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Hornwort

February 15, 2024

The name hornwort also refers to aquatic plants of the genus Ceratophyllum, in the family Ceratophyllaceae

Hornworts are a group of non-vascular Embryophytes (land plants) constituting the division Anthocerotophyta (/ˌænθˌsɛrəˈtɒfətə, -təˈftə/). The common name refers to the elongated horn-like structure, which is the sporophyte. As in mosses and liverworts, hornworts have a gametophyte-dominant life cycle, in which cells of the plant carry only a single set of genetic information; the flattened, green plant body of a hornwort is the gametophyte stage of the plant.

Hornwort
Temporal range: 90–0 Ma Upper Cretaceous (but see text) to present
Phaeoceros laevis (L.) Prosk.
Scientific classification
Kingdom: Plantae
Clade: Embryophytes
Division: Anthocerotophyta
Stotler & Stotl.-Crand., 1977[1]
Classes and orders
Leiosporocerotopsida
Anthocerotopsida

see Classification.

Synonyms

Anthocerotae

Hornworts may be found worldwide, though they tend to grow only in places that are damp or humid. Some species grow in large numbers as tiny weeds in the soil of gardens and cultivated fields. Large tropical and sub-tropical species of Dendroceros may be found growing on the bark of trees.

The total number of species is still uncertain. While there are more than 300 published species names, the actual number could be as low as 100-150 species.[2]

Description edit

Like all bryophytes, the dominant life phase of a hornwort is the haploid gametophyte. This stage usually grows as a thin rosette or ribbon-like thallus between one and five centimeters in diameter. Hornworts have lost two plastid division-associated genes, ARC3 and FtsZ2, and have just a single chloroplast per cell (monoplastidy), with the exception of the genus Megaceros and some species in the genera Nothoceros and Anthoceros, which have more than one chloroplast per cell (polyplastidy). In the polyplastidic species, and also some of the monoplastidic species, a cellular structure called a pyrenoid is absent.[3][4] The pyrenoid, which is both a food storing organ and enables a more efficient photosynthesis, has evolved independently five to six times in hornworts and is present in half of the roughly 200 species.[5] It is formed by the fusion of the chloroplast with other organelles and is comprised predominantly of RuBisCO, the key enzyme in carbon fixation. By using inorganic carbon transporters and carbonic anhydrases, up to a 50-fold increase in CO2 levels can be achieved.[6] This particular feature is very unusual in land plants, unique to hornworts, but is common among algae.[7][8]

Many hornworts develop internal mucilage-filled cavities or canals when groups of cells break down. These cavities secrete hormogonium-inducing factors (HIF) that stimulate nearby, free-living photosynthetic cyanobacteria, especially species of Nostoc, to invade and colonize these cavities.[9] Such colonies of bacteria growing inside the thallus give the hornwort a distinctive blue-green color. Symbiotic cyanobacteria have not been reported in Megaceros or Folioceros.[10] There may also be small slime pores on the underside of the thallus. These pores superficially resemble the stomata of other plants.

The horn-shaped sporophyte grows from an archegonium embedded deep in the gametophyte. The growth of the hornwort sporophyte happens from a persistent basal meristem, in contrast to the sporophyte of moss (apical growth) and liverworts (intercalary growth).[11] Unlike liverworts, hornworts have true stomata on their sporophyte as most mosses do. The exceptions are the species Folioceros incurvus, the genus Notothylas and the three closely related genera Megaceros, Nothoceros and Dendroceros, which do not have stomata.[12][13] Notothylas also differ from other hornworts in having a reduced sporophyte only a few millimeters tall. The sporophyte in hornworts is unique among bryophytes in being long-lived with a persistent photosynthetic capacity.[14] The sporophyte lacks an apical meristem, an auxin-sensitive point of divergence with other land plants some time in the Late Silurian/Early Devonian.[15][16]

When the sporophyte is mature, it has a multicellular outer layer, a central rod-like columella running up the center, and a layer of tissue in between that produces spores and pseudo-elaters. The pseudo-elaters are multi-cellular, unlike the elaters of liverworts. They have helical thickenings that change shape in response to drying out; they twist and thereby help to disperse the spores. Hornwort spores are relatively large for bryophytes, measuring between 30 and 80 µm in diameter or more. The spores are polar, usually with a distinctive Y-shaped tri-radiate ridge on the proximal surface, and with a distal surface ornamented with bumps or spines.

Life cycle edit

The life of a hornwort starts from a haploid spore. The spores can be yellow, brown or green. Yellow and brown spores have a thicker wall and contain oils that both protect against desiccation and function as a nutrient storage, allowing them to survive for years. The species Folioceros fuciformis and the genera Megaceros, Nothoceros and Dendroceros have short-lived spores with thin and colorless walls that appear green due to the presence of a chloroplast.[17][18] In most species, there is a single cell inside the spore, and a slender extension of this cell called the germ tube germinates from the proximal side of the spore.[19] The tip of the germ tube divides to form an octant (solid geometry) of cells, and the first rhizoid grows as an extension of the original germ cell.[clarification needed] The tip continues to divide new cells, which produces a thalloid protonema. By contrast, species of the family Dendrocerotaceae may begin dividing within the spore, becoming multicellular and even photosynthetic before the spore germinates.[19] In either case, the protonema is a transitory stage in the life of a hornwort.

 
Life cycle of a typical hornwort Phaeoceros. Click on the image to enlarge.

From the protonema grows the adult gametophyte, which is the persistent and independent stage in the life cycle. This stage usually grows as a thin rosette or ribbon-like thallus between one and five centimeters in diameter, and several layers of cells in thickness. It is green or yellow-green from the chlorophyll in its cells, or bluish-green when colonies of cyanobacteria grow inside the plant.

When the gametophyte has grown to its adult size, it produces the sex organs of the hornwort. Most plants are monoecious, with both sex organs on the same plant, but some plants (even within the same species) are dioecious, with separate male and female gametophytes. The female organs are known as archegonia (singular archegonium) and the male organs are known as antheridia (singular antheridium). Both kinds of organs develop just below the surface of the plant and are only later exposed by disintegration of the overlying cells.

The biflagellate sperm must swim from the antheridia, or else be splashed to the archegonia. When this happens, the sperm and egg cell fuse to form a zygote, the cell from which the sporophyte stage of the life cycle will develop. Unlike all other bryophytes, the first cell division of the zygote is longitudinal. Further divisions produce three basic regions of the sporophyte.

At the bottom of the sporophyte (closest to the interior of the gametophyte), is a foot. This is a globular group of cells that receives nutrients from the parent gametophyte, on which the sporophyte will spend its entire existence. In the middle of the sporophyte (just above the foot), is a meristem that will continue to divide and produce new cells for the third region. This third region is the capsule. Both the central and surface cells of the capsule are sterile, but between them is a layer of cells that will divide to produce pseudo-elaters and spores. These are released from the capsule when it splits lengthwise from the tip.

Evolutionary history edit

While the fossil record of crown group hornworts only begins in the upper Cretaceous, the lower Devonian Horneophyton may represent a stem group to the clade, as it possesses a sporangium with central columella not attached at the roof.[20] However, the same form of columella is also characteristic of basal moss groups, such as the Sphagnopsida and Andreaeopsida, and has been interpreted as a character common to all early land plants with stomata.[21] The divergence between hornworts and Setaphyta (mosses and liverworts) is estimated to have occurred 479–450 million years ago,[22] and the last common ancestor of present-day hornworts lived in middle Permian about 275 million years ago.[23] Chromosome-scale genome sequencing of three hornwort species corroborates that stomata evolved only once during land plant evolution. It also shows that the three groups of bryophytes share a common ancestor that branched off from the other landplants early in evolution, and that liverworts and mosses are more closely related to each other than to hornworts.[24] Unlike other land plants, the hornwort genome has the low-CO2 inducible B gene (LCIB), which is also found in some species of algae. Because the diffusion rate of carbon dioxide is 10,000-fold higher in air than in water, aquatic algae require a mechanism to concentrate CO2 in chloroplasts so as to allow the photosynthetic RuBisCo protein to function efficiently. LCIB is one component of this CO2-concentrating mechanism.[25]

Classification edit

 
The hornwort Dendroceros crispus growing on the bark of a tree.

Hornworts were traditionally considered a class within the division Bryophyta (bryophytes). Later on, the bryophytes were considered paraphyletic, and hence the hornworts were given their own division, Anthocerotophyta (sometimes misspelled Anthocerophyta). However, the most recent phylogenetic evidence leans strongly towards bryophyte monophyly,[26][27][28][29][30][31][24][32][33][excessive citations] and it has been proposed that hornworts are de-ranked to the original class Anthocerotopsida.[28]

Traditionally, there was a single class of hornworts, called Anthocerotopsida, or older Anthocerotae. More recently, a second class Leiosporocertotopsida has been segregated for the singularly unusual species Leiosporoceros dussii. All other hornworts remain in the class Anthocerotopsida. These two classes are divided further into five orders, each containing a single family.

Among land plants, hornworts are one of the earliest-diverging lineages of the early land plant ancestors;[24] cladistic analysis implies that the group originated prior to the Devonian, around the same time as the mosses and liverworts. There are about 200 species known, but new species are still being discovered. The number and names of genera are a current matter of investigation, and several competing classification schemes have been published since 1988.

Structural features that have been used in the classification of hornworts include: the anatomy of chloroplasts and their numbers within cells, the presence of a pyrenoid, the numbers of antheridia within androecia, and the arrangement of jacket cells of the antheridia.[34]

Phylogeny edit

Recent studies of molecular, ultrastructural, and morphological data have yielded a new classification of hornworts.[35][36]

Class Leiosporocerotopsida

Leiosporocerotales

Class Anthocerotopsida

Anthocerotales
Notothyladales
Phymatocerotales
Dendrocerotales
Leiosporocerotopsida
Leiosporocerotales
Leiosporocerotaceae

Leiosporoceros

Anthocerotopsida
The current phylogeny and composition of the Anthocerotophyta.[35][37][38][39]

See also edit

References edit

  1. ^ Stotler, Raymond E.; Barbara J. Candall-Stotler (1977). "A checklist of the liverworts and hornworts of North America". The Bryologist. American Bryological and Lichenological Society. 80 (3): 405–428. doi:10.2307/3242017. JSTOR 3242017.
  2. ^ Lepp, Heino (12 September 2012). "What is a hornwort?". Australian Bryophytes. Australian National Botanic Gardens.
  3. ^ Loss of plastid developmental genes coincides with a reversion to monoplastidy in hornworts - bioRxiv
  4. ^ Hornworts: An Overlooked Window into Carbon-Concentrating Mechanisms - Villarreal Lab
  5. ^ Hornwort pyrenoids, carbon-concentrating structures, evolved and were lost at least five times during the last 100 million years
  6. ^ Meyer, Moritz T.; McCormick, Alistair J.; Griffiths, Howard (2016). "Will an algal CO2-concentrating mechanism work in higher plants?". Current Opinion in Plant Biology. 31: 181–188. doi:10.1016/j.pbi.2016.04.009. PMID 27194106.
  7. ^ Hornwort pyrenoids, carbon-concentrating structures, evolved and were lost at least five times during the last 100 million years - PNAS
  8. ^ BTI researchers unlocking hornworts' secrets | EurekAlert! Science News
  9. ^ Meeks, JC (1998). "Symbiosis between nitrogen-fixing cyanobacteria and plants". BioScience. 48 (4): 266–276. doi:10.2307/1313353. JSTOR 1313353.
  10. ^ Stress Biology of Cyanobacteria: Molecular Mechanisms to Cellular Responses
  11. ^ How was apical growth regulated in the ancestral land plant? Insights from the development of non-seed plants
  12. ^ Hornwort Stomata: Architecture and Fate Shared with 400-Million-Year-Old Fossil Plants without Leaves
  13. ^ Classification of the Phylum Anthocerotophyta Stotl. & Crand.-Stotl.
  14. ^ The deepest divergences in land plants inferred from phylogenomic evidence - PNAS
  15. ^ Cooke, Todd J; Poli, DorothyBelle; Cohen, Jerry D (2003). "Did auxin play a crucial role in the evolution of novel body plans during the Late Silurian-Early Devonian radiation of land plants?". The Evolution of Plant Physiology. Elsevier. pp. 85–107. doi:10.1016/b978-012339552-8/50006-8. ISBN 978-0-12-339552-8.
  16. ^ Friedman, William E.; Moore, Richard C.; Purugganan, Michael D. (2004). "The evolution of plant development". American Journal of Botany. Botanical Society of America (Wiley). 91 (10): 1726–1741. doi:10.3732/ajb.91.10.1726. ISSN 0002-9122. PMID 21652320.
  17. ^ Bryophyte Biology
  18. ^ NEW CLASSIFICATION OF ANTHOCEROTAE - J-Stage
  19. ^ a b Chopra, R. N.; Kumra, P. K. (1988). Biology of Bryophytes. New York: John Wiley & Sons. ISBN 0-470-21359-0.
  20. ^ Qiu, Y.L.; Li, L.; Wang, B.; Chen, Z.; Knoop, V.; Groth-malonek, M.; Dombrovska, O.; Lee, J.; Kent, L.; Rest, J.; et al. (2006). "The deepest divergences in land plants inferred from phylogenomic evidence". Proceedings of the National Academy of Sciences. 103 (42): 15511–6. Bibcode:2006PNAS..10315511Q. doi:10.1073/pnas.0603335103. PMC 1622854. PMID 17030812.
  21. ^ Kenrick, Paul; Peter R. Crane (1997). The Origin and Early Diversification of Land Plants: A Cladistic Study. Washington, D. C.: Smithsonian Institution Press. pp. 55–56. ISBN 1-56098-730-8.
  22. ^ Harris, Brogan J.; Clark, James W.; Schrempf, Dominik; Szöllősi, Gergely J.; Donoghue, Philip C. J.; Hetherington, Alistair M.; Williams, Tom A. (2022). "Divergent evolutionary trajectories of bryophytes and tracheophytes from a complex common ancestor of land plants". Nature Ecology & Evolution. 6 (11): 1634–1643. doi:10.1038/s41559-022-01885-x. PMC 9630106. PMID 36175544.
  23. ^ Zhang, Jian; Fu, Xin-Xing; Li, Rui-Qi; Zhao, Xiang; Liu, Yang; Li, Ming-He; Zwaenepoel, Arthur; Ma, Hong; Goffinet, Bernard; Guan, Yan-Long; Xue, Jia-Yu; Liao, Yi-Ying; Wang, Qing-Feng; Wang, Qing-Hua; Wang, Jie-Yu; Zhang, Guo-Qiang; Wang, Zhi-Wen; Jia, Yu; Wang, Mei-Zhi; Dong, Shan-Shan; Yang, Jian-Fen; Jiao, Yuan-Nian; Guo, Ya-Long; Kong, Hong-Zhi; Lu, An-Ming; Yang, Huan-Ming; Zhang, Shou-Zhou; Van De Peer, Yves; Liu, Zhong-Jian; Chen, Zhi-Duan (2020). "The hornwort genome and early land plant evolution". Nature Plants. 6 (2): 107–118. doi:10.1038/s41477-019-0588-4. PMC 7027989. PMID 32042158.
  24. ^ a b c Li, F-W.; Nishiyama, T.; Waller, M.; et, al. (2020). "Anthoceros genomes illuminate the origin of land plants and the unique biology of hornworts". Nature Plants. 6 (3): 259–272. doi:10.1038/s41477-020-0618-2. PMC 8075897. PMID 32170292.
  25. ^ Frangedakis, Eftychios; Shimamura, Masaki; Villarreal, Juan Carlos; Li, Fay‐Wei; Tomaselli, Marta; Waller, Manuel; Sakakibara, Keiko; Renzaglia, Karen S.; Szövényi, Péter (January 2021). "The hornworts: morphology, evolution and development". New Phytologist. 229 (2): 735–754. doi:10.1111/nph.16874. PMC 7881058. PMID 32790880.
  26. ^ Cox, Cymon J.; et al. (2014). "Conflicting Phylogenies for Early Land Plants are Caused by Composition Biases among Synonymous Substitutions". Systematic Biology. 63 (2): 272–279. doi:10.1093/sysbio/syt109. PMC 3926305. PMID 24399481.
  27. ^ Puttick, Mark N.; et al. (2018). "The Interrelationships of Land Plants and the Nature of the Ancestral Embryophyte". Current Biology. 28 (5): 733–745.e2. doi:10.1016/j.cub.2018.01.063. hdl:1983/ad32d4da-6cb3-4ed6-add2-2415f81b46da. PMID 29456145. S2CID 3269165.
  28. ^ a b de Sousa, Filipe; et al. (2019). "Nuclear protein phylogenies support the monophyly of the three bryophyte groups (Bryophyta Schimp.)". New Phytologist. 222 (1): 565–575. doi:10.1111/nph.15587. hdl:1983/0b471d7e-ce54-4681-b791-1da305d9e53b. PMID 30411803. S2CID 53240320.
  29. ^ Leebens-Mack, James H.; et al. (2019). "One thousand plant transcriptomes and the phylogenomics of green plants". Nature. 574 (7780): 679–685. doi:10.1038/s41586-019-1693-2. PMC 6872490. PMID 31645766.
  30. ^ Zhang, Jian; et al. (2020). "The hornwort genome and early land plant evolution". Nature Plants. 6 (2): 107–118. doi:10.1038/s41477-019-0588-4. PMC 7027989. PMID 32042158.
  31. ^ Harris, Brogan J.; et al. (2020). "Phylogenomic Evidence for the Monophyly of Bryophytes and the Reductive Evolution of Stomata". Current Biology. 30 (11): P2201–2012.E2. doi:10.1016/j.cub.2020.03.048. hdl:1983/fbf3f371-8085-4e76-9342-e3b326e69edd. PMID 32302587. S2CID 215798377.
  32. ^ Sousa, Filipe; et al. (2020). "The Chloroplast Land Plant Phylogeny: Analyses Employing Better-Fitting Tree- and Site-Heterogeneous Composition Models". Frontiers in Plant Science. 11: 1062. doi:10.3389/fpls.2020.01062. PMC 7373204. PMID 32760416.
  33. ^ Su, Danyan; et al. (2021). "Large-Scale Phylogenomic Analyses Reveal the Monophyly of Bryophytes and Neoproterozoic Origin of Land Plants". Molecular Biology and Evolution. 38 (8): 3332–3344. doi:10.1093/molbev/msab106. PMC 8321542. PMID 33871608.
  34. ^ D. Christine Cargill; Karen S. Renzaglia; Juan Carlos Villarreal; R. Joel Duff (2005), "Generic concepts within hornworts: Historical review, contemporary insights and future directions", Australian Systematic Botany, 18: 7–16, doi:10.1071/sb04012
  35. ^ a b Duff, R. Joel; Juan Carlos Villarreal; D. Christine Cargill; Karen S. Renzaglia (2007). "Progress and challenges toward a phylogeny and classification of the hornworts". The Bryologist. 110 (2): 214–243. doi:10.1639/0007-2745(2007)110[214:PACTDA]2.0.CO;2. S2CID 85582943.
  36. ^ Cole, Theodor C. H.; Hilger, Hartmut H.; Goffinet, Bernard. "Bryophyte phylogeny poster: systematics and Characteristics of Nonvascular Land Plants (Mosses, Liverworts, Hornworts)". 2021. Retrieved 6 December 2022.
  37. ^ Villareal, J. C.; Cargill, D. C.; Hagborg, A.; Söderström, L.; Renzaglia, K. S. (2010). "A synthesis of hornwort diversity: Patterns, causes and future work" (PDF). Phytotaxa. 9: 150–166. doi:10.11646/phytotaxa.9.1.8.
  38. ^ Peñaloza-Bojacá, Gabriel Felipe; Villarreal-Aguilar, Juan Carlos; Maciel-Silva, Adaíses Simone (2019). "Phylogenetic and morphological infrageneric classification of the genus Dendroceros (Dendrocerotaceae; Anthocerotophyta), with the addition of two new subgenera". Systematics and Biodiversity. 17 (7): 712–727. Bibcode:2019SyBio..17..712P. doi:10.1080/14772000.2019.1682080. S2CID 209591279.
  39. ^ Brinda, John C.; Atwood, John J. "The Bryophyte Nomenclator". 7 December 2022. Retrieved 7 December 2022.
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  • Renzaglia, Karen S. & Vaughn, Kevin C. (2000). Anatomy, development, and classification of hornworts. In A. Jonathan Shaw & Bernard Goffinet (Eds.), Bryophyte Biology, pp. 1–20. Cambridge: Cambridge University Press. ISBN 0-521-66097-1.
  • Schofield, W. B. (1985). Introduction to Bryology. New York: Macmillan.
  • Schuster, Rudolf M. (1992). The Hepaticae and Anthocerotae of North America, East of the Hundredth Meridian. Vol. VI. Chicago: Field Museum of Natural History.
  • Smith, Gilbert M. (1938). Cryptogamic Botany, Volume II: Bryophytes and Pteridophytes. New York: McGraw-Hill Book Company.
  • Watson, E. V. (1971). The Structure and Life of Bryophytes (3rd ed.). London: Hutchinson University Library. ISBN 0-09-109301-5.

February 15, 2024
hornwort, name, hornwort, also, refers, aquatic, plants, genus, ceratophyllum, family, ceratophyllaceae, group, vascular, embryophytes, land, plants, constituting, division, anthocerotophyta, common, name, refers, elongated, horn, like, structure, which, sporo. The name hornwort also refers to aquatic plants of the genus Ceratophyllum in the family Ceratophyllaceae Hornworts are a group of non vascular Embryophytes land plants constituting the division Anthocerotophyta ˌ ae n 8 oʊ ˌ s ɛ r e ˈ t ɒ f e t e t e ˈ f aɪ t e The common name refers to the elongated horn like structure which is the sporophyte As in mosses and liverworts hornworts have a gametophyte dominant life cycle in which cells of the plant carry only a single set of genetic information the flattened green plant body of a hornwort is the gametophyte stage of the plant HornwortTemporal range 90 0 Ma PreꞒ Ꞓ O S D C P T J K Pg N Upper Cretaceous but see text to presentPhaeoceros laevis L Prosk Scientific classificationKingdom PlantaeClade EmbryophytesDivision AnthocerotophytaStotler amp Stotl Crand 1977 1 Classes and ordersLeiosporocerotopsidaLeiosporocerotalesAnthocerotopsidaAnthocerotales Dendrocerotales Notothyladales Phymatocerotalessee Classification SynonymsAnthocerotaeHornworts may be found worldwide though they tend to grow only in places that are damp or humid Some species grow in large numbers as tiny weeds in the soil of gardens and cultivated fields Large tropical and sub tropical species of Dendroceros may be found growing on the bark of trees The total number of species is still uncertain While there are more than 300 published species names the actual number could be as low as 100 150 species 2 Contents 1 Description 2 Life cycle 3 Evolutionary history 4 Classification 4 1 Phylogeny 5 See also 6 ReferencesDescription editLike all bryophytes the dominant life phase of a hornwort is the haploid gametophyte This stage usually grows as a thin rosette or ribbon like thallus between one and five centimeters in diameter Hornworts have lost two plastid division associated genes ARC3 and FtsZ2 and have just a single chloroplast per cell monoplastidy with the exception of the genus Megaceros and some species in the genera Nothoceros and Anthoceros which have more than one chloroplast per cell polyplastidy In the polyplastidic species and also some of the monoplastidic species a cellular structure called a pyrenoid is absent 3 4 The pyrenoid which is both a food storing organ and enables a more efficient photosynthesis has evolved independently five to six times in hornworts and is present in half of the roughly 200 species 5 It is formed by the fusion of the chloroplast with other organelles and is comprised predominantly of RuBisCO the key enzyme in carbon fixation By using inorganic carbon transporters and carbonic anhydrases up to a 50 fold increase in CO2 levels can be achieved 6 This particular feature is very unusual in land plants unique to hornworts but is common among algae 7 8 Many hornworts develop internal mucilage filled cavities or canals when groups of cells break down These cavities secrete hormogonium inducing factors HIF that stimulate nearby free living photosynthetic cyanobacteria especially species of Nostoc to invade and colonize these cavities 9 Such colonies of bacteria growing inside the thallus give the hornwort a distinctive blue green color Symbiotic cyanobacteria have not been reported in Megaceros or Folioceros 10 There may also be small slime pores on the underside of the thallus These pores superficially resemble the stomata of other plants The horn shaped sporophyte grows from an archegonium embedded deep in the gametophyte The growth of the hornwort sporophyte happens from a persistent basal meristem in contrast to the sporophyte of moss apical growth and liverworts intercalary growth 11 Unlike liverworts hornworts have true stomata on their sporophyte as most mosses do The exceptions are the species Folioceros incurvus the genus Notothylas and the three closely related genera Megaceros Nothoceros and Dendroceros which do not have stomata 12 13 Notothylas also differ from other hornworts in having a reduced sporophyte only a few millimeters tall The sporophyte in hornworts is unique among bryophytes in being long lived with a persistent photosynthetic capacity 14 The sporophyte lacks an apical meristem an auxin sensitive point of divergence with other land plants some time in the Late Silurian Early Devonian 15 16 When the sporophyte is mature it has a multicellular outer layer a central rod like columella running up the center and a layer of tissue in between that produces spores and pseudo elaters The pseudo elaters are multi cellular unlike the elaters of liverworts They have helical thickenings that change shape in response to drying out they twist and thereby help to disperse the spores Hornwort spores are relatively large for bryophytes measuring between 30 and 80 µm in diameter or more The spores are polar usually with a distinctive Y shaped tri radiate ridge on the proximal surface and with a distal surface ornamented with bumps or spines Life cycle editThe life of a hornwort starts from a haploid spore The spores can be yellow brown or green Yellow and brown spores have a thicker wall and contain oils that both protect against desiccation and function as a nutrient storage allowing them to survive for years The species Folioceros fuciformis and the genera Megaceros Nothoceros and Dendroceros have short lived spores with thin and colorless walls that appear green due to the presence of a chloroplast 17 18 In most species there is a single cell inside the spore and a slender extension of this cell called the germ tube germinates from the proximal side of the spore 19 The tip of the germ tube divides to form an octant solid geometry of cells and the first rhizoid grows as an extension of the original germ cell clarification needed The tip continues to divide new cells which produces a thalloid protonema By contrast species of the family Dendrocerotaceae may begin dividing within the spore becoming multicellular and even photosynthetic before the spore germinates 19 In either case the protonema is a transitory stage in the life of a hornwort nbsp Life cycle of a typical hornwort Phaeoceros Click on the image to enlarge From the protonema grows the adult gametophyte which is the persistent and independent stage in the life cycle This stage usually grows as a thin rosette or ribbon like thallus between one and five centimeters in diameter and several layers of cells in thickness It is green or yellow green from the chlorophyll in its cells or bluish green when colonies of cyanobacteria grow inside the plant When the gametophyte has grown to its adult size it produces the sex organs of the hornwort Most plants are monoecious with both sex organs on the same plant but some plants even within the same species are dioecious with separate male and female gametophytes The female organs are known as archegonia singular archegonium and the male organs are known as antheridia singular antheridium Both kinds of organs develop just below the surface of the plant and are only later exposed by disintegration of the overlying cells The biflagellate sperm must swim from the antheridia or else be splashed to the archegonia When this happens the sperm and egg cell fuse to form a zygote the cell from which the sporophyte stage of the life cycle will develop Unlike all other bryophytes the first cell division of the zygote is longitudinal Further divisions produce three basic regions of the sporophyte At the bottom of the sporophyte closest to the interior of the gametophyte is a foot This is a globular group of cells that receives nutrients from the parent gametophyte on which the sporophyte will spend its entire existence In the middle of the sporophyte just above the foot is a meristem that will continue to divide and produce new cells for the third region This third region is the capsule Both the central and surface cells of the capsule are sterile but between them is a layer of cells that will divide to produce pseudo elaters and spores These are released from the capsule when it splits lengthwise from the tip Evolutionary history editThis section needs expansion You can help by adding to it June 2008 While the fossil record of crown group hornworts only begins in the upper Cretaceous the lower Devonian Horneophyton may represent a stem group to the clade as it possesses a sporangium with central columella not attached at the roof 20 However the same form of columella is also characteristic of basal moss groups such as the Sphagnopsida and Andreaeopsida and has been interpreted as a character common to all early land plants with stomata 21 The divergence between hornworts and Setaphyta mosses and liverworts is estimated to have occurred 479 450 million years ago 22 and the last common ancestor of present day hornworts lived in middle Permian about 275 million years ago 23 Chromosome scale genome sequencing of three hornwort species corroborates that stomata evolved only once during land plant evolution It also shows that the three groups of bryophytes share a common ancestor that branched off from the other landplants early in evolution and that liverworts and mosses are more closely related to each other than to hornworts 24 Unlike other land plants the hornwort genome has the low CO2 inducible B gene LCIB which is also found in some species of algae Because the diffusion rate of carbon dioxide is 10 000 fold higher in air than in water aquatic algae require a mechanism to concentrate CO2 in chloroplasts so as to allow the photosynthetic RuBisCo protein to function efficiently LCIB is one component of this CO2 concentrating mechanism 25 Classification edit nbsp The hornwort Dendroceros crispus growing on the bark of a tree Hornworts were traditionally considered a class within the division Bryophyta bryophytes Later on the bryophytes were considered paraphyletic and hence the hornworts were given their own division Anthocerotophyta sometimes misspelled Anthocerophyta However the most recent phylogenetic evidence leans strongly towards bryophyte monophyly 26 27 28 29 30 31 24 32 33 excessive citations and it has been proposed that hornworts are de ranked to the original class Anthocerotopsida 28 Traditionally there was a single class of hornworts called Anthocerotopsida or older Anthocerotae More recently a second class Leiosporocertotopsida has been segregated for the singularly unusual species Leiosporoceros dussii All other hornworts remain in the class Anthocerotopsida These two classes are divided further into five orders each containing a single family Among land plants hornworts are one of the earliest diverging lineages of the early land plant ancestors 24 cladistic analysis implies that the group originated prior to the Devonian around the same time as the mosses and liverworts There are about 200 species known but new species are still being discovered The number and names of genera are a current matter of investigation and several competing classification schemes have been published since 1988 Structural features that have been used in the classification of hornworts include the anatomy of chloroplasts and their numbers within cells the presence of a pyrenoid the numbers of antheridia within androecia and the arrangement of jacket cells of the antheridia 34 Phylogeny edit Recent studies of molecular ultrastructural and morphological data have yielded a new classification of hornworts 35 36 Class Leiosporocerotopsida Leiosporocerotales Leiosporocerotaceae Leiosporoceros 1 species Class Anthocerotopsida Anthocerotales Anthocerotaceae Anthoceros ca 83 species Folioceros 17 species Sphaerosporoceros 2 species Notothyladales Notothyladaceae Notothylas 21 species Phaeoceros ca 41 species Paraphymatoceros 1 2 species Hattorioceros 1 species Mesoceros 2 species Phymatocerotales Phymatocerotaceae Phymatoceros 2 species Dendrocerotales Dendrocerotaceae Dendroceros 43 species Megaceros 8 species Nothoceros 7 species Phaeomegaceros 7 species Leiosporocerotopsida Leiosporocerotales Leiosporocerotaceae LeiosporocerosAnthocerotopsida Anthocerotales Anthocerotaceae FoliocerosSphaerosporocerosAnthocerosNotothyladales Notothyladaceae NotothylasPhaeocerosPhymatocerotales PhymatocerosPhymatocerotaceaeDendrocerotales Phaeomegacerotoideae PhaeomegacerosDendrocerotoideae NothocerosMegacerosDendrocerosDendrocerotaceaeThe current phylogeny and composition of the Anthocerotophyta 35 37 38 39 See also editEmbryophyteReferences edit Stotler Raymond E Barbara J Candall Stotler 1977 A checklist of the liverworts and hornworts of North America The Bryologist American Bryological and Lichenological Society 80 3 405 428 doi 10 2307 3242017 JSTOR 3242017 Lepp Heino 12 September 2012 What is a hornwort Australian Bryophytes Australian National Botanic Gardens Loss of plastid developmental genes coincides with a reversion to monoplastidy in hornworts bioRxiv Hornworts An Overlooked Window into Carbon Concentrating Mechanisms Villarreal Lab Hornwort pyrenoids carbon concentrating structures evolved and were lost at least five times during the last 100 million years Meyer Moritz T McCormick Alistair J Griffiths Howard 2016 Will an algal CO2 concentrating mechanism work in higher plants Current Opinion in Plant Biology 31 181 188 doi 10 1016 j pbi 2016 04 009 PMID 27194106 Hornwort pyrenoids carbon concentrating structures evolved and were lost at least five times during the last 100 million years PNAS BTI researchers unlocking hornworts secrets EurekAlert Science News Meeks JC 1998 Symbiosis between nitrogen fixing cyanobacteria and plants BioScience 48 4 266 276 doi 10 2307 1313353 JSTOR 1313353 Stress Biology of Cyanobacteria Molecular Mechanisms to Cellular Responses How was apical growth regulated in the ancestral land plant Insights from the development of non seed plants Hornwort Stomata Architecture and Fate Shared with 400 Million Year Old Fossil Plants without Leaves Classification of the Phylum Anthocerotophyta Stotl amp Crand Stotl The deepest divergences in land plants inferred from phylogenomic evidence PNAS Cooke Todd J Poli DorothyBelle Cohen Jerry D 2003 Did auxin play a crucial role in the evolution of novel body plans during the Late Silurian Early Devonian radiation of land plants The Evolution of Plant Physiology Elsevier pp 85 107 doi 10 1016 b978 012339552 8 50006 8 ISBN 978 0 12 339552 8 Friedman William E Moore Richard C Purugganan Michael D 2004 The evolution of plant development American Journal of Botany Botanical Society of America Wiley 91 10 1726 1741 doi 10 3732 ajb 91 10 1726 ISSN 0002 9122 PMID 21652320 Bryophyte Biology NEW CLASSIFICATION OF ANTHOCEROTAE J Stage a b Chopra R N Kumra P K 1988 Biology of Bryophytes New York John Wiley amp Sons ISBN 0 470 21359 0 Qiu Y L Li L Wang B Chen Z Knoop V Groth malonek M Dombrovska O Lee J Kent L Rest J et al 2006 The deepest divergences in land plants inferred from phylogenomic evidence Proceedings of the National Academy of Sciences 103 42 15511 6 Bibcode 2006PNAS 10315511Q doi 10 1073 pnas 0603335103 PMC 1622854 PMID 17030812 Kenrick Paul Peter R Crane 1997 The Origin and Early Diversification of Land Plants A Cladistic Study Washington D C Smithsonian Institution Press pp 55 56 ISBN 1 56098 730 8 Harris Brogan J Clark James W Schrempf Dominik Szollosi Gergely J Donoghue Philip C J Hetherington Alistair M Williams Tom A 2022 Divergent evolutionary trajectories of bryophytes and tracheophytes from a complex common ancestor of land plants Nature Ecology amp Evolution 6 11 1634 1643 doi 10 1038 s41559 022 01885 x PMC 9630106 PMID 36175544 Zhang Jian Fu Xin Xing Li Rui Qi Zhao Xiang Liu Yang Li Ming He Zwaenepoel Arthur Ma Hong Goffinet Bernard Guan Yan Long Xue Jia Yu Liao Yi Ying Wang Qing Feng Wang Qing Hua Wang Jie Yu Zhang Guo Qiang Wang Zhi Wen Jia Yu Wang Mei Zhi Dong Shan Shan Yang Jian Fen Jiao Yuan Nian Guo Ya Long Kong Hong Zhi Lu An Ming Yang Huan Ming Zhang Shou Zhou Van De Peer Yves Liu Zhong Jian Chen Zhi Duan 2020 The hornwort genome and early land plant evolution Nature Plants 6 2 107 118 doi 10 1038 s41477 019 0588 4 PMC 7027989 PMID 32042158 a b c Li F W Nishiyama T Waller M et al 2020 Anthoceros genomes illuminate the origin of land plants and the unique biology of hornworts Nature Plants 6 3 259 272 doi 10 1038 s41477 020 0618 2 PMC 8075897 PMID 32170292 Frangedakis Eftychios Shimamura Masaki Villarreal Juan Carlos Li Fay Wei Tomaselli Marta Waller Manuel Sakakibara Keiko Renzaglia Karen S Szovenyi Peter January 2021 The hornworts morphology evolution and development New Phytologist 229 2 735 754 doi 10 1111 nph 16874 PMC 7881058 PMID 32790880 Cox Cymon J et al 2014 Conflicting Phylogenies for Early Land Plants are Caused by Composition Biases among Synonymous Substitutions Systematic Biology 63 2 272 279 doi 10 1093 sysbio syt109 PMC 3926305 PMID 24399481 Puttick Mark N et al 2018 The Interrelationships of Land Plants and the Nature of the Ancestral Embryophyte Current Biology 28 5 733 745 e2 doi 10 1016 j cub 2018 01 063 hdl 1983 ad32d4da 6cb3 4ed6 add2 2415f81b46da PMID 29456145 S2CID 3269165 a b de Sousa Filipe et al 2019 Nuclear protein phylogenies support the monophyly of the three bryophyte groups Bryophyta Schimp New Phytologist 222 1 565 575 doi 10 1111 nph 15587 hdl 1983 0b471d7e ce54 4681 b791 1da305d9e53b PMID 30411803 S2CID 53240320 Leebens Mack James H et al 2019 One thousand plant transcriptomes and the phylogenomics of green plants Nature 574 7780 679 685 doi 10 1038 s41586 019 1693 2 PMC 6872490 PMID 31645766 Zhang Jian et al 2020 The hornwort genome and early land plant evolution Nature Plants 6 2 107 118 doi 10 1038 s41477 019 0588 4 PMC 7027989 PMID 32042158 Harris Brogan J et al 2020 Phylogenomic Evidence for the Monophyly of Bryophytes and the Reductive Evolution of Stomata Current Biology 30 11 P2201 2012 E2 doi 10 1016 j cub 2020 03 048 hdl 1983 fbf3f371 8085 4e76 9342 e3b326e69edd PMID 32302587 S2CID 215798377 Sousa Filipe et al 2020 The Chloroplast Land Plant Phylogeny Analyses Employing Better Fitting Tree and Site Heterogeneous Composition Models Frontiers in Plant Science 11 1062 doi 10 3389 fpls 2020 01062 PMC 7373204 PMID 32760416 Su Danyan et al 2021 Large Scale Phylogenomic Analyses Reveal the Monophyly of Bryophytes and Neoproterozoic Origin of Land Plants Molecular Biology and Evolution 38 8 3332 3344 doi 10 1093 molbev msab106 PMC 8321542 PMID 33871608 D Christine Cargill Karen S Renzaglia Juan Carlos Villarreal R Joel Duff 2005 Generic concepts within hornworts Historical review contemporary insights and future directions Australian Systematic Botany 18 7 16 doi 10 1071 sb04012 a b Duff R Joel Juan Carlos Villarreal D Christine Cargill Karen S Renzaglia 2007 Progress and challenges toward a phylogeny and classification of the hornworts The Bryologist 110 2 214 243 doi 10 1639 0007 2745 2007 110 214 PACTDA 2 0 CO 2 S2CID 85582943 Cole Theodor C H Hilger Hartmut H Goffinet Bernard Bryophyte phylogeny poster systematics and Characteristics of Nonvascular Land Plants Mosses Liverworts Hornworts 2021 Retrieved 6 December 2022 Villareal J C Cargill D C Hagborg A Soderstrom L Renzaglia K S 2010 A synthesis of hornwort diversity Patterns causes and future work PDF Phytotaxa 9 150 166 doi 10 11646 phytotaxa 9 1 8 Penaloza Bojaca Gabriel Felipe Villarreal Aguilar Juan Carlos Maciel Silva Adaises Simone 2019 Phylogenetic and morphological infrageneric classification of the genus Dendroceros Dendrocerotaceae Anthocerotophyta with the addition of two new subgenera Systematics and Biodiversity 17 7 712 727 Bibcode 2019SyBio 17 712P doi 10 1080 14772000 2019 1682080 S2CID 209591279 Brinda John C Atwood John J The Bryophyte Nomenclator 7 December 2022 Retrieved 7 December 2022 Grolle Riclef 1983 Nomina generica Hepaticarum references types and synonymies Acta Botanica Fennica 121 1 62 Hasegawa J 1994 New classification of Anthocerotae Journal of the Hattori Botanical Laboratory 76 21 34 Renzaglia Karen S 1978 A comparative morphology and developmental anatomy of the Anthocerotophyta Journal of the Hattori Botanical Laboratory 44 31 90 Renzaglia Karen S amp Vaughn Kevin C 2000 Anatomy development and classification of hornworts In A Jonathan Shaw amp Bernard Goffinet Eds Bryophyte Biology pp 1 20 Cambridge Cambridge University Press ISBN 0 521 66097 1 Schofield W B 1985 Introduction to Bryology New York Macmillan Schuster Rudolf M 1992 The Hepaticae and Anthocerotae of North America East of the Hundredth Meridian Vol VI Chicago Field Museum of Natural History Smith Gilbert M 1938 Cryptogamic Botany Volume II Bryophytes and Pteridophytes New York McGraw Hill Book Company Watson E V 1971 The Structure and Life of Bryophytes 3rd ed London Hutchinson University Library ISBN 0 09 109301 5 Retrieved from https en wikipedia org w index php title Hornwort amp oldid 1189498414, wikipedia, wiki, book, books, library,

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