Top

Journal of the Association for Research in Otolaryngology

Published in:

01-12-2012 | Invited Review

Evolutionary Paths to Mammalian Cochleae

Author: Geoffrey A. Manley

Published in: Journal of the Association for Research in Otolaryngology | Issue 6/2012

Abstract

Evolution of the cochlea and high-frequency hearing (>20 kHz; ultrasonic to humans) in mammals has been a subject of research for many years. Recent advances in paleontological techniques, especially the use of micro-CT scans, now provide important new insights that are here reviewed. True mammals arose more than 200 million years (Ma) ago. Of these, three lineages survived into recent geological times. These animals uniquely developed three middle ear ossicles, but these ossicles were not initially freely suspended as in modern mammals. The earliest mammalian cochleae were only about 2 mm long and contained a lagena macula. In the multituberculate and monotreme mammalian lineages, the cochlea remained relatively short and did not coil, even in modern representatives. In the lineage leading to modern therians (placental and marsupial mammals), cochlear coiling did develop, but only after a period of at least 60 Ma. Even Late Jurassic mammals show only a 270 ° cochlear coil and a cochlear canal length of merely 3 mm. Comparisons of modern organisms, mammalian ancestors, and the state of the middle ear strongly suggest that high-frequency hearing (>20 kHz) was not realized until the early Cretaceous (~125 Ma). At that time, therian mammals arose and possessed a fully coiled cochlea. The evolution of modern features of the middle ear and cochlea in the many later lineages of therians was, however, a mosaic and different features arose at different times. In parallel with cochlear structural evolution, prestins in therian mammals evolved into effective components of a new motor system. Ultrasonic hearing developed quite late—the earliest bat cochleae (~60 Ma) did not show features characteristic of those of modern bats that are sensitive to high ultrasonic frequencies.

Aitkin LM, Johnstone BM (1972) Middle-ear function in a monotreme: the echidna (Tachyglossus aculeatus). J Exp Zool 180:245–250PubMedCrossRef

Armstrong SD, Bloch JI, Houde P, Silkox MT (2011) Cochlear labyrinth volume in euarchontoglirans: implications for the evolution of hearing in primates. Anat Rec 294:263–266CrossRef

von Békésy G (1960) Experiments in hearing. McGraw-Hill, New York

Beurg M, Nam J-H, Chen Q, Fettiplace R (2010) Calcium balance and mechanotransduction in rat cochlear hair cells. J Neurophysiol 104:18–34PubMedCrossRef

Bininda-Emons ORP, Cardillo M, Jones KE, MacPhee RDE, Beck RMD et al (2007) The delayed rise of present-day mammals. Nature 446:507–512CrossRef

Carr C (2004) Timing is everything: organization of timing circuits in auditory and electrical sensory systems. J Comp Neurol 472:131–133PubMedCrossRef

Christensen-Dalsgaard J (2010) Vertebrate pressure-gradient receivers. Hear Res 273:37–45PubMedCrossRef

Christensen-Dalsgaard J, Manley GA (2005) Directionality of the lizard ear. J Exp Biol 208:1209–1217

Clack JA (2002) Patterns and processes in the early evolution of the tetrapod ear. J Neurobiol 53:251–264PubMedCrossRef

Coleman MN, Boyer DM (2012) Inner ear evolution in primates through the Cenozoic: implications for the evolution of hearing. Anat Rec 294:615–631CrossRef

Dallos P, Fakler B (2002) Prestin, a new type of motor protein. Nat Rev Mol Cell Biol 3:104–111PubMedCrossRef

Elgoyhen AB, Franchini LF (2011) Prestin and the cholinergic receptor of hair cells: positively-selected proteins in mammals. Hear Res 273:100–108PubMedCrossRef

Evans AR, Jones D, Boyer AG, Brown JH, Costa DP (2012) The maximum rate of mammal evolution. PNAS 109:4187–4190PubMed

Fleischer G (1978) Evolutionary principles of the mammalian middle ear. Adv Anat Embryol Cell Biol 55:1–70

Fox RC, Meng J (1997) An X-radiographic and SEM study of the osseous inner ear of multituberculates and monotremes (Mammalia): implications for mammalian phylogeny and evolution of hearing. Zool J Linn Soc 121:249–291CrossRef

Franchini LF, Elgoyhen AB (2006) Adaptive evolution in mammalian proteins involved in cochlear outer hair cell electromotility. Mol Phylogenet Evol 41:622–635PubMedCrossRef

Gates GR, Saunders JC, Bock GR, Aitkin LM, Elliot MA (1974) Peripheral auditory function in the platypus, Ornithorhynchus anatinus. J Acoust Soc Amer 56:152–156CrossRef

Gavara N, Manoussaki D, Chadwick RS (2011) Auditory mechanics of the tectorial membrane and the cochlear spiral. Curr Opin Otolaryngol Head Neck Surg 19:382–387PubMedCrossRef

Greybeal A, Rosowski JJ, Ketten DR, Crompton AW (1989) Inner-ear structure in Morganucodon, an early Jurassic mammal. Zool J Linn Soc 96:107–117CrossRef

Heffner RS, Koay G, Heffner HE (2001) Audiograms of five species of rodents: implications for the evolution of hearing and the perception of pitch. Hear Res 157:139–152CrossRef

Hemilä S, Nummela S, Reuter T (1995) What middle ear parameters tell about impedance matching and high frequency hearing. Hear Res 85:31–44PubMedCrossRef

Hudspeth AJ (2008) Making an effort to listen: mechanical amplification in the ear. Neuron 59:530–545PubMedCrossRef

Hurum JH (1998) The inner ear of two Late Cretaceous multituberculate mammals, and its implications for multituberculate hearing. J Mamm Evol 5:65–93CrossRef

Ji Q, Luo Z-X, Yuan C-X, Wible JR, Zhang J-P, Georgi JA (2002) The earliest known eutherian mammal. Nature 416:816–822PubMedCrossRef

Kemp TS (2005) The origin and evolution of mammals. Oxford University Press, Oxford

Kemp TS (2007) Acoustic transformer function of the postdentary bones and quadrate of a nonmammalian cynodont. J Vert Paleontol 27:431–441CrossRef

Köppl C, Forge A, Manley GA (2004) Low density of membrane particles in auditory hair cells of lizards and birds suggests an absence of somatic motility. J Comp Neurol 479:149–155PubMedCrossRef

Kronester-Frei A (1979) The effect of changes in endolymphatic ion concentrations on the tectorial membrane. Hear Res 1:81–94PubMedCrossRef

Ladhams A, Pickles JO (1996) Morphology of the monotreme organ of corti and macula lagena. J Comp Neurol 366:335–347PubMedCrossRef

Lavender D, Taraskin SN, Mason MJ (2011) Mass distribution and rotational inertia of "microtype" and "freely mobile" middle ear ossicles in rodents. Hear Res 282:97–107

Li Y, Liu Z, Shi P, Zhang J (2010) The hearing gene prestin unites echolocating bats and whales. Curr Biol 20:R55–R56PubMedCrossRef

Liu Y, Cotton JA, Shen B, Han X, Rossiter SJ, Zhang S (2010) Convergent sequence evolution between echolocating bats and dolphins. Curr Biol 20:R53–R54PubMedCrossRef

Luo Z-X (2007) Transformation and diversification in early mammal evolution. Nature 450:1011–1019PubMedCrossRef

Luo Z, Ketten DR (1991) CT scanning and computerized reconstructions of the inner ear of multituberculates mammals. J Vert Paleontol 11:220–228CrossRef

Luo Z-X, Ruf I, Schultz JA, Martin T (2010) Fossil evidence on evolution of inner ear cochlea in Jurassic mammals. Proc Roy Soc B 278:28–34CrossRef

Manley GA (1972) Frequency response of the middle ear of geckos. J Comp Physiol 81:251–258CrossRef

Manley GA (1973) A review of some current concepts of the functional evolution of the ear in terrestrial vertebrates. Evolution 26:608–621CrossRef

Manley GA (1990) Peripheral hearing mechanisms in reptiles and birds. Springer, HeidelbergCrossRef

Manley GA (2010) An evolutionary perspective on middle ears. Hear Res 263:3–8PubMedCrossRef

Manley GA, Clack JA (2004) An outline of the evolution of vertebrate hearing organs. In: Manley GA, Popper A, Fay RR (eds) Evolution of the vertebrate auditory system. Springer, New York, pp 1–26CrossRef

Martin T, Luo Z-X (2005) Homoplasy in the mammalian ear. Science 307:861–862CrossRef

Masterton B, Heffner H, Ravizza R (1969) The evolution of human hearing. J Acoust Soc Amer 45:966–985CrossRef

McGowan MR, Spaulding M, Gatesy J (2009) Divergence date estimation and a comprehensive molecular tree of extant cetaceans. Mol Phylogenet Evol 53:891–906CrossRef

McGowan MR (2011) Towards a resolution of an explosive radiation—a multilocus phylogeny of oceanic dolphins (Delphinidae). Mol Phylogenet Evol 60:345–357CrossRef

Meng J, Fox RC (1995) Therian petrosals from the Oldman and Milk River formations (Late Cretaceous), Alberta, Canada. J Vert Paleontol 15:122–130CrossRef

Meng J, Wang Y, Li C (2011) Transitional mammalian middle ear from a new Cretaceous Jehol eutriconodont. Nature 472:181–185PubMedCrossRef

Mills DM, Shepherd RK (2001) Distortion product otoacoustic emission and auditory brainstem response in the echidna (Tachyglossus aculeatus). JARO 2:130–146PubMedCrossRef

Müller M, Laube B, Burda H, Bruns V (1992) Structure and function of the cochlea in the African mole rat (Cryptomys hottentotus): evidence for a low frequency acoustic fovea. J Comp Physiol A 171:469–476PubMed

Novacek MJ (1977) Aspects of the problem of variation, origin and evolution of the eutherian auditory bulla. Mamml Rev 7:131–149

Nummela S, Thewissen JGM, Bajpai S, Hussain T, Kumar K (2007) Sound transmission in archaic and modern whales: anatomical adaptations for underwater hearing. Anat Rec 290:716–733CrossRef

Plassmann W, Brindle K (1992) A functional model of the auditory system in mammals and its evolutionary implications. In: Webster DB, Fay RR, Popper AN (eds) The evolutionary biology of hearing. Springer, New York, pp 637–653CrossRef

Puria S, Steele C (2010) Tympanic-membrane and malleus–incus-complex co-adaptations for high-frequency hearing in mammals. Hear Res 253:183–190CrossRef

Ravicz ME, Slama MCC, Rosowski JJ (2010) Middle-ear pressure gain and cochlear partition differential pressure in chinchilla. Hear Res 263:16–25PubMedCrossRef

Rich TH, Hopson JA, Musser AM, Flannery TF, Vickers-Rich P (2005) Independent origins of middle ear bones in monotremes and therians. Science 307:910–914PubMedCrossRef

Rosowski JJ (1992) Hearing in transitional mammals: predictions from the middle-ear anatomy and hearing capabilities of extant mammals. In: Webster DB, Fay RR, Popper AN (eds) The evolutionary biology of hearing. Springer, New York, pp 615–631CrossRef

Rosowski JJ, Graybeal A (1991) What did Morganucodon hear? Zool J Linnean Soc 101:131–168CrossRef

Rowe T (1988) Definition, diagnosis, and origin of Mammalia. J Vert Paleontol 8:241–264CrossRef

Ruf I, Luo Z-X, Wible JR, Martin T (2009) Petrosal anatomy and inner ear structures of the late Jurassic Henkelotherium (Mammalia, Cladotheria, Dryolestoidea): insight into the early evolution of the ear region in cladotherian mammals. J Anat 214:679–693PubMedCrossRef

Ruggero MA, Temchin AN (2002) The roles of the external, middle, and inner ears in determining the bandwidth of hearing. PNAS 99:13206–13210PubMedCrossRef

Schmitz L, Motani R (2011) Nocturnality in dinosaurs inferred from scleral ring and orbit morphology. Science 332:705–708PubMedCrossRef

Shoshani J, McKenna MC (1998) Higher taxanomic relationships among extant mammals based on morphology, with selected comparisons of results from molecular data. Mol Phylogenet Evol 9:572–584PubMedCrossRef

Sim JH, Puria S (2008) Soft tissue morphometry of the malleus–incus complex from micro-CT imaging. JARO 9:5–21PubMedCrossRef

Simmons NB, Seymour KL, Habersetzer J, Gunnell GF (2008) Primitive Early Eocene bat from Wyoming and the evolution of flight and echolocation. Nature 451:818–821PubMedCrossRef

Takechi M, Kuratani S (2010) History of studies on mammalian middle ear evolution: a comparative morphological and developmental biology perspective. J Exp Zool (Mol Dev Evol) 314B:417–433CrossRef

Tan X, Pecka JL, Tang J, Okoruwa OE, Zhang Q, Beisel KW, He DZZ (2011) From zebrafish to mammal: functional evolution of prestin, the motor protein of cochlear outer hair cells. J Neurophysiol 105:36–44PubMedCrossRef

Vater M, Meng J, Fox RC (2004) Hearing organ evolution and specialization: early and later mammals. In: Manley GA, Popper A, Fay RR (eds) Evolution of the vertebrate auditory system. Springer, New York, pp 256–288CrossRef

Wang Y, Hu Y, Meng J, Li C (2001) An ossified Meckel's cartilage in two Cretaceous mammals and origin of the mammalian middle ear. Science 294:357–361PubMedCrossRef

Watson DMS (1953) The evolution of the mammalian ear. Evolution 7:159–177CrossRef

West CD (1985) The relationship of the spiral turns of the cochlea and the length of the basilar membrane to the range of audible frequencies in ground dwelling mammals. J Acoust Soc Amer 77:1091–1101CrossRef

Wible JR (1990) Petrosals of Late Cretaceous marsupials from North America, and a cladistic analysis of the petrosals in therian mammals. J Vert Paleontol 10:183–205CrossRef

Wible JR (1991) Origin of Mammalia: the craniodental evidence re-examined. J Vert Paleontol 11:1–28CrossRef

Wible JR, Rougier GW, Novacek MJ, McKenna MC (2001) Earliest eutherian ear region: a petrosal referred to Prokennalestes from the early Cretaceous of Mongolia. Amer Mus Nov 3322:1–44CrossRef

Woodburne MO, Rich TH, Springer MS (2003) The evolution of tribospheny and the antiquity of mammalian clades. Mol Phylogenet Evol 28:360–385PubMedCrossRef

Zhou X, Xu S, Yang Y, Zhou K, Yang G (2011) Phylogenomic analyses and improved resolution of Cerartiodactyla. Mol Phylogenet Evol 61:255–264PubMedCrossRef

Title: Evolutionary Paths to Mammalian Cochleae
Author: Geoffrey A. Manley
Publication date: 01-12-2012
Publisher: Springer-Verlag
Published in: Journal of the Association for Research in Otolaryngology / Issue 6/2012
Print ISSN: 1525-3961
Electronic ISSN: 1438-7573
DOI: https://doi.org/10.1007/s10162-012-0349-9

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Evolutionary Paths to Mammalian Cochleae

Abstract

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 6/2012

Auditory Nerve Frequency Tuning Measured with Forward-Masked Compound Action Potentials

Hyperpolarization-Activated Current (I h) in Vestibular Calyx Terminals: Characterization and Role in Shaping Postsynaptic Events

Level-Dependent Changes in Perception of Speech Envelope Cues

Perilymph Pharmacokinetics of Markers and Dexamethasone Applied and Sampled at the Lateral Semi-Circular Canal

Temporal-Envelope Reconstruction for Hearing-Impaired Listeners

Brainstem Auditory Evoked Potentials Suggest a Role for the Ventral Cochlear Nucleus in Tinnitus