Biology:Placentalia

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Short description: Infraclass of mammals in the clade Eutheria

Placental mammals
Temporal range: Paleocene-Holocene 66.043–0 Ma
Possible Late Cretaceous record

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Placentals from different orders.
Scientific classification e
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Clade: Eutheria
Infraclass: Placentalia
Owen, 1837
Subgroups

Placental mammals (infraclass Placentalia /plæsənˈtliə/) are one of the three extant subdivisions of the class Mammalia, the other two being Monotremata and Marsupialia. Placentalia contains the vast majority of extant mammals, which are partly distinguished from monotremes and marsupials in that the fetus is carried in the uterus of its mother to a relatively late stage of development. The name is something of a misnomer considering that marsupials also nourish their fetuses via a placenta,[1] though for a relatively briefer period, giving birth to less developed young which are then nurtured for a period inside the mother's pouch. Placentalia represents the only living group within Eutheria, which contains all mammals more closely related to placentals than to marsupials.

Anatomical features

Placental mammals are anatomically distinguished from other mammals by:

  • a sufficiently wide opening at the bottom of the pelvis to allow the birth of a large baby relative to the size of the mother.[2]
  • the absence of epipubic bones extending forward from the pelvis, which are found in all other mammals.[3] (Their function in non-placental mammals is to stiffen the body during locomotion,[3] but in placentals they would inhibit the expansion of the abdomen during pregnancy.)[4]
  • the rearmost bones of the foot fit into a socket formed by the ends of the tibia and fibula, forming a complete mortise and tenon upper ankle joint.[5]
  • the presence of a malleolus at the bottom of the fibula.[5]

Subdivisions

Analysis of molecular data lead to the rapid changes in assessments of the phylogeny of placental orders at the close of the last millennium. A novel phylogeny and classification of placental orders appeared with Waddell, Hasegawa and Okada in 1999.[6] "Jumping Genes" retroposon presence/absence patterns have provided corroboration of phylogenetic relationships inferred from molecular sequences, for example .[7] It is now widely accepted that there are four major subdivisions or lineages of placental mammals: Laurasiatheria+Euarchontoglires=Boreoeutheria, Xenarthra, and Afrotheria.

According to 2022 studies of Bertrand, O. C. and Sarah L. Shelley, palaeoryctids and taeniodonts are identified to be a basal placental mammal.[8][9]

The living orders of placental mammals in the three groups are:[10]

The exact relationships among these three lineages is currently a subject of debate, and four different hypotheses have been proposed with respect to which group is basal or diverged first from other placentals. These hypotheses are Atlantogenata (basal Boreoeutheria), Epitheria (basal Xenarthra), Exafroplacentalia (basal Afrotheria) and a hypothesis supporting a near simultaneous divergence.[11] Estimates for the divergence times among these three placental groups mostly range from 105 to 120 million years ago (MYA), depending on the type of DNA, whether it is translated, and the phylogenetic method (e.g. nuclear or mitochondrial),[12][13] and varying interpretations of paleogeographic data.[11] In addition, a strict molecular clock does not hold, so it is necessary to assume models of how evolutionary rates change along lineages. These assumptions alone can make substantial differences to the relative ages of different mammal groups estimated with genomic data.[14]

Placentalia
Atlantogenata

Xenarthra

Afrotheria

Boreoeutheria
Euarchontoglires

Glires

Euarchonta

Laurasiatheria

Eulipotyphla

Scrotifera

Chiroptera

Ferungulata
Ferae

Pholidota

Carnivora

Euungulata

Perissodactyla

Artiodactyla

Cladogram and classification based on Amrine-Madsen, H. et al. (2003)[15] and Asher, R. J. et al. (2009)[16] Compare with Waddell, Hasegawa and Okada (1999)[6] and Waddell et al. (2001).[12]

Genomics

(As of 2020), the genome has been sequenced for at least one species in each extant placental order and in 83% of families (105 of 127 extant placental families).[17]

See list of sequenced animal genomes.

Evolutionary history

True placental mammals (the crown group including all modern placentals) arose from stem-group members of the clade Eutheria, which had existed since at least the Middle Jurassic period, about 170 mya. These early eutherians were small, nocturnal insect eaters, with adaptations for life in trees.[5]

True placentals may have originated in the Late Cretaceous around 90 mya, but the earliest undisputed fossils are from the early Paleocene, 66 mya, following the Cretaceous–Paleogene extinction event. The species Protungulatum donnae is sometimes placed as a stem-ungulate [18] known 1 meter above the Cretaceous-Paleogene boundary in the geological stratum that marks the Cretaceous–Paleogene extinction event [19] and Purgatorius, sometimes considered a stem-primate, appears no more than 300,000 years after the K-Pg boundary;[20] both species, however, are sometimes placed outside the crown placental group, but many newer studies place them back in eutherians[further explanation needed].[21] The rapid appearance of placentals after the mass extinction at the end of the Cretaceous suggests that the group had already originated and undergone an initial diversification in the Late Cretaceous, as suggested by molecular clocks.[22] The lineages leading to Xenarthra and Afrotheria probably originated around 90 mya, and Boreoeutheria underwent an initial diversification around 70-80 mya,[22] producing the lineages that eventually would lead to modern primates, rodents, insectivores, artiodactyls, and carnivorans.

However, modern members of the placental orders originated in the Paleogene around 66 to 23 mya, following the Cretaceous–Paleogene extinction event. The evolution of crown orders such modern primates, rodents, and carnivores appears to be part of an adaptive radiation[23] that took place as mammals quickly evolved to take advantage of ecological niches that were left open when most dinosaurs and other animals disappeared following the Chicxulub asteroid impact. As they occupied new niches, mammals rapidly increased in body size, and began to take over the large herbivore and large carnivore niches that had been left open by the decimation of the dinosaurs (and perhaps more relevantly competing synapsids[24]). Mammals also exploited niches that the non-avian dinosaurs had never touched: for example, bats evolved flight and echolocation, allowing them to be highly effective nocturnal, aerial insectivores; and whales first occupied freshwater lakes and rivers and then moved into the oceans. Primates, meanwhile, acquired specialized grasping hands and feet which allowed them to grasp branches, and large eyes with keener vision which allowed them to forage in the dark.

The evolution of land placentals followed different pathways on different continents since they cannot easily cross large bodies of water. An exception is smaller placentals such as rodents and primates, who left Laurasia and colonized Africa and then South America via rafting.

In Africa, the Afrotheria underwent a major adaptive radiation, which led to elephants, elephant shrews, tenrecs, golden moles, aardvarks, and manatees. In South America a similar event occurred, with radiation of the Xenarthra, which led to modern sloths, anteaters, and armadillos, as well as the extinct ground sloths and glyptodonts. Expansion in Laurasia was dominated by Boreoeutheria, which includes primates and rodents, insectivores, carnivores, perissodactyls and artiodactyls. These groups expanded beyond a single continent when land bridges formed linking Africa to Eurasia and South America to North America.

A study on eutherian diversity suggests that placental diversity was constrained during the Paleocene, while multituberculate mammals diversified; afterwards, multituberculates decline and placentals explode in diversity.[24]

References

  1. Renfree, M. B. (March 2010). "Review: Marsupials: placental mammals with a difference". Placenta 31 Supplement: S21–6. doi:10.1016/j.placenta.2009.12.023. PMID 20079531. 
  2. Weil, A. (April 2002). "Mammalian evolution: Upwards and onwards". Nature 416 (6883): 798–799. doi:10.1038/416798a. PMID 11976661. Bibcode2002Natur.416..798W. 
  3. 3.0 3.1 Reilly, S. M.; White, T. D. (January 2003). "Hypaxial Motor Patterns and the Function of Epipubic Bones in Primitive Mammals". Science 299 (5605): 400–402. doi:10.1126/science.1074905. PMID 12532019. Bibcode2003Sci...299..400R. 
  4. Novacek, M. J., Rougier, G. W, Wible, J. R., McKenna, M. C, Dashzeveg, D. and Horovitz, I. (October 1997). "Epipubic bones in eutherian mammals from the Late Cretaceous of Mongolia". Nature 389 (6650): 483–486. doi:10.1038/39020. PMID 9333234. Bibcode1997Natur.389..483N. 
  5. 5.0 5.1 5.2 Ji, Q., Luo, Z-X., Yuan, C-X., Wible, J. R., Zhang, J-P. and Georgi, J. A. (April 2002). "The earliest known eutherian mammal". Nature 416 (6883): 816–822. doi:10.1038/416816a. PMID 11976675. Bibcode2002Natur.416..816J. 
  6. 6.0 6.1 Waddell, P. J.; Okada, N.; Hasegawa, M. (1999). "Towards Resolving the Interordinal Relationships of Placental Mammals". Systematic Biology 48 (1): 1–5. 
  7. Kriegs, Jan Ole; Churakov, Gennady; Kiefmann, Martin; Jordan, Ursula; Brosius, Jürgen; Schmitz, Jürgen (2006). "Retroposed Elements as Archives for the Evolutionary History of Placental Mammals". PLOS Biology 4 (4): e91. doi:10.1371/journal.pbio.0040091. PMID 16515367. 
  8. Bertrand, O. C.; Shelley, S. L.; Williamson, T. E.; Wible, J. R.; Chester, S. G. B.; Flynn, J. J.; Holbrook, L. T.; Lyson, T. R. et al. (2022). "Brawn before brains in placental mammals after the end-Cretaceous extinction". Science 376 (6588): 80–85. doi:10.1126/science.abl5584. Bibcode2022Sci...376...80B. https://www.research.ed.ac.uk/en/publications/d7fb8c6e-886e-4c1d-9977-0cd6406fda20. 
  9. Sarah L. Shelley (2022.) "The phylogeny of Paleocene mammals and the evolution of Placentalia", in "The Society of Vertebrate Paleontology 82nd annual meeting"
  10. "Late Cretaceous relatives of rabbits, rodents, and other extant eutherian mammals". Nature 414 (6859): 62–5. November 2001. doi:10.1038/35102048. PMID 11689942. Bibcode2001Natur.414...62A. 
  11. 11.0 11.1 Nishihara, H.; Maruyama, S.; Okada, N. (2009). "Retroposon analysis and recent geological data suggest near-simultaneous divergence of the three superorders of mammals". Proceedings of the National Academy of Sciences 106 (13): 5235–5240. doi:10.1073/pnas.0809297106. PMID 19286970. Bibcode2009PNAS..106.5235N. 
  12. 12.0 12.1 Waddell, P. J.; Kishino, H.; Ota, R. (2001). "A phylogenetic foundation for comparative mammalian genomics". Genome Informatics Series 12: 141–154. 
  13. Springer, Mark S.; Murphy, William J.; Eizirik, Eduardo; O'Brien, Stephen J. (2003). "Placental mammal diversification and the Cretaceous–Tertiary boundary". Proceedings of the National Academy of Sciences 100 (3): 1056–1061. doi:10.1073/pnas.0334222100. PMID 12552136. Bibcode2003PNAS..100.1056S. 
  14. Kitazoe, Y.; Kishino, H.; Waddell, P. J.; Nakajima, T.; Okabayashi, T.; Watabe, T.; Okuhara, Y. (2007). "Robust time estimation reconciles views of the antiquity of placental mammals". PLoS ONE 2 (e384): 1–11. 
  15. Amrine-Madsen, H.; Koepfli, K. P.; Wayne, R. K.; Springer, M. S. (2003). "A new phylogenetic marker, apoliprotein B, provides compelling evidence for eutherian relationships". Molecular Phylogenetics and Evolution 28 (2): 225–240. doi:10.1016/s1055-7903(03)00118-0. PMID 12878460. 
  16. Asher, R. J.; Bennett, N.; Lehmann, T. (2009). "The new framework for understanding placental mammal evolution". BioEssays 31 (8): 853–864. doi:10.1002/bies.200900053. PMID 19582725. 
  17. Zoonomia Consortium (2020) A comparative genomics multitool for scientific discovery and conservation. Nature 587, 240–245
  18. O'Leary, Maureen A.; Bloch, Jonathan I.; Flynn, John J.; Gaudin, Timothy J.; Giallombardo, Andres; Giannini, Norberto P.; Goldberg, Suzann L.; Kraatz, Brian P. et al. (8 February 2013). "The Placental Mammal Ancestor and the Post–K-Pg Radiation of Placentals". Science 339 (6120): 662–667. doi:10.1126/science.1229237. PMID 23393258. Bibcode2013Sci...339..662O. 
  19. Archibald, J.D., 1982. A study of Mammalia and geology across the Cretaceous-Tertiary boundary in Garfield County, Montana. University of California Publications in Geological Sciences 122, 286.
  20. Fox, R. C.; Scott, C. S. (2011). "A new, early Puercan (earliest Paleocene) species of Purgatorius (Plesiadapiformes, Primates) from Saskatchewan, Canada". Journal of Paleontology 85 (3): 537–548. doi:10.1666/10-059.1. Bibcode2011JPal...85..537F. 
  21. Halliday, Thomas J. D. (2015). "Resolving the relationships of Paleocene placental mammals". Biological Reviews 92 (1): 521–550. doi:10.1111/brv.12242. PMID 28075073. 
  22. 22.0 22.1 dos Reis, M.; Inoue, J.; Hasegawa, M.; Asher, R. J.; Donoghue, P. C. J.; Yang, Z. (2012). "Phylogenomic datasets provide both precision and accuracy in estimating the timescale of placental mammal phylogeny". Proceedings of the Royal Society B 279 (1742): 3491–3500. doi:10.1098/rspb.2012.0683. PMID 22628470. 
  23. Alroy, J (1999). "The fossil record of North American Mammals: evidence for a Palaeocene evolutionary radiation". Systematic Biology 48 (1): 107–118. doi:10.1080/106351599260472. PMID 12078635. 
  24. 24.0 24.1 Brocklehurst, Neil; Panciroli, Elsa; Benevento, Gemma Louise; Benson, Roger B.J. (July 2021). "Mammaliaform extinctions as a driver of the morphological radiation of Cenozoic mammals". Current Biology 31 (13): 2955–2963.e4. doi:10.1016/j.cub.2021.04.044. PMID 34004143. https://ora.ox.ac.uk/objects/uuid:bda82407-db76-4c15-b061-ceb9ae271dd5. 

External links

Wikidata ☰ Q25833 entry