Vertebrate: Difference between revisions

From Wikipedia, the free encyclopedia
Jump to navigation Jump to search
Next edit →
VisualWikitext
imported>OAbot
m Open access bot: url-access updated in citation with #oabot.
 
imported>Citation bot
Altered issue. Added pmid. Formatted dashes. | Use this bot. Report bugs. | Suggested by Abductive | #UCB_toolbar
Line 41: Line 41:
As embryos, vertebrates still have a notochord; as adults, all but the [[Agnatha|jawless fishes]] have a vertebral column, made of [[bone]] or [[cartilage]], instead.<ref name="Romer 1977"/> Vertebrate embryos have [[pharyngeal arch]]es; in adult [[fish]], these support the [[gill]]s, while in adult [[tetrapod]]s they develop into other structures.<ref name=dev>{{cite journal |last=Graham |first=A. |title=Development of the pharyngeal arches |journal=[[American Journal of Medical Genetics Part A]] |volume=119A |issue=3 |pages=251–256 |year=2003 |pmid=12784288 |doi=10.1002/ajmg.a.10980 |s2cid=28318053 }}</ref><ref name="Graham2001">{{cite journal |last=Graham |first=A. |title=The development and evolution of the pharyngeal arches |journal=[[Journal of Anatomy]] |date=July 2001 |volume=199 |issue=Pt 1-2 |pages=133–141 |doi=10.1046/j.1469-7580.2001.19910133.x |pmid=11523815|pmc=1594982 }}</ref>  
As embryos, vertebrates still have a notochord; as adults, all but the [[Agnatha|jawless fishes]] have a vertebral column, made of [[bone]] or [[cartilage]], instead.<ref name="Romer 1977"/> Vertebrate embryos have [[pharyngeal arch]]es; in adult [[fish]], these support the [[gill]]s, while in adult [[tetrapod]]s they develop into other structures.<ref name=dev>{{cite journal |last=Graham |first=A. |title=Development of the pharyngeal arches |journal=[[American Journal of Medical Genetics Part A]] |volume=119A |issue=3 |pages=251–256 |year=2003 |pmid=12784288 |doi=10.1002/ajmg.a.10980 |s2cid=28318053 }}</ref><ref name="Graham2001">{{cite journal |last=Graham |first=A. |title=The development and evolution of the pharyngeal arches |journal=[[Journal of Anatomy]] |date=July 2001 |volume=199 |issue=Pt 1-2 |pages=133–141 |doi=10.1046/j.1469-7580.2001.19910133.x |pmid=11523815|pmc=1594982 }}</ref>  


[[embryonic development|In the embryo]], a [[neural plate|layer of cells]] along the back [[neurulation|folds and fuses]] into a hollow [[neural tube]].<ref name="Martín-Durán 2018">{{cite journal |last1=Martín-Durán |first1=José M. |last2=Pang |first2=Kevin |last3=Børve |first3=Aina |last4=Lê |first4=Henrike Semmler |last5=Furu |first5=Anlaug |last6=Cannon |first6=Johanna Taylor |last7=Jondelius |first7=Ulf |last8=Hejnol |first8=Andreas |display-authors=5 |title=Convergent evolution of bilaterian nerve cords |journal=[[Nature (journal)|Nature]] |volume=553 |issue=7686 |date=4 January 2018 |pmid=29236686 |pmc=5756474 |doi=10.1038/nature25030 |doi-access=free |pages=45–50}}</ref> This develops into the [[spinal cord]], and at its front end, the [[brain]].<ref name="Martín-Durán 2018"/> The brain receives information about the world through nerves which carry signals from [[sense organ]]s in the skin and body.<ref>{{cite web |title=In brief: How does the nervous system work? |url=https://www.ncbi.nlm.nih.gov/books/NBK279390/ |website=InformedHealth.org |access-date=30 November 2024 |date=4 May 2023}}</ref> Because the ancestors of vertebrates usually moved forwards, the front of the body encountered stimuli before the rest of the body, favouring [[cephalisation]], the evolution of a head containing sense organs and a brain to process the sensory information.<ref name="Brusca 2016">{{cite book |last=Brusca |first=Richard C. |url=http://www.sinauer.com/media/wysiwyg/samples/Brusca3e_Chapter_9.pdf |chapter=Introduction to the Bilateria and the Phylum Xenacoelomorpha: Triploblasty and Bilateral Symmetry Provide New Avenues for Animal Radiation |title=Invertebrates |date=2016 |publisher=[[Sinauer Associates]] |pages=345–372 |isbn=978-1605353753}}</ref>
[[embryonic development|In the embryo]], a [[neural plate|layer of cells]] along the back [[neurulation|folds and fuses]] into a hollow [[neural tube]].<ref name="Martín-Durán 2018">{{cite journal |last1=Martín-Durán |first1=José M. |last2=Pang |first2=Kevin |last3=Børve |first3=Aina |last4=Lê |first4=Henrike Semmler |last5=Furu |first5=Anlaug |last6=Cannon |first6=Johanna Taylor |last7=Jondelius |first7=Ulf |last8=Hejnol |first8=Andreas |display-authors=5 |title=Convergent evolution of bilaterian nerve cords |journal=[[Nature (journal)|Nature]] |volume=553 |issue=7686 |date=4 January 2018 |pmid=29236686 |pmc=5756474 |doi=10.1038/nature25030 |doi-access=free |pages=45–50|bibcode=2018Natur.553...45M }}</ref> This develops into the [[spinal cord]], and at its front end, the [[brain]].<ref name="Martín-Durán 2018"/> The brain receives information about the world through nerves which carry signals from [[sense organ]]s in the skin and body.<ref>{{cite web |title=In brief: How does the nervous system work? |url=https://www.ncbi.nlm.nih.gov/books/NBK279390/ |website=InformedHealth.org |access-date=30 November 2024 |date=4 May 2023}}</ref> Because the ancestors of vertebrates usually moved forwards, the front of the body encountered stimuli before the rest of the body, favouring [[cephalisation]], the evolution of a head containing sense organs and a brain to process the sensory information.<ref name="Brusca 2016">{{cite book |last=Brusca |first=Richard C. |url=http://www.sinauer.com/media/wysiwyg/samples/Brusca3e_Chapter_9.pdf |chapter=Introduction to the Bilateria and the Phylum Xenacoelomorpha: Triploblasty and Bilateral Symmetry Provide New Avenues for Animal Radiation |title=Invertebrates |date=2016 |publisher=[[Sinauer Associates]] |pages=345–372 |isbn=978-1605353753}}</ref>


Vertebrates have a tubular [[Gastrointestinal tract|gut]] that extends from the [[mouth]] to the [[anus]]. The vertebral column typically continues beyond the anus to form an elongated <!--post-anal--> [[tail]].<ref name="Handrigan 2003">{{cite journal |last=Handrigan |first=Gregory R. |title=Concordia discors: duality in the origin of the vertebrate tail |journal=[[Journal of Anatomy]] |volume=202 |issue=Pt 3 |date=2003 |pmid=12713266 |pmc=1571085 |doi=10.1046/j.1469-7580.2003.00163.x |doi-access=free |pages=255–267}}</ref><ref name="Holland 2015">{{cite journal |last=Holland |first=Nicholas D. |last2=Holland |first2=Linda Z. |last3=Holland |first3=Peter W. H. |title=Scenarios for the making of vertebrates |journal=[[Nature (journal)|Nature]] |volume=520 |issue=7548 |date=23 April 2015 |doi=10.1038/nature14433 |pages=450–455}}</ref><ref name="Hejnol 2015">{{cite journal |last=Hejnol |first=Andreas |last2=Martín-Durán |first2=José M. |title=Getting to the bottom of anal evolution |journal=Zoologischer Anzeiger - A Journal of Comparative Zoology |volume=256 |date=2015 |doi=10.1016/j.jcz.2015.02.006 |doi-access=free |pages=61–74|hdl=1956/10848 |hdl-access=free }}</ref>
Vertebrates have a tubular [[Gastrointestinal tract|gut]] that extends from the [[mouth]] to the [[anus]]. The vertebral column typically continues beyond the anus to form an elongated <!--post-anal--> [[tail]].<ref name="Handrigan 2003">{{cite journal |last=Handrigan |first=Gregory R. |title=Concordia discors: duality in the origin of the vertebrate tail |journal=[[Journal of Anatomy]] |volume=202 |issue=Pt 3 |date=2003 |pmid=12713266 |pmc=1571085 |doi=10.1046/j.1469-7580.2003.00163.x |doi-access=free |pages=255–267}}</ref><ref name="Holland 2015">{{cite journal |last1=Holland |first1=Nicholas D. |last2=Holland |first2=Linda Z. |last3=Holland |first3=Peter W. H. |title=Scenarios for the making of vertebrates |journal=[[Nature (journal)|Nature]] |volume=520 |issue=7548 |date=23 April 2015 |doi=10.1038/nature14433 |pages=450–455|pmid=25903626 |bibcode=2015Natur.520..450H }}</ref><ref name="Hejnol 2015">{{cite journal |last1=Hejnol |first1=Andreas |last2=Martín-Durán |first2=José M. |title=Getting to the bottom of anal evolution |journal=Zoologischer Anzeiger - A Journal of Comparative Zoology |volume=256 |date=2015 |doi=10.1016/j.jcz.2015.02.006 |doi-access=free |pages=61–74|bibcode=2015ZooAn.256...61H |hdl=1956/10848 |hdl-access=free }}</ref>


[[File:Gills (esox).jpg|thumb|upright=0.8|[[Branchial arch]]es bearing [[gill]]s in a [[northern pike|pike]] ]]
[[File:Gills (esox).jpg|thumb|upright=0.8|[[Branchial arch]]es bearing [[gill]]s in a [[northern pike|pike]] ]]


The ancestral<!--basal--> vertebrates, and most extant species, are [[aquatic animal|aquatic]] and carry out [[gas exchange]] in their gills. The gills are finely-branched structures which bring the blood close to the water. They are positioned just behind the head, supported by cartilaginous or bony [[branchial arch]]es.<ref>{{cite book |last=Scott |first=T. |title=Concise encyclopedia biology |year=1996 |publisher=[[De Gruyter]] |isbn=978-3-11-010661-9 |page=[https://archive.org/details/conciseencyclope00scot/page/542 542] |url-access=registration |url=https://archive.org/details/conciseencyclope00scot/page/542}}</ref> In [[jawed vertebrate]]s, the first gill arch pair evolved into the jaws.<ref>{{cite journal |title=Fossil evidence for a pharyngeal origin of the vertebrate pectoral girdle |first1=Martin D. |last1=Brazeau |first2=Marco |last2=Castiello |first3=Amin |last3=El Fassi El Fehri |first4=Louis |last4=Hamilton |first5=Alexander O. |last5=Ivanov |first6=Zerina |last6=Johanson |first7=Matt |last7=Friedman |display-authors=5 |date=20 November 2023 |journal=[[Nature (journal)|Nature]] |volume=623 |issue=7987 |pages=550–554 |doi=10.1038/s41586-023-06702-4 |bibcode=2023Natur.623..550B |doi-access=free |pmid=37914937 |pmc=10651482 |hdl=10044/1/107350 |hdl-access=free}}</ref> In [[amphibian]]s and some primitive bony fishes, the larvae have [[external gills]], branching off from the gill arches.<ref>{{cite journal |last=Szarski |first=Henryk |journal=The American Naturalist |year=1957 |volume=91 |issue=860 |pages=283–301 |title=The Origin of the Larva and Metamorphosis in Amphibia |jstor=2458911 |doi=10.1086/281990 |s2cid=85231736 }}</ref> [[Oxygen]] is carried from the gills to the body in the [[blood]], and [[carbon dioxide]] is returned to the gills, in a closed [[circulatory system]] driven by a chambered [[heart]].<ref>{{cite journal |last1=Simões-Costa |first1=Marcos S. |last2=Vasconcelos |first2=Michelle |last3=Sampaio |first3=Allysson C. |last4=Cravo |first4=Roberta M. |last5=Linhares |first5=Vania L. |last6=Hochgreb |first6=Tatiana |last7=Yan |first7=Chao Y.I. |last8=Davidson |first8=Brad |last9=Xavier-Neto |first9=José |display-authors=5 |title=The evolutionary origin of cardiac chambers |year=2005 |journal=[[Developmental Biology (journal)|Developmental Biology]] |volume=277 |issue=1 |pages=1–15 |doi=10.1016/j.ydbio.2004.09.026 |pmid=15572135}}</ref> The [[tetrapod]]s have lost the gills of their fish ancestors; they have adapted the [[swim bladder]] (that fish use for buoyancy) into [[lung]]s to breathe air, and the circulatory system is adapted accordingly.<ref name=Gaining_ground/> At the same time, they adapted the bony fins of the [[Sarcopterygii|lobe-finned fishes]] into two pairs of walking [[leg]]s, carrying the weight of the body via the [[appendicular skeleton|shoulder and pelvic girdles]].<ref name=Gaining_ground>{{cite book |last=Clack |first=J. A. |chapter=From Fins to Feet: Transformation and Transition |year=2002 |title=Gaining ground: the origin and evolution of tetrapods |publisher=[[Indiana University Press]] |pages=187–260}}</ref>  
The ancestral<!--basal--> vertebrates, and most extant species, are [[aquatic animal|aquatic]] and carry out [[gas exchange]] in their gills. The gills are finely-branched structures which bring the blood close to the water. They are positioned just behind the head, supported by cartilaginous or bony [[branchial arch]]es.<ref>{{cite book |last=Scott |first=T. |title=Concise encyclopedia biology |year=1996 |publisher=[[De Gruyter]] |isbn=978-3-11-010661-9 |page=[https://archive.org/details/conciseencyclope00scot/page/542 542] |url-access=registration |url=https://archive.org/details/conciseencyclope00scot/page/542}}</ref> In [[jawed vertebrate]]s, the first gill arch pair evolved into the jaws.<ref>{{cite journal |title=Fossil evidence for a pharyngeal origin of the vertebrate pectoral girdle |first1=Martin D. |last1=Brazeau |first2=Marco |last2=Castiello |first3=Amin |last3=El Fassi El Fehri |first4=Louis |last4=Hamilton |first5=Alexander O. |last5=Ivanov |first6=Zerina |last6=Johanson |first7=Matt |last7=Friedman |display-authors=5 |date=20 November 2023 |journal=[[Nature (journal)|Nature]] |volume=623 |issue=7987 |pages=550–554 |doi=10.1038/s41586-023-06702-4 |bibcode=2023Natur.623..550B |doi-access=free |pmid=37914937 |pmc=10651482 |hdl=10044/1/107350 |hdl-access=free}}</ref> In [[amphibian]]s and some primitive bony fishes, the larvae have [[external gills]], branching off from the gill arches.<ref>{{cite journal |last=Szarski |first=Henryk |journal=The American Naturalist |year=1957 |volume=91 |issue=860 |pages=283–301 |title=The Origin of the Larva and Metamorphosis in Amphibia |jstor=2458911 |doi=10.1086/281990 |bibcode=1957ANat...91..283S |s2cid=85231736 }}</ref> [[Oxygen]] is carried from the gills to the body in the [[blood]], and [[carbon dioxide]] is returned to the gills, in a closed [[circulatory system]] driven by a chambered [[heart]].<ref>{{cite journal |last1=Simões-Costa |first1=Marcos S. |last2=Vasconcelos |first2=Michelle |last3=Sampaio |first3=Allysson C. |last4=Cravo |first4=Roberta M. |last5=Linhares |first5=Vania L. |last6=Hochgreb |first6=Tatiana |last7=Yan |first7=Chao Y.I. |last8=Davidson |first8=Brad |last9=Xavier-Neto |first9=José |display-authors=5 |title=The evolutionary origin of cardiac chambers |year=2005 |journal=[[Developmental Biology (journal)|Developmental Biology]] |volume=277 |issue=1 |pages=1–15 |doi=10.1016/j.ydbio.2004.09.026 |pmid=15572135}}</ref> The [[tetrapod]]s have lost the gills of their fish ancestors; they have adapted the [[swim bladder]] (that fish use for buoyancy) into [[lung]]s to breathe air, and the circulatory system is adapted accordingly.<ref name=Gaining_ground/> At the same time, they adapted the bony fins of the [[Sarcopterygii|lobe-finned fishes]] into two pairs of walking [[leg]]s, carrying the weight of the body via the [[appendicular skeleton|shoulder and pelvic girdles]].<ref name=Gaining_ground>{{cite book |last=Clack |first=J. A. |chapter=From Fins to Feet: Transformation and Transition |year=2002 |title=Gaining ground: the origin and evolution of tetrapods |publisher=[[Indiana University Press]] |pages=187–260}}</ref>  


Vertebrates vary in size from the smallest [[frog]] species such as ''[[Brachycephalus pulex]]'', with a minimum adult [[snout–vent length]] of {{convert|6.45|mm|in}}<ref name="smallest_vertebrate">{{Cite journal |last1=Bolaños |first1=Wendy H. |last2=Dias |first2=Iuri Ribeiro |last3=Solé |first3=Mirco |date=2024-02-07 |title=Zooming in on amphibians: Which is the smallest vertebrate in the world? |url=https://onlinelibrary.wiley.com/doi/10.1111/zsc.12654 |journal=[[Zoologica Scripta]] |volume=53 |issue=4 |pages=414–418 |doi=10.1111/zsc.12654 |s2cid=267599475|url-access=subscription }}</ref> to the [[blue whale]], at up to {{convert|33|m|ft|abbr=on}} and weighing some 150 tonnes.<ref>{{cite web |last1=Chamary |first1=J.V. |title=How large can animals grow? |url=https://www.discoverwildlife.com/animal-facts/how-big-or-small-could-animals-get |website=[[BBC]] Discover Wildlife |access-date=29 November 2024 |date=6 June 2024}}</ref>
Vertebrates vary in size from the smallest [[frog]] species such as ''[[Brachycephalus pulex]]'', with a minimum adult [[snout–vent length]] of {{convert|6.45|mm|in}}<ref name="smallest_vertebrate">{{Cite journal |last1=Bolaños |first1=Wendy H. |last2=Dias |first2=Iuri Ribeiro |last3=Solé |first3=Mirco |date=2024-02-07 |title=Zooming in on amphibians: Which is the smallest vertebrate in the world? |url=https://onlinelibrary.wiley.com/doi/10.1111/zsc.12654 |journal=[[Zoologica Scripta]] |volume=53 |issue=4 |pages=414–418 |doi=10.1111/zsc.12654 |s2cid=267599475|url-access=subscription }}</ref> to the [[blue whale]], at up to {{convert|33|m|ft|abbr=on}} and weighing some 150 tonnes.<ref>{{cite web |last1=Chamary |first1=J.V. |title=How large can animals grow? |url=https://www.discoverwildlife.com/animal-facts/how-big-or-small-could-animals-get |website=[[BBC]] Discover Wildlife |access-date=29 November 2024 |date=6 June 2024}}</ref>
Line 63: Line 63:
[[File:Haikouichthys cropped.jpg|thumb|upright=0.9|The [[Cambrian]] ''[[Haikouichthys]]'', 518 [[myr|mya]]<ref name="Shu 2003"/>]]
[[File:Haikouichthys cropped.jpg|thumb|upright=0.9|The [[Cambrian]] ''[[Haikouichthys]]'', 518 [[myr|mya]]<ref name="Shu 2003"/>]]


Vertebrates originated during the [[Cambrian explosion]] at the start of the Paleozoic, which saw a rise in animal diversity. The earliest known vertebrates belong to the [[Chengjiang biota]]<ref name="Shu1999">{{cite journal |last1=Shu |first1=D-G. |last2=Luo |first2=H-L. |last3=Conway Morris |first3=S. |author3-link=Simon Conway Morris |last4=Zhang |first4=X-L. |last5=Hu |first5=S-X. |last6=Chen |first6=L. |last7=Han |first7=J. |last8=Zhu |first8=M. |last9=Li |first9=Y. |last10=Chen |first10=L-Z. |display-authors=5 |title=Lower Cambrian vertebrates from south China |journal=[[Nature (journal)|Nature]] |volume=402 |issue=6757 |year=1999 |pages=42–46 |doi=10.1038/46965 |bibcode=1999Natur.402...42S |s2cid=4402854 }}</ref> and lived about 518 million years ago.<ref name="Yang2018"/> These include ''[[Haikouichthys]]'', ''[[Myllokunmingia]]'',<ref name="Shu1999"/> ''[[Zhongjianichthys]]'',<ref name="Shu 2003">{{cite journal |last=Shu |first=D. |date=2003 |title=A paleontological perspective of vertebrate origin |journal=[[Chinese Science Bulletin]] |volume=48 |issue=8 |pages=725–735 |doi=10.1360/03wd0026}}</ref> and probably ''[[Yunnanozoon]]''.<ref>{{cite journal |last1=Chen |first1=J.-Y. |last2=Huang |first2=D.-Y. |last3=Li |first3=C.-W. |year=1999 |title=An early Cambrian craniate-like chordate |journal=[[Nature (journal)|Nature]] |volume=402 |issue=6761|pages=518–522 |doi=10.1038/990080 |bibcode=1999Natur.402..518C |s2cid=24895681 }}</ref> Unlike other Cambrian animals, these groups had the basic vertebrate body plan: a notochord, rudimentary vertebrae, and a well-defined head and tail, but lacked jaws.<ref>{{cite web |last=Waggoner |first=B. |title=Vertebrates: Fossil Record |url=http://www.ucmp.berkeley.edu/vertebrates/vertfr.html |publisher=[[University of California Museum of Paleontology]] |access-date=15 July 2011 |archive-url=https://web.archive.org/web/20110629070158/http://www.ucmp.berkeley.edu/vertebrates/vertfr.html |archive-date=29 June 2011 |url-status=dead}}</ref> A vertebrate group of uncertain phylogeny, small eel-like [[conodont]]s, are known from [[microfossil]]s of their paired tooth segments from the late Cambrian to the end of the Triassic.<ref>{{cite journal |doi=10.1111/j.1469-185X.1999.tb00045.x |last1=Donoghue |first1=P. C. J. |last2=Forey |first2=P. L. |last3=Aldridge |first3=R. J. |date=May 2000 |title=Conodont affinity and chordate phylogeny |journal=[[Biological Reviews]] |volume=75 |issue=2 |pages=191–251 |pmid=10881388 |s2cid=22803015 }}</ref> Zoologists have debated whether teeth [[Mineralized tissues|mineralized]] first, given the hard teeth of the soft-bodied conodonts, and then bones, or vice versa, but it seems that the mineralized skeleton came first.<ref name="Murdock Dong 2013">{{cite journal |last=Murdock |first=Duncan J. E. |last2=Dong |first2=Xi-Ping |last3=Repetski |first3=John E. |last4=Marone |first4=Federica |last5=Stampanoni |first5=Marco |last6=Donoghue |first6=Philip C. J. |display-authors=5 |title=The origin of conodonts and of vertebrate mineralized skeletons |journal=Nature |volume=502 |issue=7472 |date=2013 |doi=10.1038/nature12645 |pages=546–549}}</ref>
Vertebrates originated during the [[Cambrian explosion]] at the start of the Paleozoic, which saw a rise in animal diversity. The earliest known vertebrates belong to the [[Chengjiang biota]]<ref name="Shu1999">{{cite journal |last1=Shu |first1=D-G. |last2=Luo |first2=H-L. |last3=Conway Morris |first3=S. |author3-link=Simon Conway Morris |last4=Zhang |first4=X-L. |last5=Hu |first5=S-X. |last6=Chen |first6=L. |last7=Han |first7=J. |last8=Zhu |first8=M. |last9=Li |first9=Y. |last10=Chen |first10=L-Z. |display-authors=5 |title=Lower Cambrian vertebrates from south China |journal=[[Nature (journal)|Nature]] |volume=402 |issue=6757 |year=1999 |pages=42–46 |doi=10.1038/46965 |bibcode=1999Natur.402...42S |s2cid=4402854 }}</ref> and lived about 518 million years ago.<ref name="Yang2018"/> These include ''[[Haikouichthys]]'', ''[[Myllokunmingia]]'',<ref name="Shu1999"/> ''[[Zhongjianichthys]]'',<ref name="Shu 2003">{{cite journal |last=Shu |first=D. |date=2003 |title=A paleontological perspective of vertebrate origin |journal=[[Chinese Science Bulletin]] |volume=48 |issue=8 |pages=725–735 |doi=10.1360/03wd0026|doi-broken-date=29 June 2025 }}</ref> and probably ''[[Yunnanozoon]]''.<ref>{{cite journal |last1=Chen |first1=J.-Y. |last2=Huang |first2=D.-Y. |last3=Li |first3=C.-W. |year=1999 |title=An early Cambrian craniate-like chordate |journal=[[Nature (journal)|Nature]] |volume=402 |issue=6761|pages=518–522 |doi=10.1038/990080 |bibcode=1999Natur.402..518C |s2cid=24895681 }}</ref> Unlike other Cambrian animals, these groups had the basic vertebrate body plan: a notochord, rudimentary vertebrae, and a well-defined head and tail, but lacked jaws.<ref>{{cite web |last=Waggoner |first=B. |title=Vertebrates: Fossil Record |url=http://www.ucmp.berkeley.edu/vertebrates/vertfr.html |publisher=[[University of California Museum of Paleontology]] |access-date=15 July 2011 |archive-url=https://web.archive.org/web/20110629070158/http://www.ucmp.berkeley.edu/vertebrates/vertfr.html |archive-date=29 June 2011 |url-status=dead}}</ref> A vertebrate group of uncertain phylogeny, small eel-like [[conodont]]s, are known from [[microfossil]]s of their paired tooth segments from the late Cambrian to the end of the Triassic.<ref>{{cite journal |doi=10.1111/j.1469-185X.1999.tb00045.x |last1=Donoghue |first1=P. C. J. |last2=Forey |first2=P. L. |last3=Aldridge |first3=R. J. |date=May 2000 |title=Conodont affinity and chordate phylogeny |journal=[[Biological Reviews]] |volume=75 |issue=2 |pages=191–251 |pmid=10881388 |s2cid=22803015 }}</ref> Zoologists have debated whether teeth [[Mineralized tissues|mineralized]] first, given the hard teeth of the soft-bodied conodonts, and then bones, or vice versa, but it seems that the mineralized skeleton came first.<ref name="Murdock Dong 2013">{{cite journal |last1=Murdock |first1=Duncan J. E. |last2=Dong |first2=Xi-Ping |last3=Repetski |first3=John E. |last4=Marone |first4=Federica |last5=Stampanoni |first5=Marco |last6=Donoghue |first6=Philip C. J. |display-authors=5 |title=The origin of conodonts and of vertebrate mineralized skeletons |journal=Nature |volume=502 |issue=7472 |date=2013 |doi=10.1038/nature12645 |pages=546–549|pmid=24132236 |bibcode=2013Natur.502..546M }}</ref>


=== Paleozoic: from fish to amphibians ===
=== Paleozoic: from fish to amphibians ===
Line 95: Line 95:
[[File:Fish evolution.png|thumb|upright=1.35|[[Biodiversity|Diversity]] of various groups of vertebrates through the [[geologic ages]]. The width of the bubbles signifies the number of [[family (biology)|families]].]]
[[File:Fish evolution.png|thumb|upright=1.35|[[Biodiversity|Diversity]] of various groups of vertebrates through the [[geologic ages]]. The width of the bubbles signifies the number of [[family (biology)|families]].]]


Conventional [[evolutionary taxonomy]] groups [[extant taxon|extant]] vertebrates into seven classes based on traditional interpretations of gross [[anatomy|anatomical]] and [[Physiology|physiological]] traits. The commonly held classification lists three classes of fish and four of [[tetrapod]]s.<ref name="Campbell">{{cite book |last=Campbell |first=Neil A. |title=Biology |date=1997 |edition=4th |publisher=[[Benjamin Cummings]] |isbn=978-0-8053-1940-8 |page=632}}</ref> This ignores some of the natural relationships between the groupings. For example, the birds derive from a group of reptiles, so "[[Reptile|Reptilia]]" excluding "[[Aves]]" is not [[Clade|a natural grouping]]; it is described as [[paraphyletic]].<ref>{{cite journal |last=Farris |first=James S. |title=Formal definitions of paraphyly and polyphyly |journal=Systematic Zoology |volume=23 |issue=4 |year=1974 |pages=548-554 |jstor=2412474 |doi=10.2307/2412474}}</ref><ref>{{cite journal |last=Rieppel |first=Olivier |title=Monophyly, paraphyly, and natural kinds |journal=Biology and Philosophy |issue=20 |year=2005 |pages=465-487 |doi=10.1007/s10539-004-0679-z |quote=Something had therefore to be done about the term 'Reptilia.' It could no longer be considered to designate a natural (monophyletic) group without including birds, but only to designate an artificial (non-monophyletic) group}}</ref>
Conventional [[evolutionary taxonomy]] groups [[extant taxon|extant]] vertebrates into seven classes based on traditional interpretations of gross [[anatomy|anatomical]] and [[Physiology|physiological]] traits. The commonly held classification lists three classes of fish and four of [[tetrapod]]s.<ref name="Campbell">{{cite book |last=Campbell |first=Neil A. |title=Biology |date=1997 |edition=4th |publisher=[[Benjamin Cummings]] |isbn=978-0-8053-1940-8 |page=632}}</ref> This ignores some of the natural relationships between the groupings. For example, the birds derive from a group of reptiles, so "[[Reptile|Reptilia]]" excluding "[[Aves]]" is not [[Clade|a natural grouping]]; it is described as [[paraphyletic]].<ref>{{cite journal |last=Farris |first=James S. |title=Formal definitions of paraphyly and polyphyly |journal=Systematic Zoology |volume=23 |issue=4 |year=1974 |pages=548–554 |jstor=2412474 |doi=10.2307/2412474}}</ref><ref>{{cite journal |last=Rieppel |first=Olivier |title=Monophyly, paraphyly, and natural kinds |journal=Biology and Philosophy |issue=2–3 |year=2005 |volume=20 |pages=465–487 |doi=10.1007/s10539-004-0679-z |quote=Something had therefore to be done about the term 'Reptilia.' It could no longer be considered to designate a natural (monophyletic) group without including birds, but only to designate an artificial (non-monophyletic) group}}</ref>


* '''Subphylum Vertebrata'''
* '''Subphylum Vertebrata'''

Revision as of 00:17, 30 June 2025

Template:Short description Template:Good article Template:Use dmy dates Template:Automatic taxobox

Vertebrates (Template:IPAc-en)[1] are animals with a vertebral column (backbone or spine), and a cranium, or skull. The vertebral column surrounds and protects the spinal cord, while the cranium protects the brain.

The vertebrates make up the subphylum Vertebrata with some 65,000 species, by far the largest ranked grouping in the phylum Chordata. The vertebrates include mammals, birds, amphibians, and various classes of fish and reptiles. The fish include the jawless Agnatha, and the jawed Gnathostomata. The jawed fish include both the cartilaginous fish and the bony fish. Bony fish include the lobe-finned fish, which gave rise to the tetrapods, the animals with four limbs. Despite their success, vertebrates still only make up less than five percent of all described animal species.

The first vertebrates appeared in the Cambrian explosion some 518 million years ago. Jawed vertebrates evolved in the Ordovician, followed by bony fishes in the Devonian. The first amphibians appeared on land in the Carboniferous. During the Triassic, mammals and dinosaurs appeared, the latter giving rise to birds in the Jurassic. Extant species are roughly equally divided between fishes of all kinds, and tetrapods. Populations of many species have been in steep decline since 1970 because of land-use change, overexploitation of natural resources, climate change, pollution and the impact of invasive species.

Characteristics

Unique features

Vertebrates belong to Chordata, a phylum characterised by five synapomorphies (unique characteristics): namely a notochord, a hollow nerve cord along the back, an endostyle (often as a thyroid gland), and pharyngeal gills arranged in pairs. Vertebrates share these characteristics with other chordates.[2]

Vertebrates are distinguished from all other animals, including other chordates, by multiple synapomorphies: namely the vertebral column, skull of bone or cartilage, large brain divided into 3 or more sections, a muscular heart with multiple chambers; an inner ear with semicircular canals; sense organs including eyes, ears, and nose; and digestive organs including intestine, liver, pancreas, and stomach.[3]

Physical

Script error: No such module "Labelled list hatnote".

File:Vertebrate body plan.svg
Idealised vertebrate body plan, showing key characteristics

Vertebrates (and other chordates) belong to the Bilateria, a group of animals with mirror symmetrical bodies.[4] They move, typically by swimming, using muscles along the back, supported by a strong but flexible skeletal structure, the spine or vertebral column.[5] The name 'vertebrate' derives from the Latin Script error: No such module "Lang"., 'jointed',[6] from vertebra, 'joint', in turn from Latin Script error: No such module "Lang"., 'to turn'.[7]

File:Naturkundemuseum Berlin - Dinosaurierhalle.jpg
Fossilized skeleton (cast) of Diplodocus carnegii, showing an extreme example of the vertebral column that gives the vertebrates their name. The species is a tetrapod, its four legs adapting the fish-like body plan for walking on land. The specimen is Template:Cvt long.

As embryos, vertebrates still have a notochord; as adults, all but the jawless fishes have a vertebral column, made of bone or cartilage, instead.[5] Vertebrate embryos have pharyngeal arches; in adult fish, these support the gills, while in adult tetrapods they develop into other structures.[8][9]

In the embryo, a layer of cells along the back folds and fuses into a hollow neural tube.[10] This develops into the spinal cord, and at its front end, the brain.[10] The brain receives information about the world through nerves which carry signals from sense organs in the skin and body.[11] Because the ancestors of vertebrates usually moved forwards, the front of the body encountered stimuli before the rest of the body, favouring cephalisation, the evolution of a head containing sense organs and a brain to process the sensory information.[12]

Vertebrates have a tubular gut that extends from the mouth to the anus. The vertebral column typically continues beyond the anus to form an elongated tail.[13][14][15]

File:Gills (esox).jpg
Branchial arches bearing gills in a pike

The ancestral vertebrates, and most extant species, are aquatic and carry out gas exchange in their gills. The gills are finely-branched structures which bring the blood close to the water. They are positioned just behind the head, supported by cartilaginous or bony branchial arches.[16] In jawed vertebrates, the first gill arch pair evolved into the jaws.[17] In amphibians and some primitive bony fishes, the larvae have external gills, branching off from the gill arches.[18] Oxygen is carried from the gills to the body in the blood, and carbon dioxide is returned to the gills, in a closed circulatory system driven by a chambered heart.[19] The tetrapods have lost the gills of their fish ancestors; they have adapted the swim bladder (that fish use for buoyancy) into lungs to breathe air, and the circulatory system is adapted accordingly.[20] At the same time, they adapted the bony fins of the lobe-finned fishes into two pairs of walking legs, carrying the weight of the body via the shoulder and pelvic girdles.[20]

Vertebrates vary in size from the smallest frog species such as Brachycephalus pulex, with a minimum adult snout–vent length of Template:Convert[21] to the blue whale, at up to Template:Convert and weighing some 150 tonnes.[22]

Molecular

Molecular markers known as conserved signature indels in protein sequences have been identified and provide distinguishing criteria for the vertebrate subphylum.[23] Five molecular markers are exclusively shared by all vertebrates and reliably distinguish them from all other animals; these include protein synthesis elongation factor-2, eukaryotic translation initiation factor 3, adenosine kinase and a protein related to ubiquitin carboxyl-terminal hydrolase).[23] A specific relationship between vertebrates and tunicates is supported by two molecular markers, the proteins Rrp44 (associated with the exosome complex) and serine C-palmitoyltransferase. These are exclusively shared by species from these two subphyla, but not by cephalochordates.[23]

Evolutionary history

Cambrian explosion: first vertebrates

Script error: No such module "labelled list hatnote".

File:Haikouichthys cropped.jpg
The Cambrian Haikouichthys, 518 mya[24]

Vertebrates originated during the Cambrian explosion at the start of the Paleozoic, which saw a rise in animal diversity. The earliest known vertebrates belong to the Chengjiang biota[25] and lived about 518 million years ago.[26] These include Haikouichthys, Myllokunmingia,[25] Zhongjianichthys,[24] and probably Yunnanozoon.[27] Unlike other Cambrian animals, these groups had the basic vertebrate body plan: a notochord, rudimentary vertebrae, and a well-defined head and tail, but lacked jaws.[28] A vertebrate group of uncertain phylogeny, small eel-like conodonts, are known from microfossils of their paired tooth segments from the late Cambrian to the end of the Triassic.[29] Zoologists have debated whether teeth mineralized first, given the hard teeth of the soft-bodied conodonts, and then bones, or vice versa, but it seems that the mineralized skeleton came first.[30]

Paleozoic: from fish to amphibians

Script error: No such module "Labelled list hatnote".

File:Acanthostega BW.jpg
Acanthostega, a Devonian labyrinthodont, Template:Circa 365 mya[31]

The first jawed vertebrates may have appeared in the late Ordovician (~445 mya) and became common in the Devonian period, often known as the "Age of Fishes".[32] The two groups of bony fishes, Actinopterygii and Sarcopterygii, evolved and became common.[33] By the middle of the Devonian, a lineage of sarcopterygii with both gills and air-breathing lungs adapted to life in swampy pools used their muscular paired fins to propel themselves on land.[34] The fins, already possessing bones and joints, evolved into two pairs of walking legs.[35] These established themselves as amphibians, terrestrial tetrapods, in the next geological period, the Carboniferous.[36] A group of vertebrates, the amniotes, with membranes around the embryo allowing it to survive on dry land, branched from amphibious tetrapods in the Carboniferous.[37]

Mesozoic: from reptiles to mammals and birds

File:Hyperodapedon BW2 white background.jpg
Hyperodapedon, a diapsid reptile of the Triassic, Template:Circa 230 mya

At the onset of the Mesozoic, all larger vertebrate groups were devastated after the largest mass extinction in earth history. The following recovery phase saw the emergence of many new vertebrate groups that are still around today, and this time has been described as the origin of modern ecosystems. On the continents, the ancestors of modern lissamphibians, turtles, crocodilians, lizards, and mammals appeared, as well as dinosaurs, which gave rise to birds later in the Mesozoic. In the seas, various groups of marine reptiles evolved, as did new groups of fish.[37] At the end of the Mesozoic, another extinction event extirpated dinosaurs (other than birds) and many other vertebrate groups.[38]

Cenozoic: Age of Mammals

File:Fossil bird (Green River Formation, Lower Eocene; Fossil Lake Basin, southwestern Wyoming, USA) (15529177925).jpg
Nahmavis, an Eocene bird, Template:Circa 50 mya

The Cenozoic, the current era, is sometimes called the "Age of Mammals", because of the dominance of the terrestrial environment by that group. Placental mammals have predominantly occupied the Northern Hemisphere, with marsupial mammals in the Southern Hemisphere.[39][40]

Approaches to classification

Taxonomic history

In 1811, Jean-Baptiste Lamarck defined the vertebrates as a taxonomic group,[41] a phylum distinct from the invertebrates he was studying.[42] He described them as consisting of four classes, namely fish, reptiles, birds, and mammals,[43] but treated the cephalochordates and tunicates as molluscs.[42] In 1866, Ernst Haeckel called both his "Craniata" (vertebrates) and his "Acrania" (cephalochordates) "Vertebrata".[42] In 1877, Ray Lankester grouped the Craniates, cephalochordates, and "Urochordates (tunicates) as "Vertebrata".[42] In 1880–1881, Francis Maitland Balfour placed the Vertebrata as a subphylum within the Chordates.[42] In 2018, Naoki Irie and colleagues proposed making Vertebrata a full phylum.[42]

Traditional taxonomy

File:Fish evolution.png
Diversity of various groups of vertebrates through the geologic ages. The width of the bubbles signifies the number of families.

Conventional evolutionary taxonomy groups extant vertebrates into seven classes based on traditional interpretations of gross anatomical and physiological traits. The commonly held classification lists three classes of fish and four of tetrapods.[44] This ignores some of the natural relationships between the groupings. For example, the birds derive from a group of reptiles, so "Reptilia" excluding "Aves" is not a natural grouping; it is described as paraphyletic.[45][46]

In addition to these, there are two classes of extinct armoured fishes, Placodermi and Acanthodii, both paraphyletic.

Other ways of classifying the vertebrates have been devised, particularly with emphasis on the phylogeny of early amphibians and reptiles. An example based on work by M.J. Benton in 2004[47] is given here († = extinct):

While this traditional taxonomy is orderly, most of the groups are paraphyletic, meaning that the structure does not accurately reflect the natural evolved grouping.[47] For instance, descendants of the first reptiles include modern reptiles, mammals and birds; the agnathans have given rise to the jawed vertebrates; the bony fishes have given rise to the land vertebrates; a group of amphibians, the labyrinthodonts, have given rise to the reptiles (traditionally including the mammal-like synapsids), which in turn have given rise to the mammals and birds. Most scientists working with vertebrates use a classification based purely on phylogeny, organized by their known evolutionary history.[42]

External phylogeny

The closest relatives of vertebrates have been debated over the years. It was once thought that the Cephalochordata was the sister taxon to Vertebrata. This group, Notochordata, was taken to be sister to the Tunicata.[48] Since 2006, analysis has shown that the tunicates + vertebrates form a clade, the Olfactores, with Cephalochordata as its sister (the Olfactores hypothesis), as shown in the following phylogenetic tree.[49][50][23]

Template:Clade

Internal phylogeny

The internal phylogeny of the vertebrates is shown in the below tree.[51]

Template:Clade

The placement of hagfishes within the vertebrates has been controversial. Their lack of proper vertebrae (among other characteristics of jawless lampreys and jawed vertebrates) led authors of phylogenetic analyses based on morphology to place them outside Vertebrata.[52] Molecular data however indicates that they are vertebrates, being most closely related to lampreys.[53][54] An older view is that they are a sister group of vertebrates in the common taxon of Craniata.[55] In 2019, Tetsuto Miyashita and colleagues reconciled the two types of analysis, supporting the Cyclostomata hypothesis using only morphological data.[56]

Template:Clade

Diversity

Species by group

Described and extant vertebrate species are split roughly evenly but non-phylogenetically between non-tetrapod "fish" and tetrapods. The following table lists the number of described extant species for each vertebrate class as estimated in the IUCN Red List of Threatened Species, 2014.3.[57] Paraphyletic groups are shown in quotation marks.

Vertebrate groups Image Class Estimated number of
described species[57][58] 		Group
totals[57]
Anamniote

lack
amniotic
membrane
so need to
reproduce
in water 		Jawless "Fish" File:Eptatretus polytrema.jpg Myxini
(hagfish) 		78 >32,900
File:Eudontomyzon danfordi Tiszai ingola.jpg Hyperoartia
(lampreys) 		40
Jawed File:Shark fish chondrichthyes.jpg Chondrichthyes >1,100
File:Carassius wild golden fish 2013 G1.jpg Actinopterygii >32,000
File:Coelacanth-bgiu.png "Sarcopterygii" 8
Tetrapods File:Lithobates pipiens.jpg Amphibia 7,302 33,278
Amniote

have
amniotic
membrane
adapted to
reproducing
on land 		File:Erpétologie générale, ou, Histoire naturelle complète des reptiles (Morenia ocellata).jpg "Reptilia" 10,711
File:Bruno Liljefors - Hare studies 1885 white background.jpg Mammalia 5,513
File:Cuvier-97-Canard colvert.jpg Aves

(birds)

10,425
Total described species 66,178

The IUCN estimates that 1,305,075 extant invertebrate species have been described,[57] which means that less than 5% of the described animal species in the world are vertebrates.[59]

Population trends

The Living Planet Index, following 16,704 populations of 4,005 species of vertebrates, shows a decline of 60% between 1970 and 2014.[60] Since 1970, freshwater species declined 83%, and tropical populations in South and Central America declined 89%.[61] The authors note that "An average trend in population change is not an average of total numbers of animals lost."[61] According to WWF, this could lead to a sixth major extinction event.[62] The five main causes of biodiversity loss are land-use change, overexploitation of natural resources, climate change, pollution and invasive species.[63]

Notes

Template:Notelist

See also

References

Template:Reflist

Bibliography

  • Script error: No such module "citation/CS1".
  • Script error: No such module "template wrapper".

External links

Template:Sister project

Template:Animalia Template:Chordata Template:Portal bar

Template:Taxonbar Template:Authority control

  1. Template:Cite Dictionary.com
  2. Script error: No such module "citation/CS1".
  3. Script error: No such module "citation/CS1".
  4. Script error: No such module "citation/CS1".
  5. a b Script error: No such module "citation/CS1".
  6. Script error: No such module "citation/CS1".
  7. Script error: No such module "citation/CS1".
  8. Script error: No such module "Citation/CS1".
  9. Script error: No such module "Citation/CS1".
  10. a b Script error: No such module "Citation/CS1".
  11. Script error: No such module "citation/CS1".
  12. Script error: No such module "citation/CS1".
  13. Script error: No such module "Citation/CS1".
  14. Script error: No such module "Citation/CS1".
  15. Script error: No such module "Citation/CS1".
  16. Script error: No such module "citation/CS1".
  17. Script error: No such module "Citation/CS1".
  18. Script error: No such module "Citation/CS1".
  19. Script error: No such module "Citation/CS1".
  20. a b Script error: No such module "citation/CS1".
  21. Script error: No such module "Citation/CS1".
  22. Script error: No such module "citation/CS1".
  23. a b c d Script error: No such module "Citation/CS1".
  24. a b Script error: No such module "Citation/CS1".
  25. a b Script error: No such module "Citation/CS1".
  26. Cite error: Invalid <ref> tag; no text was provided for refs named Yang2018
  27. Script error: No such module "Citation/CS1".
  28. Script error: No such module "citation/CS1".
  29. Script error: No such module "Citation/CS1".
  30. Script error: No such module "Citation/CS1".
  31. Script error: No such module "citation/CS1".
  32. Script error: No such module "citation/CS1".
  33. Script error: No such module "citation/CS1".
  34. Script error: No such module "citation/CS1".
  35. Script error: No such module "Citation/CS1".
  36. Script error: No such module "citation/CS1".
  37. a b Script error: No such module "citation/CS1".
  38. Script error: No such module "citation/CS1".
  39. Script error: No such module "Citation/CS1".
  40. Script error: No such module "Citation/CS1".
  41. Cite error: Invalid <ref> tag; no text was provided for refs named Nielsen2012
  42. a b c d e f g Script error: No such module "Citation/CS1".
  43. Script error: No such module "citation/CS1".
  44. Script error: No such module "citation/CS1".
  45. Script error: No such module "Citation/CS1".
  46. Script error: No such module "Citation/CS1".
  47. a b Script error: No such module "citation/CS1".
  48. Script error: No such module "Citation/CS1".
  49. Script error: No such module "Citation/CS1".
  50. Script error: No such module "Citation/CS1".
  51. Script error: No such module "citation/CS1".
  52. Script error: No such module "Citation/CS1".
  53. Script error: No such module "Citation/CS1".
  54. Script error: No such module "Citation/CS1".
  55. Script error: No such module "Citation/CS1".
  56. Script error: No such module "Citation/CS1".
  57. a b c d The World Conservation Union. 2014. IUCN Red List of Threatened Species, 2014.3. Summary Statistics for Globally Threatened Species. Table 1: Numbers of threatened species by major groups of organisms (1996–2014).
  58. Script error: No such module "citation/CS1".
  59. Script error: No such module "Citation/CS1".
  60. Script error: No such module "citation/CS1".
  61. a b Script error: No such module "citation/CS1".
  62. Template:Cite magazine
  63. Script error: No such module "citation/CS1".
Retrieved from "http://debianws.lexgopc.com/wiki143/index.php?title=Vertebrate&oldid=729169"