Role of histone deacetylase activity in the developing lateral line neuromast of zebrafish larvae

Histone deacetylases are involved in many biological processes and have roles in regulating cell behaviors such as cell cycle entry, cell proliferation and apoptosis. However, the effect of histone deacetylases on the development of hair cells (HCs) has not been fully elucidated. In this study, we examined the influence of histone deacetylases on the early development of neuromasts in the lateral line of zebrafish. Hair cell development was evaluated by fluorescent immunostaining in the absence or presence of histone deacetylase inhibitors. Our results suggested that pharmacological inhibition of histone deacetylases with inhibitors, including trichostatin A, valproic acid and MS-275, reduced the numbers of both HCs and supporting cells in neuromasts. We also found that the treatment of zebrafish larvae with inhibitors caused accumulation of histone acetylation and suppressed proliferation of neuromast cells. Real-time PCR results showed that the expression of both p21 and p27 mRNA was increased following trichostatin A treatment and the increase in p53 mRNA was modest under the same conditions. However, the expression of p53 mRNA was significantly increased by treatment with a high concentration of trichostatin A. A high concentration of trichostatin A also led to increased cell death in neuromasts as detected in a TUNEL assay. Moreover, the nuclei of most of these pyknotic cells were immunohistochemically positive for cleaved caspase-3. These results suggest that histone deacetylase activity is involved in lateral line development in the zebrafish and might have a role in neuromast formation by altering cell proliferation through the expression of cell cycle regulatory proteins.

Developmental Role of Anoctamin-1/TMEM16A in Ca2+-Dependent Volume Change in Supporting Cells of the Mouse Cochlea

Mammalian cochlea undergoes morphological and functional changes during the postnatal period, around the hearing onset. Major changes during the initial 2 postnatal weeks of mouse include maturation of sensory hair cells and supporting cells, and acquisition of afferent and efferent innervations. During this period, supporting cells in the greater epithelial ridge (GER) of the cochlea exhibit spontaneous and periodic activities which involves ATP, increase in intracellular Ca2+, and cell volume change. This Ca2+-dependent volume change has been proposed to involve chloride channels or transporters. We found that the spontaneous volume changes were eliminated by anion channel blocker, 100 microM NPPB. Among candidates, expression of Anoctamin-1 (Ano1 or TMEM16A), bestriphin-1 and NKCC1 were investigated in whole-mount cochlea of P9-10 mice. Immunolabeling indicated high level of Ano1 expression in the GER, but not of betrophin-1 or NKCC1. Double-labeling with calretinin and confocal image analysis further elucidated the cellular localization of Ano1 immunoreactivity in supporting cells. It was tested if the Ano1 expression exhibits similar time course to the spontaneous activities in postnatal cochlear supporting cells. Cochlear preparations from P2-3, P5-6, P9-10, P15-16 mice were subjected to immunolabeling. High level of Ano1 immunoreactivity was observed in the GER of P2-3, P5-6, P9-10 cochleae, but not of P15-17 cochleae. Taken together, the localization and time course in Ano1 expression pattern correlates with the spontaneous, periodic volume changes recorded in postnatal cochlear supporting cells. From these results we propose that Ano1 is the pacemaker of spontaneous activities in postnatal cochlea.

The Past and Present of the Research on Cochlear Stem Cell / 대한이비인후과학회지

Hearing loss is the most frequent sensory deficit in the human population and can occur at any age. Hearing loss ranges from mild to profound, can be conductive, sensorineural or mixed type and may be congenital or acquired. Sometimes, some of hearing loss can be cured by medical or surgical interventions but most of hearing loss is irreversible and many patients struggle in their daily activities and their quality of life suffers. Although hearing aids as well as cochlear implants can give good solution to patients with a hearing loss that cannot be cured, both of them have some limitations and cannot solve the hearing problem perfectly. Recent scientific achievements in cochlear stem cell research and regenerative medicine can suggest ultimate solution to researchers as well as doctors and can give a hope to patients with a hearing loss and their family. Until now, mammalian cochlear hair cells have been known to be never replaced or regenerated, such that insults to the cochlea cause progressive and permanent hearing loss of variable degree. However, non-mammalian vertebrates are capable of replacing lost hair cells and have stem cells in their cochlea, which has recently led to efforts to understand the molecular and cellular basis of regenerative responses in different vertebrate species. In this article, I review the development of mammalian cochlea, focusing on the molecular events related with the development and regeneration. I also introduce the progress in overcoming the limits to mammalian cochlear hair cell regeneration and recent efforts to cochlear regenerative medicine.

The Effects of Neurotransmitters on the Ion Channels in the Isolated Deiters'Cells of Guinea Pig Cochlea / 대한이비인후과학회지

BACKGROUND AND OBJECTIVES: The supporting cells in the organ of Corti help to maintain the structural integrity of the organ, but it has been suggested that they also actively participate in regulating sound transduction. The existence of neural control was implied by the finding of efferent synapses in Deiters' cells, and the fact that the intracellular Ca2+ concentration was increased by the application of neurotransmitters, such as ATP (adenosine triphosphate) and Ach (acetylcholine), resulting in movement of the phalangeal processes of the Deiters' cells. This study investigated the effects of neurotransmitters on the ion channels in Deiters' cells. MATERIALS AND METHOD: Deiters' cells were isolated from guinea pig organs of Corti using collagenase and pipettes. Whole-cell patch clamps were performed under an inverted microscope and the current was measured with pClamp 8.0.2 software. RESULTS: The resting membrane potential was -21.1+/-3.5 mV. ATP (100 microM) treatment depolarized the potential to -3.1+/-1.1 mV, while the same concentration of Ach had no effect on the resting potential. In the voltage-clamping condition, the holding potential was 0 mV, and then a -80 mV pre-pulse was applied for 500 ms, followed by step pulses from -140 to +10 mV. Under these conditions, 10 microM ATP increased the inward current from -14.9+/-1.9 to -163.5+/-14.9 pA/pF at the maximal stimulus of -140 mV (n=4). In the current-voltage curve, the reversal potential was around -20 mV. Neither Ach nor carbachol induced current responses. The co-application of suramin (30 microM) and ATP (10 microM) suppressed the ATP-induced currents by 50%, and 30 microM of PPADS (pyridoxal-phosphate- 6-azophenyl-2, 4-disulphonic acid) inhibited the current almost to the level of the control. The purinoceptor-agonist, alpha, beta-meATP (alpha, beta-methylene adenosine triphosphate), 30 microM increased the inward current from -16.2+/-2.9 to -27.7+/-3.8 pA/pF, which was much smaller than the ATP-induced change. CONCLUSION: ATP-gated purinergic receptors may play an important role in regulating sound transduction by inducing an inward current and depolarizing the Deiters' cell membrane.