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Gymnosperm

January 26, 2023

Not to be confused with the flowering plant genera Gymnosperma and Gymnospermium.

The gymnosperms (pronunciation (help·info) lit. revealed seeds) are a group of seed-producing plants that includes conifers, cycads, Ginkgo, and gnetophytes, forming the clade Gymnospermae. The term gymnosperm comes from the composite word in Greek: γυμνόσπερμος (γυμνός, gymnos, 'naked' and σπέρμα, sperma, 'seed'), literally meaning 'naked seeds'. The name is based on the unenclosed condition of their seeds (called ovules in their unfertilized state). The non-encased condition of their seeds contrasts with the seeds and ovules of flowering plants (angiosperms), which are enclosed within an ovary. Gymnosperm seeds develop either on the surface of scales or leaves, which are often modified to form cones, or solitary as in yew, Torreya, Ginkgo.[2] Gymnosperm lifecycles involve alternation of generations. They have a dominant diploid sporophyte phase and a reduced haploid gametophyte phase which is dependent on the sporophytic phase. The term "gymnosperm" is often used in paleobotany to refer to all non-angiosperm seed plants. In that case, to specify the modern monophyletic group of gymnosperms, the term Acrogymnospermae is sometimes used.

The gymnosperms and angiosperms together comprise the spermatophytes or seed plants. The gymnosperms are subdivided into five Divisions, four of which, the Cycadophyta, Ginkgophyta, Gnetophyta, and Pinophyta (also known as Coniferophyta) are still in existence while the Pteridospermatophyta are now extinct.[3] Newer classification place the gnetophytes among the conifers.[4]

By far the largest group of living gymnosperms are the conifers (pines, cypresses, and relatives), followed by cycads, gnetophytes (Gnetum, Ephedra and Welwitschia), and Ginkgo biloba (a single living species). About 65% of gymnosperms are dioecious,[5] but conifers are almost all monoecious.[6]

Some genera have mycorrhiza, fungal associations with roots (Pinus), while in some others (Cycas) small specialised roots called coralloid roots are associated with nitrogen-fixing cyanobacteria.

Diversity and origin

 
Encephalartos sclavoi cone, about 30 cm long

Over 1000 living species of gymnosperm exist.[2] It was previously widely accepted that the gymnosperms originated in the Late Carboniferous period, replacing the lycopsid rainforests of the tropical region, but more recent phylogenetic evidence indicates that they diverged from the ancestors of angiosperms during the Early Carboniferous.[7][8] The radiation of gymnosperms during the late Carboniferous appears to have resulted from a whole genome duplication event around 319 million years ago.[9] Early characteristics of seed plants are evident in fossil progymnosperms of the late Devonian period around 383 million years ago. It has been suggested that during the mid-Mesozoic era, pollination of some extinct groups of gymnosperms was by extinct species of scorpionflies that had specialized proboscis for feeding on pollination drops. The scorpionflies likely engaged in pollination mutualisms with gymnosperms, long before the similar and independent coevolution of nectar-feeding insects on angiosperms.[10][11] Evidence has also been found that mid-Mesozoic gymnosperms were pollinated by Kalligrammatid lacewings, a now-extinct family with members which (in an example of convergent evolution) resembled the modern butterflies that arose far later.[12]

 
Zamia integrifolia, a cycad native to Florida

All gymnosperms are perennial woody plants,[13] apart from the cycads. The soft and highly parenchymatous wood in cycads is poorly lignified,[14] and their main structural support comes from an armor of sclerenchymatous leaf bases covering the stem,[15] with the exception of species with underground stems.[16] There are no herbaceous gymnosperms and compared to angiosperms they occupy fewer ecological niches, but have evolved both parasites (parasitaxus), epiphytes (Zamia pseudoparasitica) and rheophytes (Retrophyllum minus).[17]

Conifers are by far the most abundant extant group of gymnosperms with six to eight families, with a total of 65–70 genera and 600–630 species (696 accepted names).[18] Most conifers are evergreens.[19] The leaves of many conifers are long, thin and needle-like, other species, including most Cupressaceae and some Podocarpaceae, have flat, triangular scale-like leaves. Agathis in Araucariaceae and Nageia in Podocarpaceae have broad, flat strap-shaped leaves.

Cycads are the next most abundant group of gymnosperms, with two or three families, 11 genera, and approximately 338 species. A majority of cycads are native to tropical climates and are most abundantly found in regions near the equator. The other extant groups are the 95–100 species of Gnetales and one species of Ginkgo.[3]

Today gymnosperms are the most threatened of all plant groups.[20]

Gymnospermae

Classification

Phylogeny of Acrogymnospermae[21][22][23][24]
Pinidae
Araucariales
Araucariaceae
Agathideae
Araucarieae

Araucaria

Podocarpaceae
"Phyllocladoideae"
Cupressales
Further information: Spermatophyte

A formal classification of the living gymnosperms is the "Acrogymnospermae", which form a monophyletic group within the spermatophytes.[25][26] The wider "Gymnospermae" group includes extinct gymnosperms and is thought to be paraphyletic. The fossil record of gymnosperms includes many distinctive taxa that do not belong to the four modern groups, including seed-bearing trees that have a somewhat fern-like vegetative morphology (the so-called "seed ferns" or pteridosperms).[27] When fossil gymnosperms such as these and the Bennettitales, glossopterids, and Caytonia are considered, it is clear that angiosperms are nested within a larger gymnospermae clade, although which group of gymnosperms is their closest relative remains unclear.

The extant gymnosperms include 12 main families and 83 genera which contain more than 1000 known species.[2][26][28]

Subclass Cycadidae

Subclass Ginkgoidae

Subclass Gnetidae

Subclass Pinidae

Extinct groupings

Life cycle

 
Example of gymnosperm lifecycle

Gymnosperms, like all vascular plants, have a sporophyte-dominant life cycle, which means they spend most of their life cycle with diploid cells, while the gametophyte (gamete-bearing phase) is relatively short-lived. Like all seed plants, they are heterosporous, having two spore types, microspores (male) and megaspores (female) that are typically produced in pollen cones or ovulate cones, respectively. The exception is the females in the cycad genus Cycas, which form a loose structure called megasporophylls instead of cones.[29] As with all heterosporous plants, the gametophytes develop within the spore wall. Pollen grains (microgametophytes) mature from microspores, and ultimately produce sperm cells. Megagametophytes develop from megaspores and are retained within the ovule. Gymnosperms produce multiple archegonia, which produce the female gamete.

During pollination, pollen grains are physically transferred between plants from the pollen cone to the ovule. Pollen is usually moved by wind or insects. Whole grains enter each ovule through a microscopic gap in the ovule coat (integument) called the micropyle. The pollen grains mature further inside the ovule and produce sperm cells. Two main modes of fertilization are found in gymnosperms. Cycads and Ginkgo have flagellated motile sperm[30] that swim directly to the egg inside the ovule, whereas conifers and gnetophytes have sperm with no flagella that are moved along a pollen tube to the egg. After syngamy (joining of the sperm and egg cell), the zygote develops into an embryo (young sporophyte). More than one embryo is usually initiated in each gymnosperm seed. The mature seed comprises the embryo and the remains of the female gametophyte, which serves as a food supply, and the seed coat.[31]

Genetics

The first published sequenced genome for any gymnosperm was the genome of Picea abies in 2013.[32]

Uses

Gymnosperms have major economic uses. Pine, fir, spruce, and cedar are all examples of conifers that are used for lumber, paper production, and resin. Some other common uses for gymnosperms are soap, varnish, nail polish, food, gum, and perfumes.[33]

References

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  22. ^ Leslie, Andrew B.; et al. (2018). "ajb21143-sup-0004-AppendixS4" (PDF). American Journal of Botany. 105 (9): 1531–1544. doi:10.1002/ajb2.1143. PMID 30157290. S2CID 52120430.
  23. ^ Stull, Gregory W.; Qu, Xiao-Jian; Parins-Fukuchi, Caroline; Yang, Ying-Ying; Yang, Jun-Bo; Yang, Zhi-Yun; Hu, Yi; Ma, Hong; Soltis, Pamela S.; Soltis, Douglas E.; Li, De-Zhu; Smith, Stephen A.; Yi, Ting-Shuang; et al. (2021). "Gene duplications and phylogenomic conflict underlie major pulses of phenotypic evolution in gymnosperms". Nature Plants. 7 (8): 1015–1025. bioRxiv 10.1101/2021.03.13.435279. doi:10.1038/s41477-021-00964-4. PMID 34282286. S2CID 232282918.
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  29. ^ Liu, Yang; Wang, Sibo; Li, Linzhou; Yang, Ting; Dong, Shanshan; Wei, Tong; Wu, Shengdan; Liu, Yongbo; Gong, Yiqing; Feng, Xiuyan; Ma, Jianchao; Chang, Guanxiao; Huang, Jinling; Yang, Yong; Wang, Hongli (April 2022). "The Cycas genome and the early evolution of seed plants". Nature Plants. 8 (4): 389–401. doi:10.1038/s41477-022-01129-7. ISSN 2055-0278. PMC 9023351. PMID 35437001.
  30. ^ Southworth, Darlene; Cresti, Mauro (September 1997). "Comparison of flagellated and nonflagellated sperm in plants". American Journal of Botany. 84 (9): 1301–1311. doi:10.2307/2446056. JSTOR 2446056. PMID 21708687. Retrieved 26 March 2022.
  31. ^ Walters, Dirk R Walters Bonnie By (1996). Vascular plant taxonomy. Dubuque, Iowa: Kendall/Hunt Pub. Co. p. 124. ISBN 978-0-7872-2108-9. Gymnosperm seeds.
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General bibliography

  • Cantino, Philip D.; Doyle, James A.; Graham, Sean W.; Judd, Walter S.; Olmstead, Richard G.; Soltis, Douglas E.; Soltis, Pamela S.; Donoghue, Michael J. (August 2007). "Towards a phylogenetic nomenclature of Tracheophyta". Taxon. 56 (3): 822–846. doi:10.2307/25065864. JSTOR 25065864.

External links

 
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Look up gymnosperm in Wiktionary, the free dictionary.

January 26, 2023
gymnosperm, confused, with, flowering, plant, genera, gymnosperms, pronunciation, help, info, revealed, seeds, group, seed, producing, plants, that, includes, conifers, cycads, ginkgo, gnetophytes, forming, clade, term, gymnosperm, comes, from, composite, word. Not to be confused with the flowering plant genera Gymnosperma and Gymnospermium The gymnosperms pronunciation help info lit revealed seeds are a group of seed producing plants that includes conifers cycads Ginkgo and gnetophytes forming the clade Gymnospermae The term gymnosperm comes from the composite word in Greek gymnospermos gymnos gymnos naked and sperma sperma seed literally meaning naked seeds The name is based on the unenclosed condition of their seeds called ovules in their unfertilized state The non encased condition of their seeds contrasts with the seeds and ovules of flowering plants angiosperms which are enclosed within an ovary Gymnosperm seeds develop either on the surface of scales or leaves which are often modified to form cones or solitary as in yew Torreya Ginkgo 2 Gymnosperm lifecycles involve alternation of generations They have a dominant diploid sporophyte phase and a reduced haploid gametophyte phase which is dependent on the sporophytic phase The term gymnosperm is often used in paleobotany to refer to all non angiosperm seed plants In that case to specify the modern monophyletic group of gymnosperms the term Acrogymnospermae is sometimes used GymnospermTemporal range Carboniferous Present PreꞒ Ꞓ O S D C P T J K Pg NVarious gymnosperms Scientific classificationKingdom PlantaeClade TracheophytesClade SpermatophytesClade GymnospermsLiving orders 1 Cycadopsida Cycadales Ginkgoopsida Ginkgoales Pinopsida Cupressidae Araucariales Cupressales Pinidae Pinales Gnetidae Ephedrales Welwitschiales GnetalesThe gymnosperms and angiosperms together comprise the spermatophytes or seed plants The gymnosperms are subdivided into five Divisions four of which the Cycadophyta Ginkgophyta Gnetophyta and Pinophyta also known as Coniferophyta are still in existence while the Pteridospermatophyta are now extinct 3 Newer classification place the gnetophytes among the conifers 4 By far the largest group of living gymnosperms are the conifers pines cypresses and relatives followed by cycads gnetophytes Gnetum Ephedra and Welwitschia and Ginkgo biloba a single living species About 65 of gymnosperms are dioecious 5 but conifers are almost all monoecious 6 Some genera have mycorrhiza fungal associations with roots Pinus while in some others Cycas small specialised roots called coralloid roots are associated with nitrogen fixing cyanobacteria Contents 1 Diversity and origin 2 Classification 2 1 Extinct groupings 3 Life cycle 4 Genetics 5 Uses 6 References 7 General bibliography 8 External linksDiversity and origin Edit Encephalartos sclavoi cone about 30 cm long Over 1000 living species of gymnosperm exist 2 It was previously widely accepted that the gymnosperms originated in the Late Carboniferous period replacing the lycopsid rainforests of the tropical region but more recent phylogenetic evidence indicates that they diverged from the ancestors of angiosperms during the Early Carboniferous 7 8 The radiation of gymnosperms during the late Carboniferous appears to have resulted from a whole genome duplication event around 319 million years ago 9 Early characteristics of seed plants are evident in fossil progymnosperms of the late Devonian period around 383 million years ago It has been suggested that during the mid Mesozoic era pollination of some extinct groups of gymnosperms was by extinct species of scorpionflies that had specialized proboscis for feeding on pollination drops The scorpionflies likely engaged in pollination mutualisms with gymnosperms long before the similar and independent coevolution of nectar feeding insects on angiosperms 10 11 Evidence has also been found that mid Mesozoic gymnosperms were pollinated by Kalligrammatid lacewings a now extinct family with members which in an example of convergent evolution resembled the modern butterflies that arose far later 12 Zamia integrifolia a cycad native to Florida All gymnosperms are perennial woody plants 13 apart from the cycads The soft and highly parenchymatous wood in cycads is poorly lignified 14 and their main structural support comes from an armor of sclerenchymatous leaf bases covering the stem 15 with the exception of species with underground stems 16 There are no herbaceous gymnosperms and compared to angiosperms they occupy fewer ecological niches but have evolved both parasites parasitaxus epiphytes Zamia pseudoparasitica and rheophytes Retrophyllum minus 17 Conifers are by far the most abundant extant group of gymnosperms with six to eight families with a total of 65 70 genera and 600 630 species 696 accepted names 18 Most conifers are evergreens 19 The leaves of many conifers are long thin and needle like other species including most Cupressaceae and some Podocarpaceae have flat triangular scale like leaves Agathis in Araucariaceae and Nageia in Podocarpaceae have broad flat strap shaped leaves Cycads are the next most abundant group of gymnosperms with two or three families 11 genera and approximately 338 species A majority of cycads are native to tropical climates and are most abundantly found in regions near the equator The other extant groups are the 95 100 species of Gnetales and one species of Ginkgo 3 Today gymnosperms are the most threatened of all plant groups 20 Spermatophyta Pteridospermatophyta AcrogymnospermaeAngiospermae GymnospermaeClassification EditPhylogeny of Acrogymnospermae 21 22 23 24 Ginkgoidae Ginkgoales Ginkgoaceae GinkgoCycadidae Cycadales Cycadaceae CycasZamiaceae Diooideae DioonZamioideae BoweniaMacrozamiaLepidozamiaEncephalartosStangeriaCeratozamiaMicrocycasZamiaPinidae Gnetales Welwitschiaceae WelwitschiaGnetaceae GnetumEphedraceae EphedraPinales Pinaceae Abietoideae CedrusPseudolarixNothotsugaTsugaKeteleeriaAbiesPinoideae PseudotsugaLarixCathayaPiceaPinusAraucariales Araucariaceae Agathideae WollemiaAgathisAraucarieae AraucariaPodocarpaceae Phyllocladoideae HalocarpusPectinopitysSundacarpusPrumnopitysParasitaxusLagarostrobosManoaoLepidothamnusPhyllocladus Podocarpoideae SaxegothaeaMicrocachrysPherosphaeraAcmopyleDacrycarpusFalcatifoliumDacrydiumRetrophyllumAfrocarpusNageiaPodocarpusCupressales Sciadopityaceae SciadopitysTaxaceae Cephalotaxeae CephalotaxusTaxoideae AmentotaxusTorreyaAustrotaxusPseudotaxusTaxusCupressaceae CunninghamiaTaiwaniaAthrotaxisSequoioideae MetasequoiaSequoiadendronSequoiaTaxodioideae CryptomeriaGlyptostrobusTaxodium Actinostroboideae PapuacedrusAustrocedrusPilgerodendronLibocedrusDiselmaFitzroyaWiddringtoniaNeocallitropsisCallitris Cupressoideae ThujopsisThujaChamaecyparisTetraclinisMicrobiotaPlatycladusCalocedrusCupressusXanthocyparisHesperocyparisJuniperusFurther information Spermatophyte A formal classification of the living gymnosperms is the Acrogymnospermae which form a monophyletic group within the spermatophytes 25 26 The wider Gymnospermae group includes extinct gymnosperms and is thought to be paraphyletic The fossil record of gymnosperms includes many distinctive taxa that do not belong to the four modern groups including seed bearing trees that have a somewhat fern like vegetative morphology the so called seed ferns or pteridosperms 27 When fossil gymnosperms such as these and the Bennettitales glossopterids and Caytonia are considered it is clear that angiosperms are nested within a larger gymnospermae clade although which group of gymnosperms is their closest relative remains unclear The extant gymnosperms include 12 main families and 83 genera which contain more than 1000 known species 2 26 28 Subclass Cycadidae Order Cycadales Family Cycadaceae Cycas Family Zamiaceae Dioon Bowenia Macrozamia Lepidozamia Encephalartos Stangeria Ceratozamia Microcycas ZamiaSubclass Ginkgoidae Order Ginkgoales Family Ginkgoaceae GinkgoSubclass Gnetidae Order Welwitschiales Family Welwitschiaceae Welwitschia Order Gnetales Family Gnetaceae Gnetum Order Ephedrales Family Ephedraceae EphedraSubclass Pinidae Order Pinales Family Pinaceae Cedrus Pinus Cathaya Picea Pseudotsuga Larix Pseudolarix Tsuga Nothotsuga Keteleeria AbiesOrder Araucariales Family Araucariaceae Araucaria Wollemia Agathis Family Podocarpaceae Phyllocladus Lepidothamnus Prumnopitys Sundacarpus Halocarpus Parasitaxus Lagarostrobos Manoao Saxegothaea Microcachrys Pherosphaera Acmopyle Dacrycarpus Dacrydium Falcatifolium Retrophyllum Nageia Afrocarpus PodocarpusOrder Cupressales Family Sciadopityaceae Sciadopitys Family Cupressaceae Cunninghamia Taiwania Athrotaxis Metasequoia Sequoia Sequoiadendron Cryptomeria Glyptostrobus Taxodium Papuacedrus Austrocedrus Libocedrus Pilgerodendron Widdringtonia Diselma Fitzroya Callitris Actinostrobus Neocallitropsis Thujopsis Thuja Fokienia Chamaecyparis Cupressus Juniperus Calocedrus Tetraclinis Platycladus Microbiota Family Taxaceae Austrotaxus Pseudotaxus Taxus Cephalotaxus Amentotaxus TorreyaExtinct groupings Edit Division Pteridospermatophyta Order Bennettitales Family Cycadeoidaceae Family Williamsoniaceae Order Erdtmanithecales Order Pentoxylales Order CzekanowskialesLife cycle EditThis section relies largely or entirely upon a single source Relevant discussion may be found on the talk page Please help improve this article by introducing citations to additional sources August 2021 Learn how and when to remove this template message Example of gymnosperm lifecycle Gymnosperms like all vascular plants have a sporophyte dominant life cycle which means they spend most of their life cycle with diploid cells while the gametophyte gamete bearing phase is relatively short lived Like all seed plants they are heterosporous having two spore types microspores male and megaspores female that are typically produced in pollen cones or ovulate cones respectively The exception is the females in the cycad genus Cycas which form a loose structure called megasporophylls instead of cones 29 As with all heterosporous plants the gametophytes develop within the spore wall Pollen grains microgametophytes mature from microspores and ultimately produce sperm cells Megagametophytes develop from megaspores and are retained within the ovule Gymnosperms produce multiple archegonia which produce the female gamete During pollination pollen grains are physically transferred between plants from the pollen cone to the ovule Pollen is usually moved by wind or insects Whole grains enter each ovule through a microscopic gap in the ovule coat integument called the micropyle The pollen grains mature further inside the ovule and produce sperm cells Two main modes of fertilization are found in gymnosperms Cycads and Ginkgo have flagellated motile sperm 30 that swim directly to the egg inside the ovule whereas conifers and gnetophytes have sperm with no flagella that are moved along a pollen tube to the egg After syngamy joining of the sperm and egg cell the zygote develops into an embryo young sporophyte More than one embryo is usually initiated in each gymnosperm seed The mature seed comprises the embryo and the remains of the female gametophyte which serves as a food supply and the seed coat 31 Genetics EditThe first published sequenced genome for any gymnosperm was the genome of Picea abies in 2013 32 Uses EditGymnosperms have major economic uses Pine fir spruce and cedar are all examples of conifers that are used for lumber paper production and resin Some other common uses for gymnosperms are soap varnish nail polish food gum and perfumes 33 References Edit Yang Y Ferguson DK Liu B Mao KS Gao LM Zhang SZ Wan T Rushforth K Zhang ZX 2020 Recent advances on phylogenomics of gymnosperms and a new classification Plant Diversity 44 4 340 350 doi 10 1016 j pld 2022 05 003 ISSN 2468 2659 PMC 9363647 PMID 35967253 S2CID 249117306 a b c Gymnosperms on The Plant List Theplantlist org Archived from the original on 2013 08 24 Retrieved 2013 07 24 a b Raven P H 2013 Biology of Plants New York W H Freeman and Co Yang Yong Ferguson David Kay Liu Bing Mao Kang Shan Gao Lian Ming Zhang Shou Zhou Wan Tao Rushforth Keith Zhang Zhi Xiang 2022 07 01 Recent advances on phylogenomics of gymnosperms and a new classification Plant Diversity 44 4 340 350 doi 10 1016 j pld 2022 05 003 ISSN 2468 2659 PMC 9363647 PMID 35967253 Walas Lukasz Mandryk Wojciech Thomas Peter A Tyrala Wierucka Zanna Iszkulo Grzegorz 2018 09 01 Sexual systems in gymnosperms A review Basic and Applied Ecology 31 1 9 doi 10 1016 j baae 2018 05 009 ISSN 1439 1791 S2CID 90740232 Walas L Mandryk W Thomas PA Tyrala Wierucka Z Iszkulo G 2018 Sexual systems in gymnosperms A review PDF Basic and Applied Ecology 31 1 9 doi 10 1016 j baae 2018 05 009 S2CID 90740232 Li Hong Tao Yi Ting Shuang Gao Lian Ming Ma Peng Fei Zhang Ting Yang Jun Bo Gitzendanner Matthew A Fritsch Peter W Cai Jie Luo Yang Wang Hong May 2019 Origin of angiosperms and the puzzle of the Jurassic gap Nature Plants 5 5 461 470 doi 10 1038 s41477 019 0421 0 PMID 31061536 S2CID 146118264 Morris Jennifer L Puttick Mark N Clark James W Edwards Dianne Kenrick Paul Pressel Silvia Wellman Charles H Yang Ziheng Schneider Harald Donoghue Philip C J 2018 03 06 The timescale of early land plant evolution Proceedings of the National Academy of Sciences of the United States of America 115 10 E2274 E2283 Bibcode 2018PNAS 115E2274M doi 10 1073 pnas 1719588115 PMC 5877938 PMID 29463716 Jiao Yuannian Wickett Norman J Ayyampalayam Saravanaraj Chanderbali Andre S Landherr Lena Ralph Paula E Tomsho Lynn P Hu Yi Liang Haiying Soltis Pamela S Soltis Douglas E 2011 04 10 Ancestral polyploidy in seed plants and angiosperms Nature 473 7345 97 100 Bibcode 2011Natur 473 97J doi 10 1038 nature09916 PMID 21478875 S2CID 4313258 Ollerton J Coulthard E 2009 Evolution of Animal Pollination Science 326 5954 808 809 Bibcode 2009Sci 326 808O doi 10 1126 science 1181154 PMID 19892970 S2CID 856038 Ren D Labandeira CC Santiago Blay JA Rasnitsyn A et al 2009 A Probable Pollination Mode Before Angiosperms Eurasian Long Proboscid Scorpionflies Science 326 5954 840 847 Bibcode 2009Sci 326 840R doi 10 1126 science 1178338 PMC 2944650 PMID 19892981 Labandeira Conrad C Yang Qiang Santiago Blay Jorge A Hotton Carol L Monteiro Antonia Wang Yong Jie Goreva Yulia Shih ChungKun Siljestrom Sandra Rose Tim R Dilcher David L Ren Dong 2016 The evolutionary convergence of mid Mesozoic lacewings and Cenozoic butterflies Proceedings of the Royal Society B Biological Sciences 283 1824 20152893 doi 10 1098 rspb 2015 2893 PMC 4760178 PMID 26842570 academic oup com https academic oup com biolinnean article abstract 36 3 227 2656939 login false Retrieved 2023 01 16 a href Template Cite web html title Template Cite web cite web a Missing or empty title help Fisher Jack B Lindstrom Anders Marler Thomas E 2009 06 01 Tissue Responses and Solution Movement After Stem Wounding in Six Cycas Species HortScience 44 3 848 851 doi 10 21273 HORTSCI 44 3 848 ISSN 0018 5345 S2CID 83644706 Bell Peter R Bell Peter R Hemsley Alan R 2000 09 28 Green Plants Their Origin and Diversity Cambridge University Press ISBN 978 0 521 64673 4 Cleal Christopher J Thomas Barry A 2019 06 27 Introduction to Plant Fossils Cambridge University Press ISBN 978 1 108 48344 5 Mill R R 2016 06 22 A Monographic Revision of Retrophyllum Podocarpaceae Edinburgh Journal of Botany 73 2 171 261 doi 10 1017 S0960428616000081 ISSN 1474 0036 Catalogue of Life 2007 Annual checklist Conifer database Archived from the original on January 15 2009 Campbell Reece Phylum Coniferophyta Biology 7th 2005 Print P 595 Gilbert Natasha 2010 09 28 Threats to the world s plants assessed Nature doi 10 1038 news 2010 499 ISSN 1476 4687 Leslie Andrew B Beaulieu Jeremy Holman Garth Campbell Christopher S Mei Wenbin Raubeson Linda R Mathews Sarah et al 2018 An overview of extant conifer evolution from the perspective of the fossil record American Journal of Botany 105 9 1531 1544 doi 10 1002 ajb2 1143 PMID 30157290 S2CID 52120430 Leslie Andrew B et al 2018 ajb21143 sup 0004 AppendixS4 PDF American Journal of Botany 105 9 1531 1544 doi 10 1002 ajb2 1143 PMID 30157290 S2CID 52120430 Stull Gregory W Qu Xiao Jian Parins Fukuchi Caroline Yang Ying Ying Yang Jun Bo Yang Zhi Yun Hu Yi Ma Hong Soltis Pamela S Soltis Douglas E Li De Zhu Smith Stephen A Yi Ting Shuang et al 2021 Gene duplications and phylogenomic conflict underlie major pulses of phenotypic evolution in gymnosperms Nature Plants 7 8 1015 1025 bioRxiv 10 1101 2021 03 13 435279 doi 10 1038 s41477 021 00964 4 PMID 34282286 S2CID 232282918 Stull Gregory W et al 2021 main dated supermatrix tree T9 tre Figshare doi 10 6084 m9 figshare 14547354 v1 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Cantino 2007 a b Christenhusz M J M Reveal J L Farjon A Gardner M F Mill R R Chase M W 2011 A new classification and linear sequence of extant gymnosperms PDF Phytotaxa 19 55 70 doi 10 11646 phytotaxa 19 1 3 S2CID 86797396 Hilton Jason Bateman Richard M January 2006 Pteridosperms are the backbone of seed plant phylogeny 1 The Journal of the Torrey Botanical Society 133 1 119 168 doi 10 3159 1095 5674 2006 133 119 PATBOS 2 0 CO 2 S2CID 86395036 Christenhusz M J M Byng J W 2016 The number of known plants species in the world and its annual increase Phytotaxa 261 3 201 217 doi 10 11646 phytotaxa 261 3 1 Liu Yang Wang Sibo Li Linzhou Yang Ting Dong Shanshan Wei Tong Wu Shengdan Liu Yongbo Gong Yiqing Feng Xiuyan Ma Jianchao Chang Guanxiao Huang Jinling Yang Yong Wang Hongli April 2022 The Cycas genome and the early evolution of seed plants Nature Plants 8 4 389 401 doi 10 1038 s41477 022 01129 7 ISSN 2055 0278 PMC 9023351 PMID 35437001 Southworth Darlene Cresti Mauro September 1997 Comparison of flagellated and nonflagellated sperm in plants American Journal of Botany 84 9 1301 1311 doi 10 2307 2446056 JSTOR 2446056 PMID 21708687 Retrieved 26 March 2022 Walters Dirk R Walters Bonnie By 1996 Vascular plant taxonomy Dubuque Iowa Kendall Hunt Pub Co p 124 ISBN 978 0 7872 2108 9 Gymnosperm seeds Nystedt B Street NR Wetterbom A et al May 2013 The Norway spruce genome sequence and conifer genome evolution Nature 497 7451 579 584 Bibcode 2013Natur 497 579N doi 10 1038 nature12211 PMID 23698360 Biswas C Johri B M 1997 Economic Importance The Gymnosperms PDF Springer Berlin Heidelberg pp 440 456 doi 10 1007 978 3 662 13164 0 23 ISBN 978 3 662 13166 4 General bibliography EditCantino Philip D Doyle James A Graham Sean W Judd Walter S Olmstead Richard G Soltis Douglas E Soltis Pamela S Donoghue Michael J August 2007 Towards a phylogenetic nomenclature of Tracheophyta Taxon 56 3 822 846 doi 10 2307 25065864 JSTOR 25065864 External links Edit Wikimedia Commons has media related to Gymnosperms Look up gymnosperm in Wiktionary the free dictionary Gymnosperm Database Gymnosperms on the Tree of Life Albert Seward 1911 Gymnosperms Encyclopaedia Britannica 11th ed Retrieved from https en wikipedia org w index php title Gymnosperm amp oldid 1135513226, wikipedia, wiki, book, books, library,

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