Effect of Carbon Dioxide Concentration, Temperature, and Relative Drought on Growth Responses and Yield in Spring Potato (Solanum tuberosum L.) |
Lee, Yun-Ho
(Crop Physiology and Production, National Institute of Crop Science, Rural Development Administration)
Cho, Hyeoun-Suk (Crop Physiology and Production, National Institute of Crop Science, Rural Development Administration) Kim, Jun-Hwan (Crop Physiology and Production, National Institute of Crop Science, Rural Development Administration) Sang, Wan-Gyu (Crop Physiology and Production, National Institute of Crop Science, Rural Development Administration) Shin, Pyong (Crop Physiology and Production, National Institute of Crop Science, Rural Development Administration) Baek, Jae-Kyeong (Crop Physiology and Production, National Institute of Crop Science, Rural Development Administration) Seo, Myung-Chul (Crop Physiology and Production, National Institute of Crop Science, Rural Development Administration) |
1 | Anithakumari, A. M., O. Dolstra, B. Vosman, R. F. Visser, and G. V. D. Linden, 2011: In vitro screening and QTL analysis for drought tolerance in diploid potato. Euphytica 181, 357-369. DOI |
2 | Basu, P. S., A. Sharma, I. D. Garg, and N. P. Sukumaran, 1999: Tuber sink modifies photosynthetic response in potato under water stress. Environmental and Experimental Botany 42, 25-39. DOI |
3 | Bindi, M., F. Miglietta, E. Vaccari, V. Magliulo, and A. Giuntoli, 2006: Growth and quality responses of potato elevated []. Ecological Studies 187, 105-119. |
4 | Chaves, M., J. S. Pereira, J. Maroco, M. L. Rodrigues, C. P. P. Ricardo, M. L. Osorio, I. Carvalho, T. Faria, and C.Pinheiro, 2002: How plants cope with water stress in the field. Photosynthesis and growth. Annals of Botany 89, 907-916. DOI |
5 | Choi, S.U., A. S. Lee, S. J. Jeon, K. D. Kim, M. C. Seo, W. S. Jung, J. H. Maeng, and I. J. Kim, 2014: Estimating the yield of potato Non-Mulched sing Climatic Elements. Korean Journal of Crop Science 59, 89-96. DOI |
6 | CIP (Climate information portal), 2017: The 2016 abnormal climate report. www.climate.go.kr/ |
7 | Donnelly, A., J. Craigon, C. R. Black, J. J. Colls, and G. Landon, 2001: Elevated increases biomass and tuber yield in potato even at high ozone concentration. New phycologist 149, 265-274. DOI |
8 | Fleisher, D. H., D. J. Timlin, and V. R. Reddy, 2008b: Interactive effects of carbon dioxide and water stress on potato canopy growth and development. Agronomy Journal 100, 711-719. DOI |
9 | ESRL (Earth system research laboratory), 2018: ESRL Global Monitoring Division. (www.esrl.noaa.gov/gmd/ccgg/trends/global.html) |
10 | Fleisher, D. H., D. J. Timlin, and V. R. Reddy, 2008a: Elevated carbon dioxide and water stress effects on potato canopy gas exchange, water use, and productivity. Agricultural and Forest Meteorology 148, 1109-1122. DOI |
11 | Fleisher, D. H., J. Barnaby, R. Sicher, J. P. Resop, D. J. Timlin, and V. R. Reddy, 2013: Effects of elevated and cyclic drought on potato under varying radiation regimes. Agricultural and Forest Meteorology 171-172, 270-280. DOI |
12 | Fleisher, D. H., J. Barnaby, R. Sicher, J. P. Resop, D. J. Timlin, and V. R. Reddy, 2014: Potato gas exchange response to drought cycles under elevated carbon dioxide. Agronomy Journal 106, 2024-2034. DOI |
13 | Gudmestad, N. C., 2008: Potato health from sprouting to harvest. Potato health management, D. A. Johnson and M. L. Powelson (ed). APS Press, St. Paul, Minnesota, USA, 67-77. |
14 | KOSIS (Korean statistical information service), 2017: http://kosis.kr/index/index.jsp |
15 | Haverkort, A., M.Vandewaart, and K. B. A. Bodlaender, 1990: The effect of early drought stress on numbers of tubers and stolons of potato in controlled and field conditions. Potato Research 33, 89-96. DOI |
16 | Hogy, P., and A. Fangmeier, 2009: Atmospheric enrichment affects potatoes: 2. tuber quality traits. European Journal of Agronomy 30, 85-94. DOI |
17 | Kaminski, K. P., K. Korup, K. L. Nielsen., F. Liu, H. B. Topbjerg, H. G. Kirk, and M. N. Andersen, 2014: Gas-exchange, water use efficiency and yield responses of elite potato (Solanum tuberosum L) cultivars to changes in atmospheric carbon dioxide concentration, temperature and relative humidity. Agricultural and Forest Meteorology 187, 36-45. DOI |
18 | Kim, Y. U., and B. W. Lee, 2016: Effect of high temperature, day length, and reduced solar radiation on potato growth and yield. Korean Journal of Agricultural and Forest Meteorology 18, 74-87. DOI |
19 | KMA (Korean meteorological administration), 2017: http://hydro.kma.go.kr/drought/obsAdm.do |
20 | Lahlou, O., S. Ouattar, and J. F. Ledent, 2003: The effect of drought and cultivar on growth parameters, yield and yield components of potato. Agronomie 23, 257-268. DOI |
21 | Long, S. P., E. A. Ainsworth, A. Rogers, and D. R. Ort, 2004: Rising atmospheric carbon dioxide: plants FACE the future. Annual Review of Plant Biology 55, 591-628. DOI |
22 | Martin, B., and N. A. Ruiztorres, 1992: Effects of water-deficit stress on photosynthesis, its components, and component limitations, and on water-use efficiency in wheat (triricum-aestivum L.). Plant Physiology 100, 733-739. DOI |
23 | Schapendonk, H. C. M., M. van. Oijen, P. Dijkstra, C. S. Pot, W. J. R. M. Jordi, and G. M. Stoopen, 2000: Effects of elevated concentration on photosynthetic acclimation and productivity of two potato cultivars grown in open-top chambers. Australian Journal Plant Physiology 27, 1119-1130. |
24 | Miglietta, F., V. Magliulo, M. Bindi, L. Cerio, F. P. Vaccari, and A. Peressottis, 1998: Free air enrichment of potato (Solanum tuberosum L.): Development, growth and yield. Global Change Biology 4, 163-172. DOI |
25 | Morison, J. I. L. and D.W. Lawlor, 1999: Interaction between increasing concentration and temperature on plant growth Plant Cell & Environment 22, 659-682. DOI |
26 | Obidiegwu, J. E., G. B. Bryan, H. G. Jones, and A. Prashar, 2015: Coping with drought: stress and adaptive responses in potato and perspectives for improvement. Frontiers in Plant Science 6, 1-21. doi:10.3389/fpls.2015.00542. DOI |
27 | RDA (Rural Development Administration), 2018: Agricultural weather service. (http://weather.rda.go.kr) |
28 | Reddy. K. R., H. F. Hodges, J. J. Red, J.M. Mckinion, J. T. Baker, L. Trapley, and V. R. Redd, 2001: Soil-plant-atmosphere-research (SPAR) facility: A tool for plant research and modelling. Biotronics 30, 27-50. |
29 | Sicher, R. C., and J. A. Bunce, 1999: Photosynthetic enhancement and conductance to water vapor of filed-grown Solanum tuberosum (L.) in response to enrichment. Photosynth Research 62, 155-163. DOI |
30 | Sharkey, T. D., C. J. Bernacchi, G. D. Farquhar, and E. L. Singsaas, 2007: Fitting photosynthetic carbon dioxide response curves for C3 leaves. Plant Cell & Environment 30, 1035-1040. DOI |
31 | Tardieu, F., 2012: Any trait or trait-related allele can confer drought tolerance: just design the right drought scenario. Journal of Experimental Botany 63, 25-31. DOI |
32 | Wurr, D. C. E., 1977: Some observations of patterns of tuber formation and growth in the potato. Potato Research 20, 63-75. DOI |
33 | Wheeler, R. M., C. L. Mackowiak, J. C. Sager, and W. M. Knott, 1994: Growth of soybean and potato at high partial pressures. Advances in Space Research 14, 251-255. DOI |
34 | Wheeler, R. M., C. L. Mackowiak, N. C. Yorioand, and J. C. Sage, 1999: Effects of on stomatal conductance: Do stomata open at very high concentrations? Annals of Botany 83, 243-251. DOI |
35 | Xu, F., W. Guo, Y. Wei, and R. Wang, 2009: Leaf morphology correlates with water and light availability: what consequences for simple and compound leaves? Progress in Natural Science 19, 1798-1798. |
36 | Yamaguchi, M., H. Timm, and A. R. Spurr, 1964: Effects of soil temperature on growth and nutrition of potato plants and tuberization, composition and periderm structure of tubers. Journal for the American Society for Horticultural Science 84, 412-423. |
37 | Yamori, W., K. Noguchi, and I. Terashimal, 2005: Temperature acclimation of photosynthesis in spinach leaves: analyses of photosynthetic components and temperature dependence of photosynthetic partial reactions. Plant Cell & Environment 28, 536-547. DOI |
38 | Yamori, W., K. Hikosaka, and D. A. Way, 2014: Temperature response of photosynthesis in , , and CAM plants: temperature acclimation and temperature adaption. Photosynth Research 119, 101-117. DOI |
39 | Zhenming, J. L., C. F. Jiao, X. Bai, D. Zhang, and R. Zhai, 2017: Influence of drought stress o photosynthetic characteristics and protective enzymes of potato at seedling stage. Journal of Saudi Society of Agricultural Sciences 16, 82-88. DOI |