Metasequoia

Christopher N. Page

doi:10.1017/9781009263108.011

Chapter 47 - Metasequoia

Cupressales: Sequoiaceae

from Part III - Living Arborescent Gymnosperm Genetic Presentations

Published online by Cambridge University Press: 11 November 2024

Christopher N. Page

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Christopher N. Page: Affiliation:
University of Exeter

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Summary

Fairly fast-growing monoecious trees of fully winter-deciduous habit. When young they have a typically conical, tapering crown, long remaining symmetric and spire-like, with slender, level branches bearing masses of small, flattened, soft-textured and highly flexible bright-yellow–green leaves set oppositely in two flattened sub-pinnate ranks.

Type: Chapter
Information: Evolution of the Arborescent Gymnosperms
Pattern, Process and Diversity
, pp. 140 - 171

DOI: https://doi.org/10.1017/9781009263108.011 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2024

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References

Archibald, J.D. 2011. Extinction and Radiation: How the Fall of Dinosaurs Led to the Rise of Mammals. Baltimore, MD: Johns Hopkins University Press.CrossRef Google Scholar

Arnold, C.A. & Lowther, J.S. 1955. A new Cretaceous conifer from Northern Alaska. American Journal of Botany 42: 522–528.CrossRef Google Scholar

Axelrod, D.I. 1986. Cenozoic history of some western American pines. Annals of the Missouri Botanical Garden 73: 565–641.CrossRef Google Scholar

Axelrod, D.I. 1987 The Late Oligocene Creede Flora, Colorado. Berkeley, CA: University of California Press.Google Scholar

Axelrod, D.I. 1988. An interpretation of high montane conifers in western Tertiary floras. Paleobiology 14(3): 301–306.CrossRef Google Scholar

Baikovskaya, T.N. 1956. Upper Cretaceous floras of northern Asia. Palaeobotanica 2: 49–181.Google Scholar

Basinger, J.F. 1981. The vegetative body of Metasequoia milleri from the Middle Eocene of southern British Columbia. Canadian Journal of Botany 59: 2379–2410.CrossRef Google Scholar

Basinger, J.F. 1984. Seed cones of Metasequoia milleri from the Middle Eocene of southern British Columbia. Canadian Journal of Botany 62: 281–289.CrossRef Google Scholar

Basinger, J.F. 1991. The fossil forests of the Buchanan Lake Formation (early Tertiary), Axel Heiberg Island, Canadian High Arctic: preliminary floristics and paleoclimate. Geological Survey of Canada Bulletin 403: 39–66.Google Scholar

Battles, J.J., Armento, J.J., Vann, D.R., et al. 2002. Vegetation composition, structure and biomass of two unpolluted watersheds in the Cordillera de Piuchue, Chiloé Island, Chile. Plant Ecology 158: 5–19.CrossRef Google Scholar

Bechtel, A., Sachsenhofer, R.F., Markic, M., et al. 2003. Paleoenvironmental implications from biomarker and stable isotope investigations on the Pliocene Velenje lignite seam (Slovenia). Organic Geochemistry 34(9): 1277–1298.CrossRef Google Scholar

Beering, D.J. & Woodward, F.I. 2001. Vegetation and the Terrestrial Carbon Cycle: Modelling the First 4000 Million Years. Cambridge: Cambridge University Press.CrossRef Google Scholar

Beerling, D.J. & Osborne, C.P. 2002. Physiological ecology of Metasequoia polar forests in a high CO₂ environment. Annals of Botany 89: 1–11.CrossRef Google Scholar

Berner, R.A. & Kothavala, Z. 2001. GEOCARB III: a revised model of atmospheric CO2 over Phanerozoic time. American Journal of Science 301(2): 182–204.CrossRef Google Scholar

Blokhina, N.I. 1982. Dopointel’nyye dannyye o paleogena ide Metasequoia klerkiana (Taxodiaceae) [Additional data on the Paleogene species Metasequoia klerkiana (Taxodiaceae)]. Botanicheskii Zhurnal 67: 988–996.Google Scholar

Blokhina, N.I. 1995. Petrified wood of Metasequoia from the Miocene of Kamchatka (Korfa Bay). Paleontological Journal 29: 103–112.Google Scholar

Boulter, M.C. & Kvaček, Z. 1989. The Palaeocene flora of the Isle of Mull. Palaeontological Association of London Special Papers on Palaeontology 42: 1–149.Google Scholar

Brentnall, S.J., Beerling, D.J. & Osborne, C.P. 2005. Climatic and ecological determinants of leaf lifespan in polar forests of the high CO₂ Cretaceous ‘greenhouse’ world. Global Change Biology 11: 2177–2195.CrossRef Google Scholar PubMed

Brinkhuis, H. S., Schouten, M.E., Collinson, A., et al. 2006. Episodic fresh surface waters in the Eocene Arctic Ocean. Nature 441: 606–609.CrossRef Google Scholar

Brunsfeld, S.J., Soltis, P.S., Soltis, D.E., Gadek, P.A. & Quinn, C.J. 1994. Phylogenetic relationships amongst the genera of the Taxodiaceae and Cupressaceae: evidence from rbcL sequences. Systematic Botany 19: 253–262.CrossRef Google Scholar

Budantsev, L.Y. 1997. Late Eocene flora of Western Kamchatka. Proceedings of the Botanical Institute of the Russian Academy of Sciences 19: 3–115.Google Scholar

Canright, J.E. 1972. A first report on the occurrence of Metasequoia in the middle Miocene of Taiwan. American Journal of Botany 59: 660.Google Scholar

Cantrill, D.J. & Poole, I. 2002. Cretaceous patterns of floristic change in the Antarctic Peninsula. Pp 141–152 in Crame, J.A. & Owen, A.W. (eds.), Palaeobiogeography and Biodiversity Change: The Ordovician and Mesozoic-Cenozoic Radiations. London: Geological Society of London.Google Scholar

Chaney, R.W. 1947. Tertiary centers and migration routes, in origin and development of natural floristic areas with special reference to North America. Ecological Monographs 17(2): 139–148.CrossRef Google Scholar

Chaney, R.W. 1951. A revision of fossil Sequoia and Taxodium in western North America based on the recent discovery of Metasequoia. Transactions of the American Philosophical Society New Series 40: 171–263.CrossRef Google Scholar

Chochiyeva, K.I. 1968. Novye dannye o przdnepliotsenovoi – postpliosenovi rastitel’nosti Zapadnoi Gruzii. Bulletin Academy of Science Georgia SSR 52: 219–222 (in Russian).Google Scholar

Chochiyeva, K.I. 1975. Khvarbetskiy Iskopayemyy Khvoynyy Les. [The Khvarbetian Fossil Coniferous Forest]. Tiflis: Metsniyereba.Google Scholar

Chochiyeva, K.I. 1980. The family of Taxodiaceae in the fossil flora of Georgia. Izvestiya Akademii Nauk Gruzinsloi SSR Seriya Biologicheskaya (Bulletin of the Academy of Sciences of the Georgian Soviet Socialist Republic, ser. Biological) 6(1): 61–66 (in Russian, with English summary).Google Scholar

Chu, K. & Cooper, W.S. 1950. An ecological reconnaissance in the native home of Metasequoia glyptostroboides. Ecology 31: 260–278.CrossRef Google Scholar

Chu, L.-L. 1987. Looking at the origin of Sequoia sempervirens from the point of view of karyotype. Acta Botanica Yunnanica 9: 187–190 (in Chinese).Google Scholar

Collinson, M.E. 1983. Palaeofloristic assemblages and palaeoecology of the lower Oligocene Bembridge marls, Hamstead Ledge, Isle of Wight. Botanical Journal of the Linnean Society 86: 177–225.CrossRef Google Scholar

Craggs, H.J. 2005. Late Cretaceous climate signal of the Northern Pekulney range flora of northeastern Russia. Palaeogeography, Palaeoclimatology, Palaeoecology 217: 25–46.CrossRef Google Scholar

Crane, P.R. & Lidgard, S. 1989. Angiosperm diversification and paleolatitudinal gradients in Cretaceous floristic diversity. Science 246: 675–678.CrossRef Google Scholar

Creber, G.T. & Chaloner, W.G. 1985. Tree growth in the Mesozoic and Early Tertiary and the reconstruction of palaeoclimates. Palaeogeography, Palaeoclimatology and Palaeoecology 52: 35–60.CrossRef Google Scholar

Daly, R.J., Jolley, D.W. & Spicer, R.A. 2011. The role of angiosperms in Palaeocene Arctic ecosystems: a palynological study from the Alaskan North Slope. Palaeogeography, Palaeoclimatology, Palaeoecology 309(3–4): 374–382.CrossRef Google Scholar

Dawson, M. R., West, R.M., Langston, W., Jr. & Hutchison, J. H. 1976. Paleogene terrestrial vertebrates: northernmost occurrence, Ellesmere Island, Canada. Science 192(4241): 781–782.CrossRef Google Scholar PubMed

Dickens, G.R., O’Neil, J.R., Rea, D.K. & Owen, R.M. 1995. Dissociation of oceanic methane hydrate as a cause of the carbon isotope excursion at the end of the Palaeocene. Paleoceanography 10: 965–971.CrossRef Google Scholar

Eberle, J.J. 2005. A new ‘tapir’ from Ellesmere Island, Arctic Canada: implications for northern high latitude palaeobiogeography and tapir palaeobiology. Palaeogeography, Palaeoclimatology, Palaeoecology 227: 311–322.CrossRef Google Scholar

Eberle, J.J. 2006. Early Eocene Brontotheriidae (Perissodactyla) from the Eureka Sound Group, Ellesmere Island, Canadian High Arctic: implications for brontothere origins and high-latitude dispersal. Journal of Vertebrate Paleontology 26: 381–386.CrossRef Google Scholar

Eberle, J.J. & McKenna, M.C. 2002. Early Eocene Leptictida, Pantolesta, Creodonta, Carnivora, and Mesonychidae (Mammalia) from the Eureka Sound Group, Ellesmere Island, Nunavut. Canadian Journal of Earth Sciences 39(6): 899–910.CrossRef Google Scholar

Eberle, J., Fricke, H. & Humphrey, J. 2009. Lower-latitude mammals as year-round residents in Eocene Arctic forests. Geology 37(6): 499–502.CrossRef Google Scholar

Eberle, J.J., Fricke, H.C., Humphrey, J.D., et al. 2010. Seasonal variability in Arctic temperatures during early Eocene time. Earth and Planetary Science Letters 296(3–4): 481–486.CrossRef Google Scholar

Eckenwalder, J.E. 1976. Re-evaluation of Cupressaceae and Taxodiaceae: a proposed merger. Madrõno 23: 237–256.Google Scholar

Endo, S. 1951. A record of Sequoia from the Jurassic of Manchuria. Botanical Gazette 113: 228–230.Google Scholar

Equiza, M.A., Day, M.E. & Jagels, R. 2006a. Physiological responses of three deciduous conifers (Metasequoia glyptostroboides, Taxodium distichum and Larix laricina) to continuous light: adaptive implications for the early Tertiary polar summer. Tree Physiology 26: 353–364.CrossRef Google Scholar PubMed

Equiza, M.A., Day, M.E., Jagels, R, & Li, X. 2006b. Photosynthetic downregulation in the conifer Metasequoia glyptostroboides growing under continuous light: the significance of carbohydrate sinks and paleoecophysiological implications. Canadian Journal of Botany 84: 1453–1461.CrossRef Google Scholar

Equiza, M.A., Jagels, R. & Cirelli, D. 2007. Differential carbon allocation in Metasequoia glyptostroboides, Taxodium distichum and Sequoia sempervirens growing under continuous light. Bulletin of the Peabody Museum of Natural History 48(2): 269–280.CrossRef Google Scholar

Estes, R. & Hutchison, J.H. 1980. Eocene lower vertebrates from Ellesmere Island, Canadian Arctic archipelago. Palaeogeography, Palaeoclimatology, Palaeoecology 30: 325–347.CrossRef Google Scholar

Falcon-Lang, H.J., MacRae, R.A. & Csank, A.Z. 2004. Palaeoecology of Late Cretaceous polar vegetation preserved in the Hansen Point Volcanics, NW Ellesmere Island, Canada. Palaeogeography, Palaeoclimatology, Palaeoecology 212: 45–64.CrossRef Google Scholar

Falder, A.B., Stockey, R.A. & Rothwell, G.W. 1999. In situ fossil seedlings of a Metasequoia-like taxodiaceous conifer from Paleocene river floodplain deposits of central Alberta, Canada. American Journal of Botany 86: 900–902.CrossRef Google Scholar PubMed

Farjon, A. & Page, C.N. (eds.) 1999. Conifers: Status Survey and Conifer Action Plan. IUCN/SSC Conifer Specialist Group Report. Gland: IUCN.Google Scholar

Ferguson, D.K. 1967. On the phytogeography of Coniferales in the European Cenozoic. Palaeogeography, Palaeoclimatology, Palaeoecology 33: 73–110.CrossRef Google Scholar

Florin, R. 1952. On Metasequoia, living and fossil. Bot. Notiser 105: 1–29.Google Scholar

Flower, B.P. & Kennett, J.P. 1994. The middle Miocene climatic transition: East Antarctic ice sheet development, deep ocean circulation and global carbon cycling. Palaeogeography, Palaeoclimatology, Palaeoecology 108: 537–555.CrossRef Google Scholar

Fowells, H.A. 1965. Silvics of Forest Trees of the United States. Washington, DC: USDA.Google Scholar

Frakes, L.A., Francis, J.E. & Sykus, J.L. 1992. Climate Models of the Phanerozoic. Cambridge: Cambridge University Press.CrossRef Google Scholar

Francis, J.E. 1991. The dynamics of polar fossil forests: Tertiary fossil forests of Axel Heiberg Island, Canadian Arctic Archipelago. Geological Survey of Canada Bulletin 403: 29–38.Google Scholar

Frederiksen, N.O. 1994. Paleocene floral diversities and turnover events in eastern North America and their relation to diversity models. Review of Palaeobotany and Palynology 82(3–4): 225–238.CrossRef Google Scholar

Fricke, H.C., Clyde, W.C., O’Neil, J.R. & Gingerich, P.D. 1998. Evidence for rapid climate change in North America during the latest Paleocene thermal maximum: oxygen isotope compositions of biogenic phosphate from the Bighorn Basin (Wyoming). Earth and Planetary Science Letters 160(1–2): 193–208.CrossRef Google Scholar

Fulling, E.H. 1976. Metasequoia – Fossil and Living: an initial thirty-year (1941–1970) annotated and indexed bibliography with an historical introduction. The Botanical Review 42(3): 215–315.CrossRef Google Scholar

Gemmill, C.E. & Johnson, K.R. 1997. Paleoecology of a late Paleocene (Tiffanian) megaflora from the northern Great Divide Basin, Wyoming. Palaios 12(5): 439–448.CrossRef Google Scholar

Graham, A. 1999. The Tertiary history of the northern temperate element in the northern Latin American biota. American Journal of Botany 86(1): 32–38.CrossRef Google Scholar PubMed

Greenwood, D.R. & Basinger, J.F. 1994. The paleoecology of high-latitude Eocene swamp forests from Axel Heiberg Island, Canadian High Arctic. Review of Palaeobotany and Palynology 81: 83–97.CrossRef Google Scholar

Greenwood, D.R. & Wing, S.L. 1995. Eocene continental climates and latitudinal temperature gradients. Geology 23: 1044–1048.2.3.CO;2>CrossRef Google Scholar

Greenwood, D.R., Archibald, S.B., Mathewes, R.W. & Moss, P.T. 2005. Fossil biotas from the Okanagan Highlands, southern British Columbia and northeastern Washington State: climates and ecosystems across an Eocene landscape. Canadian Journal of Earth Sciences 42(2): 167–185.CrossRef Google Scholar

Greguss, P. 1955. Identification of Living Gymnosperms on the Basis of Xylotomy. Budapest: Akademia Kiado.Google Scholar

Grier, C.C. & Logan, R.S. 1977. Old-growth Pseudotsuga menziesii communities of a western Oregon watershed: biomass distribution and production budgets. Ecological Monographs 47: 373–400.CrossRef Google Scholar

Grime, J.P. 2001. Plant Strategies, Vegetation Processes, and Ecosystem Processes, 2nd edn. Chichester: Wiley.Google Scholar

Harland, M., Francis, J.E., Brentnall, S.J. & Beerling, D.J. 2007. Cretaceous (Albian–Aptian) conifer wood from Northern Hemisphere high latitudes: forest composition and palaeoclimate. Review of Palaeobotany and Palynology 143(3–4): 167–196.CrossRef Google Scholar

Harris, A.S. 1973. Dawn redwood in Alaska. Journal of Forestry 71: 228.Google Scholar

Harris, T.M. 1943. The fossil conifer Elatides williamsoni. Annals of Botany 7: 325–339.CrossRef Google Scholar

Harris, T.M. 1953. Conifers of the Taxodiaceae from the Wealden Formation of Belgium. Memoirs of the Royal Belgian Institute of Natural Sciences 126: 1–43.Google Scholar

Harris, T.M. 1979. The Yorkshire Jurassic Flora. 5. Coniferales. London: British Museum.Google Scholar

Hart, J.A. 1987. A cladistic analysis of conifers: preliminary results. Journal of the Arnold Arboretum 68: 269–307.CrossRef Google Scholar

Hase, Y. & Hatanaka, K.I. 1984. Pollen stratigraphical study of the Late Cenozoic sediments in southern Kyushu, Japan. Quaternary Research, Tokyo 23: 1–20.CrossRef Google Scholar

He, Z., Li, J., Cai, Q., Li, X. & Huang, H. 2004. Cytogenetic studies on Metasequoia glyptostroboides, a living fossil species. Genetica 122: 269–276.CrossRef Google Scholar PubMed

Hejinowicz, A. 1973. Anatomical studies on the development of Metasequoia glyptostroboides Hu et Cheng wood. Acta Soc Acta Poloniae 42: 473–491.CrossRef Google Scholar

Herman, A.B. 1994. A review of Late Cretaceous floras and climates of Arctic Russia. Pp 127–149 in Boulter, M.C. & Fisher, H.C. (eds.), Cenozoic Plants and Climates of the Arctic. Berlin: Springer.CrossRef Google Scholar

Herman, A.B. & Spicer, R.A. 1995. Latest Cretaceous flora of northeastern Russia and the ‘terminal Cretaceous event’ in the Arctic. Paleontological Journal 29: 22–35.Google Scholar

Herman, A.B. & Spicer, R.A. 1996. Palaeobotanical evidence for a warm Cretaceous Arctic ocean. Nature 380: 330–333.CrossRef Google Scholar

Herman, A.B. & Spicer, R.A. 1997. New quantitative palaeoclimate data for the Late Cretaceous Arctic: evidence for a warm polar ocean. Palaeogeography, Palaeoclimatology, Palaeoecology 128: 227–251.CrossRef Google Scholar

Herman, A.B. & Spicer, R.A. 2010. Mid-Cretaceous floras and climate of the Russian high Arctic (Novosibirsk Islands, northern Yakutia). Palaeogeography, Palaeoclimatology, Palaeoecology 295(3–4): 409–422.CrossRef Google Scholar

Hernández-Castillo, G.R., Stockey, R.A. & Beard, G. 2005. Taxodiaceous pollen cones from the Early Tertiary of British Columbia, Canada. International Journal of Plant Sciences 166(2): 339–346.CrossRef Google Scholar

Hopkins, D.M. (ed.). 1967. The Bering Land Bridge. Stanford, CA: Stanford University Press.Google Scholar

Hu, H.H. 1946. Notes on a Palaeogene species of Metasequoia in China. Bulletin of the Geological Society of China 26: 105–107.CrossRef Google Scholar

Hu, H.H. 1948. How Metasequoia, the ‘living fossil’, was discovered in China. Journal of the New York Botanic Garden 49: 201–207.Google Scholar

Hu, H.-H. & Cheng, W.C. 1948. On the new family Metasequoiaceae and on Metasequoia glyptostroboides, a living species of the genus Metasequoia found in Szechuan and Hupeh. Bulletin of the Fan Memorial Institute Biology, NS 1: 153–161.Google Scholar

Hu, S.-Y. 1980. The Metasequoia flora and its phytogeographic significance. Journal of the Arnold Arboretum 61: 41–94.CrossRef Google Scholar

Hu, Z.-A., Wang, H.-X. & Liu, C.-J. 1986. Biochemical systematics of Gymnosperms (4): seed protein peptides and needle peroxidases of Taxodiaceae. Acta Phytotaxica Sinica 24: 471–473.Google Scholar

Ishida, S., Makinouchi, T., Nishimura, A., et al. 1980. Middle Pleistocene of Kakegawa district, central Japan. The Quaternary Research (Daiyonki-Kenkyu) 19(3): 133–147.CrossRef Google Scholar

Iwauchi, A. & Hase, Y. 1992. Late Cenozoic vegetation and paleoenvironment of northern and central Kyushu, Japan – part 5. Yoshino area (Middle Pleistocene). Journal of the Geological Society of Japan 98: 205–221.Google Scholar

Jagels, R. & Day, M.E. 2003. The adaptive physiology of Metasequoia to Eocene high-latitude environments. Pp 398–429 in Hemsley, A.R. & Poole, I. (eds.), The Evolution of Plant Physiology: From Whole Plants to Ecosystems. London: Elsevier.Google Scholar

Jagels, R. & Equiza, M.A. 2005. Competitive advantages of Metasequoia in warm, high latitudes. Pp 335–349 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia; With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.Google Scholar

Jagels, R. & Equiza, M.A. 2007. Why did Metasequoia disappear from North America but not from China? Bulletin of the Peabody Museum of Natural History 48: 281–290.CrossRef Google Scholar

Jagels, R., Visscher, G.E., Lucas, J. & Goodell, B. 2003. Palaeo-adaptive properties of the xylem of Metasequoia: mechanical/hydraulic compromises. Annals of Botany 92: 79-88.CrossRef Google Scholar

Jahren, A.H. 2007. The Arctic forest of the middle Eocene. Annual Reviews of Earth Planetary Science 35: 509–540.CrossRef Google Scholar

Jahren, A.H., LePage, B.A. & Werts, S.P. 2004. Methanogenesis in Eocene Arctic soils inferred from 13C of tree fossil carbonates. Palaeogeography, Palaeoclimatology, Palaeoecology 214: 347–358.CrossRef Google Scholar

Johnson, K.R. 1992. Leaf-fossil evidence for extensive floral extinction at the Cretaceous–Tertiary boundary, North Dakota, USA. Cretaceous Research 13(1): 91–117.CrossRef Google Scholar

Kingdon-Ward, F. 1954. Berried Treasure. London: Ward Lock and Co. Ltd.Google Scholar

Kohn, M.J. 1996. Predicting animal δ¹⁸O: accounting for diet and physiological adaptation. Geochimica et Cosmochimica Acta 60(23): 4811–4829.CrossRef Google Scholar

Kovar-Eder, J. & Hably, L. 2006. The flora of Mataschen: a unique plant assemblage from the late Miocene of eastern Styria (Austria). Acta Palaeobotanica Krakow 46(2): 157.Google Scholar

Kowalski, E.A. & Dilcher, D.L. 2003. Warmer paleotemperatures for terrestrial ecosystems. Proceedings of the National Academy of Sciences, USA 100: 167–170.CrossRef Google Scholar PubMed

Kuan, C.-T. 1981. Fundamental features of the distribution of Coniferae in Sichuan. Acta Phytotaxica Sinica 14: 407–420 (in Chinese).Google Scholar

Kumagi, H., Sweda, T., Hayashi, K., et al. 1995. Growth-ring analysis of Early tertiary conifer woods from the Canadian High Arctic and its paleoclimatic interpretation. Palaeogeography, Palaeoclimatology, Palaeoecology 116: 247–262.CrossRef Google Scholar

Kunzmann, L. & Mai, D.H. 2011. The first record of fossil Metasequoia (Cupressaceae) from continental Europe. Review of Palaeobotany and Palynology 164: 247–250.CrossRef Google Scholar

Kusumi, J., Tsumura, Y., Yoshimaru, H. & Tacida, H. 2000. Phylogenetic relationships in Taxodiaceae and Cupressaceae sensu stricto based on matK gene, chiL gene, trnL–trnF IGS region, and trnL intron sequence. American Journal of Botany 87: 1480–1488.CrossRef Google Scholar

LaPasha, C.A. & Miller, C.N. 1981. New taxodiaceous seed cones from the Upper Cretaceous of New Jersey. American Journal of Botany 68: 1374–1382.CrossRef Google Scholar

Lemoigne, Y. 1967. Paleoflore a Cupressales dans le Trias-Rhetien du contentin. Comptes Rendus de l’Academie des Sciences (Paris) 264: 715–718.Google Scholar

Leng, Q. 2005. Cuticle analysis of living and fossil Metasequoia. Pp 197–217 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia; With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.Google Scholar

Leng, Q., Yang, H., Yang, Q. & Zhou, J. 2001. Variation of cuticle micromorphology in native population of Metasequoia glyptostroboides (Taxodiaceae). Botanical Journal of the Linnean Society 136: 207–219.CrossRef Google Scholar

LePage, B. & Basinger, J. 1989. Early Tertiary Larix from the Canadian High Arctic. Musk-Ox 37: 103–109.Google Scholar

LePage, B.A., Williams, C.J. & Yang, H. (eds.) 2005. The Geobiology and Ecology of Metasequoia; With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.Google Scholar

Lesquereux, L. 1883. Contributions to the Fossil Flora of the Western Territories, vol. 3. Washington, DC: US Government Printing Office.Google Scholar

Li, C.X. & Yang, Q. 2002. Polymorphism of ITS sequences of nuclear ribosomal DNA in Metasequoia glyptostroboides. Journal of Genetics and Molecular Biology 13(4): 264–271.Google Scholar

Li, C.X. & Yang, Q. 2003. Phylogenetic relationships among the genera of Taxodiaceae and Cupressaceae from 28S rDNA sequences. Yi Chuan= Hereditas 25(2): 177–180.Google Scholar PubMed

Li, H.-L. 1953. Present distribution and habitats of the conifers and taxads. Evolution 7: 245–261.CrossRef Google Scholar

Li, H.-L. 1957. The discovery and cultivation of Metasequoia. Morris Arboretum Bulletin 8: 49–53.Google Scholar

Li, J. 1999. Metasequoia: an overview of its phylogeny, reproductive biology, and ecotypic variation. Arnoldia 58: 54–59.CrossRef Google Scholar

Li, L.-C. 1989. Studies on the cytotaxonomy and systematic evolution of Taxodiaceae Warming. Acta Botanica Yunnanica 11: 113–131 (in Chinese with English abstract).Google Scholar

Li, L.-C. 1990. Two evolutionary lines of Taxodiaceae. Acta Phytotaxonomica Sinica 28: 1–9 (in Chinese with English abstract).Google Scholar

Li, X.-D., Huang, H.-W. & Li, J.Q. 2003. Genetic diversity of the relict plant Metasequoia glyptostroboides. Biodiversity Science 11(2): 100–108 (in Chinese with English abstract).Google Scholar

Li, Y.-H. 1948. Anatomical study of the wood of ‘Shuisha’ (Metasequoia glyptostroboides Hu et Cheng). Tropical Woods 94: 28–29.Google Scholar

Li, Y.Y., Chen, X.-Y., Zhang, X., et al. 2005. Genetic differences between wild and artificial populations of Metasequoia glyptostroboides Hu et Cheng (Taxodiaceae): implications for species recovery. Conservation Biology 19: 224–231.CrossRef Google Scholar

Li, Z.X. & Powell, C.McA. 2001. An outline of the palaeogeographic evolution of the Australasian region since the beginning of the Neoproterozoic. Earth-Science Reviews 53: 237–277.CrossRef Google Scholar

Liang, H., Chow, K.Y. & Au, C.N. 1948. Properties of a ‘living fossil’ wood (Metasequoia glyptostroboides). Wood Technology 1: 1–6.Google Scholar

Liu, Y.-J. & Li, C.-S. 2000. On Metasequoia in Eocene age from Liaoning Province of Northeast China. Acta Botanica Sinica 42: 873–878.Google Scholar

Liu, Y.-J., Arens, N.C. & Li, C.-S. 2007. Range change in Metasequoia: relationship to palaeoclimate. Botanical Journal of the Linnean Society 154: 115–127.CrossRef Google Scholar

Liu, Y.-S. & Basinger, J.F. 2009. Metasequoia Hu et Cheng (Cupressaceae) from the Eocene of Axel Heiberg Island, Canadian High Arctic. Palaeontographica Abteilung B-Palaophytologie 282: 69–97.CrossRef Google Scholar

Longman, A., Dick, J. & Page, C.N. 1982. Cone induction with gibberellin for taxonomic studies in Cupressaceae and Taxodiaceae. Biologia Plantarum 24: 195–201.CrossRef Google Scholar

López-Pujol, J., Zhang, F.M., Sun, H.Q., Ying, T.S. & Ge, S. 2011. Mountains of southern China as ‘plant museums’ and ‘plant cradles’: evolutionary and conservation insights. Mountain Research and Development 31(3): 261–269.CrossRef Google Scholar

Ma, J. & Shao, G. 2003. Rediscovery of the first collection of the ‘living fossil’ Metasequoia glyptostroboides. Taxon 52: 585–588.CrossRef Google Scholar

Ma, Q.-W. & Gu, F.-Q. 2000. Comparative studies on morphological features of some genera in Taxodiaceae. China Bulletin of Botany 17: 161–164.Google Scholar

Ma, Q.-W., Ferguson, D.K., Li, F. & Li, C.-S. 2009. Leaf epidermal structure of extant plants of Cunninghamia and Taiwania (Cupressaceae sensu lato) and their taxonomic application. Review of Palaeobotany and Palynology 155: 15–24.CrossRef Google Scholar

Ma, Q.W., Li, F.L. & Li, C.S. 2005. The coast redwoods (Sequoia, Taxodiaceae) from the Eocene of Heilongjiang and the Miocene of Ongjiang and the Miocene of Yinnan, China. Review of Palaeobotany and Palynology 135: 117–129.CrossRef Google Scholar

Maekawa, F. 1974. Origin and characteristics of Japan’s flora. Pp 33–86 in Numa-Ta, N. (ed.), The Flora and Vegetation of Japan. Tokyo: Kodansha.Google Scholar

Manchester, S.R., Chen, Z., Geng, B.A., Tao, J.U. 2005. Middle Eocene flora of Huadian, Jilin Province, Northeastern China. Acta Palaeobotanica Krakow 45(1): 3.Google Scholar

Manum, S.B. 1963. Some new species of Deflandrea and their probable affinity with Peridinium. Rbok-Norsk Polarinstitutt 1962: 54–67.Google Scholar

Markevich, V.S., Golovneva, L.B. & Bugdaeva, E.V. 2005. Floristicheskaya kharakteristika santon-kampanskikh otlozheny Zeisko-Bureinskovo basseina – Priamur’e (summary: The Santonian Campanian flora of the Zeya-Bureya Basin – Amur Region). Pp 198–206 in Akhmet’ev, M.A. & German, A.B. (eds.), Sovremennye problemy paleofl oristiki, paleofi togeografi i i fi tostratigrafi i. Moscow: GEOS.Google Scholar

Markwick, P.J. 1998. Fossil crocodilians as indicators of Late Cretaceous and Cenozoic climates: implications for using paleontological data in reconstructing microclimates. Palaeogeography, Palaeoclimatology and Palaeoecology 137: 205–271.CrossRef Google Scholar

Maslova, N.P. 2000. New species of Metasequoia Miki (Taxodiaceae, Coniferales) from the late Paleocene of western Kamchatka. Paleontological Journal 34(1): 98–104.Google Scholar

Matsuo, H. 1954. On the Miocene plant fossils from the Hokuriku Region. II. On the genus Metasequoia. Hokiriku Journal of Botany 3: 45–48, 58–61 (in Japanese with English summary).Google Scholar

McIntyre, D.J. 1991. Pollen and spore flora of an Eocene forest, Eastern Axel Heiberg Island, N.W.T. Geological Survey of Canada Bulletin 403: 83–98.Google Scholar

McKenna, M.C. 1975. Fossil mammals and Early Eocene North Atlantic land continuity. Annals of the Missouri Botanical Garden 62: 335–353.CrossRef Google Scholar

Meyer, H.W. 2005. Metasequoia in the Oligocene Bridge Creek Flora of Western North America: ecological implications and the history of research. Pp 159–186 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia; With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.Google Scholar

Meyer, H.W. & Manchester, S.R. 1997. The Oligocene Bridge Creek flora of the John Day Formation, Oregon. University of California Publications in Geological Sciences 141: 1–195.Google Scholar

Miki, S. 1941. On the change of flora in eastern Asia since Tertiary period. 1. The clay and lignite beds flora in Japan with special reference to the Pinus trifoliate beds in central Hondo. Japanese Journal of Botany 11: 237–303.Google Scholar

Miki, S. 1948. Metasequoia, a “living fossil”. Botanica Magazine (Tokyo) 61: 108.CrossRef Google Scholar

Miller, C.N. 1975. Petrified cones and needle-bearing twigs of a new taxodiaceous conifer from the Early Cretaceous of California. American Journal of Botany 62: 706–713.CrossRef Google Scholar

Miller, C.N. 1977. Mesozoic conifers. Biological Review 43: 218–280.Google Scholar

Miller, C.N. 1982. Current status of Paleozoic and Mesozoic conifers. Review of Palaeobotany and Palynology 37: 99–114.CrossRef Google Scholar

Mitchell, A.F. 1972. Conifers in the British Isles. A Descriptive Handbook. London: Her Majesty’s Stationery Office.Google Scholar

Momohara, A. 1993. Early Pleistocene plant extinction and evolution in and around central Japan. Abstract no. 1368 in International Botanical Congress, Tokyo.Google Scholar

Momohara, A. 1994a. Floral and paleoenvironmental history from the Late Pliocene to Middle Pleistocene in and around central Japan. Palaeogeography, Palaeoclimatology, Palaeoecology 108(3–4): 281–293.CrossRef Google Scholar

Momohara, A. 1994b. Paleoecology and paleobiogeography of Metasequoia. Fossils 57: 24–30.Google Scholar

Momohara, A. 2005. Palaeoecology and history of Metasequoia in Japan, with reference to its extinction and survival in East Asia. Pp 115–156 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia: With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.CrossRef Google Scholar

Mustoe, G.E. 1985. Eocene amber from the Pacific coast of North America. Geological Society of America Bulletin 96(12): 1530–1536.2.0.CO;2>CrossRef Google Scholar

Nakamura, J. 1952. Pollen analyses from two Pliocene beds in Shikoku. Report Kochi University Natural Sciences 2: 1–4.Google Scholar

Nordt, L.C., Boutton, T.W., Jacob, J.S. & Mandel, R.D. 2002. C₄ plant productivity and climate-CO₂ variations in south-central Texas during the late Quaternary. Quaternary Research 58(2): 182–188.CrossRef Google Scholar

Osborne, C.P. & Beerling, D.J. 2003. The penalty of a long, hot summer: photosynthetic acclimation to high CO₂ and continuous light in ‘living fossil’ conifers. Plant Physiology 133: 803–812.CrossRef Google Scholar PubMed

Osborne, C.P., Royer, D.L. & Beeerling, D.J. 2004. Adaptive role of leaf-habit in extinct polar forests. International Forestry Review 6: 181–186.CrossRef Google Scholar

Page, C.N. 1973. Ferns, polyploids, and their bearing on the evolution of the Canarian flora. Monographia Biologicae Canariensis 4: 83–88.Google Scholar

Page, C.N. 1977. An ecological survey of the ferns of the Canary Islands. Fern Gazette 11: 297–312.Google Scholar

Page, C.N. 1979. The experimental biology of ferns. Pp 551–579 in Dyer, A.F. (ed.), The Experimental Biology of Ferns. London: Academic Press.Google Scholar

Parrish, J.T. 1998. Interpreting Pre-Quaternary Climate from the Geologic Record. New York: Columbia University Press.Google Scholar

Parrish, J.T. & Spicer, R.A. 1988. Cretaceous (Nanushuk Group, Albian–Cenomanian) wetland environments of the North Slope, Alaska. Abstracts, Geological Society of America 30: 366.Google Scholar

Pearson, P.N. & Palmer, M.R. 2000. Atmospheric carbon dioxide concentration over the past 60 million years. Nature 406: 695–699.CrossRef Google Scholar PubMed

Price, R.A. & Lowenstein, J.M. 1989. An immunological comparison of the Sciadopityaceae, Taxodiaceae, and Cupressaceae. Systematic Botany 14: 141–149.CrossRef Google Scholar

Price, R.A., Thomas, J., Strauss, S.H., et al. 1993. Familial relationships of the conifers from rbcL sequence data. American Journal of Botany 80(172): 22–33.Google Scholar

Quinn, C.J., Price, R.A. & Gadek, P.A. 2002. Familial concepts and relationships in the conifers based on rbcL and matK sequence comparisons. Kew Bulletin 57: 513–531.CrossRef Google Scholar

Rasmussen, J. & Koch, E. 1963. Fossil Metasequoia from Mikines, Faroe Islands. Frooskaparvit (Annales Soc. Science Faeroensis) 12: 83–96 (in Danish with English summary).Google Scholar

Read, J. & Frances, J. 1992. Responses of some Southern Hemisphere tree species to a prolonged dark period and their implications for high-latitude Cretaceous and Tertiary floras. Palaeogeography, Palaeoclimatology, Palaeoecology 99: 271–290.CrossRef Google Scholar

Richter, S. L. & LePage, B.A. 2005. A high-resolution palynological analysis, Axel Heiberg Island, Canadian High Arctic. Pp 137–158 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia: With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.CrossRef Google Scholar

Ricketts, B.D. 1991. Lower Paleocene drowned valley and barred estuaries, Canadian Arctic Islands: aspects of their geomorphological and sedimentological evolution. Clastic Tidal Sedimentology 16: 91–106.Google Scholar

Rothwell, G.W. & Basinger, J.F. 1979. Metasequoia milleri n. sp., anatomically preserved pollen cones from the Middle Eocene (Allenby Formation) of British Columbia. Canadian Journal of Botany 57: 958–970.CrossRef Google Scholar

Royer, D.L., Osborne, C.P. & Beerling, D.J. 2005. Carbon loss by deciduous trees in a CO₂-rich ancient polar environment. Nature 424: 60–62.CrossRef Google Scholar

Sakai, A. 1971. Freezing resistance of relicts from the Arcto-Tertiary flora. New Phytologist 70: 1199–1205.CrossRef Google Scholar

Schlarbaum, S.E. & Tsuchiya, T. 1984. Cytotaxonomy and phylogeny in certain species of Taxodiaceae. Plant Systematics and Evolution 147: 29–54.CrossRef Google Scholar

Schloemer-Jaeger, A. 1958. Alttertiaere Pflanzen aus Floezcn der Broegger-halbinsel Spitzbergens. Palaeontographica Abteilung B 104: 39–103.Google Scholar

Schoenhut, K. 2005. Ultrastructural preservation in Middle Eocene Metasequoia leaf tissues from the Buchanan Lake Formation. Pp 219–252 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia: With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.CrossRef Google Scholar

Serbet, R. & Stockey, R.A. 1991. Taxodiaceous pollen cones from the Upper Cretaceous (Horseshoe Canyon Formation) of Drumheller, Alberta, Canada. Review of Paleobotany and Palynology 70: 67–76.CrossRef Google Scholar

Seward, A.C. 1933. Plant Life Through the Ages. Cambridge: Cambridge University Press.Google Scholar

Shao, Q.H. 1982. Silviculture of some important tree species in China. Allgemeine Forst Zeitschrift 11: 314–315.Google Scholar

Shimada, M. 1953 . The pollen analyses of sonie lignite beds in the north-eastern provinces of Japan. BZCLL Society of Plant Ecology 3.Google Scholar

Spicer, R.A. & Chapman, J.L. 1990. Climate change and the evolution of high-latitude terrestrial vegetation and floras. Trends in Ecology and Evolution 5: 279–284.CrossRef Google Scholar PubMed

Srinivasan, V. & Friis, E.M. 1989. Taxodiaceous conifers from the Upper Cretaceous of Sweden. Biologiske Skrifter 35: 1–57.Google Scholar

Stebbins, G.L. 1948. The chromosomes and relationships of Metasequoia and Sequoia. Science 108: 95–98.CrossRef Google Scholar PubMed

Stockey, R.A., Rothwell, G.W. & Falder, A.B. 2001. Diversity among taxodioid conifers: Metasequoia foxii sp. nov. from the Paleocene of central Alberta, Canada. International Journal of Plant Sciences 162: 221–234.CrossRef Google Scholar

Sun, G., Quan, C., Sun, C.L., et al. 2005. Some new knowledge on subdivisions and age of Wuyun Formation in Jiayin of Heilongjiang, China. Journal of Jilin University (Geoogical Edition) 35(2): 137–142.Google Scholar

Sunderlin, D., Loope, G., Parker, N.E. & Williams, C.J. 2011. Paleoclimatic and paleoecological implications of a Paleocene–Eocene fossil leaf assemblage, Chickaloon Formation, Alaska. Palaios 26(6): 335–345.CrossRef Google Scholar

Sveshnikova, I.N. 1967. Late Cretaceous Coniferae from the U.S.S.R., I. Fossil Coniferae of the Viliuyian depression. Trud Bot Inst An SSSR Ser 8 Paleobotanika 6: 177–203.Google Scholar

Takaso, T. & Tomlinson, P.B. 1992. Seed cone and ovule ontogeny in Metasequoia, Sequoia and Sequoiadendron (Taxodiaceae – Coniferales). Botanical Journal of the Linnean Society 109: 15–37.CrossRef Google Scholar

Tanai, T. 1961. Neogene floral change in Japan. Journal of the Faculty of Science, Hokkaido University 4(9): 1–112.Google Scholar

Tarduno, J.A., Brinkman, D.B., Renne, P.R., et al. 1998. Evidence for extreme climatic warmth from Late Cretaceous Arctic vertebrates. Science 18(5397): 2241–2243.CrossRef Google Scholar

Vakhrameev, V.A. 1991. Jurassic and Cretaceous Floras and Climates of the Earth. Cambridge: Cambridge University Press.Google Scholar

Vann, D.R. 2005. Physiological ecology of Metasequoia glyptostroboides Hu et Cheng. Pp 305–333 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia: With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.CrossRef Google Scholar

Vann, D.R., Williams, C.J., & LePage, B.A. 2003. Experimental evaluation of photosystem parameters and their role in the evolution of stand structure and deciduousness in response to paleoclimate seasonality in Metasequoia glyptostroboides (Huet Cheng). Pp 431–449 in Hemsley, A.R. & Poole, I. (eds.), The Evolution of Plant Physiology: From Whole Plants to Ecosystems. London: Elsevier.Google Scholar

Visscher, G.E. & Jagels, R. 2003. Separation of Metasequoia and Glyptostrobus (Cupressaceae) based on wood anatomy. IAWA Journal 24(4): 439–450.CrossRef Google Scholar

Wang, C.-W. 1961. The forests of China, with a survey of grassland and desert vegetation. Maria Moors Cabot Foundation Publication 5: 1–313.Google Scholar

Wang, F.-H. & Chien, N.-F. 1964. Embryogeny of Metasequoia. Acta Botanica Sinica 1: 241–262 (in Chinese with English summary).Google Scholar

Wang, X.-Q. & Guo, B.-X. 2002. Suggestions for the protection and study of Metasequoia glyptostroboides. Hubei Forest Science and Technology 1: 27–29 (in Chinese).Google Scholar

West, R.M. & Dawson, M.R. 1978. Vertebrate paleontology and the Cenozoic history of the North Atlantic region. Polarforschung 48(1–2): 103–119.Google Scholar

Wilf, P. 2000. Late Paleocene–early Eocene climate changes in southwestern Wyoming: paleobotanical analysis. Geological Society of America Bulletin 112(2): 292–307.2.0.CO;2>CrossRef Google Scholar

Wilf, P. & Labandeira, C.C. 1999. Response of plant–insect associations to Paleocene–Eocene warming. Science 284(5423): 2153–2156.CrossRef Google Scholar PubMed

Wilf, P., Cuneo, N.R., Johnson, K.R., et al. 2003. High plant diversity in Eocene South America: evidence from Patagonia. Science 300: 122–125.CrossRef Google Scholar PubMed

Williams, C.A., Hanan, N., Scholes, R.J. & Kutsch, W. 2009. Complexity in water and carbon dioxide fluxes following rain pulses in an African savanna. Oecologia 161: 469–480.CrossRef Google Scholar

Williams, C.J. 2005. Ecological characteristics of Metasequoia glyptostroboides. Pp 285–304 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia: With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.CrossRef Google Scholar

Williams, C.J., Johnson, A.H., LePage, B.A., Vann, D.R. & Sweda, T. 2003. Reconstruction of Metasequoia forests. II: Structure, biomass, and productivity of Eocene floodplain forests in the Canadian Arctic. Paleobiology 29: 271–292.2.0.CO;2>CrossRef Google Scholar

Wing, S.L., Alroy, J. & Hickey, L.J. 1995. Plant and mammal diversity in the Paleocene to Early Eocene of the Bighorn Basin. Palaeogeography, Palaeoclimatology, Palaeoecology 115: 117–155.CrossRef Google Scholar

Wolfe, J.A. 1972. An interpretation of Alaskan Tertiary floras. Pp 201–233 in Graham, A. (ed.). Floristics and Paleofloristics of Asia and Eastern North America. Amsterdam: Elsevier.Google Scholar

Wolfe, J.A. 1977. Paleogene floras from the Gulf of Alaska region: U.S. Geological Survey Professional Paper 997.CrossRef Google Scholar

Wolfe, J.A. 1978. A paleobotanical interpretation of Tertiary climates in the Northern Hemisphere. American Science 66: 694–703.Google Scholar

Wolfe, J.A. 1979. Temperature parameters of humid to mesic forests of eastern Asia and relation to forests of other regions of the northern hemisphere and Australia. US Geological Survey Professional paper 1106.CrossRef Google Scholar

Wolfe, J.A. 1985. Distribution of major vegetational types during the Tertiary. Geophysical Monographs 32: 357–375.Google Scholar

Wolfe, J.A. 1987. Late Cretaceous–Cenozoic history of deciduousness and the terminal Cretaceous event. Paleobiology 13: 215–226.CrossRef Google Scholar

Wolfe, J.A. 1994. Tertiary climatic changes at middle latitudes of western North America. Palaeogeography, Palaeoclimatology, Palaeoecology 108: 195–205.CrossRef Google Scholar

Wolfe, J.A. 1995. Paleoclimatic estimates from Tertiary leaf assemblages. Annual Review of Earth and Planetary Sciences 23: 119–142.CrossRef Google Scholar

Wolfe, J.A. & Upchurch, G.R. Jr. 1987. North American nonmarine climates and vegetation during the Late Cretaceous. Palaeogeography, Palaeoclimatology, Palaeoecology 61: 33–77.CrossRef Google Scholar

Woodward, F.I. & Kelly, C.K. 2008. Responses of global plant diversity capacity to changes in carbon dioxide concentration and climate. Ecology Letters 11(11): 1229–1237.CrossRef Google Scholar

Xi, Y.-Z. 1986. Studies on pollen morphology of Taxodiaceae. Bulletin of Botanical Research 6(3): 127–144.Google Scholar

Xiong, X.Z. 1986. Palaeocene flora from the Wuyun Formation in Jiayin of Heilongjiang. Acta Palaeontologica Sinica 25(5): 571–576.Google Scholar

Yamakawa, C., Momohara, A., Nunotani, T., Matsumoto, M & Watano, Y. 2008. Paleovegetation reconstruction of fossil forests dominated by Metasequoia and Glyptostrobus from the late Pliocene Kobiwako Group, central Japan. Paleontological Research 12: 167–180.CrossRef Google Scholar

Yang, H. 2005. Biomolecules from living and fossil Metasequoia: biological and geological applications. Pp 253–281 in LePage, B.A., Williams, C.J. & Yang, H. (eds.), The Geobiology and Ecology of Metasequoia:; With Contributions from the 1st International Metasequoia Symposium 2002 Aug 5–7, Wuhan, Hubei, People’s Republic of China. Dordrecht: Springer.CrossRef Google Scholar

Yang, H. & Jin, J.-H. 2000. Phytogeographical history and evolutionary stasis of Metasequoia: geological and genetic information contrasted. Acta Palaeontologica Sinica 39 (suppl.): 288–307.Google Scholar

Yao, X., Zhou, Z. & Zhang, B. 1998. Reconstruction of the Jurassic conifer Sewardiodendron laxum (Taxodiaceae). American Journal of Botany 85: 1289–1300.CrossRef Google Scholar PubMed

Yarmolenko, A.V. & Krystofovich, A.N. 1956. Taxodiaceae. Oligotsenovaia flory gory Ashutas v Kazakhstana. Paleobotanika 1: 51–59.Google Scholar

Ying, T.-S. & Li, L.-Q. 1981. Ecological distribution of endemic genera of taxads and conifers in China and neighbouring area in relation to phytogeographical significance. Acta Phytotaxonomica Sinica 14: 415–425.Google Scholar

Ying, T. S., Zhang, Y. L. & Boufford, D. E. 1993. The Endemic Genera of Seed Plants of China. Beijing: Science Press.Google Scholar

Zachos, J., Oaganini, M., Sloan, I., Thomas, E. & Billups, K. 2001. Trends, rhythms, and aberrations in global climate 65 Ma to present. Science 292: 686–693.CrossRef Google Scholar PubMed

Zachos, J.C., Stott, L.D. & Lohmann, K.C. 1994. Evolution of early Cenozoic marine temperatures. Palaeoceanography 9: 353–387.CrossRef Google Scholar

Zalewska, Z. 1959. The fossil flora of Turow near Bogatinia. Coniferae: Taxodiaceae. Prace Muzeum Ziemi 3: 69–73 (in Polish and English).Google Scholar

Zhilin, S.G. 1989. History of the development of the temperate forest flora in Kazakhstan (USSR) from the Oligocene to the Early Miocene. Botanical Review 55: 205.CrossRef Google Scholar

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Chapter 47 - Metasequoia

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