Evolution of mammalian auditory ossicles

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The evolution of mammalian auditory ossicles is one of the most well-documented[1] and important evolutionary events, demonstrating both numerous transitional forms as well as an excellent example of exaptation, the re-purposing of existing structures during evolution.

In reptiles, the eardrum is connected to the inner ear via a single bone, the stapes or stirrup, while the upper and lower jaws contain several bones not found in mammals. Over the course of the evolution of mammals, one upper and one lower jaw bone (the quadrate and articular) lost their purpose in the jaw joint and were put to new use in the middle ear, connecting to the stapes and forming a chain of three bones which amplify sounds and allow more acute hearing. In mammals, these two bones are known as the malleus and incus (hammer and anvil).

The evidence that the malleus and incus are homologous to the reptilian articular and quadrate was originally embryological, and since this discovery an abundance of transitional fossils has both supported the conclusion and given a detailed history of the transition. A history of this discovery (up to 1940) is presented by Bowler.[2]The evolution of the stapes was an earlier and distinct event[3] and is not discussed here.

Contents

[edit] Reichert–Gaupp theory

The relationship between the reptilian jaw bones and mammalian middle-ear bones was first established on the basis of embryology and comparative anatomy by Reichert (in 1837, before the publication of On the Origin of Species in 1859) and advanced by Gaupp, and this is known as the Reichert–Gaupp Theory.

In the course of the development of the embryo, the incus and malleus arise from the same First Pharyngeal arch as the Mandible and Maxilla, and are served by mandibular and maxillary division of the Trigeminal Cranial nerve[4].

...the discovery that the mammalian malleus and incus were actually homologues of visceral elements of the "reptilian" jaw articulation ... ranks as one of the milestones in the history of comparative biology.[5]

... it is one of the triumphs of the long series of researches on the extinct Theromorph reptiles, begun by Owen (1845), and continued by Seeley, Broom, and Watson, to have revealed the intermediate steps by which the change may have occurred from an inner quadrate to an outer squamosal articulation ...[6]


There are also more recent studies in the genetic basis for the development of the ossicles from the embryonic arch.[7] and relating this to evolutionary history.[8] "Bapx1, also known as Nkx3.2, is the vertebrate homologue of the Drosophila gene Bagpipe. A member of the NK2 class of homeobox genes ..."[9] and this gene is implicated in the change from the jaw bones of non-mammals to the ossicles of mammals.[10]

Yet the transition between the "reptilian" jaw and the "mammalian" inner ear was not bridged in the fossil record until the 1950s[11] with the elaboration of such fossils as the now-famous Morganucodon.[12]

Tensor tympani Incus Stapedius Labyrinth Stapes Tympanic cavity Eustachian Tube Ear drum Ear canal Malleus

A typical mammalian middle ear: sound makes the tympanum (ear-drum) vibrate; 3 small bones, the malleus, incus and stapes, transmit the vibrations to the Labyrinth (inner ear), which transforms the vibrations into nerve signals.
A typical mammalian middle ear: sound makes the tympanum (ear-drum) vibrate; 3 small bones, the malleus, incus and stapes, transmit the vibrations to the Labyrinth (inner ear), which transforms the vibrations into nerve signals.

[edit] Definitive mammalian middle ear

The mammalian middle ear contains three tiny bones known as the ossicles: malleus, incus, and stapes. The ossicles are a complex system of levers whose functions include: reducing the amplitude of the vibrations; increasing the amount of energy transmitted. The details of these effects vary noticeably between different mammal species, even when the species are as closely related as humans and chimpanzees.[13]

[edit] Evolutionary history

[edit] Definition of "mammal"

Living mammal species can be identified by the presence in females of mammary glands which produce milk. Other features are required when classifying fossils, since mammary glands and other soft-tissue features are not visible in fossils. Paleontologists therefore use a distinguishing feature that is shared by all living mammals (including monotremes), but is not present in any of the early Triassic therapsids ("mammal-like reptiles"): mammals use two bones for hearing that all other amniotes use for eating. The earliest amniotes had a jaw joint composed of the articular (a small bone at the back of the lower jaw) and the quadrate (a small bone at the back of the upper jaw). All non-mammalian amniotes use this system including lizards, crocodilians, dinosaurs (and their descendants the birds) and therapsids; so the only ossicle in their middle ears is the stapes. But mammals have a different jaw joint, composed only of the dentary (the lower jaw bone which carries the teeth) and the squamosal (another small skull bone). And in mammals the quadrate and articular bones have become the incus and malleus bones in the middle ear.[14][15]

[edit] Summary of the fossil evidence

Here is a very simplified "family tree" of the various lineages involved:

--Tetrapods------ 
    |       ("4 legged"; the earliest breathed via gills)
    |
    +-- Amphibians ----------------------------------------------
    |
    `--------Reptiliomorphs-----
               |         ("reptile-like" amphibians)
               |
               `--Amniotes------
                    |
                    +--Sauropsids ("lizard faces")---------------
                         |     (lizards, crocodilians, dinosaurs, birds
                         |      Testudines; and some extinct groups)
                         |
                         `--Synapsids------
                              |
                              `--Pelycosaurs----
                                   |
                                   `--Therapsids-----
                                        |
                                        `--Mammals---------------

The first fully terrestrial vertebrates were amniotes - their eggs had internal membranes which allowed the developing embryo to breathe but kept water in. This allowed amniotes to lay eggs on dry land, while amphibians generally need to lay their eggs in water. The first amniotes apparently arose in the late Carboniferous from the ancestral reptiliomorphs (a group of amphibians whose only living descendants are amniotes). Within a few million years two important amniote lineages became distinct: mammals' synapsid ancestors and the sauropsids, from which lizards, snakes, crocodilians, dinosaurs and birds are descended. [16] The earliest known fossils of all these groups date from about 320 to 315M years ago. Unfortunately it is difficult to be sure about when each of them evolved, since vertebrate fossils from the late Carboniferous are very rare, and therefore the actual first occurrences of each of these types of animal might have been considerably earlier.[17][15]

The pattern in most of the following sections is that each successive more "advanced" group started with the more "primitive" jaws and ears of its predecessors, then developed more mammal-like jaws and ears, and so on. The evolution of mammalian jaw joints and ears did not proceed neatly in step with the evolution of other mammalian features; or, to put it another way, all but the last of the various stages into which paleontologists divide the evolution towards the mammalian condition are not defined by their jaw joints and ears.

Mammalian and non-mammalian jaws. In the mammal configuration, the quadrate and articular bones are much smaller and form part of the middle ear. Note that in mammals the lower jaw consists of only the dentary bone.
Mammalian and non-mammalian jaws. In the mammal configuration, the quadrate and articular bones are much smaller and form part of the middle ear. Note that in mammals the lower jaw consists of only the dentary bone.

[edit] Early tetrapod and amniote ears

In modern amniotes (including mammals), the middle ear collects airborne sounds through an ear drum and transmits the vibrations to the inner ear via thin cartilaginous and ossified structures, which usually include the stapes (a stirrup-shaped auditory ossicle). But the earliest tetrapods, amphibians and amniotes probably did not have ear drums. In fact ear drums apparently evolved independently three to six times, in: stegocephalians (very primitive amphibians); in anurans (the amphibian group that includes frogs and toads); in synapsids (mammals and their extinct relatives), in diapsids (the most important sauropsid group, including lizards, crocodiles, dinosaurs and birds); perhaps separately in anapsids (turtles and their extinct relatives), if turtles are not modified diapsids; probably in seymouriamorphs (a group of reptiliomorphs); and possibly in some temnospondyls (primitive amphibians).[18] In all basal members of the 3 major clades of amniotes (synapsids, eureptiles, and parareptiles) the stapes bones are relatively massive props that support the braincase, and this function prevents them from being used as part of the hearing system. But there is increasing evidence that synapsids, eureptiles and parareptiles developed eardrums connected to the inner ear by stapes during the Permian.[19]

[edit] Early therapsid jaws and ears

The jaws of early synapsids, including the ancestors of mammals, were similar to those of other tetrapods of the time, with a lower jaw consisting of a tooth-bearing dentary bone and several smaller posterior bones. The jaw joint consisted of the articular bone in the lower jaw and the quadrate in the upper jaw. The early pelycosaurs (late Carboniferous and early Permian) most probably did not have tympanic membranes (external eardrums), and their massive stapes bones supported the braincase, with the lower ends resting on the quadrates. But their descendants the therapsids (including mammals' ancestors) probably did have tympanic membranes and these probably were in contact with the quadrate bones; and the stapes bones were still in contact with the quadrates but functioned as auditory ossicles rather than braincase supports; so the therapsids' quadrates had a dual function, as part of the jaw joint and as parts of the hearing system.[20][21]

[edit] Twin-jointed jaws

Morganucodontidae and other transitional forms had both types of jaw joint: dentary-squamosal (front) and articular- quadrate (rear).
Morganucodontidae and other transitional forms had both types of jaw joint: dentary-squamosal (front) and articular- quadrate (rear).

During the Permian and early Triassic the dentary of therapsids, including the ancestors of mammals, continually enlarged while other jaw bones were reduced.[22] Eventually, the dentary was able to make contact with the squamosal, a bone in the upper jaw located anterior to the quadrate, allowing two simultaneous jaw joints[23] - an anterior "mammalian" joint between the dentary and squamosal and a posterior "reptilian" joint between the quadrate and articular. This "twin-jointed jaw" can be seen in late cynodonts and early mammaliforms[24]. Morganucodon is one of the first discovered and most thoroughly studied of the mammaliforms, since an unusually large number of morganucodont fossils have been found, and

Morganucodon is an almost perfect intermediate in this respect (the "twin-jointed jaw") between the higher mammal-like reptiles on the one hand and the typical mammals on the other.[25] (note: "mammal-like reptiles" is an obsolete term for the therapsids)

[edit] Mammal-like jaws and ears

As the dentary continued to enlarge during the Triassic, the older quadrate-articular joint fell out of use. Some of the bones were lost, but the quadrate (which is directly connected to the stapes), the articular (connected to the quadrate) and the angular (connected to the articular) became free-floating and associated with the stapes. This occurred at least twice in the mammaliformes ("almost-mammals"). The Multituberculates, which lived from about 160M years ago (mid-Jurassic) to about 35M years ago (early Oligocene) had jaw joints that consisted of only the dentary and squamosal bones, and the quadrate and articular bones were part of the middle ear; but other features of their teeth, jaws and skulls are significantly different from those of mammals.[26] In the lineage most closely related to mammals, the jaws of Hadrocodium (about 195M years ago in the very early Jurassic) suggest that it or a very close ancestor may have been the first to have a fully mammalian middle ear: it lacks the trough at the rear of the lower jaw, over which the eardrum stretched in therapsids and earlier mammaliformes, and the absence of this trough which suggests that Hadrocodium’s ear was part of the cranium, as it is in mammals, and hence that the former articular and quadrate had migrated to the middle ear and become the malleus and incus; but Hadrocodium’s dentary has a "bay" at the rear which mammals lack, a hint that that its dentary bone retained the same shape that it would have had if the articular and quadrate had remained part of the jaw joint.[27]

It has been suggested that a relatively large trough in the jaw bone of the early Cretaceous monotreme Teinolophos provides evidence of a pre-mammalian jaw joint, because therapsids and many mammaliforms had such troughs, in which the articular and angular bones "docked", and therefore that Teinolophos had a pre-mammalian middle ear; and therefore that the mammalian middle ear ossicles evolved indepedendently in monotremes and in other mammals.[28] But a more recent analysis of Teinolophos concluded that the animal was a full-fledged platypus and the trough was a channel for the large number of nerves that collect signals from the electrical and vibration sensors in the bill (this is a signature feature of the platypi within monotremes), and therefore that the trough is not evidence that Teinolophos had a pre-mammalian jaw joint and a pre-mammalian middle ear.[29]

[edit] How these changes affected hearing

The frequency range and sensitivity of the ear is dependent upon the shape and arrangement of the middle-ear bones. In early synapsids such as the pelycosaurs, the quadrate and articular had to function as the jaw joint, and this severely limited how far these bones could be modified to alter the frequency range of the ear. But once these bones were no longer involved in the jaw joint, variations which affected hearing would not also affect jaw joint function, and this allowed unconstrained evolution of the mammalian hearing apparatus.[30]

By the Jurassic, the typical mammalian ear had evolved, in which the angular had become the tympanic annula (a bony support for the tympanic membrane), while the articular and quadrate had become the malleus and incus, respectively, connected in series with the stapes. This series of three bones acts as an amplification system to allow enhanced hearing.

The transition between these two states is one of the most well-documented[31] and supported in all of evolution, and newly discovered fossils from this transitional period have recently improved our understanding of this transition. But they also suggest that it was not a simple linear process from the early therapsid jaw (quadrate-articular joint) and middle ear (with stapes as the only ossicles) to the modern mammalian condition.[32][21]

[edit] Natural selection

It has been suggested that Natural selection could be a factor in the preservation of the structure of the middle ear in mammals.[1][33] Many of the earliest mammals were quite small, and the dentition indicates that they were insectivorous. If they were "Warm-blooded" (homeothermous), like modern mammals, then they could have been nocturnal. This fits with the popular image of small, nocturnal insectivorous mammals surviving in niches not accessible to the large, dominant contemporary dinosaurs. The enhanced hearing, particularly in the higher frequencies, would be helpful for nocturnal animals, in particular for detecting insects. This scenario is consistent with selective advantage being a contributory factor to the transition, quite apart from the evidence for the reality of the transition.

[edit] Summary

The presence of these two small bones in the middle ear is a signature feature of mammals, distinguishing them from reptiles and all other vertebrates. They therefore have the appearance of representing a discontinuity in the tree of life. But in the early 19th century, it was hypothesized that these bones are not a total novelty, but are the equivalents of two bones which non-mammals have in their jaws. This hypothesis made sense, not only of the existence of these middle-ear bones, but also of certain other features of the anatomy, such as the paths taken by nerves in the head.

As evolutionary biology began to be expanded upon, this relationship became treated as one of common descent. For the evolutionary explanation to make sense, it seemed to demand that there would be a transition in function between being part of the feeding mechanism in the joint of the jaw and serving only in hearing; and this would mean that somehow there had to be an intermediate connecting these two quite different functions. With the discovery of Morganucodon and other fossils, there were concrete examples of this. There was a double jaw joint: the "older reptilian", as well as the "newer mammalian", in the same animal. This meant a confirmation of the pattern of inference from comparative anatomy to evolutionary biology.

The earliest mammals were generally small animals, probably nocturnal insectivores. This suggests a plausible evolutionary mechanism driving the change, for with these small bones in the middle ear, an mammal has extended its range of hearing for higher-pitched sounds which would improve the detection of insects in the dark. Natural selection would account for the success of this feature.

And still one more connection with another part of biology: genetics suggested a mechanism for this transition, the kind of major change of function seen elsewhere in the world of life being studied by Evodevo.

[edit] References

  1. ^ a b Edgar F. Allin, "Evolution of the mammalian middle ear", Journal of Morphology Volume 147 Number 4 (December 1975), pages 403-437.
  2. ^ Peter J. Bowler, Life's Splendid Drama: Evolutionary Biology and the Reconstruction of Life's Ancestry 1860-1940 University of Chicago Press, 1996 ISBN 0-226-06921-4. Chapter 6, "The Origin of Birds and Mammals"
  3. ^ For example, page 56 in Philippe Janvier, Early Vertebrates, Oxford: Clarendon Press, New York: Oxford University Press, 2002 ISBN 978-0198526469
  4. ^ Page 435, Scott F. Gilbert Developmental Biology, Sinauer Associates, 7th edition, 2003 ISBN 0-87893-258-5
  5. ^ Page 510, Michael J. Novacek, "Patterns of Diversity in the Mammalian Skull", volume 2 pages 438-545 The Skull, edited by James Hanken and Brian K. Hall, University of Chicago Press, 1993 ISBN 0-226-31568-1. Novacek references these early works: Johann Friedrich Meckel Handbuch der Menschlichen Anatomie, Halle, 1820; Reichert "Ueber die Visceralbogen der Wirbelthiere im Allegemeinen und deren Metamorphosen bei den Vögln und Säugethieren", Archiv für Anatomie, Physiologie, und wissenschaftliche Medizin, Leipzig 1837, pages 120-122; and Gaupp "Die Reichertsche Theorie (Hammer-, Amboss- und Kieferfrage)" Archiv für Anatomie und Entwicklungsgeschichte 1913, pages 1-416.
  6. ^ Page 474 of Edwin S. Goodrich, Studies on the Structure & Development of Vertebrates, Macmillan, 1930. Reprinted by Dover, 1958.
  7. ^ Moisés Mallo, "Formation of the Middle Ear: Recent Progress on the Developmental and Molecular Mechanisms", Developmental Biology, volume 231, number 2 (March 2001), pages 410-419 doi:1006/dbio.2001.0154
  8. ^ Rudolf A. Raff, "Written in stone: fossils, genes and evo-devo", Nature Reviews Genetics, volume 8 issue 12 (December 2007) pages 911-920 doi:10.1038/nrg2225. See particularly the section "Fossils in testing evo-devo hypotheses", pages 915-916
  9. ^ Joanne Wilson and Abigail S. Tucker, "Fgf and Bmp signals repress the expression of Bapx1 in the mandibular mesenchyme and control the position of the developing jaw joint", Developmental Biology, volume 266 issue 1 (February 2004) pages 138-150 doi:10.1016/j.ydbio.2003.10.1012
  10. ^ Abigail S. Tucker, Robert P. Watson, Laura A. Lettice, Gen Yamada and Robert E. Hill, "Bapx1 regulates patterning in the middle ear: altered regulatory role in the transition from the proximal jaw during vertebrate evolution", Development volume 131 (2004) pages 1235-1245 doi:10.1242/dev.01017
  11. ^ A. W. Crompton and F. A. Jenkins, Jr., "Mammals from Reptiles: A Review of Mammalian Origins", Annual Review of Earth and Planetary Sciences, Volume 1 (1973), pages 131-155 doi:10.1146/annurev.ea.01.050173.001023
  12. ^ Walter Georg Kühne, "Rhaetische Triconodonten aus Glamorgan, ihre Stellung zwischen den Klassen Reptilia und Mammalia und ihre Bedeutung für die REICHART'sche Theorie" (Rhaetian triconodonts from Glamorgan, their place between the classes Reptilia and Mammalia and their meaning for the Reichart Theory), Palaeontologische Zeitschrift, Band 32, Heft 3/4 (1958), pages 197-235
  13. ^ Masali, M. (October 1992). "Citation is missing a {{{title}}}. Either specify one, or click here and a bot will complete the citation details for you. {{{title}}}". Human Evolution 7 (4). Springer Netherlands. doi:10.1007/BF02436407. 
  14. ^ Mammalia: Overview - Palaeos
  15. ^ a b Cowen, R. (2000). History of Life. Oxford: Blackwell Science, 432. 
  16. ^ Amniota - Palaeos.
  17. ^ Synapsida: Varanopseidae - Palaeos.
  18. ^ Laurin, M. (January-March 1998). "The importance of global parsimony and historical bias in understanding tetrapod evolution. Part I. Systematics, middle ear evolution and jaw suspension". Annales des Sciences Naturelles - Zoologie et Biologie Animale 19 (1): 1-42. Elsevier. doi:10.1016/S0003-4339(98)80132-9.  summarised at Laurin, M.. Hearing in Stegocephalians. Tree of Life.
  19. ^ "Impedance-Matching Hearing in Paleozoic Reptiles: Evidence of Advanced Sensory Perception at an Early Stage of Amniote Evolution" (September 2007). PLoS ONE 2 (9). doi:10.1371/journal.pone.0000889. 
  20. ^ Clack, J.A. & Allin, E. (2004), “The Evolution of Single- and Multi-Ossicle Ears in Fishes and Tetrapods”, in Manley, G.A.; Popper, A.N. & Fay, R.R., Evolution Of The Vertebrate Auditory System, Springer, pp. 128-163, ISBN 038721089X 
  21. ^ a b Template:Cite journal A author=Luo, Z-X.
  22. ^ Christian A. Sidor, "Simplification as a trend in Synapsid cranial evolution", Evolution (International Journal of Organic Evolution), volume 55, issue 7 (July 2001), pages 1419-1442
  23. ^ Page 229, Michael J. Benton, Vertebrate Palaeontology: Biology and evolution, Unwin Hyman, 1990 ISBN 0-04-566001-8
  24. ^ Page 228 of Edward H. Colbert and Michael Morales, Evolution of the Vertebrates: A History of the Backboned Animals Through Time, Wiley-Liss, 4th edition, 1991 ISBN 0471-85074-8
  25. ^ page 147 in K. A. Kermack, Frances Mussett and H. W. Rigney, "The skull of Morganucodon", Zoological Journal of the Linnean Society, volume 71 number 1 (January 1981), pages 1-158.
  26. ^ Mammaliformes - Palaeos.
  27. ^ Symmetrodonta - Palaeos.
  28. ^ "Independent Origins of Middle Ear Bones in Monotremes and Therians" (February 2005). Science 307 (5711): 910 - 914. doi:10.1126/science.1105717. 
  29. ^ "The oldest platypus and its bearing on divergence timing of the platypus and echidna clades" (January 2008). Proceedings of the National Academy of Sciences 105 (4): 1238-1242. doi:10.1073/pnas.0706385105.  Ironically Rich and Vickers-Rich were among the authors of the 2005 paper on which they later cast doubt!
  30. ^ R. Eric Lombard and Thomas E. Hetherington, "Structural Basis of Hearing and Sound Transmission," volume 3 ("Functional and Evolutionary Mechanisms"), pages 241-302 of The Skull, edited by James Hanken and Brian K. Hall, University of Chicago Press, 1993 ISBN 0226-31571-1
  31. ^ See, for example, the references at http://www.gcssepm.org/special/cuffey_14.htm
  32. ^ For example, Zhe-Zi Luo, Peiji Chen, Gang Li and Meng Chen, "A new eutriconodont mammal and evolutionary development in early mammals", Nature Volume 446 Number 7133, pages 288-293 (15 March 2007) doi:10.1038/nature05627
  33. ^ Zhi-Xi Luo, "Transformation and diversification in early mammal evolution", Nature volume 450 issue 7172 (13 December 2007) pages 1011-1019. doi:10.1038/nature06277

[edit] See also

[edit] General references

  • Egdar F. Allin and James A. Hopson, "Evolution of the Auditory System in Synapsida ("Mammal-Like Reptiles" and Primitive Mammals) as Seen in the Fossil Record", Section IV ("Mammals"), Chapter 28, pages 587-614 in The Evolutionary Biology of Hearing, edited by Douglas B. Webster, Richard R. Fay, and Arthur N. Popper. Springer-Verlag, 1992 ISBN 0-387-97588-8. Also in the same volume, Chapter 29, pages 615-632 "Hearing in Transitional Mammals: Predictions from the Middle-Ear Anatomy and Hearing Capabilities of Extant Mammals" by John J. Rosowski.
  • James A. Hopson, "The Mammal-like Reptiles: A study of transitional fossils", The American Biology Teacher Volume 49 Number 1 (January 1987), pages 16-26
  • Zofia Kielan-Jaworowska, Richard L. Cifelli, and Zhe-Xi Luo, Mammals from the Age of Dinosaurs: Origins, Evolution, and Structure, Columbia University Press, New York, 2004 ISBN 0-231-11918-6. Chapter 3 "Origin of Mammals"
  • Guillermo W. Rougier and John R. White, "Major Changes in the Ear Region and Basicranium of Early Mammals", Chapter 6, pages 269-311, in Amniote Paleobiology: Perspectives on the Evolution of Mammals, Birds, and Reptiles: A volume honoring James Allen Hopson edited by Matthew T. Carrano, Timothy J. Gaudin, Richard W. Blob, and John R. Wible, University of Chicago Press, 2006 ISBN 0-226-09477-4
  • Neil Shubin, Your Inner Fish: A Journey into the 3.5-Billion-Year History of the Human Body Pantheon Books, 2008 ISBN 978-0-375-42447-2. Chapter 10, "Ears"

[edit] External links

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