Ensemble modelling to assess the dynamics of invasive plant species under changing climate in Bagmati Province, Nepal

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Published: 2025-06-29
DOI: https://doi.org/10.13057/biodiv/d260604
Keywords:
Climate change, ensemble modelling, invasive alien plant species, SSP245, SSP585
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MANISH SHRESTHA
School of Forestry and Natural Resource Management, Institute of Forestry, Tribhuvan University. Kirtipur, Kathmandu 44600, Nepal
SONY BARAL
Institute of Forestry, Tribhuvan University. Kirtipur and Pokhara Campus, Pokhara 33700, Nepal
UTTAM BABU SHRESTHA
Global Institute for Interdisciplinary Studies. Kathmandu 44600, Nepal
RIPU MARDHAN KUNWAR
Gandaki University. Pokhara 33700, Nepal

Abstract

Abstract. Shrestha M, Baral S, Shrestha UB, Kunwar RM. 2025. Ensemble modelling to assess the dynamics of invasive plant species under changing climate in Bagmati Province, Nepal. Biodiversitas 26: 2589-2600. Invasive Alien Plant species (IAPs) present a significant threat to biodiversity, particularly under changing climatic conditions. This study investigates the distribution patterns of three IAPs, viz. Ageratina adenophora, Chromolaena odorata, and Lantana camara, within Bagmati Province, Nepal, under both current and projected climate scenarios (SSP245 and SSP585). Using species occurrence data from field surveys, available secondary data, and eight bioclimatic variables, we applied an ensemble modelling approach across twelve Global Circulation Models (GCMs). The findings reveal that, under present conditions, A. adenophora occupies the most extensive suitable area (4,121.6 km²), whereas C. odorata occupies the least (1,964.07 km²). Future projections indicate an increase in habitat suitability for all three IAPs in future climates. Specifically, under SSP245, L. camara shows a 12.4% rise in suitable habitat area during the period 2021-2040, with C. odorata showing a 15.6% increase during 2041-2060. Under SSP585, the suitability of L. camara is projected to increase substantially by 37.2% and 40.7% in the periods 2021-2040 and 2041-2060, respectively. This highlights the more conducive environment created by climate change for IAPs in the future. The models demonstrate higher suitability in the middle mountain regions and a decline in suitability with increasing elevation. Specifically, C. odorata favors tropical zones, and A. adenophora and L. camara thrive in subtropical regions. These IAPs pose the greatest risks to cropland and forest ecosystems, adversely affecting local economies and biodiversity. The high-performance metrics of the models (AUC: 0.85-0.92, TSS: 0.51-0.67) confirm their reliability, with Precipitation of Driest Month (BIO14) being the most significant variable under current climate conditions and Mean Diurnal Range (BIO2) emerging as critical for future climate scenarios. These results emphasize the need for proactive site-specific management strategies to mitigate the impacts of IAPs under climate change.

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Vol. 26 No. 6 (2025)

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References

Adhikari P, Jeon JY, Kim HW, Shin MS, Adhikari P, Seo C. 2019. Potential impact of climate change on plant invasion in the Republic of Korea. J Ecol Environ 43: 36. DOI: 10.1186/s41610-019-0134-3.

Adhikari P, Lee YH, Poudel A, Hong SH, Park YS. 2023. Global spatial distribution of Chromolaena odorata habitat under climate change: Random forest modeling of one of the 100 worst invasive alien species. Sci Rep 13 (1): 9745. DOI: 10.1038/s41598-023-36358-z.

Aguirre-Gutiérrez J, van Treuren R, Hoekstra R, van Hintum TJL. 2017. Crop wild relatives range shifts and conservation in Europe under climate change. Divers Distrib 23 (7): 739-750. DOI: 10.1111/ddi.12573.

Alexander JM, Lembrechts JJ, Cavieres LA, Daehler C, Haider S, Kueffer C, Liu G, McDougall K, Milbau A, Pauchard A, Rew LJ, Seipel T. 2016. Plant invasions into mountains and alpine ecosystems: Current status and future challenges. Alp Bot 126 (2): 89-103. DOI: 10.1007/s00035-016-0172-8.

Araújo MB, Pearson RG, Thuiller W, Erhard M. 2005. Validation of species-climate impact models under climate change. Glob Change Biol 11 (9): 1504-1513. DOI: 10.1111/j.1365-2486.2005.01000.x.

Barbet-Massin M, Jiguet F, Albert CH, Thuiller W. 2012. Selecting pseudo-absences for species distribution models: how, where and how many? Methods Ecol Evol 3 (2): 327-338. DOI: 10.1111/j.2041-210X.2011.00172.x.

Bellard C, Cassey P, Blackburn TM. 2016. Alien species as a driver of recent extinctions. Biol Lett 12 (2): 20150623. DOI: 10.1098/rsbl.2015.0623.

Bellard C, Jeschke JM, Leroy B, Mace GM. 2018. Insights from modeling studies on how climate change affects invasive alien species geography. Ecol Evol 8 (11): 5688-5700. DOI: 10.1002/ece3.4098.

Bhattacharjee A, Anadón J, Lohman D, Doleck T, Lakhankar T, Shrestha B, Thapa P, Devkota D, Tiwari S, Jha A, Siwakoti M, Devkota N, Jha P, Krakauer N. 2017. The impact of climate change on biodiversity in Nepal: Current knowledge, lacunae, and opportunities. Climate 5 (4): 80. DOI: 10.3390/cli5040080.

Boria RA, Olson LE, Goodman SM, Anderson RP. 2014. Spatial filtering to reduce sampling bias can improve the performance of ecological niche models. Ecol Model 275: 73-77. DOI: 10.1016/j.ecolmodel.2013.12.012.

CFSC. 2023. Using Gini Coefficient for Analyzing Distribution of Community Forests by Provinces in Nepal. https://cfsc.gov.np/download/14.

Department of Hydrology and Meteorology (DHM). 2017. Observed Climate Trend Analysis in the Districts and Physiographic Regions of Nepal (1971-2014). Government of Nepal, Kathmandu.

Dullinger I, Wessely J, Bossdorf O, Dawson W, Essl F, Gattringer A, Klonner G, Kreft H, Kuttner M, Moser D, Pergl J, Pyšek P, Thuiller W, van Kleunen M, Weigelt P, Winter M, Dullinger S. 2017. Climate change will increase the naturalization risk from garden plants in Europe. Glob Ecol Biogeogr 26 (1): 43-53. DOI: 10.1111/geb.12512.

Early R, Bradley BA, Dukes JS, Lawler JJ, Olden JD, Blumenthal DM, Gonzalez P, Grosholz ED, Ibañez I, Miller LP, Sorte CJB, Tatem AJ. 2016. Global threats from invasive alien species in the twenty-first century and national response capacities. Nat Commun 7 (1): 12485. DOI: 10.1038/ncomms12485.

Elith J, Kearney M, Phillips S. 2010. The art of modelling range-shifting species. Methods Ecol Evol 1 (4): 330-342. DOI: 10.1111/j.2041-210X.2010.00036.x.

Everard M, Gupta N, Chapagain PS, Shrestha BB, Preston G, Tiwari P. 2018. Can control of invasive vegetation improve water and rural livelihood security in Nepal? Ecosyst Serv 32: 125-133. DOI: 10.1016/j.ecoser.2018.07.004.

Fick SE, Hijmans RJ. 2017. WorldClim 2: New 1-km spatial resolution climate surfaces for global land areas. Intl J Climatol 37 (12): 4302-4315. DOI: 10.1002/joc.5086.

Finch DM, Butler JL, Runyon JB, Fettig CJ, Kilkenny FF, Jose S, Frankel SJ, Cushman SA, Cobb RC, Dukes JS, Hicke JA, Amelon SK. 2021. Effects of climate change on invasive species. In: Poland TM, Patel-Weynand T, Finch DM, Miniat CF, Hayes DC, Lopez VM (eds). Invasive Species in Forests and Rangelands of the United States. Springer International Publishing, Cham.

González-Trujillo JD, Escobar-Alba MR, Lara DE, Carvajal-C JE. 2024. Mapping the threat: Projecting invasive plant distribution in the tropical Andes under climate change. Perspect Ecol Conserv 22 (4): 348-357. DOI: 10.1016/j.pecon.2024.11.002.

Harisena NV, Groen TA, Toxopeus AG, Naimi B. 2021. When is variable importance estimation in species distribution modelling affected by spatial correlation? Ecography 44 (5): 5534. DOI: 10.1111/ecog.05534.

Harisena NV. 2019. Factors Affecting Variable Importance Estimations from Species Distribution Models: A Virtual Ecologist Approach. [Thesis]. University of Twente, Enschede. [Netherlands]

Hausfather Z, Peters GP. 2020. Emissions - the ‘business as usual’ story is misleading. Nature 577 (7792): 618-620. DOI: 10.1038/d41586-020-00177-3.

Hernandez JO, Buot IE Jr, Park BB. 2022. Prioritizing choices in the conservation of flora and fauna: Research trends and methodological approaches. Land 11 (10): 1645. DOI: 10.3390/land11101645.

Hiremath AJ, Prasad A, Sundaram B. 2018. Restoring Lantana camara-invaded tropical deciduous forest: The response of native plant regeneration to two common Lantana removal practices. Indian For 144 (6): 545.

Horvitz N, Wang R, Zhu M, Wan F, Nathan R. 2014. A simple modeling approach to elucidate the main transport processes and predict invasive spread: River-mediated invasion of Ageratina adenophora in China. Water Resour Res 50: 9738-9747. DOI: 10.1002/2014WR015537.

IPBES. 2019. Summary for Policymakers of the Global Assessment Report on Biodiversity and Ecosystem Services of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services. www.ipbes.net.

IPBES. 2023. Summary for Policymakers of the Thematic Assessment Report on Invasive Alien Species and Their Control of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services. www.ipbes.net.

Kariyawasam CS, Kumar L, Ratnayake SS. 2019. Invasive plant species establishment and range dynamics in Sri Lanka under climate change. Entropy 21: 571. DOI: 10.3390/e21060571.

Kotu V, Deshpande B. 2015. Data mining process. In: Kotu V, Deshpande B (eds). Predictive Analytics and Data Mining. Elsevier, Netherlands.

Lamsal P, Kumar L, Aryal A, Atreya K. 2018. Invasive alien plant species dynamics in the Himalayan region under climate change. Ambio 47 (6): 697-710. DOI: 10.1007/s13280-018-1017-z.

Lamsal P, Kumar L, Shabani F, Atreya K. 2017. The greening of the Himalayas and Tibetan Plateau under climate change. Glob Planet Change 159: 77-92. DOI: 10.1016/j.gloplacha.2017.09.010.

Lee J-Y, Marotzke J, Bala G, Cao L, Corti S, Dunne JP, Engelbrecht F, Fischer E, Fyfe JC, Jones C, Maycock A, Mutemi J, Ndiaye O, Panickal S, Zhou T. 2021. Future global climate: Scenario-based projections and near-term information. In: IPCC (eds). Climate Change 2021: The Physical Science Basis, Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, United Kingdom.

Liu Y, Oduor AMO, Zhang Z, Manea A, Tooth IM, Leishman MR, Xu X, van Kleunen M. 2017. Do invasive alien plants benefit more from global environmental change than native plants? Glob Change Biol 23 (8): 3363-3370. DOI: 10.1111/gcb.13579.

Mainali KP, Warren DL, Dhileepan K, McConnachie A, Strathie L, Hassan G, Karki D, Shrestha BB, Parmesan C. 2015. Projecting future expansion of invasive species: Comparing and improving methodologies for species distribution modeling. Glob Change Biol 21 (12): 4464-4480. DOI: 10.1111/gcb.13038.

Makori D, Fombong A, Abdel-Rahman E, Nkoba K, Ongus J, Irungu J, Mosomtai G, Makau S, Mutanga O, Odindi J, Raina S, Landmann T. 2017. Predicting spatial distribution of key honeybee pests in Kenya using remotely sensed and bioclimatic variables: Key honeybee pests distribution models. ISPRS Intl J Geo-Inf 6 (3): 66. DOI: 10.3390/ijgi6030066.

McDougall KL, Khuroo AA, Loope LL, Parks CG, Pauchard A, Reshi ZA, Rushworth I, Kueffer C. 2011. Plant invasions in mountains: Global lessons for better management. Mountain Res Dev 31 (4): 380-387. DOI: 10.1659/MRD-JOURNAL-D-11-00082.1.

Mohammadi S, Ebrahimi E, Shahriari M, Bosso L. 2019. Modelling current and future potential distributions of two desert jerboas under climate change in Iran. Ecol Inform 52: 7-13. DOI: 10.1016/j.ecoinf.2019.04.003.

Naimi B, Araújo MB. 2016. SDM: A reproducible and extensible R platform for species distribution modelling. Ecography 39 (4): 368-375. DOI: 10.1111/ecog.01881.

National Statistics Office. 2024. Environment Statistics of Nepal, 2024. www.nsonepal.gov.np.

Negi GCS, Sharma S, Vishvakarma SCR, Samant SS, Maikhuri RK, Prasad RC, Palni LMS. 2019. Ecology and use of Lantana camara in India. Bot Rev 85 (2): 109-130. DOI: 10.1007/s12229-019-09209-8.

Oh M, Heo Y, Lee EJ, Lee H. 2021. Major environmental factors and traits of invasive alien plants determine their spatial distribution: A case study in Korea. J Ecol Environ 45 (1): 18. DOI: 10.1186/s41610-021-00196-9.

Paini DR, Sheppard AW, Cook DC, De Barro PJ, Worner SP, Thomas MB. 2016. Global threat to agriculture from invasive species. Proc Natl Acad Sci 113 (27): 7575-7579. DOI: 10.1073/pnas.1602205113.

Panday K, Poudel G, Neupane A, Acharya KR, Adhikari S. 2021. Status of invasive alien plant species in urban forest of Hetauda, Nepal. Forestry 18 (1): 107-118. DOI: 10.3126/forestry.v18i01.41764.

Poudel AS, Shrestha BB, Joshi MD, Muniappan R, Adiga A, Venkatramanan S, Jha PK. 2020. Predicting the current and future distribution of the invasive weed Ageratina adenophora in the Chitwan-Annapurna Landscape, Nepal. Mountain Res Dev 40 (2): R61-R71. DOI: 10.1659/MRD-JOURNAL-D-19-00069.1.

Qin X, Li M. 2023. Predicting the potential distribution of Oxalis debilis Kunth, an invasive species in China with a Maximum Entropy Model. Plants 12 (23): 3999. DOI: 10.3390/plants12233999.

R Core Team. 2023. R: The R Project for Statistical Computing. https://www.r-project.org/.

Rai P, Singh JS. 2020. Invasive alien plant species: Their impact on environment, ecosystem services and human health. Ecol Indic 111: 106020. DOI: 10.1016/j.ecolind.2019.106020.

Ramaswami G, Sukumar R. 2013. Long-term environmental correlates of invasion by Lantana camara (Verbenaceae) in a seasonally dry tropical forest. Plos One 8 (10): e76995. DOI: 10.1371/journal.pone.0076995.

Ramirez-Reyes C, Nazeri M, Street G, Jones-Farrand DT, Vilella FJ, Evans KO. 2021. Embracing ensemble species distribution models to inform at-risk species status assessments. J Fish Wildl Manag 12 (1): 98-111. DOI: 10.3996/JFWM-20-072.

Rodríguez-Rey M, Jiménez-Valverde A. 2024. Differing sensitivity of species distribution modelling algorithms to climate data source. Ecol Inform 79: 102387. DOI: 10.1016/j.ecoinf.2023.102387.

Saranya KRL, Lakshmi TV, Reddy CS. 2021. Predicting the potential sites of Chromolaena odorata and Lantana camara in forest landscape of Eastern Ghats using habitat suitability models. Ecol Informat 66: 101455. DOI: 10.1016/j.ecoinf.2021.101455.

Seebens H, Blackburn TM, Dyer EE, Genovesi P, Hulme PE, Jeschke JM, Pagad S, Pyšek P, Winter M, Arianoutsou M, Bacher S, Blasius B, Brundu G, Capinha C, Celesti-Grapow L, Dawson W, Dullinger S, Fuentes N, Jäger H. 2017. No saturation in the accumulation of alien species worldwide. Nat Commun 8 (1): 14435. DOI: 10.1038/ncomms14435.

Sharma J, Singh R, Garai S, Rahaman SM, Khatun M, Ranjan A, Mishra SN, Tiwari S. 2022. Climate change and dispersion dynamics of the invasive plant species Chromolaena odorata and Lantana camara in parts of the central and eastern India. Ecol Informat 72: 101824. DOI: 10.1016/j.ecoinf.2022.101824.

Sharma LN, Adhikari B, Bist MR, Shrestha BB. 2020. Mimosa diplotricha (Fabaceae): A new report of invasive weed from Eastern Tarai of Nepal. J Plant Resour 18: 1-5.

Shrestha BB, Joshi S, Bisht N, Yi S, Kotru R, Chaudhary RP, Wu N. 2018. Inventory and Impact Assessment of Invasive Alien Plant Species in Kailash Sacred Landscape. ICIMOD, Kathmandu.

Shrestha BB, Paudel N, Poudel S, Pandey M, Joshi GD. 2023. Occurrence (Survey) Data of Invasive Alien Plants of Nepal. Central Department of Botany, Tribhuvan University. GBIF.org.

Shrestha BB, Shrestha KK. 2021. Invasions of Alien Plant Species in Nepal. Wiley, United States.

Shrestha BB, Shrestha UB, Sharma KP, Thapa-Parajuli RB, Devkota A, Siwakoti M. 2019. Community perception and prioritization of invasive alien plants in Chitwan-Annapurna landscape, Nepal. J Environ Manag 229: 38-47. DOI: 10.1016/j.jenvman.2018.06.034.

Shrestha BB, Siwakoti M, Ranjit JD. 2017. Status of Invasive Alien Plant Species in Nepal. [Report]. Ministry of Forests and Soil Conservation, Kathmandu, Nepal.

Shrestha HS, Adhikari B, Shrestha BB. 2021. Sphagneticola trilobata (Asteraceae): First report of a naturalized plant species for Nepal. Rheedea 31 (2): 77-81. DOI: 10.22244/rheedea.2021.31.02.07.

Shrestha UB, Sharma KP, Devkota A, Siwakoti M, Shrestha BB. 2018. Potential impact of climate change on the distribution of six invasive alien plants in Nepal. Ecol Indic 95: 99-107. DOI: 10.1016/j.ecolind.2018.07.009.

Shrestha UB, Shrestha BB. 2019. Climate change amplifies plant invasion hotspots in Nepal. Divers Distrib 25 (10): 1599-1612. DOI: 10.1111/ddi.12963.

Somodi I, Lepesi N, Botta-Dukát Z. 2017. Prevalence dependence in model goodness measures with special emphasis on true skill statistics. Ecol Evol 7 (3): 863-872. DOI: 10.1002/ece3.2654.

Steen V, Sofaer HR, Skagen SK, Ray AJ, Noon BR. 2017. Projecting species’ vulnerability to climate change: Which uncertainty sources matter most and extrapolate best? Ecol Evol 7 (21): 8841-8851. DOI: 10.1002/ece3.3403.

Thapa S, Chitale V, Rijal SJ, Bisht N, Shrestha BB. 2018. Understanding the dynamics in distribution of invasive alien plant species under predicted climate change in Western Himalaya. Plos One 13 (4): e0195752. DOI: 10.1371/journal.pone.0195752.

Thuiller W, Georges D, Engler R, Breiner F. 2023. Biomod2: Ensemble platform for species distribution modeling. R package version 3: 3-15.

Tiwari S, Adhikari B, Siwakoti M, Subedi K. 2005. An Inventory and Assessment of Invasive Alien Plant Species of Nepal. IUCN Nepal, Kathmandu.

Turbelin A, Catford JA. 2021. Invasive plants and climate change. Clim Change 2021: 515-539. DOI: 10.1016/B978-0-12-821575-3.00025-6.

van Kleunen M, Pyšek P, Dawson W, Essl F, Kreft H, Pergl J, Weigelt P, Stein A, Dullinger S, König C, Lenzner B, Maurel N, Moser D, Seebens H, Kartesz J, Nishino M, Aleksanyan A, Ansong M, Antonova LA. 2019. The Global Naturalized Alien Flora (GloNAF) database. Ecology 100 (1): e02542. DOI: 10.1002/ecy.2542.

Wright AN, Hijmans RJ, Schwartz MW, Shaffer HB. 2015. Multiple sources of uncertainty affect metrics for ranking conservation risk under climate change. Divers Distrib 21 (1): 111-122. DOI: 10.1111/ddi.12257.

Xian X, Zhao H, Wang R, Zhang H, Chen B, Huang H, Liu W, Wan F. 2022. Predicting the potential geographical distribution of Ageratina adenophora in China using equilibrium occurrence data and ensemble model. Front Ecol Evol 10: 973371. DOI: 10.3389/fevo.2022.973371.

Zhao X, Liu W, Zhou M. 2013. Lack of local adaptation of invasive crofton weed (Ageratina adenophora) in different climatic areas of Yunnan Province, China. J Plant Ecol 6 (4): 316-322. DOI: 10.1093/jpe/rts036.

Zurell D, Thuiller W, Pagel J, Cabral JS, Münkemüller T, Gravel D, Zimmermann NE. 2016. Benchmarking novel approaches for modelling species range dynamics. Glob Change Biol 22 (8): 2651-2664. DOI: 10.1111/gcb.13251.