[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5423/PPJ.OA.05.2019.0140

An Integrated Modeling Approach for Predicting Potential Epidemics of Bacterial Blossom Blight in Kiwifruit under Climate Change

Kim, Kwang-Hyung (APEC Climate Center)
Koh, Young Jin (Department of Plant Medicine, College of Life Science and Natural Resources, Sunchon National University)

Publication Information

The Plant Pathology Journal / v.35, no.5, 2019 , pp. 459-472 More about this Journal

Abstract

The increasing variation in climatic conditions under climate change directly influences plant-microbe interactions. To account for as many variables as possible that may play critical roles in such interactions, the use of an integrated modeling approach is necessary. Here, we report for the first time a local impact assessment and adaptation study of future epidemics of kiwifruit bacterial blossom blight (KBB) in Jeonnam province, Korea, using an integrated modeling approach. This study included a series of models that integrated both the phenological responses of kiwifruit and the epidemiological responses of KBB to climatic factors with a 1 km resolution, under the RCP8.5 climate change scenario. Our results indicate that the area suitable for kiwifruit cultivation in Jeonnam province will increase and that the flowering date of kiwifruit will occur increasingly earlier, mainly due to the warming climate. Future epidemics of KBB during the predicted flowering periods were estimated using the Pss-KBB Risk Model over the predicted suitable cultivation regions, and we found location-specific, periodic outbreaks of KBB in the province through 2100. Here, we further suggest a potential, scientifically-informed, long-term adaptation strategy using a cultivar of kiwifruit with a different maturity period to relieve the pressures of future KBB risk. Our results clearly show one of the possible options for a local impact assessment and adaptation study using multiple models in an integrated way.

Keywords

adaptation; integrated modeling; kiwifruit; Korea; local impact assessment;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Arneson, P. A. 2001. Plant disease epidemiology: temporal aspects. The Plant Health Instructor. URL https://www.apsnet.org/edcenter/disimpactmngmnt/topc/EpidemiologyTemporal/Pages/default.aspx [15 May 2019].
2	Baek, H.-J., Lee, J., Lee, H.-S., Hyun, Y.-K., Cho, C., Kwon, W.-T., Marzin, C., Gan, S.-Y., Kim, M.-J., Choi, D.-H., Lee, J., Lee, J., Boo, K.-O., Kang, H.-S. and Byun, Y.-H. 2013. Climate change in the 21st century simulated by HadGEM2-AO under representative concentration pathways. Asia Pac. J. Atmos. Sci. 49:603-618. DOI
3	Cesaraccio, C., Spano, D., Snyder, R. L. and Duce, P. 2004. Chilling and forcing model to predict bud-burst of crop and forest species. Agric. For. Meteorol. 126:1-13. DOI
4	Cesaraccio, C., Spano, D., Snyder, R. L. and Duce, P. 2005. Corrigendum to "Chilling and forcing model to predict bud-burst of crop and forest species" [Agric. For. Meteorol. 126 (2004), 1-13]. Agric. For. Meteorol. 129:211. DOI
5	Cho, J. 2013. Assessment of climate change impacts on agricultural reservoirs in consideration of uncertainty. APCC Clim. Cent. Annu. Rep. 5:51-136 (in Korean with English abstract).
6	Datson, P., Nardozza, S., Manako, K., Herrick, J., Martinez-Sanchez, M., Curtis, C. and Montefiori, M. 2013. Monitoring the Actinidia germplasm for resistance to Pseudomonas syringae pv. actinidiae. Acta Hortic. 1095:181-184. DOI
7	Everett, K. R. and Henshall, W. R. 1994. Epidemiology and population ecology of kiwifruit blossom blight. Plant Pathol. 43:824-830. DOI
8	Everett, K. and Henshall, W. 2012. Bacterial blossom blight, KiwiTech Bulletin No. 78. Plant and Food Research Institute, Oakland, New Zealand. 4 pp.
9	Fang, D., Hu, F. and Xie, L. 1999. Preliminary study on bacterial blossom blight of kiwifruit in Jianning County, Fujian province. J. Fujian Agric. Univ. Nat. Sci. 28:54-58.
10	Francesca, S., Simona, G., Francesco Nicola, T., Andrea, R., Vittorio, R., Federico, S., Cynthia, R. and Maria Lodovica, G. 2006. Downy mildew (Plasmopara viticola) epidemics on grapevine under climate change. Glob. Chang. Biol. 12:1299-1307. DOI
11	Kim, J. U., Kim, M. K., Kim, S., Kim, Y. H., Han, M. S. and Lee, W. S. 2012a. High-resolution climate change scenarios in South Korea using PRIDE MODEL. In: Proceedings of the Spring Meeting of KMS 2012, ed. by Korean Meteorological Society, pp. 127-128. Korean Meteorological Society, Seoul, Korea (in Korean).
12	Geerts, S., Raes, D., Garcia, M., Del Castillo, C. and Buytaert, W. 2006. Agro-climatic suitability mapping for crop production in the Bolivian Altiplano: a case study for quinoa. Agric. For. Meteorol. 139:399-412. DOI
13	Holling, C. S. 1986. The resilience of terrestrial ecosystems; local surprise and global change. In: Sustainable development of the biosphere, eds. W. C. Clark and R. E. Munn, pp. 292-317. Cambridge University Press, Cambridge, UK.
14	Jeong, Y., Chung, U. and Kim, K.-H. 2018. Predicting future frost damage risk of kiwifruit in Korea under climate change using an integrated modelling approach. Int. J. Climatol. 38:5354-5367. DOI
15	Jung, J. E., Kwon, E. Y., Chung, U. and Yun, J. I. 2005. Predicting cherry flowering date using a plant phenology model. Korean J. Agric. For. Meteorol. 7:148-155 (in Korean with English abstract).
16	Keith, D. A., Akçakaya, H. R., Thuiller, W., Midgley, G. F., Pearson, R. G., Phillips, S. J., Regan, H. M., Araújo, M. B. and Rebelo, T. G. 2008. Predicting extinction risks under climate change: coupling stochastic population models with dynamic bioclimatic habitat models. Biol. Lett. 4:560-563. DOI
17	Kim, K.-H. and Koh, Y. J. 2015. Development of a Maryblytbased forecasting model for kiwifruit bacterial blossom blight. Res. Plant Dis. 21:67-73 (in Korean). DOI
18	Kim, K.-H. and Cho, J. 2016. Predicting potential epidemics of rice diseases in Korea using multi-model ensembles for assessment of climate change impacts with uncertainty information. Clim. Change 134:327-339. DOI
19	Kim, K.-H., Cho, J., Lee, Y. H. and Lee, W.-S. 2015a. Predicting potential epidemics of rice leaf blast and sheath blight in South Korea under the RCP 4.5 and RCP 8.5 climate change scenarios using a rice disease epidemiology model, EPIRICE. Agric. For. Meteorol. 203:191-207. DOI
20	Kim, K.-H., Jeong, Y. M., Cho, Y.-S. and Chung, U. 2016. Preliminary result of uncertainty on variation of flowering date of kiwifruit: case study of kiwifruit growing area of Jeollanamdo. Korean J. Agric. For. Meteorol. 18:42-54 (in Korean). DOI
21	Kim, K.-H., Koh, Y. J., Jung, U., Han, J., Jeong, Y. and Son, K. I. 2015b. Enhancing agricultural climate services for kiwifruit growers in Jeonnam province. Gwangju Regional Meteorological Administration, Gwangju, Korea. 202 pp. (in Korean).
22	Kim, K.-H., Son, K. I. and Koh, Y. J., 2018. Adaptation of the New Zealand Psa Risk Model for forecasting kiwifruit bacterial canker in Korea. Plant Pathol. 67:1208-1219. DOI
23	Kim, M.-K., Han, M.-S., Jang, D.-H., Baek, S.-G., Lee, W.-S., Kim, Y.-H. and Kim, S. 2012b. Production technique of observation grid data of 1 km Resolution. J. Clim. Res. 7:55-68 (in Korean).
24	Krol, M. S. and Bronstert, A. 2007. Regional integrated modelling of climate change impacts on natural resources and resource usage in semi-arid Northeast Brazil. Environ. Model. Softw. 22:259-268. DOI
25	KMA (Korea Meteorological Administration). 2015. Production of fine-scale climate change data over the Korean Peninsula using RCP scenarios. Korea Meteorological Administration, Seoul, Korea. 822 pp. (in Korean).
26	Koh, Y. J. 1995. Economically important diseases of kiwifruit. Plant Dis. Agric. 1:3-13.
27	Koh, Y. J., Lee, D. H., Shin, J. S. and Hur, J.-S. 2001. Chemical and cultural control of bacterial blossom blight of kiwifruit caused by Pseudomonas syringae in Korea. N. Z. J. Crop Hortic. Sci. 29:29-34. DOI
28	Lightner, G. W. and Steiner, P. W. 1992. $Maryblyt^{TM}$ : a computer model for predicting of fire blight disease in apples and pears. Comput. Electron. Agric. 7:249-260. DOI
29	Lee, I.-H., Park, S.-H., Kang, H.-S. and Cho, C.-H. 2012. Regional climate projections using the HadGEM3-RA. In: 3rd International Conference on Earth System Modeling, Vol. 3ICESM-236-2, ed. by Max Planck Institute for Meteorology. Max Planck Institute for Meteorology, Hamburg, Germany.
30	Lenoir J., Gegout J. C., Marquet P. A., de Ruffray, P. and Brisse, H. 2008. A significant upward shift in plant species optimum elevation during the 20th century. Science 320:1768-1771. DOI
31	Lim, D. K. 2009. Phenological survey for the subtropical fruit trees. Jeonnam Agricultural Research & Extension Services, Naju, Korea. 14 pp. (in Korean).
32	Kwon, Y.-S., Kim, S.-O., Seo, H.-H., Moon, K.-H. and Yun, J. I. 2012. Geographical shift in blooming date of kiwifruits in Jeju Island by global warming. Korean J. Agric. For. Meteorol. 14:179-188 (in Korean). DOI
33	Mathukumalli, S. R., Dammu, M., Sengottaiyan, V., Ongolu, S., Biradar, A. K., Kondru, V. R., Karlapudi, S., Bellapukonda, M. K. R., Chitiprolua, R. R. A. and Cherukumalli, S. R. 2016. Prediction of Helicoverpa armigera Hubner on pigeonpea during future climate change periods using MarkSim multimodel data. Agric. For. Meteorol. 228-229:130-138. DOI
34	Olivier, J. G. J., Schure, K. M. and Peters, J. A. H. W. 2017. Trends in global $CO_2$ and total greenhouse gas emissions: 2017 report. PBL Netherlands Environmental Assessment Agency, The Hague. 69 pp.
35	Ouma, P. O., Odera, P. A. and Mukundi, J. B. 2016. Spatial modelling of weather variables for plant disease applications in Mwea Region. J. Geosci. Environ. Prot. 4:127-136.
36	Reglinski, T., Vanneste, J., Wurms, K., Gould, E., Spinelli, F. and Rikkerink, E. 2013. Using fundamental knowledge of induced resistance to develop control strategies for bacterial canker of kiwifruit caused by Pseudomonas syringae pv. actinidiae. Front. Plant Sci. 4:24. DOI
37	Pennycook, S. R. and Triggs, C. M. 1991. Bacterial blossom blight of kiwifruit: a 5-year survey. Acta Hortic. 297:559-566. DOI
38	Rahmstorf, S., Cazenave, A., Church, J. A., Hansen, J. E., Keeling, R. F., Parker, D. E. and Somerville, R. C. J. 2007. Recent climate observations compared to projections. Science 316:709. DOI
39	R Development Core Team. 2008. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL http://www.R-project.org [15 May 2019].
40	Roberts, D. 2008. Thinking globally, acting locally: institutionalizing climate change at the local government level in Durban, South Africa. Environ. Urban. 20:521-537. DOI
41	Shin, J. S. 2004. Ecology and eco-friendly control of blossom blight of kiwifruits. Ph.D. thesis. Sunchon National University, Suncheon, Korea. 138 pp (in Korean).
42	Shin, J.-S., Park, J.-K., Kim, G.-H., Jung, J.-S., Hur, J.-S. and Koh, Y.-J. 2004. Optimum spray program of preventive bactericides for the control of bacterial blossom blight of kiwifruit. Res. Plant Dis. 10:297-303 (in Korean). DOI
43	Tachibana, Y. 1988. Occurrence of kiwifruit bacterial blossom rot and its control. Plant Quar. 42:182-186.
44	Tuck, G., Glendining, M. J., Smith, P., House, J. I. and Wattenbach, M. 2006. The potential distribution of bioenergy crops in Europe under present and future climate. Biomass Bioenergy 30:183-197. DOI
45	Wilbanks, T. J. and Kates, R. W. 1999. Global change in local places: how scale matters. Clim. Change 43:601-628. DOI
46	Yun, J. I. 2006. Climate change impact on the flowering season of Japanese cherry (Prunus serrulata var. spontanea) in Korea during 1941-2100. Korean J. Agric. For. Meteorol. 8:68-76 (in Korean).
47	Wilby, R. L., Whitehead, P. G., Wade, A. J., Butterfield, D., Davis, R. J. and Watts, G. 2006. Integrated modeling of climate change impacts on water resources and quality in a lowland catchment: River Kennet, UK. J. Hydrol. 330:204-220. DOI
48	Young, J. M. 1984. Little light at the end of the bud rot tunnel. South. Hortic. 13:12-14.