Book contents
- Evolution of the Arborescent Gymnosperms: Pattern, Process and Diversity
- Reviews
- Evolution of the Arborescent Gymnosperms
- Copyright page
- Contents
- Preface and Acknowledgements
- Structure of the Volumes
- Part I Aims, Approaches and Diversity
- Part II Phylogenetic Bases and Revised Taxonomic Structure
- Part III Living Arborescent Gymnosperm Genetic Presentations
- Chapter 1 Ginkgo
- Chapter 2 Picea
- Chapter 3 Cathaya
- Chapter 4 Pinus
- Chapter 5 Larix
- Chapter 6 Pseudotsuga
- Chapter 7 Abies
- Chapter 8 Nothotsuga
- Chapter 9 Tsuga
- Chapter 10 Keteleeria
- Chapter 11 Pseudolarix
- Chapter 12 Cedrus
- Chapter 13 Taxus
- Chapter 14 Pseudotaxus
- Chapter 15 Austrotaxus
- Chapter 16 Cephalotaxus
- Chapter 17 Amentotaxus
- Chapter 18 Torreya
- Chapter 19 Sciadopitys
- Chapter 20 Cupressus
- Chapter 21 Hesperocyparis
- Chapter 22 Chamaecyparis
- Chapter 23 Fokienia
- Chapter 24 Thujopsis
- Chapter 25 Thuja
- Chapter 26 Xanthocyparis
- Chapter 27 Juniperus
- Chapter 28 Platycladus
- Chapter 29 Microbiota
- Chapter 30 Calocedrus
- Chapter 31 Neocallitropsis
- Chapter 32 Callitris
- Chapter 33 Actinostrobus
- Chapter 34 Widdringtonia
- Chapter 35 Tetraclinis
- Chapter 36 Libocedrus
- Chapter 37 Papuacedrus
- Chapter 38 Austrocedrus
- Chapter 39 Pilgerodendron
- Chapter 40 Diselma
- Part IV From Ecosystem Services to Conservation and Sustainability
- Selected Bibliography
- Genus Index
- Plate Section (PDF Only)
- References
Chapter 34 - Widdringtonia
Cupressales: Cupressaceae S.S.
from Part III - Living Arborescent Gymnosperm Genetic Presentations
Published online by Cambridge University Press: 11 November 2024
Book contents
- Evolution of the Arborescent Gymnosperms: Pattern, Process and Diversity
- Reviews
- Evolution of the Arborescent Gymnosperms
- Copyright page
- Contents
- Preface and Acknowledgements
- Structure of the Volumes
- Part I Aims, Approaches and Diversity
- Part II Phylogenetic Bases and Revised Taxonomic Structure
- Part III Living Arborescent Gymnosperm Genetic Presentations
- Chapter 1 Ginkgo
- Chapter 2 Picea
- Chapter 3 Cathaya
- Chapter 4 Pinus
- Chapter 5 Larix
- Chapter 6 Pseudotsuga
- Chapter 7 Abies
- Chapter 8 Nothotsuga
- Chapter 9 Tsuga
- Chapter 10 Keteleeria
- Chapter 11 Pseudolarix
- Chapter 12 Cedrus
- Chapter 13 Taxus
- Chapter 14 Pseudotaxus
- Chapter 15 Austrotaxus
- Chapter 16 Cephalotaxus
- Chapter 17 Amentotaxus
- Chapter 18 Torreya
- Chapter 19 Sciadopitys
- Chapter 20 Cupressus
- Chapter 21 Hesperocyparis
- Chapter 22 Chamaecyparis
- Chapter 23 Fokienia
- Chapter 24 Thujopsis
- Chapter 25 Thuja
- Chapter 26 Xanthocyparis
- Chapter 27 Juniperus
- Chapter 28 Platycladus
- Chapter 29 Microbiota
- Chapter 30 Calocedrus
- Chapter 31 Neocallitropsis
- Chapter 32 Callitris
- Chapter 33 Actinostrobus
- Chapter 34 Widdringtonia
- Chapter 35 Tetraclinis
- Chapter 36 Libocedrus
- Chapter 37 Papuacedrus
- Chapter 38 Austrocedrus
- Chapter 39 Pilgerodendron
- Chapter 40 Diselma
- Part IV From Ecosystem Services to Conservation and Sustainability
- Selected Bibliography
- Genus Index
- Plate Section (PDF Only)
- References
Summary
Graceful evergreen trees or large shrubs, with linear acicular soft greyish-green leaves which long-persist or changing gradually to adult cupressoid foliage. Branches and branchlets are not flattened into a single plane. The adult foliage is without distinction between facial and lateral pairs. The seed cones are borne erect, often clustered and each of two pairs of scales which are woody when mature.
- Type
- Chapter
- Information
- Evolution of the Arborescent GymnospermsPattern, Process and Diversity, pp. 588 - 600Publisher: Cambridge University PressPrint publication year: 2024
References
Bond, W.J. & Breytenbach, G.J. 1985. Ants, rodents and seed predation in Proteaceae. South African Journal of Zoology 20: 150–154.CrossRefGoogle Scholar
Brown, P.J., Manders, P.T. & Bands, D.P. 1991. Prescribed burning as a conservation management practice: a case history from the Cederberg Mountains, Cape Province, South Africa. Biological Conservation 56: 133–150.CrossRefGoogle Scholar
Brunsfeld, S.J., Soltis, P.S., Soltis, D.E., Gadek, P.A. & Quinn, C.J. 1994. Phylogenetic relationships amongst the genera of the Taxodicaeae and Cupressaceae: evidence from rbcL sequences. Systematic Botany 19: 253–262.CrossRefGoogle Scholar
Chapman, J.D. 1961. Some notes of the taxonomy, distribution, ecology and economic importance of Widdringtonia, with particular reference to W. whytei. Kirkia 1: 138–154.Google Scholar
Chapman, J.D. 1992. Notes on Mulanje Cedar Malawi’s national tree. Commonwealth Forestry Review (United Kingdom) 73: 272–273.Google Scholar
Chapola, B.B.J. 1990. Wood properties of wide and narrow crowned variants of Widdringtonia nodiflora Powrie (Mulanje Cedar) growing at Zomba Mountain, Malawi. South African Forestry Journal 154: 47–50.CrossRefGoogle Scholar
Erdtman, H. & Norin, T. 1966. Chemistry of the Cupressales. Fortschritte der Chemie Organischer Naturstoffe 24: 206–287.Google Scholar
Farjon, A. 2005. A Monograph of Cupressaceae and Sciadopitys. Kew: Royal Botanic Gardens.Google Scholar
Farjon, A. & Ortiz García, S. 2005. The early development of ovuliferous cones in Cupressaceae s.lat: a survey of the genera. Pp 27–46 in Farjon, A. (ed.), A Monograph of Cupressaceae and Sciadopitys. Kew: Royal Botanic Gardens.Google Scholar
February, E.C. & Stock, W.D. 1999. Declining trend in the 13C/12C ratio of atmospheric carbon dioxide from tree rings of South African Widdringtonia cedarbergensis. Quaternary Research 52: 229–236.CrossRefGoogle Scholar
Gadek, P.A. & Quinn, C.J. 1983. Biflavones of the subfamily Callitroideae, Cupressceae. Phytochemistry 22: 969–972.CrossRefGoogle Scholar
Gadek, P.A. & Quinn, C.J. 1993. An analysis of relationships within the Cupressaceae sensu stricto based on rbcL sequences. Annals of the Missouri Botanic Garden 80: 581–586.CrossRefGoogle Scholar
Gadek, P.A., Alpers, D.L., Heslewood, M.M. & Quinn, C.J. 2000. Relationships within Cupressaceae sensu lato: a combined morphological and molecular approach. American Journal of Botany 87: 1044–1057.CrossRefGoogle Scholar
Hart, J.A. 1987. A cladistic analysis of conifers: preliminary results. Journal of the Arnold Arboretum 68: 269–307.CrossRefGoogle Scholar
Heer, O. 1874. Nachträge zur Miocene Flora Grönlands. Flora Fossilis Arctica. Band III: Heft 2 & 3. Kgl. Svenska Vetenskapsakad. Handlingar 12: 1–11.Google Scholar
Higgins, K.B., Manders, P.T. & Lamb, A.B. 1989. The efficacy of microclimate shelters in improving seedling survival in re-establishment of the Clanwilliam cedar. South African Forestry Journal 151: 1–5.CrossRefGoogle Scholar
Hubbard, C.S. 1937. Observations on the distribution and rate of growth of Clanwilliam cedar Widdringtonia juniperoides Endl. (now cedarbergensis). South African Journal of Science 33: 572–586.Google Scholar
Krasser, F. 1896. Beitrage zur Kenntniss der fossilen Kreideflora von Kunstadt in Mahren. Beitrage Palaeontol. Oesterr Ungarns 10: 113–152.Google Scholar
Linder, H.P. 2003. Evolution of diversity: the Cape Flora. Trends in Plant Science 10: 536–541.CrossRefGoogle Scholar
Manders, P.T. 1986a. The effect of shading on nursery-grown seedlings of the Clanwilliam cedar. South African Forestry Journal 138: 15–22.CrossRefGoogle Scholar
Manders, P.T. 1986b. An assessment of the current status of the Clanwilliam cedar Widdringtonia cedarbergensis and the reasons for its decline. South African Forestry Journal 139: 48–53.CrossRefGoogle Scholar
Manders, P.T. & Botha, S.A. 1987. Experimental re-establishment of the Clanwilliam cedar (Widdringtonia cedarbergensis): a preliminary study. South African Journal of Wildlife Research 17: 86–90.Google Scholar
Manders, P.T. & Botha, S.A. 1989. A note on establishment of Widdringtonia cedarbergensis (Clanwilliam cedar). Journal of Applied Ecology 26: 571–574.CrossRefGoogle Scholar
Manders, P.T., Botha, S.A., Bond, W.J. & Meadows, M.E. 1990. The enigmatic Clanwilliam cedar. Veld and Flora 76: 8–11.Google Scholar
Marsh, J.A. 1966. Cupressaceae. Pp 43–48 in Codd, L.E., de Winter, B. & Rycroft, H.B. (eds.), Flora of Southern Africa: I. Pretoria: Government Printer.Google Scholar
McIver, E.E. 2001. Cretaceous Widdringtonia Endl. (Cupressaceae) from North America. International Journal of Plant Sciences 162: 937–961.CrossRefGoogle Scholar
Meadows, M.E. & Sugden, J.M. 1990. Late Quaternary vegetation of the Cederberg, south-west Cape. Palaeoecology of Africa 21: 269–281.Google Scholar
Meadows, M.E. & Sugden, J.M. 1991. A vegetation history of the last 14,000 years in the Cederberg, south-western Cape Province. South African Journal of Science 87: 34–43.Google Scholar
Miller, C.N. 1999. Implications of fossil conifers for the phylogenetic relationships of living families. The Botanical Review 65: 239–277.CrossRefGoogle Scholar
Moseley, M.F. 1943. Contributions to the life history, morphology and phylogeny of Widdringtonia cupressoides. Lloydia 6: 109–132.Google Scholar
Mustart, P., Juritz, J. Makua, C., Van der Merwe, S.W. & Wessels, N. 1995. Restoration of the Clanwilliam cedar Widdringtonia cedarbergensis: the importance of monitoring seedlings planted in the Cederberg, South Africa. Biological Conservation 72: 73–76.CrossRefGoogle Scholar
Pauw, C.A. & Linder, H.P. 1997. Tropical African cedars (Widdringtonia, Cupressaceae): systematics, ecology and conservation status. Botanical Journal of the Linnean Society 123: 297–319.CrossRefGoogle Scholar
Saki, I. 1989. A report on the Mulanje cedar resources and the present crisis. Forestry Research Institute of Malawi Record 65: 1–10.Google Scholar
Saporta, G. 1863. Etudes sur la vegetation du sud-est de la France a l’epoque Tertaire. Annales des Sciences Naturelles, Botanique, pt 1 ser 4, 19: 5–124.Google Scholar
Saxton, W.T. 1913. Contributions to the life-history of Tetraclinis articulata Masters with some notes on the phylogeny of the Cupressoideae and Callitroideae. Annals of Botany 27: 577-605.CrossRefGoogle Scholar
Taylor, H.C. 1976. Notes of the vegetation and flora of the Cederberg. Veld and Flora 62: 28–30.Google Scholar
Tiffney, B.H. 1985. The Eocene North Atlantic land bridge: its importance in the Tertiary and modern phytogeography of the Northern Hemisphere. Journal of the Arnold Arboretum 66: 243–273.CrossRefGoogle Scholar
Thomas, J.C. & Bond, W.J. 1997. Genetic variation in an endangered cedar (Widdringtonia cedarbergensis) versus two congeneric species. South African Journal of Botany 63: 133–140.CrossRefGoogle Scholar
Vakhrameev, V.A. 1991. Jurassic and Cretaceous Floras and Climates of the Earth. Cambridge: Cambridge University Press.Google Scholar
Velenovsky, J. 1885. Die Gymnospermen der bohmischen Kreide-formation. Prague: Ed. Greger.CrossRefGoogle Scholar
Venkatesh, C.S. 1987. Narrow-crowned variants of the Mulanje Cedar (Widdringtonia nodiflora Powrie) in Malawi. Silvae Genetica 36: 238–240.Google Scholar
Walther, H. 1995. Invasion of Arcto-Tertiary elements in the Palaeogene of central Europe. Pp 239–250 in Boulter, M.C. & Fisher, H.C. (eds.), Cenozoic Plants and Climates of the Arctic. Berlin: Springer.Google Scholar
White, F. 1983. The Vegetation of Africa, a Descriptive Memoir to accompany the UNESCO/AETFAT/UNSO Vegetation Map of Africa. Gland: UNESCO.Google Scholar