Global advances in phylogeny, taxonomy and biogeography of Lauraceae

doi:10.1016/j.pld.2025.04.001

Plant Diversity ›› 2025, Vol. 47 ›› Issue (03): 341-364.DOI: 10.1016/j.pld.2025.04.001

Global advances in phylogeny, taxonomy and biogeography of Lauraceae

Lang Li (李朗)^a, Bing Liu (刘冰)^b,c, Yu Song (宋钰)^d, Hong-Hu Meng (孟宏虎)^a, Xiu-Qin Ci (慈秀芹)^a, John G. Conran^e, Rogier P.J. de Kok^f, Pedro Luís Rodrigues de Moraes^g, Jun-Wei Ye (叶俊伟)^h, Yun-Hong Tan (谭运洪)^i,j, Zhi-Fang Liu (刘志芳)^k, Marlien van der Merwe^l, Henk van der Werff^m, Yong Yang (杨永)ⁿ, Jens G. Rohwer^o, Jie Li (李捷)^a,b

a. Plant Phylogenetics and Conservation Group, Center for Integrative Conservation & Yunnan Key Laboratory for Conservation of Tropical Rainforests and Asian Elephants, Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences, Kunming 650223, China;
b. State Key Laboratory of Plant Diversity and Specialty Crops, Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China;
c. Sino-Africa Joint Research Center, Chinese Academy of Sciences, Wuhan 430074, China;
d. Key Laboratory of Ecology of Rare and Endangered Species and Environmental Protection (Ministry of Education) & Guangxi Key Laboratory of Landscape Resources Conservation and Sustainable Utilization in Lijiang River Basin, Guangxi Normal University, Guilin 541004, China;
e. Environment Institute, School of Biological Sciences, The University of Adelaide, SA 5005, Australia;
f. Honorary Research Associate, Singapore Botanic Gardens, National Parks Board, 1 Cluny Road, 259569 Singapore;
g. Departamento de Biodiversidade, Instituto de Biociências, Universidade Estadual Paulista "Júlio de Mesquita Filho", Av. 24 A 1515, Bela Vista, P. O. Box 199, 13506-900 Rio Claro, SP, Brazil;
h. Key Laboratory for Forest Resources Conservation and Utilization in the Southwest Mountains of China, Ministry of Education, Southwest Forestry University, Kunming 650224, China;
i. Southeast Asia Biodiversity Research Institute, Chinese Academy of Sciences & Center for Integrative Conservation, Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences, Mengla 666303, China;
j. Yunnan International Joint Laboratory of Southeast Asia Biodiversity Conservation & Yunnan Key Laboratory for Conservation of Tropical Rainforests and Asian Elephants, Mengla 666303, China;
k. Institute of Leisure Agriculture, Shandong Academy of Agricultural Sciences, Jinan 250100, China;
l. Research Centre for Ecosystem Resilience, Australian Institute of Botanical Science, Royal Botanic Gardens and Domain Trust, Mrs Macquaries Road, Sydney, NSW 2000, Australia;
m. Missouri Botanical Garden, 4344 Shaw Boulevard, St. Louis, Missouri 63110, U. S. A.;
n. Co-Innovation Center for Sustainable Forestry in Southern China, College of Life Sciences, Nanjing Forestry University, Nanjing 210037, China;
o. Institute of Plant Science and Microbiology, Universität Hamburg, Ohnhorststr. 18, D-22609 Hamburg, Germany

Received:2024-12-11 Revised:2025-03-31 Online:2025-05-21 Published:2025-05-25
Contact: Henk van der Werff,E-mail:henk.vanderwerff@mobot.org;Yong Yang (杨永),E-mail:yangyong@njfu.edu.cn;Jens G. Rohwer,E-mail:Jens.Rohwer@uni-hamburg.de;Jie Li (李捷),E-mail:jieli@xtbg.ac.cn
Supported by:
This work was supported by the National Natural Science Foundation of China (31970222; 31770569; 31500454; 31500165; 32260060; 32270217; 32260056; 31970223; 32400180); the Science and Technology Basic Resources Investigation Program of China (2017FY100100; 2017FY100102); Biodiversity Conservation Program of Chinese Academy of Sciences (ZSSD-013); National Key Research and Development Program of China (2022YFC2601200; 2023YFF0805800); Yunnan Fundamental Research Projects (202201AS070055; 202301AU070224); the 14th Five-Year Plan of Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences (XTBG-1450101); Australian Research Council grant (DP130104314); RSNZ Marsden grant (11-UOO-043); Xingdian Talent Support Program (XDRC-QNRC-2022-0323); Shandong Provincial Natural Science Foundation (ZR2022QC214).

Global advances in phylogeny, taxonomy and biogeography of Lauraceae

a. Plant Phylogenetics and Conservation Group, Center for Integrative Conservation & Yunnan Key Laboratory for Conservation of Tropical Rainforests and Asian Elephants, Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences, Kunming 650223, China;
b. State Key Laboratory of Plant Diversity and Specialty Crops, Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China;
c. Sino-Africa Joint Research Center, Chinese Academy of Sciences, Wuhan 430074, China;
d. Key Laboratory of Ecology of Rare and Endangered Species and Environmental Protection (Ministry of Education) & Guangxi Key Laboratory of Landscape Resources Conservation and Sustainable Utilization in Lijiang River Basin, Guangxi Normal University, Guilin 541004, China;
e. Environment Institute, School of Biological Sciences, The University of Adelaide, SA 5005, Australia;
f. Honorary Research Associate, Singapore Botanic Gardens, National Parks Board, 1 Cluny Road, 259569 Singapore;
g. Departamento de Biodiversidade, Instituto de Biociências, Universidade Estadual Paulista "Júlio de Mesquita Filho", Av. 24 A 1515, Bela Vista, P. O. Box 199, 13506-900 Rio Claro, SP, Brazil;
h. Key Laboratory for Forest Resources Conservation and Utilization in the Southwest Mountains of China, Ministry of Education, Southwest Forestry University, Kunming 650224, China;
i. Southeast Asia Biodiversity Research Institute, Chinese Academy of Sciences & Center for Integrative Conservation, Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences, Mengla 666303, China;
j. Yunnan International Joint Laboratory of Southeast Asia Biodiversity Conservation & Yunnan Key Laboratory for Conservation of Tropical Rainforests and Asian Elephants, Mengla 666303, China;
k. Institute of Leisure Agriculture, Shandong Academy of Agricultural Sciences, Jinan 250100, China;
l. Research Centre for Ecosystem Resilience, Australian Institute of Botanical Science, Royal Botanic Gardens and Domain Trust, Mrs Macquaries Road, Sydney, NSW 2000, Australia;
m. Missouri Botanical Garden, 4344 Shaw Boulevard, St. Louis, Missouri 63110, U. S. A.;
n. Co-Innovation Center for Sustainable Forestry in Southern China, College of Life Sciences, Nanjing Forestry University, Nanjing 210037, China;
o. Institute of Plant Science and Microbiology, Universität Hamburg, Ohnhorststr. 18, D-22609 Hamburg, Germany

通讯作者: Henk van der Werff,E-mail:henk.vanderwerff@mobot.org;Yong Yang (杨永),E-mail:yangyong@njfu.edu.cn;Jens G. Rohwer,E-mail:Jens.Rohwer@uni-hamburg.de;Jie Li (李捷),E-mail:jieli@xtbg.ac.cn
基金资助:
This work was supported by the National Natural Science Foundation of China (31970222; 31770569; 31500454; 31500165; 32260060; 32270217; 32260056; 31970223; 32400180); the Science and Technology Basic Resources Investigation Program of China (2017FY100100; 2017FY100102); Biodiversity Conservation Program of Chinese Academy of Sciences (ZSSD-013); National Key Research and Development Program of China (2022YFC2601200; 2023YFF0805800); Yunnan Fundamental Research Projects (202201AS070055; 202301AU070224); the 14th Five-Year Plan of Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences (XTBG-1450101); Australian Research Council grant (DP130104314); RSNZ Marsden grant (11-UOO-043); Xingdian Talent Support Program (XDRC-QNRC-2022-0323); Shandong Provincial Natural Science Foundation (ZR2022QC214).

Abstract

Abstract: Over the past two decades, our understanding of Lauraceae, a large family of woody plants, has undergone significant advances in phylogeny, taxonomy, and biogeography. Molecular systematic studies have elucidated the basic relationships within the family with plastid phylogenomic analyses providing robust support for deep-level relationships between Lauraceae lineages, leading to the recognition of nine tribes: Hypodaphnideae, Cryptocaryeae, Cassytheae, Neocinnamomeae, Caryodaphnopsideae, Mezilaureae, Perseeae, Laureae, and Cinnamomeae, with Mezilaureae validated here. Nuclear genomes and comparative genomics studies have also clarified aspects of the family’s evolutionary history and metabolic diversity. Taxonomic studies have focused mainly on the most diverse regions, e.g., tropical Asia, tropical America, and Africa (Madagascar), with six new genera described and five reinstated since the last major overview of the family. The extensive fossil record suggests that Lauraceae diversified globally during the Late Cretaceous and Early Cenozoic. Biogeographic studies indicate that different lineages of the family are sorted into Gondwanan and Laurasian lineages, with patterns resulting from the disruption of boreotropical flora and multiple long-distance dispersal events. Phylogeographic studies, predominantly from East Asia, have shown patterns of in situ survival and demographic stability or expansion during the Quaternary. Nevertheless, many systematic relationships within the family remain unresolved and further research is needed into the complex biogeographic history and ecological roles of Lauraceae. A multifaceted approach integrating genomic studies, field work, morphological and ecological investigations is therefore needed to understand the evolution and diversity of this ecologically and economically significant plant family.

Key words: Lauraceae, Phylogeny, Taxonomy, Biogeography, Phylogenomics

摘要： Over the past two decades, our understanding of Lauraceae, a large family of woody plants, has undergone significant advances in phylogeny, taxonomy, and biogeography. Molecular systematic studies have elucidated the basic relationships within the family with plastid phylogenomic analyses providing robust support for deep-level relationships between Lauraceae lineages, leading to the recognition of nine tribes: Hypodaphnideae, Cryptocaryeae, Cassytheae, Neocinnamomeae, Caryodaphnopsideae, Mezilaureae, Perseeae, Laureae, and Cinnamomeae, with Mezilaureae validated here. Nuclear genomes and comparative genomics studies have also clarified aspects of the family’s evolutionary history and metabolic diversity. Taxonomic studies have focused mainly on the most diverse regions, e.g., tropical Asia, tropical America, and Africa (Madagascar), with six new genera described and five reinstated since the last major overview of the family. The extensive fossil record suggests that Lauraceae diversified globally during the Late Cretaceous and Early Cenozoic. Biogeographic studies indicate that different lineages of the family are sorted into Gondwanan and Laurasian lineages, with patterns resulting from the disruption of boreotropical flora and multiple long-distance dispersal events. Phylogeographic studies, predominantly from East Asia, have shown patterns of in situ survival and demographic stability or expansion during the Quaternary. Nevertheless, many systematic relationships within the family remain unresolved and further research is needed into the complex biogeographic history and ecological roles of Lauraceae. A multifaceted approach integrating genomic studies, field work, morphological and ecological investigations is therefore needed to understand the evolution and diversity of this ecologically and economically significant plant family.

关键词: Lauraceae, Phylogeny, Taxonomy, Biogeography, Phylogenomics

Lang Li (李朗), Bing Liu (刘冰), Yu Song (宋钰), Hong-Hu Meng (孟宏虎), Xiu-Qin Ci (慈秀芹), John G. Conran, Rogier P.J. de Kok, Pedro Luís Rodrigues de Moraes, Jun-Wei Ye (叶俊伟), Yun-Hong Tan (谭运洪), Zhi-Fang Liu (刘志芳), Marlien van der Merwe, Henk van der Werff, Yong Yang (杨永), Jens G. Rohwer, Jie Li (李捷). Global advances in phylogeny, taxonomy and biogeography of Lauraceae[J]. Plant Diversity, 2025, 47(03): 341-364.

References

Allen, C.K., 1938. Studies in the Lauraceae, I. Chinese and Indo-Chinese species of Litsea, Neolitsea, and Actinodaphne. Ann. Mo. Bot. Gard. 25, 361-434.
Allen, C.K., 1939. Studies in the Lauraceae II. Some critical and new species of Cinnamomum and Neocinnamomum. J. Arnold Arbor. 20, 44-63.
Allen, C.K., 1941. Studies in the Lauraceae, III. some critical and new species of Asiatic Lindera, with occasional notes on Litsea. J. Arnold Arbor. 22, 1-31.
Allen, C.K., 1942a. Studies in the Lauraceae, IV, preliminary study of the Papuasian species collected by the archbold expeditions. J. Arnold Arbor. 23, 112-155.
Allen, C.K., 1942b. Studies in the Lauraceae, V. some eastern Asiatic species of Beilschmiedia and related genera. J. Arnold Arbor. 23, 444-463.
Alves, F.M., Souza, V.C., 2013. Phylogenetic analysis of the neotropical genus Mezilaurus and reestablishment of Clinostemon (Lauraceae). Taxon 62, 281-290.
Ara, H., Mia, M.U.K., Khan, B., 2007. An annotated checklist of Lauraceae. Bangladesh. J. Plant Taxon. 14, 147-162.
Arifiani, D., 2001. Taxonomic revision of Endiandra (Lauraceae) in Borneo. Blumea 46, 99-124.
Atkinson, B.A., Stockey, R.A., Rothwell, G.W., et al., 2015. Lauraceous flowers from the Eocene of Vancouver Island: Tinaflora beardiae gen. et sp. nov. (Lauraceae).Int. J. Plant Sci. 176, 567-585.
Avise, J., 2009. Phylogeography: retrospect and prospect. J. Biogeogr. 36, 3-15.
Backer, C.A., Bakhuizen, van den Brink, R.C., 1963. Flora of Java, vol. 1. Noordhoff, Groningen.
Baitello, J.B., Lorea-Hern andez, F.H., Moraes, P.L.R. de, et al., 2003. Lauraceae. In:Wanderley, M.G.L., Shepherd, G.J., Melhem, T.S., et al. (Eds.), Flora Fanerogamica ^do Estado de Sao Paulo. Instituto de Botanica, vol. 3. RiMa, Sao Paulo, pp. 149-224.
Bannister, J.M., Lee, D.E., Conran, J.G., 2012. Lauraceae from rainforest surrounding an early Miocene maar lake, Otago, southern New Zealand. Rev. Palaeobot. Palynol. 178, 13-34.
Barbosa, T.D.M., Baitello, J.B., Moraes, P.L.R. de, 2012. A família Lauraceae no município de Santa Teresa, Espírito Santo. Bol. Mus. Biol. Mello Leitao, Nova Ser. 30, 5-178.
Bentham, G., 1880. Laurineae. In: Bentham, G., Hooker, J.D. (Eds.), Genera Plantarum, vol. 3. L. Reeve, London, pp. 146-168.
Beurel, S., Bachelier, J.B., Munzinger, J., et al., 2024. First flower inclusion and fossil evidence of Cryptocarya (Laurales, Lauraceae) from Miocene amber of Zhangpu(China). Foss. Rec. 27, 1-11.
Bi, C.W., Sun, N., Han, F.C., et al., 2024. The first mitogenome of Lauraceae (Cinnamomum chekiangense). Plant Divers. 46, 144-148.
Bhuinya, T., Singh, P., Mukherjee, S.K., 2009. Distribution of the genus Litsea Lam.(Lauraceae) in India with special reference to rare and endemic species. Phytotaxonomy 9, 116-121.
Bhuinya, T., Singh, P., Mukherjee, S.K., 2010. An account of the species of Litsea Lam.(Lauraceae) endemic to India. Bangladesh J. Plant Taxon. 17, 183-191.
Blume, C.L., 1825-1826. Bijdragen tot de Flora van Nederlandsch Indie (Batavia).
Blume, C.L., 1836. Eenige waarnemingen omtrent den Culilawan-boom van Rumphius, in het 11de deel, pp 65-69 van zijn Herbarium Amboinense. Rumphia 1, 46-65.
Blume, C.L., 1849-1851. Museum Botanicum Lugduno-Batavum, vol. 1 (Leiden).
Burger, W.C., 1988. A new genus of Lauraceae from Costa Rica, with comments on problems of generic and specific delimitation within the family. Brittonia 40, 275-282.
Cammerloher, H., 1925. Die Cinnamomum-Arten von Niederlandisch-Ostindien. Bull. Jard. Bot. Buitenzorg, ser. iii 7, 446-497.
Cantrill, D.J., Wanntorp, L., Drinnan, A.N., 2011. Mesofossil flora from the late Cretaceous of New Zealand. Cretac. Res. 32, 164-173.
Cao, Y.N., Wang, I.J., Chen, L.Y., et al., 2018. Inferring spatial patterns and drivers of population divergence of Neolitsea sericea (Lauraceae), based on molecular phylogeography and landscape genomics. Mol. Phylogenet. Evol. 126, 162-172.
Cao, Z.Y., Qu, Y.Y., Song, Y., et al., 2024. Comparative genomics and phylogenetic analysis of chloroplast genomes of Asian Caryodaphnopsis taxa (Lauraceae).Gene 907, 148259.
Cao, Z.Y., Yang, L.Y., Xin, Y.X., et al., 2023. Comparative and phylogenetic analysis of complete chloroplast genomes from seven Neocinnamomum taxa (Lauraceae).Front. Plant Sci. 14, 1205051.
Carpenter, R.J., Jordan, G.J., Hill, R.S., 2007. A toothed Lauraceae leaf from the early Eocene of Tasmania, Australia. Int. J. Plant Sci. 168, 1191-1198.
Carpenter, R.J., Truswell, E.M., Harris, W.K., 2010. Lauraceae fossils from a volcanic Palaeocene oceanic island, Ninetyeast Ridge, Indian Ocean: ancient longdistance dispersal? J. Biogeogr. 37, 1202-1213.
Carter, S.N., 2017. Molecular Systematics of the New Caledonian Cryptocaryeae(Lauraceae). University of Waikato, Hamilton, New Zealand.
Cevallos-Ferriz, S.R.S., Catharina, A.S., Kneller, B., 2021. Cretaceous Lauraceae wood from El Rosario, Baja California, Mexico. Rev. Palaeobot. Palynol. 292, 104478.
Chakrabarty, T., Kumar, A., Krishna, G., 2022. A revision of the genus Dehaasia(Lauraceae) in the Indo-Burmese region. Plant Sci. Today 9, 61-67.
Chakrabarty, T., Kumar, A., Krishna, G., 2023. A revision of the genus Phoebe(Lauraceae) in the Indo-Burmese region. Phytotaxa 606, 26-42.
Chakrabarty, T., Lakra, G.S., Diwakar, P.G., 2010. The family Lauraceae in Andaman and Nicobar islands. In: Ramakrishna, Raghunathan C., Sivaperuman, C. (Eds.), Recent Trends in Biodiversity of Andaman and Nicobar Islands. Zoological Survey of India, Kolkata, pp. 179-193.
Chambers, K.L., Poinar, G.O., Chanderbali, A.S., 2012. Treptostemon (Lauraceae), a new genus of fossil flower from mid-Tertiary Dominican amber. J. Bot. Res. Inst.Tex. 6, 551-556.
Chambers, K.L., Poinar Jr., G.O., Brown, A.E., 2011. A fossil flower of Persea (Lauraceae) in Tertiary Dominican amber. J. Bot. Res. Inst. Tex. 5, 457-462.
Chanderbali, A.S., 2004. Endlicheria (Lauraceae). Flora Neotrop. Monogr. 91, 1-141.New York Botanical Garden Press.
Chanderbali, A.S., van der Werff, H., Renner, S.S., 2001. Phylogeny and historical biogeography of Lauraceae: evidence from the chloroplast and nuclear genomes. Ann. Mo. Bot. Gard. 88, 104-134.
Chandler, M.E.J., 1964. A summary and survey of findings in the light of recent botanical observations. In: The Lower Tertiary Floras of Southern England, Vol. 4. British Museum (Natural History), London, UK, p. 151.
Chase, M.W., Soltis, D.E., Olmstead, R.G., et al., 1993. Phylogenetics of seed plants: an analysis of nucleotide sequences from the plastid gene rbcL. Ann. Mo. Bot. Gard. 80, 528-548+550-580.
Chaw, S.M., Liu, Y.C., Wu, Y.W., et al., 2019. Stout camphor tree genome fills gaps in understanding of flowering plant genome evolution. Nat. Plants 5, 63-73.
Chen, S.B., Ferry, Slik, J.W., Gao, J., et al., 2015. Latitudinal diversity gradients in bryophytes and woody plants: roles of temperature and water availability.J. Syst. Evol. 53, 535-545.
Chen, S.P., Sun, W.H., Xiong, Y.F., et al., 2020b. The Phoebe genome sheds light on the evolution of magnoliids. Hortic. Res. 7, 146.
Chen, Y.C., Li, Z., Zhao, Y.X., et al., 2020a. The Litsea genome and the evolution of the laurel family. Nat. Commun. 11, 1675.
Christophel, D.C., Rowett, A.I., 1996. Leaf and cuticle atlas of Australian leafy Lauraceae. In: Flora of Australia Supplementary Series, vol. 6, pp. 1-217.
Christophersen, E., 1935. Flowering Plants of Samoa, vol. 128. Bernice P. Bishop Museum Bulletin, Hawaii.Co, L.L., 2024. Co's Digital Flora of the Philippines e Lauraceae (philippineplants.org.(Accessed June 2024).
Coiffard, C., El, Atfy, H., Renaudie, J., et al., 2023. The emergence of the tropical rainforest biome in the Cretaceous. Biogeosciences 20, 1145-1154.
Collinson, M.E., Fowler, K., Boulter, M.C., 1981. Floristic changes indicate a cooling climate in the Eocene of southern England. Nature 291, 315-317.
Conran, J.G., Bannister, J.M., Reichgelt, T., et al., 2016. Epiphyllous fungi and leaf physiognomy indicate an ever-wet humid mesothermal (subtropical) climate in the late Eocene of southern New Zealand. Palaeogeogr. Palaeoclimatol. Palaeoecol. 452, 1-10.
Das, A., 1937. Phoebe of Assam and some new species. Assam Forest Rec. Bot. 2, 1-12.
Davis, C.C., Bell, C.D., Fritsch, P.W., et al., 2002. Phylogeny of Acridocarpus-Brachylophon (Malpighiaceae): implications for tertiary tropical floras and Afroasian biogeography. Evolution 56, 2395-2405.
de Kok, R.P.J., 2015. A revision of Cryptocarya R.Br. (Lauraceae) of Thailand and IndoChina. Gard. Bull. Singapore 67, 309-349.
de Kok, R.P.J., 2016a. Notes on the monotypic genus Hexapora (Lauraceae), endemic to peninsular Malaysia. Gard. Bull. Singapore 68, 201-208.
de Kok, R.P.J., 2016b. A revision of Beilschmiedia (Lauraceae) of Peninsular Malaysia.Blumea 61, 147-164.
de Kok, R.P.J., 2016c. A revision of Cryptocarya R.Br. (Lauraceae) of Peninsular Malaysia. Kew Bull. 71, 1-26.
de Kok, R.P.J., 2019. A revision of Cinnamomum Schaeffer (Lauraceae) of Peninsular Malaysia. Gard. Bull. Singapore 71, 89-139.
de Kok, R.P.J., 2021a. A revision of Beilschmiedia (Lauraceae) for Thailand and Indochina. Thai For. Bull. (Bot.) 49, 1-26.
de Kok, R.P.J., 2021b. A revision of Litsea (Lauraceae) in Peninsular Malaysia and Singapore. Gard. Bull. Singapore 73, 81-178.
de Kok, R.P.J., 2025a. Lauraceae. In: Flora of Laos, Cambodia and Vietnam. Museum National d'Histoire Naturelle, Paris (in press).
de Kok, R.P.J., 2025b. Lauraceae. In: Kiew, R., Chung, R.C.K., Saw, L.G., et al. (Eds.), Flora of Peninsular Malaysia, Series II: Seed Plants. Forest Research Institute Malaysia (FRIM), Kuala Lumpur (in press).
de Kok, R.P.J., Middleton, D., 2025. Lauraceae (accepted). In: Santisuk, T., Chayamarit, C., Balslev, H. (Eds.), Flora of Thailand. Forest Herbarium. Royal Forest Department, Bangkok.
de Kok, R.P.J., Sengun, S., 2020. A revision of Cinnadenia Kosterm. (Lauraceae).Adansonia, Ser. 3 (42), 105-112.
de Kok, R.P.J., Thomas, D.C., 2025. Lauraceae. In: Middleton, D. (Ed.), Flora of Singapore. Singapore Botanic Gardens, Singapore (in press).
de Kok, R.P.J., Utteridge, T.M.A., 2021. Lauraceae. In: Utteridge, T.M.A., Jennings, L.V.S. (Eds.), Trees of New Guinea. Kew Publishing, Kew, pp. 81-89.
Denk, T., Grímsson, F., Kvaccek, Z., 2005. The Miocene floras of Iceland and their significance for late Cainozoic North Atlantic biogeography. Bot. J. Linn. Soc. 149, 369-417.
Doyle, J.J., 1992. Gene trees and species trees: molecular systematics as onecharacter taxonomy. Syst. Bot. 17, 144-163.
Doyle, J.A., Endress, P.K., 2000. Morphological phylogenetic analysis of basal angiosperms: comparison and combination with molecular data. Int. J. Plant Sci. 161, S121-S153.
Drinnan, A.N., Crane, P.R., Friis, E.M., et al., 1990. Lauraceous flowers from the Potomac group (mid-Cretaceous) of eastern North America. Bot. Gaz. 151, 370-384.
Duperon-Laudoueneix, M., Duperon, J., 2005. Bois fossiles de Lauraceae: nouvelle
decouverte au Cameroun, inventaire et discussion. Ann. Paleontol. 91, 127-151.
Eklund, H., 2000. Lauraceous flowers from the Late Cretaceous of North Carolina, U.S.A. Bot. J. Linn. Soc. 132, 397-428.
Eklund, H., Kvacek, J., 1998. Lauraceous inflorescences and flowers from the Cenomanian of Bohemia (Czech Republic, Central Europe). Int. J. Plant Sci. 159, 668-686.
Endemia, 2001. Endemia.nc e Faune & Flore de Nouvelle-Caledonie. onwards.Retrieved 2 Oct 2024 from. http://www.endemia.nc/.
Fan, D.M., Hu, W., Li, B., et al., 2016. Idiosyncratic responses of evergreen broadleaved forest constituents in China to the late Quaternary climate changes.Sci. Rep. 6, 31044.
Fan, D.M., Lei, S.Q., Liang, H., et al., 2022. More opportunities more species: Pleistocene differentiation and northward expansion of an evergreen broad-leaved tree species Machilus thunbergii (Lauraceae) in Southeast China. BMC Plant Biol. 22, 35.
Fijridiyanto, I.A., Murakami, N., 2009. Phylogeny of Litsea and related genera (Laureae-Lauraceae) based on analysis of rpb2 gene sequences. J. Plant Res. 122, 283-298.
Fijridiyanto, I.A., Smets, E., Arifiani, D., 2020. Taxonomic revision of Dehaasia(Lauraceae) in Sumatra. Blumea 65, 167-175.
Franco, M.J., Brea, M., Passeggi, E., et al., 2015. The first record of Lauraceae fossil woods from the Cretaceous Puerto Yeru a Formation of eastern Argentina and palaeobiogeographic implications. Cretac. Res. 56, 388-398.
Friis, E.M., Crane, P.R., Pedersen, K.R., 2011. Early Flowers and Angiosperm Evolution.Cambridge University Press, Cambridge, UK.
Gamble, J.S., 1910a. New Lauraceae from the Malayan region I. Bull. Misc. Inform.Kew 1910, 142-153.
Gamble, J.S., 1910b. New Lauraceae from the Malayan region II. Bull. Misc. Inform.
Kew 1910, 218-228.
Gamble, J.S., 1910c. New Lauraceae from the Malayan region III. Bull. Misc. Inform.Kew 1910, 312-321.
Gamble, J.S., 1910d. New Lauraceae from the Malayan region IV. Bull. Misc. Inform.Kew 1910, 357-368.
Gangopadhyay, M., Chakrabarty, T., 2005. The genus Cryptocarya R.Br. (Lauraceae) in the Indian subcontinent. J. Econ. Taxon. Bot. 29, 274-293.
Garrouste, R., Munzinger, J., Leslie, A., et al., 2021. New fossil discoveries illustrate the diversity of past terrestrial ecosystems in New Caledonia. Sci. Rep. 11, 18388.
Geethakumary, M.P., Deepu, S., Pandurangan, A.G., 2021. Synopsis of the genus Cinnamomum Schaeffer (Lauraceae) in India. Plant Sci. Today 8, 199-209.
Givnish, T.J., Renner, S.S., 2004. Tropical intercontinental disjunctions: Gondwana breakup, immigration from the boreotropics, and transoceanic dispersal. Int. J.Plant Sci. 165, S1eS6.
Gonz alez, J., Poveda, L.J., 2007. Lauraceae. In: Hammel, B.R., Grayum, M.H., Herrera, C., et al. (Eds.), Manual de Plantas de Costa Rica, Vol. VI. Dicotiledoneas (HaloragaceaeePhytolaccaceae), Monographs in Systematic Botany from the Missouri Botanical Garden 111. Missouri Botanical Garden Press, St. Louis, pp. 90-172.
Gottwald, H., 1992. Holzer aus marinen Sanden des Oberen Eozan von Helmstedt (Niedersachsen). Palaeontograph. Abteilung B 225, 27-103.
Han, X., Zhang, J., Han, S., et al., 2022. The chromosome-scale genome of Phoebe bournei reveals contrasting fates of terpene synthase (TPS)-a and TPS-b subfamilies. Plant Commun. 3, 100410.
Harrison, S.P., Yu, G., Takahara, H., et al., 2001. Palaeovegetation (Communications arising): diversity of temperate plants in East Asia. Nature 413, 129-130.
Heintz, H., 2007. Untersuchungen zur Morphologie und Ontogenie der Infloreszenzen und Blüten einiger Lauraceae. Unpublished Ph.D. thesis. Universit at Hamburg, Hamburg, Germany.
Helmstetter, A.J., Ezedin, Z., de Lírio, E.J., et al., 2025. Toward a phylogenomic classification of magnoliids. Am. J. Bot. 112, e16451.
Heo, K., van der Werff, H., Tobe, H., 1998. Embryology and relationships of Lauraceae(Laurales). J. Linn. Soc. Bot. 126, 295-322.
Herendeen, P.S., Crepet, W.L., Nixon, K.C., 1994. Fossil flowers and pollen of Lauraceae from the Upper Cretaceous of New Jersey. Plant Syst. Evol. 189, 29-40.
Hill, R.S. (Ed.), 2017. History of the Australian Vegetation: Cretaceous to Recent.University of Adelaide Press, Adelaide, SA.
Ho, P.H., 1991. Lauraceae. An Illustrated Flora of Vietnam, vol. 2. Mekong Printing, Montreal, pp. 619-1249.
Ho, P.H., 1999. Lauraceae. An Illustrated Flora of Vietnam, vol. 1. Youth Publishing House, Ho Chi Minh City, pp. 343-402.
Hooker, J.D., 1890. Laurineae. In: Hooker, J.D. (Ed.), The Flora of British India, vol. 5. L.Reeve, London, pp. 116-189.
Huang, H., Li, J., 2018. Flower fossils of Lauraceae in the geological time and its phylogenetic evolutionary significance. Guihaia 38, 210-219.
Huang, J.F., Li, L., van der Werff, H., et al., 2016. Origins and evolution of cinnamon and camphor: A phylogenetic and historical biogeographical analysis of the Cinnamomum group (Lauraceae). Mol. Phylogenet. Evol. 96, 33-44.
Hyland, B.P.M., 1989. A revision of Lauraceae in Australia (excluding Cassytha). Aust.Syst. Bot. 2, 135-367.
Irawan, B., 2004. Ironwood (Eusideroxylon zwageri Teijsm. & Binn.) and its Varieties in Jambi, Indonesia. Cuvillier Verlag, Gottingen.
Jiang, R., Chen, X., Liao, X., et al., 2022. A chromosome-level genome of the Camphor Tree and the underlying genetic and climatic factors for its Top-Geoherbalism.Front. Plant Sci. 13, 1-17.
Jo, S.J., Kim, Y.K., Cheon, S.H., et al., 2019. Characterization of 20 complete plastomes from the tribe Laureae (Lauraceae) and distribution of small inversions. PLoS One 14, e0224622.
Johnson, M.G., Pokorny, L., Dodsworth, S., et al., 2019. A universal probe set for targeted sequencing of 353 nuclear genes from any flowering plant designed using k-medoids clustering. Syst. Biol. 68, 594-606.
Julia, S., 2005. A synopsis of the genus Actinodaphne Nees (Lauraceae) in Sabah and Sarawak, Malaysia. Gard. Bull. Singapore 57, 69-100.
Julia, S., Soepadmo, E., Yahud, W., 2009. Problems in the generic delimitation between Alseodaphne, Dehaasia and Nothaphoebe (Lauraceae) in Borneo. Blumea 54, 192-197.
Kennedy, E.M., 2003. Late Cretaceous and Paleocene terrestrial climates of New Zealand: leaf fossil evidence from South Island assemblages. New Zeal. J. Geol.Geophys. 46, 295-306.
Klucking, E.P., 1987. Leaf venation patterns. In: Lauraceae, Vol. 2, pp. 1-216. J.Cramer, Berlin-Stuttgart.
Kochummen, K.M., 1989. Lauraceae. In: Ng, F.S.P. (Ed.), Tree Flora of Malaya, vol. 4.Longman, Malaysia, pp. 98-178.
Kokubugata, G., Nakamura, K., Forster, P.I., et al., 2012. Cassytha pubescens and C. glabella (Lauraceae) are not disjunctly distributed between Australia and the Ryukyu Archipelago of Japan e evidence from morphological and molecular data. Aust. Syst. Bot. 25, 364-373.
Kopp, L.E., 1966. A taxonomic revision of the genus Persea in the Western Hemisphere (Perseae-Lauraceae). Mem. N. Y. Bot. Gard. 14, 1-120.
Kostermans, A.J.G.H., 1937. Revision of the Lauraceae II: the genera Endlicheria, Cryptocarya (American species) and Licaria. Recueil Trav. Bot. Neerl. 34, 500-609.

[1]	Na-Na Zhang (张娜娜), Gregory W. Stull, Xue-Jie Zhang (张学杰), Shou-Jin Fan (樊守金), Ting-Shuang Yi (伊廷双), Xiao-Jian Qu (曲小健). PlastidHub: An integrated analysis platform for plastid phylogenomics and comparative genomics [J]. Plant Diversity, 2025, 47(04): 544-560.
[2]	Ibrokhimjon Ergashov, Ziyoviddin Yusupov, Alireza Dolatyari, Mina Khorasani, İsmail Eker, Nazgul Turdumatova, Georgy Lazkov, Farruhbek Rasulov, Hang Sun, Tao Deng, Komiljon Tojibaev. New insights into the molecular phylogeny and biogeographical history of Allium subgenus Melanocrommyum (Amaryllidaceae) based on plastome and nuclear sequences [J]. Plant Diversity, 2025, 47(04): 561-575.
[3]	Xiao-Hua Lin (林晓华), Si-Yu Xie (解思宇), Dai-Kun Ma (马代锟), Shuai Liao (廖帅), Bin-Jie Ge (葛斌杰), Shi-Liang Zhou (周世良), Liang Zhao (赵亮), Chao Xu (徐超), De-Yuan Hong (洪德元), Bin-Bin Liu (刘彬彬). Phylogenomic insights into Adenophora and its allies (Campanulaceae): Revisiting generic delimitation and hybridization dynamics [J]. Plant Diversity, 2025, 47(04): 576-592.
[4]	Zhi-Qiong Mo (莫智琼), Chao-Nan Fu (付超男), Alex D. Twyford, Pete M. Hollingsworth, Ting Zhang (张挺), Jun-Bo Yang (杨俊波), De-Zhu Li (李德铢), Lian-Ming Gao (高连明). Evaluating the utility of deep genome skimming for phylogenomic analyses: A case study in the species-rich genus Rhododendron [J]. Plant Diversity, 2025, 47(04): 593-603.
[5]	Kai Chen, Yan-Chun Liu, Yue Huang, Xu-Kun Wu, Hai-Ying Ma, Hua Peng, De-Zhu Li, Peng-Fei Ma. Reassessing the phylogenetic relationships of Pseudosorghum and Saccharinae (Poaceae) using plastome and nuclear ribosomal sequences [J]. Plant Diversity, 2025, 47(03): 382-393.
[6]	Kai-Yun Chen, Jin-Dan Wang, Rui-Qi Xiang, Xue-Dan Yang, Quan-Zheng Yun, Yuan Huang, Hang Sun, Jia-Hui Chen. Backbone phylogeny of Salix based on genome skimming data [J]. Plant Diversity, 2025, 47(02): 178-188.
[7]	Amos Kipkoech, Ke Li, Richard I. Milne, Oyetola Olusegun Oyebanji, Moses C. Wambulwa, Xiao-Gang Fu, Dennis A. Wakhungu, Zeng-Yuan Wu, Jie Liu. An integrative approach clarifies species delimitation and biogeographic history of Debregeasia (Urticaceae) [J]. Plant Diversity, 2025, 47(02): 229-243.
[8]	Xue Wang, Xinrui Liu, Shuang Chen, Jiang Zhu, Yanqi Yuan, Rong Zhu, Kaixi Chen, Xue Yang, Xiaochun Wang, Weiyi Mo, Ruili Wang, Shuoxin Zhang. Elevational variation in anatomical traits of the first-order roots and their adaptation mechanisms [J]. Plant Diversity, 2025, 47(02): 291-299.
[9]	Zengke Zhang, Wensheng Chen, Zengyan Li, Wentao Ren, Ling Mou, Junyong Zheng, Tian Zhang, Hantang Qin, Liyi Zhou, Bile Sai, Hang Ci, Yongchuan Yang, Shekhar R. Biswas, Enrong Yan. The island rule-like patterns of plant size variation in a young land-bridge archipelago: Roles of environmental circumstance and biotic competition [J]. Plant Diversity, 2025, 47(02): 300-310.
[10]	Yongli Wang, Yan-Da Li, Shuo Wang, Erik Tihelka, Michael S. Engel, Chenyang Cai. Modeling compositional heterogeneity resolves deep phylogeny of flowering plants [J]. Plant Diversity, 2025, 47(01): 13-20.
[11]	Liansheng Xu, Zhuqiu Song, Tian Li, Zichao Jin, Buyun Zhang, Siyi Du, Shuyuan Liao, Xingjie Zhong, Yousheng Chen. New insights into the phylogeny and infrageneric taxonomy of Saussurea based on hybrid capture phylogenomics (Hyb-Seq) [J]. Plant Diversity, 2025, 47(01): 21-33.
[12]	Zheng-Yu Zuo, Germinal Rouhan, Shi-Yong Dong, Hong-Mei Liu, Xin-Yu Du, Li-Bing Zhang, Jin-Mei Lu. A revised classification of Dryopteridaceae based on plastome phylogenomics and morphological evidence, with the description of a new genus, Pseudarachniodes [J]. Plant Diversity, 2025, 47(01): 34-52.
[13]	Tian-Rui Wang, Xin Ning, Si-Si Zheng, Yu Li, Zi-Jia Lu, Hong-Hu Meng, Bin-Jie Ge, Gregor Kozlowski, Meng-Xiao Yan, Yi-Gang Song. Genomic insights into ecological adaptation of oaks revealed by phylogenomic analysis of multiple species [J]. Plant Diversity, 2025, 47(01): 53-67.
[14]	Wei Gu, Ting Zhang, Shui-Yin Liu, Qin Tian, Chen-Xuan Yang, Qing Lu, Xiao-Gang Fu, Heather R. Kates, Gregory W. Stull, Pamela S. Soltis, Douglas E. Soltis, Ryan A. Folk, Robert P. Guralnick, De-Zhu Li, Ting-Shuang Yi. Phylogenomics, reticulation, and biogeographical history of Elaeagnaceae [J]. Plant Diversity, 2024, 46(06): 683-697.
[15]	Yanwei Guan, Yongru Wu, Zheng Cao, Zhifeng Wu, Fangyuan Yu, Haibin Yu, Tiejun Wang. Island biogeography theory and the habitat heterogeneity jointly explain global patterns of Rhododendron diversity [J]. Plant Diversity, 2024, 46(05): 565-574.

Global advances in phylogeny, taxonomy and biogeography of Lauraceae

Global advances in phylogeny, taxonomy and biogeography of Lauraceae

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments