Geographic patterns and ecological causes of phylogenetic structure in mosses along an elevational gradient in the central Himalaya

doi:10.1016/j.pld.2024.07.005

Abstract

Abstract: Understanding the underlying mechanisms driving species assembly along elevational gradients is of great interest in ecology and biogeography. The Himalaya is one of the world’s hotspots of biodiversity, and the elevational gradient of the central Himalaya in Nepal is one of the longest elevational gradients in the world. Mosses are important constituents of vegetation in the Himalaya, and knowledge of geographic patterns and ecological causes of phylogenetic structure of mosses along elevational gradients in the Himalaya is critical to understanding the assembly of plant diversity in general, and moss diversity in particular, in the Himalaya. Here, we investigate the relationships of phylogenetic structure metrics reflecting different evolutionary depths with elevation and climatic variables representing mean temperature and precipitation conditions, climate extremes, and climate seasonality for mosses distributed along an elevational gradient spanning about 5000 m in the central Himalaya, Nepal. For a given climatic variable, different metrics of phylogenetic structure show different spatial and climatic patterns, but all phylogenetic metrics standardized for species richness show that phylogenetic dispersion in moss assemblages tend to increase with increasing elevation and decreasing temperature. The standardized effect size of mean pairwise distance of moss assemblages shows a triphasic (zig-zag) pattern, which is generally consistent with the triphasic patterns previously found in angiosperms and ferns along the same elevational gradient. Our study shows that temperature-related variables and climate seasonality variables are more important drivers of phylogenetic dispersion in mosses in Nepal, compared with precipitation-related variables and climate extreme variables, respectively.

Key words: Bryophyte, Climatic gradient, Nepal, Niche evolution, Phylogenetic diversity, Phylogenetic relatedness

Hong Qian, Oriol Grau. Geographic patterns and ecological causes of phylogenetic structure in mosses along an elevational gradient in the central Himalaya[J]. Plant Diversity, 2025, 47(01): 98-105.

References

Bhattarai, K.R., Vetaas, O.R., Grytnes, J.A., 2004. Fern species richness along a central Himalayan elevational gradient, Nepal. J. Biogeogr. 31, 389-400.
Brinda, J.C., Atwood, J.J., 2023. Bryophyte Nomenclator. In: Banki, O., Roskov, Y., Doring, M., et al., Catalogue of Life Checklist (Jan 2023). https://doi.org/10.48580/dfqt-8zm.
Cadotte, M.W., Davies, T.J., 2016. Phylogenies in Ecology: A Guide to Concepts and Methods Princeton University Press, Princeton and Oxford.
Cai, L., Kreft, H., Taylor, et al., 2023. Global models and predictions of plant diversity based on advanced machine learning techniques. New Phytol. 237, 1432-1445.
Faith, D.P., 1992. Conservation evaluation and phylogenetic diversity. Biol. Conserv. 61, 1-10.
Fritz, S.A., Rahbek, C., 2012. Global patterns of amphibian phylogenetic diversity. J. Biogeogr. 39, 1373-1382.
Grau, O., Grytnes, J.-A., Birks, H.J.B., 2007. A comparison of altitudinal species richness patterns of bryophytes with other plant groups in Nepal, central Himalaya. J. Biogeogr. 34, 1907-1915.
Jin, Y., Qian, H., 2022. V.PhyloMaker2: An updated and enlarged R package that can generate very large phylogenies for vascular plants. Plant Divers. 44, 335-339.
Jin, Y., Qian, H., 2023. U.PhyloMaker: An R package that can generate large phylogenetic trees for plants and animals. Plant Divers. 45, 347-352.
Kamilar, J.M., Guidi, L.M., 2010. The phylogenetic structure of primate communities: variation within and across continents. J. Biogeogr. 37, 801-813.
Karger, D.N., Conrad, O., Bohner, J., et al., 2017. Climatologies at high resolution for the earth’s land surface areas. Sci. Data 4, Article number: 170122.
Kattel, L.P., Adhikari, M.K., 1992. Mosses of Nepal. Natural History Society of Nepal, Kathmandu.
Legendre, P., Legendre, L., 2012. Numerical Ecology, 3rd edn. Elsevier, Amsterdam.
Lehtonen, S., Jones, M.M., Zuquim, G., et al., 2015. Phylogenetic relatedness within Neotropical fern communities increases with soil fertility. Global Ecol. Biogeogr. 24, 695-705.
Li, L., Xu, X., Qian, H., et al., 2022. Elevational patterns of phylogenetic structure of angiosperms in a biodiversity hotspot in eastern Himalaya. Divers. Distrib. 28, 2534-2548.
Lu, L.-M., Mao, L.-F., Yang, T., et al., 2018. Evolutionary history of the angiosperm flora of China. Nature, 554, 234-238.
Mazel, F., Davies, T.J., Gallien, L., et al., 2016. Influence of tree shape and evolutionary time-scale on phylogenetic diversity metrics. Ecography, 39, 913-920.
Myers, N., Mittermeier, R.A., Mittermeier, C.G., et al., 2000. Biodiversity hotspots for conservation priorities. Nature, 403, 853-858.
Patterson, B.D., Pacheco, V., Solari, S., 1996. Distributions of bats along an elevational gradient in the Andes of south-eastern Peru. J. Zool. 240, 637-658.
Qian, H., Chen, S., 2016. Reinvestigation on species richness and environmental correlates of bryophytes at a regional scale in china. J. Plant Ecol. 9, 734-741.
Qian, H., Ricklefs, R.E., 2016. Out of the tropical lowlands: latitude versus elevation. Trends Ecol. Evol. 31, 738-741.
Qian, H., Sandel, B., Deng, T., et al., 2019. Geophysical, evolutionary and ecological processes interact to drive phylogenetic dispersion in angiosperm assemblages along the longest elevational gradient in the world. Bot. J. Linn. Soc. 190, 333-344.
Qian, H., Jin, Y., 2021. Are phylogenies resolved at the genus level appropriate for studies on phylogenetic structure of species assemblages? Plant Divers. 43, 255-263.
Qian, H., Kessler, M., Deng, T., et al., 2021. Patterns and drivers of phylogenetic structure of pteridophytes in China. Global Ecol. Biogeogr. 30, 1835-1846.
Qian, H., Kessler, M., Vetaas, O.R., 2022. Pteridophyte species richness in the central Himalaya is limited by cold climate extremes at high elevations, and rainfall seasonality at low elevations. Ecol. Evol. 12, e8958.
Qian, H., Kessler, M., Jin, Y., 2023. Spatial patterns and climatic drivers of phylogenetic structure for ferns along the longest elevational gradient in the world. Ecography, e06516.
Rahbek, C., Borregaard, M.K., Colwell, R.K., et al., 2019. Humboldt’s enigma: What causes global patterns of mountain biodiversity? Science, 365, 1108-1113.
Rana, S.K., Price, T.D., Qian., H., 2019. Plant species richness across the Himalaya driven by evolutionary history and current climate. Ecosphere, 10, Article e02945.
Ricklefs, R.E., 1987. Community diversity: relative roles of local and regional processes. Science, 235, 167-171.
Ricklefs, R.E., 2004. A comprehensive framework for global patterns in biodiversity. Ecol. Lett. 7, 1-15.
Sanbonmatsu, K.K., Spalink, D., 2022. A global analysis of mosses reveals low phylogenetic endemism and highlights the importance of long-distance dispersal. J. Biogeogr. 49, 654-667.
Sandel, B., Weigelt, P., Kreft, H., et al., 2020. Current climate, isolation and history drive global patterns of tree phylogenetic endemism. Global Ecol. Biogeogr. 29, 4-15.
Shaw, A.J., Cox, C.J., Goffinet, B., 2005. Global patterns of moss diversity: taxonomic and molecular inferences. Taxon, 54, 337-352.
Takhtajan, A.L., 1969. Flowering plants: origin and dispersal. Oliver & Boyd, Edinburgh.
Tsirogiannis, C., Sandel, B., 2016. PhyloMeasures: a package for computing phylogenetic biodiversity measures and their statistical moments. Ecography 39:709-714.
Webb, C.O., Ackerly, D.D., Kembel, S.W., 2008. Phylocom: software for the analysis of phylogenetic community structure and trait evolution. Bioinformatics, 24, 2098-2100.
Weigelt, P., Kissling, W.D., Kisel, Y., et al., 2015. Global patterns and drivers of phylogenetic structure in island floras. Sci. Rep. 5, 12213.
Wiens, J.J., Donoghue, M.J., 2004. Historical biogeography, ecology, and species richness. Trends Ecol. Evol. 19, 639-644.
Wilkinson, L., Hill, M., Welna, J.P., et al., 1992. SYSTAT for Windows: statistics SYSTAT Inc., Evanston.
Wu, E.T.Y., Liu, Y., Jennings, L., et al., 2022. Detecting the phylogenetic signal of glacial refugia in a bryodiversity hotspot outside the tropics. Divers. Distrib. 28, 2681-2695.
Zhang, J., Qian, H., 2023. U.Taxonstand: An R package for standardizing scientific names of plants and animals. Plant Divers. 45, 1-5.

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[13]	MA Wen-Zhang-, James R. SHEVOCK. New Distributional Records of Two Monotypic Moss Genera Arthrocormus and Noguchiodendron in China [J]. Plant Diversity, 2015, 37(4): 389-395.
[14]	MA Wen-Zhang-, LIU Wen-Yao. Species Composition and Distribution of Bryophytes on Different Substrate Types in Middle Mountain Moist Evergreen Broadleaved Forest in Ailao Mountains [J]. Plant Diversity, 2011, 33(4): 443-450.
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