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Equisetidae

February 15, 2024

See also: Equisetopsida sensu lato

Equisetidae is one of the four subclasses of Polypodiopsida (ferns), a group of vascular plants with a fossil record going back to the Devonian. They are commonly known as horsetails.[2] They typically grow in wet areas, with whorls of needle-like branches radiating at regular intervals from a single vertical stem.

Equisetidae
Temporal range: Late Devonian[1] to Recent
Equisetum telmateia
Scientific classification
Kingdom: Plantae
Clade: Tracheophytes
Division: Polypodiophyta
Class: Polypodiopsida
Subclass: Equisetidae
Warm.
Orders
Synonyms

See text.

The Equisetidae were formerly regarded as a separate division of spore plants and called Equisetophyta, Arthrophyta, Calamophyta or Sphenophyta. When treated as a class, the names Equisetopsida s.s. and Sphenopsida have also been used. They are now recognized as rather close relatives of the ferns (Polypodiopsida) of which they form a specialized lineage.[3] However, the division between the horsetails and the other ferns is so ancient that many botanists, especially paleobotanists, still regard this group as fundamentally separate at the higher level.

Description edit

The horsetails comprise photosynthesising, "segmented", hollow stems, sometimes filled with pith. At the junction ("node", see diagram) between each segment is a whorl of leaves. In the only extant genus Equisetum, these are small leaves (microphylls) with a singular vascular trace, fused into a sheath at each stem node. However, the leaves of Equisetum probably arose by the reduction of megaphylls, as evidenced by early fossil forms such as Sphenophyllum, in which the leaves are broad with branching veins.[4]

The vascular bundles trifurcate at the nodes, with the central branch becoming the vein of a microphyll, and the other two moving left and right to merge with the new branches of their neighbours.[5] The vascular system itself resembles that of the vascular plants' eustele, which evolved independently and convergently.[5] Very rapid internode elongation results in the formation of a pith cavity and a ring of carinal canals formed by disruption of the primary xylem. Similar spaces, the vallecular canals are formed in the cortex.[5] Due to the softer nature of the phloem, these are very rarely seen in fossil instances.[citation needed] In the Calamitaceae, secondary xylem (but not secondary phloem) was secreted as the cambium grew outwards, producing a woody stem, and allowing the plants to grow as high as 10m. All extant species of Equisetum are herbaceous, and have lost the ability to produce secondary growth.[5]

The underground parts of the plants consist of jointed rhizomes, from which roots and aerial axes emerge. The plants have intercalary meristems in each segment of the stem and rhizome that grow as the plant gets taller. This contrasts with most seed plants, which grow from an apical meristem - i.e. new growth comes only from growing tips (and widening of stems).

Horsetails bear cones (technically strobili, sing. strobilus) at the tips of some stems. These cones comprise spirally arranged sporangiophores, which bear sporangia at their edges, and in extant horsetails cover the spores externally - like sacs hanging from an umbrella, with its handle embedded in the axis of the cone. In extinct groups, further protection was afforded to the spores by the presence of whorls of bracts - big pointed microphylls protruding from the cone.

The extant horsetails are homosporous, but extinct heterosporous species such as Calamostachys casheana appear in the fossil record.[6] The sporangia open by lateral dehiscence to release the spores. The spores bear characteristic elaters, distinctive spring-like attachments which are hygroscopic: i.e. they change their configuration in the presence of water, helping the spores move and aiding their dispersal.

 
Vegetative stem:
N = node,
I = internode,
B = branch in whorl,
L = fused microphylls
 
Cross-section through a strobilus; sporangiophores, with attached sporangia (spore capsules) full of spores, can be discerned.
 
Strobilus of E. telmateia, terminal on an unbranched stem

Taxonomy edit

Classification edit

The horsetails and their fossil relatives have long been recognized as distinct from other seedless vascular plants, such as the ferns (Polypodiopsida).[7] Before the advent of modern molecular studies, the relationship of this group to other living and fossil plants was considered problematic.[8] Because of their unclear relationships, the rank botanists assigned to the horsetails varied from order to division. When recognized as a separate division, the literature uses many possible names, including Arthrophyta,[8] Calamophyta, Sphenophyta,[1][9] or Equisetophyta. Other authors regarded the same group as a class, either within a division consisting of the vascular plants or, more recently, within an expanded fern group. When ranked as a class, the group has been termed the Equisetopsida[10] or Sphenopsida.[5]

Modern phylogenetic analysis, back to 2001, demonstrated that horsetails belong firmly within the fern clade of vascular plants.[11][12] Smith et al. (2006) carried out the first higher-level pteridophyte classification published in the molecular phylogenetic era, and considered the ferns (monilophytes), to comprise four classes, with the horsetails as class Equisetopsida sensu stricto.[3] (This distinction is necessary because of the alternative usage of Equisetopsida sensu lato as a synonym for all land plants (Embryophyta) with rank of class.[13]) Chase and Reveal (2009) treated the horsetails as subclass Equisetidae of class Equisetopsida sensu lato. The consensus classification produced by the Pteridophyte Phylogeny Group in 2016 also places horsetails in the subclass Equisetidae, but in the class Polypodiopsida (ferns broadly defined).[2]

Phylogeny edit

The following diagram shows a likely phylogenic relationship between subclass Equisetidae and the other fern subclasses according to the Pteridophyte Phylogeny Group.[2]

A 2018 study by Elgorriaga et al. suggests the relationships within the Equisetidae are as shown in the following cladogram.[14]

Sphenophyllales

Equisetales

†Archaeocalamitaceae

A.G. clade (†Paracalamitina, †Cruciaetheca)

Calamitaceae

†Neocalamitaceae

Equisetaceae

According to the study, the age of the crown group of Equisetum dates at least to the Early Cretaceous, and most probably up to the Jurassic.[14]

Subdivision edit

Subclass Equisetidae contains a single extant order, Equisetales. This order consists of a single monotypic family, Equisetaceae, with one genus Equisetum. Equisetum has about 20 species.[12][2]

Fossil record edit

The extant horsetails represent a tiny fraction of horsetail diversity in the past. There were three orders of the Equisetidae. The Pseudoborniales first appeared in the late Devonian.[1] The Sphenophyllales were a dominant member of the Carboniferous understory, and prospered until the mid and early Permian. The Equisetales existed alongside the Sphenophyllales, but diversified as that group disappeared into extinction, gradually dwindling in diversity to today's single genus Equisetum.

The organisms first appear in the fossil record during the late Devonian,[1] a time when land plants were undergoing a rapid diversification, with roots, seeds and leaves having only just evolved. (See Evolutionary history of plants) However, plants had already been on the land for almost a hundred million years, with the first evidence of land plants dating to 475 million years ago.[15]

References edit

  1. ^ a b c d Taylor, T.N. & Taylor., E.L. (1993). The biology and evolution of fossil plants. Englewood Cliffs, NJ: Prentice Hall. pp. 303–305. ISBN 978-0-13-651589-0.
  2. ^ a b c d Pteridophyte Phylogeny Group I (November 2016), "A community-derived classification for extant lycophytes and ferns", Journal of Systematics and Evolution, 54 (6): 563–603, doi:10.1111/jse.12229, S2CID 39980610
  3. ^ a b Smith, A.R.; Pryer, K.M.; Schuettpelz, E.; Korall, P.; Schneider, H. & Wolf, P.G. (2006). (PDF). Taxon. 55 (3): 705–731. doi:10.2307/25065646. JSTOR 25065646. Archived from the original (PDF) on 2008-02-26. Retrieved 2019-10-28.
  4. ^ Rutishauser, R. (1999). "Polymerous leaf whorls in vascular plants: Developmental morphology and fuzziness of organ identities". International Journal of Plant Sciences. 160 (6): 81–103. doi:10.1086/314221. JSTOR 10.1086/314221. PMID 10572024. S2CID 4658142.
  5. ^ a b c d e Stewart, W.N. & Rothwell, G.W. (1993). Paleobotany and the evolution of plants (2nd ed.). Cambridge: Cambridge University Press. ISBN 978-0-521-38294-6.
  6. ^ Bower, F.O. (1959) [1935]. The origin of the land flora, a theory based upon the facts of alternation. New York: Hafner publishing Co. p. 381.
  7. ^ Eames, A.J. (1936). Morphology of vascular plants (Lower Groups). New York and London: McGraw-Hill Book Company. pp. 110–115.
  8. ^ a b Bold, H.C.; Alexopoulos, C.J.; Delevoryas, T. (1987). Morphology of Plants and Fungi (5th ed.). New York: Harper-Collins. pp. 371–387, 478, 506–514. ISBN 978-0-06-040839-8.
  9. ^ Gifford, E.M.; Foster, A.S. (1988). Morphology and evolution of vascular plants (3rd ed.). New York: W. H. Freeman and Company. pp. 175–207. ISBN 978-0-7167-1946-5.
  10. ^ Kenrick, P.; Crane, P.R. (1997). The Origin and early diversification of land plants: A cladistic study. Washington, D. C.: Smithsonian Institution Press. pp. 241–242. ISBN 978-1-56098-730-7.
  11. ^ Pryer, K.M.; Schneider, H.; Smith, A.R.; Cran, R.; Wolf, P.G.; Hunt, J.S.; Sipes, S.D. (2001). (PDF). Nature. 409 (6820): 618–621. Bibcode:2001Natur.409..618S. doi:10.1038/35054555. PMID 11214320. S2CID 4367248. Archived from the original (PDF) on 2009-09-02.
  12. ^ a b Christenhusz, Maarten J.M. & Chase, Mark W. (2014). "Trends and concepts in fern classification". Annals of Botany. 113 (4): 571–594. doi:10.1093/aob/mct299. PMC 3936591. PMID 24532607.
  13. ^ Chase, Mark W. & Reveal, James L. (2009), "A phylogenetic classification of the land plants to accompany APG III", Botanical Journal of the Linnean Society, 161 (2): 122–127, doi:10.1111/j.1095-8339.2009.01002.x
  14. ^ a b Elgorriaga, A.; Escapa, I.H.; Rothwell, G.W.; Tomescu, A.M.F.; Cúneo, N.R. (2018). "Origin of Equisetum: Evolution of horsetails (Equisetales) within the major euphyllophyte clade Sphenopsida". American Journal of Botany. 105 (8): 1286–1303. doi:10.1002/ajb2.1125. PMID 30025163.
  15. ^ Wellman, C.H.; Osterloff, P.L.; Mohiuddin, U. (2003). "Fragments of the earliest land plants" (PDF). Nature. 425 (6955): 282–285. Bibcode:2003Natur.425..282W. doi:10.1038/nature01884. PMID 13679913. S2CID 4383813.

  Data related to Equisetopsida at Wikispecies

 
Wikimedia Commons has media related to Equisetopsida.

February 15, 2024
equisetidae, also, equisetopsida, sensu, lato, four, subclasses, polypodiopsida, ferns, group, vascular, plants, with, fossil, record, going, back, devonian, they, commonly, known, horsetails, they, typically, grow, areas, with, whorls, needle, like, branches,. See also Equisetopsida sensu lato Equisetidae is one of the four subclasses of Polypodiopsida ferns a group of vascular plants with a fossil record going back to the Devonian They are commonly known as horsetails 2 They typically grow in wet areas with whorls of needle like branches radiating at regular intervals from a single vertical stem EquisetidaeTemporal range Late Devonian 1 to Recent PreꞒ Ꞓ O S D C P T J K Pg NEquisetum telmateiaScientific classificationKingdom PlantaeClade TracheophytesDivision PolypodiophytaClass PolypodiopsidaSubclass EquisetidaeWarm OrdersEquisetales Archaeocalamitaceae Calamitaceae Equisetaceae Pseudoborniales SphenophyllalesSynonymsSee text The Equisetidae were formerly regarded as a separate division of spore plants and called Equisetophyta Arthrophyta Calamophyta or Sphenophyta When treated as a class the names Equisetopsida s s and Sphenopsida have also been used They are now recognized as rather close relatives of the ferns Polypodiopsida of which they form a specialized lineage 3 However the division between the horsetails and the other ferns is so ancient that many botanists especially paleobotanists still regard this group as fundamentally separate at the higher level Contents 1 Description 2 Taxonomy 2 1 Classification 2 2 Phylogeny 2 3 Subdivision 2 4 Fossil record 3 ReferencesDescription editThe horsetails comprise photosynthesising segmented hollow stems sometimes filled with pith At the junction node see diagram between each segment is a whorl of leaves In the only extant genus Equisetum these are small leaves microphylls with a singular vascular trace fused into a sheath at each stem node However the leaves of Equisetum probably arose by the reduction of megaphylls as evidenced by early fossil forms such as Sphenophyllum in which the leaves are broad with branching veins 4 The vascular bundles trifurcate at the nodes with the central branch becoming the vein of a microphyll and the other two moving left and right to merge with the new branches of their neighbours 5 The vascular system itself resembles that of the vascular plants eustele which evolved independently and convergently 5 Very rapid internode elongation results in the formation of a pith cavity and a ring of carinal canals formed by disruption of the primary xylem Similar spaces the vallecular canals are formed in the cortex 5 Due to the softer nature of the phloem these are very rarely seen in fossil instances citation needed In the Calamitaceae secondary xylem but not secondary phloem was secreted as the cambium grew outwards producing a woody stem and allowing the plants to grow as high as 10m All extant species of Equisetum are herbaceous and have lost the ability to produce secondary growth 5 The underground parts of the plants consist of jointed rhizomes from which roots and aerial axes emerge The plants have intercalary meristems in each segment of the stem and rhizome that grow as the plant gets taller This contrasts with most seed plants which grow from an apical meristem i e new growth comes only from growing tips and widening of stems Horsetails bear cones technically strobili sing strobilus at the tips of some stems These cones comprise spirally arranged sporangiophores which bear sporangia at their edges and in extant horsetails cover the spores externally like sacs hanging from an umbrella with its handle embedded in the axis of the cone In extinct groups further protection was afforded to the spores by the presence of whorls of bracts big pointed microphylls protruding from the cone The extant horsetails are homosporous but extinct heterosporous species such as Calamostachys casheana appear in the fossil record 6 The sporangia open by lateral dehiscence to release the spores The spores bear characteristic elaters distinctive spring like attachments which are hygroscopic i e they change their configuration in the presence of water helping the spores move and aiding their dispersal nbsp Vegetative stem N node I internode B branch in whorl L fused microphylls nbsp Cross section through a strobilus sporangiophores with attached sporangia spore capsules full of spores can be discerned nbsp Strobilus of E telmateia terminal on an unbranched stemTaxonomy editClassification edit The horsetails and their fossil relatives have long been recognized as distinct from other seedless vascular plants such as the ferns Polypodiopsida 7 Before the advent of modern molecular studies the relationship of this group to other living and fossil plants was considered problematic 8 Because of their unclear relationships the rank botanists assigned to the horsetails varied from order to division When recognized as a separate division the literature uses many possible names including Arthrophyta 8 Calamophyta Sphenophyta 1 9 or Equisetophyta Other authors regarded the same group as a class either within a division consisting of the vascular plants or more recently within an expanded fern group When ranked as a class the group has been termed the Equisetopsida 10 or Sphenopsida 5 Modern phylogenetic analysis back to 2001 demonstrated that horsetails belong firmly within the fern clade of vascular plants 11 12 Smith et al 2006 carried out the first higher level pteridophyte classification published in the molecular phylogenetic era and considered the ferns monilophytes to comprise four classes with the horsetails as class Equisetopsida sensu stricto 3 This distinction is necessary because of the alternative usage of Equisetopsida sensu lato as a synonym for all land plants Embryophyta with rank of class 13 Chase and Reveal 2009 treated the horsetails as subclass Equisetidae of class Equisetopsida sensu lato The consensus classification produced by the Pteridophyte Phylogeny Group in 2016 also places horsetails in the subclass Equisetidae but in the class Polypodiopsida ferns broadly defined 2 Phylogeny edit The following diagram shows a likely phylogenic relationship between subclass Equisetidae and the other fern subclasses according to the Pteridophyte Phylogeny Group 2 Polypodiopsida Equisetidae horsetails OphioglossidaeMarattiidaePolypodiidaeA 2018 study by Elgorriaga et al suggests the relationships within the Equisetidae are as shown in the following cladogram 14 SphenophyllalesEquisetales ArchaeocalamitaceaeA G clade Paracalamitina Cruciaetheca Calamitaceae NeocalamitaceaeEquisetaceaeAccording to the study the age of the crown group of Equisetum dates at least to the Early Cretaceous and most probably up to the Jurassic 14 Subdivision edit Subclass Equisetidae contains a single extant order Equisetales This order consists of a single monotypic family Equisetaceae with one genus Equisetum Equisetum has about 20 species 12 2 Fossil record edit The extant horsetails represent a tiny fraction of horsetail diversity in the past There were three orders of the Equisetidae The Pseudoborniales first appeared in the late Devonian 1 The Sphenophyllales were a dominant member of the Carboniferous understory and prospered until the mid and early Permian The Equisetales existed alongside the Sphenophyllales but diversified as that group disappeared into extinction gradually dwindling in diversity to today s single genus Equisetum The organisms first appear in the fossil record during the late Devonian 1 a time when land plants were undergoing a rapid diversification with roots seeds and leaves having only just evolved See Evolutionary history of plants However plants had already been on the land for almost a hundred million years with the first evidence of land plants dating to 475 million years ago 15 References edit a b c d Taylor T N amp Taylor E L 1993 The biology and evolution of fossil plants Englewood Cliffs NJ Prentice Hall pp 303 305 ISBN 978 0 13 651589 0 a b c d Pteridophyte Phylogeny Group I November 2016 A community derived classification for extant lycophytes and ferns Journal of Systematics and Evolution 54 6 563 603 doi 10 1111 jse 12229 S2CID 39980610 a b Smith A R Pryer K M Schuettpelz E Korall P Schneider H amp Wolf P G 2006 A classification for extant ferns PDF Taxon 55 3 705 731 doi 10 2307 25065646 JSTOR 25065646 Archived from the original PDF on 2008 02 26 Retrieved 2019 10 28 Rutishauser R 1999 Polymerous leaf whorls in vascular plants Developmental morphology and fuzziness of organ identities International Journal of Plant Sciences 160 6 81 103 doi 10 1086 314221 JSTOR 10 1086 314221 PMID 10572024 S2CID 4658142 a b c d e Stewart W N amp Rothwell G W 1993 Paleobotany and the evolution of plants 2nd ed Cambridge Cambridge University Press ISBN 978 0 521 38294 6 Bower F O 1959 1935 The origin of the land flora a theory based upon the facts of alternation New York Hafner publishing Co p 381 Eames A J 1936 Morphology of vascular plants Lower Groups New York and London McGraw Hill Book Company pp 110 115 a b Bold H C Alexopoulos C J Delevoryas T 1987 Morphology of Plants and Fungi 5th ed New York Harper Collins pp 371 387 478 506 514 ISBN 978 0 06 040839 8 Gifford E M Foster A S 1988 Morphology and evolution of vascular plants 3rd ed New York W H Freeman and Company pp 175 207 ISBN 978 0 7167 1946 5 Kenrick P Crane P R 1997 The Origin and early diversification of land plants A cladistic study Washington D C Smithsonian Institution Press pp 241 242 ISBN 978 1 56098 730 7 Pryer K M Schneider H Smith A R Cran R Wolf P G Hunt J S Sipes S D 2001 Horsetails and ferns are a monophyletic group and the closest living relatives to seed plants PDF Nature 409 6820 618 621 Bibcode 2001Natur 409 618S doi 10 1038 35054555 PMID 11214320 S2CID 4367248 Archived from the original PDF on 2009 09 02 a b Christenhusz Maarten J M amp Chase Mark W 2014 Trends and concepts in fern classification Annals of Botany 113 4 571 594 doi 10 1093 aob mct299 PMC 3936591 PMID 24532607 Chase Mark W amp Reveal James L 2009 A phylogenetic classification of the land plants to accompany APG III Botanical Journal of the Linnean Society 161 2 122 127 doi 10 1111 j 1095 8339 2009 01002 x a b Elgorriaga A Escapa I H Rothwell G W Tomescu A M F Cuneo N R 2018 Origin of Equisetum Evolution of horsetails Equisetales within the major euphyllophyte clade Sphenopsida American Journal of Botany 105 8 1286 1303 doi 10 1002 ajb2 1125 PMID 30025163 Wellman C H Osterloff P L Mohiuddin U 2003 Fragments of the earliest land plants PDF Nature 425 6955 282 285 Bibcode 2003Natur 425 282W doi 10 1038 nature01884 PMID 13679913 S2CID 4383813 nbsp Data related to Equisetopsida at Wikispecies nbsp Wikimedia Commons has media related to Equisetopsida Retrieved from https en wikipedia org w index php title Equisetidae amp oldid 1170116173, wikipedia, wiki, book, books, library,

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