Monotreme

Monotremes (/ˈmɒnətrmz/) are prototherian mammals of the order Monotremata. They are one of the three groups of living mammals, along with placentals (Eutheria) and marsupials (Metatheria). Monotremes are typified by structural differences in their brains, jaws, digestive tract, reproductive tract, and other body parts, compared to the more common mammalian types. In addition, they lay eggs rather than bearing live young, but, like all mammals, the female monotremes nurse their young with milk.

Monotremes[1]
Temporal range:
Four of the five extant monotreme species: platypus (top-left), short-beaked echidna (top-right), western long-beaked echidna (bottom-left), and replica eastern long-beaked echidna (bottom-right)
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Monotremata
C.L. Bonaparte, 1837[2]
Subgroups

Monotremes have been considered members of Australosphenida, a clade that contains extinct mammals from the Jurassic and Cretaceous of Madagascar, South America, and Australia, though this is disputed.

The only surviving examples of monotremes are all indigenous to Australia and New Guinea, although there is evidence that they were once more widespread, as Monotrematum is known from the Paleocene of South America.[6] The extant monotreme species are the platypus and four species of echidnas. There is currently some debate regarding monotreme taxonomy.

The name monotreme derives from the Greek words μονός (monós 'single') and τρῆμα (trêma 'hole'), referring to the cloaca.

General characteristics

Like other mammals, monotremes are endothermic with a high metabolic rate (though not as high as other mammals; see below); have hair on their bodies; produce milk through mammary glands to feed their young; have a single bone in their lower jaw; and have three middle-ear bones.

In common with reptiles and marsupials, monotremes lack the connective structure (corpus callosum) which in placental mammals is the primary communication route between the right and left brain hemispheres.[7] The anterior commissure does provide an alternate communication route between the two hemispheres, though, and in monotremes and marsupials it carries all the commissural fibers arising from the neocortex, whereas in placental mammals the anterior commissure carries only some of these fibers.[8]

Long-beaked echidna
Diagram of a monotreme egg. (1) Shell; (2) Yolk; (3) Yolk Sac; (4) Allantois; (5) Embryo; (6) Amniotic Fluid; (7) Amniotic Membrane; and (8) Membrane

Extant monotremes lack teeth as adults. Fossil forms and modern platypus young have a "tribosphenic" form of molars (with the occlusal surface formed by three cusps arranged in a triangle), which is one of the hallmarks of extant mammals. Some recent work suggests that monotremes acquired this form of molar independently of placental mammals and marsupials,[9] although this hypothesis remains disputed.[10] Tooth loss in modern monotremes might be related to their development of electrolocation.[11]

Monotreme jaws are constructed somewhat differently from those of other mammals, and the jaw opening muscle is different. As in all true mammals, the tiny bones that conduct sound to the inner ear are fully incorporated into the skull, rather than lying in the jaw as in cynodonts and other premammalian synapsids; this feature, too, is now claimed to have evolved independently in monotremes and therians,[12] although, as with the analogous evolution of the tribosphenic molar, this hypothesis is disputed.[13][14] Nonetheless, findings on the extinct species Teinolophos confirm that suspended ear bones evolved independently among monotremes and therians.[15] The external opening of the ear still lies at the base of the jaw.

The sequencing of the platypus genome has also provided insight into the evolution of a number of monotreme traits, such as venom and electroreception, as well as showing some new unique features, such as monotremes possessing 5 pairs of sex chromosomes and that one of the X chromosomes resembles the Z chromosome of birds,[16] suggesting that the two sex chromosomes of marsupial and placental mammals evolved after the split from the monotreme lineage.[17] Additional reconstruction through shared genes in sex chromosomes supports this hypothesis of independent evolution.[18] This feature, along with some other genetic similarities with birds, such as shared genes related to egg-laying, is thought to provide some insight into the most recent common ancestor of the synapsid lineage leading to mammals and the sauropsid lineage leading to birds and modern reptiles, which are believed to have split about 315 million years ago during the Carboniferous.[19][20] The presence of vitellogenin genes (a protein necessary for egg shell formation) is shared with birds; the presence of this symplesiomorphy suggests that the common ancestor of monotremes, marsupials, and placental mammals was oviparous, and that this trait was retained in monotremes but lost in all other extant mammal groups. DNA analyses suggest that although this trait is shared and is synapomorphic with birds, platypuses are still mammals and that the common ancestor of extant mammals lactated.[21]

The monotremes also have extra bones in the shoulder girdle, including an interclavicle and coracoid, which are not found in other mammals. Monotremes retain a reptile-like gait, with legs on the sides of, rather than underneath, their bodies. The monotreme leg bears a spur in the ankle region; the spur is not functional in echidnas, but contains a powerful venom in the male platypus. This venom is derived from β-defensins, proteins that are present in mammals that create holes in viral and bacterial pathogens. Some reptile venom is also composed of different types of β-defensins, another trait shared with reptiles.[19] It is thought to be an ancient mammalian characteristic, as many non-monotreme archaic mammal groups also possess venomous spurs.[22]

Reproductive system

The key anatomical difference between monotremes and other mammals gives them their name; monotreme means “single opening” in Greek, referring to the single duct (the cloaca) for their urinary, defecatory, and reproductive systems. Like reptiles, monotremes have a single cloaca. Marsupials have a separate genital tract, whereas most placental mammalian females have separate openings for reproduction (the vagina), urination (the urethra), and defecation (the anus). In monotremes, only semen passes through the penis while urine is excreted through the male's cloaca.[23] The monotreme penis is similar to that of turtles and is covered by a preputial sac.[24][25]

Monotreme eggs are retained for some time within the mother and receive nutrients directly from her, generally hatching within 10 days after being laid — much shorter than the incubation period of sauropsid eggs.[26][27] Much like newborn marsupials (and perhaps all non-placental mammals[28]), newborn monotremes, called "puggles,"[29] are larval- and fetus-like and have relatively well-developed forelimbs that enable them to crawl around. In fact, because monotremes lack nipples, puggles crawl about more frequently than marsupial joeys in search of milk, this difference raising questions about the supposed developmental restrictions on marsupial forelimbs.[30]

Rather than through nipples, monotremes lactate from their mammary glands via openings in their skin. All five extant species show prolonged parental care of their young, with low rates of reproduction and relatively long life-spans.

Monotremes are also noteworthy in their zygotic development: Most mammalian zygotes go through holoblastic cleavage, where the ovum splits into multiple, divisible daughter cells. Contrastingly, monotreme zygotes, like those of birds and reptiles, undergo meroblastic (partial) division. This means the cells at the yolk's edge have cytoplasm continuous with that of the egg, allowing the yolk and embryo to exchange waste and nutrients with the surrounding cytoplasm.[19]

Physiology

Monotreme female reproductive organs
Male platypus reproductive system. 1. Testes, 2. Epididymis, 3. Bladder, 4. Rectum, 5. Ureter, 6. Vas Deferens, 7. Genito-urinary sinus, 8. Penis enclosed in a fibrous sheath, 9. Cloaca, 10. Opening in the ventral wall of the cloaca for the penis.

Monotremes' metabolic rate is remarkably low by mammalian standards. The platypus has an average body temperature of about 31 °C (88 °F) rather than the averages of 35 °C (95 °F) for marsupials and 37 °C (99 °F) for placental mammals.[31][32] Research suggests this has been a gradual adaptation to the harsh, marginal environmental niches in which the few extant monotreme species have managed to survive, rather than a general characteristic of extinct monotremes.[33][34]

Monotremes may have less developed thermoregulation than other mammals, but recent research shows that they easily maintain a constant body temperature in a variety of circumstances, such as the platypus in icy mountain streams. Early researchers were misled by two factors: firstly, monotremes maintain a lower average temperature than most mammals; secondly, the short-beaked echidna, much easier to study than the reclusive platypus, maintains normal temperature only when active; during cold weather, it conserves energy by "switching off" its temperature regulation. Understanding of this mechanism came when reduced thermal regulation was observed in the hyraxes, which are placental mammals.

The echidna was originally thought to experience no rapid eye movement sleep.[35] However, a more recent study showed that REM sleep accounted for about 15% of sleep time observed on subjects at an environmental temperature of 25 °C (77 °F). Surveying a range of environmental temperatures, the study observed very little REM at reduced temperatures of 15 °C (59 °F) and 20 °C (68 °F), and also a substantial reduction at the elevated temperature of 28 °C (82 °F).[36]

Monotreme milk contains a highly expressed antibacterial protein not found in other mammals, perhaps to compensate for the more septic manner of milk intake associated with the absence of nipples.[37]

Both the platypus and echidna species have spurs on their hind limbs. The echidna spurs are vestigial and have no known function, while the platypus spurs contain venom.[38] Molecular data show that the main component of platypus venom emerged before the divergence of platypus and echidnas, suggesting that the most recent common ancestor of these taxa was also possibly a venomous monotreme.[39]

Monotremes synthesize L-ascorbic acid only in the kidneys.[40]

Taxonomy

Monotremes are conventionally treated as comprising a single order Monotremata, though a recent classification[41] proposes to divide them into the orders Platypoda (the platypus along with its fossil relatives) and Tachyglossa (the echidnas, or spiny anteaters). The entire grouping is also traditionally placed into a subclass Prototheria, which was extended to include several fossil orders, but these are no longer seen as constituting a group allied to monotreme ancestry. A controversial hypothesis now relates the monotremes to a different assemblage of fossil mammals in a clade termed Australosphenida, a group of mammals from the Jurassic and Cretaceous of Madagascar, South America and Australia, that share tribosphenic molars.[9][42] However in a 2022 review of montreme evolution, it was noted that the most primitive monotreme Teinolophos differed substantially from non-monotreme australosphenidans, having five molars as opposed to three in all other non-monotreme australosphenidans, and having non-tribosphenic teeth, which appears to have only evolved in more derived monotremes, meaning that the two groups were likely to be unrelated.[5]

The traditional "theria hypothesis" states that the divergence of the monotreme lineage from the Metatheria (marsupial) and Eutheria (placental mammal) lineages happened prior to the divergence between marsupials and placental mammals, and this explains why monotremes retain a number of primitive traits presumed to have been present in the synapsid ancestors of later mammals, such as egg-laying.[43][44][45] Most morphological evidence supports the theria hypothesis, but one possible exception is a similar pattern of tooth replacement seen in monotremes and marsupials, which originally provided the basis for the competing "Marsupionta" hypothesis in which the divergence between monotremes and marsupials happened later than the divergence between these lineages and the placental mammals. Van Rheede (2005) concluded that the genetic evidence favors the theria hypothesis,[46] and this hypothesis continues to be the more widely accepted one.[47]

The time when the monotreme line diverged from other mammalian lines is uncertain, but one survey of genetic studies gives an estimate of about 220 million years ago.[48] Fossils of a jaw fragment 110 million years old were found at Lightning Ridge, New South Wales. These fragments, from the species Steropodon galmani, are the oldest known fossils of monotremes. Fossils from the genera Teinolophos, and Obdurodon have also been discovered. In 1991, a fossil tooth of a 61 million-year-old platypus was found in southern Argentina (since named Monotrematum, though it is now considered to be an Obdurodon species). (See fossil monotremes below.) Molecular clock and fossil dating give a wide range of dates for the split between echidnas and platypuses, with one survey putting the split at 19–48 million years ago,[49] but another putting it at 17–89 million years ago.[50] All these dates are more recent than the oldest known platypus fossils; and, if correct, suggest that both the short-beaked and long-beaked echidna species are derived from a platypus-like ancestor. The earliest echidna found to date is about 13 million years.[51]

The precise relationships among extinct groups of mammals and modern groups such as monotremes are uncertain, but cladistic analyses usually put the last common ancestor (LCA) of placentals and monotremes close to the LCA of placentals and multituberculates, whereas some suggest that the LCA of placentals and multituberculates was more recent than the LCA of placentals and monotremes.[52][53]

  • ORDER MONOTREMATA
    • Family Ornithorhynchidae: platypus
    • Family Tachyglossidae: echidnas
      • Genus Tachyglossus
        • Short-beaked echidna, T. aculeatus
          • T. a. aculeatus (Common short-beaked echidna)
          • T. a. acanthion (Northern short-beaked echidna)
          • T. a. lawesii (New Guinea short-beaked echidna)
          • T. a. multiaculeatus (Kangaroo Island short-beaked echidna)
          • T. a. setosus (Tasmanian short-beaked echidna)
      • Genus Zaglossus
        • Sir David's long-beaked echidna, Z. attenboroughi
        • Eastern long-beaked echidna, Z. bartoni
          • Z. b. bartoni
          • Z. b. clunius
          • Z. b. diamondi
          • Z. b. smeenki
        • Western long-beaked echidna, Z. bruijni

Fossil monotremes

A model of the extinct platypod Steropodon at the Australian Museum.

The fossil record of monotremes is relatively sparse. The first Mesozoic monotreme to be discovered was Steropodon galmani from Lightning Ridge, New South Wales.[54] Although biochemical and anatomical evidence suggests that the monotremes diverged from the mammalian lineage before the marsupials and placental mammals arose, only a handful of monotreme fossils are known from before the Miocene epoch. The known Mesozoic monotremes are Steropodon and Teinolophos, all from Australian deposits in the Cretaceous, so monotremes had already diversified by that time.[55] A platypus tooth has been found in the Palaeocene of Argentina, so one hypothesis is that monotremes arose in Australia in the Late Jurassic or Early Cretaceous, and that some migrated across Antarctica to South America, both of which were still united with Australia at that time;[56] however, several genetic studies suggest an origin in the Triassic.[57]

Fossil species

A 100 million-year-old Steropodon jaw on display at the American Museum of Natural History, New York City, USA

Excepting Ornithorhynchus anatinus, all the animals listed in this section are known only from fossils.

  • Family Incertae sedis
    • Genus Kryoryctes
      • Species Kryoryctes cadburyi
  • Family Steropodontidae – paraphyletic assemblage
    • Genus Steropodon
      • Species Steropodon galmani
    • Genus Teinolophos
      • Species Teinolophos trusleri – 123 million years old, oldest monotreme specimen
  • Family Ornithorhynchidae
    • Genus Ornithorhynchus – oldest Ornithorhynchus specimen 9 million years old
    • Genus Obdurodon – includes a number of Miocene (5–24 million years ago; Riversleigh platypuses)
      • Species Obdurodon dicksoni
      • Species Obdurodon insignis
      • Species Obdurodon tharalkooschild – Middle Miocene and Upper Miocene (15–5 mya)
    • Genus Monotrematum
      • Species Monotrematum sudamericanum – 61 million years old, originally placed in separate genus, now thought an Obdurodon
  • Family Tachyglossidae
    • Genus Zaglossus – Upper Pleistocene (0.1–1.8 million years ago)
      • Species Zaglossus robustus
    • Genus Murrayglossus
      • Species Murrayglossus hacketti
    • Genus Megalibgwilia
      • Species Megalibgwilia ramsayi – Late Pleistocene
      • Species Megalibgwilia robustaMiocene

References

  1. Groves, C. P. (2005). Wilson, D. E.; Reeder, D. M. (eds.). Mammal Species of the World: A Taxonomic and Geographic Reference (3rd ed.). Baltimore: Johns Hopkins University Press. pp. 1–2. ISBN 0-801-88221-4. OCLC 62265494.
  2. Bonaparte, C.L. (1837). "A New Systematic Arrangement of Vertebrated Animals". Transactions of the Linnean Society of London. 18 (3): 258. doi:10.1111/j.1095-8339.1838.tb00177.x.
  3. Thomas H. Rich; Timothy F. Flannery; Patricia Vickers-Rich (2020). "Evidence for a remarkably large toothed-monotreme from the Early Cretaceous of Lightning Ridge, NSW, Australia". In Guntupalli V.R. Prasad; Rajeev Patnaik (eds.). Biological consequences of plate tectonics. New perspectives on post-Gondwana break-up–A tribute to Ashok Sahni. Vertebrate Paleobiology and Paleoanthropology. Springer. pp. 77–81. doi:10.1007/978-3-030-49753-8_4. ISBN 978-3-030-49752-1. S2CID 229647914.
  4. Thomas H. Rich; Timothy F. Flannery; Alistair R. Evans; Matt White; Timothy Ziegler; Alanna Maguire; Stephen Poropat; Peter Trusler; Patricia Vickers-Rich (2020). "Multiple hypotheses about two mammalian upper dentitions from the Early Cretaceous of Australia". Alcheringa: An Australasian Journal of Palaeontology. 44 (4): 528–536. doi:10.1080/03115518.2020.1829042. S2CID 230531306.
  5. Flannery, T. F.; Rich, T. H.; Vickers-Rich, P.; Ziegler, T.; Veatch, E. G.; Helgen, K. M. (2022). "A review of monotreme (Monotremata) evolution". Alcheringa: An Australasian Journal of Palaeontology. 46: 3–20. doi:10.1080/03115518.2022.2025900. S2CID 247542433.
  6. Pascual, Rosendo; Archer, Michael; Jaureguizar, Edgardo Ortiz; Prado, José L.; Godthelp, Henk; Hand, Suzanne J. (23 April 1992). "First discovery of monotremes in South America". Nature. 356 (6371): 704–706. Bibcode:1992Natur.356..704P. doi:10.1038/356704a0. S2CID 4350045.
  7. "Order Monotremata". Animal Bytes. Archived from the original on 23 December 2010. Retrieved 6 September 2009.
  8. Butler, Ann B.; Hodos, William (2005). Comparative Vertebrate Neuroanatomy: Evolution and Adaptation. Wiley. p. 361. ISBN 978-0-471-73383-6.
  9. Luo, Z.-X.; Cifelli, R.L.; Kielan-Jaworowska, Z. (2001). "Dual origin of tribosphenic mammals". Nature. 409 (6816): 53–57. Bibcode:2001Natur.409...53L. doi:10.1038/35051023. PMID 11343108. S2CID 4342585.
  10. Weil, A. (4 January 2001). "Mammalian evolution: Relationships to chew over". Nature. 409 (6816): 28–31. Bibcode:2001Natur.409...28W. doi:10.1038/35051199. PMID 11343097. S2CID 37912232.
  11. Masakazu Asahara; Masahiro Koizumi; Macrini, Thomas E.; Hand, Suzanne J.; Archer, Michael (2016). "Comparative cranial morphology in living and extinct platypuses: Feeding behavior, electroreception, and loss of teeth". Science Advances. 2 (10): e1601329. Bibcode:2016SciA....2E1329A. doi:10.1126/sciadv.1601329. PMC 5061491. PMID 27757425.
  12. Rich, T.H.; Hopson, J.A.; Musser, A.M.; Flannery, T.F.; Vickers-Rich, P. (2005). "Independent origins of middle ear bones in monotremes and therians (I)". Science. 307 (5711): 910–914. Bibcode:2005Sci...307..910R. doi:10.1126/science.1105717. PMID 15705848. S2CID 3048437.
  13. Bever, G.S.; Rowe, T.; Ekdale, E.G.; MacRini, T.E.; Colbert, M.W.; Balanoff, A.M. (2005). "Comment on "Independent Origins of Middle Ear Bones in Monotremes and Therians" (I)". Science. 309 (5740): 1492a. doi:10.1126/science.1112248. PMID 16141050.
  14. Rougier, G.W. (2005). "Comment on "Independent Origins of Middle Ear Bones in Monotremes and Therians" (II)". Science. 309 (5740): 1492b. doi:10.1126/science.1111294. PMID 16141051.
  15. Rich, Thomas H.; Hopson, James A.; Gill, Pamela G.; Trusler, Peter; Rogers-Davidson, Sally; Morton, Steve; et al. (2016). "The mandible and dentition of the Early Cretaceous monotreme Teinolophos trusleri". Alcheringa: An Australasian Journal of Palaeontology. 40 (4): 475–501. doi:10.1080/03115518.2016.1180034. S2CID 89034974.
  16. "Platypus genome explains animal's peculiar features; holds clues to evolution of mammals". Sciencedaily.com. 7 May 2008. Retrieved 9 June 2011.
  17. Veyrunes; et al. (June 2008). "Bird-like sex chromosomes of platypus imply recent origin of mammal sex chromosomes". Genome Res. 18 (6): 965–973. doi:10.1101/gr.7101908. PMC 2413164. PMID 18463302.
  18. Cortez, Diego; Marin, Ray; Toledo-Flores, Deborah; Froidevaux, Laure; Liechti, Angélica; Waters, Paul D.; Grützner, Frank; Kaessmann, Henrik (24 April 2014). "Origins and functional evolution of Y chromosomes across mammals". Nature. 508 (7497): 488–493. Bibcode:2014Natur.508..488C. doi:10.1038/nature13151. PMID 24759410. S2CID 4462870.
  19. Myers, PZ (2008). "Interpreting Shared Characteristics: The Platypus Genome". Nature Education. 1 (1): 46.
  20. Warren, W. C.; Hillier, L. W.; Marshall Graves, J. A.; Birney, E.; Ponting, C. P.; Grützner, F.; et al. (2008). "Genome analysis of the platypus reveals unique signatures of evolution". Nature. 453 (7192): 175–183. Bibcode:2008Natur.453..175W. doi:10.1038/nature06936. PMC 2803040. PMID 18464734.
  21. Brawand D, Wahli W, Kaessmann H (2008). "Loss of egg yolk genes in mammals and the origin of lactation and placentation". PLOS Biol. 6 (3): e63. doi:10.1371/journal.pbio.0060063. PMC 2267819. PMID 18351802.
  22. Hurum, Jørn H.; Zhe-Xi Luo; Kielan-Jaworowska, Zofia (2006). "Were mammals originally venomous?". Acta Palaeontologica Polonica. 51 (1): 1–11.
  23. Griffiths, Mervyn (2 December 2012). The Biology of the Monotremes. Elsevier Science. ISBN 978-0-323-15331-7.
  24. Grützner, F.; Nixon, B.; Jones, R.C. (2008). "Reproductive biology in egg-laying mammals". Sexual Development. 2 (3): 115–127. doi:10.1159/000143429. PMID 18769071. S2CID 536033.
  25. Lombardi, Julian (6 December 2012). Comparative Vertebrate Reproduction. Springer Science & Business Media. ISBN 978-1-4615-4937-6.
  26. Cromer, Erica (14 April 2004). Monotreme Reproductive Biology and Behavior (Report). Iowa State University.
  27. "Short-beaked echidna (Tachyglossus aculeatus)". Arkive.org. Archived from the original on 13 August 2009. Retrieved 5 July 2016.
  28. Power, Michael L.; Schulkin, Jay (2012). The Evolution of the Human Placenta. Johns Hopkins University Press. pp. 68ff. ISBN 978-1-4214-0870-5.
  29. Ashwell, K. W.; Shulruf, B.; Gurovich, Y. (2019). "Quantitative analysis of the timing of development of the cerebellum and precerebellar nuclei in monotremes, metatherians, rodents, and humans". The Anatomical Record. 303 (7): 1998–2013. doi:10.1002/ar.24295. PMID 31633884. S2CID 204815010.
  30. Schneider, Nanette Y. (2011). "The development of the olfactory organs in newly hatched monotremes and neonate marsupials". J. Anat. 219 (2): 229–42. doi:10.1111/j.1469-7580.2011.01393.x. PMC 3162242. PMID 21592102.
  31. White (1999). "Thermal Biology of the Platypus". Davidson College. Archived from the original on 6 March 2012. Retrieved 14 September 2006.
  32. "Control Systems Part 2" (PDF). Retrieved 6 July 2016.
  33. Watson, J.M.; Graves, J.A.M. (1988). "Monotreme Cell-Cycles and the Evolution of Homeothermy". Australian Journal of Zoology. 36 (5): 573–584. doi:10.1071/ZO9880573.
  34. Dawson, T.J.; Grant, T.R.; Fanning, D. (1979). "Standard Metabolism of Monotremes and the Evolution of Homeothermy". Australian Journal of Zoology. 27 (4): 511–515. doi:10.1071/ZO9790511.
  35. Siegel, J.M.; Manger, P.R.; Nienhuis, R.; Fahringer, H.M.; Pettigrew, J.D. (1998). "Monotremes and the evolution of rapid eye movement sleep". Philosophical Transactions of the Royal Society B: Biological Sciences. 353 (1372): 1147–1157. doi:10.1098/rstb.1998.0272. PMC 1692309. PMID 9720111.
  36. Nicol, S.C.; Andersen, N.A.; Phillips, N.H.; Berger, R.J. (2000). "The echidna manifests typical characteristics of rapid eye movement sleep". Neuroscience Letters. 283 (1): 49–52. doi:10.1016/S0304-3940(00)00922-8. PMID 10729631. S2CID 40439226.
  37. Bisana, S.; Kumar, S.; Rismiller, P.; Nicol, S.C.; Lefèvre, C.; Nicholas, K.R.; Sharp, J.A. (9 January 2013). "Identification and functional characterization of a novel monotreme-specific antibacterial protein expressed during lactation". PLOS ONE. 8 (1): e53686. Bibcode:2013PLoSO...853686B. doi:10.1371/journal.pone.0053686. PMC 3541144. PMID 23326486.
  38. Whittington, Camilla M.; Belov, Katherine (April 2014). "Tracing Monotreme Venom Evolution in the Genomics Era". Toxins. 6 (4): 1260–1273. doi:10.3390/toxins6041260. PMC 4014732. PMID 24699339.
  39. Whittington, Camilla M.; Belov, Katherine (April 2014). "Tracing Monotreme Venom Evolution in the Genomics Era". Toxins. 6 (4): 1260–1273. doi:10.3390/toxins6041260. PMC 4014732. PMID 24699339.
  40. "Ascorbic acid biosynthesis in the mammalian kidney". ScienceScape.org. Archived from the original on 17 December 2014. Retrieved 14 November 2014.{{cite web}}: CS1 maint: unfit URL (link)
  41. McKenna, Malcolm C.; Bell, Susan K. (1997). Classification of Mammals above the Species Level. New York, NY: Columbia University Press. ISBN 0-231-11013-8.
  42. Luo, Z.-X.; Cifelli, R.L.; Kielan-Jaworowska, Z. (2002). "In quest for a phylogeny of Mesozoic mammals". Acta Palaeontologica Polonica. 47: 1–78.
  43. Vaughan, Terry A.; Ryan, James M.; Czaplewski, Nicholas J. (2011). Mammalogy (5th ed.). Jones & Bartlett Learning. p. 80. ISBN 978-0-7637-6299-5.
  44. "Introduction to the Monotremata". Ucmp.berkeley.edu. Retrieved 9 June 2011.
  45. Jacks. "Lecture 3" (PDF). Moscow, ID: University of Idaho.
  46. van Rheede, Teun (2005). "The platypus is in its place: Nuclear genes and indels confirm the sister group relation of monotremes and therians". Molecular Biology and Evolution. 23 (3): 587–597. doi:10.1093/molbev/msj064. PMID 16291999.
  47. Janke, A.; Xu, X.; Arnason, U. (1997). "Monotremes". Proceedings of the National Academy of Sciences. 94 (4): 1276–1281. doi:10.1073/pnas.94.4.1276. PMC 19781. PMID 9037043. Retrieved 9 June 2011.
  48. Madsen, Ole (2009). "chapter 68 – Mammals (Mamalia)". In Hedges, S. Blair; Kumar, Sudhir (eds.). The Timetree of Life. timetree.org. Oxford University Press. pp. 459–461. ISBN 978-0-19-953503-3.
  49. Phillips, M.J.; Bennett, T.H.; Lee, M.S. (2009). "Molecules, morphology, and ecology indicate a recent, amphibious ancestry for echidnas". Proc. Natl. Acad. Sci. U.S.A. 106 (40): 17089–17094. Bibcode:2009PNAS..10617089P. doi:10.1073/pnas.0904649106. PMC 2761324. PMID 19805098.
  50. Springer, Mark S.; Krajewski, Carey W. (2009). "chapter 69 – Monotremes (Prototheria)" (PDF). In Hedges, S. Blair; Kumar, Sudhir (eds.). The Timetree of Life. timetree.org. Oxford University Press. pp. 462–465.
  51. "Echidna and platypus share common ancestor: research". Australian Broadcasting Corporation. 22 September 2009.
  52. Benton, Michael J. (2004). Vertebrate Palaeontology. Wiley. p. 300. ISBN 978-0-632-05637-8.
  53. Carrano, Matthew T.; Blob, Richard W.; Gaudin, Timothy J.; Wible, John R. (2006). Amniote Paleobiology: Perspectives on the Evolution of Mammals, Birds, and Reptiles. University of Chicago Press. p. 358. ISBN 978-0-226-09478-6.
  54. Ashwell, K., ed. (2013). Neurobiology of Monotremes. Melbourne: CSIRO Publishing. ISBN 9780643103115.
  55. "Fossil Record of the Monotremata". Ucmp.berkeley.edu. Retrieved 9 June 2011.
  56. Benton, Michael J. (1997). Vertebrate Palaeontology (2nd ed.). Wiley. pp. 303–304. ISBN 978-0-632-05614-9.
  57. Madsen (2009). "Chapter 68" (PDF). Time Tree.

Further reading

  • Nowak, Ronald M. (1999). Walker's Mammals of the World (6th ed.). Baltimore, MD: Johns Hopkins University Press. ISBN 978-0-8018-5789-8. LCCN 98023686.
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