Developing conservation strategies for Pinus koraiensis and Eleutherococcus senticosus by using model-based geographic distributions

Jizhong Wan; Chunjing Wang; Jinghua Yu; Siming Nie; Shijie Han; Juzhao Liu; Yuangang Zu; Qinggui Wang

doi:10.1007/s11676-015-0170-5

Journal of Forestry Research ›› 2015, Vol. 27 ›› Issue (2) : 389 -400. DOI: 10.1007/s11676-015-0170-5

Original Paper

Developing conservation strategies for Pinus koraiensis and Eleutherococcus senticosus by using model-based geographic distributions

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Abstract

We described potential changes in the geographic distribution and occurrence probability of Pinus koraiensis Sieb. et Zucc. and Eleutherococcus senticosus (Rupr. et Maxim.) Maxim. in the counties of northeast China. This information was used to identify priority areas for protection and provide protection and management recommendations within each studied county. The two species were mapped in 2884 study plots throughout this region over a 4-year period (38°40′N–53°30′N, 115°05′E–135°02′E). We used the species distribution models (Maxent), systematic conservation planning models (Marxan), and Geographic Information Systems (ArcGIS 10.0). The distributions of two species were correlated in the study area, enabling unique and economically viable joint conservation measures to be implemented. Three models were combined to identify feasible priority conservation sites. We used local spatial statistics to assess all identified conservation areas in relation to potential climate change based shifts in the geographic distribution of the two species. Model-based conservation strategies were used to identify effective measures to protect and utilize these two tree species in the study region. This study presents a novel technique for assessing wild plant distributions, in addition to serving as a model for the conservation of other species within the framework of general forest management, ecological construction, and geographical surveying.

Keywords

Eleutherococcus senticosus / GIS / Modeling / Pinus koraiensis

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Jizhong Wan, Chunjing Wang, Jinghua Yu, Siming Nie, Shijie Han, Juzhao Liu, Yuangang Zu, Qinggui Wang. Developing conservation strategies for Pinus koraiensis and Eleutherococcus senticosus by using model-based geographic distributions. Journal of Forestry Research, 2015, 27(2): 389-400 DOI:10.1007/s11676-015-0170-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Adhikari D, Barik SK, Upadhaya K. Habitat distribution modelling for reintroduction of Ilex khasiana Purk., a critically endangered tree species of northeastern India. Ecol Eng, 2012, 40: 37-43.

[2]	Ardron JA, Possingham HP, Klein CJ. Marxan good practices handbook. 2008, Victoria: BC Ministry of Environment

[3]	Ban NC, Hansen GJ, Jones M, Vincent AC. Systematic marine conservation planning in data-poor regions: socioeconomic data is essential. Mar Policy, 2009, 33: 794-800.

[4]	Chen X, Li BL. Change in soil carbon and nutrient storage after human disturbance of a primary Korean pine forest in Northeast China. For Ecol Manag, 2003, 186: 197-206.

[5]	Convertino M, Welle P, Munoz-Carpena R, Kiker GA, Chu-Agor ML, Fischer RA, Linkov I. Epistemic uncertainty in predicting shorebird biogeography affected by sea-level rise. Ecol Model, 2012, 240: 1-15.

[6]	Dai L, Zheng B, Shao G, Zhou L. The roles of a decision support system in applying forest ecosystem management in Northeast China. Sci China Ser E Technol Sci, 2006, 49: 9-18.

[7]	Davies KW, Boyd CS, Beck JL, Bates JD, Svejcar TJ, Gregg MA. Saving the sagebrush sea: an ecosystem conservation plan for big sagebrush plant communities. Biol Conserv, 2011, 144: 2573-2584.

[8]	De la Estrella M, Mateo RG, Wieringa JJ, Mackinder B, Muñoz J. Legume diversity patterns in West Central Africa: influence of species biology on distribution models. PLoS One, 2012, 7 e41526

[9]	Deng SY, Liu WD, Guo ZL, Wang MJ. Community structure and diversity forests at different restoring stages. For Res, 2009, 22: 493-499.

[10]	Du F, Jiang H, Guo Z, Wang H, Lv W, Dong Y. Study on the distribution pattern and niche of endangered Magnolia sieboldii in Jilin province. J Nanjing For Univ Nat Sci Ed, 2011, 35: 33-37.

[11]	Farley KA, Anderson WG, Bremer LL, Harden CP. Compensation for ecosystem services: an evaluation of efforts to achieve conservation and development in Ecuadorian páramo grasslands. Environ Conserv, 2011, 38: 393-405.

[12]	Frapporti G, Vriend SP, Van Gaans PFM. Qualitative time trend analysis of ground water monitoring networks. Environ Monit Assess, 1994, 30: 81-102.

[13]	Fu C, Li J, Liu Z. Spatial and temporal differentiation rule of the climate change in Northeast China in the past 60 years. J Arid Land Resour Environ, 2009, 23: 60-65.

[14]	Gaikwad J, Wilson PD, Ranganathan S. Ecological niche modeling of customary medicinal plant species used by Australian Aborigines to identify species-rich and culturally valuable areas for conservation. Ecol Model, 2011, 222: 3437-3443.

[15]	Guo ZL, Zhang JP, Ma YD, Li QK, Yu GR, Han SJ, Fan CN, Liu WD. Researches on litterfall decomposition rates and model simulating of main species in various forest vegetations of Changbai Mountains, China. Acta Ecol Sin, 2006, 26: 1037-1046.

[16]	Hamilton MB. Ex situ conservation of wild plant species: time to reassess the genetic assumptions and implications of seed banks. Conserv Biol, 1994, 8: 39-49.

[17]	Howell KL, Holt R, Endrino IP, Stewart H. When the species is also a habitat: comparing the predictively modelled distributions of Lophelia pertusa and the reef habitat it forms. Biol Conserv, 2011, 144: 2656-2665.

[18]	Johns TC, Gregory JM, Ingram WJ, Johnson CE, Jones A, Lowe JA, Mitchell JFB, Roberts DL, Sexton DMH, Stevenson DS, Tett SFB, Woodage MJ. Anthropogenic climate change for 1860 to 2100 simulated with the HadCM3 model under updated emissions scenarios. Clim Dyn, 2003, 20: 583-612.

[19]	Jones PG, Thornton PK. Generating downscaled weather data from a suite of climate models for agricultural modelling applications. Agric Syst, 2013, 114: 1-5.

[20]	Kelly AE, Goulden ML. Rapid shifts in plant distribution with recent climate change. Proc Natl Acad Sci, 2008, 105: 11823-11826.

[21]	Kikuchi J, Futai K. Spatial distribution of sporocarps and the biomass of ectomycorrhizas of Suillus pictus in a Korean pine (Pinus koraiensis) stand. J For Res, 2003, 8: 0017-0025.

[22]	Ko CY, Root TL, Lin SH, Schneider SH, Lee PF. Global change projections for Taiwan Island birds: linking current and future distributions. Nat Conserv, 2012, 2: 21-40.

[23]	Kozak KH, Graham CH, Wiens JJ. Integrating GIS-based environmental data into evolutionary biology. Trends Ecol Evol, 2008, 23: 141-148.

[24]	Lyet A, Thuiller W, Cheylan M, Besnard A. Fine-scale regional distribution modelling of rare and threatened species: bridging GIS Tools and conservation in practice. Divers Distrib, 2013, 19: 651-663.

[25]	Mischler P, Kearney M, McCarroll JC, Scholte RG, Vounatsou P, Malone JB. Environmental and socio-economic risk modelling for Chagas disease in Bolivia. Geospat Health, 2012, 6: S59-S66.

[26]	Năpăruş M, Kuntner M. A GIS model predicting potential distributions of a lineage: a test case on hermit spiders (Nephilidae: Nephilengys). PLoS One, 2012, 7 e30047

[27]	Nijman V. In-situ and ex situ status of the Javan gibbon and the role of zoos in conservation of the species. Contrib Zool, 2006, 75: 161-168.

[28]	Piao Z, Tang L, Swihart RK, Wang S. Human–wildlife competition for Korean pine seeds: vertebrate responses and implications for mixed forests on Changbai Mountain, China. Ann For Sci, 2011, 68: 911-919.

[29]	Prendergast JR, Quinn RM, Lawton JH, Eversham BC, Gibbons DW. Rare species, the coincidence of diversity hotspots and conservation strategies. Nature, 1993, 365: 335-337.

[30]	Tang JM, Zhai MP. Advances in the factors affecting natural forest regeneration. J Fujian Coll For, 2005, 25 379.

[31]	Trivedi MR, Morecroft MD, Berry PM, Dawson TP. Potential effects of climate change on plant communities in three montane nature reserves in Scotland, UK. Biol Conserv, 2008, 141: 1665-1675.

[32]	Van Zonneveld M, Scheldeman X, Escribano P, Viruel MA, Van Damme P, Garcia W, César T, José R, Manuel S, Hormaza JI. Mapping genetic diversity of cherimoya (Annona cherimola Mill.): application of spatial analysis for conservation and use of plant genetic resources. PLoS One, 2012, 7 e29845

[33]	Volk GM, Richards CM, Reilley AA, Henk AD, Forsline PL, Aldwinckle HS. Ex situ conservation of vegetatively propagated species: development of a seed-based core collection for Malus sieversii. J Am Soc Hortic Sci, 2005, 130: 203-210.

[34]	Wang H, Shao GF, Dai LM, Dong X, Gu HY, Wang F. An impact of logging operations on understory plants for the broadleaved/Korean pine mixed forest on Changbai Mountain, China. J For Res, 2005, 16: 27-30.

[35]	Womelsdorf T, Schoffelen JM, Oostenveld R, Singer W, Desimone R, Engel AK, Fries P. Modulation of neuronal interactions through neuronal synchronization. Science, 2007, 16: 1609-1612.

[36]	Xiao X, Boles S, Liu J, Zhuang D, Liu M. Characterization of forest types in Northeastern China, using multi-temporal SPOT-4 VEGETATION sensor data. Remote Sens Environ, 2002, 82: 335-348.

[37]	Yang X, Xu M. Biodiversity conservation in Changbai Mountain Biosphere Reserve, northeastern China: status, problem, and strategy. Biodivers Conserv, 2003, 12: 883-903.

[38]	Yang XQ, Kushwaha SPS, Saran S, Xu J, Roy PS. Maxent modeling for predicting the potential distribution of medicinal plant, Justicia adhatoda L. in Lesser Himalayan foothills. Ecol Eng, 2013, 51: 83-87.

[39]	Yu D, Zhou L, Zhou W, Ding H, Wang Q, Wang Y, Wu XQ, Dai L. Forest management in Northeast China: history, problems, and challenges. Environ Manag, 2011, 48: 1122-1135.

[40]	Zhang J, Hao ZQ, Li BH, Ye J, Wang XG, Yao XL. Composition and seasonal dynamics of seed rain in broad-leaved Korean pine (Pinus koraiensis) mixed forest in Changbai Mountain, China. Acta Ecol Sin, 2008, 28: 2445-2454.

[41]	Zhang L, Ouyang ZY, Xu WH, Li ZQ, Zhu CQ. Biodiversity Priority areas analysis for amphibians and reptiles in the yangtze basin based on systematic conservation planning idea. Resour Environ Yangtze Basin, 2010, 19: 1020-1028.

[42]	Zhang MG, Zhou ZK, Chen WY, Slik JW, Cannon CH, Raes N. Using species distribution modeling to improve conservation and land use planning of Yunnan, China. Biol Conserv, 2012, 153: 257-264.