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Bennettitales

April 13, 2023

Bennettitales (also known as cycadeoids) is an extinct order of seed plants that first appeared in the Permian period and became extinct in most areas toward the end of the Cretaceous. Bennettitales were amongst the most common seed plants of the Mesozoic, and had morphologies including shrub and cycad-like forms. The foliage of bennettitaleans is superficially nearly indistinguishable from that of cycads, but they are distinguished from cycads by their more complex flower-like reproductive organs, at least some of which were likely pollinated by insects.[1]

Bennettitales
Temporal range: Permian - Late Cretaceous,
Kungurian –Maastrichtian Possible Oligocene record
Restoration of a member of Williamsoniaceae by Thérèse Ekblom
Life restoration of "Williamsonia" sewardiana from the Early Cretaceous of India, which may represent an early member of Cycadeoidaceae
Scientific classification
Kingdom: Plantae
Clade: Tracheophytes
Clade: Spermatophytes
Order: Bennettitales
Engler, 1892
Families

Although certainly gymnosperms (cone-bearing seed plants), the relationships of bennettitaleans to other seed plants is debated. Their general resemblance to cycads is contradicted by numerous more subtle features of their reproductive systems and leaf structure. Some authors have linked bennettitaleans to angiosperms (flowering plants) and gnetophytes (a rare and unusual group of modern gymnosperms), forming a broader group known as Anthophyta. Molecular data contradicts this, with gnetophytes found to be much more genetically similar to conifers. The exact position of Bennettitales remains uncertain.

Description

 
Bennettitales foliage assigned to the genus Pterophyllum
 
Restoration of the willamsoniacean shrub Wielandiella angustifolia showing divaricate branching habit

Bennettitales are divided into two families, Cycadeoidaceae and Williamsoniaceae, which have distinct growth habits. Cycadeoidaceae had stout, cycad-like trunks with bisporangiate (containing both megaspores and microspores) strobili (cones) serving as their reproductive structures. Williamsoniaceae either had bisporangiate or monosporangiate cones, and distinctly slender and branching woody trunks.[1] The Williamsoniaceae grew as woody shrubs with a divaricate branching habit, similar to that of Banksia.[2] It has been suggested that Williamsoniaceae are a paraphyletic (not containing all descendants of a common ancestor) assemblage of all Bennettitales that do not belong to the Cycadeoidaceae.[2]

Foliage

In general, bennettitalean leaves are attached to the stem with a helical (corkscrew) arrangement. Some leaves (most species of Nilssoniopteris, etc.) are narrow, solitary blades with a smooth-edged ("entire") margin.[3] Most leaf morphotypes (Pterophyllum, Ptilophyllum, Zamites, Otozamites, etc.) are pinnate (feather-shaped), with many small leaf segments attached to a central shaft. Others (Anomozamites, a few species of Nilssoniopteris) are incompletely pinnate (sawtooth-shaped) and transitional between these two end members. One unusual leaf form, Eoginkgoites, even approaches a palmate appearance similar to early species of Ginkgo.[4]

The foliage of bennettitaleans resembles that of cycads to such an extent that the foliage of the two groups cannot be reliably distinguished based on gross morphology alone. However, fossil foliage which preserves the cuticle can be assigned to either group with confidence. The stomata of bennettitaleans are described as syndetocheilic. This means that the main paired guard cells develop from the same mother cells as the subsidiary cells which surround them. This contrasts with the haplocheilic stomata of cycads and conifers. In haplocheilic stomata, the ring of subsidiary cells are not derived from the same original structures as the guard cells. This fundamental difference is the main way to differentiate bennettitalean and cycad foliage.[5]

Cones and seeds

 
Diagram of male Williamsoniaceae reproductive structure Weltrichia. Labels: CFR Centrifugal ray; CPR Centripetal ray; MR Median ridge; FS Fibrous strand; PS Pollen sac position (in this case, pollen sac attachment); CC Central cup; RBA Resin (resinous) body or attractant; ST Stalk
 
Cross section of the female williamsoniaceous seed cone Williamsonia harrisiana

Like other gymnosperms, bennettitalean reproductive inflorescences come in the form of cones, which produce pollen and ovules (unfertilized seeds). The cones have a thick central receptacle surrounded by simple, helically-arranged fertile and infertile structures. Tissue at the base of the cone forms layers of scale-like or petal-like bracts to protect the radiating inner structures. Some authors refer to bennettitalean cones as “flowers”, though they are not equivalent to true angiosperm flowers. Pollen is often enclosed in paired synangia (pollen sacs). The synangia lie on the adaxial (inner) edge of pollen-bearing leaf-like structures known as microsporophylls. This contrasts with cycads, all of which lack discrete synangia and bear pollen on the abaxial (outer) surface of their microsporophylls.[6]

Many bennettitaleans are bisporangiate, where the pollen and ovules are hosted on the same (bisexual or hermaphrodite) cone. Cavities filled with curved synangia-bearing microsporophylls are encased by thin radiating structures, including thick, infertile interseminal scales and fertile sporophylls with ovules at their tips. The presence of ovules at the tips of sporophylls, rather than the tips of stems, is a major difference between the cones of bennettitaleans and gnetophytes. As the cone is fertilized and matures, the microsporophylls wither away and the ovules transform into seeds.[6]

Most bennettitaleans in the family Williamsoniaceae are instead monosporangiate, with separate pollen and ovule-producing (unisexual) cones on the same plant. The ovule-producing (female) cones (Williamsonia, etc.) are similar to mature bisporangiate cones, with interseminal scales and ovule-tipped sporophylls enclosed by bracts. Pollen-producing (male) cones (Weltrichia, etc.), on the other hand, feature an exposed crown of tapering microsporophylls with adaxial rows of synangia. The microsporophylls may host a single linear row of paired synangia, or instead synangia arranged in a pinnate (feather-shaped) pattern.[6]

Seeds are dicotyledonous (possess two embryonic leaves), with a central embryo surrounded by three layers: the thin megagametophyte, the slightly thicker nucellus, and the protective integument. The upper tip of the seed is tapered and opens through a thin and often extended micropyle. A long, narrow micropyle extending out of the seed is superficially similar to the condition in living gnetophytes. Once the seed is fertilized, the micropyle is sealed by a plug-shaped extension of the nucellus. Unlike living gymnosperms, the tip of the nucellus lacks a pollen chamber (receptacle for stored pollen). The integument is dense and thick, with many layers of differentiated cells. This contrasts with the thin, biseriate (two cell-layer) integument of gnetophytes. Bennettitaleans also lack another gnetophyte-like trait: a sheath of fused bracteoles enveloping the seed. Most integument cells are not unusual in size or shape. However, near the micropyle the innermost layer of integument cells become radially-oriented and elongated, partially closing in on the micropyle. The nucellus and integument are unfused above the chalaza (base of the seed), unlike cycads or gnetophytes, where the layers are fused for much of their height.[6]

Cycadeoidaceans were likely self-pollinating, with their stems and cones buried underground.[1][7] The flower-like williamsoniacean male reproductive structure Weltrichia is associated with the female reproductive structure Williamsonia, though it is uncertain whether the parent plants were monoecious (male and female reproductive structures being present on the same plant) or dioecious (where each plant has only one gender of reproductive organ). Weltrichia was likely primarily wind-pollinated, with some species possibly pollinated by beetles.[8] Several groups of Jurassic and Early Cretaceous insects possessed a long proboscis, and it has been suggested that they fed on nectar produced by bennettitalean reproductive structures, such as the bisexual williamsoniacean reproductive structure Williamsoniella, which had a long, narrow central receptacle which was likely otherwise inaccessible.[9] Early Cretaceous bennettitalean pollen has been found directly associated with a proboscis bearing fly belonging to the extinct family Zhangsolvidae, providing evidence that this family acted as pollinators for the group.[10] The interseminal scales of Bennettitales ovulate cones may have become fleshy at maturity, which could have potentially made then attractive to wild animals that served as seed dispersers.[11]

Taxonomy

The Cycadeoideaceae (originally “Cycadeoideae”) were named by English geologist William Buckland in 1828, from fossil trunks found in Jurassic strata on the Isle of Portland, England, which Buckland gave the genus name Cycadeoidea. Buckland provided a description of the family and two species, but failed to give a description of the genus, which has led to Buckland's description of the family being considered invalid by modern taxonomic standards.[12] In publications in 1870, Scottish botanist William Carruthers and English paleobotanist William Crawford Williamson described the first known reproductive organs of the Bennettitales from Jurassic strata of Yorkshire and Jurassic-Cretaceous strata of the Isle of Wight and the Isle of Portland.[13][14][15] Caruthers was the first to recognise that Bennettitales had distinct differences from cycads, and established the tribes "Williamsonieae" and "Bennettiteae",[15] with the latter being named after the genus Bennettites named by Caruthers in the same publication, the name being in honour of British botanist John Joseph Bennett.[13][16] The order Bennettitales was erected by German botanist Adolf Engler in 1892, who recognised the group as separate from the Cycadales.[17] The Anthophyte hypothesis erected by Arber and Parking in 1907[18] posited that angiosperms arose from Bennettitales, as suggested by the wood-like structures and rudimentary flowers.[1] Based on morphological data, however, Bennettitales were classified as a monophyletic group when paired with Gnetales.[19] a study in 2006 suggested that Bennettitales, Angiosperms, and Gigantopteridales form a clade based on the presence of oleanane.[20] A 2007 study examining phase-contrast X-ray images of gymnosperm seeds supported the Anthophyte hypothesis.[21] Evidence from seed coats suggest that Bennettitales form a clade with the gymnosperm orders of Gnetales and Erdtmanithecales.[21] Molecular evidence has consistently contradicted the Anthophyte hypothesis, finding that Angiosperms are the sister group to all living gymnosperms, including Gnetales.[22] A 2017 phylogeny based on molecular signatures of fossilised cuticles found that Bennettitales were more closely related to the Ginkgo+Cycads clade than conifers, and were closely related to Nilssonia and Ptilozamites.[23]

Evolutionary history

The oldest confirmed fossils of bennettitaleans are leaves of Nilssoniopteris shanxiensis, a species from the upper part of the Upper Shihhotse Formation in Shanxi Province, China.[5] This strata is dated to the early Kungurian stage of the early Permian (Cisuralian), around 281 million years ago.[24] Supposed Carboniferous-Permian records of Pterophyllum do not have conclusive bennettitalean affinities or have been reinterpreted as cycad foliage in the form genus Pseudoctenis.[25] True Permian records of benettitalean leaves are rare; outside of the Shihhotse Formation they are only found in the Late Permian (likely Changhsingian)-age Umm Irna Formation in Jordan.[5] This formation is notable for the early occurrence of other Mesozoic-style flora, including the earliest records of corystospermalean foliage (Dicroidium), podocarpacean conifer branches (Elatocladus), and Triassic-style zamiinean cycads.[26] The order Fredlindiales (containing the genus Fredlindia) from the Late Triassic of Gondwana appears to be closely related to Bennettitales, but differs from it in some aspects of its reproductive organs.[15]

The bennettitalean fossil record reappeared in the Middle Triassic, and williamsoniaceans became globally distributed by the end of the period.[27][5] The oldest bennettitalean reproductive structures are small Williamsonia "flowers" from the Middle Triassic Esk Formation of Australia.[15] While Williamsoniaceae had a global distribution, Cycadeoidaceae appear to have been primarily confined to the western parts of Laurasia, and are primarily known from the Cretaceous.[15] Bennettitales were widespread and abundant during the Jurassic and Early Cretaceous, however Bennettitales severely declined during the Late Cretaceous, coincident with the rise of flowering plants, being mostly extinct by the end of the period, with the final known remains from the Northern Hemisphere being found in the polar latitude Kakanaut Formation in Chukotka, Russia, dating to the Maastrichtian, assignable to Pterophyllum.[28] A possible late record has been reported from the early Oligocene of eastern Australia and Tasmania, assignable to the genus Ptilophyllum, but no cuticle was preserved, making the referral inconclusive.[29]

Subgroups

Gallery

References

  1. ^ a b c d Peñalver, Enrique; Arillo, Antonio; Pérez-de la Fuente, Ricardo; Riccio, Mark L.; Delclòs, Xavier; Barrón, Eduardo; Grimaldi, David A. (2015). "Long-Proboscid Flies as Pollinators of Cretaceous Gymnosperms". Current Biology. 25 (14): 1917–1923. doi:10.1016/j.cub.2015.05.062.
  2. ^ a b Pott, Christian; McLoughlin, Stephen (2014-06-01). "Divaricate growth habit in Williamsoniaceae (Bennettitales): unravelling the ecology of a key Mesozoic plant group". Palaeobiodiversity and Palaeoenvironments. 94 (2): 307–325. doi:10.1007/s12549-014-0157-9. S2CID 84440045.
  3. ^ Ray, M.M.; Rothwell, G.W.; Stockey, R.A. (September 2014). "Anatomically Preserved Early Cretaceous Bennettitalean Leaves: Nilssoniopteris corrugata n. sp. from Vancouver Island, Canada". Journal of Paleontology. 88 (5): 1085–93. doi:10.1017/S002233600005767X. S2CID 232349931.
  4. ^ Pott, Christian; Axsmith, Brian J. (February 2015). "Williamsonia carolinensis sp. nov. and Associated Eoginkgoites Foliage from the Upper Triassic Pekin Formation, North Carolina: Implications for Early Evolution in the Williamsoniaceae (Bennettitales)". International Journal of Plant Sciences. 176 (2): 174–185. doi:10.1086/679471. S2CID 44559347.
  5. ^ a b c d Blomenkemper, Patrick; Bäumer, Robert; Backer, Malte; Abu Hamad, Abdalla; Wang, Jun; Kerp, Hans; Bomfleur, Benjamin (2021). "Bennettitalean Leaves From the Permian of Equatorial Pangea—The Early Radiation of an Iconic Mesozoic Gymnosperm Group". Frontiers in Earth Science. 9: 162. Bibcode:2021FrEaS...9..162B. doi:10.3389/feart.2021.652699.
  6. ^ a b c d Rothwell, Gar W.; Crepet, William L.; Stockey, Ruth A. (2009). "Is the anthophyte hypothesis alive and well? New evidence from the reproductive structures of Bennettitales". American Journal of Botany. 96 (1): 296–322. doi:10.3732/ajb.0800209. PMID 21628190.
  7. ^ Osborn, J.M.; Taylor, M.L. (2010). "Pollen and coprolite structure in Cycadeoidea (Bennettitales): implications for understanding pollination and mating systems in Mesozoic cycadeoids". Plants in deep Mesozoic time: morphological innovations, phylogeny, and ecosystems. Bloomington, IN: Indiana University Press. pp. 34–49. ISBN 978-0-253-00199-3.
  8. ^ Popa, Mihai Emilian (2019-02-27). "Review of the bennettitalean genus Weltrichia". Journal of Palaeogeography. 8 (1): 12. Bibcode:2019JPalg...8...12P. doi:10.1186/s42501-019-0023-9. S2CID 85458053.
  9. ^ Khramov, Alexander V.; Lukashevich, Elena D. (July 2019). "A Jurassic dipteran pollinator with an extremely long proboscis". Gondwana Research. 71: 210–215. Bibcode:2019GondR..71..210K. doi:10.1016/j.gr.2019.02.004. S2CID 134847380.
  10. ^ Peñalver E, Arillo A, Pérez-de la Fuente R, Riccio ML, Delclòs X, Barrón E, Grimaldi DA (July 2015). "Long-Proboscid Flies as Pollinators of Cretaceous Gymnosperms". Current Biology. 25 (14): 1917–23. doi:10.1016/j.cub.2015.05.062. PMID 26166781.
  11. ^ Friis, Else Marie; Pedersen, Kaj Raunsgaard; Crane, Peter R., eds. (2011), "Angiosperms in context: extant and fossil seed plants", Early Flowers and Angiosperm Evolution, Cambridge: Cambridge University Press, pp. 101–140, ISBN 978-0-521-59283-3, retrieved 2023-03-20
  12. ^ Doweld, Alexander B. (2016-05-03). "The nomenclature of Cycadeoidea (fossil Spermatophyta: Cycadeoideopsida)". Taxon. 65 (2): 372–379. doi:10.12705/652.16.
  13. ^ a b Carruthers, William (May 1870). "XVIII. On Fossil Cycadean Stems from the Secondary Rocks of Britain". Transactions of the Linnean Society of London. 26 (4): 675–708. doi:10.1111/j.1096-3642.1870.tb00201.x.
  14. ^ Williamson, W. C. (May 1870). "XVII. Contributions towards the History of Zamia Gigas, Lindl. & Hutt.*". Transactions of the Linnean Society of London. 26 (4): 663–674. doi:10.1111/j.1096-3642.1870.tb00200.x.
  15. ^ a b c d e McLoughlin, Stephen; Pott, Christian; Sobbe, Ian H. (2018-03-01). "The diversity of Australian Mesozoic bennettitopsid reproductive organs" (PDF). Palaeobiodiversity and Palaeoenvironments. 98 (1): 71–95. doi:10.1007/s12549-017-0286-z. S2CID 135237376.
  16. ^ Britten, James; Boulger, George Simonds (1893). A biographical index of British and Irish botanists. London: West, Newman & co. p. 14. doi:10.5962/bhl.title.56947.
  17. ^ Engler, H.G.A. 1892. Syllabus der Vorlesungen über specielle und medicinisch-pharmaceutische Botanik. xxiii + 184 pp. Gebr. Borntraeger, Berlin
  18. ^ Arber, E.N.; Parkin, J. (July 1907). "On the Origin of Angiosperms". Botanical Journal of the Linnean Society. 38 (263): 29–80. doi:10.1111/j.1095-8339.1907.tb01074.x.
  19. ^ Crane, P.R. (September 1985). "Phylogenetic relationships in seed plants". Cladistics. 1 (4): 329–348. doi:10.1111/j.1096-0031.1985.tb00432.x. PMID 34965681. S2CID 85709030.
  20. ^ Taylor, David Winship; Li, Hongqi; Dahl, Jeremy; Fago, Fred J.; Zinniker, David; Moldowan, J. Michael (March 2006). "Biogeochemical evidence for the presence of the angiosperm molecular fossil oleanane in Paleozoic and Mesozoic non-angiospermous fossils". Paleobiology. 32 (2): 179–90. doi:10.1666/0094-8373(2006)32[179:BEFTPO]2.0.CO;2. S2CID 83801635.
  21. ^ a b Friis, Else Marie; Crane, Peter R.; Pedersen, Kaj Raunsgaard; Bengtson, Stefan; Donoghue, Philip C. J.; Grimm, Guido W.; Stampanoni, Marco (November 2007). "Phase-contrast X-ray microtomography links Cretaceous seeds with Gnetales and Bennettitales". Nature. 450 (7169): 549–52. Bibcode:2007Natur.450..549F. doi:10.1038/nature06278. PMID 18033296. S2CID 1198220.
  22. ^ Ran, Jin-Hua; Shen, Ting-Ting; Wang, Ming-Ming; Wang, Xiao-Quan (June 2018). "Phylogenomics resolves the deep phylogeny of seed plants and indicates partial convergent or homoplastic evolution between Gnetales and angiosperms". Proceedings. Biological Sciences. 285 (1881): 20181012. doi:10.1098/rspb.2018.1012. PMC 6030518. PMID 29925623.
  23. ^ Vajda, Vivi; Pucetaite, Milda; McLoughlin, Stephen; Engdahl, Anders; Heimdal, Jimmy; Uvdal, Per (August 2017). "Molecular signatures of fossil leaves provide unexpected new evidence for extinct plant relationships". Nature Ecology & Evolution. 1 (8): 1093–1099. doi:10.1038/s41559-017-0224-5. PMID 29046567. S2CID 3604369.
  24. ^ Wu, Qiong; Ramezani, Jahandar; Zhang, Hua; Wang, Jun; Zeng, Fangui; Zhang, Yichun; Liu, Feng; Chen, Jun; Cai, Yaofeng; Hou, Zhangshuai; Liu, Chao (2021-02-05). "High-precision U-Pb age constraints on the Permian floral turnovers, paleoclimate change, and tectonics of the North China block". Geology. 49 (6): 677–681. Bibcode:2021Geo....49..677W. doi:10.1130/G48051.1. S2CID 234064909.
  25. ^ Pott, Christian; McLoughlin, Stephen; Lindström, Anna (2009). "Late Palaeozoic Foliage from China Displays Affinities to Cycadales Rather than to Bennettitales Necessitating a Re-Evaluation of the Palaeozoic Pterophyllum Species". Acta Palaeontologica Polonica. 55 (1): 157–168. doi:10.4202/app.2009.0070. S2CID 52253114.
  26. ^ Blomenkemper, Patrick; Kerp, Hans; Abu Hamad, Abdalla; DiMichele, William A.; Bomfleur, Benjamin (December 2018). "A hidden cradle of plant evolution in Permian tropical lowlands". Science. 362 (6421): 1414–1416. Bibcode:2018Sci...362.1414B. doi:10.1126/science.aau4061. PMID 30573628.
  27. ^ Kustatscher, Evelyn; van Konijnenburg-van Cittert, Johanna H.A. (2005). "The Ladinian Flora (Middle Triassic) of the Dolomites: palaeoenvironmental reconstructions and palaeoclimatic considerations" (PDF). Geo.Alp. 2: 31–51.
  28. ^ Gnilovskaya, Anastasia A.; Golovneva, Lina B. (February 2018). "The Late Cretaceous Pterophyllum (Bennettitales) in the North-East of Russia". Cretaceous Research. 82: 56–63. doi:10.1016/j.cretres.2017.09.013.
  29. ^ McLoughlin, Stephen; Carpenter, Raymond J.; Pott, Christian (April 2011). "Ptilophyllum muelleri (Ettingsh.) comb. nov. from the Oligocene of Australia: last of the Bennettitales?". International Journal of Plant Sciences. 172 (4): 574–85. doi:10.1086/658920. S2CID 52885618.

External links

  • Gymnosperms
  • Lecture Notes on Mesozoic Mesophytic Communities
  • Weblinks to articles about the Bennettitales

April 13, 2023
bennettitales, also, known, cycadeoids, extinct, order, seed, plants, that, first, appeared, permian, period, became, extinct, most, areas, toward, cretaceous, were, amongst, most, common, seed, plants, mesozoic, morphologies, including, shrub, cycad, like, fo. Bennettitales also known as cycadeoids is an extinct order of seed plants that first appeared in the Permian period and became extinct in most areas toward the end of the Cretaceous Bennettitales were amongst the most common seed plants of the Mesozoic and had morphologies including shrub and cycad like forms The foliage of bennettitaleans is superficially nearly indistinguishable from that of cycads but they are distinguished from cycads by their more complex flower like reproductive organs at least some of which were likely pollinated by insects 1 BennettitalesTemporal range Permian Late Cretaceous Kungurian Maastrichtian PreꞒ Ꞓ O S D C P T J K Pg N Possible Oligocene recordRestoration of a member of Williamsoniaceae by Therese EkblomLife restoration of Williamsonia sewardiana from the Early Cretaceous of India which may represent an early member of CycadeoidaceaeScientific classificationKingdom PlantaeClade TracheophytesClade SpermatophytesOrder BennettitalesEngler 1892FamiliesCycadeoidaceae WilliamsoniaceaeAlthough certainly gymnosperms cone bearing seed plants the relationships of bennettitaleans to other seed plants is debated Their general resemblance to cycads is contradicted by numerous more subtle features of their reproductive systems and leaf structure Some authors have linked bennettitaleans to angiosperms flowering plants and gnetophytes a rare and unusual group of modern gymnosperms forming a broader group known as Anthophyta Molecular data contradicts this with gnetophytes found to be much more genetically similar to conifers The exact position of Bennettitales remains uncertain Contents 1 Description 1 1 Foliage 1 2 Cones and seeds 2 Taxonomy 3 Evolutionary history 4 Subgroups 5 Gallery 6 References 7 External linksDescription Edit Bennettitales foliage assigned to the genus Pterophyllum Restoration of the willamsoniacean shrub Wielandiella angustifolia showing divaricate branching habit Bennettitales are divided into two families Cycadeoidaceae and Williamsoniaceae which have distinct growth habits Cycadeoidaceae had stout cycad like trunks with bisporangiate containing both megaspores and microspores strobili cones serving as their reproductive structures Williamsoniaceae either had bisporangiate or monosporangiate cones and distinctly slender and branching woody trunks 1 The Williamsoniaceae grew as woody shrubs with a divaricate branching habit similar to that of Banksia 2 It has been suggested that Williamsoniaceae are a paraphyletic not containing all descendants of a common ancestor assemblage of all Bennettitales that do not belong to the Cycadeoidaceae 2 Foliage Edit In general bennettitalean leaves are attached to the stem with a helical corkscrew arrangement Some leaves most species of Nilssoniopteris etc are narrow solitary blades with a smooth edged entire margin 3 Most leaf morphotypes Pterophyllum Ptilophyllum Zamites Otozamites etc are pinnate feather shaped with many small leaf segments attached to a central shaft Others Anomozamites a few species of Nilssoniopteris are incompletely pinnate sawtooth shaped and transitional between these two end members One unusual leaf form Eoginkgoites even approaches a palmate appearance similar to early species of Ginkgo 4 The foliage of bennettitaleans resembles that of cycads to such an extent that the foliage of the two groups cannot be reliably distinguished based on gross morphology alone However fossil foliage which preserves the cuticle can be assigned to either group with confidence The stomata of bennettitaleans are described as syndetocheilic This means that the main paired guard cells develop from the same mother cells as the subsidiary cells which surround them This contrasts with the haplocheilic stomata of cycads and conifers In haplocheilic stomata the ring of subsidiary cells are not derived from the same original structures as the guard cells This fundamental difference is the main way to differentiate bennettitalean and cycad foliage 5 Cones and seeds Edit Diagram of male Williamsoniaceae reproductive structure Weltrichia Labels CFR Centrifugal ray CPR Centripetal ray MR Median ridge FS Fibrous strand PS Pollen sac position in this case pollen sac attachment CC Central cup RBA Resin resinous body or attractant ST Stalk Cross section of the female williamsoniaceous seed cone Williamsonia harrisiana Like other gymnosperms bennettitalean reproductive inflorescences come in the form of cones which produce pollen and ovules unfertilized seeds The cones have a thick central receptacle surrounded by simple helically arranged fertile and infertile structures Tissue at the base of the cone forms layers of scale like or petal like bracts to protect the radiating inner structures Some authors refer to bennettitalean cones as flowers though they are not equivalent to true angiosperm flowers Pollen is often enclosed in paired synangia pollen sacs The synangia lie on the adaxial inner edge of pollen bearing leaf like structures known as microsporophylls This contrasts with cycads all of which lack discrete synangia and bear pollen on the abaxial outer surface of their microsporophylls 6 Many bennettitaleans are bisporangiate where the pollen and ovules are hosted on the same bisexual or hermaphrodite cone Cavities filled with curved synangia bearing microsporophylls are encased by thin radiating structures including thick infertile interseminal scales and fertile sporophylls with ovules at their tips The presence of ovules at the tips of sporophylls rather than the tips of stems is a major difference between the cones of bennettitaleans and gnetophytes As the cone is fertilized and matures the microsporophylls wither away and the ovules transform into seeds 6 Most bennettitaleans in the family Williamsoniaceae are instead monosporangiate with separate pollen and ovule producing unisexual cones on the same plant The ovule producing female cones Williamsonia etc are similar to mature bisporangiate cones with interseminal scales and ovule tipped sporophylls enclosed by bracts Pollen producing male cones Weltrichia etc on the other hand feature an exposed crown of tapering microsporophylls with adaxial rows of synangia The microsporophylls may host a single linear row of paired synangia or instead synangia arranged in a pinnate feather shaped pattern 6 Seeds are dicotyledonous possess two embryonic leaves with a central embryo surrounded by three layers the thin megagametophyte the slightly thicker nucellus and the protective integument The upper tip of the seed is tapered and opens through a thin and often extended micropyle A long narrow micropyle extending out of the seed is superficially similar to the condition in living gnetophytes Once the seed is fertilized the micropyle is sealed by a plug shaped extension of the nucellus Unlike living gymnosperms the tip of the nucellus lacks a pollen chamber receptacle for stored pollen The integument is dense and thick with many layers of differentiated cells This contrasts with the thin biseriate two cell layer integument of gnetophytes Bennettitaleans also lack another gnetophyte like trait a sheath of fused bracteoles enveloping the seed Most integument cells are not unusual in size or shape However near the micropyle the innermost layer of integument cells become radially oriented and elongated partially closing in on the micropyle The nucellus and integument are unfused above the chalaza base of the seed unlike cycads or gnetophytes where the layers are fused for much of their height 6 Cycadeoidaceans were likely self pollinating with their stems and cones buried underground 1 7 The flower like williamsoniacean male reproductive structure Weltrichia is associated with the female reproductive structure Williamsonia though it is uncertain whether the parent plants were monoecious male and female reproductive structures being present on the same plant or dioecious where each plant has only one gender of reproductive organ Weltrichia was likely primarily wind pollinated with some species possibly pollinated by beetles 8 Several groups of Jurassic and Early Cretaceous insects possessed a long proboscis and it has been suggested that they fed on nectar produced by bennettitalean reproductive structures such as the bisexual williamsoniacean reproductive structure Williamsoniella which had a long narrow central receptacle which was likely otherwise inaccessible 9 Early Cretaceous bennettitalean pollen has been found directly associated with a proboscis bearing fly belonging to the extinct family Zhangsolvidae providing evidence that this family acted as pollinators for the group 10 The interseminal scales of Bennettitales ovulate cones may have become fleshy at maturity which could have potentially made then attractive to wild animals that served as seed dispersers 11 Taxonomy EditThe Cycadeoideaceae originally Cycadeoideae were named by English geologist William Buckland in 1828 from fossil trunks found in Jurassic strata on the Isle of Portland England which Buckland gave the genus name Cycadeoidea Buckland provided a description of the family and two species but failed to give a description of the genus which has led to Buckland s description of the family being considered invalid by modern taxonomic standards 12 In publications in 1870 Scottish botanist William Carruthers and English paleobotanist William Crawford Williamson described the first known reproductive organs of the Bennettitales from Jurassic strata of Yorkshire and Jurassic Cretaceous strata of the Isle of Wight and the Isle of Portland 13 14 15 Caruthers was the first to recognise that Bennettitales had distinct differences from cycads and established the tribes Williamsonieae and Bennettiteae 15 with the latter being named after the genus Bennettites named by Caruthers in the same publication the name being in honour of British botanist John Joseph Bennett 13 16 The order Bennettitales was erected by German botanist Adolf Engler in 1892 who recognised the group as separate from the Cycadales 17 The Anthophyte hypothesis erected by Arber and Parking in 1907 18 posited that angiosperms arose from Bennettitales as suggested by the wood like structures and rudimentary flowers 1 Based on morphological data however Bennettitales were classified as a monophyletic group when paired with Gnetales 19 a study in 2006 suggested that Bennettitales Angiosperms and Gigantopteridales form a clade based on the presence of oleanane 20 A 2007 study examining phase contrast X ray images of gymnosperm seeds supported the Anthophyte hypothesis 21 Evidence from seed coats suggest that Bennettitales form a clade with the gymnosperm orders of Gnetales and Erdtmanithecales 21 Molecular evidence has consistently contradicted the Anthophyte hypothesis finding that Angiosperms are the sister group to all living gymnosperms including Gnetales 22 A 2017 phylogeny based on molecular signatures of fossilised cuticles found that Bennettitales were more closely related to the Ginkgo Cycads clade than conifers and were closely related to Nilssonia and Ptilozamites 23 Evolutionary history EditThe oldest confirmed fossils of bennettitaleans are leaves of Nilssoniopteris shanxiensis a species from the upper part of the Upper Shihhotse Formation in Shanxi Province China 5 This strata is dated to the early Kungurian stage of the early Permian Cisuralian around 281 million years ago 24 Supposed Carboniferous Permian records of Pterophyllum do not have conclusive bennettitalean affinities or have been reinterpreted as cycad foliage in the form genus Pseudoctenis 25 True Permian records of benettitalean leaves are rare outside of the Shihhotse Formation they are only found in the Late Permian likely Changhsingian age Umm Irna Formation in Jordan 5 This formation is notable for the early occurrence of other Mesozoic style flora including the earliest records of corystospermalean foliage Dicroidium podocarpacean conifer branches Elatocladus and Triassic style zamiinean cycads 26 The order Fredlindiales containing the genus Fredlindia from the Late Triassic of Gondwana appears to be closely related to Bennettitales but differs from it in some aspects of its reproductive organs 15 The bennettitalean fossil record reappeared in the Middle Triassic and williamsoniaceans became globally distributed by the end of the period 27 5 The oldest bennettitalean reproductive structures are small Williamsonia flowers from the Middle Triassic Esk Formation of Australia 15 While Williamsoniaceae had a global distribution Cycadeoidaceae appear to have been primarily confined to the western parts of Laurasia and are primarily known from the Cretaceous 15 Bennettitales were widespread and abundant during the Jurassic and Early Cretaceous however Bennettitales severely declined during the Late Cretaceous coincident with the rise of flowering plants being mostly extinct by the end of the period with the final known remains from the Northern Hemisphere being found in the polar latitude Kakanaut Formation in Chukotka Russia dating to the Maastrichtian assignable to Pterophyllum 28 A possible late record has been reported from the early Oligocene of eastern Australia and Tasmania assignable to the genus Ptilophyllum but no cuticle was preserved making the referral inconclusive 29 Subgroups EditCycadolepis scales or bracts unplaced in family Lunzia pollen organ unplaced in family Westersheimia ovulate organ unplaced in family Family Cycadeoidaceae Cycadeoidea Monanthesia Family Williamsoniaceae Anomozamites leaf Bennetticarpus female seed cone Bennettistemon male pollen organ Bucklandia axes Eoginkgoites leaf Ischnophyton Kimuriella whole plant Nilssoniopteris leaf Otozamites leaf Pterophyllum leaf Ptilophyllum leaf Vardekloeftia female seed cone Weltrichia male pollen organ Wielandiella whole plant Williamsonia female seed cones Williamsoniella bisexual reproductive structure Zamites leaf in partim Haitingeria pollen organ Gallery Edit Fossil leaf of Zamites mariposana from the Jurassic Restoration of Weltrichia magna from the Jurassic of Mexico Otozamites leaf Leaf of Anomozamites Seed bearing strobilus of Bennettites Trunk of Cycadeoidea Fossil of Ptilophyllum grandifoliumReferences Edit a b c d Penalver Enrique Arillo Antonio Perez de la Fuente Ricardo Riccio Mark L Delclos Xavier Barron Eduardo Grimaldi David A 2015 Long Proboscid Flies as Pollinators of Cretaceous Gymnosperms Current Biology 25 14 1917 1923 doi 10 1016 j cub 2015 05 062 a b Pott Christian McLoughlin Stephen 2014 06 01 Divaricate growth habit in Williamsoniaceae Bennettitales unravelling the ecology of a key Mesozoic plant group Palaeobiodiversity and Palaeoenvironments 94 2 307 325 doi 10 1007 s12549 014 0157 9 S2CID 84440045 Ray M M Rothwell G W Stockey R A September 2014 Anatomically Preserved Early Cretaceous Bennettitalean Leaves Nilssoniopteris corrugata n sp from Vancouver Island Canada Journal of Paleontology 88 5 1085 93 doi 10 1017 S002233600005767X S2CID 232349931 Pott Christian Axsmith Brian J February 2015 Williamsonia carolinensis sp nov and Associated Eoginkgoites Foliage from the Upper Triassic Pekin Formation North Carolina Implications for Early Evolution in the Williamsoniaceae Bennettitales International Journal of Plant Sciences 176 2 174 185 doi 10 1086 679471 S2CID 44559347 a b c d Blomenkemper Patrick Baumer Robert Backer Malte Abu Hamad Abdalla Wang Jun Kerp Hans Bomfleur Benjamin 2021 Bennettitalean Leaves From the Permian of Equatorial Pangea The Early Radiation of an Iconic Mesozoic Gymnosperm Group Frontiers in Earth Science 9 162 Bibcode 2021FrEaS 9 162B doi 10 3389 feart 2021 652699 a b c d Rothwell Gar W Crepet William L Stockey Ruth A 2009 Is the anthophyte hypothesis alive and well New evidence from the reproductive structures of Bennettitales American Journal of Botany 96 1 296 322 doi 10 3732 ajb 0800209 PMID 21628190 Osborn J M Taylor M L 2010 Pollen and coprolite structure in Cycadeoidea Bennettitales implications for understanding pollination and mating systems in Mesozoic cycadeoids Plants in deep Mesozoic time morphological innovations phylogeny and ecosystems Bloomington IN Indiana University Press pp 34 49 ISBN 978 0 253 00199 3 Popa Mihai Emilian 2019 02 27 Review of the bennettitalean genus Weltrichia Journal of Palaeogeography 8 1 12 Bibcode 2019JPalg 8 12P doi 10 1186 s42501 019 0023 9 S2CID 85458053 Khramov Alexander V Lukashevich Elena D July 2019 A Jurassic dipteran pollinator with an extremely long proboscis Gondwana Research 71 210 215 Bibcode 2019GondR 71 210K doi 10 1016 j gr 2019 02 004 S2CID 134847380 Penalver E Arillo A Perez de la Fuente R Riccio ML Delclos X Barron E Grimaldi DA July 2015 Long Proboscid Flies as Pollinators of Cretaceous Gymnosperms Current Biology 25 14 1917 23 doi 10 1016 j cub 2015 05 062 PMID 26166781 Friis Else Marie Pedersen Kaj Raunsgaard Crane Peter R eds 2011 Angiosperms in context extant and fossil seed plants Early Flowers and Angiosperm Evolution Cambridge Cambridge University Press pp 101 140 ISBN 978 0 521 59283 3 retrieved 2023 03 20 Doweld Alexander B 2016 05 03 The nomenclature of Cycadeoidea fossil Spermatophyta Cycadeoideopsida Taxon 65 2 372 379 doi 10 12705 652 16 a b Carruthers William May 1870 XVIII On Fossil Cycadean Stems from the Secondary Rocks of Britain Transactions of the Linnean Society of London 26 4 675 708 doi 10 1111 j 1096 3642 1870 tb00201 x Williamson W C May 1870 XVII Contributions towards the History of Zamia Gigas Lindl amp Hutt Transactions of the Linnean Society of London 26 4 663 674 doi 10 1111 j 1096 3642 1870 tb00200 x a b c d e McLoughlin Stephen Pott Christian Sobbe Ian H 2018 03 01 The diversity of Australian Mesozoic bennettitopsid reproductive organs PDF Palaeobiodiversity and Palaeoenvironments 98 1 71 95 doi 10 1007 s12549 017 0286 z S2CID 135237376 Britten James Boulger George Simonds 1893 A biographical index of British and Irish botanists London West Newman amp co p 14 doi 10 5962 bhl title 56947 Engler H G A 1892 Syllabus der Vorlesungen uber specielle und medicinisch pharmaceutische Botanik xxiii 184 pp Gebr Borntraeger Berlin Arber E N Parkin J July 1907 On the Origin of Angiosperms Botanical Journal of the Linnean Society 38 263 29 80 doi 10 1111 j 1095 8339 1907 tb01074 x Crane P R September 1985 Phylogenetic relationships in seed plants Cladistics 1 4 329 348 doi 10 1111 j 1096 0031 1985 tb00432 x PMID 34965681 S2CID 85709030 Taylor David Winship Li Hongqi Dahl Jeremy Fago Fred J Zinniker David Moldowan J Michael March 2006 Biogeochemical evidence for the presence of the angiosperm molecular fossil oleanane in Paleozoic and Mesozoic non angiospermous fossils Paleobiology 32 2 179 90 doi 10 1666 0094 8373 2006 32 179 BEFTPO 2 0 CO 2 S2CID 83801635 a b Friis Else Marie Crane Peter R Pedersen Kaj Raunsgaard Bengtson Stefan Donoghue Philip C J Grimm Guido W Stampanoni Marco November 2007 Phase contrast X ray microtomography links Cretaceous seeds with Gnetales and Bennettitales Nature 450 7169 549 52 Bibcode 2007Natur 450 549F doi 10 1038 nature06278 PMID 18033296 S2CID 1198220 Ran Jin Hua Shen Ting Ting Wang Ming Ming Wang Xiao Quan June 2018 Phylogenomics resolves the deep phylogeny of seed plants and indicates partial convergent or homoplastic evolution between Gnetales and angiosperms Proceedings Biological Sciences 285 1881 20181012 doi 10 1098 rspb 2018 1012 PMC 6030518 PMID 29925623 Vajda Vivi Pucetaite Milda McLoughlin Stephen Engdahl Anders Heimdal Jimmy Uvdal Per August 2017 Molecular signatures of fossil leaves provide unexpected new evidence for extinct plant relationships Nature Ecology amp Evolution 1 8 1093 1099 doi 10 1038 s41559 017 0224 5 PMID 29046567 S2CID 3604369 Wu Qiong Ramezani Jahandar Zhang Hua Wang Jun Zeng Fangui Zhang Yichun Liu Feng Chen Jun Cai Yaofeng Hou Zhangshuai Liu Chao 2021 02 05 High precision U Pb age constraints on the Permian floral turnovers paleoclimate change and tectonics of the North China block Geology 49 6 677 681 Bibcode 2021Geo 49 677W doi 10 1130 G48051 1 S2CID 234064909 Pott Christian McLoughlin Stephen Lindstrom Anna 2009 Late Palaeozoic Foliage from China Displays Affinities to Cycadales Rather than to Bennettitales Necessitating a Re Evaluation of the Palaeozoic Pterophyllum Species Acta Palaeontologica Polonica 55 1 157 168 doi 10 4202 app 2009 0070 S2CID 52253114 Blomenkemper Patrick Kerp Hans Abu Hamad Abdalla DiMichele William A Bomfleur Benjamin December 2018 A hidden cradle of plant evolution in Permian tropical lowlands Science 362 6421 1414 1416 Bibcode 2018Sci 362 1414B doi 10 1126 science aau4061 PMID 30573628 Kustatscher Evelyn van Konijnenburg van Cittert Johanna H A 2005 The Ladinian Flora Middle Triassic of the Dolomites palaeoenvironmental reconstructions and palaeoclimatic considerations PDF Geo Alp 2 31 51 Gnilovskaya Anastasia A Golovneva Lina B February 2018 The Late Cretaceous Pterophyllum Bennettitales in the North East of Russia Cretaceous Research 82 56 63 doi 10 1016 j cretres 2017 09 013 McLoughlin Stephen Carpenter Raymond J Pott Christian April 2011 Ptilophyllum muelleri Ettingsh comb nov from the Oligocene of Australia last of the Bennettitales International Journal of Plant Sciences 172 4 574 85 doi 10 1086 658920 S2CID 52885618 External links EditGymnosperms Lecture Notes on Mesozoic Mesophytic Communities Weblinks to articles about the Bennettitales Retrieved from https en wikipedia org w index php title Bennettitales amp oldid 1147118283, wikipedia, wiki, book, books, library,

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