The expression of unconventional vesicular glutamate transporter VGLUT3 by neurons known to release a different classical transmitter has suggested novel roles for signaling by glutamate, but this distribution has raised questions about whether the protein actually contributes to glutamate release. We now report that mice lacking VGLUT3 are profoundly deaf due to the absence of glutamate release from hair cells at the first synapse in the auditory pathway. The early degeneration of some cochlear ganglion neurons in knockout mice also indicates an important developmental role for the glutamate released by hair cells before the onset of hearing. In addition, the mice exhibit primary, generalized epilepsy that is accompanied by remarkably little change in ongoing motor behavior. The glutamate release conferred by expression of VGLUT3 thus has an essential role in both function and development of the auditory pathway, as well as in the control of cortical excitability.
Although the connections of the auditory brainstem nuclei are well described in adult mammals, almost nothing is known concerning how and when these connections develop. The purpose of the present study was to describe the development of the efferent projections of the cochlear nucleus (CN), the first central relay station in the ascending auditory pathway of mammals. We used two tracers in rats aged between embryonic day 15 (E15) and postnatal day 14 (P14; birth in the rat is at E22 = P0). The carbocyanine dye DiI was applied into the CN in aldehyde-fixed tissue. The second tracer, biocytin, was applied into the ventral acoustic stria in an in vitro slice preparation. The ontogeny of the efferent projections from the CN could be divided into three periods. The first period (E15-E17) is characterized by axonal outgrowth. Axons traverse nuclei in the superior olivary complex and the lateral lemniscus and finally grow up into the inferior colliculus, but axon collaterals do not form during this period. The second period (E18-P5) is marked by pronounced collateral branching of CN fibers in auditory brainstem nuclei. Collateralisation in the contralateral inferior colliculus starts shortly before that in the ipsilateral superior olivary complex. The remaining auditory nuclei become successively innervated, as indicated by collaterals found in them. During the third period (P5-P14) terminal structures mature further, as shown by the morphological changes of the calyces of Held in the medial nucleus of the trapezoid body. In conclusion, our results show that the efferent connections from the cochlear nucleus form over a period of almost two weeks and are laid down without forming aberrant internuclear connections. On a nuclear level, an adult-like projection pattern is already achieved one week prior to the onset of physiological hearing.
Synapse elimination and strengthening are central mechanisms for the developmental organization of excitatory neuronal networks. Little is known, however, about whether these processes are also involved in establishing precise inhibitory circuits. We examined the development of functional connectivity before hearing onset in rats in the tonotopically organized, glycinergic pathway from the medial nucleus of the trapezoid body (MNTB) to the lateral superior olive (LSO), which is part of the mammalian sound localization system. We found that LSO neurons became functionally disconnected from approximately 75% of their initial inputs, resulting in a two-fold sharpening of functional topography. This was accompanied by a 12-fold increase in the synaptic conductance generated by maintained individual inputs. Functional elimination of MNTB-LSO synapses was restricted to the period when these glycinergic/GABAergic synapses are excitatory. These results provide new insights into the mechanisms by which precisely organized inhibitory circuits are established during development.
SUMMARY Patterned spontaneous activity is a hallmark of developing sensory systems. In the auditory system, rhythmic bursts of spontaneous activity are generated in cochlear hair cells and propagated along central auditory pathways. The role of these activity patterns in the development of central auditory circuits has remained speculative. Here we demonstrate that blocking efferent cholinergic neurotransmission to developing hair cells in mice that lack the α9 subunit of nicotinic acetylcholine receptors (α9 KO mice) altered the temporal fine-structure of spontaneous activity without changing activity levels. KO mice showed a severe impairment in the functional and structural sharpening of an inhibitory tonotopic map, as evidenced by deficits in synaptic strengthening and silencing of connections and an absence in axonal pruning. These results provide evidence that the precise temporal pattern of spontaneous activity before hearing onset is crucial for the establishment of precise tonotopy, the major organizing principle of central auditory pathways.
A fundamental organizing principle of auditory brain circuits is tonotopy, the orderly representation of the sound frequency to which neurons are most sensitive. Tonotopy arises from the coding of frequency along the cochlea and the topographic organization of auditory pathways. The mechanisms that underlie the establishment of tonotopy are poorly understood. In auditory brainstem pathways, topographic precision is present at very early stages in development, which may suggest that synaptic reorganization contributes little to the construction of precise tonotopic maps. Accumulating evidence from several brainstem nuclei, however, is now changing this view by demonstrating that developing auditory brainstem circuits undergo a marked degree of refinement on both a subcellular and circuit level.Increasing the topographic organization of synaptic connections via activity-dependent refinement is a major milestone in the maturation of neuronal circuits 1 . In the developing auditory system, experience-dependent refinement of tonotopic maps has been well demonstrated in the auditory cortex and in multimodal-integration brain areas [2][3][4][5] . In contrast, primary auditory circuits in the brainstem are assembled with high topographic (tonotopic) precision early in development and show little evidence of subsequent refinement. This picture is based on a wealth of anatomical tracing studies in both birds and mammals that have shown that growing axons innervate their topographically correct target areas from the outset and do not establish aberrant, transient connections to incorrect nuclei [6][7][8][9] . Likewise, physiological studies indicate that a precise tonotopic organization is present as soon as central auditory pathways can be activated by sound [10][11][12] . Even if the formation of a projection is induced by embryonic otocyst (an ectodermal invagination that constitutes the primordium of the internal ear) removal, the projection is tonotopically organized 13 .Recently, however, this traditional picture of a developmentally predetermined and 'hardwired' auditory brainstem has undergone a substantial revision. It is becoming increasingly apparent that auditory synapses in the brainstem can express activity-dependent synaptic plasticity [14][15][16] and that auditory brainstem circuits undergo an unexpected degree of synaptic reorganization. Here we summarize recent evidence from the cochlear nucleus and primary © 2009 Nature America, Inc. All rights reserved.Correspondence should be addressed to K.K. (kkarl@pitt.edu).. (Fig. 1) that support the view that the emergence of precise tonotopy depends on circuit refinement, and discuss potential underlying mechanisms. NIH Public Access Auditory nerve projections to the cochlear nucleusCochlear hair cells, the sensory cells that transform sound energy into electrical signals, are connected to the brain by spiral ganglion neurons whose centrally directed axons form the auditory nerve. After entering the brain, each auditory nerve fiber branches to innervate...
In contrast to our knowledge about the anatomical development of the mammalian central auditory system, the development of its physiological properties is still poorly understood. In order to better understand the physiological properties of the developing mammalian auditory brainstem, we made intracellular recordings in brainstem slices from perinatal rats to examine synaptic transmission in the superior olivary complex, the first binaural station in the ascending auditory pathway. We concentrated on neurons in the lateral superior olive (LSO), which in adults, are excited from the ipsilateral side and inhibited from the contralateral side. Already at embryonic day (E) 18, when axon collaterals begin to invade the LSO anlage, synaptic potentials could be evoked from ipsilateral, as well as from contralateral inputs. Ipsilaterally elicited PSPs were always depolarizing, regardless of age. They had a positive reversal potential and could be completely blocked by the non-NMDA glutamate receptor antagonist CNQX. In contrast, contralaterally elicited PSPs were depolarizing from E18-P4, yet they turned into "adult-like," hyperpolarizing PSPs after P8. Their reversal potential shifted dramatically from -21.6 +/- 17.7 mV (E18-P0) to -73.0 +/- 7.1 mV (P10). Regardless of their polarity, contralaterally elicited PSPs were reversibly blocked by the glycine receptor antagonist strychnine. Bath application of glycine and its agonist beta-alanine further confirmed the transitory depolarizing action of glycine in the auditory brainstem. Since the transient excitatory behavior of glycine occurs during a period during which glycinergic synaptic connections in the LSO are refined by activity-dependent mechanisms, glycinergic excitation might be a mechanism by which synaptic rearrangement in the contralateral inhibitory pathway is accomplished.
Activity-dependent synapse refinement is crucial for the formation of precise excitatory and inhibitory neuronal circuits. Whereas the mechanisms that guide refinement of excitatory circuits are becoming increasingly clear, the mechanisms guiding inhibitory circuits have remained obscure. In the lateral superior olive (LSO), a nucleus in the mammalian sound localization system that receives inhibitory input from the medial nucleus of the trapezoid body (MNTB), specific elimination and strengthening of synapses that are both GABAergic and glycinergic (GABA/glycinergic synapses) is essential for the formation of a precise tonotopic map. We provide evidence that immature GABA/glycinergic synapses in the rat LSO also release the excitatory neurotransmitter glutamate, which activates postsynaptic NMDA receptors (NMDARs). Immunohistochemical studies demonstrate synaptic colocalization of the vesicular glutamate transporter 3 with the vesicular GABA transporter, indicating that GABA, glycine and glutamate are released from single MNTB terminals. Glutamatergic transmission at MNTB-LSO synapses is most prominent during the period of synapse elimination. Synapse-specific activation of NMDARs by glutamate release at GABAergic and glycinergic synapses could be important in activity-dependent refinement of inhibitory circuits.
Many non-glutamatergic synaptic terminals in the mammalian brain contain the vesicular glutamate transporter 3 (VGLUT3), indicating that they co-release the excitatory neurotransmitter glutamate. However, the functional role of glutamate co-transmission at these synapses is poorly understood. In the auditory system, VGLUT3 expression and glutamate co-transmission are prominent in a developing GABA/glycinergic sound localization pathway. Here we show that mice with a genetic deletion of VGLUT3 exhibit disrupted glutamate-co-transmission and severe impairment in the refinement of this inhibitory pathway. Specifically, loss of glutamate co-transmission disrupts synaptic silencing and the strengthening of GABA/glycinergic connections that normally occur with maturation. Functional mapping studies further revealed that these deficits markedly degrade the precision of tonotopy in this inhibitory auditory pathway. These results demonstrate the crucial role of glutamate co-transmission in the synaptic reorganization and topographic specification of a developing inhibitory circuit.
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