Jason R. Meyers

Late-Stage Neuronal Progenitors in the Retina Are Radial Müller Glia That Function as Retinal Stem Cells

Neuronal progenitors in the mammalian brain derive from radial glia or specialized astrocytes. In developing neural retina, radial glia-like Müller cells are generated late in neurogenesis and are not considered to be neuronal progenitors, but they do proliferate after injury and can express neuronal markers, suggesting a latent neurogenic capacity. To examine the neurogenic capacity of retinal glial cells, we used lineage tracing in transgenic zebrafish with a glial-specific promoter (gfap, for glial fibrillary acid protein) driving green fluorescent protein in differentiated Müller glia. We found that all Müller glia in the zebrafish retina express low levels of the multipotent progenitor marker Pax6 (paired box gene 6), and they proliferate at a low frequency in the intact, uninjured retina. Müller glia-derived progenitors express Crx (cone rod homeobox) and are late retinal progenitors that generate the rod photoreceptor lineage in the postembryonic retina. These Müller glia-derived progenitors also remain competent to produce earlier neuronal lineages, in that they respond to loss of cone photoreceptors by specifically regenerating the missing neurons. We conclude that zebrafish Müller glia function as multipotent retinal stem cells that generate retinal neurons by homeostatic and regenerative developmental mechanisms.

β-catenin/Wnt signaling controls progenitor fate in the developing and regenerating zebrafish retina

BackgroundThe zebrafish retina maintains two populations of stem cells: first, the germinal zone or ciliary marginal zone (CMZ) contains multipotent retinal progenitors that add cells to the retinal periphery as the fish continue to grow; second, radial glia (Müller cells) occasionally divide asymmetrically to generate committed progenitors that differentiate into rod photoreceptors, which are added interstitially throughout the retina with growth. Retinal injury stimulates Müller glia to dedifferentiate, re-enter the cell cycle, and generate multipotent retinal progenitors similar to those in the CMZ to replace missing neurons. The specific signals that maintain these two distinct populations of endogenous retinal stem cells are not understood.ResultsWe used genetic and pharmacological manipulation of the β-catenin/Wnt signaling pathway to show that it is required to maintain proliferation in the CMZ and that hyperstimulation of β-catenin/Wnt signaling inhibits normal retinal differentiation and expands the population of proliferative retinal progenitors. To test whether similar effects occur during regeneration, we developed a method for making rapid, selective photoreceptor ablations in larval zebrafish with intense light. We found that dephosphorylated β-catenin accumulates in Müller glia as they re-enter the cell cycle following injury, but not in Müller glia that remain quiescent. Activation of Wnt signaling is required for regenerative proliferation, and hyperstimulation results in loss of Müller glia from the INL as all proliferative cells move into the ONL.Conclusionsβ-catenin/Wnt signaling is thus required for the maintenance of retinal progenitors during both initial development and lesion-induced regeneration, and is sufficient to prevent differentiation of those progenitors and maintain them in a proliferative state. This suggests that the β-catenin/Wnt cascade is part of the shared molecular circuitry that maintains retinal stem cells for both homeostatic growth and epimorphic regeneration.

Shape Change Controls Supporting Cell Proliferation in Lesioned Mammalian Balance Epithelium

Mature mammals are uniquely vulnerable to permanent auditory and vestibular deficits, because the cell proliferation that produces replacement hair cells in other vertebrates is limited in mammals. To investigate the cellular mechanisms responsible for that difference, we created excision lesions in the sensory epithelium of embryonic and 2-week-old mouse utricles. Lesions in embryonic utricles closed in <24 h via localized expansion of supporting cells, which then reentered the cell cycle. Pharmacological treatments combined with time-lapse microscopy demonstrated that the healing depended on Rho-mediated contraction of an actin ring at the leading edge of the lesion. In contrast, lesions in utricles from 2-week-old and older mice remained open even after 48 h. Supporting cells in those utricles remained compact and columnar and had significantly stouter cortical actin belts than those in embryonic sensory epithelia. This suggests that cytoskeletal changes may underlie the age-related loss of proliferation in mammalian ears by limiting the capacity for mature supporting cells to change shape. In mature utricles, exogenous stimulation with lysophosphatidic acid overcame this maturational block and induced closure of lesions, promoting supporting cell expansion and subsequent proliferation. After lysophosphatidic acid treatment, 85% of the mature supporting cells that had spread to a planar area >300 μm2 entered S-phase, whereas only 10% of those cells that had a planar area <100 μm2 entered S-phase. Together, these results indicate that cellular shape change can overcome the normal postnatal cessation of supporting cell proliferation that appears to limit regeneration in mammalian vestibular epithelia.

Activation of canonical Wnt/β-catenin signaling stimulates proliferation in neuromasts in the zebrafish posterior lateral line.

Background: The posterior lateral line in zebrafish develops from a migrating primordium that deposits clusters of cells that differentiate into neuromasts at regular intervals along the trunk. The deposition of these neuromasts is known to be coordinated by Wnt and FGF signals that control the proliferation, migration, and organization of the primordium. However, little is known about the control of proliferation in the neuromasts following their deposition. Results: We show that pharmacological activation of the Wnt/β‐catenin signaling pathway with 1‐azakenpaullone upregulates proliferation in neuromasts post‐deposition. This results in increased size of the neuromasts and overproduction of sensory hair cells. We also show that activation of Wnt signaling returns already quiescent supporting cells to a proliferative state in mature neuromasts. Additionally, activation of Wnt signaling increases the number of supporting cells that return to the cell cycle in response to hair cell damage and the number of regenerated hair cells. Finally, we show that inhibition of Wnt signaling by overexpression of dkk1b suppresses proliferation during both differentiation and regeneration. Conclusions: These data suggest that Wnt/β‐catenin signaling is both necessary and sufficient for the control of proliferation of lateral line progenitors during development, ongoing growth of the neuromasts, and hair cell regeneration. Developmental Dynamics 242:832–846, 2013.

Solitary Hair Cells Are Distributed Throughout the Extramacular Epithelium in the Bullfrog's Saccule

The frog inner ear contains eight sensory organs that provide sensitivities to auditory, vestibular, and ground-borne vibrational stimuli. The saccule in bullfrogs is responsible for detecting ground- and air-borne vibrations and is used for studies of hair cell physiology, development, and regeneration. Based on hair bundle morphology, a number of hair cell types have been defined in this organ. Using immunocytochemistry, vital labeling, and electron microscopy, we have characterized a new hair cell type in the bullfrog saccule. A monoclonal antibody that is specific to hair cells revealed that a population of solitary hair cells exists outside the sensory macula in what was previously thought to be nonsensory epithelium. We call these extramacular hair cells. There are 80–100 extramacular hair cells in both tadpole and adult saccules, which extend up to 1 mm from the edge of the sensory macula. The extramacular hair cells have spherical cell bodies and small apical surfaces. Even in adults, the hair bundles of the extramacular cells appear immature, with a long kinocilium (6–9 μm) and short stereocilia (0.5–2 μm). At least 90% of extramacular hair cells are likely to be innervated as demonstrated by labeling of nerve fibers with an antineurofilament antibody. The extramacular hair cells may differentiate in regions just beyond the edge of the macula at an early stage in development and then be pushed out via the interstitial growth of the epithelium that surrounds the macula. It is also possible that they may be produced from cell divisions in the extramacular epithelium that has not been considered capable of giving rise to hair cells.

Sulf1 modulates BMP signaling and is required for somite morphogenesis and development of the horizontal myoseptum.

Heparan sulfate proteoglycans (HSPGs) are glycosylated extracellular or membrane-associated proteins. Their unbranched heparan sulfate (HS) disaccharide chains interact with many growth factors and receptors, modifying their activity or diffusion. The pattern of HS sulfation can be altered by the enzymes Sulf1 and Sulf2, secreted extracellular 6-O endosulfatases, which remove specific sulfate groups from HS. Modification by Sulf enzymes changes the binding affinity of HS for protein such as ligands and receptors, affecting growth factor gradients and activities. The precise expression of these sulfatases are thought to be necessary for normal development. We have examined the role of the sulf1 gene in trunk development of zebrafish embryos. sulf1 is expressed in the developing trunk musculature and as well as in midline structures such as the notochord, floorplate and hypochord. Knockdown of sulf1 with antisense morpholinos results in poor differentiation of the somitic trunk muscle, loss of the horizontal myoseptum, lack of pigmentation along the mediolateral stripe, and improper migration of the lateral line primordium. sulf1 knockdown results in a decrease in the number of Pax7-expressing dermomyotome cells, particularly along the midline where the horizontal myoseptum develops. It also leads to decreased sdf1/cxcl12 expression along the mediolateral trunk musculature. Both the Pax7 and cxcl12 expression can be restored by inhibition pharmacological inhibition of BMP signaling, which also restores formation of the myoseptum, fast muscle development, and pigmentation patterning. Lateral line migration and neuromast deposition depend on sdf1/cxcl12 and FGF signaling respectively, both of which are disrupted in sulf1 morphants. Pharmacological activation of FGF signaling can rescue the spacing of neuromast deposition in these fish. Together this data indicate that sulf1 plays a crucial role in modulating both BMP and FGF signaling along the developing myoseptum to coordinate the morphogenesis of trunk musculature, associated pigment cells, and lateral line neuromasts.

Variations in Shape-Sensitive Restriction Points Mirror Differences in the Regeneration Capacities of Avian and Mammalian Ears

When inner ear hair cells die, humans and other mammals experience permanent hearing and balance deficits, but non-mammalian vertebrates quickly recover these senses after epithelial supporting cells give rise to replacement hair cells. A postnatal decline in cellular plasticity appears to limit regeneration in mammalian balance organs, where declining proliferation responses are correlated with decreased spreading of supporting cells on artificial and native substrates. By culturing balance epithelia on substrates that differed in flexibility, we assessed spreading effects independent of age, showing a strong correlation between shape change and supporting cell proliferation. Then we made excision wounds in utricles cultured from young and old chickens and mice and compared quantified levels of spreading and proliferation. In utricles from young mice, and both young and old chickens, wounds re-epithelialized in <24 hours, while those in utricles from mature mice took three times longer. More cells changed shape in the fastest healing wounds, which accounted for some differences in the levels of proliferation, but inter-species and age-related differences in shape-sensitive restriction points, i.e., the cellular thresholds for shape changes that promote S-phase, were evident and may be particularly influential in the responses to hair cell losses in vivo.

Morphological Correlates of Regeneration and Repair in the Inner Ear

The loss of hair cells is a major cause of disabling hearing impairments that affect approximately 250 million persons worldwide and a contributor to inner ear balance disorders that can lead to falls late in life. Normal healthy human inner ears contain approximately 16,000 hair cells in the sound sensing cochlea, around 8000 hair cells in each of the three rotation sensitive semicircular canal cristae, and 18,000–33,000 hair cells each in the gravity sensing utriculus and sacculus (Fig. 2.1; Rosenhall 1972; Wright et al. 1987). The majority of people will lose some of those hair cells as they mature and age and many will develop age-related deficits of hearing called presbycusis (Fig. 2.2; Bredberg 1968; Rosenhall 1973). Presbycusis and age-related deterioration of vestibular reflexes correlate with declines in the numbers of cochlear and vestibular hair cells, respectively (Fig. 2.2; Bredberg 1968; Rosenhall 1973; Paige 1992). Hair cells can be damaged and killed by loud sounds, infections, head trauma, and autoimmune disorders. The clinical use of aminoglycoside antibiotics and certain chemotherapeutic agents such as cisplatin can also cause hair cell loss. As life expectancies have lengthened, the occurrence of hearing and balance disabilities has grown, because hair cell losses in humans and other mammals are permanent and cumulative. In contrast to mammals, many nonmammalian vertebrates produce hair cells throughout life and regenerate replacements for hair cells that have been lost. The replacement cells become innervated, which leads to the restoration of hearing and balance sensitivity, usually within a matter of weeks. Hair cell regeneration also occurs in the lateral line neuromasts of fish and amphibians, which share many aspects of tissue structure and organization with the hearing and balance end organs of the ear (Fig. 2.3). This chapter reviews and discusses current understanding and highlights unresolved questions pertaining to morphological aspects of the mechanisms that

Hair Cell Regeneration

Hair cells are the sensory cells in the inner ear, and damage to or loss of the cells results in auditory and/or vestibular deficit. In nonmammalian vertebrates, neighboring supporting cells return to the cell cycle and divide and their progeny differentiate into replacement hair cells and supporting cells. These replacement hair cells become innervated and bring about the restoration of auditory or vestibular function. In mammals, such regenerative proliferation is limited, and sensory deficits from the loss of hair cells appear to be permanent. Ongoing work seeks to understand the mechanisms behind regeneration and how to promote regeneration in the mammalian inner ear.

Axon cap morphology of the sea robin (Prionotus carolinus): mauthner cell is correlated with the presence of “signature” field potentials and a C‐Type startle response

Studies on the Mauthner cell (M‐cell) of goldfish, Carassius auratus, have facilitated our understanding of how sensory information is integrated in the hindbrain to initiate C‐type fast startle responses (C‐starts). The goldfish M‐cell initial segment/axon hillock is surrounded by a composite axon cap consisting of a central core and a peripheral zone covered by a glial cell layer. The high resistivity of the axon cap results in “signature” field potentials recorded on activation of the M‐cell, allowing unequivocal physiological identification of the M‐cell and of its feedback and reciprocal inhibitory networks that are crucial in ensuring that only one M‐cell is active and that it fires only once. Phylogenetic mapping of axon cap morphology to muscle activity patterns and behavior predicts that teleost fishes that have a composite axon cap, like that of the goldfish, will perform C‐start behavior with primarily unilateral muscle activity. We have chosen to study these predictions in the northern sea robin, Prionotus carolinus, a percomorph fish. Although sea robins have a very different phylogenetic position, body form, and habitat compared with the goldfish, they display the correlation of axon cap morphology to physiology and C‐start behavior. Differences in response parameters suggest some evolutionary trade‐offs in sea robin C‐start behavior compared with that of the goldfish, but the correlations in morphology, physiology, and behavior are common features of both otophysan and nonotophysan teleosts. The M‐cell will continue to provide an unprecedented opportunity to study the evolution of a neural circuit in the context of behavior. J. Comp. Neurol. 519:1979–1998, 2011.