Aziz Hafidi

Peripherin-like immunoreactivity in type II spiral ganglion cell body and projections.

Peripherin, an intermediate filament protein, is present in neuronal subpopulations of both peripheral and central nervous systems. The distribution of peripherin was studied in the adult rat cochlea using immunohistochemistry on whole mount material, in cryostat sections and sections of plastic embedded tissue. In the spiral ganglion, peripherin labeling was restricted to the perikarya of a subpopulation of neurons and their peripheral and central processes. Peripherin positive neurons had the following features: (i) they have a large eccentric nucleus, they were often found in a cluster of 2 or 3 cells, (ii) they were often located near the intraganglionic spiral bundle fibers, (iii) they represented roughly 8% of the whole ganglion population and (iv) on the average they had smaller perikarya than non-immunoreactive cells. Immunostaining on semithin plastic sections revealed positive reactivity on Type II ganglion cells, while Type I neurons were negative. Double labeling using peripherin and three neurofilament (NF) subunit antibodies confirmed the presence of both markers within the same spiral ganglion cell type. Type II neurons have been previously documented as the only subpopulation of the spiral ganglion that presents a strong positive NF immunoreactivity within their perikarya. In the organ of Corti, peripherin-positive fibers formed bundles that course beneath the outer hair cells and send branches that end as boutons contacting the outer hair cells. All these characteristics suggest that peripherin-positive cells are Type II neurons, and that peripherin constitutes a reliable marker for this spiral ganglion subpopulation, as well as their peripheral and central processes.

Regional distribution of neurotrophin receptors in the developing auditory brainstem

Neuron survival and axonal regeneration become severely limited during early postnatal development. In conjunction with our recent organotypic analysis of regeneration in the auditory midbrain, we wished to determine whether neurotrophins could serve as a trophic substance during the postnatal period. Therefore, the current study examines the development of three neurotrophin receptor tyrosine kinases (TrkA, TrkB, and TrkC) in the gerbil auditory brainstem. Immunoreactivity to TrkA, the nerve growth‐factor receptor, was observed in nonneuronal cells during the first two postnatal weeks. In the cochlear nucleus of mature animals, however, there was a TrkA‐positive neuronal subpopulation. In contrast, immunoreactivity to TrkB and TrkC (the receptors for brain‐derived neurotrophic factor and neurotrophin‐3, respectively) displayed a widespread distribution in the auditory brainstem. At postnatal day 0, TrkB and TrkC staining was virtually absent from auditory nuclei, although immunopositive neurons were present in the mesencephalic trigeminal nucleus. By postnatal day 7, TrkB‐ and TrkC‐positive neurons were present in most brainstem auditory nuclei. At postnatal day 15, TrkB immunoreactivity was observed throughout the inferior colliculus (IC), the cochlear nucleus, the medial and lateral nuclei of the trapezoid body, and the lateral superior olive, whereas TrkC labeled only a subpopulation of neurons within the central nucleus of the IC. The TrkB immunoreactivity was present on both neuronal somata and dendrites, whereas TrkC was generally restricted to cell bodies. At postnatal day 30, TrkB immunostaining was observed on most neurons of the 1C. The medial and lateral nuclei of the trapezoid body displayed extremely strong TrkB staining, followed by the cochlear nucleus. In contrast, the TrkC immunostaining was decreased dramatically by postnatal day 21. Observations at the ultrastructural level confirmed a neuronal localization of TrkB and TrkC. Immunostaining for both receptors was restricted largely to the postsynaptic density of synaptic profiles in both dendrites and somata. In summary, this study illustrates a differential pattern of immunoreactivity between three neurotrophin receptors during development. The general increase of TrkB expression is well correlated with the onset of sound‐evoked activity in this system, and its synaptic localization suggests that it may be involved in the modulation or maintenance of postsynaptic physiology.

Distribution of BDNF, NT-3 and NT-4 in the developing auditory brainstem.

This study describes the developmental expression of three neurotrophins, brain derived neurotrophic factor (BDNF), neurotrophin 3 (NT‐3) and neurotrophin (NT‐4) in the rat auditory brainstem using immunohistochemistry. At postnatal day 0 (PND 0), neurotrophins expression was virtually absent from all auditory nuclei in the brainstem, even though some positive neurons were observed in the mesencephalic trigeminal nucleus at this age. However, BDNF, NT‐3 and NT‐4 positive neurons were observed in most brainstem auditory nuclei by PND 6. At the following stages, there was a general increase in the intensity of the neurotrophins immunoreactivity and BDNF labeling was particularly prominent in most cochlear nucleus neurons. A differential pattern of staining emerged in cochlear nucleus subdivisions, with more intense staining present in the ventral part. The superior olivary complex nuclei followed a similar pattern of BDNF staining compared to the cochlear nucleus. In the adult, BDNF heavily labeled most neurons of the superior olivary nuclei and moderately labeled neurons of the inferior colliculus (IC). NT‐3 and NT‐4 showed a similar pattern of staining in most auditory brainstem nuclei. The first staining was observed by PND 6 in some neuronal cell bodies. NT‐3 and NT‐4 immunoreactivity increased in the following stages and in the adult moderate labelings were observed in most neurons of the cochlear nucleus, the superior olivary nuclei and the IC.

Ontogenesis of type II spiral ganglion neurons during development: Peripherin immunohistochemistry

In this study, we analysed the distribution of the intermediate filament peripherin in the developing cochlea of the rat. At gestational day 16, weak immunolabeling was observed in neuronal somas throughout the spiral ganglion. At gestational day 20, the peripherin labeling increased in intensity throughout the cochlea but became especially strong in some ganglion neurons of the basal turn. Homogeneous immunolabeling was observed throughout the spiral ganglion of the apical turn. Double immunofluorescence labeling of the prenatal cochlea with peripherin and neurofilament (NF) antibodies revealed colocalization on the same structures. By postnatal day 3, the peripherin labeling intensity had decreased in the majority of spiral ganglion neurons, but remained strong in some cells of the basal turn. Only a few neurons continued to be immunolabeled into adulthood that correspond to Type II spiral ganglion neurons expressing both NF protein and peripherin, two classes of intermediate filament proteins. In the organ of Corti, the first immunolabeling was observed on gestational day 20 as peripheral fibers reaching the receptor cells. Positive fibers were observed below both inner (IHCs) and outer (OHCs) hair cells. At birth and at postnatal day 3, peripherin immunolabeling was still observed below both IHCs and OHCs. By postnatal day 4, peripherin labeling became more dominant in fibers below OHCs, but some immunoreactivity was still present below IHCs. No immunoreactivity was present in the intraganglionic spiral bundle (IGSB) fibers containing the olivary complex efferent fibers before birth. A few days after birth some fibers of the IGSB started to be immunoreactive.

Glycinergic transmission regulates dendrite size in organotypic culture

We previously demonstrated that inhibitory synaptic transmission influences dendrite development in vivo. We now report an analogous finding in an organotypic culture of a glycinergic projection nucleus, the medial nucleus of the trapezoid body (MNTB), and its postsynaptic target, the lateral superior olive (LSO) of gerbils. Cultures were generated at 6-7 days postnatal and grown in serum containing medium with or without the glycine receptor antagonist, strychnine (SN), at 2 microM. LSO neurons were then labeled with biocytin, and the dendritic arbors were analyzed morphometrically. Compared to neurons form age-matched in vivo tissue, the neurons cultured in control media were somewhat atrophic, including decreases in dendritic branching and length. Incubation in strychnine led to a dramatic increase in dendritic branching and total dendritic length. Control neurons averaged 6.3 branches compared to 18 branches/neuron in SN-treated cultures. There was a similar increase in primary dendrites and total dendritic length. The physical elimination of MNTB cells did not mimic SN treatment, presumably because glycinergic LSO neurons generated intrinsic connections. In fact, the LSO soma area was significantly greater following MNTB removal, suggesting that these afferents provide a second signal to postsynaptic neurons. These results suggest that spontaneous glycinergic transmission regulates the growth of postsynaptic processes.

Immunocytochemical localization of neurofilament protein subunits in the spiral ganglion of the adult rat

Spiral ganglion neurons from adult rats were treated with several monoclonal antibodies that react with neurofilaments (NFs) and NF subunits. An antibody against NFs used with immunocytochemical techniques showed a strong reaction with most neuron processes in the spiral ganglion, whereas only a few neurons presented a reaction. Using monoclonal antibodies against the 3 subunits, we obtained the same results with a small percentage of neurons labelled. From quantitative observations, reacting neurons showed the same percentage as and a smaller size than T II neurons observed with a more conventional method. This shows that reacting neurons are indeed T II neurons and that they can easily be differentiated by an accumulation of NFs in their perikaryon by well characterized commercially available antibodies.

Distribution of glutamate receptors GluR 2/3 and NR1 in the developing rat cerebellum

The distribution of glutamate receptors GluR2/3 and NR1 was analysed immunohistochemically during development of the rat cerebellum. GluR2/3 immunoreactivity appeared by postnatal day P0 in somata of Purkinje cells. Throughout P7, P15, P20 and adulthood, GluR2/3 immunoreactivity was found in the entire Purkinje cell dendritic arbor reaching to the external granular layer and, by P15, the surface of the cerebellum. By P7, the granular layer revealed scattered, mildly reactive, cells. NR-1 immunoreactivity first gained prominence about P7 in the region of the multi-layered Purkinje cell somata. By P15, NR1 was prominent in Purkinje cell somata and Golgi cells. The reaction product extended into the primary main dendrite of Purkinje cells. By P21, stellate and basket cells had intense reactivity throughout the molecular layer and reactive large-diameter dendrites of Golgi cells projected toward the molecular layer. Granule cells remained very weak among strongly reactive Golgi cell somata and dendrites. Ultrastructural immunohistochemistry revealed NR1 reaction product in Purkinje cell somata, in stellate cell somata and dendrites and on postsynaptic membranes of scattered spines throughout the molecular layer. The later appearance and restricted location of NR1 in somata and proximal dendrites of Purkinje cells contrasted markedly with GluR2/3 which appeared before birth and remained prominent throughout Purkinje cell dendritic arbors of adults. The time of NR1 expression correlated with the generation of granule cells, their synaptogenesis on Purkinje cells, the formation of stellate/baske cells and the shift of climbing fibre synapses from distal to proximal dendrites. The developmental appearance of stellate/basket cells and Golgi cells as well as their high reactivity remaining into adulthood suggest that these inhibitory molecular and granular layer interneurons are the principal targets of glutamate axons serving NR1 synaptic properties while Purkinje cells and brush type granule cells are targets for glutamate connections with GluR2/3 characteristics.

Immunohistochemical localization of nerve growth factor receptor in the cochlea and in the brainstem of the perinatal rat

Nerve growth factor receptor (NGF-R) localization was studied immunohistochemically in the cochlea and in the brainstem of the perinatal rat, using a specific monoclonal antibody directed against the rat NGF-R. In the cochlea, NGF-R immunoreactivity is positive during the whole perinatal period studied, and is located at the hair cell level, in fibers that reach the organ of Corti, in the intraganglionic spiral bundle and in some small bundles of fibers in the auditory nerve. In the brainstem, NGF-R is detected in auditory structures such as the ventral cochlear nucleus, the superior olivary complex, the nuclei of the trapezoid body and the trapezoid body. Many auditory structures labelled by the NGF-R antibody are implicated in the efferent cochlear innervation. These results suggest that NGF could be implicated in interactions between auditory receptors and efferent innervation of the developing cochlea. This coincides with findings on the immunohistochemical localization of NGF-like protein in the organ of Corti of the developing rat. Moreover, these observations could be related to an early prenatal development of auditory efferent innervation.

Age-dependent failure of axon regeneration in organotypic culture of gerbil auditory midbrain

Inferior colliculus (IC) slice cultures from postnatal (P) day 6-8 gerbils exhibit axonal regeneration across a lesion site, and these regrowing processes can form synapses. To determine whether regenerative capacity is lost in older tissue, as occurs in vivo, slices from P12-21-day animals were grown under similar conditions. While these cultures displayed a near complete loss of neurons over 6 days in vitro, glutamate receptor antagonists (AP5 and/or CNQX) significantly enhanced survival, particularly at P12-15. In contrast, several growth factors or high potassium did not improve neuron survival. Therefore, axonal regeneration was assessed following complete transection of the commissure in AP5/CNQX-treated IC cultures from P12 animals. Neurofilament staining revealed that transected commissural axons survived for 6 days in vitro, but only a few processes crossed the lesion site and these axons did not extend into the contralateral lobe. In contrast, there was robust axonal sprouting and growth within one lobe of the IC, remote from the lesion site. When P6 and P12 tissue was explanted onto a coated substrate, the P6 axons grew onto the substrate, but the P12 axons were seemingly prevented from reaching the substrate by a veil of nonneuronal cells. Coculture of the IC and one of its afferent populations, the lateral superior olive, provided a similar finding, indicating that failure to regenerate was a general property at the age examined. These data show that neuron survival is not sufficient to permit axon regeneration at P12, and suggest that P12 lesion sites manufacture a prohibitive substrate since process outgrowth is blocked specifically at the commissure transection.

Insular cortex representation of dynamic mechanical allodynia in trigeminal neuropathic rats.

Dynamic mechanical allodynia is a widespread symptom of neuropathic pain for which mechanisms are still poorly understood. The present study investigated the organization of dynamic mechanical allodynia processing in the rat insular cortex after chronic constriction injury to the infraorbital nerve (IoN-CCI). Two weeks after unilateral IoN-CCI, rats showed a dramatic bilateral trigeminal dynamic mechanical allodynia. Light, moving stroking of the infraorbital skin resulted in strong, bilateral upregulation of extracellular-signal regulated kinase phosphorylation (pERK-1/2) in the insular cortex of IoN-CCI animals but not sham rats, in whose levels were similar to those of unstimulated IoN-CCI rats. pERK-1/2 was located in neuronal cells only. Stimulus-evoked pERK-1/2 immunopositive cell bodies displayed rostrocaudal gradient and layer selective distribution in the insula, being predominant in the rostral insula and in layers II-III of the dysgranular and to a lesser extent, of the agranular insular cortex. In layers II-III of the rostral dysgranular insular cortex, intense pERK also extended into distal dendrites, up to layer I. These results demonstrate that trigeminal nerve injury induces a significant alteration in the insular cortex processing of tactile stimuli and suggest that ERK phosphorylation contributes to the mechanisms underlying abnormal pain perception under this condition.