Impact of Bioclimatic Factors on Diversity Patterns in Quercus brantii (Persian Oak) Populations within the Western Iranian Forest Ecosystem
Adele Rafezi
1
(
Department of Plant Production and Genetics, Agriculture Faculty, University of Zanjan
)
Mohammad Reza Azimi
2
(
Department of Plant Production and Genetics, Agriculture Faculty, University of Zanjan
)
Mehrshad Zeinalabedini
3
(
Agricultural Biotechnology Research Institute of Iran, Karaj, Iran
)
Mohammad reza Ghaffari
4
(
Agricultural Biotechnology Research Institute of Iran, Karaj, Iran
)
Keywords: Quercus brantii, spatial distribution, Bioclimatic factors, (Geographic Information System) GIS, Redundancy analysis (RDA),
Abstract :
The woodlands in western Iran, especially the Zagros forests, are ecologically crucial for their ability to withstand environmental stresses and conserve water and soil. These ecosystems have suffered significant degradation, particularly in Ilam province, where Persian oak trees (Quercus brantii) have experienced widespread mortality. Understanding the impact of climatic factors on tree species dominance and forest composition is vital for ecosystem conservation. Despite some knowledge about oak species diversity, research on the influence of bioclimatic parameters on Q. brantii, a native Iranian species, is limited. This study aimed to explore how topographical and climatic factors have shaped the population structure and diversity of Q. brantii in western Iran. The study collected data from five habitats within three forested regions in the Ilam province, including 183 samples. A total of 20 phenotypic traits, three geographic, and 19 bioclimatic parameters were measured, and statistical analyses revealed distinct oak ecotypes based on leaf and seed characteristics. Based on the morphological characteristics, a clustering analysis identified two distinct groups among all ecotypes. Redundancy analysis (RDA) revealed that three bioclimatic factors namely annual mean temperature, annual precipitation, and altitude significantly influenced population diversity. Specifically, they had a significant impact on fruit formation and seed morphology and together accounted for 86.9% of the observed variability. The spatial distribution analysis based on PCNM indices revealed that the Sarmast, Kochali, and Sirvan locations had the highest morphotypic diversity. This study emphasizes how bioclimatic and geographic factors shape Iranian oak diversity, informing conservation and sustainable management in western Iran.
Alcantara-Ayala O, Oyama K, Rios-Munoz C, Rivas G, Ramirez-Barahona S, Luna-Vega I (2014) Morphological variation of leaf traits in the Ternstroemia lineata species complex (Ericales: Penthaphylacaceae) in response to geographic and climatic variation. PeerJ. 8, e830.
Alikhani L, Rahmani MS, Shabanian N, Badakhshan H, Khadivi-Khub A (2014) Genetic variability and structure of Quercus brantii assessed by ISSR, IRAP, and SCoT markers. Gene. 552(1), 176-183.
Arab MM, Marrano A, Abdollahi-Arpanahi R, Leslie CA, Cheng H, Neale DB, Vahdati K. (2020). Combining phenotype, genotype, and environment to uncover genetic components underlying water use efficiency in Persian walnut. Journal of Experimental Botany 23; 71(3), 1107-1127.
Cavender-Bares J, Kothari S, Meireles JE, Kaproth MA, Manos PS, Hipp AL (2018) The role of diversification in community assembly of the oaks (Quercus L.) across the continental U.S. American Journal of Botany. 105(3), 565-586.
Borcard D, Legendre P (2002) All-scale spatial analysis of ecological data using means of principal coordinates of neighbor matrices. Ecological Modelling. 153, 51–68. doi: 10.1016/S0304-3800(01)00501-4
Chen R, Fan Z, Guan J, Li X, Wu F, Niklas KJ (2017) Ecogeographical variation of 12 morphological traits within Pinus tabulaeformis: the effects of environmental factors and demographic histories. Plant Ecology. 10, 386–396.
Collart F, Wang J, Patino J, Hagborg A, Söderström L, Goffinet B, Magain N, Hardy OJ, Vanderpoorten A (2021) Macroclimatic structuring of spatial phylogenetic turnover in liverworts. Ecography. 44, 1474–1485.
Danicici V, Kovacevic B, Ballian D (2018) Variability in fruit morphology of European sweet chestnut (Castanea sativa Mill.) in natural populations in Bosnia and Herzegovina. Sumarski List. 142, 517–528.
Das AA, Ratnam J (2022) The thermal niche and phylogenetic assembly of evergreen tree metacommunities in a mid-to-upper tropical montane zone. Proceedings of the Royal Society B. 289(1977), 1471-2954.
Ebrahimi A, Nejadsattari T, Assadi M, Larijani K, Mehregan I (2017) Morphological and molecular differentiation in the population of Persian Oak (Quercus brantii Lindl.) in southwestern Iran. Egyptian Journal of Botany. 57(2), 379-393.
Ficetola GF, Maiorano L, Falcucci A, et al. (2010) Knowing the past to predict the future: land-use change and the distribution of invasive bullfrogs. Global Change Biology. 16, 528–37.
Forester BR, Lasky JR, Wagner HH, Urban DL (2018) Comparing methods for detecting multilocus adaptation with multivariate genotype-environment associations. Molecular Ecology. 27, 2215–2233. doi: 10.1111/mec.14584
Gao SH, Ren Y, Masabni J, Zou F, Xiong H, Zhu J (2021) Influence of Geographical and Climatic Factors on Quercus variabilis Blume Fruit Phenotypic Diversity. Diversity. 13, 329. doi: 10.3390/ d13070329
Ghezel MA, Ghasemnezhad A, Hemmati K, Sohrabi O (2022) Effect of foliar application of plant extracts on the growth behavior and quality of evening Primrose (Oenothera biennis L.). International Journal of Horticultural Science and Technology. 9, 393-404.
Hailemariam MB, Temam TD (2020) Pattern of plant community distribution along the elevational gradient and anthropogenic disturbance in Gole forest Ethiopia. International Journal of Ecology. doi: 10.1155/ 2020/6536374
Ji MF, Zhang XW, Wang ZQ, Zhang Q, Deng JM (2011) Intra- versus inter-population variation of cone and seed morphological traits of Pinus tabulaeformis Carr in northern China: Impact of climate-related conditions. Polish Journal of Ecology. 59, 717–727.
Kassambara A (2017) Practical Guide to Cluster Analysis in R. Unsupervised Machine Learning. STHDA (http://www.sthda.com).
Legendre P, Fortin MJ (2010) Comparison of the Mantel test and alternative approaches for detecting complex multivariate relationships in the spatial analysis of genetic data. Molecular Ecology Resources. 10, 831–844. doi: 10.1111/j.1755-0998.2010.02866.x
Lin L, Jiang X, Guo K, Byrne A, Deng M (2023) Climate change impacts the distribution of Quercus section Cyclobalanopsis (Fagaceae), a keystone lineage in East Asian evergreen broadleaved forests. Plant Diversity. 45(5). DOI: 10. 1016 /j.pld .2023.03.014
Li Y, Li S, Lu XH, Wang QQ, Han HY, Zhang XM, Ma YH, Gan XH (2020) Leaf phenotypic variation of endangered plant Tetracentron sinense Oliv. And influence of geographical and climatic factors. Journal of Forestry Research. 32, 623–636.
Li YP, Zhang YB, Zhang XL, Korpelainen H, Berninger F, Li CY (2013) Effects of elevated CO2 and temperature on photosynthesis and leaf traits of an understory dwarf bamboo in subalpine forest zone, China. Physiologia Plantarum. 148, 261–272.
Li Y, Zhang X, Fang Y (2019) Landscape features and climatic forces shape the genetic structure and evolutionary history of an Oak species (Quercus chenii) in east China. Frontiers in Plant Science. 10, 1060. doi: 10.3389/fpls.2019.01060
Molina–Venegas R, Ottaviani G, Campetella G, Canullo R, Chelli S (2022) Biogeographic deconstruction of phylogenetic and functional diversity provides insights into the formation of regional assemblages. Ecography. e06140.
Munishi PKT, Shear TH, Wentworth T, Temu RAPC (2007) Compositional gradients of plant communities in submontane rainforests of Eastern Tanzania. Tropical Forest Science. 19, 35–45.
Oksanen J, Blanchet F, Friendly M, Kindt R, Legendre P, McGlinn D (2018) Vegan: Community Ecology Package. R package version 2.5-2. Available at: https://CRAN.R-project.org/package=vegan
Panahi P, Jamzad Z (2017) The conservation status of oak species of Iran. Nature of Iran. 2(1), 82-9. [In Persian].
Poljak I, Idzojtic M, Sapic I, Korijan P, Vukelic J (2018) Diversity and structure of Croatian continental and Alpine-Dinaric populations of grey alder (Alnus incana/L./Moench subsp. incana): Isolation by distance and environment explains phenotypic divergence. Sumarski List. 142, 19–31.
Routson KJ, Volk GM, Richards, CM, Smith SE, Nabhan GP, de Echeverria VW (2012) Genetic variation and distribution of pacific crabapple. Journal of the American Society for Horticultural Science. 137, 325–332.
Shiran B, Mashayekhi S, Jahanbazi H, Soltani A, Bruschi P (2011) Morphological and molecular diversity among populations of Quercus brantii Lindl. in western forest of Iran. Plant Biosystems. 145, 452–460.
Taleshi H, Maasoumi Babarabi M (2013) Leaf morphological variation of Quercus brantii Lindl. Along an altitudinal gradient in Zagros forests of Fars Province, Iran. European Journal of Experimental Biology. 3(5), 463-468.
Thammanu S, Marod D, Han H, Bhusal N, Asanok L, Ketdee P (2021) The influence of environmental factors on species composition and distribution in a community forest in Northern Thailand. Journal of Forestry Research. 32, 649–662.
Thomas CL, Alcock TD, Graham NS, Hayden R, Matterson S, Wilson L, Young SD, Dupuy LX, White PJ, Hammond JP (2016) Root morphology and seed and leaf ionomic traits in a Brassica napus L. diversity panel show wide phenotypic variation and are characteristic of crop habit. BMC Plant Biology. 16, 214. doi: 10.1186/s12870-016-0902-5
Vahdati K (2014) Traditions and folks for walnut growing around the Silk Road. Acta Horticulturae 1032, 19-24.
Vahdati K, Bavani AR, Khosh-Khui M, Fakour P, Sarikhani S. (2019) Applying the AOGCM-AR5 models to the assessments of land suitability for walnut cultivation in response to climate change: A case study of Iran. PloS ONE. 14(6), e0218725
Vacek Z, Vacek S, Bılek L, Remes J, Stefancı kI (2015) Changes in horizontal structure of natural beech forests on an altitudinal gradient in the Sudetes. Dendrobiology. 73, 33–45.
Vitasse Y, Lenz A, Keorner C (2014) The interaction between freezing tolerance and phenology in temperate deciduous trees. Frontiers in Plant Science. 5, 54.
Willig MR, Kaufman DM, Stevens RD (2003) Latitudinal gradients of biodiversity: Pattern, process, scale, and synthesis. Annual Review of Ecology, Evolution, and Systematics. 34, 273–309.
Woz A (2015) Quantitative and qualitative differences in morphological traits of endocarps revealed between Cornus L. species. 291–308.
Xu X, Wang Z, Rahbek C, Sanders NJ, Fang F (2016) Geographical variation in the importance of water and energy for oak diversity. Journal of Biogeography. 43(2), 279-288. doi: 10.1111/jbi.12620
Zanne AE, Tank DC, Cornwell WK, Eastman JM, Smith SA, FitzJohn RG, McGlinn DJ, O’meara BC, Moles AT, Reich PB (2014) Three keys to the radiation of angiosperms into freezing environments. Nature. 506, 89–92.
Zappia L and Oshlack A (2018) Clustering trees: a visualization for evaluating clusterings at multiple resolutions. Giga Science. 7, 1-9.
Zeinalabedini M, Majidian P, Ashori R, Gholaminejad A, Ebrahimi MA, Martinez-Gomez P (2019) Integration of molecular and geographical data analysis of Iranian Prunus scoparia populations in order to assess genetic diversity and conservation planning. Scientia Horticulturae. 247, 49–57.