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Invited Revie W Role of Diffusible and Transcription Factors in Inner Ear

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Invited Revie W Role of Diffusible and Transcription Factors in Inner Ear Histol Histopathol (2000) 15: 657-666 Histology and http://www.ehu.es/histol-histopathol Histopathology Cellular and Molecular Biology Invited Revie W Role of diffusible and transcription factors in inner ear development: implications in regeneration L.M. Fragol, G. Camarerol, S. CaA6n1, C. PaAedal, C. Sanzl, Y. Leoni, F. Giraldez2 and I. Varela-Nietol 'Institute of Biomedical Research "Alberto Sols", CSIC-UAM, Madrid, Spain and *Institute of Biology and Molecular Genetic (IBGM), University of Valladolid-CSIC, School of Medicine, Valladolid, Spain Summary. Organogenesis involves a dynamic balance show an elaborated spatial organisation responsible for of the mechanisms regulating cell division, the different functions of the organ: the vestibular differentiation and death. The development of the portion of the ear is responsible for the senses of motion chicken embryo inner ear offers a well-characterised and position while the auditory or cochlear region is model at the morphological level to study which signals responsible for the sense of hearing. In both portions, are implicated in the modulation of cellular activation hair cells convert mechanical stimulation into electrical and commitment. The early developmental decisions signals, which are then processed by the nervous system. that control the origin of the inner ear elements are just Hair cells are innervated by sensory neurons that project beginning to be identified by complementary in vivo and towards specific nuclei in the central nervous system. in vitro studies. Insulin-like growth factor-I (IGF-I) and The development of the chicken embryo inner ear offers nerve growth factor (NGF) are among the best a well-characterised model at the morphological level to characterised diffusible factors acting during inner ear study which signals are implicated in the modulation of development. Although the cellular actions of these cellular proliferation, differentiation and programmed factors are beginning to be understood, the signalling cell death (Fekete, 1996). pathways triggered by them still remain largely The vertebrate inner ear originates from the head unknown. In this context, viral vehicles can be used to ectoderm where the otic placode is formed. After it deliver genes and then analyse their functional roles invaginates to form the otic pit that latter closes forming during inner ear development. A model is proposed the otic vesicle or otocyst (Fig. 1). This is a transient where the actions of IGF-I and NGF contribute to the structure that undergoes a distinct period of intense cell combinatorial expression of Jun and Fos family proliferation (stages 18-22 in the chicken, Hamburguer members in particular domains of the otic vesicle. Some and Hamilton, 1951) that precedes the differentiation of of these mechanisms may be also implicated in otic the various cell types and compartments that will regeneration. conform the adult inner ear (Bissonnette and Fekete, 1996). Neuroblasts for the cochleo-vestibular ganglion Key words: Apoptosis, Insulin-like growth factor-I, (CVG) migrate out from the medial wall of the otic Nerve growth factor, RCAS retroviral vectors, Jun vesicle. The CVG contains the afferent neurons that signalling pathways connect the sensory epithelium of the inner ear to the central nervous system (Hemond and Morest, 1991). Later in development, the CVG is separated into two 1. The early development of the vertebrate inner ear ganglia that innervate separately the cochlear and vestibular parts of the inner ear connecting them to the The adult inner ear in vertebrates is a complex, central nervous system. highly-differentiated structure responsible for audition, There are several experimental approaches to study the perception of movement, and the sense of inner ear development in the chicken embryo. In vivo equilibrium. It contains more than a dozen different cell studies facilitate the analysis of the expression of target types, which include neurons, sensory hair cells, genes in whole mount preparations and also the study of secretory cells, and supporting cells. These cell types are cell proliferation and cell death patterns through organised in functional regions (www.iurc.montp. development (reviewed by Torres and Giraldez, 1998). inserm.fr/cric/audition). Different regions of the ear Embryonic day 2.5 (E2.5) otic vesicles can be dissected and the explants cultured to analyse the role of Offprint requests to: Dr. lsabel Varela-Nieto, lnstituto de lnvestigaciones extracellular factors and intracellular signals in a defined Biomedicas "Alberto Sols", CSIC-UAM, Arturo Duperier 4, 28029 medium (Le6n et al., 1998; Torres and Giraldez, 1998). Madrid, Spain. Fax: 34-91-5854587. e-mail: [email protected] Finally, viral vehicles can be used to deliver genes and .
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