Research reportThe development of stereociliary bundles in the cochlear duct of chick embryos
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Cited by (78)
The contributions of Dr. Kathleen K. Sulik to fetal alcohol spectrum disorders research and prevention
2018, AlcoholCitation Excerpt :She began her career studying the pathogenesis of cleft lip and palate (Johnston & Sulik, 1979; Miller & Atnip, 1977; Miller, 1977; Sulik & Atnip, 1978; Sulik, Johnston, Ambrose, & Dorgan, 1979; Tyan & Miller, 1978). She moved on to investigate the normal development of the inner ear and other structures derived from neural crest cells (Cotanche & Sulik, 1982, 1983, 1984, 1985; Cotanche, Cotton, Gatzy, & Sulik, 1987; Sulik et al., 2001), the pathogenesis of diverse developmental disorders, such as Treacher Collins and Smith-Lemli-Opitz syndromes (Dehart, Lanoue, Tint, & Sulik, 1997; Sulik, Johnston, Smiley, Speight, & Jarvis, 1987; Sulik, Smiley, Turvey, Speight, & Johnston, 1989; Waage-Baudet, Dunty, Dehart, Hiller, & Sulik, 2005), and the teratology of retinoic acid, anticonvulsants, ochratoxin, chemotherapeutic agents, and infectious agents (Alles & Sulik, 1990; Chernoff et al., 1989; Cook & Sulik, 1988; Darab, Minkoff, Sciote, & Sulik, 1987; Francis et al., 1990; Mesrobian, Sessions, Lloyd, & Sulik, 1994; Peiffer, McCullen, Alles, & Sulik, 1991; Sulik et al., 1987, 1989, 1979; Sulik & Dehart, 1988; Sulik, Dehart, Rogers, & Chernoff, 1995; Webster, Johnston, Lammer, & Sulik, 1986). Finally, she was the first to show that the primitive node, the site on the embryo that initiates gastrulation (the formation of the three germ layers), contained motile cilia (Sulik et al., 1994), structures that are crucial to determining left-right asymmetry (Zhang, Ramalho-Santos, & McMahon, 2001).
Firing properties of auditory primary afferents from the basilar papilla in the chick
2015, International Journal of Developmental NeuroscienceCitation Excerpt :The studies by Manley et al. (1991) and Jones and Jones (2000) are also consistent with other reports in which the pattern of spontaneous activity of afferent neurons is considered as a good physiological marker in the functionality of the inner ear afferent fibers (Whitehead and Morest, 1985; Jones and Jones, 2000; Shao et al., 2006a; Sonntag et al., 2009; Kalluri et al., 2010). For example, the maturation process described for spontaneous discharge of cochlear neurons is congruent with the temporal course of morphological and functional changes described for the chick’s auditory system (Ryals et al., 1984; Fermin and Cohen, 1984; Cotanche and Sulik, 1984; Cohen and Fermin, 1985; Tilney et al., 1986). Therefore, in order to compare physiological changes in the auditory system during development it is important to analyze changes in the discharge patterns of the afferent neurons, at least around E19, as inferred from the abovementioned studies.
A brief history of hair cell regeneration research and speculations on the future
2013, Hearing ResearchCitation Excerpt :Remarkably however, 2 days later, small stereociliary bundles began populating the area where hair cells had been lost. In addition, apical surfaces of the cells with these small bundles bore a striking resemblance to immature hair cells and the sequence of stereociliary differentiation paralleled that seen in embryogenesis over the course of 10 days of recovery (Fig. 2; Cotanche and Sulik, 1984; Cotanche, 1987b). Taken together, data from these two labs strongly suggested that new hair cells were being produced in the mature basilar papilla to replace those destroyed by aminoglycoside treatment or noise trauma.
Fgf signaling regulates development and transdifferentiation of hair cells and supporting cells in the basilar papilla
2012, Hearing ResearchCitation Excerpt :The initial progenitor cell (PC) population forms a pseudostratified epithelium with multiple layers of disorganized nuclei (Fig. 1A). As the distal-to-proximal gradient of HC differentiation begins, the epithelium reorganizes (Fig. 1B) to form a single lumenal layer of HCs with several layers of SCs located more basally (Cotanche and Sulik, 1984). Recent work has demonstrated that formation of the PC population, often referred to as prosensory cells in mammals, is dependent on expression of the transcription factor Sox2 and activation of the Notch signaling pathway (Basch et al., 2011; Daudet and Lewis, 2005; Daudet et al., 2007; Kiernan et al., 2005; Yamamoto et al., 2011), while subsequent development of some PCs into HCs requires expression of another transcription factor, Atoh1 (Bermingham et al., 1999; Woods et al., 2004).
Hair cell fate decisions in cochlear development and regeneration
2010, Hearing ResearchFeathers and fins: Non-mammalian models for hair cell regeneration
2009, Brain ResearchCitation Excerpt :In contrast, no ongoing hair cell production occurs in the chicken auditory epithelium (Oesterle and Rubel, 1993). Rather, progenitor cells are mitotically quiescent by mid-embryogenesis, and cellular differentiation is completed by hatching (Cohen and Fermin, 1978; Cotanche and Sulik, 1984; Tilney et al., 1986). Production of new hair cells is only triggered by hair cell damage (Cruz et al., 1987; Corwin and Cotanche, 1988; Ryals and Rubel, 1988; Oesterle and Rubel, 1993), and the replacement of hair cells leads to near-complete recovery of auditory and vestibular function within 1–2 months (reviewed in Bermingham-McDonogh and Rubel, 2003).