Methods to experimentally control waterlogging and measure soil oxygen in field trials, Aust. J. Soil, Res. 24, 477-483   DOI
28 Kozlowski, T. T. (1984) Responses of woody plants to flooding. In T.T. Kozlowski (ed.). Flooding and Plant Growth, Academic Press, Orlando, FL, USA, p. 129-163
29 Wang, T. S. C., S. Cheng, Y. and Tung, H. (1967) Dynamics of soil organic acids, Soil Sci. 104, 138-144   DOI
30 Dudal, R. (1976) Inventory of the major soils of the world with special reference to mineral stress hazards: Plant adaptation to mineral stress in problem soils, Cornell University, Ithaca, New York, p. 3-13
31 KNSO, (2006) Damages from storms & floods (1971-2004), http://kosis.nso.go.kr/