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Topical Reviews |
1 The John Curtin School of Medical Research, Australian National University, Canberra, ACT 0200, Australia
2 Department of Neuroscience, Cell Biology and Physiology, Wright State University, Dayton, OH 45459, USA
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Abstract |
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 Top Abstract IntroductionReferences |
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(Received 5 January 2006;
accepted after revision 6 February 2006;
first published online 9 February 2006)
Corresponding author B. Walmsley: Synapse and Hearing Laboratory, Division of Neuroscience, John Curtin School of Medical Research, Australian National University, PO Box 334, Canberra, ACT 0200, Australia. Email: bruce.walmsley{at}anu.edu.au
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Introduction |
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TopAbstractIntroductionReferences |
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Thus, a variety of model systems have been used to demonstrate that activity can alter synaptic strength (both pre- and post-synaptically) and postsynaptic cell excitability. Some of these results are consistent with a so-called ‘homeostatic response’, and some are consistent with opposing mechanisms, such as ‘Hebbian’ strengthening of active synapses (Burrone & Murthy, 2003; Murphy, 2003). Furthermore, there is evidence that the response of a neuron to a change in activity may be different during development than in maturity (Burrone et al. 2002; Murphy, 2003). Despite these complications, recent studies, primarily using neuronal cultures, emphasize that the predominant response to a reduction in neuronal activity is a postsynaptic increase in quantal size (Turrigiano & Nelson, 2004). This raises the issue of what happens in the intact nervous system (Desai et al. 2002). This review highlights recent results from studies of the mammalian auditory system, in particular using deafness as a model of reduced or abolished sensory input during development. The results reveal that altered activity during development has multiple effects, including changes in excitatory and/or inhibitory synaptic transmission, and postsynaptic membrane properties. Furthermore, these changes may be different in different neuronal types, as previously described for long-term plasticity in the dorsal cochlear nucleus by Tzounopoulos et al. (2004). In addition, the results show that spontaneous activity during development is necessary for the proper formation of neural circuits (tonotopic maps) in central auditory nuclei.
Auditory pathways in the mammalian brainstem
Figure 1 illustrates the pathways in the mammalian brainstem that contribute to the initial central processing of auditory input. Sound entering the ear stimulates hair cells in the cochlea. Hair cells make synaptic connection via special ribbon synapses with spiral ganglion cells, which in turn give rise to the primary auditory nerve fibres carrying auditory information to the brain. Under normal circumstances, the ribbon synapses continually release neurotransmitter, even in the absence of sound stimulation, and this results in the generation of spontaneous nerve impulses in the auditory nerves. The rate of spontaneous nerve impulses varies between auditory nerve fibres, but can reach high rates (100 Hz or more; Liberman, 1991). Spontaneous activity occurs before the opening of the ear canal and the onset of airborne sound-generated responses.
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Figure 1 illustrates the major brainstem auditory nuclei and connections, highlighting several large synaptic connections which have received much attention for study; the endbulb of Held connection between auditory nerve fibres and bushy cells in the anteroventral cochlear nucleus (AVCN), and the calyx of Held connection arising from bushy cells and contacting principal cells in the MNTB (Yin, 2002). At these connections, both pre- and post-synaptic properties can be assessed directly (e.g. Forsythe, 1994; Isaacson & Walmsley, 1995; Borst & Sakmann, 1996; Sakaba et al. 2002; Schneggenburger et al. 2002; Taschenburger et al. 2002). In addition to large excitatory terminals, AVCN and MNTB neurons also receive many small inhibitory boutons (Leao et al. 2004b). MNTB principal neurons, in turn, send inhibitory inputs to the lateral superior olive (LSO) and medial superior olive (MSO). These pathways are involved primarily in sound localization, for which precise timing is required, involving both excitatory and inhibitory inputs (Friauf & Lohmann, 1999; FitzGerald et al. 2001; McAlpine et al. 2001; Paolini et al. 2001, 2004; Brand et al. 2002; Yin, 2002; Rubel & Fritzsch, 2002; Grothe, 2003; Kim & Kandler, 2003; McAlpine & Grothe, 2003; Mauk & Buonomano, 2004; Kandler & Gillespie, 2005).
Deafness-induced changes in central auditory pathways
Insight into the role of activity in regulating synaptic transmission and neuronal membrane properties has been gained by studying the effects of eliminating or reducing auditory nerve activity i.e. deafness. These studies have revealed a variety of changes in central auditory neurons following experimentally induced or naturally occurring deafness.
Cochlear ablation studies
Cochlear ablation, which destroys the hair cells and spiral ganglion cells (and hence the auditory nerve), has been reported to increase the excitability of brainstem auditory neurons (McAlpine et al. 1997; Kotak et al. 2005), reduce (Suneja et al. 1998; Mossop et al. 2000; Vale & Sanes, 2002; Vale et al. 2003) or increase inhibitory transmission (Suneja et al. 1998), increase (Vale & Sanes, 2002) or decrease (Kotak & Sanes, 1997) excitatory synaptic transmission, transiently reduce NMDA receptor expression (Nakagawa et al. 2000), reduce potassium-dependent chloride transport (Vale et al. 2003), depolarize neurons (Francis & Manis, 2000; Vale & Sanes, 2002), increase input resistance (Francis & Manis, 2000), elevate tyrosine kinase B levels (Suneja & Potashner, 2002), alter synaptic morphology (Russell & Moore, 2002), cause cell death (Hashisaki & Rubel, 1989; Mostafapour et al. 2000), alter GAP-43 expression (Illing et al. 1997), reduce protein synthesis (Sie & Rubel, 1992) and reduce calretinin expression (Zettel et al. 2003). These studies emphasize the wide range of possible effects resulting from the complete removal of the auditory nerve, as is the case for the recent in vitro models of altered activity. However, cochlear ablation is a severe method of silencing auditory nerve input, and recently, investigations have been extended to the study of deaf mutant animals. The results of these studies are the focus of the remainder of this review.
Naturally occurring deafness
There are a variety of naturally occurring animal models of deafness, some of which exhibit deficits from birth, and others which show age-related hearing loss (Keats & Berlin, 1999). DBA mice exhibit age-related hearing loss, beginning with a loss of high-frequency responses in spiral ganglion cells in the cochlea. Wang & Manis (2005) found that, in the AVCN of old DBA mice, synaptic transmission at the endbulb of Held–bushy cell connection is impaired; spontaneous mEPSC frequency is reduced, mEPSCs are slower and smaller, and release probability is lower in old DBA mice compared with young DBA mice. Wang & Manis (2005) suggested that auditory nerve activity regulates presynaptic release probability and postsynaptic receptor composition and kinetics at the endbulb of Held synapse. These results are opposite to those expected from a ‘homeostatic’ mechanism as commonly defined, and are more consistent with a ‘Hebbian’ reduction in synaptic strength due to a lack of correlated firing of pre- and post-synaptic cells.
Related structural analyses have examined synaptic features that may correlate with synaptic strength. Shaker-2 mice have dysfunctional cochlear hair cells from birth, and electron microscopy shows that the endbulbs of Held in adult deaf mice exhibit fewer vesicles and larger postsynaptic densities (Lee et al. 2003). This is similar to deaf white cats (Ryugo et al. 1997), which have endbulbs with a reduced synaptic vesicle density, structural abnormalities in endulb mitochondria, thickening of the pre- and post-synaptic densities, and enlargement of synaptic size. Ryugo et al. (1998) further demonstrated in the deaf white cats that there is a correlation between the amount of auditory nerve activity and the degree of abnormality in endbulb morphology. This is consistent with observations in normal cats in which endbulbs arising from auditory nerve fibres with a high spontaneous discharge rate are larger, with more synaptic specializations (Ryugo et al. 1996). These results support the proposal that activity during development induces the endbulbs to grow and generate more release sites, perhaps through the splitting of large specializations into multiple smaller specializations. Again, the functional consequences associated with these changes in synaptic structure appear to be opposite to the result expected from a homeostatic mechanism. Ryugo's group also studied small bouton terminals in the AVCN of deaf white cats (Redd et al. 2002). Compared with normal-hearing cats, bouton endings of congenitally deaf cats were smaller, but there was no difference in synaptic vesicle density or size of synaptic specializations. These anatomical observations indicate that, while synaptic structure may be different in congenitally deaf animals, the differences depend on the type of synaptic connection and/or the type of postsynaptic neuron.
Physiological aspects of synaptic transmission have been examined in the AVCN and MNTB of congenitally deaf (dn/dn) mice, which lack spontaneous and acoustically driven input due to cochlea hair cell dysfunction (Bock et al. 1982). The large excitatory calyceal synapse, the endbulb of Held, formed with AVCN bushy cells, has been studied by Oleskevich & Walmsley (2002) who found that, in congenitally deaf mice, the amplitude of evoked EPSCs is larger, due to an increased presynaptic release probability; a result that is consistent with homeostasis. There is also a much greater occurrence of delayed asynchronous mEPSCs following a train of stimuli (Fig. 2). These differences may be explained by impaired calcium buffering in the presynaptic terminal. In contrast to the results on the effects of reduced activity in neuronal culture systems, there appears to be no postsynaptic difference in quantal size, since the amplitude and time course of mEPSCs are the same in dn/dn and normal mice. Interestingly, no difference was found in synaptic transmission at the calyx of Held connection with MNTB principal cells, between normal and deaf mice (Oleskevich et al. 2004; Youssoufian et al. 2005). This is surprising as globular bushy cells give rise to the calyces of Held, and these cells have lost their major excitatory drive (the endbulbs of Held).
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Membrane properties of auditory brainstem neurons in deaf mice
The postsynaptic membrane properties have also been examined in the AVCN and MNTB of normal and deaf (dn/dn) mice. In the AVCN, there appears to be no significant difference in the passive or active membrane properties of bushy cells, despite the loss of powerful excitatory auditory nerve input. However, MNTB principal cells in dn/dn mice exhibit a substantial increase in excitability, which is primarily due to smaller low-threshold potassium currents (Fig. 3; Dodson et al. 2002; Leao et al. 2004a). In addition, there is an increase in the high-threshold potassium currents and hyperpolarization-activated currents in the MNTB of dn/dn mice (Leao et al. 2004a, 2005b; see also Wang et al. 1998; Li et al. 2001; Lu et al. 2004). No differences were found between normal and deaf mice in voltage-activated calcium currents in the AVCN or MNTB (Leao et al. 2004a). These results show that a reduction in excitatory drive to auditory neurons can lead to no change (AVCN) or an increase (MNTB) in postsynaptic membrane excitability.
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As indicated above, neurons in brainstem auditory nuclei such as the AVCN and MNTB are tonotopically organized. The membrane properties of neurons within a particular nucleus are systematically different, an arrangement which has previously been demonstrated in cochlea hair cells (Pantelias et al. 2001). von Hehn et al. (2004) used immunolabelling to show that the normal gradient of high-threshold potassium channel expression in MNTB neurons is disrupted in age-related hearing loss. Recently, Brew & Forsythe (2005) described a tonotopic gradient of low-threshold potassium currents in MNTB neurons (see also Barnes-Davies et al. 2004). Leao et al. (2005a) have recently reported that there are gradients of low- and high-threshold potassium currents, and hyperpolarization-activated currents in the MNTB of normal mice. These gradients do not all increase in the same direction. Importantly, all gradients appear to be absent in dn/dn mice (see Fig. 4). This demonstrates that spontaneous activity during development plays a critical role in the expression of gradients of voltage-activated currents and the formation of tonotopic maps.
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It is clear that neurons and circuits in the intact nervous system do not respond in a universal, stereotypical manner in response to a change in activity. Although the relevance of homeostasis and Hebbian processes to these responses both during development and in the mature nervous system is uncertain, the auditory system offers a valuable opportunity to investigate the mechanisms underlying activity-dependent changes in synaptic strength and membrane excitability. In this context, it is interesting to note that a recent study has demonstrated the restoration of synapses in congenitally deaf cats by stimulation of the auditory nerve by cochlear implants (Ryugo et al. 2005).
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