Abortive synaptogenesis as a factor in the inner hair cell degeneration in the bronx waltzer (bv) mutant mouse

The bronx waltzer (vb) mutation in the mouse results in the degeneration of most but not all of the primary auditory receptors, the inner hair cells, and their afferent neurons. We analyzed the ultrastructure of 94 inner hair cells in the intact postnatal mutant mouse and in neonatal cochleas in culture to understand the pathogenesis of hair cell death and to detect factors that may prevent it. The vb spiral neurons of the bronx waltzer display two distinctive features: some of them continue to divide mitotically for at least seven postnatal days, and the type I radial fibers that innervate inner hair cells display a deficiency in immunoexpression of GAD. The growing endings of spiral neurons converge around the inner hair cells or, in their absence, invade the outer hair cell region. Their profuse sprouting among inner spiral sulcus cells contributes to the characteristic ultrastructural picture of the bv cochlea. During the first three days after birth, 40% of the inner hair cells appear normal and innervated, 40% are mostly denervated and degenerating, and 20% are immature, with minimal or no neuronal appositions. However, in mutants 6 days and older only a few inner hair cells survive, and these show either normal or superfluous afferent innervation and axosomatic GABAergic efferent innervation. Degeneration of inner hair cells begins with a distention of the nuclear envelope and the ribosomal endoplasmic reticulum. The outer nuclear membrane eventually breaks, and exudate fills the cell interior. The cellular edema leads to cell death. We propose that success or failure in synaptic acquisition is a decisive factor in the survival or decline of the mutant inner hair cells. We also suggest that the developmental delay in maturation of the spiral ganglion neurons (type I) and the failure in their synaptogenesis may be caused by an impairment in neurotrophin (NT3/BDNF) synthesis by their mutant receptor cells.     

Apoptosis of inner hair cells caused by laser ablation of their spiral ganglion neurons in cultures of the mouse organ of Corti

Laser beam ablation of spiral ganglion neurons was performed in seven organotypic cultures of the newborn mouse cochlea between 5 and 8 days in vitro, with a recovery period of from 18 hours to 3 days. Direct somatic injury (laser or mechanical) inflicted on hair cells does not necessarily cause their death; many of them survive, repair damage and re-establish their neurosensory connections. By contrast, laser irradiation and ablation of their afferent spiral ganglion neurons causes a most spectacular degeneration of sensory cells within 18–48 hours after the insult. Ultrastructurally, the degenerated hair cells—characteristically the inner hair cells—display “dark-cell vacuolar degeneration” that combines the signs of apoptotic death (the peripheral condensation of nuclear chromatin and nuclear pyknosis) with signs of cell edema, vacuolization and necrosis. The ultimate condensation of the cytoplasm gives the dead cells a jet black appearance. The irradiated spiral ganglion neurons die displaying similar pathological characteristics. The extent and locus of inner hair cell degeneration correspond to that of ablated spiral ganglion neurons: ultimately the ablation of one neuron causes degeneration of a single inner hair cell within the closest radial segment of the afferent innervation. The elimination of spiral ganglion neurons by mechanical means does not affect hair cell survival. It is inferred that the laser pulse acts as a stimulus depolarizing the neuronal membrane of the spiral ganglion neurons and their radial fibers and causing the excitotoxic death of their synaptic sensory cells through excessive stimulation of the glutamatergic receptors. Reciprocal pre-and postsynaptic synapses between the afferent dendrites and inner hair cells in culture could possibly serve as entryways of the stimulus. The pathogenesis of this apparent transsynaptically-induced apoptotic death of inner hair cells will be further examined in culture.