Horneophyton

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Horneophyton
Temporal range: Early Devonian
Schematic reconstruction of Horneophyton lignieri to show its growth habit
Scientific classification
Kingdom: Plantae
Subkingdom: Embryophyta
Clade: Polysporangiophyta
Class: Horneophytopsida
Kenrick & Crane (1997)[1]
Genus: Horneophyton
Bargh. & Darrah (1938)[2]
Species

H. lignieri

Synonyms

Hornea

Horneophyton, a member of the Horneophytopsida, is an extinct early plant which may form a "missing link" between the hornworts and the Rhyniopsida. It is among the most abundant organisms found in the Rhynie chert, a Devonian Lagerstätte in Scotland.

Description

The sporophyte had bare stems (axes) up to 20 cm high and about 2 mm in diameter with an undivided cortex; stomata were present but rare. There was a thin central strand of conducting tissue, but this was not reinforced with spiral and reticulate thickenings (and thus does not constitute true vascular tissue).[1] Early stages of development of the sporophytes of Horneophyton (as of hornworts) may have been dependent on their parent gametophytes for nutrition, but mature specimens have expanded, corm-like bases to their stems, up to 6 mm in diameter, that bore rhizoids and appear to be anchored in soil, suggesting a capacity for independent existence after the gametophyte had degenerated.

The sporangium (spore-forming organ) is unique among both living and fossil plants, consisting as it does of branched lobes at the apex of some of the branches of the stem. Each lobe contains a central collumella, analogous to the sporangia of hornworts; however, the sporangia of hornworts do not dichotomise.[3][4] The number of lobes possessed by a sporangium varied; at least three orders of dichotomous branching have been found, resulting in more than four lobes. The sporangia were much less regular than shown in most reconstructions (including that opposite), and they had 'bumps' or emergences on them. Spores were released through a slit at the top of each lobe.[5] The sporangia of Horneophyton contained trilete meiospores, the surfaces of which were decorated with short conical protuberances.[3][6]

The female gametophyte of the plant has been recognised and described as the form taxon Langiophyton mackiei.[7] It grew to a height of around 6 cm, and was free living. It may have been dioicous, i.e. produced male and female gametes on separate plants.[8]

Horneophyton grew on sandy, organic-rich soil in damp to wet locations. They usually grew as isolated individuals.[9]

Surface view of a polished piece of Rhynie chert showing many corms/tubers of Horneophyton. Marked examples: centre – single corm with rhizoids; left – linked corms with rhizoids. Scale bar is 1 cm.

Taxonomy

First named by Kidston & Lang in 1920 from Early Devonian fossils forming the "Rhynie flora",[10] the original generic name Hornea transpired to be a synonym, leading to Barghoorn and Darrah renaming the genus to Horneophyton in 1938.[2] It was classified as a rhyniophyte (subdivision Rhyniophytina) by Banks; the absence of true vascular tissue led Kenrick and Crane in 1997 to create a new class, Horneophytopsida, for this and apparently similar genera.[11]

Phylogeny

A possible phylogeny for Horneophyton is shown below (based on Crane et al. for the polysporangiophytes[12] and Qiu et al. for the bryophytes[13]).


liverworts




mosses




hornworts


polysporangiophytes

 Horneophytopsida (Caia, Horneophyton, Tortilicaulis)




 Aglaophyton



tracheophytes






With vascular tissue but "bryophyte"-like alternation of phases and sporangia, the organism has been considered a missing link between the hornworts and the vascular plants or tracheophytes (which molecular data suggest are sister groups).[13] Features suggesting a relationship with the hornworts include the general form of its sporangia; its corm also resembles the foot of some hornworts. The free living nature of its sporophytes, and the fact that they display branching, are marked differences which force it into the stem group of tracheophytes (along with Aglaophyton).

References

  1. 1.0 1.1 Kenrick, Paul & Crane, Peter R. (1997), The Origin and Early Diversification of Land Plants: A Cladistic Study, Washington, D.C.: Smithsonian Institution Press, ISBN 978-1-56098-730-7 
  2. 2.0 2.1 Barghoorn, E.S. & Darrah, W.C. (1938), "Horneophyton a necessary change of name for Hornea", Harvard University Botanical Museum Leaflets 6: 142–4 
  3. 3.0 3.1 Eggert, D.A. (1974), "The sporangium of Horneophyton lignieri (Rhyniophytina)", American Journal of Botany 61 (4): 405–13, doi:10.2307/2441808 
  4. Taylor, T.N.; Taylor, E.L. & Krings, M. (2009), Paleobotany, The Biology and Evolution of Fossil Plants (2nd ed.), Amsterdam; Boston: Academic Press, ISBN 978-0-12-373972-8 , pp. 237–8
  5. El-Saadawy, W.E.-S. & Lacey, W.S. (1979), "The sporangia of Horneophyton lignieri (Kidston and Lang) Barghoorn and Darrah", Review of Palaeobotany and Palynology 28 (2): 137–144, doi:10.1016/0034-6667(79)90005-8 
  6. Wellman, C.H.; Kerp, H. & Hass, H. (2004), "Spores of the Rhynie chert plant Horneophyton lignieri (Kidston & Lang) Barghoorn & Darrah, 1938", Transactions of the Royal Society of Edinburgh: Earth Sciences 94: 429–43 
  7. Remy, W. & Hass, H. (1991), "Langiophyton mackiei nov. gen., nov. spec., ein Gametophyt mit Archegoniophoren aus dem Chert von Rhynie (Unterdevon Schottland)", Argumenta Palaeobotanica (in German) 8: 69–117 
  8. Taylor, Taylor & Krings 2009, p. 234
  9. Selden, P.A. & Nudds, J.R. (2006), Fenster zur Evolution : Berühmte Fossilfundstellen der Welt, München: Elsevier Spektrum Akademischer Verlag, ISBN 978-3-8274-1771-8 
  10. Kidston, R. & Lang, W.H. (1920), "On Old Red Sandstone plants showing structure, from the Rhynie chert bed, Aberdeenshire. Part II. Additional notes on Rhynia gwynne-vaughani Kidston and Lang; with descriptions of Rhynia major, n.sp., and Hornia lignieri, n.g., n.sp", Transactions of the Royal Society of Edinburgh 52 (24): 603–27 
  11. Edwards, Dianne (2003), "Embryophytic sporophytes in the Rhynie and Windyfield cherts", Transactions of the Royal Society of Edinburgh: Earth Sciences 94 (04): 397–410, doi:10.1017/S0263593300000778 , p. 399
  12. Crane, P.R.; Herendeen, P. & Friis, E.M. (2004), "Fossils and plant phylogeny", American Journal of Botany 91 (10): 1683–99, doi:10.3732/ajb.91.10.1683, PMID 21652317, retrieved 2011-01-27 
  13. 13.0 13.1 Qiu, Y.L.; Li, L.; Wang, B.; Chen, Z.; Knoop, V.; Groth-Malonek, M.; Dombrovska, O.; Lee, J.; Kent, L.; Rest, J.; Estabrook, G.F.; Hendry, T.A.; Taylor, D.W.; Testa, C.M.; Ambros, M.; Crandall-Stotler, B.; Duff, R.J.; Stechi, M.; Frey, W.; Quandt, D. & Davis, C.C. (2006), "The deepest divergences in land plants inferred from phylogenomic evidence", Proceedings of the National Academy of Sciences 103 (42): 15511–6, doi:10.1073/pnas.0603335103, PMC 1622854, PMID 17030812 

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