Different release modes of α-tectorin contribute to the development of the tectorial membrane.

The tectorial membrane extracellular matrix in the cochlea controls auditory transduction, but its earliest development remains unclear. In this issue of Developmental Cell, Niazi et al. have provided insight into tectorial membrane formation, demonstrating proteolytic shedding early in development and interaction with α-tectorin and collagen.

Irx3/5 Null Deletion in Mice Blocks Cochlea-Saccule Segregation and Disrupts the Auditory Tonotopic Map.

A gene cadre orchestrates the normal development of sensory and non-sensory cells in the inner ear, segregating the cochlea with a distinct tonotopic sound frequency map, similar brain projection, and five vestibular end-organs. However, the role of genes driving the ear development is largely unknown. Here, we show double deletion of the Iroquois homeobox 3 and 5 transcription factors (Irx3/5 DKO) leads to the fusion of the saccule and the cochlear base.

define the cochlear sensory domain and regulate vestibular and cochlear sensory patterning in the mammalian inner ear.

The mammalian inner ear houses the vestibular and cochlear sensory organs dedicated to sensing balance and sound, respectively. These distinct sensory organs arise from a common prosensory region, but the mechanisms underlying their divergence remain elusive. Here, we showed that two evolutionarily conserved homeobox genes, and , are required for the patterning and segregation of the saccular and cochlear sensory domains, as well as for the formation of auditory sensory cells.

Harmony in the Molecular Orchestra of Hearing: Developmental Mechanisms from the Ear to the Brain.

Auditory processing in mammals begins in the peripheral inner ear and extends to the auditory cortex. Sound is transduced from mechanical stimuli into electrochemical signals of hair cells, which relay auditory information via the primary auditory neurons to cochlear nuclei. Information is subsequently processed in the superior olivary complex, lateral lemniscus, and inferior colliculus and projects to the auditory cortex via the medial geniculate body in the thalamus.

The Piezo channel is a mechano-sensitive complex component in the mammalian inner ear hair cell.

The inner ear is the hub where hair cells (HCs) transduce sound, gravity, and head acceleration stimuli to the brain. Hearing and balance rely on mechanosensation, the fastest sensory signals transmitted to the brain. The mechanoelectrical transducer (MET) channel is the entryway for the sound-balance-brain interface, but the channel-complex composition is not entirely known.

Fish hearing revealed: Do we understand hearing in critical fishes and marine tetrapods.

Hearing evolved in lampreys with a frequency range of 50-200 Hz. This hearing range is comparable to that of elasmobranchs, most non-teleosts, and lungfish. Elasmobranchs most likely use the saccule and the papilla neglecta (PN) for hearing.

The Development of Speaking and Singing in Infants May Play a Role in Genomics and Dementia in Humans.

The development of the central auditory system, including the auditory cortex and other areas involved in processing sound, is shaped by genetic and environmental factors, enabling infants to learn how to speak. Before explaining hearing in humans, a short overview of auditory dysfunction is provided. Environmental factors such as exposure to sound and language can impact the development and function of the auditory system sound processing, including discerning in speech perception, singing, and language processing.

The Piezo channel is central to the mechano-sensitive channel complex in the mammalian inner ear.

The inner ear is the hub where hair cells transduce sound, gravity, and head acceleration stimuli carried by neural codes to the brain. Of all the senses, hearing and balance, which rely on mechanosensation, are the fastest sensory signals transmitted to the central nervous system. The mechanoelectrical transducer (MET) channel in hair cells is the entryway for the sound-balance-brain interface, but the channel's composition has eluded biologists due to its complexity.

Corrigendum to "The evolution of the various structures required for hearing in Latimeria and tetrapods" [IBRO Neurosci. Rep., vol. 14, June 2023, pp. 325-341].

[This corrects the article DOI: 10.1016/j.ibneur.

Early Steps towards Hearing: Placodes and Sensory Development.

Sensorineural hearing loss is the most prevalent sensory deficit in humans. Most cases of hearing loss are due to the degeneration of key structures of the sensory pathway in the cochlea, such as the sensory hair cells, the primary auditory neurons, and their synaptic connection to the hair cells. Different cell-based strategies to replace damaged inner ear neurosensory tissue aiming at the restoration of regeneration or functional recovery are currently the subject of intensive research.

Ptf1a expression is necessary for correct targeting of spiral ganglion neurons within the cochlear nuclei.

Two transcription factors, Atoh1 and Ptf1a, are essential for cochlear nuclei development. Atoh1 is needed to develop glutamatergic neurons, while Ptf1a is required to generate glycinergic and GABAergic neurons that migrate into the cochlear nucleus. While central projections of inner ear afferents are normal following loss of Atoh1, we wanted to know whether the loss of Ptf1a affects central projections.

The evolution of the various structures required for hearing in and tetrapods.

Sarcopterygians evolved around 415 Ma and have developed a unique set of features, including the basilar papilla and the cochlear aqueduct of the inner ear. We provide an overview that shows the morphological integration of the various parts needed for hearing, e.g.

Hair cell morphological patterns and polarity organization in the sea lamprey vestibular cristae.

The inner ear of the sea lamprey was examined by scanning electron microscopy, antibody labeling with tubulin, Myo7a, Spectrin, and Phalloidin stain to elucidate the canal cristae organization and the morphology and polarity of the hair cells. We characterized the hair cell stereocilia bundles and their morphological polarity with respect to the kinocilia. We identified three types of hair cells.

SOX9 and SOX10 control fluid homeostasis in the inner ear for hearing through independent and cooperative mechanisms.

The in vivo mechanisms underlying dominant syndromes caused by mutations in SRY-Box Transcription Factor 9 () and () transcription factors, when they either are expressed alone or are coexpressed, are ill-defined. We created a mouse model for the campomelic dysplasia mutation, which truncates the transactivation domain but leaves DNA binding and dimerization intact. Here, we find that causes deafness via distinct mechanisms in the endolymphatic sac (ES)/duct and cochlea.

Function of bidirectional sensitivity in the otolith organs established by transcription factor Emx2.

Otolith organs of the inner ear are innervated by two parallel afferent projections to the brainstem and cerebellum. These innervations were proposed to segregate across the line of polarity reversal (LPR) within each otolith organ, which divides the organ into two regions of hair cells (HC) with opposite stereociliary orientation. The relationship and functional significance of these anatomical features are not known.

Molecular mechanisms governing development of the hindbrain choroid plexus and auditory projection: A validation of the seminal observations of Wilhelm His.

Studies by His from 1868 to 1904 delineated the critical role of the dorsal roof plate in the development of the hindbrain choroid plexus, and of the rhombic lips in the development of hindbrain auditory centers. Modern molecular studies have confirmed these observations and placed them in a mechanistic context. Expression of the transcription factor is crucial to the development of the hindbrain choroid plexus, and also regulates the expression of a transcription factor that is essential for the formation of the cochlear hair cells and auditory nuclei.

Neurosensory development of the four brainstem-projecting sensory systems and their integration in the telencephalon.

Somatosensory, taste, vestibular, and auditory information is first processed in the brainstem. From the brainstem, the respective information is relayed to specific regions within the cortex, where these inputs are further processed and integrated with other sensory systems to provide a comprehensive sensory experience. We provide the organization, genetics, and various neuronal connections of four sensory systems: trigeminal, taste, vestibular, and auditory systems.

ISL1 is necessary for auditory neuron development and contributes toward tonotopic organization.

A cardinal feature of the auditory pathway is frequency selectivity, represented in a tonotopic map from the cochlea to the cortex. The molecular determinants of the auditory frequency map are unknown. Here, we discovered that the transcription factor ISL1 regulates the molecular and cellular features of auditory neurons, including the formation of the spiral ganglion and peripheral and central processes that shape the tonotopic representation of the auditory map.

Vision and retina evolution: How to develop a retina.

Early in vertebrate evolution, a single homeobox (Hox) cluster in basal chordates was quadrupled to generate the Hox gene clusters present in extant vertebrates. Here we ask how this expanded gene pool may have influenced the evolution of the visual system. We suggest that a single neurosensory cell type split into ciliated sensory cells (photoreceptors, which transduce light) and retinal ganglion cells (RGC, which project to the brain).

Early Deletion of Alters Neuronal Lineage Potential and Diminishes Neurogenesis in the Inner Ear.

Neuronal development in the inner ear is initiated by expression of the proneural basic Helix-Loop-Helix (bHLH) transcription factor that specifies neuronal precursors in the otocyst. The initial specification of the neuroblasts within the otic epithelium is followed by the expression of an additional bHLH factor, Although NEUROD1 is essential for inner ear neuronal development, the different aspects of the temporal and spatial requirements of NEUROD1 for the inner ear and, mainly, for auditory neuron development are not fully understood. In this study, using Foxg1 for the early elimination of in the mouse otocyst, we showed that deletion results in a massive reduction of differentiating neurons in the otic ganglion at E10.