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Composition and structure of mountain forests containing two tropical pines, Pinus krempfii and Pinus dalatensis, on the Da Lat Plateau, southern Vietnam

Published online by Cambridge University Press:  28 May 2021

Masatoshi Hara*
Affiliation:
Natural History Museum and Institute, Aoba-cho, Chiba, 260-8682, Japan
Trường Thanh Hoàng
Affiliation:
Forest Science Institute of Central Highlands and South of Central Vietnam, 09 Hung Vuong Street, Dist. Da Lat, Lam Dong, Vietnam
Trần Văn Tiến
Affiliation:
Faculty of Biology, Dalat University, 01 Phu Dong Thien Vuong, Dist. Da Lat, Lam Dong, Vietnam
Masahiko Ohsawa
Affiliation:
Institute of Ecology and Geobotany, Yunnan University, Kunming650091, China
*
Author for correspondence:*Masatoshi Hara, Email: musefield@gmail.com

Abstract

We examined the floristic composition and stand structure of tropical mountain forests containing two pine species, Pinus krempfii Lecomte and Pinus dalatensis Ferré, on the Da Lat Plateau in southern Vietnam. A total of 92 tree species were identified, and the greatest species richness at the family level was found in Lauraceae and Fagaceae. Both pine species grew to more than 25 m in height and spread their crowns over the continuous canopy layer. Under crowns of P. krempfii, Castanopsis chinensis, Trigonobalanus verticillata, Engelhardia roxburghiana, and Dendropanax hainanensis constituted the continuous canopy layer. Under crowns of P. dalatensis, pioneer species such as Schima wallichii, Exbucklandia populnea, and Pentaphylax euryoides along with gymnosperms such as Dacrycarpus imbricatus and Dacrydium elatum constituted the continuous canopy layer. Juveniles of P. krempfii were prevalent on the forest floor, but juveniles of P. dalatensis were scarce. We suggest that two pine species have different regeneration requirements related to disturbance and soil condition.

Type
Research Article
Copyright
© The Author(s), 2021. Published by Cambridge University Press

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References

Aiba, S and Kitayama, K (1999) Structure, composition and species diversity in an altitude-substrate matrix of rain forest tree communities on Mount Kinabalu, Borneo. Plant Ecology 140, 139157.CrossRefGoogle Scholar
Akkarasedthanon, J, Chuea-Nongthon, C and Grote, PJ (2017) Factors affecting size distribution and sapling occurrence of Podocarpaceae at Khao Yai National Park, Thailand. Tropical Natural History 17, 94110.Google Scholar
APG IV – Angiosperma Phylogeny Group (2016) An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants: APG IV. Botanical Journal of the Linnean Society 181, 120.CrossRefGoogle Scholar
Ashton, P (2014) On the Forests of Tropical Asia: Lest the Memory of Fade. Kew: Royal Botanic Gardens.Google Scholar
Averyanov, LV, Loc, PK, Heap, NT and Harder, DK (2003) Phytogeographic review of Vietnam and adjacent areas of eastern Indochina. KOMAROVIA 3, 183.Google Scholar
Bhat, BP, Singha, LB, Satapathy, KK, Sharma, YP and Bujarbaruah, KM (2010) Rehabilitation of shifting cultivation areas through agroforestry – a case study in eastern Himalaya, India. Journal of Tropical Forest Science 22, 1320.Google Scholar
Brodribb, TJ and Field, TS (2007) Evolutionary significance of a flat needle Pinus in Vietnamese rainforest. New Phytologist 178, 201209.CrossRefGoogle Scholar
Businsky, R (1999) Study of Pinus dalatensis Ferré and of the enigmatic “Pin du Moyen Annam.” Candollea 54, 125143.Google Scholar
Carlquist, S (1984) Wood anatomy and relationships of Pentaphylaceae: significance of vessel features. Phytomorphology 34, 14.Google Scholar
Chua, LSL and Saw, LG (2001) A reassessment of the flora of Gunugn Ulu Kali, Genting Highland, Malaysia – preliminary findings and trends. Malaysian Nature Journal 55, 6576.Google Scholar
Davis, SD, Heywood, VH and Hamilton, AC (eds.) (1998) Centers of Plant Diversity, volume 2. Asia, Australia and the Pacific. Cambridge: IUCN Publications Unit.Google Scholar
Gernandt, DS, López, GG, Garcia, SO and Liston, A (2005) Phylogeny and classification of Pinus . Taxon 54, 2942.CrossRefGoogle Scholar
Hiep, NT, Loc, PK, Luu, NDT, Thomas, PI, Farjon, A, Averyanov, L and Regalado, JJ (2005) Vietnam Conifers: Conservation Status Review 2004. Hanoi: Fauna and Flora International, Vietnam Programme.Google Scholar
Jaccard, P (1901) Etude comparative de la distribution florale dans une portion des Alpes et du Jura. Bulletin de la Société vaudoise des sciences naturelles 37, 547579.Google Scholar
Keeley, JE and Zedler, H (1998) Evolution of life histories in Pinus. In Richardson, DM (ed.), Ecology and Biogeography of Pinus, Cambridge: Cambridge University Press, pp. 219250.Google Scholar
Khan, ML, Rai, JPN and Tripathi, RS (1987) Population structure of some tree species in disturbed and protected subtropical forests of north-east India. Acta Oecologia 8, 247255.Google Scholar
Kitayama, K, Aiba, S, Takyu, M, Majalap, N and Wagai, R (2004) Soil phosphorus fractionation and phosphorus-use efficiency of a Bornean tropical montane rain forest during soil aging with podozolization. Ecosystems 7, 259274.CrossRefGoogle Scholar
Kitayama, K, Aiba, S, Ushio, M, Seino, T and Fujiki, Y (2011) The ecology of podocarps in tropical montane forests of Borneo: distribution, population dynamics, and soil nutrient acquisition. Smithsonian Contributions to Botany 95, 101117.CrossRefGoogle Scholar
Li, J, Bogle, AL and Klein, S (1999) Phylogenetic relationships in the Hammamelidaceae: evidence from the nucleotide sequences of the plastid gene matK. Plant Systematics and Evolution 218, 205219.CrossRefGoogle Scholar
Magallón, S (2007) From fossils to molecules: phylogeny and the core Eudicot floral groundplan in Hamamelidoideae (Hamamelidaceae, Saxifragales). Systematic Botany 32, 317347.CrossRefGoogle Scholar
Ng, SC and Lin, JY (2008) A new distribution record of Trigonobalanus verticillata (Fagaceae) from Hainan Island, South China. Kew Bulletin 63, 341344.CrossRefGoogle Scholar
Phong, DT, Lieu, TT, Hien, VT and Hiep, N (2015) Genetic diversity of the endemic flat-needle pine Pinus krempfii (Pinaceae) from Vietnam revealed by SSR markers. Genetics and Molecular Research 14, 77277739.CrossRefGoogle ScholarPubMed
Price, RA, Liston, A and Strauss, SH (1998) Phylogeny and systematics of Pinus. In Richardson, DM (ed.), Ecology and Biogeography of Pinus, Cambridge: Cambridge University Press, pp. 346.Google Scholar
Rao, P, Barik, SK, Pandey, HN and Tripathi, RS (1990) Community composition and tree population structure in a sub-tropical broad-leaved forest along a disturbance gradient. Vegetatio 88, 151162.CrossRefGoogle Scholar
Rundel, PW (1999) Forest Habitats and Flora in Laos PDR, Cambodia and Vietnam. Conservation Priorities In Indochina - WWF Desk Study. Prepared for World Wide Fund for Nature. Hanoi: Indochina Programme Office.Google Scholar
Rundel, PW and Middleton, DJ (2017) The flora of the Bokor Plateau, southeastern Cambodia: a homage to Pauline Dy Phon. Cambodian Journal of Natural History 1, 1737.Google Scholar
Santisuk, T (1988) An Account of the Vegetation of Northern Thailand. Stuttgart: Franz Steiner Verlag Wiesbaden GMBH.Google Scholar
Schmid, M (1974) Végétation du Viet-Nam: Le Massif Sud-Annamitigue et les Régions Limitrophes. Paris: Orstom.Google Scholar
Sørensen, T (1948) A method of establishing groups of equal amplitude in plant sociology based on similarity of species content and its application to analysis of the vegetation on Danish commons. Biologiske skrifter 5, 134.Google Scholar
Thomas, P, Sengdala, K, Lamxay, V and Khou, E (2007) New records of conifers in Cambodia and Laos. Edinburgh Journal of Botany 64, 19.CrossRefGoogle Scholar
Truong, NK, Tien, TV, Trieu, LN, Giang, NV, Anh, TTL, Nghia, NH and Truong, HT (2019) Geographical variation in vegetative growth, sexual reproduction and genetic diversity of Pinus krempfii H. Lec. and Pinus dalatensis Ferré in Tay Nguyen Plateau, Vietnam. Annual Report of Pro Natura Foundation Japan 28, 211223.Google Scholar
Wang, B, Mahani, MK, Ng, WL, Kasumi, J, Phi, HH, Inomata, N, Wang, XR and Szmidt, AE (2014) Extremely low nucleotide polymorphism in Pinus krempfii Locomte, a unique flat needle pine endemic to Vietnam. Ecology and Evolution 4, 22282238.CrossRefGoogle ScholarPubMed
Wang, HL, Miao, SY, Wu, WD, Xue, XT and Jin, JH (2008) Characteristics of Pinus kwantongensis community in Luokeng Nature Reserve, Guangdong Province. Journal of Wuhan Botanical Research 26, 5358. In Chinese with English abstract.Google Scholar
Whitmore, TC (1984) Tropical Rain Forests of the Far East. 2nd ed., Oxford: Oxford University Press.Google Scholar
Yao, TL, Kamarudin, S, Chew, MY and Kiew, R (2009) Sphagnum bogs of Kelantan, Peninsular Malaysia. Blumea 54, 139141.CrossRefGoogle Scholar
Zhang, and Xu, Y (2004) A preliminary study on the growth of 5 native broad-leaf tree species. Guangdong Forestry and Science Technology 3, 3941. In Chinese with English abstract.Google Scholar
Zhu, H and Zhou, SS (2017) A primitive Cupuliferae plant (Trigonobalanus verticillata) found in Xishuangbanna, Yunnnan, and its biogeographical significance. Plant Science Journal 35, 205206. In Chinese with English abstract.Google Scholar