Transforming the vestibular system one molecule at a time: The molecular and developmental basis of vertebrate auditory evolution

Advances in Experimental Medicine and Biology

Volumn 739, Issue , 2012, Pages 173-186

  Duncan, Jeremy S ^a   Fritzsch, Bernd ^a  

^a UNIVERSITY OF IOWA   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

BETA CATENIN; BRAIN DERIVED NEUROTROPHIC FACTOR RECEPTOR; CYCLIN DEPENDENT KINASE INHIBITOR 1B; MESSENGER RNA; NEUROGENIC DIFFERENTIATION FACTOR; NEUROGENIN 1; NEUROTROPHIN; TRANSCRIPTION FACTOR; TRANSCRIPTION FACTOR ATOH1; TRANSCRIPTION FACTOR GATA 2; TRANSCRIPTION FACTOR GATA 3; TRANSCRIPTION FACTOR MASH1; TRANSCRIPTION FACTOR OTX2; TRANSCRIPTION FACTOR PAX2; TRANSCRIPTION FACTOR PAX258; TRANSCRIPTION FACTOR PAX6; TRANSCRIPTION FACTOR PAX8; UNCLASSIFIED DRUG; WNT PROTEIN;

ACOUSTIC NERVE FIBER; ARTICLE; ATOH1 GENE; AUDITORY RESPONSE; CELL CYCLE REGULATION; CELL PROLIFERATION; CELLULAR DISTRIBUTION; COPY NUMBER VARIATION; FOXG1 GENE; GENE; GENE DELETION; GENE DUPLICATION; GENE LOCATION; GENE LOSS; GENE SEGREGATION; HEARING; INNER EAR; INTRACELLULAR SIGNALING; MOLECULAR DYNAMICS; MOLECULAR EVOLUTION; NEUROMODULATION; NONHUMAN; OTX1 GENE; PRIORITY JOURNAL; PROTEIN EXPRESSION; PROTEIN FUNCTION; PROTEIN LOCALIZATION; STRUCTURE ANALYSIS; VESTIBULAR SYSTEM; ANIMAL; CYTOLOGY; EFFERENT NERVE; EPITHELIUM; GROWTH, DEVELOPMENT AND AGING; HUMAN; METABOLISM; PHYSIOLOGY; REVIEW; SENSORY RECEPTOR; VESTIBULE;

MAMMALIA; MUS; VERTEBRATA;

ANIMALS; EPITHELIUM; EVOLUTION, MOLECULAR; HUMANS; NEURONS, EFFERENT; SENSORY RECEPTOR CELLS; VESTIBULE, LABYRINTH;

EID: 84859541922     PISSN: 00652598     EISSN: None     Source Type: Book Series    
DOI: 10.1007/978-1-4614-1704-0_11     Document Type: Article

References (68)

1. Fritzsch B, Eberl DF, Beisel KW. The role of bHLH genes in ear development and evolution: revisiting a 10-year-old hypothesis. Cell Mol Life Sci 2010; 67(18):3089-3099.
2. Spring J, Yanze N, Josch C et al. Conservation of Brachyury, Mef2, and Snail in the myogenic lineage of jellyfish: a connection to the mesoderm ofbilateria. Dev Biol2002; 244(2):372-384.
3. Reichert C. Uber die Visceralbogen der Wirbeltiere im allgemeinen und deren Metamorphose bei den Vogeln und Saugetieren. Arch Anat Physiol 1837; 120-222.
4. Gaupp E. Ontogenese und Phylogenese des schalleitenden Apparates bei den Wirbeltieren. Erg Anat Entwicklungsgesch 1898; (8):990-1149.
5. Knoll AH, Carroll SB. Early animal evolution: emerging views from comparative biology and geology. Science 1999; 284(5423):2129-2137.
6. Clack J. The stapes of Acanthostega gunnari and the role of the stapes in early tetrapods. In: DB W, AN P, Fay RR. eds. The Evolutionary Biology of Hearing. New York: Springer-Verlag 1992; 405-419.
7. Jarvik E. Basic Structure and Evolution of Vertebrates, Vol. 1. London: Academic Press; 1980.
8. Carrol R. Vertebrate Palaeontology and Evolution. New York: Freeman; 1988.
9. Thewissen JG, Cohn MJ, Stevens LS et al. Developmental basis for hind-limb loss in dolphins and origin of the cetacean bodyplan. Proc Natl Acad Sci U S A 2006; 103(22):8414-8418.
10. Eberl DF, Boekhoff-Falk G. Development of Johnston's organ in Drosophila. Int J Dev Biol 2007; 51(6-7):679-687.
11. Budelmann B. Morphological diversity of equilibirum receptor systems in aquatic invertebrates. In: Atema J, Popper AN, Tavolga W, eds. Sensory Biology of Aquatic Animals. New York: Springer-Verlag 1987; 757-782.
12. Fritzsch B, Beisel KW, Pauley S et al. Molecular evolution of the vertebrate mechanosensory cell and ear. Int J Dev Biol 2007; 51(6-7):663-678.
13. Ayers H. Vertebrate cephalogensis. Journal of Morphology 1892; 6:1-360.
14. van Bergeijk WA. The evolution ofvertebrate hearing. In: NeffWD, ed. Contributions to Sensory Physiology. Vol 2. Berlin and New York: Springer-Verlag 1967; 1-49.
15. Streit A. The preplacodal region: an ectodermal domain with multipotential progenitors that contribute to sense organs and cranial sensory ganglia. Int J Dev Biol 2007; 51(6-7):447-461.
16. Groves AK, Bronner-Fraser M. Competence, specification and commitment in otic placode induction. Development 2000; 127(16):3489-3499.
17. Fritz sch B, Barald K, Lomax M. Early embryology of the vertebrate ear. In: Rubel EW, Popper AN, Fay RR, eds. Development of the Auditory System. New York: Springer-Verlag 1998; 80-145.
18. Burighel P, Caicci F, Zaniolo G et al. Does hair cell differentiation predate the vertebrate appearance? Brain Res Bull 2008; 75(2-4):331-334.
19. Padanad MS, Riley BB. Pax2/8 proteins coordinate sequential induction of otic and epibranchial placodes through differential regulation of foxi1, sox3 and fgf24. Dev Biol. 2011; 351(1):90-98.
20. Bouchard M, de Caprona D, Busslinger M et al. Pax2 and Pax8 cooperate in mouse inner ear morphogenesis and innervation. BMC Dev Biol 2010; 10:89.
21. Li H, Liu H, Corrales CE et al. Correlation of Pax-2 expression with cell proliferation in the developing chicken inner ear. J Neurobiol 2004; 60(1):61-70.
22. Halder G, Callaerts P, Gehring WJ. New perspectives on eye evolution. Curr Opin Genet Dev 1995; 5(5):602-609.
23. Fritzsch B, Beisel KW. Molecular conservation and novelties in vertebrate ear development. Curr Top Dev Biol 2003; 57:1-44.
24. Pierce ML, Weston MD, Fritzsch B et al. MicroRNA-183 family conservation and ciliated neurosensory organ expression. Evol Dev 2008; 10(1):106-113.
25. Fritzsch B, Wake MH. The inner-ear of gymnophione amphibians and its nerve supply a comparative-study of regressive events in a complex sensory system (amphibia, gymnophiona). Zoomorphology 1988; 108(4):201-217.
26. Fritzsch B, Beisel KW, Jones K et al. Development and evolution of inner ear sensory epithelia and their innervation. J Neurobiol 2002; 53(2):143-156.
27. Norris HW. Studies on the development of the ear in Amblystoma I. Developemnt of the auditory vesicle. Journal of Morphology 1892; 7:23-34.
28. Nichols DH, Pauley S, Jahan I et al. Lmx1a is required for segregation of sensory epithelia and normal ear histogenesis and morphogenesis. Cell Tissue Res 2008; 334(3):339-358.
29. Tomsa JM, Langeland JA. Otx expression during lamprey embryogenesis provides insights into the evolution of the vertebrate head and jaw. Dev Biol 1999; 207(1):26-37.
30. Mazan S, Jaillard D, Baratte B et al. Otx1 gene-controlled morphogenesis of the horizontal semicircular canal and the origin of the gnathostome characteristics. Evol Dev 2000; 2(4):186-193.
31. Fritzsch B, Signore M, Simeone A. Otxl null mutant mice show partial segregation of sensory epithelia comparable to lamprey ears. Dev Genes Evol 2001; 211(8-9):388-396.
32. Pauley S, Lai E, Fritzsch B. Foxg1 is required for morphogenesis and histogenesis of the mammalian inner ear. Dev Dyn 2006; 235(9):2470-2482.
33. Wever EG. The evolution of vertebrate hearing. In: Keidel WD, Neff WD, eds. Auditory System Vol V.1 1974; 423-454.
34. Fritzsch B. Hearing in two worlds: Theoretical and realistic adaptive changes of the aquatic and terrectrial ear for sound reception. In: Fay RR, Popper AN, eds. Comparative Hearing: Fish and Amphibians. New York: Springer-Verlag 1999; 15-42.
35. Fritzsch B. The water-to-land transition: Evolution ofthe tetrapod basilar papilla, middle ear and auditory nuclei. The Evolutionary Biology of Hearing. New York: Springer Verlag 1992; 351-375.
36. Farinas I, Jones KR, Tessarollo L et al. Spatial shaping of cochlear innervation by temporally regulated neurotrophin expression. J Neurosci 2001; 21(16):6170-6180.
37. Morsli H, Choo D, Ryan A et al. Development of the mouse inner ear and origin of its sensory organs. J Neurosci 1998; 18(9):3327-3335.
38. Cole LK, Le Roux I, Nunes F et al. Sensory organ generation in the chicken inner ear: contributions of bone morphogenetic protein 4, serrate1 and lunatic fringe. J Comp Neurol 2000; 424(3):509-520.
39. Fritzsch B. On the role played by ontogenetic remodeling and functional transformation in the evolution of terrestrial hearing. Brain Behav Evol 1997; 50(1):38-49.
40. Kopecky B, Santi P, Johnson S et al. Conditional deletion ofN-myc distrupts neurosensory and non-sensory development of the ear. Devlopmental Dynamics 2011 In Press.
41. Qian D, Jones C, Rzadzinska A et al. Wnt5a functions in planar cell polarity regulation in mice. Dev Biol 2007; 306(1):121-133.
42. Ladher RK, Wright TJ, Moon AM et al. FGF8 initiates inner ear induction in chick and mouse. Genes Dev 2005; 19(5):603-613.
43. Jacques BE, Montcouquiol ME, Layman EM et al. Fgf8 induces pillar cell fate and regulates cellular patterning in the mammalian cochlea. Development 2007; 134(16):3021-3029.
44. Pirvola U, Ylikoski J, Trokovic R et al. FGFR1 is required for the development of the auditory sensory epithelium. Neuron 2002; 35(4):671-680.
45. Duncan JS, Lim KC, Engel JD et al. Limited inner ear morphogenesis and neurosensory development are possible in the absence of Gata3. Int J Dev Biol 2011 (accepted).
46. Fritzsch B. Development of inner ear afferent connections: forming primary neurons and connecting them to the developing sensory epithelia. Brain Res Bull 2003; 60(5-6):423-433.
47. Bell D, Streit A, Gorospe I et al. Spatial and temporal segregation of auditory and vestibular neurons in the otic placode. Dev Biol 2008; 322(1):109-120.
48. Ma Q, Anderson DJ, Fritzsch B. Neurogenin 1 null mutant ears develop fewer, morphologically normal hair cells in smaller sensory epithelia devoid of innervation. Journal of the Association for Research in Otolaryngology: JARO 2000; 1(2):129-143.
49. Satoh T, Fekete DM. Clonal analysis of the relationships between mechanosensory cells and the neurons that innervate them in the chicken ear. Development 2005; 132(7):1687-1697.
50. Raft S, Koundakjian EJ, Quinones H et al. Cross-regulation of Ngn1 and Math1 coordinates the production of neurons and sensory hair cells during inner ear development. Development 2007; 134(24):4405-4415.
51. Tessarollo L, Coppola V, Fritzsch B. NT-3 replacement with brain-derived neurotrophic factor redirects vestibular nerve fibers to the cochlea. J Neurosci 2004; 24(10):2575-2584.
52. Jahan I, Pan N, Kersigo J et al. Neurod1 suppresses hair cell differentiation in ear ganglia and regulates hair cell subtype development in the cochlea. PLoS One 2010; 5(7):e11661.
53. Striedter G. Principles of Brain Evolution. Sunderland MA: Sinauer Associates; 2004.
54. Fritzsch B. Experimental reorganization in the alar plate of the clawed toad, Xenopus laevis. I. Quantitative and qualitative effects of embryonic otocyst extirpation. Brain Res Dev Brain Res 1990; 51(1):113-122.
55. Bullock TH, Heiligenberg W. Electroreception. New York: Wiley and Sons; 1986.
56. Fritzsch B. The pattern of lateral-line afferents in urodeles. A horseradish-peroxidase study. Cell Tissue Res 1981; 218(3):581-594.
57. Fritzsch B, Ryan M, Wilczynski W et al, eds. The evolution of the amphibian auditory system. New York: Wiley & Sons 1988.
58. McCormick CA. Anatomy of the central auditory pathways of fish and amphibians. In: Popper AN, Fay RR, eds. Comparative Hearing: Fish and Amphibians. New York: Springer-Verlag 1999; 155-217.
59. Rubel EW, Fritzsch B. Auditory system development: primary auditory neurons and their targets. Annu Rev Neurosci 2002; 25:51-101.
60. Levi-Montalcini R. The development to the acousticovestibular centers in the chick embryo in the absence of the afferent root fibers and of descending fiber tracts. J Comp Neurol 1949; 91(2):209-241, illust, incl 203 pl.
61. Elliott KL, Fritzsch B. Transplantation of Xenopus laevis ears reveals the ability to form afferent and efferent connections with the spinal cord. Int J Dev Biol 2010; 54(10):1443-1451.
62. Bermingham NA, Hassan BA, Price SD et al. Math1: an essential gene for the generation of inner ear hair cells. Science 1999; 284(5421):1837-1841.
63. Liu M, Pereira FA, Price SD et al. Essential role of BETA2/NeuroD1 in development of the vestibular and auditory systems. Genes Dev 2000; 14(22):2839-2854.
64. Kim WY, Fritzsch B, Serls A et al. NeuroD-null mice are deaf due to a severe loss of the inner ear sensory neurons during development. Development 2001; 128(3):417-426.
65. Maricich SM, Xia A, Mathes EL et al. Atoh1-lineal neurons are required for hearing and for the survival of neurons in the spiral ganglion and brainstem accessory auditory nuclei. J Neurosci 2009; 29(36):11123-11133.
66. Roberts BL, Meredith GE. The efferent innervation of the ear: Variations on an enigma. New York: Springer-Verlag; 1992.
67. Fritzsch B. Ontogenetic and Evolutionary evidence for the motoneuron nature of vestibular and cochlear efferents. In: Berlin C, ed. The Efferent Auditory System: Basic Science and Clinical Applications: Singular Publishing Group, Inc, 1999; 31.
68. Simmons D, Duncan J, Caprona DC et al. Development of the inner ear efferent system. Auditory and Vestibular Efferents Vol 38. New York: Springer 2011; 187-216.