Lungfish#Extant lungfish

Dipnoi is Modern Latin derived from the Greek δίπνοος (dipnoos) with two breathing structures, from δι- twice and πνοή breathing, breath.

All lungfish demonstrate an uninterrupted cartilaginous notochord and an extensively developed palatal dentition. Basal ("primitive") lungfish groups may retain marginal teeth and an ossified braincase, but derived lungfish groups, including all modern species, show a significant reduction in the marginal bones and a cartilaginous braincase. The bones of the skull roof in primitive lungfish are covered in a mineralized tissue called cosmine, but in post-Devonian lungfishes, the skull roof lies beneath the skin and the cosmine covering is lost. All modern lungfish show significant reductions and fusions of the bones of the skull roof, and the specific bones of the skull roof show no homology to the skull roof bones of ray-finned fishes or tetrapods. During the breeding season, the South American lungfish develops a pair of feathery appendages that are actually highly modified pelvic fins. These fins are thought to improve gas exchange around the fish's eggs in its nest.{{cite book |author-link=Ross Piper |author=Piper, Ross |year=2007 |title=Extraordinary Animals: An encyclopedia of curious and unusual animals |publisher=Greenwood Press}}

Through convergent evolution, lungfishes have evolved internal nostrils similar to the tetrapods' choana,{{cite news |url=http://scienceweek.com/2004/sa041224-3.htm |title=Evolution: On the evolution of internal nostrils (choanae) |website=Science-Week |access-date=23 September 2011 |archive-url=https://web.archive.org/web/20120320190643/http://scienceweek.com/2004/sa041224-3.htm |archive-date=20 March 2012 |url-status=dead }} and a brain with certain similarities to Lissamphibian brain (except for the Queensland lungfish, which branched off in its own direction about 277 million years ago and has a brain resembling that of the Latimeria).{{cite journal |title=The first virtual cranial endocast of a lungfish ( sarcopterygii: dipnoi ) |journal=PLOS ONE |id=10.1371 |doi=10.1371/journal.pone.0113898 |volume=9 |year=2014 |page=e113898 |author=Clement Alice M| issue=11 |doi-access=free |pmid=25427173 |pmc=4245222 |bibcode=2014PLoSO...9k3898C }} 50px Text was copied from this source, which is available under a [https://creativecommons.org/licenses/by/4.0/ Creative Commons Attribution 4.0 International License].

The dentition of lungfish is different from that of any other vertebrate group. "Odontodes" on the palate and lower jaws develop in a series of rows to form a fan-shaped occlusion surface. These odontodes then wear to form a uniform crushing surface. In several groups, including the modern lepidosireniformes, these ridges have been modified to form occluding blades.

The modern lungfishes have a number of larval features, which suggest paedomorphosis. They also demonstrate the largest genome among the vertebrates.

Modern lungfish all have an elongate body with fleshy, paired pectoral and pelvic fins and a single unpaired caudal fin replacing the dorsal, caudal and anal fins of most fishes.

Image:Lungs of Protopterus dolloi.JPG (Protopterus dolloi)]]

Lungfish have a highly specialized respiratory system. They have a distinct feature in that their lungs are connected to the larynx and pharynx without a trachea. While other species of fish can breathe air using modified, vascularized gas bladders,{{citation |title=Did lungs and the intracardiac shunt evolve to oxygenate the heart in vertebrates |author=Colleen Farmer |journal=Paleobiology |year=1997 |volume=23 |issue=3 |pages=358–372 |url=http://www.biology.utah.edu/farmer/publications%20pdf/1997%20Paleobiology23.pdf |url-status=dead |archive-url=https://web.archive.org/web/20100611170942/http://www.biology.utah.edu/farmer/publications%20pdf/1997%20Paleobiology23.pdf |archive-date=11 June 2010 | doi = 10.1017/s0094837300019734 |s2cid=87285937 }} these bladders are usually simple sacs, devoid of complex internal structure. In contrast, the lungs of lungfish are subdivided into numerous smaller air sacs, maximizing the surface area available for gas exchange.

Most extant lungfish species have two lungs, with the exception of the Australian lungfish, which has only one. The lungs of lungfish are homologous to the lungs of tetrapods. As in tetrapods and bichirs, the lungs extend from the ventral surface of the esophagus and gut.{{cite book |chapter-url=http://cwx.prenhall.com/bookbind/pubbooks/martini10/chapter24/custom2/deluxe-content.html |title=Human Anatomy |first=Brian |last=Wisenden |chapter=Chapter 24: The Respiratory System – Evolution Atlas |archive-url=https://web.archive.org/web/20101125095303/http://cwx.prenhall.com/bookbind/pubbooks/martini10/chapter24/custom2/deluxe-content.html |archive-date=25 November 2010 |publisher=Pearson Education, Inc |year=2003}}{{cite web |url=http://people.biology.ufl.edu/sahilber/VertZooLab2007/Lab2.htm |url-status=dead |id=Lab 2 |author=Hilber, S.A. |title=Gnathostome form & function |series=Vertebrate Zoology Lab |year=2007 |publisher=U. Florida |access-date=31 December 2010 |archive-url=https://web.archive.org/web/20110720083608/http://people.biology.ufl.edu/sahilber/VertZooLab2007/Lab2.htm |archive-date=20 July 2011 }}

Of extant lungfish, only the Australian lungfish can breathe through its gills without needing air from its lung. In other species, the gills are too atrophied to allow for adequate gas exchange. When a lungfish is obtaining oxygen from its gills, its circulatory system is configured similarly to the common fish. The spiral valve of the conus arteriosus is open, the bypass arterioles of the third and fourth gill arches (which do not actually have gills) are shut, the second, fifth and sixth gill arch arterioles are open, the ductus arteriosus branching off the sixth arteriole is open, and the pulmonary arteries are closed. As the water passes through the gills, the lungfish uses a buccal pump. Flow through the mouth and gills is unidirectional. Blood flow through the secondary lamellae is countercurrent to the water, maintaining a more constant concentration gradient.

When breathing air, the spiral valve of the conus arteriosus closes (minimizing the mixing of oxygenated and deoxygenated blood), the third and fourth gill arches open, the second and fifth gill arches close (minimizing the possible loss of the oxygen obtained in the lungs through the gills), the sixth arteriole's ductus arteriosus is closed, and the pulmonary arteries open. Importantly, during air breathing, the sixth gill is still used in respiration; deoxygenated blood loses some of its carbon dioxide as it passes through the gill before reaching the lung. This is because carbon dioxide is more soluble in water. Air flow through the mouth is tidal, and through the lungs it is bidirectional and observes "uniform pool" diffusion of oxygen.

Lungfish are omnivorous, feeding on fish, insects, crustaceans, worms, mollusks, amphibians and plant matter. They have an intestinal spiral valve rather than a true stomach.{{cite journal |doi=10.1002/ar.1091820109 |volume=182 |title=Electron microscopy of the intestine of the African lungfish, Protopterus aethiopicus |year=1975 |journal=The Anatomical Record |pages=71–89 |author=Purkerson, M.L.|issue=1 |pmid=1155792 |s2cid=44787314 }}

African and South American lungfish are capable of surviving seasonal drying out of their habitats by burrowing into mud and estivating throughout the dry season. Changes in physiology allow it to slow its metabolism to as little as one sixtieth of the normal metabolic rate, and protein waste is converted from ammonia to less-toxic urea (normally, lungfish excrete nitrogenous waste as ammonia directly into the water).

Burrowing is seen in at least one group of fossil lungfish, the Gnathorhizidae.

File:Granddad, Shedd Aquarium, Chicago.jpg

Lungfish can be extremely long-lived. A Queensland lungfish called "Granddad" at the Shedd Aquarium in Chicago was part of the permanent live collection from 1933 to 2017 after a previous residence at the Sydney Aquarium; at 109 years old,{{Cite web |last=CSIRO |title=DNA reveals the true age of Granddad the lungfish |url=https://www.csiro.au/en/news/all/articles/2022/june/granddad-lungfish |access-date=2024-11-26 |website=www.csiro.au |language=en}} it was euthanized following a decline in health consistent with old age.{{cite news |url=http://www.startribune.com/chicago-aquarium-euthanizes-more-than-90-year-old-lungfish/412918113/|title=Chicago aquarium euthanizes 90 year-old lungfish |access-date=6 February 2017 |archive-url=https://web.archive.org/web/20170207031540/http://www.startribune.com/chicago-aquarium-euthanizes-more-than-90-year-old-lungfish/412918113/ |archive-date=7 February 2017 |newspaper=Star Tribune |url-status=dead}}

As of 2022, the oldest lungfish, and probably the oldest aquarium fish in the world is "Methuselah", an Australian lungfish {{convert|4|ft}} long and weighing around {{convert|40|lb}}. Methuselah is believed to be female, unlike its namesake, and is estimated to be over 90 years old.{{cite news |url=https://www.theguardian.com/us-news/2022/jan/26/methuselah-oldest-aquarium-fish-lives-san-francisco |title=Methuselah: Oldest aquarium fish lives in San Francisco and likes belly rubs |newspaper=The Guardian |date=26 January 2022 }}

About 420 million years ago, during the Devonian, the last common ancestor of lungfish and tetrapods split into two separate evolutionary lineages, with the ancestor of the extant coelacanths diverging a little earlier from a sarcopterygian progenitor.[https://www.newscientist.com/article/2265127-australian-lungfish-has-largest-genome-of-any-animal-sequenced-so-far/ Australian lungfish has largest genome of any animal sequenced so far - New Scientist] Youngolepis and Diabolepis, dating to 419–417 million years ago, during Early Devonian (Lochkovian), are the currently oldest known lungfish, and show that the lungfishes had adapted to a diet including hard-shelled prey (durophagy) very early in their evolution.{{Cite journal |last1=Cui |first1=Xindong |last2=Friedman |first2=Matt |last3=Qiao |first3=Tuo |last4=Yu |first4=Yilun |last5=Zhu |first5=Min |date=2022-05-02 |title=The rapid evolution of lungfish durophagy |journal=Nature Communications |language=en |volume=13 |issue=1 |pages=2390 |doi=10.1038/s41467-022-30091-3 |pmid=35501345 |pmc=9061808 |issn=2041-1723}} The earliest lungfish were marine. Almost all post-Carboniferous lungfish inhabit or inhabited freshwater environments. There were likely at least two transitions amongst lungfish from marine to freshwater habitats. The last common ancestor of all living lungfish likely lived sometime between the Late Carboniferous and the Jurassic.{{Cite journal |last=Brownstein |first=Chase Doran |last2=Harrington |first2=Richard C |last3=Near |first3=Thomas J. |date=July 2023 |title=The biogeography of extant lungfishes traces the breakup of Gondwana |url=https://onlinelibrary.wiley.com/doi/10.1111/jbi.14609 |journal=Journal of Biogeography |language=en |volume=50 |issue=7 |pages=1191–1198 |doi=10.1111/jbi.14609 |issn=0305-0270}} Lungfish remained present in the northern Laurasian landmasses into the Cretaceous period.{{Cite journal |last1=Frederickson |first1=Joseph A. |last2=Cifelli |first2=Richard L. |date=January 2017 |title=New Cretaceous lungfishes (Dipnoi, Ceratodontidae) from western North America |journal=Journal of Paleontology |language=en |volume=91 |issue=1 |pages=146–161 |doi=10.1017/jpa.2016.131 |s2cid=131962612 |issn=0022-3360|doi-access=free }}

Lungfish and Convergent Evolution

Lungfish (Dipnoi) are a group of lobe-finned fishes that have undergone significant evolutionary adaptations, particularly in their respiratory, locomotor, and neurological systems. Through convergent evolution, lungfish have developed traits similar to those of early tetrapods, including air-breathing lungs, internal nostrils functionally analogous to choanae, and tetrapod-like locomotion. Additionally, certain brain structures and jaw-opening muscles in lungfish resemble those found in amphibians, suggesting functional convergence despite phylogenetic distance.

Evolution of Air-Breathing Lungs

The development of lungs in lungfish mirrors the pulmonary structures of early tetrapods. Lungfish lungs, which are derived from the swim bladder (an organ typically used for buoyancy in most bony fishes), are directly connected to the alimentary tract and lined with a dense network of blood vessels within honeycomb-like cavities. This anatomical specialization enables efficient gas exchange, a crucial adaptation for survival in freshwater environments prone to hypoxia (low oxygen levels).

Internal Nostrils and Convergent Traits with Tetrapods

Lungfish have evolved internal nostrils, enabling them to breathe air through nasal passages. These structures are functionally analogous to the choanae in tetrapods and are believed to have evolved independently in both groups, an example of convergent evolution.

Tetrapod-Like Locomotion and Skeletal Adaptations

Some species, such as the West African lungfish (Protopterus annectens), exhibit movement patterns that resemble those of early terrestrial vertebrates. Lungfish can propel themselves along a substrate using fin-supported, elongated bodies, sometimes lifting themselves in a quadrupedal fashion. This behavior suggests that certain locomotor features may have predated the full evolution of tetrapod limbs.

Furthermore, the synchronized rotation of the pectoral girdle and cranial rib, along with muscle shortening during buccal expansion, indicates that lungfish had preadaptations for air breathing requiring minimal morphological changes.

Neurological and Sensory Convergence

Neurological studies of the African lungfish (Protopterus) reveal structural and functional similarities to amphibians, especially in regions associated with cognitive and sensory processing. Despite their phylogenetic separation, these parallels may reflect convergent evolution in neural architecture.

Jaw-Opening Muscles and Functional Convergence

The South American (Lepidosiren) and African lungfish species possess a jaw-opening muscle that is topographically and functionally similar to the depressor mandibulae of salamanders. Although this suggests potential homology, the absence of this muscle in the Australian lungfish (Neoceratodus forsteri) and its absence in fossil records of primitive lungfishes support the idea that the muscle evolved independently in lepidosirenids. Differences in embryonic development between this muscle in lungfish and salamanders further support this conclusion.

Evolutionary History of Lungfish

The lineage of lungfish dates back to the Devonian period (~382–359 million years ago), with fossil genera such as Scaumenacia and Phaneropleuron displaying early morphological adaptations. These include a reduced first dorsal fin and a second dorsal fin that shifted toward the tail. By the Permian, lungfish evolved a more continuous fin structure along the dorsal, caudal, and anal regions, a feature that persists in modern species.

Locomotor behavior observed in fossil and living lungfish suggests that walking and bounding behaviors may have originated in sarcopterygian fishes before the evolution of true tetrapods. Protopterus annectens can lift its body using its fins, propelling itself across surfaces in a quadrupedal, and occasionally bipedal, manner.

Molecular and Genomic Insights into Lungfish Evolution

Molecular and genomic studies reveal that lungfish diverged from other lobe-finned fishes over 400 million years ago. The Australian lungfish (Neoceratodus forsteri) retains many primitive traits, making it especially valuable for evolutionary research.

The genome of the African lungfish (Protopterus annectens) is one of the largest known among vertebrates, approximately 40 billion base pairs, largely due to the accumulation of transposable elements. Despite its size, the lungfish genome maintains efficient transcription mechanisms that ensure proper gene expression.

File:Barramunda.jpg

The Queensland lungfish, Neoceratodus forsteri, is endemic to Australia.{{cite book |last=Lake |first=John S. |title=Australian Freshwater Fishes |series=Nelson Field Guides |place=Melbourne |publisher=Thomas Nelson Australia Pty. Ltd. |year=1978 |page=12}} Fossil records of this group date back 380 million years, around the time when the higher vertebrate classes were beginning to evolve.{{cite book |last1=Allen |first1=G.R. |first2=S.H. |last2=Midgley |first3=M. |last3=Allen |title=Field Guide to the Freshwater Fishes of Australia. |editor1-first=Jan |editor1-last=Knight |editor2-first=Wendy |editor2-last=Bulgin |place=Perth, W.A. |publisher=Western Australia Museum |year=2002 |pages=54–55}} Fossils of lungfish belonging to the genus Neoceratodus have been uncovered in northern New South Wales, indicating that the Queensland lungfish has existed in Australia for at least 100 million years, making it a living fossil and one of the oldest living vertebrate genera on the planet.{{Cite journal|last1=Kemp|first1=Anne|last2=Berrell|first2=Rodney|date=2020-05-03|title=A New Species of Fossil Lungfish (Osteichthyes: Dipnoi) from the Cretaceous of Australia|url=https://www.tandfonline.com/doi/full/10.1080/02724634.2020.1822369|journal=Journal of Vertebrate Paleontology|language=en|volume=40|issue=3|pages=e1822369|doi=10.1080/02724634.2020.1822369|s2cid=225133051|issn=0272-4634}} It is the most primitive surviving member of the ancient air-breathing lungfish (Dipnoi) lineages.{{cite journal |author1=Frentiu, F.D. |author2=Ovenden, J.R. |author3=Street, R. |title=Australian lungfish (Neoceratodus forsteri: Dipnoi) have low genetic variation at allozyme and mitochondrial DNA loci: A conservation alert? |series=2 |journal=Conservation Genetics |date=2001 |doi=10.1023/A:1011576116472 |pages=63–67 |volume=2|s2cid=22778872 }} The five other freshwater lungfish species, four in Africa and one in South America, are very different morphologically to N. forsteri. The Queensland lungfish can live for several days out of the water if it is kept moist, but will not survive total water depletion, unlike its African counterparts.

File:F de Castelnau-poissonsPl50.jpg

The South American lungfish, Lepidosiren paradoxa, is the single species of lungfish found in swamps and slow-moving waters of the Amazon, Paraguay, and lower Paraná River basins in South America. Notable as an obligate air-breather, it is the sole member of its family native to the Americas. Relatively little is known about the South American lungfish.{{cite book |author1=Haeckel, Ernst Heinrich Philipp August |url=https://archive.org/details/TheHistoryOfCreationOrTheDevelopmentOfTheEarthAndItsInhabitants_126 |title=The History of Creation, or, the Development of the Earth and Its Inhabitants by the Action of Natural Causes |author2=Lankester, Edwin Ray |author3=Schmitz, L. Dora |publisher=D. Appleton |year=1892 |pages=289, 422 |quote=A popular exposition of the doctrine of evolution in general, and of that of Darwin, Goethe, and Lamarck in particular. From the 8th German edition by Ernst Haeckel |author1-link=Ernst Haeckel}} When immature it is spotted with gold on a black background. In the adult this fades to a brown or gray color.{{cite web |url=http://animal-world.com/encyclo/fresh/Misc_PseudoBony/SouthAmericanLungfish.php |title=South American Lungfish |publisher=Animal World}} Its tooth-bearing premaxillary and maxillary bones are fused like other lungfish. South American lungfishes also share an autostylic jaw suspension (where the palatoquadrate is fused to the cranium) and powerful adductor jaw muscles with the extant lungfish (Dipnoi). Like the African lungfishes, this species has an elongate, almost eel-like body. It may reach a length of {{convert|125|cm|ftin}}. The pectoral fins are thin and threadlike, while the pelvic fins are somewhat larger, and set far back. The fins are connected to the shoulder by a single bone, which is a marked difference from most fish, whose fins usually have at least four bones at their base; and a marked similarity with nearly all land-dwelling vertebrates."Your Inner Fish" Neil Shubin, 2008,2009,Vintage, p.33 They have the lowest aquatic respiration of all extant lungfish species,[https://pubmed.ncbi.nlm.nih.gov/11691604/ The differential cardio-respiratory responses to ambient hypoxia and systemic hypoxaemia in the South American lungfish, Lepidosiren paradoxa] and their gills are greatly reduced and essentially non-functional in the adults.{{cite book |editor=Paxton, J.R. |editor2=Eschmeyer, W.N.|author= Bruton, Michael N.|year=1998|title=Encyclopedia of Fishes|publisher= Academic Press|location=San Diego|page= 70|isbn= 978-0-12-547665-2}}

File:Marbled lungfish 1.jpg

The marbled lungfish, Protopterus aethiopicus, is found in Africa. The marbled lungfish is smooth and elongated with deeply embedded scales, and (starting from the head end) is cylindrical for much of its length. The tail is very long and tapers at the end. They are the largest of the African lungfish species as they can reach a length of up to 200 cm.[http://www.fishbase.org/Summary/SpeciesSummary.php?id=8734 Fishbase.org] The pectoral and pelvic fins are also very long and thin, almost spaghetti-like. The newly hatched young have branched external gills much like those of newts. After 2 to 3 months the young transform (called metamorphosis) into the adult form, losing the external gills for gill openings. These fish have a yellowish gray or pinkish toned ground color with dark slate-gray splotches, creating a marbling or leopard effect over the body and fins. The color pattern is darker along the top and lighter below.{{cite web|url=http://animal-world.com/encyclo/fresh/Misc_PseudoBony/LeopardLungfish.php|title=Marbled Lungfish|author=Animal-World|work=Animal World}} The marbled lungfish's genome contains 133 billion base pairs, making it the largest known genome of any vertebrate. The only organisms known to have more base pairs are the protist Polychaos dubium and the flowering plant Paris japonica at 670 billion and 150 billion, respectively.{{cite journal | author = IJ Leitch | date = 13 June 2007 | title = Genome sizes through the ages | journal = Heredity | volume = 99 | pages = 121–122 | publisher = Nature Publishing Group | issn = 0018-067X | doi = 10.1038/sj.hdy.6800981 | pmid = 17565357 | issue=2| s2cid = 5406138 }}

File:Protopterus amphibius.png

The gilled lungfish, Protopterus amphibius is a species of lungfish found in East Africa.[http://www.eol.org/pages/217169 EOL.org] (Retrieved 19 February 2010.)[http://www.fishbase.org/summary/Speciessummary.php?id=8735 Fishbase.org] (Retrieved 19 February 2010.) It generally reaches only {{convert|44|cm|in|0|abbr=off}} long, making it the smallest extant lungfish in the world.[http://www.primitivefishes.com/Gilled%20African%20Lungfish.htm Primitive Fishes.com] {{webarchive|url=https://web.archive.org/web/20081211022858/http://www.primitivefishes.com/Gilled%20African%20Lungfish.htm |date=11 December 2008 }} Retrieved 19 February 2010. This lungfish is uniform blue, or slate grey in colour. It has small or inconspicuous black spots, and a pale grey belly.[http://www.fishbase.org/summary/Speciessummary.php?id=8735 Fishbase.org] (Retrieved 25 September 2010.)

File:LepidosirenFord.jpg

The west African lungfish, Protopterus annectens, is a species of lungfish found in West Africa.[http://www.eol.org/pages/217169 EOL.org] (Retrieved 13 May 2010.)[http://www.fishbase.org/summary/Speciessummary.php?id=8735 Fishbase.org] (Retrieved 13 May 2010.){{cite web|url=http://fishbase.org/Summary/SpeciesSummary.php?id=2384|title=Protopterus annectens, West African lungfish : fisheries, aquaculture|work=FishBase}} It has a prominent snout and small eyes. Its body is long and eel-like, some 9–15 times the length of the head. It has two pairs of long, filamentous fins. The pectoral fins have a basal fringe and are about three times the head length, while its pelvic fins are about twice the head length. In general, three external gills are inserted posterior to the gill slits and above the pectoral fins. It has cycloid scales embedded in the skin. There are 40–50 scales between the operculum and the anus and 36–40 around the body before the origin of the dorsal fin. It has 34–37 pairs of ribs. The dorsal side is olive or brown in color and the ventral side is lighter, with great blackish or brownish spots on the body and fins except on its belly.{{cite encyclopedia|url=http://www.eol.org/pages/1298995?text_id=6652736|title=West African Lungfish (Protopterus annectens annectens) - Information on West African Lungfish - Encyclopedia of Life|encyclopedia=Encyclopedia of Life}}{{Dead link|date=March 2020 |bot=InternetArchiveBot |fix-attempted=yes }} They reach a length of about 100 cm in the wild.[http://www.primitivefishes.com/pannectens.htm Primitivefishes.com (Retrieved May 13, 2010.)] {{webarchive|url=https://web.archive.org/web/20101011104325/http://www.primitivefishes.com/pannectens.htm |date=11 October 2010 }}

File:Protopterus dolloi Boulenger2.jpg

The spotted lungfish, Protopterus dolloi, is a species of lungfish found in Africa. Specifically, it is found in the Kouilou-Niari Basin of the Republic of the Congo and Ogowe River basin in Gabon. It is also found in the lower and Middle Congo River Basins.[http://www.fishbase.org/summary/speciessummary.php?id=8736 Fishbase.org] Protopterus dolloi can aestivate on land by surrounding itself in a layer of dried mucus.Brien, P. (1959). Ethologie du Protopterus dolloi(Boulenger) et de ses larves. Signification des sacs pulmonaires des Dipneustes. Ann. Soc. R. Zool. Belg. 89, 9–48.Poll, M. (1961). Révision systématique et raciation géographique des Protopteridae de l’Afrique centrale. Ann. Mus. R. Afr. Centr. Sér. 8. Sci. Zool. 103, 3–50. It can reach a length of up to 130 cm.

{{Clear}}

File:Ceratodus.jpg by Heinrich Harder]]

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The relationship of lungfishes to the rest of the bony fish is well understood:

• Lungfishes are most closely related to Powichthys, and then to the Porolepiformes.
• Together, these taxa form the Dipnomorpha, the sister group to the Tetrapodomorpha.
• Together, these form the Rhipidistia, the sister group to the coelacanths.

Recent molecular genetic analyses strongly support a sister relationship of lungfishes and tetrapods (Rhipidistia), with coelacanths branching slightly earlier.{{cite journal |title=The African coelacanth genome provides insights into tetrapod evolution |journal=Nature |date=18 April 2013 |doi=10.1038/nature12027 |pmid=23598338 |volume=496 |issue=7445 |pages=311–316 |pmc=3633110 |last1=Amemiya |first1=Chris T. |last2=Alföldi |first2=Jessica |last3=Lee |first3=Alison P. |last4=Fan |first4=Shaohua |last5=Philippe |first5=Hervé |last6=MacCallum |first6=Iain |last7=Braasch |first7=Ingo |last8=Manousaki |first8=Tereza |last9=Schneider |first9=Igor |last10=Rohner |first10=Nicolas |last11=Organ |first11=Chris |last12=Chalopin | first12 = Domitille | last13 = Smith |first13=Jeramiah J. |last14=Robinson |first14=Mark |last15=Dorrington |first15=Rosemary A. |last16=Gerdol |first16=Marco |last17=Aken |first17=Bronwen |last18=Biscotti |first18=Maria Assunta |last19=Barucca |first19=Marco |last20=Baurain |first20=Denis |last21=Berlin |first21=Aaron M. |last22=Blatch |first22=Gregory L. |last23=Buonocore |first23=Francesco |last24=Burmester |first24=Thorsten |last25=Campbell |first25=Michael S. |last26=Canapa |first26=Adriana |last27=Cannon |first27=John P. |last28=Christoffels |first28=Alan |last29=De Moro |first29=Gianluca |last30=Edkins |first30=Adrienne L. |bibcode=2013Natur.496..311A |display-authors=6}}{{cite journal |author1=Takezaki, N. |author2=Nishihara, H. |year=2017 |title=Support for lungfish as the closest relative of tetrapods by using slowly evolving ray-finned fish as the outgroup |journal=Genome Biology and Evolution |volume=9 |issue=1 |pages=93–101 |doi=10.1093/gbe/evw288 |pmid=28082606 |pmc=5381532}}

The relationships among lungfishes are significantly more difficult to resolve. While Devonian lungfish had enough bone in the skull to determine relationships, post-Devonian lungfish are represented entirely by skull roofs and teeth, as the rest of the skull is cartilaginous. Additionally, many of the taxa already identified may not be monophyletic.

Phylogeny after Kemp, Cavin & Guinot, 2017

{{Clade|{{Clade

|1=†Diabolepis

|2={{Clade

|1={{Clade

|1=†Westollrhynchus

|2={{Clade

|1=†Ichnomylax

|2={{Clade

|1=†Dipnorhynchus

|2=†Speonesydrion

}} }} }}

|2={{Clade

|1=†Uranolophus

|2={{Clade

|1=†Stomiahykus

|2={{Clade

|1={{Clade

|1=†Iowadipterus

|2=†Jessenia

}}

|2={{Clade

|1=†Melanognathus

|2=†Tarachomylax

|3={{Clade

|1=†Dipterus

|2={{Clade

|1=†Adololopas

|2={{Clade

|1={{Clade

|1={{Clade

|1=†Chirodipterus australis

|2=†Gogodipterus

}}

|2={{Clade

|1=†Pillararhynchus

|2=†Sorbitorhynchus

}} }}

|2={{Clade

|1=†Chirodipterus liangchengi

|2={{Clade

|1=†Chirodipterus wildungensis

|2={{Clade

|1=†Sinodipterus

|2={{Clade

|1=†Rhinodipterus ulrichi

|2={{Clade

|1={{Clade

|1=†Soederberghia

|2={{Clade

|1=†Griphognathus

|2=†Holodipterus

}} }}

|2={{Clade

|1={{Clade

|1=†Andreyevichthys

|2={{Clade

|1=†Scaumenacia

|2={{Clade

|1=†Adelargo

|2={{Clade

|1=†Sagenodus

|2={{Clade

|1=†Howidipterus

|2={{Clade

|1=†Barwickia

|2=†Fleurentia

}} }} }} }} }} }}

|2={{Clade

|1=†Orlovichthys

|2={{Clade

|1=†Rhinodipterus kimberleyensis

|2={{Clade

|label2=Ceratodontoidei

|1={{Clade

|1=†Conchopoma

|2=†Ganopristodus

}}

|2={{Clade

|1=†Paraceratodus

|2={{Clade

|1=†Ferganoceratodus

|2={{Clade

|label1=Neoceratodontidae

|1={{Clade

|1=†Mioceratodus

|2=Neoceratodus (Queensland lungfish)

}}

|2={{Clade

|1=†Ceratodus

|2={{Clade

|1={{Clade

|1=†Gosfordia

|2=†Ptychoceratodus

}}

|2={{Clade

|label1=†Gnathorhizidae

|label2=Lepidosirenidae

|1={{Clade

|1=†Gnathorhiza

|2=†Persephonichthys

}}

|2={{Clade

|1=Lepidosiren (South American lungfish)

|2=Protopterus (African lungfish)

}} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }} }}|style=font-size:85%; line-height:85%}}

Cladogram after Brownstein et al. 2023

{{clade

|1={{clade

|1=†Chirodipterus

|2=†Dipterus

}}

|2={{clade

|1={{clade

|1=†Ctenodus

|2=†Sagenodus

}}

|2={{clade

|1={{clade

|1=†Conchopoma

|2=†Ganopristodus

}}

|2={{clade

|1={{clade

|1=†Gnathorhiza

|2=†Persephonichthys

}}

|2={{clade

|1=†Ceratodus

|2={{clade

|1=†Gosfordia

|2={{clade

|1=†Paraceratodus

|2={{clade

|1=†Ptychoceratodus

|2={{clade

|1={{clade

|1=†Ferganoceratodus

|2={{clade

|1=†Mioceratodus

|2=Neoceratodus (Queensland lungfish)

}}}}

|2={{clade

|1=Lepidosiren (South American lungfish)

|2=Protopterus (African lungfish)

}}}}}}}}}}}}}}}}}}|label=}}

• Ceratodus
• Lepidogalaxias salamandroides
• Polypteridae

{{Reflist|25em}}

• {{cite journal |author1=Ahlberg, P.E. |author2=Smith, M.M. |author3=Johanson, Z. |year=2006 |title=Developmental plasticity and disparity in early dipnoan (lungfish) dentitions |journal=Evolution and Development |volume=8 |issue=4 |pages=331–349 |doi=10.1111/j.1525-142x.2006.00106.x|pmid=16805898 |s2cid=28339324 }}
• {{cite encyclopedia |editor=Palmer, Douglas |title=The Simon & Schuster Encyclopedia of Dinosaurs & Prehistoric Creatures, A visual who's who of prehistoric life. |page=45 |place=Great Britain |publisher=Marshall Editions Developments Limited |year=1999}}
• {{cite journal |author1=Schultze, H.P. |author2=Chorn, J. |year=1997 |title=The Permo-Carboniferous genus Sagenodus and the beginning of modern lungfish |journal=Contributions to Zoology |volume=61 |issue=7 |pages=9–70|doi=10.1163/18759866-06701002 |doi-access=free }}
• {{cite journal |last=Sepkoski |first=Jack |title=A compendium of fossil marine animal genera |journal=Bulletins of American Paleontology |volume=364 |page=560 |year=2002 |url=http://strata.ummp.lsa.umich.edu/jack/showgenera.php?taxon=611&rank=class |access-date=17 May 2011 |url-status=dead |archive-url=https://web.archive.org/web/20090220223520/http://strata.ummp.lsa.umich.edu/jack/showgenera.php?taxon=611&rank=class |archive-date=20 February 2009 }}

{{Wikispecies|Dipnoi}}

{{Wikibooks|Dichotomous Key|Dipnoi}}

• {{cite web |url=http://annekempslungfish.com/index.html |archive-url=https://web.archive.org/web/20140802224356/http://annekempslungfish.com/index.html |url-status=dead |archive-date=2014-08-02 |first=Anne, Dr. |last=Kemps |title=Lungfish Information site}}
• {{cite web |url=http://www.palaeos.com/Vertebrates/Units/140Sarcopterygii/140.500.html |archive-url=https://web.archive.org/web/20060313152753/http://www.palaeos.com/Vertebrates/Units/140Sarcopterygii/140.500.html |url-status=dead |archive-date=2006-03-13 |title=Dipnoiformes |website=Palaeos.com}}
• {{cite web |url=http://www.ucmp.berkeley.edu/vertebrates/sarco/dipnoi.html |title=Dipnoi |publisher=University of California Museum of Paleontology}}
• {{cite web |url=http://www.tellapallet.com/tree_of_life.htm |archive-url=https://web.archive.org/web/20090123062500/https://www.tellapallet.com/tree_of_life.htm |title=Tree of life illustration showing lungfish's relation to other organisms |url-status=dead |archive-date=2009-01-23 |website=tellapallet.com}}
• {{cite web |url=https://www.youtube.com/watch?v=D1UKHimLZao | archive-url=https://ghostarchive.org/varchive/youtube/20211118/D1UKHimLZao| archive-date=2021-11-18 | url-status=live|title=Lungfish video |website=YouTube}}{{cbignore}}

{{Chordata}}

{{Sarcopterygii}}

{{Sarcopterygian genera|R.|state=autocollapse}}

{{diversity of fish}}

{{Taxonbar|from=Q168422}}

{{Authority control}}

Category:Articles which contain graphical timelines

Category:Extant Early Devonian first appearances