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2. Insulin-like growth factor 1 is required for survival of transit-amplifying neuroblasts and differentiation of otic neurons

Author

Camarero, G., Leon, Y., Gorospe, I., De Pablo, F., Alsina, B., Giraldez, F., and Varela-Nieto, I.

Subjects
Insulin-like growth factor 1 -- Research, Biological sciences
Abstract

Neurons that connect mechanosensory hair cell receptors to the central nervous system derive from the otic vesicle from where otic neuroblasts delaminate and form the cochleovestibular ganglion (CVG). Local signals interact to promote this process, which is autonomous and intrinsic to the otic vesicle. We have studied the expression and activity of insulin-like growth factor-1 (IGF-1) during the formation of the chick CVG, focusing attention on its role in neurogenesis. IGF-1 and its receptor (IGFR) were detected at the mRNA and protein levels in the otic epithelium and the CVG. The function of IGF-1 was explored in explants of otic vesicle by assessing the formation of the CVG in the presence of anti-IGF-1 antibodies or the receptor competitive antagonist JB1. Interference with IGF-1 activity inhibited CVG formation in growth factor-free media, revealing that endogenous IGF-1 activity is essential for ganglion generation. Analysis of cell proliferation cell death, and expression of the early neuronal antigens Tuj-1, Islet-1/2, and G4 indicated that IGF-1 was required for survival, proliferation, and differentiation of an actively expanding population of otic neurobtasts. IGF-1 blockade, however, did not affect NeuroD within the otic epithelium. Experiments carried out on isolated CVG showed that exogenous IGF-1 induced cell proliferation, neurite outgrowth, and G4 expression. These effects of IGF-1 were blocked by JB1. These findings suggest that IGF-1 is essential for neurogenesis by allowing the expansion of a transit-amplifying neuroblast population and its differentiation into postmitotic neurons. IGF-1 is one of the signals underlying autonomous development of the otic vesicle. Keywords: Sensory organs; Ectodermal placodes; IGF-1; Neurogenesis; Otic vesicle autonomy; Cell proliferation; Cell differentiation; Cell survival

Published
2003

5. Sculpting the labyrinth: Morphogenesis of the developing inner ear

Author

Alsina, B. and Whitfield, T.T.

Subjects
animal structures, embryonic structures, otorhinolaryngologic diseases, sense organs
Abstract

The vertebrate inner ear is a precision sensory organ, acting as both a microphone to receive sound and an accelerometer to detect gravity and motion. It consists of a series of interlinked, fluid-filled chambers containing patches of sensory epithelia, each with a specialised function. The ear contains many different differentiated cell types with distinct morphologies, from the flask-shaped hair cells found in thickened sensory epithelium, to the thin squamous cells that contribute to non-sensory structures, such as the semicircular canal ducts. Nearly all cell types of the inner ear, including the afferent neurons that innervate it, are derived from the otic placode, a region of cranial ectoderm that develops adjacent to the embryonic hindbrain. As the ear develops, the otic epithelia grow, fold, fuse and rearrange to form the complex three-dimensional shape of the membranous labyrinth. Much of our current understanding of the processes of inner ear morphogenesis comes from genetic and pharmacological manipulations of the developing ear in mouse, chicken and zebrafish embryos. These traditional approaches are now being supplemented with exciting new techniques-including force measurements and light-sheet microscopy-that are helping to elucidate the mechanisms that generate this intricate organ system.

Published
2016

7. Sensational placodes: Neurogenesis in the otic and olfactory systems

Author

Maier, E.C, Saxena, A, Alsina, B, Bronner, M.E, and Whitfield, T.T

Abstract

For both the intricate morphogenetic layout of the sensory cells in the ear and the elegantly radial arrangement of the sensory neurons in the nose, numerous signaling molecules and genetic determinants are required in concert to generate these specialized neuronal populations that help connect us to our environment. In this review, we outline many of the proteins and pathways that play essential roles in the differentiation of otic and olfactory neurons and their integration into their non-neuronal support structures. In both cases, well-known signaling pathways together with region-specific factors transform thickened ectodermal placodes into complex sense organs containing numerous, diverse neuronal subtypes. Olfactory and otic placodes, in combination with migratory neural crest stem cells, generate highly specialized subtypes of neuronal cells that sense sound, position and movement in space, odors and pheromones throughout our lives.

Published
2014

9. Dbx1 is a direct target of SOX3 in the spinal cord.

Author

Alsina, B, Rogers, N, McAninch, D, Thomas, P, Alsina, B, Rogers, N, McAninch, D, and Thomas, P

Abstract

SoxB1 sub-family of transcriptional regulators are expressed in progenitor (NP) cells throughout the neuroaxis and are generally downregulated during neuronal differentiation. Gain- and loss-of-function studies indicate that Sox1, Sox2 and Sox3 are key regulators of NP differentiation and that their roles in CNS development are largely redundant. Nevertheless, mutation of each SoxB1 individually results in a different array of CNS defects, raising the possibility that SoxB1 proteins have subtly different functions in NP cells. To explore the mechanism of SOXB1 functional redundancy, and to identify genes that are most sensitive to loss of the Sox3 gene, we performed genome wide expression profiling of Sox3 null NP cells. Nineteen genes with abnormal expression were identified, including the homeobox gene Dbx1. Analysis of Sox3 null embryos revealed that Dbx1 was significantly reduced in the neural tube and developing brain and that SOX3 bound directly to conserved elements associated with this gene in cultured NP cells and in vivo. These data define Dbx1 as a direct SOX3 target gene whose expression, intriguingly, is not fully rescued by other SOXB1 transcription factors, suggesting that there are inherent differences in SOXB1 protein activity.

Published
2014

10. Multiple enhancers located in a 1-Mb region upstream of POU3F4 promote expression during inner ear development and may be required for hearing.

Author

Naranjo, S., Voesenek, K.E.J., Calle-Mustienes, E. de la, Robert-Moreno, A., Kokotas, H., Grigoriadou, M., Economides, J., Camp, G. van, Hilgert, N., Moreno, F., Alsina, B., Petersen, M.B., Kremer, J.M.J., Gomez-Skarmeta, J.L., Naranjo, S., Voesenek, K.E.J., Calle-Mustienes, E. de la, Robert-Moreno, A., Kokotas, H., Grigoriadou, M., Economides, J., Camp, G. van, Hilgert, N., Moreno, F., Alsina, B., Petersen, M.B., Kremer, J.M.J., and Gomez-Skarmeta, J.L.

Abstract

1 oktober 2010, Contains fulltext : 89315.pdf (publisher's version ) (Closed access), POU3F4 encodes a POU-domain transcription factor required for inner ear development. Defects in POU3F4 function are associated with X-linked deafness type 3 (DFN3). Multiple deletions affecting up to ~900-kb upstream of POU3F4 are found in DFN3 patients, suggesting the presence of essential POU3F4 enhancers in this region. Recently, an inner ear enhancer was reported that is absent in most DFN3 patients with upstream deletions. However, two indications suggest that additional enhancers in the POU3F4 upstream region are required for POU3F4 function during inner ear development. First, there is at least one DFN3 deletion that does not eliminate the reported enhancer. Second, the expression pattern driven by this enhancer does not fully recapitulate Pou3f4 expression in the inner ear. Here, we screened a 1-Mb region upstream of the POU3F4 gene for additional cis-regulatory elements and searched for novel DFN3 mutations in the identified POU3F4 enhancers. We found several novel enhancers for otic vesicle expression. Some of these also drive expression in kidney, pancreas and brain, tissues that are known to express Pou3f4. In addition, we report a new and smallest deletion identified so far in a DFN3 family which eliminates 3.9 kb, comprising almost exclusively the previous reported inner ear enhancer. We suggest that multiple enhancers control the expression of Pou3f4 in the inner ear and these may contribute to the phenotype observed in DFN3 patients. In addition, the novel deletion demonstrates that the previous reported enhancer, although not sufficient, is essential for POU3F4 function during inner ear development.

Published
2010

11. DARENET: A novel technological platform to promote the use of zebrafish model

Author

Pardo, M.A., primary, Rainieri, S., additional, Muriana, A., additional, Callol, C., additional, Gómez, J.L., additional, Díaz, E., additional, Cayuela, M.L., additional, Figueras, A., additional, Sarasquete, C., additional, Fernández de Mera, I.G., additional, Rodríguez, R.E., additional, Barrallo, A., additional, Coll, J., additional, Burgos, J.S., additional, Caballero, J.M., additional, Montero, J.A., additional, Mulero, V., additional, Cajaraville, M.P., additional, Alsina, B., additional, Rodríquez, J.F., additional, and Sela, E., additional

Published
2009
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13. Wnt9a deficiency discloses a repressive role of Tcf7l2 on endocrine differentiation in the embryonic pancreas

Author

Pujadas i Rovira, Gemma, Cervantes, Sara, Tutusaus, Anna, Ejarque, M., Sanchez, Lidia, García, A., Esteban, Yaiza, Fargas, L., Alsina, B., Hartmann, C., Gomis, Ramon, 1946, Gasa, Rosa, and Universitat de Barcelona

Subjects
Embryology, Microxips d'ADN, Embriologia, Endocrinologia molecular, DNA microarrays, Pancreas, Molecular endocrinology, Pàncrees
Abstract

Transcriptional and signaling networks establish complex cross-regulatory interactions that drive cellular differentiation during development. Using microarrays we identified the gene encoding the ligand Wnt9a as a candidate target of Neurogenin3, a basic helix-loop-helix transcription factor that functions as a master regulator of pancreatic endocrine differentiation. Here we show that Wnt9a is expressed in the embryonic pancreas and that its deficiency enhances activation of the endocrine transcriptional program and increases the number of endocrine cells at birth. We identify the gene encoding the endocrine transcription factor Nkx2-2 as one of the most upregulated genes in Wnt9a-ablated pancreases and associate its activation to reduced expression of the Wnt effector Tcf7l2. Accordingly, in vitro studies confirm that Tcf7l2 represses activation of Nkx2-2 by Neurogenin3 and inhibits Nkx2-2 expression in differentiated β-cells. Further, we report that Tcf7l2 protein levels decline upon initiation of endocrine differentiation in vivo, disclosing the downregulation of this factor in the developing endocrine compartment. These findings highlight the notion that modulation of signalling cues by lineage-promoting factors is pivotal for controlling differentiation programs. This work has been supported by the Spanish Ministerio de Ciencia e Innovación (BFU2008-02299/BMC to RGa), Ministerio de Economía y Competitividad/Instituto de Salud Carlos III (PI13/01500 to RGa) and Generalitat de Catalunya (2014 SGR659 to RGo). Predoctoral fellowships were provided by the Spanish Ministerio de Ciencia e Innovación (BES-2007- 17284, GP) and IDIBAPS (ME). The research leading to these results has received funding from the European Community’s Seventh Framework Programme (FP7/2009-2013) under the grant agreement n°229673 (SC). CIBERDEM (Centro de Investigación Biomédica en Red de Diabetes y Enfermedades Metabólicas Asociadas) is an initiative of the Instituto de Salud Carlos III.

15. Cellular diversity of human inner ear organoids revealed by single-cell transcriptomics.

Author

Rumbo M and Alsina B

Subjects
Humans, Cell Differentiation genetics, Cell Lineage genetics, Gene Expression Profiling, Organoids metabolism, Organoids cytology, Ear, Inner embryology, Ear, Inner cytology, Ear, Inner metabolism, Single-Cell Analysis methods, Transcriptome genetics
Abstract

Human inner ear organoids are three-dimensional tissular structures grown in vitro that recapitulate some aspects of the fetal inner ear and allow the differentiation of inner ear cell types. These organoids offer a system in which to study human inner ear development, mutations causing hearing loss and vertigo, and new therapeutic drugs. However, the extent to which such organoids mimic in vivo human inner ear development and cellular composition remains unclear. Several recent studies have performed single-cell transcriptomics on human inner ear organoids to interrogate cellular heterogeneity, reveal the developmental trajectories of sensory lineages and compare organoid-derived vesicles to the developing human inner ear. Here, we discuss the new insights provided by these analyses that help to define new paths of investigation to understand inner ear development., (© 2024. Published by The Company of Biologists Ltd.)

Published
2024
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16. Pioneer statoacoustic neurons guide neuroblast behaviour during otic ganglion assembly.

Author

Bañón A and Alsina B

Subjects
Animals, Cell Differentiation genetics, Hair Cells, Auditory physiology, Sensory Receptor Cells, Zebrafish genetics, Ear, Inner metabolism
Abstract

Cranial ganglia are aggregates of sensory neurons that mediate distinct types of sensation. The statoacoustic ganglion (SAG) develops into several lobes that are spatially arranged to connect appropriately with hair cells of the inner ear. To investigate the cellular behaviours involved in the 3D organization of the SAG, we use high-resolution confocal imaging of single-cell, labelled zebrafish neuroblasts (NBs), photoconversion, photoablation, and genetic perturbations. We show that otic NBs delaminate out of the otic epithelium in an epithelial-mesenchymal transition-like manner, rearranging apical polarity and primary cilia proteins. We also show that, once delaminated, NBs require RhoGTPases in order to perform active migration. Furthermore, tracking of recently delaminated NBs revealed their directed migration and coalescence around a small population of pioneer SAG neurons. These pioneer SAG neurons, not from otic placode origin, populate the coalescence region before otic neurogenesis begins and their ablation disrupts delaminated NB migratory pathways, consequentially affecting SAG shape. Altogether, this work shows for the first time the role of pioneer SAG neurons in orchestrating SAG development., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2023. Published by The Company of Biologists Ltd.)

Published
2023
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17. Wiring the senses: Factors that regulate peripheral axon pathfinding in sensory systems.

Author

Nomdedeu-Sancho G and Alsina B

Subjects
Animals, Sensory Receptor Cells, Neuroglia, Sense Organs, Axon Guidance, Axons physiology
Abstract

Sensory neurons of the head are the ones that transmit the information about the external world to our brain for its processing. Axons from cranial sensory neurons sense different chemoattractant and chemorepulsive molecules during the journey and in the target tissue to establish the precise innervation with brain neurons and/or receptor cells. Here, we aim to unify and summarize the available information regarding molecular mechanisms guiding the different afferent sensory axons of the head. By putting the information together, we find the use of similar guidance cues in different sensory systems but in distinct combinations. In vertebrates, the number of genes in each family of guidance cues has suffered a great expansion in the genome, providing redundancy, and robustness. We also discuss recently published data involving the role of glia and mechanical forces in shaping the axon paths. Finally, we highlight the remaining questions to be addressed in the field., (© 2022 The Authors. Developmental Dynamics published by Wiley Periodicals LLC on behalf of American Association for Anatomy.)

Published
2023
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19. Polyphosphate degradation by Nudt3-Zn 2+ mediates oxidative stress response.

Author

Samper-Martín B, Sarrias A, Lázaro B, Pérez-Montero M, Rodríguez-Rodríguez R, Ribeiro MPC, Bañón A, Wolfgeher D, Jessen HJ, Alsina B, Clotet J, Kron SJ, Saiardi A, Jiménez J, and Bru S

Subjects
Acid Anhydride Hydrolases genetics, Acid Anhydride Hydrolases physiology, Animals, HEK293 Cells, Humans, Male, Mammals metabolism, Oxidation-Reduction, Phosphoric Monoester Hydrolases physiology, Rats, Rats, Sprague-Dawley, Substrate Specificity physiology, Zebrafish, Zinc metabolism, Acid Anhydride Hydrolases metabolism, Oxidative Stress physiology, Polyphosphates metabolism
Abstract

Polyphosphate (polyP) is a polymer of hundreds of phosphate residues present in all organisms. In mammals, polyP is involved in crucial physiological processes, including coagulation, inflammation, and stress response. However, after decades of research, the metabolic enzymes are still unknown. Here, we purify and identify Nudt3, a NUDIX family member, as the enzyme responsible for polyP phosphatase activity in mammalian cells. We show that Nudt3 shifts its substrate specificity depending on the cation; specifically, Nudt3 is active on polyP when Zn 2+ is present. Nudt3 has in vivo polyP phosphatase activity in human cells, and importantly, we show that cells with altered polyP levels by modifying Nudt3 protein amount present reduced viability upon oxidative stress and increased DNA damage, suggesting that polyP and Nudt3 play a role in oxidative stress protection. Finally, we show that Nudt3 is involved in the early stages of embryo development in zebrafish., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2021
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20. Mechanisms of cell specification and differentiation in vertebrate cranial sensory systems.

Author

Alsina B

Subjects
Animals, Cell Lineage, Cellular Reprogramming, Humans, Morphogenesis, Cell Differentiation, Skull cytology, Vertebrates physiology
Abstract

Vertebrates sense a large variety of sensory stimuli that ranges from temperature, volatile and nonvolatile chemicals, touch, pain, light, sound and gravity. To achieve this, they use specialized cells present in sensory organs and cranial ganglia. Much of our understanding of the transcription factors and mechanisms responsible for sensory cell specification comes from cell-lineage tracing and genetic experiments in different species, but recent advances in single-cell transcriptomics, high-resolution imaging and systems biology approaches have allowed to study these processes in an unprecedented resolution. Here I will point to the transcription factor programs driving cell diversity in the different sensory organs of vertebrates to then discuss in vivo data of how cell specification is coupled with tissue morphogenesis., Competing Interests: Conflict of interest statement Nothing declared., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published
2020
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21. Sensory Neuroblast Quiescence Depends on Vascular Cytoneme Contacts and Sensory Neuronal Differentiation Requires Initiation of Blood Flow.

Author

Taberner L, Bañón A, and Alsina B

Subjects
Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Blood Circulation drug effects, Body Patterning drug effects, Bridged Bicyclo Compounds, Heterocyclic pharmacology, Cell Count, Cell Proliferation drug effects, Down-Regulation drug effects, Endothelial Cells drug effects, Endothelial Cells metabolism, Intracellular Signaling Peptides and Proteins metabolism, Nerve Tissue Proteins metabolism, Neurogenesis drug effects, Oxygen metabolism, Pseudopodia drug effects, Pseudopodia metabolism, Receptors, Notch metabolism, Sensory Receptor Cells drug effects, Sensory Receptor Cells metabolism, Signal Transduction drug effects, Skull blood supply, Thiazolidines pharmacology, Transcription, Genetic drug effects, Vestibulocochlear Nerve cytology, Vestibulocochlear Nerve metabolism, Zebrafish, Zebrafish Proteins metabolism, Blood Circulation physiology, Blood Vessels cytology, Cell Cycle drug effects, Cell Differentiation drug effects, Sensory Receptor Cells cytology
Abstract

In many organs, stem cell function depends on communication with their niche partners. Cranial sensory neurons develop in close proximity to blood vessels; however, whether vasculature is an integral component of their niches is yet unknown. Here, two separate roles for vasculature in cranial sensory neurogenesis in zebrafish are uncovered. The first involves precise spatiotemporal endothelial-neuroblast cytoneme contacts and Dll4-Notch signaling to restrain neuroblast proliferation. The second, instead, requires blood flow to trigger a transcriptional response that modifies neuroblast metabolic status and induces sensory neuron differentiation. In contrast, no role of sensory neurogenesis in vascular development is found, suggesting unidirectional signaling from vasculature to sensory neuroblasts. Altogether, we demonstrate that the cranial vasculature constitutes a niche component of the sensory ganglia that regulates the pace of their growth and differentiation dynamics., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Universitat Pompeu Fabra. Published by Elsevier Inc. All rights reserved.)

Published
2020
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22. Anatomical map of the cranial vasculature and sensory ganglia.

Author

Taberner L, Bañón A, and Alsina B

Subjects
Animals, Cranial Nerves embryology, Ganglia blood supply, Ganglia embryology, Blood Vessels embryology, Brain blood supply, Brain embryology, Cranial Nerves blood supply, Zebrafish embryology
Abstract

There is growing evidence of a direct influence of vasculature on the development of neurons in the brain. The development of the cranial vasculature has been well described in zebrafish but its anatomical relationship with the adjacent developing sensory ganglia has not been addressed. Here, by 3D imaging of fluorescently labelled blood vessels and sensory ganglia, we describe for the first time the spatial organization of the cranial vasculature in relation to the cranial ganglia during zebrafish development. We show that from 24 h post-fertilization (hpf) onwards, the statoacoustic ganglion (SAG) develops in direct contact with two main blood vessels, the primordial hindbrain channel and the lateral dorsal aortae (LDA). At 48 hpf, the LDA is displaced medially, losing direct contact with the SAG. The relationship of the other cranial ganglia with the vasculature is evident for the medial lateral line ganglion and for the vagal ganglia that grow along the primary head sinus (PHS). We also observed that the innervation of the anterior macula runs over the PHS vessel. Our spatiotemporal anatomical map of the cranial ganglia and the head vasculature indicates physical interactions between both systems and suggests a possible functional interaction during development., (© 2017 Anatomical Society.)

Published
2018
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23. Pioneer neurog1 expressing cells ingress into the otic epithelium and instruct neuronal specification.

Author

Hoijman E, Fargas L, Blader P, and Alsina B

Subjects
Animals, Body Patterning, Cell Movement, Basic Helix-Loop-Helix Transcription Factors metabolism, Ear embryology, Epithelium embryology, Nerve Tissue Proteins metabolism, Nervous System embryology, Neuroepithelial Cells physiology, Neurogenesis, Zebrafish embryology, Zebrafish Proteins metabolism
Abstract

Neural patterning involves regionalised cell specification. Recent studies indicate that cell dynamics play instrumental roles in neural pattern refinement and progression, but the impact of cell behaviour and morphogenesis on neural specification is not understood. Here we combine 4D analysis of cell behaviours with dynamic quantification of proneural expression to uncover the construction of the zebrafish otic neurogenic domain. We identify pioneer cells expressing neurog1 outside the otic epithelium that migrate and ingress into the epithelialising placode to become the first otic neuronal progenitors. Subsequently, neighbouring cells express neurog1 inside the placode, and apical symmetric divisions amplify the specified pool. Interestingly, pioneer cells delaminate shortly after ingression. Ablation experiments reveal that pioneer cells promote neurog1 expression in other otic cells. Finally, ingression relies on the epithelialisation timing controlled by FGF activity. We propose a novel view for otic neurogenesis integrating cell dynamics whereby ingression of pioneer cells instructs neuronal specification.

Published
2017
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24. Sculpting the labyrinth: Morphogenesis of the developing inner ear.

Author

Alsina B and Whitfield TT

Subjects
Animals, Cell Differentiation, Cell Movement, Chick Embryo, Ectoderm metabolism, Epithelial Cells metabolism, Gene Expression Regulation, Developmental, Hair Cells, Auditory metabolism, Labyrinth Supporting Cells metabolism, Mice, Species Specificity, Transcription Factors genetics, Transcription Factors metabolism, Zebrafish, Cell Lineage genetics, Ectoderm cytology, Epithelial Cells cytology, Hair Cells, Auditory cytology, Labyrinth Supporting Cells cytology, Organogenesis genetics
Abstract

The vertebrate inner ear is a precision sensory organ, acting as both a microphone to receive sound and an accelerometer to detect gravity and motion. It consists of a series of interlinked, fluid-filled chambers containing patches of sensory epithelia, each with a specialised function. The ear contains many different differentiated cell types with distinct morphologies, from the flask-shaped hair cells found in thickened sensory epithelium, to the thin squamous cells that contribute to non-sensory structures, such as the semicircular canal ducts. Nearly all cell types of the inner ear, including the afferent neurons that innervate it, are derived from the otic placode, a region of cranial ectoderm that develops adjacent to the embryonic hindbrain. As the ear develops, the otic epithelia grow, fold, fuse and rearrange to form the complex three-dimensional shape of the membranous labyrinth. Much of our current understanding of the processes of inner ear morphogenesis comes from genetic and pharmacological manipulations of the developing ear in mouse, chicken and zebrafish embryos. These traditional approaches are now being supplemented with exciting new techniques-including force measurements and light-sheet microscopy-that are helping to elucidate the mechanisms that generate this intricate organ system., (Copyright © 2016 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published
2017
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25. Retinoic Acid Signaling Mediates Hair Cell Regeneration by Repressing p27kip and sox2 in Supporting Cells.

Author

Rubbini D, Robert-Moreno À, Hoijman E, and Alsina B

Subjects
Animals, Animals, Genetically Modified, Cyclin-Dependent Kinase Inhibitor p27 antagonists & inhibitors, Female, Male, SOX Transcription Factors antagonists & inhibitors, Zebrafish, Zebrafish Proteins antagonists & inhibitors, Cyclin-Dependent Kinase Inhibitor p27 metabolism, Hair Cells, Auditory metabolism, Nerve Regeneration physiology, SOX Transcription Factors metabolism, Signal Transduction physiology, Tretinoin physiology, Zebrafish Proteins metabolism
Abstract

During development, otic sensory progenitors give rise to hair cells and supporting cells. In mammalian adults, differentiated and quiescent sensory cells are unable to generate new hair cells when these are lost due to various insults, leading to irreversible hearing loss. Retinoic acid (RA) has strong regenerative capacity in several organs, but its role in hair cell regeneration is unknown. Here, we use genetic and pharmacological inhibition to show that the RA pathway is required for hair cell regeneration in zebrafish. When regeneration is induced by laser ablation in the inner ear or by neomycin treatment in the lateral line, we observe rapid activation of several components of the RA pathway, with dynamics that position RA signaling upstream of other signaling pathways. We demonstrate that blockade of the RA pathway impairs cell proliferation of supporting cells in the inner ear and lateral line. Moreover, in neuromast, RA pathway regulates the transcription of p27(kip) and sox2 in supporting cells but not fgf3. Finally, genetic cell-lineage tracing using Kaede photoconversion demonstrates that de novo hair cells derive from FGF-active supporting cells. Our findings reveal that RA has a pivotal role in zebrafish hair cell regeneration by inducing supporting cell proliferation, and shed light on the underlying transcriptional mechanisms involved. This signaling pathway might be a promising approach for hearing recovery., Significance Statement: Hair cells are the specialized mechanosensory cells of the inner ear that capture auditory and balance sensory input. Hair cells die after acoustic trauma, ototoxic drugs or aging diseases, leading to progressive hearing loss. Mammals, in contrast to zebrafish, lack the ability to regenerate hair cells. Here, we find that retinoic acid (RA) pathway is required for hair cell regeneration in vivo in the zebrafish inner ear and lateral line. RA pathway is activated very early upon hair cell loss, promotes cell proliferation of progenitor cells, and regulates two key genes, p27(kip) and sox2. Our results position RA as an essential signal for hair cell regeneration with relevance in future regenerative strategies in mammals., (Copyright © 2015 the authors 0270-6474/15/3515752-15$15.00/0.)

Published
2015
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26. Mitotic cell rounding and epithelial thinning regulate lumen growth and shape.

Author

Hoijman E, Rubbini D, Colombelli J, and Alsina B

Subjects
Animals, Ear, Inner cytology, Embryo, Nonmammalian, Imaging, Three-Dimensional, Intracellular Fluid metabolism, Organogenesis, Zebrafish, Cell Shape, Ear, Inner embryology, Epithelial Cells cytology, Mitosis
Abstract

Many organ functions rely on epithelial cavities with particular shapes. Morphogenetic anomalies in these cavities lead to kidney, brain or inner ear diseases. Despite their relevance, the mechanisms regulating lumen dimensions are poorly understood. Here, we perform live imaging of zebrafish inner ear development and quantitatively analyse the dynamics of lumen growth in 3D. Using genetic, chemical and mechanical interferences, we identify two new morphogenetic mechanisms underlying anisotropic lumen growth. The first mechanism involves thinning of the epithelium as the cells change their shape and lose fluids in concert with expansion of the cavity, suggesting an intra-organ fluid redistribution process. In the second mechanism, revealed by laser microsurgery experiments, mitotic rounding cells apicobasally contract the epithelium and mechanically contribute to expansion of the lumen. Since these mechanisms are axis specific, they not only regulate lumen growth but also the shape of the cavity.

Published
2015
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27. LOXL2 Oxidizes Methylated TAF10 and Controls TFIID-Dependent Genes during Neural Progenitor Differentiation.

Author

Iturbide A, Pascual-Reguant L, Fargas L, Cebrià JP, Alsina B, García de Herreros A, and Peiró S

Subjects
Animals, Epigenesis, Genetic, HEK293 Cells, Humans, Methylation, Oxidation-Reduction, Transcription Factor TFIID metabolism, Zebrafish, Amino Acid Oxidoreductases physiology, Cell Differentiation, Neural Stem Cells physiology, Protein Processing, Post-Translational, TATA-Binding Protein Associated Factors metabolism, Transcription Factor TFIID physiology
Abstract

Protein function is often regulated and controlled by posttranslational modifications, such as oxidation. Although oxidation has been mainly considered to be uncontrolled and nonenzymatic, many enzymatic oxidations occur on enzyme-selected lysine residues; for instance, LOXL2 oxidizes lysines by converting the ε-amino groups into aldehyde groups. Using an unbiased proteomic approach, we have identified methylated TAF10, a member of the TFIID complex, as a LOXL2 substrate. LOXL2 oxidation of TAF10 induces its release from its promoters, leading to a block in TFIID-dependent gene transcription. In embryonic stem cells, this results in the inactivation of the pluripotency genes and loss of the pluripotent capacity. During zebrafish development, the absence of LOXL2 resulted in the aberrant overexpression of the neural progenitor gene Sox2 and impaired neural differentiation. Thus, lysine oxidation of the transcription factor TAF10 is a controlled protein modification and demonstrates a role for protein oxidation in regulating pluripotency genes., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published
2015
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29. The role of her4 in inner ear development and its relationship with proneural genes and Notch signalling.

Author

Radosevic M, Fargas L, and Alsina B

Subjects
Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Ear, Inner metabolism, Embryo, Nonmammalian, Gene Expression Regulation, Developmental, Hair Cells, Auditory, Inner metabolism, Nerve Tissue Proteins biosynthesis, Nerve Tissue Proteins genetics, Receptors, Notch biosynthesis, Receptors, Notch genetics, Sensory Receptor Cells metabolism, Signal Transduction genetics, Zebrafish, Zebrafish Proteins genetics, Basic Helix-Loop-Helix Transcription Factors biosynthesis, Ear, Inner growth & development, Embryonic Development, Neurogenesis, Zebrafish Proteins biosynthesis
Abstract

The generation of sensory neurons and hair cells of the inner ear is under tight control. Different members of the Hairy and Enhancer of Split genes (HES) are expressed in the inner ear, their full array of functions still not being disclosed. We have previously shown that zebrafish her9 acts as a patterning gene to restrict otic neurogenesis to an anterior domain. Here, we disclose the role of another her gene, her4, a zebrafish ortholog of Hes5 that is expressed in the neurogenic and sensory domains of the inner ear. The expression of her4 is highly dynamic and spatiotemporally regulated. We demonstrate by loss of function experiments that in the neurogenic domain her4 expression is under the regulation of neurogenin1 (neurog1) and the Notch pathway. Moreover, her4 participates in lateral inhibition during otic neurogenesis since her4 knockdown results in overproduction of the number of neurog1 and deltaB-positive otic neurons. In contrast, during sensorigenesis her4 is initially Notch-independent and induced by atoh1b in a broad prosensory domain. At later stages her4 expression becomes Notch-dependent in the future sensory domains but loss of her4 does not result in hair cell overproduction, suggesting that there other her genes can compensate its function.

Published
2014
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30. Sensational placodes: neurogenesis in the otic and olfactory systems.

Author

Maier EC, Saxena A, Alsina B, Bronner ME, and Whitfield TT

Subjects
Animals, Cell Differentiation genetics, Cell Differentiation physiology, Ear, Inner cytology, Ear, Inner metabolism, Ectoderm cytology, Ectoderm metabolism, Gene Expression Regulation, Developmental, Humans, Neurogenesis genetics, Olfactory Pathways cytology, Olfactory Pathways metabolism, Sense Organs cytology, Sense Organs metabolism, Sensory Receptor Cells cytology, Sensory Receptor Cells metabolism, Ear, Inner embryology, Ectoderm embryology, Neurogenesis physiology, Olfactory Pathways embryology, Sense Organs embryology
Abstract

For both the intricate morphogenetic layout of the sensory cells in the ear and the elegantly radial arrangement of the sensory neurons in the nose, numerous signaling molecules and genetic determinants are required in concert to generate these specialized neuronal populations that help connect us to our environment. In this review, we outline many of the proteins and pathways that play essential roles in the differentiation of otic and olfactory neurons and their integration into their non-neuronal support structures. In both cases, well-known signaling pathways together with region-specific factors transform thickened ectodermal placodes into complex sense organs containing numerous, diverse neuronal subtypes. Olfactory and otic placodes, in combination with migratory neural crest stem cells, generate highly specialized subtypes of neuronal cells that sense sound, position and movement in space, odors and pheromones throughout our lives., (Copyright © 2014 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2014
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31. β amyloid protein precursor-like (Appl) is a Ras1/MAPK-regulated gene required for axonal targeting in Drosophila photoreceptor neurons.

Author

Mora N, Almudi I, Alsina B, Corominas M, and Serras F

Subjects
Animals, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Drosophila, Drosophila Proteins genetics, Membrane Proteins genetics, Mitogen-Activated Protein Kinases genetics, Nerve Tissue Proteins genetics, Proto-Oncogene Proteins genetics, Proto-Oncogene Proteins metabolism, Proto-Oncogene Proteins c-ets genetics, Proto-Oncogene Proteins c-ets metabolism, Signal Transduction genetics, Signal Transduction physiology, Transcription Factors genetics, Transcription Factors metabolism, ras Proteins genetics, Drosophila Proteins metabolism, Membrane Proteins metabolism, Mitogen-Activated Protein Kinases metabolism, Nerve Tissue Proteins metabolism, Photoreceptor Cells cytology, Photoreceptor Cells metabolism, ras Proteins metabolism
Abstract

In a genome-wide expression profile search for genes required for Drosophila R7 photoreceptor development we found β amyloid protein precursor-like (Appl), the ortholog of human APP, which is a key factor in the pathogenesis of Alzheimer's disease. We analyzed Appl expression in the eye imaginal disc and found that is highly accumulated in R7 photoreceptor cells. The R7 photoreceptor is responsible for UV light detection. To explore the link between high expression of Appl and R7 function, we have analyzed Appl null mutants and found reduced preference for UV light, probably because of mistargeted R7 axons. Moreover, axon mistargeting and inappropriate light discrimination are enhanced in combination with neurotactin mutants. R7 differentiation is triggered by the inductive interaction between R8 and R7 precursors, which results in a burst of Ras1/MAPK, activated by the tyrosine kinase receptor Sevenless. Therefore, we examined whether Ras1/MAPK is responsible for the high Appl expression. Inhibition of Ras1 signaling leads to reduced Appl expression, whereas constitutive activation drives ectopic Appl expression. We show that Appl is directly regulated by the Ras/MAPK pathway through a mechanism mediated by PntP2, an ETS transcription factor that specifically binds ETS sites in the Appl regulatory region. We also found that zebrafish appb expression increased after ectopic fgfr activation in the neural tube of zebrafish embryos, suggesting a conserved regulatory mechanism.

Published
2013
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32. Her9 represses neurogenic fate downstream of Tbx1 and retinoic acid signaling in the inner ear.

Author

Radosevic M, Robert-Moreno A, Coolen M, Bally-Cuif L, and Alsina B

Subjects
Animals, Animals, Genetically Modified, Basic Helix-Loop-Helix Transcription Factors genetics, Cell Proliferation drug effects, Ear, Inner, Embryo, Nonmammalian drug effects, Immunohistochemistry, In Situ Hybridization, T-Box Domain Proteins genetics, Tretinoin pharmacology, Zebrafish, Zebrafish Proteins genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Embryo, Nonmammalian cytology, Embryo, Nonmammalian metabolism, T-Box Domain Proteins metabolism, Tretinoin metabolism, Zebrafish Proteins metabolism
Abstract

Proper spatial control of neurogenesis in the inner ear ensures the precise innervation of mechanotransducing cells and the propagation of auditory and equilibrium stimuli to the brain. Members of the Hairy and enhancer of split (Hes) gene family regulate neurogenesis by inhibiting neuronal differentiation and maintaining neural stem cell pools in non-neurogenic zones. Remarkably, their role in the spatial control of neurogenesis in the ear is unknown. In this study, we identify her9, a zebrafish ortholog of Hes1, as a key gene in regulating otic neurogenesis through the definition of the posterolateral non-neurogenic field. First, her9 emerges as a novel otic patterning gene that represses proneural function and regulates the extent of the neurogenic domain. Second, we place Her9 downstream of Tbx1, linking these two families of transcription factors for the first time in the inner ear and suggesting that the reported role of Tbx1 in repressing neurogenesis is in part mediated by the bHLH transcriptional repressor Her9. Third, we have identified retinoic acid (RA) signaling as the upstream patterning signal of otic posterolateral genes such as tbx1 and her9. Finally, we show that at the level of the cranial otic field, opposing RA and Hedgehog signaling position the boundary between the neurogenic and non-neurogenic compartments. These findings permit modeling of the complex genetic cascade that underlies neural patterning of the otic vesicle.

Published
2011
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33. Characterization of new otic enhancers of the pou3f4 gene reveal distinct signaling pathway regulation and spatio-temporal patterns.

Author

Robert-Moreno À, Naranjo S, de la Calle-Mustienes E, Gómez-Skarmeta JL, and Alsina B

Subjects
Animals, Binding Sites, Ear embryology, Enhancer Elements, Genetic, Gene Deletion, Green Fluorescent Proteins metabolism, Humans, Mice, Models, Genetic, Mutation, Time Factors, Transcription Factors metabolism, Xenopus, Zebrafish, POU Domain Factors genetics
Abstract

POU3F4 is a member of the POU-homedomain transcription factor family with a prominent role in inner ear development. Mutations in the human POU3F4 coding unit leads to X-linked deafness type 3 (DFN3), characterized by conductive hearing loss and progressive sensorineural deafness. Microdeletions found 1 Mb 5' upstream of the coding region also displayed the same phenotype, suggesting that cis-regulatory elements might be present in that region. Indeed, we and others have recently identified several enhancers at the 1 Mb 5' upstream interval of the pou3f4 locus. Here we characterize the spatio-temporal patterns of these regulatory elements in zebrafish transgenic lines. We show that the most distal enhancer (HCNR 81675) is activated earlier and drives GFP reporter expression initially to a broad ear domain to progressively restrict to the sensory patches. The proximal enhancer (HCNR 82478) is switched later during development and promotes expression, among in other tissues, in sensory patches from its onset. The third enhancer (HCNR 81728) is also active at later stages in the otic mesenchyme and in the otic epithelium. We also characterize the signaling pathways regulating these enhancers. While HCNR 81675 is regulated by very early signals of retinoic acid, HCNR 82478 is regulated by Fgf activity at a later stage and the HCNR 81728 enhancer is under the control of Hh signaling. Finally, we show that Sox2 and Pax2 transcription factors are bound to HCNR 81675 genomic region during otic development and specific mutations to these transcription factor binding sites abrogates HCNR 81675 enhancer activity. Altogether, our results suggest that pou3f4 expression in inner ear might be under the control of distinct regulatory elements that fine-tune the spatio-temporal activity of this gene and provides novel data on the signaling mechanisms controlling pou3f4 function.

Published
2010
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34. Multiple enhancers located in a 1-Mb region upstream of POU3F4 promote expression during inner ear development and may be required for hearing.

Author

Naranjo S, Voesenek K, de la Calle-Mustienes E, Robert-Moreno A, Kokotas H, Grigoriadou M, Economides J, Van Camp G, Hilgert N, Moreno F, Alsina B, Petersen MB, Kremer H, and Gómez-Skarmeta JL

Subjects
Animals, Base Sequence, DNA Mutational Analysis, Ear, Inner growth & development, Embryo, Nonmammalian embryology, Embryo, Nonmammalian metabolism, Family Health, Female, Gene Deletion, Gene Expression Regulation, Developmental, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Hearing Loss genetics, Humans, In Situ Hybridization, Male, Microscopy, Fluorescence, Pedigree, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Regulatory Sequences, Nucleic Acid genetics, Xenopus embryology, Xenopus genetics, 5' Flanking Region genetics, Ear, Inner metabolism, Enhancer Elements, Genetic genetics, Hearing genetics, POU Domain Factors genetics
Abstract

POU3F4 encodes a POU-domain transcription factor required for inner ear development. Defects in POU3F4 function are associated with X-linked deafness type 3 (DFN3). Multiple deletions affecting up to ~900-kb upstream of POU3F4 are found in DFN3 patients, suggesting the presence of essential POU3F4 enhancers in this region. Recently, an inner ear enhancer was reported that is absent in most DFN3 patients with upstream deletions. However, two indications suggest that additional enhancers in the POU3F4 upstream region are required for POU3F4 function during inner ear development. First, there is at least one DFN3 deletion that does not eliminate the reported enhancer. Second, the expression pattern driven by this enhancer does not fully recapitulate Pou3f4 expression in the inner ear. Here, we screened a 1-Mb region upstream of the POU3F4 gene for additional cis-regulatory elements and searched for novel DFN3 mutations in the identified POU3F4 enhancers. We found several novel enhancers for otic vesicle expression. Some of these also drive expression in kidney, pancreas and brain, tissues that are known to express Pou3f4. In addition, we report a new and smallest deletion identified so far in a DFN3 family which eliminates 3.9 kb, comprising almost exclusively the previous reported inner ear enhancer. We suggest that multiple enhancers control the expression of Pou3f4 in the inner ear and these may contribute to the phenotype observed in DFN3 patients. In addition, the novel deletion demonstrates that the previous reported enhancer, although not sufficient, is essential for POU3F4 function during inner ear development.

Published
2010
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35. Patterning and cell fate in ear development.

Author

Alsina B, Giraldez F, and Pujades C

Subjects
Animals, Cell Differentiation genetics, Chickens, Ear, Inner cytology, Hair Cells, Auditory cytology, Hair Cells, Auditory metabolism, Mice, Models, Biological, Rhombencephalon embryology, Rhombencephalon metabolism, Body Patterning genetics, Ear, Inner embryology, Ear, Inner metabolism, Gene Expression Regulation, Developmental
Abstract

The inner ear is a complex structure responsible for the senses of audition and balance in vertebrates. The ear is organised into different sense organs that are specialised to detect specific stimuli such as sound and linear or angular accelerations. The elementary sensory unit of the ear consists of hair cells, supporting cells, neurons and Schwann cells. Hair cells are the mechano-electrical transducing elements, and otic neurons convey information coded in electrical impulses to the brain. With the exception of the Schwann cells, all cellular elements of the inner ear derive from the otic placode. This is an ectodermal thickening that is specified in the head ectoderm adjacent to the caudal hindbrain. The complex organisation of the ear requires precise coupling of regional specification and cell fate decisions during development, i.e. specificity in defining particular spatial domains containing particular cell types. Those decisions are taken early in development and are the subject of this article. We review here recent work on: i) early patterning of the otic placode, ii) the role of neural tube signals in the patterning of the otic vesicle, and iii) the genes underlying cell fate determination of neurons and sensory hair cells.

Published
2009
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36. Spatial and temporal segregation of auditory and vestibular neurons in the otic placode.

Author

Bell D, Streit A, Gorospe I, Varela-Nieto I, Alsina B, and Giraldez F

Subjects
Animals, Antigens, Differentiation biosynthesis, Antigens, Differentiation genetics, Avian Proteins biosynthesis, Avian Proteins genetics, Basic Helix-Loop-Helix Transcription Factors biosynthesis, Basic Helix-Loop-Helix Transcription Factors genetics, Cell Differentiation physiology, Cell Lineage, Cell Movement physiology, Chick Embryo, Cochlea cytology, Cochlea innervation, Epithelium embryology, Epithelium innervation, Fluorescent Dyes, Gene Expression Regulation, Developmental, In Situ Hybridization, Nerve Tissue Proteins biosynthesis, Nerve Tissue Proteins genetics, Neurons, Afferent physiology, Neuropeptides biosynthesis, Neuropeptides genetics, Stem Cells cytology, Stem Cells metabolism, Vestibule, Labyrinth cytology, Vestibule, Labyrinth innervation, Cochlea embryology, Neurons, Afferent cytology, Vestibule, Labyrinth embryology
Abstract

The otic placode generates the auditory and vestibular sense organs and their afferent neurons; however, how auditory and vestibular fates are specified is unknown. We have generated a fate map of the otic placode and show that precursors for vestibular and auditory cells are regionally segregated in the otic epithelium. The anterior-lateral portion of the otic placode generates vestibular neurons, whereas the posterior-medial region gives rise to auditory neurons. Precursors for vestibular and auditory sense organs show the same distribution. Thus, different regions of the otic placode correspond to particular sense organs and their innervating neurons. Neurons from contiguous domains rarely intermingle suggesting that the regional organisation of the otic placode dictates positional cues to otic neurons. But, in addition, vestibular and cochlear neurogenesis also follows a stereotyped temporal pattern. Precursors from the anterior-lateral otic placode delaminate earlier than those from its medial-posterior portion. The expression of the proneural genes NeuroM and NeuroD reflects the sequence of neuroblast formation and differentiation. Both genes are transiently expressed in vestibular and then in cochlear neuroblasts, while differentiated neurons express Islet1, Tuj1 and TrkC, but not NeuroM or NeuroD. Together, our results indicate that the position of precursors within the otic placode confers identity to sensory organs and to the corresponding otic neurons. In addition, positional information is integrated with temporal cues that coordinate neurogenesis and sensory differentiation.

Published
2008
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37. Differential expression of Sox2 and Sox3 in neuronal and sensory progenitors of the developing inner ear of the chick.

Author

Neves J, Kamaid A, Alsina B, and Giraldez F

Subjects
Age Factors, Animals, Cell Differentiation, Chick Embryo, DNA-Binding Proteins genetics, HMGB Proteins genetics, High Mobility Group Proteins genetics, Immunohistochemistry methods, In Situ Hybridization methods, Models, Anatomic, Nerve Tissue Proteins metabolism, Proliferating Cell Nuclear Antigen metabolism, SOXB1 Transcription Factors, Transcription Factors genetics, DNA-Binding Proteins metabolism, Ear, Inner cytology, Ear, Inner embryology, Ear, Inner metabolism, Gene Expression Regulation, Developmental physiology, HMGB Proteins metabolism, High Mobility Group Proteins metabolism, Neurons, Afferent metabolism, Stem Cells metabolism, Transcription Factors metabolism
Abstract

The generation of the mechanosensory elements of the inner ear during development proceeds in a precise temporal and spatial pattern. First, neurosensory precursors form sensory neurons. Then, prosensory patches emerge and give rise to hair and supporting cells. Hair cells are innervated by cochleovestibular neurons that convey sound and balance information to the brain. SOX2 is an HMG transcription factor characteristic of the stem-cell genetic network responsible for progenitor self-renewal and commitment, and its loss of function generates defects in ear sensory epithelia. The present study shows that SOX2 protein is expressed in a spatially and temporally restricted manner throughout development of the chick inner ear. SOX2 is first expressed in the neurogenic region that gives rise to sensory neurons. SOX2 is then restricted to the prosensory patches in E4 and E5 embryos, as revealed by double and parallel labelling with SOX2 and Tuj1, MyoVIIa, or Islet1. Proliferating cell nuclear antigen labelling showed that SOX2 is expressed in proliferating cells during those stages. By E5, SOX2 is also expressed in the Schwann cells of the cochleovestibular ganglion, but not in the otic neurons. At E8 and E17, beyond stages of sensory cell specification, SOX2 is transiently expressed in hair cells, but its level remains high in supporting cells. SOX3 is concomitantly expressed with SOX2 in the neurogenic domain of the otic cup, but not in prosensory patches. Our data are consistent with a role for SOX2 in specifying a population of otic progenitors committed to a neural fate, giving rise to neurons and hair cells., ((c) 2007 Wiley-Liss, Inc.)

Published
2007
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38. Early regionalization of the otic placode and its regulation by the Notch signaling pathway.

Author

Abelló G, Khatri S, Giráldez F, and Alsina B

Subjects
Amyloid Precursor Protein Secretases antagonists & inhibitors, Amyloid Precursor Protein Secretases metabolism, Animals, Body Patterning, Chick Embryo, Ear, Inner metabolism, Gene Expression Regulation, Developmental, Receptors, Notch genetics, Receptors, Notch metabolism, Signal Transduction, Triglycerides pharmacology, gamma-Aminobutyric Acid analogs & derivatives, gamma-Aminobutyric Acid pharmacology, Ear, Inner embryology, Receptors, Notch physiology
Abstract

Otic neuronal precursors are the first cells to be specified and do so in the anterior domain of the otic placode, the proneural domain. In the present study, we have explored the early events of otic proneural regionalization in relation to the activity of the Notch signaling pathway. The proneural domain was characterized by the expression of Sox3, Fgf10 and members of the Notch pathway such as Delta1, Hes5 and Lunatic Fringe. The complementary non-neural domain expressed two patterning genes, Lmx1b and Iroquois1, and the members of the Notch pathway, Serrate1 and Hairy1. Fate map studies and double injections with DiI/DiO showed that labeled cells remained confined to anterior or posterior territories with limited cell intermingling. To explore whether Notch signaling pathway plays a role in the initial regionalization of the otic placode, Notch activity was blocked by a gamma-secretase inhibitor (DAPT). Notch blockade induced the expansion of non-neural genes, Lmx1 and Iroquois1, into the proneural domain. Combined gene expression and DiI experiments showed that these effects were not due to migration of non-neural cells into the proneural domain, suggesting that Notch activity regulates the expression of non-neural genes. This was further confirmed by the electroporation of a dominant-negative form of the Mastermind-like1 gene that caused the up-regulation of Lmx1 within the proneural domain. In addition, Notch pathway was involved in neuronal precursor selection, probably by a classical mechanism of lateral inhibition. We propose that the regionalization of the otic domain into a proneural and a non-neural territory is a very early event in otic development, and that Notch signaling activity is required to exclude the expression of non-neural genes from the proneural territory.

Published
2007
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39. Establishment of a proneural field in the inner ear.

Author

Abello G and Alsina B

Subjects
Animals, Ear, Inner metabolism, Embryo, Nonmammalian metabolism, Embryonic Induction, Fibroblast Growth Factors genetics, Fibroblast Growth Factors metabolism, Gene Expression Regulation, Developmental, Hair Cells, Auditory metabolism, Labyrinth Supporting Cells cytology, Labyrinth Supporting Cells metabolism, Mechanotransduction, Cellular, Models, Biological, Neurons, Afferent metabolism, Receptors, Notch metabolism, Signal Transduction, Transcription Factors genetics, Transcription Factors metabolism, Ear, Inner cytology, Ear, Inner embryology
Abstract

Hair-cells, supporting cells and sensory neurons are the main specialized cell-types responsible for mechanotransduction in the inner ear. They derive from precursors expressing proneural genes and recent data has underlined the importance of SoxB1 genes as upstream activators of proneural genes during cranial placode development. Here we review the steps of establishing a proneural field and propose several models for how early otic regionalization into a proneural territory is achieved.

Published
2007
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40. BMP-signaling regulates the generation of hair-cells.

Author

Pujades C, Kamaid A, Alsina B, and Giraldez F

Subjects
Animals, Apoptosis genetics, Avian Proteins antagonists & inhibitors, Avian Proteins biosynthesis, Avian Proteins genetics, Bone Morphogenetic Protein 4, Bone Morphogenetic Proteins antagonists & inhibitors, Bone Morphogenetic Proteins biosynthesis, Bone Morphogenetic Proteins genetics, Carrier Proteins biosynthesis, Carrier Proteins genetics, Carrier Proteins physiology, Cell Count, Cell Death genetics, Cell Death physiology, Cell Differentiation genetics, Cell Proliferation, Chick Embryo, DNA-Binding Proteins metabolism, Glycosyltransferases biosynthesis, Glycosyltransferases genetics, Growth Inhibitors antagonists & inhibitors, Growth Inhibitors biosynthesis, Growth Inhibitors genetics, Growth Inhibitors physiology, Hair Cells, Auditory enzymology, Hair Cells, Auditory physiology, Homeodomain Proteins metabolism, MSX1 Transcription Factor biosynthesis, Organ Culture Techniques, Organ of Corti embryology, Signal Transduction genetics, Stem Cells cytology, Stem Cells enzymology, Stem Cells physiology, Avian Proteins physiology, Bone Morphogenetic Proteins physiology, Cell Differentiation physiology, Hair Cells, Auditory cytology, Hair Cells, Auditory embryology, Signal Transduction physiology
Abstract

Bone morphogenetic proteins (BMPs) are diffusible molecules involved in a variety of cellular interactions during development. Bmp4 expression accompanies the development of the ear sensory organs during patterning and specification of sensory cell fates, yet there is no understanding of the role of BMP4 in this process. The present work was aimed at exploring the effects of BMP-signaling on the development of hair-cells. For this purpose, we studied gene expression, cell proliferation and cell death in isolated chick otic vesicles that were grown in vitro in the presence of recombinant BMP4 or the BMP-inhibitor Noggin. Cath1 was used as a marker for hair-cell specification. BMP4 reduced the number of Cath1-cells and, conversely, Noggin increased the size of the sensory patches and the number of Cath1-positive cells. The effect of BMP4 was irreversible and occurred before hair-cell specification. Lfng and Fgf10 were expressed in the prosensory domain before Cath1, and their expression was expanded by Noggin. At these stages, modifications of BMP activity did not respecify non-sensory epithelium of the otic vesicle. The expression of Bmp4 at sensory patches was suppressed by BMP4 and induced by Noggin suggesting an autoregulatory loop. Analysis of BrdU incorporation during 6 and 18 h indicated that the effects of BMP4 were due to its ability to reduce the number of actively proliferating progenitors and inhibit cell fate specification. BMP4 induced cell death within the prosensory domain of the otic vesicle, along with the expression of Msx1, but not Msx2. On the contrary, BMP-inhibition with Noggin favored hair-cell specification without changes in the overall cell proliferation. We propose that about the stage of terminal division, the balance between BMP and BMP-inhibitory signals regulates survival and specification of hair-cell precursors, the final number of sensory hair-cells being limited by excess levels of BMPs. The final size of sensory patches would hence depend on the balance between BMP4 and opposing signals.

Published
2006
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41. vHnf1 regulates specification of caudal rhombomere identity in the chick hindbrain.

Author

Aragón F, Vázquez-Echeverría C, Ulloa E, Reber M, Cereghini S, Alsina B, Giraldez F, and Pujades C

Subjects
Animals, Chick Embryo, Epithelium embryology, Epithelium metabolism, Fibroblast Growth Factor 3 metabolism, Gene Expression Regulation, Developmental, Hepatocyte Nuclear Factor 1 genetics, Rhombencephalon metabolism, Cell Differentiation, Hepatocyte Nuclear Factor 1 metabolism, Neurons cytology, Neurons metabolism, Rhombencephalon cytology, Rhombencephalon embryology
Abstract

The homeobox-containing gene variant hepatocyte nuclear factor-1 (vHnf1) has recently been shown to be involved in zebrafish caudal hindbrain specification, notably in the activation of MafB and Kro x 20 expression. We have explored this regulatory network in the chick by in ovo electroporation in the neural tube. We show that mis-expression of vHnf1 confers caudal identity to more anterior regions of the hindbrain. Ectopic expression of mvHnf1 leads to ectopic activation of MafB and Kro x 20, and downregulation of Hoxb1 in rhombomere 4. Unexpectedly, mvhnf1 strongly upregulates Fgf3 expression throughout the hindbrain, in both a cell-autonomous and a non-cell-autonomous manner. Blockade of FGF signaling correlates with a selective loss of MafB and Kro x 20 expression, without affecting the expression of vHnf1, Fgf3, or Hoxb1. Based on these observations, we propose that in chick, as in zebrafish, vHnf1 acts with FGF to promote caudal hindbrain identity by activating MafB and Kro x 20 expression. However, our data suggest differences in the vHnf1 downstream cascade in different vertebrates., (Developmental Dynamics 234:567-576, 2005. (c) 2005 Wiley-Liss, Inc.)

Published
2005
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42. FGF signaling is required for determination of otic neuroblasts in the chick embryo.

Author

Alsina B, Abelló G, Ulloa E, Henrique D, Pujades C, and Giraldez F

Subjects
Animals, Chick Embryo, Fibroblast Growth Factor 10, Ear embryology, Fibroblast Growth Factors metabolism, Neurons cytology, Signal Transduction
Abstract

The interplay between intrinsic and extrinsic factors is essential for the transit into different cell states during development. We have analyzed the expression and function of FGF10 and FGF-signaling during the early stages of the development of otic neurons. FGF10 is expressed in a highly restricted domain overlapping the presumptive neurogenic region of the chick otic placode. A detailed study of the expression pattern of FGF10, proneural, and neurogenic genes revealed the following temporal sequence for the onset of gene expression: FGF10>Ngn1/Delta1/Hes5>NeuroD/NeuroM. FGF10 and FGF receptor inhibition cause opposed effects on cell determination and cell proliferation. Ectopic expression of FGF10 in vivo promotes an increase in NeuroD and NeuroM expression. BrdU incorporation experiments showed that the increase in NeuroD-expressing cells is not due to an increase in cell proliferation. Inhibition of FGF receptor signaling in otic explants causes a severe reduction in Neurogenin1, NeuroD, Delta1, and Hes5 expression with no change in non-neural genes like Lmx1. However, it does not interfere with NeuroD expression within the CVG or with neuroblast delamination. The loss of proneural gene expression caused by FGF inhibition is not caused by decreased cell proliferation or by increased cell death. We suggest that FGF signaling in the otic epithelium is required for neuronal precursors to withdraw from cell division and irreversibly commit to neuronal fate.

Published
2004
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43. Growth factors and early development of otic neurons: interactions between intrinsic and extrinsic signals.

Author

Alsina B, Giraldez F, and Varela-Nieto I

Subjects
Animals, Ear, Inner embryology, Ear, Inner growth & development, Gene Expression Regulation, Developmental, Morphogenesis, Fibroblast Growth Factors physiology, Hair Cells, Auditory embryology, Hair Cells, Auditory growth & development, Nerve Growth Factors physiology, Somatomedins physiology
Published
2003
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44. Visualizing synapse formation in arborizing optic axons in vivo: dynamics and modulation by BDNF.

Author

Alsina B, Vu T, and Cohen-Cory S

Subjects
Animals, Axons ultrastructure, Coculture Techniques, Fluorescent Dyes metabolism, Green Fluorescent Proteins, Image Processing, Computer-Assisted, Indicators and Reagents metabolism, Luminescent Proteins genetics, Luminescent Proteins metabolism, Membrane Proteins genetics, Membrane Proteins metabolism, Microscopy, Confocal, Nerve Tissue Proteins metabolism, R-SNARE Proteins, Recombinant Fusion Proteins metabolism, Retinal Ganglion Cells cytology, Superior Colliculi cytology, Superior Colliculi metabolism, Synaptosomal-Associated Protein 25, Time Factors, Xenopus laevis, Axons physiology, Brain-Derived Neurotrophic Factor pharmacology, Retinal Ganglion Cells drug effects, Retinal Ganglion Cells physiology, Synapses physiology
Abstract

Dynamic developmental changes in axon arbor morphology may directly reflect the formation, stabilization and elimination of synapses. We used dual-color imaging to study, in the live, developing animal, the relationship between axon arborization and synapse formation at the single cell level, and to examine the participation of brain-derived neurotrophic factor (BDNF) in synaptogenesis. Green fluorescent protein (GFP)-tagged synaptobrevin II served as a marker to visualize synaptic sites in individual fluorescently labeled Xenopus optic axons. Time-lapse confocal microscopy revealed that although most synapses remain stable, synapses are also formed and eliminated as axons branch and increase their complexity. Most new branches originated at GFP-labeled synaptic sites. Increasing BDNF levels significantly increased both axon arborization and synapse number, with BDNF increasing synapse number per axon terminal. The ability to visualize central synapses in real time provides insights about the dynamic mechanisms underlying synaptogenesis, and reveals BDNF as a modulator of synaptogenesis in vivo.

Published
2001
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45. The Drosophila selenophosphate synthetase (selD) gene is required for development and cell proliferation.

Author

Serras F, Morey M, Alsina B, Baguñà J, and Corominas M

Subjects
Animals, Apoptosis, Cell Division, Drosophila melanogaster embryology, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Female, Gene Expression Regulation, Developmental, Gene Expression Regulation, Enzymologic, Genes, Lethal, Genomic Imprinting, Male, Mosaicism, Mutation, Protein Biosynthesis, Selenoproteins, Signal Transduction, Drosophila Proteins, Drosophila melanogaster enzymology, Phosphotransferases genetics, Phosphotransferases metabolism, Proteins
Abstract

To study the function of selenoproteins in development and growth we have used a lethal mutation (selD(ptuf)) of the Drosophila homologous selenophosphate synthetase (selD) gene. This enzyme is involved in the selenoprotein biosynthesis. The selD(ptuf) loss-of-function mutation causes aberrant cell proliferation and differentiation patterns in the brain and imaginal discs, as deduced from genetic mosaics, patterns of gene expression and analysis of cell cycle markers. In addition to that, selenium metabolism is also necessary for the ras/MAPKinase signal tansduction pathway. Therefore, the use of Drosophila imaginal discs and brain and in particular the selD(ptuf) mutation, provide an excellent model to investigate the role of selenoproteins in the regulation of cell proliferation, growth and differentiation.

Published
2001
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46. Characterisation of a selenophosphate synthetase from a collection of P-lacW insertion mutants in Drosophila.

Author

Alsina B, Serras F, Baguñà J, and Corominas M

Subjects
Animals, Apoptosis, Cell Division, DNA, Complementary genetics, Drosophila growth & development, Genes, Insect, Larva cytology, Larva enzymology, Larva growth & development, Mutagenesis, Insertional, Bacterial Proteins genetics, Drosophila enzymology, Drosophila genetics, Drosophila Proteins, Phosphotransferases
Published
1996

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