Predicting the suitable habitats of Elwendia persica in the Indian Himalayan Region (IHR)

References

• Aiello-Lammens ME, Boria RA, Radosavljevic A, Vilela B, Anderson RP. 2015. spThin: an R package for spatial thinning of species occurrence records for use in ecological niche models. Ecography. 38(5):541–545.
   Web of Science ®Google Scholar
• Barbosa MA, Sillero N, Martínez-Freiría F, Real R. 2012. Ecological niche models in mediterranean herpetology: past, present and future in ecological modelling (Ed. Wen Jun Zhang). Hauppauge (NY): Nova Science Publishers; p. 173–204.
   Google Scholar
• Beerling DJ, Huntley B, Bailey JP. 1995. Climate and the distribution of Fallopia japonica: use of an introduced species to test the predictive capacity of response surface. J Vegetat Sci. 6(2):269–282.
   Web of Science ®Google Scholar
• Bonamour S, Chevin LM, Charmantier A, Teplitsky C. 2019. Phenotypic plasticity in response to climate change: the importance of cue variation. Philos Trans R Soc Lond B Biol Sci. 374(1768):20180178.
   PubMed Web of Science ®Google Scholar
• Boogar AR, Salehi H, Pourghasemi HR, Blaschke T. 2019. Predicting habitat suitability and conserving Juniperus spp. habitat using SVM and maximum entropy machine learning techniques. Water. 11(10):2049.
   Web of Science ®Google Scholar
• Cahill AE, Aiello-Lammens M, Fisher-Reid MC, Hua X, Karanewsky CJ, Yeong Ryu H, Sbeglia GC, Spagnolo F, Waldron JB, Warsi O, et al. 2012. How does climate change cause extinction? Proc Roy Soc B Biol Sci. 280:1–9.
   Web of Science ®Google Scholar
• Cano E, Musarella CM, Cano-Ortiz A, Piñar Fuentes JC, Spampinato G, Pinto Gomes CJ. 2017. Morphometric analysis and bioclimatic distribution of Glebionis coronaria s.l. (Asteraceae) in the Mediterranean area. PK. 81:103–126.
   Google Scholar
• Cano Ortiz A, Piñar Fuentes JC, Pinto Gomes CJ, Cano E. 2015. Expansion of the Juniperus Genus due to anthropic activity. In: Old-growth forests and coniferous forests: ecology, habitat and conservation. New York (NY): NOVA Science Publishers; p. 55–65. [accessed 2021 May 22]. https://www.novapublishers.com/catalog/product_info.php?products_id=54012.
   Google Scholar
• Chen I-C, Hill J, Ohlemüller R, Roy DB, Thomas C. 2011. Rapid range shifts of species associated with high levels of climate warming. Science. 333(6045):1024–1026.
   PubMed Web of Science ®Google Scholar
• Chizzola R, Saeidnejad AH, Azizi M, Oroojalian F, Mardani H. 2014. Bunium persicum: variability in essential oil and antioxidants activity of fruits from different Iranian wild populations. Genet Resour Crop Evol. 61(8):1621–1631.
   Web of Science ®Google Scholar
• del Río S, Álvarez-Esteban R, Cano E, Pinto-Gomes C, Penas A. 2018. Potential impacts of climate change on habitat suitability of Fagus sylvatica L. forests in Spain. Plant Biosystems. 152(6):1205–1213.
   Web of Science ®Google Scholar
• del Río S, Canas R, Cano E, Cano-Ortiz A, Musarella C, Pinto-Gomes C, Penas A. 2021. Modelling the impacts of climate change on habitat suitability and vulnerability in deciduous forests in Spain. Ecol Indic. 131:108202.
   Web of Science ®Google Scholar
• Dutt HC, Bhagat N, Pandita S. 2015. Oral traditional knowledge on medicinal plants in jeopardy among Gaddi shepherds in hills of Northwestern Himalaya, J&K, India. J Ethnopharmacol. 168:337–348.
   PubMed Web of Science ®Google Scholar
• Edalat M, Jahangiri E, Dastras E, Pourghasemi HR. 2019. Prioritization of effective factors on Zataria multiflora habitat suitability and its spatial modeling in GIS and R for earth and environmental sciences (Eds.: Pourghasemi HR, and Gokceoglu C.) Amsterdam (The Netherlands): Elsevier; p. 411–427.
   Google Scholar
• Elith J, Phillips SJ, Hastie T, Dudík M, Chee YE, Yates CJ. 2011. A statistical explanation of MaxEnt for ecologists. Divers Distribut. 17(1):43–57.
   Web of Science ®Google Scholar
• Felix Ribeiro KA, Madeira de Medeiros C, Sánchez Agudo JA. 2022. How effective are the protected areas to preserve endangered plant species in a climate change scenario? The case of three Iberian endemics. Plant Biosyst. 156(3):679–692.
   Web of Science ®Google Scholar
• Feng X, Park DS, Liang Y, Pandey R, Papeş M. 2019. Collinearity in ecological niche modeling: confusions and challenges. Ecol Evol. 9(18):10365–10376.
   PubMed Web of Science ®Google Scholar
• Fois M, Cuena-Lombraña A, Fenu G, Bacchetta G. 2018. Using species distribution models at local scale to guide the search of poorly known species: review, methodological issues and future directions. Ecol Model. 385:124–132.
   Web of Science ®Google Scholar
• Garzón MB, Robson TM, Hampe A. 2019. ΔTrait SDMs: species distribution models that account for local adaptation and phenotypic plasticity. New Phytol. 222(4):1757–1765.
   PubMed Web of Science ®Google Scholar
• Guisan A, Holten JI, Spichiger R, Tessier L. 1995. Potential ecological impacts of climate change in the Alps and Fennoscandian mountains. Conservatoire et Jardin botaniques, Geneve 1–194.
   Google Scholar
• Hamid M, Khuroo AA, Charles B, Khuroo R, Singh CP, Aravind NA. 2019. Impact of climate change on the distribution range and niche dynamics of Himalayan birch, a typical treeline species in Himalayas. Biodivers Conserv. 28(8–9):2345–2370.
   Web of Science ®Google Scholar
• Hooker JD. 1875–97. The Flora of British India. Vol-1-VII. Covent Garden, London: L. Reeve & Co.
   Google Scholar
• Ishihama F, Takenaka A, Yokomizo H, Kadoya T. 2019. Evaluation of the ecological niche model approach in spatial conservation prioritization. PLoS ONE. 14(12):e0226971.
   PubMed Web of Science ®Google Scholar
• Jaynes ET. 1957. Information theory and statistical mechanics. Phys Rev. 106(4):620–630.
   Web of Science ®Google Scholar
• MacLaren CA. 2016. Climate change drives decline of Juniperus seravschanica in Oman. J Arid Environ. 128:91–100.
   Web of Science ®Google Scholar
• Mardani H, Ziaratnia SM, Azizi M, Aung HP, Appiah KS, Fujii Y. 2015. In vitro microtuberization of Black Zira (Bunium persicum Boiss.). Afr J Biotechnol. 14(25):2080–2087.
   Google Scholar
• Méndez-Encina FM, Méndez-González J, Mendieta-Oviedo R, López-Díaz JÓM, Nájera-Luna JA. 2021. Ecological niches and suitability areas of three host pine species of Bark Beetle Dendroctonus mexicanus Hopkins. Forests. 12(4):385.
   Web of Science ®Google Scholar
• Mendoza-Fernández AJ, MartíNez-Hernández F, Pérez-García FJ, Garrido-Becerra JA, Benito BM, Salmerón-Sánchez E, Guirado J, Merlo ME, Mota JF. 2015. Extreme habitat loss in a Mediterranean habitat: Maytenus senegalensis subsp. europaea. Plant Biosystems. 149(3):503–511.
   Web of Science ®Google Scholar
• Motti R, Zotti M, Bonanomi G, Cozzolino A, Stinca A, Migliozzi A. 2021. Climatic and anthropogenic factors affect Ailanthus altissima invasion in a Mediterranean region. Plant Ecol. 222(12):1347–1359.
   Web of Science ®Google Scholar
• Musarella CM, Cano-Ortiz A, Canas Q. 2020. R. Habitats of the World. Biodivers Threat; p. 3–8. https://www.intechopen.com/chapters/67377.
   Google Scholar
• Nasir E, Ali SI. 2005. Flora of Pakistan. Karachi: University of Karachi.
   Google Scholar
• Orsenigo S, Astuti G, Bartolucci F, Citterio S, Conti F, Garrido-Becerra JA, Gentili R, del Galdo GG, Jiménez-Martínez JF, Karrer G, et al. 2017. Global and Regional IUCN Red List Assessments: 3. IB. 3:83–98.
   Google Scholar
• Orsenigo S, Bernardo L, Cambria S, Gargano D, Laface VLA, Musarella CM, Passalacqua NG, Spampinato G, Tavilla G, Fenu G. 2020. Global and regional IUCN Red List Assessments: 9. IB. 9:111–123.
   Google Scholar
• Perrino EV, Valerio F, Gannouchi A, Trani A, Mezzapesa G. 2021. Ecological and plant community implication on essential oils composition in useful wild officinal species: a Pilot Case Study in Apulia (Italy). Plants. 10(3):574.
   Google Scholar
• Phillips SJ, Anderson RP, Schapire RE. 2006. Maximum entropy modelling of species geographic distribution. Ecol Model. 190(3–4):231–259.
   Web of Science ®Google Scholar
• Raghavan RK, Koestel Z, Ierardi R, Peterson AT, Cobos ME. 2021. Climatic suitability of the eastern paralysis tick, Ixodes holocyclus, and its likely geographic distribution in the year 2050. Sci Rep. 11(1):15330.
   PubMed Web of Science ®Google Scholar
• Shahsavari N, Barzegar M, Sahari MA, Naghdibadi H. 2008. Antioxidant activity and chemical characterization of essential oil of Bunium persicum. Plant Foods Hum Nutr. 63(4):183–188.
   PubMed Web of Science ®Google Scholar
• Sharma BM, Kachroo P. 1983. Flora of Jammu and plants of neighbourhood, (Vol. I–II). Bishen Singh Mahendra Pal Singh, Dehradun, India.
   Google Scholar
• Silva LD, Costa H, de Azevedo EB, Medeiros V, Alves M, Elias RB, Silva L. 2017. Modelling native and invasive woody species: a comparison of ENFA and MaxEnt applied to the Azorean Forest. In Modeling, dynamics, optimization and bioeconomics II, Proceedings in mathematics & statistics (Eds. Pinto AA, Zilberman D). Berlin (Germany): Springer; 195: p. 415–444.
   Google Scholar
• Singh S, Singh B, Surmal O, Bhat MN, Singh B, Musarella CM. 2021. Fragmented forest patches in the Indian Himalayas preserve unique components of biodiversity: investigation of the Floristic Composition and Phytoclimate of the Unexplored Bani Valley. Sustainability. 13(11):6063.
   Web of Science ®Google Scholar
• Sofi PA, Zeerak NA, Singh P. 2009. Kala Zeera (Bunium persicum Boiss.): a Kashmirian high value crop. Turkish J Biol. 33:249–258.
   Web of Science ®Google Scholar
• Sousa-Guedes D, Arenas-Castro S, Sillero N. 2020. Ecological niche models reveal climate change effect on biogeographical regions: the Iberian Peninsula as a case study. Climate. 8(3):42.
   Web of Science ®Google Scholar
• Spampinato G, Musarella CM, Cano-Ortiz A, Signorino G. 2018. Habitat, occurrence and conservation status of the Saharo-Macaronesian and Southern-Mediterranean element Fagonia cretica L. (Zygophyllaceae) in Italy. J Arid Land. 10(1):140–151.
   Web of Science ®Google Scholar
• Stalin N, Swamy PS. 2015. Prediction of suitable habitats for Syzygium caryophyllatum, an endangered medicinal tree by using species distribution modelling for conservation planning. Eur J Experim Biol. 5(11):12–19.
   Google Scholar
• Swets JA. 1988. Measuring the accuracy of diagnostic systems. Science. 240(4857):1285–1293.
   PubMed Web of Science ®Google Scholar
• Talei GR, Mosavi Z. 2009. Chemical composition and antibacterial activity of Bunium persicum from west of Iran. Asian J Chem. 21:4749–4754.
   Google Scholar
• Thakur S, Dutt HC. 2019. Bunium persicum (Boiss.) Fedtsch. Distribution, botany and agrotechnology in plants of commercial values (Ed. Singh B.). New Delhi: New India Publishing Agency; p. 89–95.
   Google Scholar
• Thakur S, Tashi N, Singh B, Dutt HC, Singh B. 2020. Ethnobotanical plants used for gastrointestinal ailments by the inhabitants of Kishtwar plateau in Northwestern Himalaya, India. Indian J Tradition Knowl. 19(2):288–298.
   Web of Science ®Google Scholar
• Willcock S, Martínez-López J, Hooftman DA, Bagstad KJ, Balbi S, Marzo A, Prato C, Sciandrello S, Signorello G, Voigt B, et al. 2018. Machine learning for ecosystem services. Ecosyst Serv. 33(B):165–174.
   Google Scholar
• Yackulic CB, Chandler R, Zipkin EF, Royle JA, Nichols JD, Grant EHC, Veran S. 2013. Presence-only modelling using MAXENT: when can we trust the inferences? Methods Ecol Evol. 4(3):236–243.
   Web of Science ®Google Scholar
• Zhang K, Zhang Y, Zhou C, Meng J, Sun J, Zhou T, Tao J. 2019. Impact of climate factors on future distributions of Paeonia ostii across China estimated by MaxEnt. Ecol Inform. 50:62–67.
   Web of Science ®Google Scholar