Composition and structure of plant communities in the Moist Temperate Forest Ecosystem of the Hindukush Mountains, Pakistan

Matiullah,; Rahman, A. U.; Ullah, Z.; Qureshi, R.; Burslem, D. F. R. P.; Mashwani, Z. U. R.

doi:10.1590/1519-6984.266637

Abstract

Here, we investigated the relationship between Plant communities and the environment from the moist temperate vegetation of Lakoo mountainous forest District Swat. We sampled data from 162 sampling units (Quadrates) using 1x1m² for herbs 5x5m² and shrubs, while 10 x10m² for trees, systematically considering six elevation gradients between the altitudinal from 1970m to 3095m. We performed statistical analysis like Canonical correspondence analysis (CCA) and TWINSPAN (two-way indicator species analysis) for ecological assessment and clustering of plant communities. To check upon the correlation of species (CR) with topographic and edaphic variables we used statistical software PC-ORD version 7. We recognized 264 species plants belonging to thirty families. We recorded key sampling measurements of density, frequency, and cover for all these species which are vital for community description. The results showed Shannon-Winner^,s, and Simpson diversity values as 19.18 and 3.17 respectively. The importance value indexes (IVI) were used to identify the leading and rare species of plant in each community or cluster group. In total we recognized eleven different communities as: Berberis- Abies- Bergeni, Picea - Indigofera- Poa,Abies- Parrotiopsis- Poa, Quercus- Viburnum- Poa, Picea- Salix- Primula, Abies- Viburnum- Poa, Viburnum- Taxus- Poa, Pinus- Viburnum- Lithospermum, Abies-Berberis- carex, Pinus- Viburnum- Poa and Parrotiopsis- Picea- Poa through hierarchical cluster analysis (TWINSPAN). CCA analysis revealed that of all studied edaphic and topographic variables altitude, silt, calcium carbonate, and organic matter were the strongest factors determining plant community diversity and composition in each microclimate of the eleven communities. Visually the vegetation of the forest was dominated by small-sized trees followed by shrubs, and regenerates indicating the stage of secondary regeneration. We found severe human interference in disturbing the existing biodiversity, which requires immediate conservation to ensure sustainable management and utilization of natural resources of the Lalkoo moist temperate forest.

Keywords:
phytosociology; Lalkoo moist temperate forest; floristic pattern; indicator species; plant communities

Resumo

Aqui, investigamos a relação entre as comunidades vegetais e o meio ambiente da vegetação temperada úmida da floresta montanhosa de Lalkoo, distrito de Swat. Foram amostrados dados de 162 unidades amostrais (quadrados) utilizando 1 x 1 m² para ervas, 5 x 5 m² para arbustos e 10 x 10 m² para árvores, considerando sistematicamente seis gradientes de altitude entre 1.970 m e 3.095 m. Realizamos análises estatísticas, como análise de correspondência canônica (CCA) e TWINSPAN (análise de espécies indicadoras de duas vias), para avaliação ecológica e agrupamento de comunidades de plantas. Para verificar a correlação das espécies (CR) com as variáveis topográficas e edáficas, foi utilizado o software estatístico PC-ORD, versão 7. Foram reconhecidas 264 espécies de plantas pertencentes a 30 famílias. Registramos as principais medições de amostragem de densidade, frequência e cobertura para todas essas espécies que são vitais para a descrição da comunidade. Os resultados mostraram valores de diversidade de Shannon-Wiener e Simpson de 19,18 e 3,17, respectivamente. Os índices de valor de importância (IVI) foram usados para identificar as espécies de plantas principais e raras em cada comunidade ou grupo de cluster. No total, reconhecemos 11 comunidades diferentes, como: Berberis-Abies-Bergeni, Picea-Indigofera-Poa, Abies-Parrotiopsis-Poa, Quercus-Viburnum-Poa, Picea-Salix-Primula, Abies-Viburnum-Poa, Viburnum-Taxus-Poa, Pinus-Viburnum-Lithospermum, Abies-Berberis-Carex, Pinus-Viburnum-Poa e Parrotiopsis-Picea-Poa, por meio de análise de agrupamento hierárquico (TWINSPAN). A análise de CCA revelou que, de todas as variáveis edáficas e topográficas estudadas, altitude, silte, carbonato de cálcio e matéria orgânica foram os fatores mais fortes na determinação da diversidade e composição da comunidade vegetal em cada microclima das 11 comunidades. Visualmente a vegetação da floresta foi dominada por árvores de pequeno porte, seguidas de arbustos, e se regenera, indicando o estágio de regeneração secundária. Encontramos grave interferência humana na biodiversidade existente, o que requer conservação imediata para garantir o manejo sustentável e a utilização dos recursos naturais da floresta temperada úmida de Lalkoo.

Palavras-chave:
fitossociologia; floresta temperada úmida de Lalkoo; padrão florístico; espécies indicadoras; comunidades vegetais

1. Introduction

Plant community assessments and structural studies of vegetation along ecological gradients are one of the most significant topics in community ecology (Peters et al., 2019PETERS, M.K., HEMP, A., APPELHANS, T., BECKER, J.N., BEHLER, C., CLASSEN, A., DETSCH, F., ENSSLIN, A., FERGER, S.W., FREDERIKSEN, S.B., GEBERT, F., GERSCHLAUER, F., GÜTLEIN, A., HELBIG-BONITZ, M., HEMP, C., KINDEKETA, W.J., KÜHNEL, A., MAYR, A.V., MWANGOMO, E., NGEREZA, C., NJOVU, H.K., OTTE, I., PABST, H., RENNER, M., RÖDER, J., RUTTEN, G., SCHELLENBERGER COSTA, D., SIERRA-CORNEJO, N., VOLLSTÄDT, M.G.R., DULLE, H.I., EARDLEY, C.D., HOWELL, K.M., KELLER, A., PETERS, R.S., SSYMANK, A., KAKENGI, V., ZHANG, J., BOGNER, C., BÖHNING-GAESE, K., BRANDL, R., HERTEL, D., HUWE, B., KIESE, R., KLEYER, M., KUZYAKOV, Y., NAUSS, T., SCHLEUNING, M., TSCHAPKA, M., FISCHER, M. and STEFFAN-DEWENTER, I., 2019. Climate-land-use interactions shape tropical mountain biodiversity and ecosystem functions. Nature, vol. 568, no. 7750, pp. 88-92. http://dx.doi.org/10.1038/s41586-019-1048-z. PMid:30918402.
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http://dx.doi.org/10.15666/aeer/1605_561... ). The study of plant associations and their classification is related to the field phytosociology while vegetation in the strict sense is the ecological quantification of plant resources (Timilehin et al., 2017TIMILEHIN, K.E., OLAJIDE, O.S., ADEMAYOWA, O. and OLUSANYA, O., 2017. Floristic composition and structural diversity of Ibodi Monkey Forest, Ibodi, Southwestern Nigeria. Pakistan Journal of Botany, vol. 49, no. 4, pp. 1359-1371.; Ali et al., 2018ALI, A., BADSHAH, L. and HUSSAIN, F., 2018. Vegetation structure and threats to Montane Temperate Ecosystems in Hindukush Range, Swat, Pakistan. Applied Ecology and Environmental Research, vol. 16, no. 4, pp. 4789-4811. http://dx.doi.org/10.15666/aeer/1604_47894811.
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http://dx.doi.org/10.1080/20964129.2017.... ) and availability of light (Bonari et al., 2017BONARI, G., ACOSTA, A.T. and ANGIOLINI, C., 2017. Mediterranean coastal pine forest stands: understory distinctiveness or not? Forest Ecology and Management, vol. 391, pp. 19-28. http://dx.doi.org/10.1016/j.foreco.2017.02.002.
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http://dx.doi.org/10.1038/s41586-019-104... ).

A community is a cluster of plant species that present fundamental functional units both spatially and temporally, which have a direct relation to seasonal differences and sampling periods (Ali et al., 2018ALI, A., BADSHAH, L. and HUSSAIN, F., 2018. Vegetation structure and threats to Montane Temperate Ecosystems in Hindukush Range, Swat, Pakistan. Applied Ecology and Environmental Research, vol. 16, no. 4, pp. 4789-4811. http://dx.doi.org/10.15666/aeer/1604_47894811.
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http://dx.doi.org/10.15666/aeer/1704_990... ). Species diversity plays a key role in biodiversity conservation supervision and most effectively as an indicator of community constancy in most of moist temperate and temperate forests (Shaheen et al., 2011aSHAHEEN, H., KHAN, S.M., HARPER, D.M., ULLAH, Z. and QURESHI, R.A., 2011a. Species diversity, community structure, and distribution patterns in western Himalayan alpine pastures of Kashmir, Pakistan. Mountain Research and Development, vol. 31, no. 2, pp. 153-159. http://dx.doi.org/10.1659/MRD-JOURNAL-D-10-00091.1.
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http://dx.doi.org/10.15666/aeer/1604_478... ). Community structure, distribution pattern, and vegetative function are the greatest ecological features of forest ecosystems (Zhang et al., 2006ZHANG, X., WANG, M., SHE, B. and XIAO, Y., 2006. Quantitative classification and ordination of forest communities in Pangquangou National Nature Reserve. Acta Ecologica Sinica, vol. 26, no. 3, pp. 754-761. http://dx.doi.org/10.1016/S1872-2032(06)60013-9.
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http://dx.doi.org/10.15666/aeer/1604_478... ). Understanding how diverse community processes interact is not only fascinating in itself but is also essential for predicting how communities will respond to various environmental conditions. Therefore distribution pattern of plant species in a community is a function of surrounding environmental variables (Weiher and Howe 2003WEIHER, E. and HOWE, A., 2003. Scale-dependence of environmental effects on species richness in oak savannas. Journal of Vegetation Science, vol. 14, no. 6, pp. 917-920. http://dx.doi.org/10.1111/j.1654-1103.2003.tb02226.x.
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http://dx.doi.org/10.1111/j.1469-185X.20... ). Therefore, it is necessary for understanding plant community composition and distribution, along an elevation gradient in forest ecosystems (Zhang et al., 2006ZHANG, X., WANG, M., SHE, B. and XIAO, Y., 2006. Quantitative classification and ordination of forest communities in Pangquangou National Nature Reserve. Acta Ecologica Sinica, vol. 26, no. 3, pp. 754-761. http://dx.doi.org/10.1016/S1872-2032(06)60013-9.
http://dx.doi.org/10.1016/S1872-2032(06)... ; Bonari et al., 2017BONARI, G., ACOSTA, A.T. and ANGIOLINI, C., 2017. Mediterranean coastal pine forest stands: understory distinctiveness or not? Forest Ecology and Management, vol. 391, pp. 19-28. http://dx.doi.org/10.1016/j.foreco.2017.02.002.
http://dx.doi.org/10.1016/j.foreco.2017.... ; Li et al., 2017LI, W., CUI, L., SUN, B., ZHAO, X., GAO, C., ZHANG, Y., ZHANG, M., PAN, X., LEI, Y. and MA, W., 2017. Distribution patterns of plant communities and their associations with environmental soil factors on the eastern shore of Lake Taihu, China. Ecosystem Health and Sustainability, vol. 3, no. 9, pp. 1385004. http://dx.doi.org/10.1080/20964129.2017.1385004.
http://dx.doi.org/10.1080/20964129.2017.... ). Environmental gradients like topographic and edaphic factors (Zhang and Zhang, 2011ZHANG, J.T. and ZHANG, F., 2011. Ecological relations between forest communities and environmental variables in the Lishan mountain nature reserve, China. African Journal of Agricultural Research, vol. 6, no. 2, pp. 248-259.; Khadanga and Jayakumar 2020KHADANGA, S.S. and JAYAKUMAR, S., 2020. Tree biomass and carbon stock: understanding the role of species richness, elevation, and disturbance. Tropical Ecology, vol. 61, no. 1, pp. 128. http://dx.doi.org/10.1007/s42965-020-00070-0.
http://dx.doi.org/10.1007/s42965-020-000... ) influence plant community structures in forests (Ullah et al., 2015ULLAH, Z., AHMAD, M., SHER, H., SHAHEEN, H. and KHAN, S.M., 2015. Phytogeographic analysis and diversity of grasses and sedges (Poales) of northern Pakistan. Pakistan Journal of Botany, vol. 47, pp. 93-104.; Ismail et al., 2019ISMAIL, A.H., LIM, C.C. and OMAR, W.M.W., 2019. Evaluation of spatial and temporal variations in zooplankton community structure with reference to water quality in Teluk Bahang Reservoir, Malaysia. Tropical Ecology, vol. 60, no. 2, pp. 186-198. http://dx.doi.org/10.1007/s42965-019-00023-2.
http://dx.doi.org/10.1007/s42965-019-000... ; Zeb et al., 2020ZEB, A., IQBAL, Z., KHAN, S.M., RAHMAN, I.U., HAQ, F., AFZAL, A., QADIR, G. and IJAZ, F., 2020. Species diversity, biological spectrum and phenological behaviour of vegetation of Biha Valley (Swat). Acta Ecologica Sinica, vol. 40, no. 3, pp. 190-196. http://dx.doi.org/10.1016/j.chnaes.2019.05.004.
http://dx.doi.org/10.1016/j.chnaes.2019.... ). Research has shown that the patterns of vegetation are widely influenced by ecological factors, such as regional topography features (such as aspect and slope), edaphic factors, and anthropogenic pressure (Rahman et al., 2021RAHMAN, A., KHAN, S.M., AHMAD, Z., ALAMRI, S., HASHEM, M., ILYAS, M., AKSOY, A., DÜLGEROĞLU, C. and SHAHAB ALI, G.K., 2021. Impact of multiple environmental factors on species abundance in various forest layers using an integrative modeling approach. Global Ecology and Conservation, vol. 29, e01712. http://dx.doi.org/10.1016/j.gecco.2021.e01712.
http://dx.doi.org/10.1016/j.gecco.2021.e... ). Relation of vegetation attributes, indicator values (predictable richness), and ecological gradients establish various community structures (Ullah et al., 2015ULLAH, Z., AHMAD, M., SHER, H., SHAHEEN, H. and KHAN, S.M., 2015. Phytogeographic analysis and diversity of grasses and sedges (Poales) of northern Pakistan. Pakistan Journal of Botany, vol. 47, pp. 93-104.; Iqbal et al., 2018IQBAL, Z., ZEB, A., ABD_ALLAH, E.F., RAHMAN, I.U., KHAN, S.M., ALI, N., IJAZ, F., ANWAR, Y., MUZAMMIL, S., ALQARAWI, A.A., HASHEM, A., AFZAL, A., MAJID, A., KHAN, M.A. and CALIXTO, E.S., 2018. Ecological assessment of plant communities along the edaphic and topographic gradients of biha valley, district swat, Pakistan. Applied Ecology and Environmental Research, vol. 16. http://dx.doi.org/10.15666/aeer/1605_56115631.
http://dx.doi.org/10.15666/aeer/1605_561... ; Ismail et al., 2019ISMAIL, A.H., LIM, C.C. and OMAR, W.M.W., 2019. Evaluation of spatial and temporal variations in zooplankton community structure with reference to water quality in Teluk Bahang Reservoir, Malaysia. Tropical Ecology, vol. 60, no. 2, pp. 186-198. http://dx.doi.org/10.1007/s42965-019-00023-2.
http://dx.doi.org/10.1007/s42965-019-000... ). In an ecosystem indicator species monitor outcoming changes in the component of plant associations that result from various environmental factors which are fundamental baselines in management decisions (Zhang and Zhang, 2011ZHANG, J.T. and ZHANG, F., 2011. Ecological relations between forest communities and environmental variables in the Lishan mountain nature reserve, China. African Journal of Agricultural Research, vol. 6, no. 2, pp. 248-259.; Li et al., 2017LI, W., CUI, L., SUN, B., ZHAO, X., GAO, C., ZHANG, Y., ZHANG, M., PAN, X., LEI, Y. and MA, W., 2017. Distribution patterns of plant communities and their associations with environmental soil factors on the eastern shore of Lake Taihu, China. Ecosystem Health and Sustainability, vol. 3, no. 9, pp. 1385004. http://dx.doi.org/10.1080/20964129.2017.1385004.
http://dx.doi.org/10.1080/20964129.2017.... ; Rahman et al., 2020RAHMAN, A.U., KHAN, S.M., SAQIB, Z., ULLAH, Z., AHMAD, Z., EKERCIN, S., MUMTAZ, A.S. and AHMAD, H., 2020. Diversity and abundance of climbers in relation to their hosts and elevation in the monsoon forests of Murree in the Himalayas. Pakistan Journal of Botany, vol. 52, no. 2, pp. 601-612. http://dx.doi.org/10.30848/PJB2020-2(17).
http://dx.doi.org/10.30848/PJB2020-2(17)... ).

An elevation gradient is a composite environmental gradient (Zhang et al., 2006ZHANG, X., WANG, M., SHE, B. and XIAO, Y., 2006. Quantitative classification and ordination of forest communities in Pangquangou National Nature Reserve. Acta Ecologica Sinica, vol. 26, no. 3, pp. 754-761. http://dx.doi.org/10.1016/S1872-2032(06)60013-9.
http://dx.doi.org/10.1016/S1872-2032(06)... ; Körner, 2007KÖRNER, C., 2007. The use of ‘altitude’ in ecological research. Trends in Ecology & Evolution, vol. 22, no. 11, pp. 569-574. http://dx.doi.org/10.1016/j.tree.2007.09.006. PMid:17988759.
http://dx.doi.org/10.1016/j.tree.2007.09... ) that offers a supreme prospect for critically observing species diversity and shaping the composition of plant communities. Variations in elevation, slopes, and aspects also enhance diversity in various plant communities (Arora, 2002ARORA, V., 2002. Modeling vegetation as a dynamic component in soil‐vegetationatmosphere transfer schemes and hydrological models. Reviews of Geophysics, vol. 40, no. 2, pp. 3-1-3-26. http://dx.doi.org/10.1029/2001RG000103.
http://dx.doi.org/10.1029/2001RG000103... ; Rahman et al., 2020RAHMAN, A.U., KHAN, S.M., SAQIB, Z., ULLAH, Z., AHMAD, Z., EKERCIN, S., MUMTAZ, A.S. and AHMAD, H., 2020. Diversity and abundance of climbers in relation to their hosts and elevation in the monsoon forests of Murree in the Himalayas. Pakistan Journal of Botany, vol. 52, no. 2, pp. 601-612. http://dx.doi.org/10.30848/PJB2020-2(17).
http://dx.doi.org/10.30848/PJB2020-2(17)... ). In tropical rain forests these gradients are measured as natural monitoring sites where drivers of community distribution patterns and ecosystem functions can be assessed over small geographical reserves (Li et al., 2017LI, W., CUI, L., SUN, B., ZHAO, X., GAO, C., ZHANG, Y., ZHANG, M., PAN, X., LEI, Y. and MA, W., 2017. Distribution patterns of plant communities and their associations with environmental soil factors on the eastern shore of Lake Taihu, China. Ecosystem Health and Sustainability, vol. 3, no. 9, pp. 1385004. http://dx.doi.org/10.1080/20964129.2017.1385004.
http://dx.doi.org/10.1080/20964129.2017.... ; Körner et al., 2017KÖRNER, C., JETZ, W., PAULSEN, J., PAYNE, D., RUDMANN-MAURER, K. and SPEHN, E., 2017. A global inventory of mountains for bio-geographical applications. Alpine Botany, vol. 127, no. 1, pp. 1-15. http://dx.doi.org/10.1007/s00035-016-0182-6.
http://dx.doi.org/10.1007/s00035-016-018... ; Veintimilla et al., 2019VEINTIMILLA, D., NGO BIENG, M.A., DELGADO, D., VILCHEZ-MENDOZA, S., ZAMORA, N. and FINEGAN, B., 2019. Drivers of tropical rainforest composition and alpha diversity patterns over a 2,520 m altitudinal gradient. Ecology and Evolution, vol. 9, no. 10, pp. 5720-5730. http://dx.doi.org/10.1002/ece3.5155. PMid:31160993.
http://dx.doi.org/10.1002/ece3.5155... ).

A great concern emerged in ecological and environmental sciences about the strong relationship between biodiversity and ecological factors. Regionally Moist temperate forests with high altitudes in Hindukush-Himalaya are the most liable vegetation to environmental change (Salick et al., 2009SALICK, J., FANG, Z. and BYG, A., 2009. Eastern Himalayan alpine plant ecology, Tibetan ethnobotany, and climate change. Global Environmental Change, vol. 19, no. 2, pp. 147-155. http://dx.doi.org/10.1016/j.gloenvcha.2009.01.008.
http://dx.doi.org/10.1016/j.gloenvcha.20... ; Shaheen et al., 2015SHAHEEN, H., SARWAR, R., FIRDOUS, S.S., DAR, M.E.I., ULLAHAND, Z. and KHAN, S.M., 2015. Distribution and structure of conifers with special emphasis on Taxusbaccata in moist temperate forests of Kashmir Himalayas. Pakistan Journal of Botany, vol. 47, pp. 71-76.). Among different ecological factors, elevation is the most essential ecological factor that monitors species and plant community diversity. Especially in plant community ecology, a lot of work has been carried out on the relationship between species diversity, community diversity, and elevation gradient (Donoghue, 2008DONOGHUE, M.J., 2008. A phylogenetic perspective on the distribution of plant diversity. Proceedings of the National Academy of Sciences of the United States of America, vol. 105, suppl. 1, pp. 11549-11555. http://dx.doi.org/10.1073/pnas.0801962105. PMid:18695216.
http://dx.doi.org/10.1073/pnas.080196210... ; Li and Feng, 2015LI, M. and FENG, J., 2015. Biogeographical interpretation of elevational patterns of genus diversity of seed plants in Nepal. PLoS One, vol. 10, no. 10, e0140992. http://dx.doi.org/10.1371/journal.pone.0140992. PMid:26488164.
http://dx.doi.org/10.1371/journal.pone.0... ; Kluge et al., 2017KLUGE, J., WORM, S., LANGE, S., LONG, D., BÖHNER, J., YANGZOM, R. and MIEHE, G., 2017. Elevational seed plants richness patterns in Bhutan, Eastern Himalaya. Journal of Biogeography, vol. 44, no. 8, pp. 1711-1722. http://dx.doi.org/10.1111/jbi.12955.
http://dx.doi.org/10.1111/jbi.12955... ; Lei et al., 2020LEI, W., YANG, J., LI, H. and ZHANG, C., 2020. Effects of environmental factors on species diversity among the plant communities in the mount Lao nature reserve, Shandong province of China. Pakistan Journal of Botany, vol. 52, no. 4, pp. 1205-1213. http://dx.doi.org/10.30848/PJB2020-4(42).
http://dx.doi.org/10.30848/PJB2020-4(42)... ). This indicates that distribution patterns and richness of plant species with elevation frequently vary along various transects and at various spatial scales in vegetation (Nogués-Bravo et al., 2008NOGUÉS-BRAVO, D., ARAÚJO, M.B., ROMDAL, T. and RAHBEK, C., 2008. Scale effects and human impact on the elevational species richness gradients. Nature, vol. 453, no. 7192, pp. 216-219. http://dx.doi.org/10.1038/nature06812. PMid:18464741.
http://dx.doi.org/10.1038/nature06812... ; Rowe and Lidgard, 2009ROWE, R.J. and LIDGARD, S., 2009. Elevational gradients and species richness: do methods change pattern perception? Global Ecology and Biogeography, vol. 18, no. 2, pp. 163-177. http://dx.doi.org/10.1111/j.1466-8238.2008.00438.x.
http://dx.doi.org/10.1111/j.1466-8238.20... ).

In Pakistan, moist temperate forests like Lalkoo valley are rich biodiversity hotspots of the great mountain ranges of Hindukush-Himalaya (Ahmad et al., 2016AHMAD, K.S., HAMEED, M., AHMAD, F. and SADIA, B., 2016. Edaphic factors as major determinants of plant distribution of temperate Himalayan grasses. Pakistan Journal of Botany, vol. 48, no. 2, pp. 567-573.). However, some phytosociological work regarding the establishment of plant communities along an elevation gradient in moist temperate forests has been reported in some countries around the world. The pioneering work of these includes Ahmad (2009)AHMAD, S.S., 2009. Ordination and classification of herbaceous vegetation in Margalla Hills National Park Islamabad Pakistan. Biological Diversity and Conservation, vol. 2, no. 2, pp. 38-44. and Siddiqui et al. (2010)SIDDIQUI, M.F., AHMED, M., SHAUKAT, S.S. and KHAN, N., 2010. Advanced multivariate techniques to investigate vegetation-environmental complex of pine forests of moist temperate areas of Pakistan. Pakistan Journal of Botany, vol. 42, pp. 267-293. used multivariate statistical analysis to inspect the vegetation-environmental complex of blue pine forests of moist temperate zones in Pakistan. Similarly, Shaheen et al. (2015)SHAHEEN, H., SARWAR, R., FIRDOUS, S.S., DAR, M.E.I., ULLAHAND, Z. and KHAN, S.M., 2015. Distribution and structure of conifers with special emphasis on Taxusbaccata in moist temperate forests of Kashmir Himalayas. Pakistan Journal of Botany, vol. 47, pp. 71-76. documented species distribution patterns and community structures of conifers in moist temperate forests of the Kashmir Himalayas, and Dhyani and Dhyani (2016)DHYANI, S. and DHYANI, D., 2016. Significance of provisioning ecosystem services from moist temperate forest ecosystems: lessons from upper Kedarnath valley, Garhwal, India. Energy, Ecology & Environment, vol. 1, no. 2, pp. 109-121. http://dx.doi.org/10.1007/s40974-016-0008-9.
http://dx.doi.org/10.1007/s40974-016-000... reported ecosystem provisioning services from moist temperate forest ecosystems in India. We aimed to investigate changes in plant community dynamics along altitudinal and edaphic gradients in Lalkoo moist temperate forest, in Pakistan.

2. Material and Methods

The investigated area Lalkoo is a mountainous moist temperate type of forest, located in the Swat district Hindukush belt of north Pakistan. The area is 60 km from the capital city Mingora/Saidu Sharif. Geographically Lalkoo area lies within the coordinates of 35°08' 27.62”N and 72°23'09.12 ” E with an altitudinal range starting from about 1581m.a.s.l., and reaches the highest peak of alpine pastures of 3849 m.a.s.l. The area with a monsoon belt consists of moist temperate forests (Beg and Khan, 1974BEG, A. and KHAN, A., 1974. Flora of Malakand Division, part 1 (A). Pakistan Journal of Forest, vol. 24, pp. 171-185.; Ullah et al., 2015ULLAH, Z., AHMAD, M., SHER, H., SHAHEEN, H. and KHAN, S.M., 2015. Phytogeographic analysis and diversity of grasses and sedges (Poales) of northern Pakistan. Pakistan Journal of Botany, vol. 47, pp. 93-104.). The annual temperature of the investigated area was recorded at 13.96-22.25 °C. The mean annual rainfall (RF) is 1777mm. The RF was recorded in July and August with a mean total RF of 228.9mm and 220.9mm while minimum RF occurred in November and December which is recorded at 42.4mm and 78.4mm (Data source PMD; http://www.pmd.gov.pk). Lalkoo valley lies in the Sino-Japanese (SJ) phytogeographical region (Ilyas et al., 2015ILYAS, M., QURESHI, R., AKHTAR, N., MUNIR, M. and HAQ, Z., 2015. Vegetation analysis of Kabal valley, district Swat, Pakistan using multivariate approach. Pakistan Journal of Botany, vol. 47, pp. 77-86.). The investigated area is covered with undulating slopes and ridges covered with thick vegetation in the sub-alpine zone and scrubs and meadows in alpine pastures. Current work on Lalkoo valley is mainly concerned with the establishment of plant communities and distribution patterns in correlation with environmental variables (Zhang et al., 2006ZHANG, X., WANG, M., SHE, B. and XIAO, Y., 2006. Quantitative classification and ordination of forest communities in Pangquangou National Nature Reserve. Acta Ecologica Sinica, vol. 26, no. 3, pp. 754-761. http://dx.doi.org/10.1016/S1872-2032(06)60013-9.
http://dx.doi.org/10.1016/S1872-2032(06)... ; Sanders and Rahbek, 2012SANDERS, N.J. and RAHBEK, C., 2012. The patterns and causes of elevational diversity gradients. Ecography, vol. 35, no. 1, pp. 1-3. http://dx.doi.org/10.1111/j.1600-0587.2011.07338.x.
http://dx.doi.org/10.1111/j.1600-0587.20... ; Li et al., 2017LI, W., CUI, L., SUN, B., ZHAO, X., GAO, C., ZHANG, Y., ZHANG, M., PAN, X., LEI, Y. and MA, W., 2017. Distribution patterns of plant communities and their associations with environmental soil factors on the eastern shore of Lake Taihu, China. Ecosystem Health and Sustainability, vol. 3, no. 9, pp. 1385004. http://dx.doi.org/10.1080/20964129.2017.1385004.
http://dx.doi.org/10.1080/20964129.2017.... ).

The phytosociological work of the study area was carried out systematically in six altitudinal transects based on, species richness and diversity, habitats, and physiognomic contrasts. Density (D), Frequency (F), and Cover (C) for each plant species was recorded to attain Importance values (IV) for the establishment of various community patterns (Figure 1). Geographical coordinates of each study site were recorded using Global Position System (GPS). The formation of various plant communities was based on the highest importance values (IV) calculated for each specie following (Badshah et al., 2016BADSHAH, L., HUSSAIN, F. and SHER, Z., 2016. Floristic inventory, ecological characteristics and biological spectrum of plants of Parachinar, Kurram agency, Pakistan. Pakistan Journal of Botany, vol. 48, no. 4, pp. 1547-1558.; Forzieri et al., 2011FORZIERI, G., DEGETTO, M., RIGHETTI, M., CASTELLI, F. and PRETI, F., 2011. Satellite multispectral data for improved floodplain roughness modelling. Journal of Hydrology, vol. 407, no. 1-4, pp. 41-57. http://dx.doi.org/10.1016/j.jhydrol.2011.07.009.
http://dx.doi.org/10.1016/j.jhydrol.2011... ; Ilyas et al., 2015ILYAS, M., QURESHI, R., AKHTAR, N., MUNIR, M. and HAQ, Z., 2015. Vegetation analysis of Kabal valley, district Swat, Pakistan using multivariate approach. Pakistan Journal of Botany, vol. 47, pp. 77-86.; Ali et al., 2018ALI, A., BADSHAH, L. and HUSSAIN, F., 2018. Vegetation structure and threats to Montane Temperate Ecosystems in Hindukush Range, Swat, Pakistan. Applied Ecology and Environmental Research, vol. 16, no. 4, pp. 4789-4811. http://dx.doi.org/10.15666/aeer/1604_47894811.
http://dx.doi.org/10.15666/aeer/1604_478... ). Total area quantification was assessed by species-area curve by using statistical software PC-ORD version 7.0 (Figure 2).

Figure 1
Samping sites in Lalkoo valley.

Figure 2
Species area curve obtained from 264 plant species in Lalkoo valley.

Plant communities, organization, distribution, and diversity were evaluated along an altitudinal gradient from1970 to 3120m in 54 sites in Lalkoo valley. For detailed data, collection vegetation was systematically divided into

For detailed data, collection vegetation was systematically divided into 6 altitudinal transects, each one with 9 plots (resulting in 54 sampling units), and in each plot you established 3 quadrats - one for each strata for herbs, shrubs, and trees (Kent and Coker, 1992KENT, M. and COKER, P., 1992. Vegetation description and analysis: a practical approach. New York: John Wiley & Sons.). Vegetation was analyzed by using quadrates 1 × 1 m² designed for herbs, 5 × 5 m² designed for shrubs and 10 × 10 m² for tree species, at each site. To each sampling site, relative and absolute values of density (D), frequency (F), and cover (C) along with their IVI values were recorded following the procedure of Curtis and McIntosh (1950)CURTIS, J.T. and MCINTOSH, R., 1950. The interrelations of certain analytic and synthetic phytosociological characters. Ecology, vol. 31, no. 3, pp. 434-455. http://dx.doi.org/10.2307/1931497.
http://dx.doi.org/10.2307/1931497... and Kamran et al. (2019)KAMRAN, S., KHAN, S.M., AHMAD, Z., RAHMAN, A.U., IQBAL, M., MANAN, F., HAQ, Z.U. and ULLAH, S., 2019. The role of graveyards in species conservation and beta diversity: a vegetation appraisal of sacred habitats from Bannu, Pakistan. Journal of Forestry Research, vol. 30, no. 4, pp. 1147-1158. http://dx.doi.org/10.1007/s11676-019-00893-1.
http://dx.doi.org/10.1007/s11676-019-008... .

During the study 264 plant species were documented in 162 quadrates. The slope and aspect were recorded with the help of a digital compass, elevation was measured by altimeter and the depth of soil (DS) was calculated with a 2m iron rod and ruler of 36Cm was used for analysis of depth of litter (DL). Index of Diversity (D) was measured by using methodology of Simpson (1949)SIMPSON, E.H., 1949. Measurement of diversity. Nature, vol. 163, no. 4148, pp. 688. http://dx.doi.org/10.1038/163688a0.
http://dx.doi.org/10.1038/163688a0... and Shannon (1948)SHANNON, C.E., 1948. A mathematical theory of communication. The Bell System Technical Journal, vol. 27, no. 3, pp. 379-423. http://dx.doi.org/10.1002/j.1538-7305.1948.tb01338.x.
http://dx.doi.org/10.1002/j.1538-7305.19... for each stand as (Equation 1):

D i v e r s i t y I n d e x (D) = \frac{\sum n (n - 1)}{N (N - 1)}

(1)

were, D stands for index of diversity, n represents the sum of individuals of a particular species, and N is the sum of individuals of all species.

The Shannon Wiener index ( $H^{,}$ ) is the measure of the average degree of uncertainty in expecting what species of an individual selected at arbitrary from a sampling unit will fit to (Shannon 1948SHANNON, C.E., 1948. A mathematical theory of communication. The Bell System Technical Journal, vol. 27, no. 3, pp. 379-423. http://dx.doi.org/10.1002/j.1538-7305.1948.tb01338.x.
http://dx.doi.org/10.1002/j.1538-7305.19... ).

If pi is the proportion of individuals from overall samples of species i, then Shannon Wiener indexes of diversity H' is (Equation 2).

H^{,} = \sum_{i = 1}^{S} p i p i l n p i

(2)

Multivariate analyses were carried out for clustering plant communities by using polythetic diverse classification TWINSPAN- Two-way Indicator Species Analysis (Hill, 1979HILL, M.O., 1979. TWINSPAN, a FORTRAN program for two-way-indicator-species-analysis. Ithaca: Cornell University.). The soil texture (Sand %, Silt %, Clay %) was determined by technique as described by Koehler et al. (1984)KOEHLER, F.E., MOUDRE, C.D. and MCNEAL, B.L., 1984. Laboratory manual for soil fertility. Pulman: Washington State University, pp. 456-461. Other factors determined were Potassium mg/Kg), Phosphorus mg/Kg) and Nitrogen % (Soltanpour, 1991SOLTANPOUR, P.N., 1991. Determination of nutrient availability and elemental toxicity by AB-DTPA soil test and ICPS. In: B.A. STEWART, ed. Advances in soil science. New York: Springer, pp. 165-190.; Rahman et al., 2016RAHMAN, A.U., KHAN, S.M., KHAN, S., HUSSAIN, A., RAHMAN, I.U., IQBAL, Z. and IJAZ, F., 2016. Ecological assessment of plant communities and associated edaphic and topographic variables in the Peochar Valley of the Hindu Kush mountains. Mountain Research and Development, vol. 36, no. 3, pp. 332-341. http://dx.doi.org/10.1659/MRD-JOURNAL-D-14-00100.1.
http://dx.doi.org/10.1659/MRD-JOURNAL-D-... ), EC dSm-1 (Wilson and Bayley, 2012WILSON, M.J. and BAYLEY, S.E., 2012. Use of single versus multiple biotic communities as indicators of biological integrity in northern prairie wetlands. Ecological Indicators, vol. 20, pp. 187-195. http://dx.doi.org/10.1016/j.ecolind.2012.02.009.
http://dx.doi.org/10.1016/j.ecolind.2012... ), CaCO3% (Black, 1965BLACK, C.A., 1965. Particle fractionation and particle-size analysis. In: C.A. BLACK, ed. Methods of soil analysis part 1, physical and mineralogical properties including statistics of measurement and sampling. Madison: American Society of Agronomy, pp. 550-551.), Organic matter % (Nelson and Sommers, 1982NELSON, D.W. and SOMMERS, L.E. 1982. Total carbon, organic carbon and organic matter. In: In: A.L. PAGE, R.H. MILLER and D.R. KEENEY, eds. Methods of soil analysis. Madison: American Society of Agronomy, Soil Science Society of America, vol. 2, pp. 539-579.), pH (McLean, 1982MCLEAN, E.O., 1982. Soil pH and lime requirement: chemical and microbiological properties. In: A.L. PAGE, R.H. MILLER and D.R. KEENEY, eds. Methods of soil analysis. Madison: American Society of Agronomy, Soil Science Society of America, vol. 2, pp. 199-224.), Grazing class1≤5, Anthropogenic pressure/ Deforestation class1≤5, EC dSm-1 (Rahman et al., 2021RAHMAN, A., KHAN, S.M., AHMAD, Z., ALAMRI, S., HASHEM, M., ILYAS, M., AKSOY, A., DÜLGEROĞLU, C. and SHAHAB ALI, G.K., 2021. Impact of multiple environmental factors on species abundance in various forest layers using an integrative modeling approach. Global Ecology and Conservation, vol. 29, e01712. http://dx.doi.org/10.1016/j.gecco.2021.e01712.
http://dx.doi.org/10.1016/j.gecco.2021.e... ). Species-environmental correlations were assessed by applying CCA- canonical correspondence analysis using PC-ORD Version 7.0 (McCune and Mefford, 1999MCCUNE, B. and MEFFORD, M.J., 1999. PC-ORD: multivariate analysis of ecological data. Version 4 for Windows. User's guide. Gleneden Beach: MjM Software Design.) to categorize main plant clusters entitled plant communities (Haq et al., 2017HAQ, F., AHMAD, H., IQBAL, Z., ALAM, M. and AKSOY, A., 2017. Multivariate approach to the classification and ordination of the forest ecosystem of Nandiar valley western Himalayas. Ecological Indicators, vol. 80, pp. 232-241. http://dx.doi.org/10.1016/j.ecolind.2017.05.047.
http://dx.doi.org/10.1016/j.ecolind.2017... ). The computation cluster was done on resemblance via Sorenson Distance Measurements, using Ward’s linkage method and IVI (Greig- Smith 1983GREIG-SMITH, P., 1983. Quantitative plant ecology. 3rd ed. Berkeley: University of California Press.; Siddiqui et al., 2010SIDDIQUI, M.F., AHMED, M., SHAUKAT, S.S. and KHAN, N., 2010. Advanced multivariate techniques to investigate vegetation-environmental complex of pine forests of moist temperate areas of Pakistan. Pakistan Journal of Botany, vol. 42, pp. 267-293.; Haq, 2018HAQ, F., 2018. Vegetation mapping above tree line in Nandiar valley, western Himalayas: a multivariate approach. Acta Ecologica Sinica, vol. 38, no. 1, pp. 15-20. http://dx.doi.org/10.1016/j.chnaes.2017.09.005.
http://dx.doi.org/10.1016/j.chnaes.2017.... ). For authentic clustering of distributed plant species, the most accurate and accepted analyses TWINSPAN- Two-way Indicator Species Analysis, correlation analysis, and CCA- Canonical Correspondence Analysis were in common practice in the community ecology were followed (Ahmad, 2009AHMAD, S.S., 2009. Ordination and classification of herbaceous vegetation in Margalla Hills National Park Islamabad Pakistan. Biological Diversity and Conservation, vol. 2, no. 2, pp. 38-44. and Siddiqui et al., 2010SIDDIQUI, M.F., AHMED, M., SHAUKAT, S.S. and KHAN, N., 2010. Advanced multivariate techniques to investigate vegetation-environmental complex of pine forests of moist temperate areas of Pakistan. Pakistan Journal of Botany, vol. 42, pp. 267-293.).

3. Results

3.1. Plant community classification

Clustering describes the unsupervised learning task of partitioning observations into homogenous subsets, or clusters, to uncover subpopulation structure in a dataset. Hierarchical cluster analysis (TWINSPAN) classified 264 plant species into eleven community types by using PC-ORD 7. Figure 3. A comprehensive explanation of these community types concerning associated species of plants and ecological edaphic and topographic variables (Supplementary material 1).

Figure 3
Cluster Dendrogram indicating 11 plant association types in the Lalkoo Valley.

3.2. Berberis -Abies -Bergenia community (BAB)

BAB community was established in 06 sampling sites comprising 47 species of plant and is located from 2125-2240m, latitude (35°08'45.95” - 35°09'36.58”N) and longitude (72°23'17.47” -72°23'19.08 “E). The leading indicator species of this association were Berberis lyceum (35.02 IVI), Abies pindrow (107.1 IVI), Bergenia ciliate (14.2 IVI) as indicated in Table 1 Other most co-dominant shrubs were Rubus sanctus (23.3 IVI), Indigofera heterantha (41.7 IVI). Herbs of this community with the highest importance values were Agrostis tenella (12.5 IVI), Carex remota (10.4), Pseudomartensia parvifolia (9.7), Polygonum alpinum (8.2 IVI), Microstegium nudum (8.2 IVI), Plantago lanceolata (7.5 IVI), Rumex hastatus (7.4 IVI), Thlaspi arvense (7.4 IVI), Veronica anagalis-aquatica (7.2 IVI), Androsace rotundifolia (14.2 IVI) . The trees were Celtis australis (22.2 IVI) and Juglans regia (22.2 IVI). Due to large number of the co-dominant/ associated species, so they are resented in supplementary material 3. The soil of this community was sandy loam with slightly acidic (pH 4.9-4.3) and contained 6.8±2.3% organic matter, potassium 132.67-87.37 mg/Kg, 9.3-7.9% calcium carbonate, phosphorous 3.09-1.72 mg/Kg, nitrogen 0.35-0.13%, EC 0.27-0.27dSm^-1. The content of silt, sand, and clay was 51.7-31.2%, 37.7-15.1%, and 6.3-2.7% respectively. This community was under high grazing (GP=4), and deforestation pressure (DP=5) as presented in Supplementary material 1.

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Table 1
Overall indicator species from eleven plant communities with the highest importance value index (IVI) in Lalkoo valley.

3.3. Picea- Indigofera- Poa community (PIP)

Picea- Indigofera- Poa association was evaluated in 21 sampling sites between the elevation range of 2125-3045m. A total of 67 plant species were recorded in PIP community; Picea smithiana was the leading specie with the highest IVI value (76.6) followed by Indigofera heterantha (41.7) and Poa alpine (38.9). Tree species of this association were Abies pindrow (107.1), Alnus nitida (32.8 IVI), Taxus wallichina (23.5 IVI), and Quercus baloot (22.5 IVI) were stands as Co-dominant. While Viburnum grandiflorum (19.9 IVI), Andrachne cordifoli (33.1 IVI), and Thalictrum cultratum (31.1 IVI) were co-dominant shrubby vegetation in the study area. Topmost common co-dominant herbs (supplementary material 3) recorded were Plantago major (19.9 IVI), Plantago lanceolata (17.6 IVI), Poa bulbosa (14.6 IVI), Achillea ambugas (10.7 IVI), Bergenia ciliata (14.2 IVI) and Polygonum aviculare (9.1 IVI) as presented (supplementary material 3). Overall, some herbs were found with the lowest importance values (rare species) including Ajuga parviflora (2.7 IVI), Bistorta amplexcaulis (2.2 IVI), Bromus pectinatus (2.7 IVI), Poa nemoralis (22.6 IVI), Poa supina (10 IVI), Viola biflora (2.2 IVI) and Stellaria media (2.9 IVI).

Soil content of Picea- Indigofera- Poa association was loamy with a slightly acidic nature having a pH of 5.3-4.6. Soil texture content includes silt (41.7-32.2%), clay (8.2-4.7%) and sand (31.3-13.3%). Electrical conductivity 0.33-0.11 dSm^-1 was recorded. The soil contained 3.63-1.83 mg/Kg phosphorus, 0.31-0.18% nitrogen, 135.45±86.787 mg/Kg potassium, 8.9-3.7% calcium carbonate and 3.1-2.3% organic matter. PIP association was recorded under the low effect of grazing pressure(GP=2) and deforestation pressure (DP=1).

3.4. Abies - Parrotiopsis - Poa community (APP)

This community was distributed from 2092-3095m, latitude (35°08'15.23”- 35°09'39.83”N) and longitude (72°23'39.01” -72°20'59.96 “E).The leading species of APP community were A-pindrow, P-jacquemontiana and P-alpina having importance values 107.1, 70.3 and 38.9 respectively. The second most diagnostic tree species were Quercus dilatata (74.3 IVI) and Pinus wallichiana (123.2 IVI). The second most leading shrubby plant species were Viburnum grandiflorum (19.9 IVI), Juniperus communis (25.9 IVI) and Rhamnus purpurea (23.2 IVI), while herbs were Poa nemoralis (13.7 IVI), Valariana jatamansi (10.2 IVI), Agrostis tenella (10.2 IVI), Filipendula ulmaria (9.3 IVI), Aconitum violaceum (8.4 IVI), Anaphalis nepelnsis (2.4 IVI), Ipomoea hederacea (8.3 IVI) and Poa annua (8.2 IVI) . Very rare species of APP were Gagea elegans (3.4 IVI), Gallium asplenioides (3.4 IVI), Justicia adhatoda (3.3 IVI), Arisaema flavum (3.1 IVI) and Swertia ciliate (3.0 IVI). The soil was mostly silt loam that contained 3.9-2.5% organic matter, 9.3-2.4% calcium carbonate, 167.23-71.34 mg/Kg potassium, 0.6-0.17% nitrogen, 2.3-1.84 mg/Kg phosphorus and 4.9-6.1 pH. Soil content with silt, clay and sand were 53.5-37.9%, 6.3-2.9%, 21.5-15.6% respectively. Grazing was low while deforestation pressure was slightly moderate (Supplementary material 1).

3.5. Quercus - Viburnum - Poa community (QVP)

QVP community existed in high elevation flora between 2368-2920m with latitude (35°09'12.32” - 35°09'15.16”N) and longitude (72°24'45.50” - 72°20'39.43”E). The prominant (Table 1) dominant species includes Quercus dilatata (74.3 IVI), Viburnum cotinifolium (54.3 IVI) and Poa alpina (38.9 IVI). The co-dominant herbs included Rumex nepalensis (17.5 IVI), Persicaria capitate (15.4 IVI), Potentilla atrosanguinea (15.2 IVI), Digitaria ciliaris (15.1 IVI), Viola canescens (12.2 IVI), Potentilla nepalensis (11.6 IVI) and Nepeta laevigata (11.4 IVI). Common representative co-dominant trees were Quercus semecarpifolia (50.25 IVI) and shrubs with importance values were Salix acmophylla (28.9 IVI), Parthenocissus semicordata (37.5 IVI) and Buxus wallichiana (34.6 IVI). Soil of QVP community the was slightly acidic with percentage of 39.4-16.7 sand, 5.3-2.7 clay, 93.1-31.9 silt. Recorded phosphorus values of soil were 3.09-1.91 mg/Kg, potassium 135.45-61.56 mg/Kg, EC were 0.17-0.007 dSm^-1, nitrogen 0.38-0.18%, organic matter 2.8-2.3% and CaCO3% were 7.5-3.6% (Supplementary material 1).

3.6. Picea - Salix -Primula community (PSP)

Picea - Salix -Primula possesses an average number of 81 plant species concerning other community types in the study area. This association was found in 12 sampling sites accompanied by 81 plant species located between 2087-2865m. The representative indicator species of this vegetation type were Picea smithiana, Salix acmophylla and Primula rosea with the highest importance values (76.6 IVI), (28.9 IVI) and (7.3 IVI) respectively. The second topmost dominant species of trees were Abies pindrow (107.1 IVI) and Pinus wallichiana (123.2 IVI) while shrubby vegetation included Viburnum cotinifolium (54.3 IVI), Parrotiopsis jacquemontiana (70.3 IVI), Indigofera heterantha (41.7 IVI) and Zanthoxylum armatum (24.9 IVI). Among 55 herb species of PSP association 6 plant species were co-dominant of which Ajuga bracteosa (6.2 IVI), Carex schlagintweitiana (5.5 IVI), Solena amplexicaulis (5.2 IVI), Veronica anagalis-aquatica (5.2 IVI), Impatiens edgeworthi (4.8 IVI) and Plantago lanceolate (4.6 IVI). The loamy soil of PSP community contained 10.3-2.4% calcium carbonate, 133.4±113.57 mg/Kg potassium, 3.23-1.91 mg/Kg phosphorus, 0.29-0.14%nitrogen, 2.9-2.1% organic matter and EC 0.19-0.07 dSm^-1. Soil pH values were 6.2-4.5 with clay 7.3-2.4%, sand 29.7-15.3% and silt 39.6-33.7%. The community was affected by moderate grazing and deforestation.

3.7. Abies - Viburnum - Poa community (AVP)

This Plant community were found between 2198-2635m, latitude (35°08'15.10”- 35°09'34.94”N) and longitude (72°23'91.95” -72°21'59.83 “E). Based on 15 investigated sites this community contained a maximum number of 101 plant species including 10 trees, 22 shrubs and 69 herbs. The topmost dominant species of this plant community were Abies pindrow (107.1 IVI), Viburnum cotinifolium (54.3 IVI) and Poa alpina (38.9 IVI). The top most co-dominant herb species of AVP community were Polygonum plebeium (10.6 IVI), Rumex nepalensis (8.6 IVI), Poa annua (54.4 IVI), Carex infuscate (7.2 IVI), Bromus japonicas (7.1 IVI), Potentilla nepalensis (6.8 IVI), Bergenia ciliate (14.2 IVI), Swertia ciliate (5.8 IVI), Potentilla atrosanguinea (5.8 IVI), Medicago polymorpha (5.7 IVI), Ajuga bracteosa (5.4 IVI), Ajuga bracteosa (5.3 IVI), Polygala abyssinica (5.3 IVI), Pimpinella stewartii (5.3 IVI), Poa bulbosa (5.3 IVI) and Origanum vulgare (5.1 IVI). Among trees (supplementary material 3) Picea smithiana (76.6 IVI) were found second most dominant plant species. AVP plant community with co-dominant shrubby flora included Sarcococca saligna (22.3 IVI), Rhamnus purpurea (20.2 IVI), Andrachne cordifolia (19.2 IVI), Salix acmophylla (28.9 IVI) and Buxus wallichiana (15.5 IVI). The soil was silt loamy that contained 13.3-3.7% calcium carbonate, 139.05-88.23mg/Kg potassium, 2.67-1.82mg/Kg phosphorus, 0.2-0.11%nitrogen, 3.7-2.1% organic matter and EC 0.29-0.007 dSm^-1. Soil pH value were 4.9-4.1 with clay 5.8-3.3%, sand 32.4-17.7% and silt 57.5-38.4%. AVP community was under moderate deforestation (DP) and very low grazing pressure (GP).

3.8. Viburnum - Taxus - Poa community (VTP)

A total of 24 sampling sites were clustered in this association by TWINSPAN. In comparison with other community types, VTP was a unique association with the highest recorded 141 plant species. The top 3 indicator species of this association were Viburnum cotinifolium, Taxus wallichina and, Poa supine with importance values of 42.1, 23.5 and 10 respectively. Co-dominant trees were Ilex dipyrena (21.5 VI), Aesculus indica (17.6 IVI) and Pyrus pashia (18.7 IVI), however Diospyros lotus (5.9 IVI), Quercus dilatata (5.9 IVI) and Alnus nitida (4.7 IVI) were rare species of this association. Co-dominant shrubs with high IVI values were Parrotiopsis jacquemontiana (23.9 IVI), Indigofera heterantha (23.6 IVI) and Rhamnus purpurea (22.8 IVI) while H. nepalensis, R. alpestre, R. ellipticus and Z. armatum were rare most shrubs of this community. Among 106 herbs second high IVI values were found for Hypericum perforatum (8.1 IVI), Primula denticulate (5.9 IVI) and Cynodon dactylon (5.0 IVI) while 28 plant species were lowest IVI values equal to 1of which A. mutica, A. vulgaris, A. grahamianus, B. pectinatus, V.thapsus, T. minuta, S. laureola, S. auriculata, P. eriocarpa, P. eriocarpa and P. nepalensis were prominent rare species. The soil were mostly loamy and slightly acidic (pH 5.2-4.3) with silt 36.1-31.1%, clay 7.6-4.9% and sand 35.5-13.3%. Soil also contained 5.7-2.3% organic matter, 12.3-3.5% calcium carbonate, EC 0.18-0.09 dSm^-1, 115.27-71.34mg/Kg potassium, 0.6-0.27% nitrogen, 3.03-1.72mg/Kg phosphorus. Grazing pressure was high with moderate deforestation.

3.9. Pinus -Viburnum -Lithospermum community (PVL)

This is a unique association with the greater number of 126 plant species which represents the best growth of vegetation. The community is situated at lower altitudes between 2000-2230m. The highest importance value 46.2 were recorded for Pinus wallichiana that stands 1^st dominant among 14 tree species, 19.6 for Viburnum grandiflorum as 1^st dominant among 23shrub species and 6.7 Lithospermum arvense as 1^st dominant among 89 herb species. The 2^nd most dominant tree species were Pyrus pashia(44.6 IVI), Ficus carica(29.6 IVI), Ailanthus altissima (27.3 IVI), Diospyros lotus L.(26.6 IVI) and Platinus orientale(26.6 IVI). 2^nd most dominant shrubs with nearest importance values were 19.1,18.6,16.5,16.3,16.3 were recorded for C. microphyllus, B. parkeriana, J. humile, S. saligna and S. canescens respectively (supplementary material 3). Recorded 2^nd dominant 6 herbs were V. jatamansi(5.9 IVI), V. thapsus (5.9 IVI), G. ocillatum(5.3 IVI), S. urticifolia(5.2 IVI), T. royleanum(5.1 IVI) and S. auriculata(5.0 IVI). Overall, 5 plant species Anaphalis triplinervis, Arisaema flavum, Artemisia japonica, Arthraxon prionodes and Festuca gigantean of PVL association type with lowest importance values were rare. PVL community contained silty loam soil that highly acidic (pH 3.7-4.6) and contained 3.9-2.5% organic matter, potassium 155.52-85.37mg/Kg, 7.9-3.5% calcium carbonate, phosphorous 2.1-1.23mg/Kg, nitrogen 0.37-0.24%, EC 0.26-0.11 dSm^-1. Silt, sand and clay values were 43.7-36.1%, 39.4-15.6% and 7.1-3.7% respectively. The community is under severe grazing and deforestation pressure(DP) however terrain cultivation was common to this community.

3.10. Abies - Berberis - Carex community (ABC)

ABC community was recognized in 18 sampling sites started in the lower elevation range of 1970m at Dunkacha area, with latitude(35°08'08.48” - 35°09'16.81”N) and reaches at higher elevation range at Julba area, with longitude (72°22'28.35” -72°21'06.09 “E). TWINSPANS clustered a total of 62 plant species for ABC plant community. The leading dominant tree species of this community were Abies pindrow (95.5 IVI) followed by a shrub specie Berberis pseudoumbellta (37.1 IVI) and the herb specie Carex cardiolepis (16.7 IVI). The topmost leading co-dominant 4 tree species with importance values were Abies pindrow (95.5 IVI), Picea smithiana (56.6 IVI), Quercus semecarpifolia (33.1 IVI) and Pinus wallichiana (32.2 IVI). Among shrubs Parrotiopsis jacquemontiana (36.1 IVI), Viburnum cotinifolium (32.6 IVI) and Daphne mucronata (26.9 IVI) were recorded as the top most co-dominant species. While Plantago major with IVI 14.6, Oxalis corniculata with IVI 13.2, Heliotropium strigosum IVI 12.9 and Bergenia ciliate with IVI 12.1 were stood second co-dominant herbs of this community. In overall recorded species of ABC community A. pubiflora with IVI 2.8 and F. nubicola with IVI 2.9 were highly rare (supplementary material 3). In this community the soil contained sand 31.5-15.3%, clay 5.3-2.9%, silt 44.6-31.9%, 5.3-4.8% calcium carbonate, 143.27-73.97mg/Kg potassium, 3.09-1.83mg/Kg phosphorus, 0.36-0.18%nitrogen, 4.6-2.9% organic matter and EC 0.26-0.11 dSm^-1. Soil were comparatively neutral with pH value of 7.3-4 while deforestation and grazing pressure was moderate with the high frequency of regenerates.

3.11. Pinus -Viburnum - Poa community (PVP)

Pinus -Viburnum - Poa community is located at altitude of 2000-2345m. Pinus wallichiana leading specie with 123.2 IVI value followed by Viburnum cotinifolium (35.1) and Poa nemoralis(22.6). The recorded 16 samplings sites of PVP plant community in the investigated area 3 tree species included Quercus incana (36.1 IVI), Abies pindrow (26.1 IVI), and Aesculus indica (22.1 IVI) while among shrubs Parrotiopsis jacquemontiana (26.4 IVI), Rubus ellipticus(22.5 IVI) and Indigofera heterantha (20.8 IVI) represents co-dominant species.Of total 65 herb species of PVP community type Poa annua (21.9 IVI) Paeonia emodi(10.2.4 IVI) and Chrozophora tinctoria (7.9 IVI) were the second co-dominant species. Moreover of total of 99 plant species Sisymbrium orientale, Sigesbekia orientalis, Sambucus wightiana, Fumaria indica, Aquilegia pubiflora, Bidens tripartite were the most commonly rare occurring species.The silty loam soil of Pinus -Viburnum - Poa community contained 13.5±5.6% calcium carbonate, 133.4-74.12mg/Kg potassium, 2.67-1.84mg/Kg phosphorus, 0.35-0.18%nitrogen, 6.7-2.3% organic matter and EC 0.25-0.13 dSm^-1. Soil was slightly acidic properties with a content of clay 6.7-2.9%, sand 35.5-15.7%, and silt 93.5-37.3%. The community were under low grazing and high deforestation pressure (Supplementary material 1).

3.12. Parrotiopsis- Picea- Poa community (PPP)

PPP is a unique community association with 15 sampling sites included 14 tree species,12 herbs and 39 shrubs located within altitudinal range of 2085-2920m, latitude(35°08'20.77” - 35°09'04.34”N) and longitude(72°22'48.75” -72°24'45.48 “E).Followed by TWINSPAN cluster analysis this community type is accompanied by dominant species Parrotiopsis jacquemontiana, Picea smithiana, and Poa annua with IVI values 70.3,68.1, and 54.1 respectively. Other 2^nd leading co-dominant species of shrubs were Zanthoxylum armatum (27.3 IVI), Andrachne cordifolia (40.6 IVI) and Cotoneaster affinities (21.1 IVI) followed by 2 tree species were Abies pindrow (51.26 IVI) and Taxus wallichina (46.0 IVI). The topmost herb species including Swertia chordata (14.8 IVI), Ajuga bracteosa (12.1 IVI), and Viola canescens (11.1 IVI) were occurring as co-dominant of PPP association.

Soil were slightly acidic with silt 47.8-36.1%,clay 4.7-3.4 and sand 21.5-15.1%. Soil chemical content were 3.5-2.1% organic matter, 6.7-2.4% calcium carbonate, EC.18-0.07, 98 dSm^-1. Major soil content were 23-61.56mg/Kg potassium, 0.6-.23% nitrogen, 2.89-1.91mg/Kg phosphorus (Supplementary material 1).

3.13. Plant community diversity parameters

Shannon’s diversity index for all species shows significant differences among different plant associations and presents a gradual increase from lower altitude to higher altitudes. Values obtained from the analysis of Shannon-Wiener and Simpson indices were used for measurements of diversity among different plant communities presented in Table 2. Of the total eleven plant communities, Picea- Indigofera- Poa, Quercus -Viburnum - Poa, and Berberis- Abies- Bergenia represents the lowest Shannon diversity values 0.76, 1.2 and 1.50 respectively. Hence strength of diversity become increases for certain communities like Abies- Parrotiopsis- Poa (2.42), and Abies- Viburnum- Poa(2.03), Viburnum- Taxus- Poa(2.50) and Pinus- Viburnum- Lithospermum(2.65). However, four plant communities of the study site were significantly highest diversity values from 3.6 -3.99 for community types Abies-Berberis-Carex, Parrotiopsis-Picea-Poa, Pinus-Viburnum-Poa, and Picea- Salix - Primula that indicates overall potential diversity.

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Table 2
Calculated values of Diversity indices from Lalkoo valley Swat.

Simpson^, s diversity index for all plant species shows the remarkable differences among distributed groups. These differences are indeed related to human interference like deforestation and grazing intensity. Concerning the vertical structure of the study area, this index shows a significant difference only in the Pinus- Viburnum- Lithospermum community with a maximum value D= 0.99 as presented in Table 1. However Berberis-Abie- Bergenia, Abies- Parrotiopsis- Poa(APP-III), Viburnum- Taxus- Poa (VTP-VII) and Pinus- Viburnum- Poa stands average Simpson^, s diversity values from 0.99 - 0.91 .More Plant community Parrotiopsis- Picea- Poa stands the lowest value of Simpson^, s diversity (0.87).

3.14. Canonical correspondence analysis

For investigation, the effects of eleven environmental variables(EV) on the distribution patterns of plant communities Canonical correspondence analysis (CCA) was used (Figures 4-6). Analysis of CCA model (11-Environmental variables) revealed variation of 3.8 Axis -1, 3.3 Axis -2, and 2.9 Axis -3 alone of total unexplained variance (Figure 4 and supplementary material 2). The total variance (“inertia”) of CCA data was 8.578. The main patterns in plant community distribution in the overall data set of CCA reflect on silt, altitude, and calcium carbonate. Silt represents a strong positive correlation on Parrotiopsis - Picea - Poa (PPP) community and a negative with Berberis- Abies- Bergenia (BAB) along Axis-2. Interestingly PPP community shows potential growth toward high altitudes (2920m) while BAB community towards lower altitudes (2085m) as presented in Figure 5. While Abies- Parrotiopsis- Poa(APP) shows a strong negative correlation with Axis -1 influenced by calcium carbonate. Similarly, Picea- Indigofera- Poa community affected by altitude shows a strong positive correlation with Axis -1. Most of the plant communities were clustered around the center of the ordination axis (Figure 4 and supplementary material 2) while among all environmental variables phosphorous was found negligible influence on the distribution of plant communities.

Figure 4
Results of CCA joint biplot showing results for eleven plant communities’ correlation with environmental variable. BAB-I: Berberis- Abies- Bergenia; PIP-II: Picea-Indigofera- Poa; APP-III: Abies- Parrotiopsis- Poa,QVP-IV:Quercus-Viburnum-Poa,PSP-V:Picea-Salix-Primula,AVP-VI:Abies-Viburnum -Poa; VTP-VII: Viburnum-Taxus-Poa; PVL-VIII: Pinus-Viburnum-Lithospermum; ABC-IX: Abies-Berberis-Carex; PVP-X: Pinus-Viburnum-Poa; and PPP-XI: Parrotiopsis-Picea-Poa represents community types.

Figure 6
Analysis of CCA plot illustrating correlation between calciumcarbonate and plant communities along axis-1 and 2.

Figure 5
CCA plot Analysis of illustrating the influence of elevation on spreading pattern of plant communities in Lalkoo valley Swat.

Our study also revealed that, Quercus dilatata, Abies pindrow, Pinus wallichiana and Picea smithiana had high dominance trees in terms of IVI while in shrubs were Berberis lyceum, Indigofera heterantha, and Viburnum cotinifolium and herbs were Poa alpina, and Poa annua (Table 1).

4. Discussion

Multivariate analysis was carried out to examine the distribution and classification of plant communities that vary greatly in Lalkoo Hindukush mountainous range Pakistan. The most important factors controlling this variation is elevation, soil texture, soil organic matter, soil pH, soil electrical conductivity, soil chemical nature topography, and so on among which elevation is a key factor that affect community distribution (Keddy, 1992KEDDY, P.A., 1992. Assembly and response rules: two goals for predictive community ecology. Journal of Vegetation Science, vol. 3, no. 2, pp. 157-164. http://dx.doi.org/10.2307/3235676.
http://dx.doi.org/10.2307/3235676... ; Rahman et al., 2021RAHMAN, A., KHAN, S.M., AHMAD, Z., ALAMRI, S., HASHEM, M., ILYAS, M., AKSOY, A., DÜLGEROĞLU, C. and SHAHAB ALI, G.K., 2021. Impact of multiple environmental factors on species abundance in various forest layers using an integrative modeling approach. Global Ecology and Conservation, vol. 29, e01712. http://dx.doi.org/10.1016/j.gecco.2021.e01712.
http://dx.doi.org/10.1016/j.gecco.2021.e... ).

The systematic classification of plant communities is a basic tool used in vegetation ecology that is subjected for various purposes like conservation, land planning and management data reduction and synthesis that were used by scientists up to date (Diamond, 1975DIAMOND, J.M., 1975. Assembly of species communities. In: M.L. CODY and J.M. DIAMOND, eds. Ecology and evolution of communities. Cambridge: Harvard University Press, pp. 342-444.; Götzenberger et al., 2012GÖTZENBERGER, L., DE BELLO, F., BRÅTHEN, K.A., DAVISON, J., DUBUIS, A., GUISAN, A., LEPŠ, J., LINDBORG, R., MOORA, M., PÄRTEL, M., PELLISSIER, L., POTTIER, J., VITTOZ, P., ZOBEL, K. and ZOBEL, M., 2012. Ecological assembly rules in plant communities: approaches, patterns and prospects. Biological Reviews of the Cambridge Philosophical Society, vol. 87, no. 1, pp. 111-127. http://dx.doi.org/10.1111/j.1469-185X.2011.00187.x. PMid:21692965.
http://dx.doi.org/10.1111/j.1469-185X.20... ; Oyola-Guzman and Oyola-Morales, 2018OYOLA-GUZMÁN, D.R. and OYOLA-MORALES, R., 2018. Implementing a fast, practical, and rational quality control technique at a soil mixture production plant, based on a continuous and quantitative classification of materials: a case study. Case Studies in Construction Materials, vol. 9, e00199. http://dx.doi.org/10.1016/j.cscm.2018.e00199.
http://dx.doi.org/10.1016/j.cscm.2018.e0... ) however traditional classification of plant communities is typically constructed on general features of species assessed by personal experience (Yong-Chang, 2004YONG-CHANG, S., 2004. Tentative classification scheme of evergreen broad-leaved forests of China. Acta Phytoecologica Sinica, vol. 28, no. 4, pp. 435-448. http://dx.doi.org/10.17521/cjpe.2004.0061.
http://dx.doi.org/10.17521/cjpe.2004.006... ; Qin et al., 2016QIN, P.Y., YANG, H.J., JIANG, F.L., ZHANG, S.B., TIAN, X.M., HUANG, X.R. and ZHANG, Z.D., 2016. Quantitative classification of natural plant communities in the Saihanba national nature reserve, Hebei province, China. Ying Yong Sheng Tai Xue Bao, vol. 27, no. 5, pp. 1383-1392. PMid:29732798.). The methods applied in the present analysis provide a baseline for users to provide multiple classification procedures of plant communities for accurate information in future perspectives. The study identified 264 species of vascular plants that were classified in to eleven plant community types (clusters) with different diagnostic species in Lalkoo mountainous forest. Differences among dominant species and forest plant community compositionindicate an influence of environmental, anthropogenic, and topographic factors (Wiens and Donoghue, 2004WIENS, J.J. and DONOGHUE, M.J., 2004. Historical biogeography, ecology and species richness. Trends in Ecology & Evolution, vol. 19, no. 12, pp. 639-644. http://dx.doi.org/10.1016/j.tree.2004.09.011. PMid:16701326.
http://dx.doi.org/10.1016/j.tree.2004.09... ; Khan, 2012KHAN, S., 2012. Plant communities and vegetation ecosystem services in the Naran Valley, Western Himalaya. UK: University of Leicester. PhD. dissertation.; Idowu et al., 2020IDOWU, A.M., OLONIMOYO, E.A., IDOWU, A.M. and AIYESANMI, A.F., 2020. Impact of gas and oil-fired power plants on proximal water and soil environments: case study of Egbin power plant, Ikorodu, Lagos State, Nigeria. SN Applied Sciences, vol. 2, no. 8, pp. 1352. http://dx.doi.org/10.1007/s42452-020-3150-0.
http://dx.doi.org/10.1007/s42452-020-315... ; Ohler et al., 2020OHLER, L.-M., LECHLEITNER, M. and JUNKER, R.R., 2020. Microclimatic effects on alpine plant communities and flower-visitor interactions. Scientific Reports, vol. 10, no. 1, pp. 1366. http://dx.doi.org/10.1038/s41598-020-58388-7. PMid:31992825.
http://dx.doi.org/10.1038/s41598-020-583... ; Rahman et al., 2021RAHMAN, A., KHAN, S.M., AHMAD, Z., ALAMRI, S., HASHEM, M., ILYAS, M., AKSOY, A., DÜLGEROĞLU, C. and SHAHAB ALI, G.K., 2021. Impact of multiple environmental factors on species abundance in various forest layers using an integrative modeling approach. Global Ecology and Conservation, vol. 29, e01712. http://dx.doi.org/10.1016/j.gecco.2021.e01712.
http://dx.doi.org/10.1016/j.gecco.2021.e... ). The dominant plant species of the study area in all communities (1-11) are Berberis, Picea smithiana, Abies pindrow, Abies pindrow, Viburnum grandiflorum Pinus wallichian, and Parrotiopsis jacquemontiana which were also reported for adjacent temperate and moist temperate forests of Pakistan as dominant species in most of the plant communities (Khan, 2012KHAN, S., 2012. Plant communities and vegetation ecosystem services in the Naran Valley, Western Himalaya. UK: University of Leicester. PhD. dissertation.; Habib et al., 2016HABIB, T., MALIK, Z.H., DAR, M.E.U.I. and SHAHEEN, H., 2016. Wood utilization pattern in Kashmir region, western Himalaya. Forest Products Journal, vol. 66, no. 3-4, pp. 257-261. http://dx.doi.org/10.13073/FPJ-D-14-00099.
http://dx.doi.org/10.13073/FPJ-D-14-0009... ; Shaheen et al., 2017SHAHEEN, H., AZIZ, S. and DAR, M.E.U.I., 2017. Ecosystem services and structure of western Himalayan temperate forests stands in Neelum valley, Pakistan. Pakistan Journal of Botany, vol. 49, no. 2, pp. 707-714.). Indigofera, Salix, Taxus, Bergenia, Poa, Carex, Lithospermum, and Primula is representing typical leading species of the study area that have been reported in different plant communities connected to moist temperate forests (Khan et al. 2020KHAN, S.A., KHAN, S.M., ULLAH, Z., AHMAD, Z., ALAM, N., SHAH, S.N., KHAN, R. and ZADA, M., 2020. Phytogeographic classification using multivariate approach; a case study from the Jambil Valley Swat, Pakistan. Pakistan Journal of Botany, vol. 52, no. 1, pp. 279-290. http://dx.doi.org/10.30848/PJB2020-1(11).
http://dx.doi.org/10.30848/PJB2020-1(11)... ).

One of the basic parameters for measurement of plant community structure and composition is the importance value index (IVI), Species with the same IVI have the same or similar population structure (Lamprecht, 1989LAMPRECHT, H., 1989. Silverculture in the tropics: tropical forest ecosystems and their tree species-possibilities and methods for their long-term utilization. Germany: T2 Verlagsgesells chaft GmbH.; Hundera and Gadissa, 2008HUNDERA, K. and GADISSA, T., 2008. Vegetation composition and structure of Belete Forest, Jimma Zone, South western Ethiopia. Ethiopian Journal of Biological Sciences, vol. 7, no. 1, pp. 1-15.) resulting in maximum IVI values ascribed to some species. In comparison to this approach, all studied species showed different ecological importance and difference in relation to their recorded values of IVI. This indicates that these nine plant species are highly ecological significance that is adapted to high ecological amplitude, disturbance, and influence of local communities in Lalkoo moist temperate forest.

Assessment of plant communities -environmental correlation multivariate technique CCA was applied. Of the environmental variables, Altitude, Clay, Silt, Sand, pH, Organic Matter, Calcium Carbonate, Nitrogen, Phosphorus Potassium, and Electrical Conductivity affect the plant community’s classification and distribution. This is also documented that a species with the high cumulative percentage of variance (3.8) and environmental correlation on the ordination scale was exhibited along axis 1 . However of the total measured environmental variable used in CCA analysis the most influential factors were Calcium Carbonate looked to be the cause for the distribution pattern of the community of Abies- Parrotiopsis- Poa, silt for Parrotiopsis- Picea- Poa community and altitude (Shaheen et al., 2011bSHAHEEN, H., QURESHI, R.A., ULLAH, Z. and AHMAD, T., 2011b. Anthropogenic pressureon the western Himalayan moist temperate forests of Bagh, Azad Jammu & Kashmir. Pakistan Journal of Botany, vol. 43, no. 1, pp. 695-703.) for Picea- Indigofera- Poa community. Likewise, outcomes were also described by Khan et al. (2019)KHAN, A.M., QURESHI, R. and SAQIB, Z., 2019. Multivariate analyses of the vegetation of the western Himalayan forests of Muzaffarabad district, Azad Jammu and Kashmir, Pakistan. Ecological Indicators, vol. 104, pp. 723-736. http://dx.doi.org/10.1016/j.ecolind.2019.05.048.
http://dx.doi.org/10.1016/j.ecolind.2019... , and Ahmad et al. (2016)AHMAD, K.S., HAMEED, M., AHMAD, F. and SADIA, B., 2016. Edaphic factors as major determinants of plant distribution of temperate Himalayan grasses. Pakistan Journal of Botany, vol. 48, no. 2, pp. 567-573..

Altitudinal variation is a significant factor controlling plant community structure. In mountainous forests altitudinal gradient limits species distribution and plant community types (Chawla et al., 2008CHAWLA, A., RAJKUMAR, S., SINGH, K., LAL, B., SINGH, R. and THUKRAL, A., 2008. Plant species diversity along an altitudinal gradient of Bhabha Valley in western Himalaya. Journal of Mountain Science, vol. 5, no. 2, pp. 157-177. http://dx.doi.org/10.1007/s11629-008-0079-y.
http://dx.doi.org/10.1007/s11629-008-007... ; Rahman et al., 2022RAHMAN, A., GÜRBÜZ, E., CHEN, J. and EKERCIN, S., 2022. Spatial diversity, patterns of forest vegetation, and sustainability analysis of the Murree Mountains of Western Himalayas. In: M. ÖZTÜRK, S.M. KHAN, V. ALTAY, R. EFE, D. EGAMBERDIEVA and F.O. KHASSANOV, eds. Biodiversity, conservation and sustainability in Asia. Cham: Springer, pp. 267-286. http://dx.doi.org/10.1007/978-3-030-73943-0_15.
http://dx.doi.org/10.1007/978-3-030-7394... ). In this context, a lot of studies were carried out on the variation of the diversity of species along elevation gradient in mountainous forests (Lomolino, 2001LOMOLINO, M., 2001. Elevation gradients of species-density: historical and prospective views. Global Ecology and Biogeography, vol. 10, no. 1, pp. 3-13. http://dx.doi.org/10.1046/j.1466-822x.2001.00229.x.
http://dx.doi.org/10.1046/j.1466-822x.20... ). In Lalkoo hills we found a lot of indicator species with different altitudinal preferences for example Abies pindrow was found from 1900-2920m, Picea smithiana was of common occurrence in the elevation range of 2215-3045m, Pinus wallichiana most abundantly recorded from 2000-2345m, Parrotiopsis jacquemontiana ranged from lower elevation 2085m was distributed at high elevation 3095m. Quercus dilatata is distributed from mid-elevation (2368m) but shows its peak of dominancy towards high elevations (2920m). Dominant indicator shrubs Berberis lyceum and Indigofera heterantha herbs Poa annua and Primula rosea were found in range from 2000-3045m. All plant species showed significant floristic and structural heterogeneity with local ecological variables. Other studies in the Hindu Kush-Himalayas have documented similar elevation ranges for temperate ecosystems (Shaheen et al., 2012SHAHEEN, H., ULLAH, Z., KHAN, S.M. and HARPER, D.M., 2012. Species composition and community structure of western Himalayan moist temperate forests in Kashmir. Forest Ecology and Management, vol. 278, pp. 138-145. http://dx.doi.org/10.1016/j.foreco.2012.05.009.
http://dx.doi.org/10.1016/j.foreco.2012.... ; Rahman et al., 2021RAHMAN, A., KHAN, S.M., AHMAD, Z., ALAMRI, S., HASHEM, M., ILYAS, M., AKSOY, A., DÜLGEROĞLU, C. and SHAHAB ALI, G.K., 2021. Impact of multiple environmental factors on species abundance in various forest layers using an integrative modeling approach. Global Ecology and Conservation, vol. 29, e01712. http://dx.doi.org/10.1016/j.gecco.2021.e01712.
http://dx.doi.org/10.1016/j.gecco.2021.e... ).

Present findings revealed that Lalkoo forest is a potentially complex region, chiefly in terms of wide spread range of biodiversity and important portable natural resources. The area is under heavy anthropogenic and biotic pressure which needs conservation strategies for the complete restoration of Lalkoo forest. The present investigation also suggests that if human pressure remains exists in the study area, the established natural plant resources may be disappeared and will follow rapid extinction as observed in the nearby Hindukush mountainous forests of District Swat, commonly Girbanr hills Miandam hills (Hussain et al., 1997HUSSAIN, F., ILYAS, M. and TAKATSUKI, S., 1997. Plant communities of Girbanr hills, Swat district, North-Western Pakistan. Ecological Review, vol. 23, no. 4, pp. 247-260.), Qalagai hills (Ilyas et al., 2012ILYAS, M., SHINWARI, Z.K. and QURESHI, R., 2012. Vegetation composition and threats to the montane temperate forest ecosystem of Qalagai hills, Swat, Khyber Pakhtunkhwa, Pakistan. Pakistan Journal of Botany, vol. 44, pp. 113-122.; Ali et al., 2018ALI, A., BADSHAH, L. and HUSSAIN, F., 2018. Vegetation structure and threats to Montane Temperate Ecosystems in Hindukush Range, Swat, Pakistan. Applied Ecology and Environmental Research, vol. 16, no. 4, pp. 4789-4811. http://dx.doi.org/10.15666/aeer/1604_47894811.
http://dx.doi.org/10.15666/aeer/1604_478... ). Our description of plant communities, species and environmental variables is an integrated way to study diversity in the ecosystem.

5. Conclusion

Current work investigated 11 plant communities with potential indicator plant species in sub-alpine natural mature forests of Lalkoo Valley, Hindukush mountains Pakistan. These indicators will be helpful in the future for monitoring variations in response to ecological fluctuations that affect plant community structure and composition (Conti et al., 2017CONTI, L., DE BELLO, F., LEPŠ, J., ACOSTA, A.T.R. and CARBONI, M., 2017. Environmental gradients and micro-heterogeneity shape fine-scale plant community assembly on coastal dunes. Journal of Vegetation Science, vol. 28, no. 4, pp. 762-773. http://dx.doi.org/10.1111/jvs.12533.
http://dx.doi.org/10.1111/jvs.12533... ). Altitude and edaphic factors (silt, organic matter, and calcium carbonate) played a vital roles in determining the plant communities. These forests provide carbon storage, a better environment, biodiversity, and other natural resources to the indigenous communities. Our analysis also revealed that several anthropogenic and edaphic factors like deforestation, overgrazing, wood extraction, expansion of agriculture fields by the destruction of soil cover, and soil erosion are serious threats to the vegetation in the investigated area Lalkoo valley. It is strictly recommended that conservation strategies are essential to deal with restoration plans, rangeland management, fuel alternatives sources, and local community awareness for restoration of existing natural biodiversity.

Supplementary Material

Supplementary material accompanies this paper.

Supplementary Material 1 Description of plant communities with their respective values of environmental variables

Supplementary Material 2 Results of Canonical correspondence analysis illustrating relationship of various parameters among species of community and environmental variables (EV).

Supplementary Material 3 Dominant and Rare plant species of each community

This material is available as part of the online article from https://doi.org/10.1590/1519-6984.266637

Acknowledgements

Prof. Dr. Walter Carson, Department of Biological Sciences, University of Pittsburgh is highly acknowledged for finalizing and critically reviews this article.

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Publication Dates

Publication in this collection
21 Nov 2022
Date of issue
2022

History

Received
04 Aug 2022
Accepted
14 Oct 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Botanical Name	ROD/C	RD	RF	IVI	IVI%
Berberis lyceum Royle	16.82	0.02	18.18	35.02	11.67
Bergenia ciliate (Haw.) Sternb.	11.53	0.24	2.43	14.2	4.73
Indigofera heterantha Brandis	6.52	20.63	14.632	41.7	13.90
Poa alpina L.	1.20	30.31	7.46	38.9	12.96
Quercus dilatata A.Kern.	44.25	5.08	24.99	74.3	24.76
Viburnum cotinifolium D. Don	9.37	28.3	16.66	54.3	18.10
Picea smithiana (Wall.) Boiss.	33.45	24.44	18.75	76.6	25.53
Salix acmophylla Boiss.	6.48	9.37	13.04	28.9	9.63
Primula rosea Royle	5.72	0.02	1.44	7.3	2.43
Abies pindrow (Royle ex D.Don) Royle	43.85	42.25	21.05	107.1	35.70
Taxus wallichina Zucc.	15	5.24	3.70	23.5	7.83
Poa supina Schrad.	0.26	7.58	2.2	10	3.33
Viburnum grandiflorum Wall. ex DC.	10.70	2.11	7.14	19.9	6.63
Lithospermum arvense L.	1.54	3.29	1.92	6.7	2.23
Berberis pseudoumbellata R.Parker	8.35	12.13	16.66	37.1	12.36
Carex cardiolepis Nees	1.98	9.48	5.26	16.7	5.56
Pinus wallichiana A.B.Jacks.	67.79	45.43	19.05	123.2	41.06
Poa nemoralis L.	0.71	17.09	4.76	22.6	7.53.
Parrotiopsis jacquemontiana (Decne.) Rehder	10.35	38.98	21.05	70.3	23.43
Poa annua L.	1.051	42.79	10.63	54.4	18.13

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