The influence of chronic lithium administration on deafferentation-induced cellular changes in the chick cochlear nucleus

The avian brainstem serves as a useful model system to address the question of how afferent activity influences viability of target neurons. Approximately 20-30% of neurons in the chick cochlear nucleus, nucleus magnocellularis (NM) die following deafferentation (i.e. deafness produced by cochlea removal). Previous studies have identified cellular events that occur within hours following cochlea removal, which are thought to lead to the ultimate death of NM neurons. We have recently shown that chronic lithium treatment increases neuronal survival following deafferentation. To assess where in the cell death cascade lithium is having its effect, we evaluated some of the early deafferentation-induced cellular changes in NM neurons. Lithium did not affect deafferentation-induced changes that occur across the entire population of NM neurons. There were still deafferentation-induced increases in intracellular calcium concentrations and early changes in the ribosomes, as indicated by Y10b immunolabeling. Lithium did, however, affect changes that are believed to be indicative of the subpopulation of NM neurons that will eventually die. Ribosomes recovered in all of the deafferented NM neurons (as assessed by Y10b labeling) by 10 h following cochlea removal in subjects pretreated with lithium, while a subpopulation of the NM neurons in saline-treated subjects showed dramatic reduction in Y10b labeling at that time. Lithium treatment also prevented the robust upregulation of b cell leukemia/lymphoma-2 (Bcl-2) mRNA that is observed in a subpopulation of deafferented NM neurons 6 h following cochlea removal.     

Deafferentation-induced caspase-3 activation and DNA fragmentation in chick cochlear nucleus neurons

Cochlea removal severs peripheral processes of cochlear ganglion cells and permanently abolishes afferent input to nucleus magnocellularis (NM) neurons. Deafferented chick NM neurons undergo a series of morphologic and metabolic changes, which ultimately trigger the death of 20%–40% of neurons. Previous studies suggested that this cell specific death involves activation of the intrinsic apoptotic pathway, including increased presence of cytochrome c and active caspase-9 in the cytoplasm of deafferented NM neurons. Interestingly, however, both markers were detected pan-neuronally, in both degenerating and surviving NM neurons [Wilkinson BL, Elam JS, Fadool DA, Hyson RL (2003) Afferent regulation of cytochrome-c and active caspase-9 in the avian cochlear nucleus. Neuroscience 120:1071–1079]. Here, we provide evidence for the increased appearance of late apoptotic indicators and describe novel characteristics of cell death in deafferented auditory neurons. Young broiler chickens were subjected to unilateral cochlea removal, and brainstem sections through NM were reacted for active caspase-3 and terminal deoxynucleotidyl transferase–mediated dUTP nick-end labeling (TUNEL). Caspase-3 activation is observed in the cytoplasm of both dying and surviving deafferented NM neurons 24 h to 7 days following cochlea removal, suggesting that caspase-3, usually considered an “executioner” of apoptotic death, may also function as a “modulator” of death. In addition, we find that TUNEL labeling of degraded DNA is observed in deafferented NM. In contrast to upstream apoptotic markers, however, TUNEL labeling is restricted to a subpopulation of deafferented neurons. Twelve hours following cochlea removal, TUNEL labeling is observed as punctate accumulations within nuclei. Twenty-four hours following cochlea removal, TUNEL accumulates diffusely throughout neuronal cytoplasm in those neurons likely to die. This cytoplasmic TUNEL labeling may implicate mitochondrial nucleic acid degradation in the selective death of some deafferented NM neurons. Our study examines the subcellular distributions of two prominent apoptotic mediators, active caspase-3 and TUNEL, relative to known histochemical markers, in deafferented NM; provides new insight into the apoptotic mechanism of cell death; and proposes a role for mitochondrial DNA in deafferentation-induced cell death.     

Activity-dependent regulation of the subcellular localization of neuronal calcium sensor-1 in the avian cochlear nucleus

Neurons in the avian cochlear nucleus, nucleus magnocellularis (NM), are highly sensitive to manipulations of afferent input, and removal of afferent activity through cochlear ablation results in the death of approximately 20-40% of ipsilateral NM neurons. The intracellular cascades that determine whether an individual NM neuron will die or survive are not fully understood. One early event observed in NM following deafferentation is a rapid rise in intracellular calcium concentration. In most cellular systems, the activity of calcium-binding proteins is believed to accommodate calcium influx. The calcium-binding protein, neuronal calcium sensor-1 (NCS-1), is an intracellular neuronal calcium sensor belonging to the EF-hand superfamily. NCS-1 has been implicated in calcium-dependent regulation of signaling cascades. To evaluate NCS-1 action in NM neurons, the localization of NCS-1 protein was examined. Double-label immunofluorescence experiments revealed that NCS-1 expression is evident in both the presynaptic nerve terminal and postsynaptic NM neuron. The postsynaptic expression of NCS-1 typically appears to be closely associated with the cell membrane. This close proximity of NCS-1 to the postsynaptic membrane could allow NCS-1 to function as a modulator of postsynaptic signaling events. Following deafferentation, NM neurons were more likely to show diffuse cytoplasmic NCS-1 labeling. This increase in the number of cells showing diffuse cytoplasmic labeling was observed 12 and 24 h following cochlea ablation, but was not observed 4 days following surgery. This activity-dependent regulation of NCS-1 subcellular localization suggests it may be associated with, or influenced by, processes important for the survival of NM neurons.     

Lithium increases bcl-2 expression in chick cochlear nucleus and protects against deafferentation-induced cell death

Approximately 20-30% of neurons in the avian cochlear nucleus (nucleus magnocellularis) die following deafferentation (i.e. deafness produced by cochlea removal) and the remaining neurons show a decrease in soma size. Cell death is generally accepted to be a highly regulated process involving various pro-survival and pro-death molecules. One treatment that has been shown to modify the expression of these molecules is chronic administration of lithium. The present experiments examined whether lithium treatment can protect neurons from deafferentation-induced cell death. Post-hatch chicks were treated with LiCl or saline for 17 consecutive days, beginning on the day of hatching. On the 17th day, a unilateral cochlea ablation was performed. Five days following surgery, the nucleus magnocellularis neurons were counted stereologically on opposite sides of the same brains. Lithium reduced deafferentation-induced cell death by more than 50% (9.8% cell death as compared with 22.4% in saline-treated subjects). Lithium did not affect cell number on the intact side of the brain. Lithium also did not prevent the deafferentation-induced decrease in soma size, suggesting a dissociation between the mechanisms involved in the afferent control of soma size and those involved in the afferent control of cell viability. A possible mechanism for lithium's neuroprotective influence was examined in a second set of subjects. Previous studies suggest that the pro-survival molecule, bcl-2, may play a role in regulating cell death following deafferentation. Tissues from lithium- and saline-treated subjects were examined using immunocytochemistry. Chronic administration of lithium dramatically increased the expression of bcl-2 protein in nucleus magnocellularis neurons. These data suggest that lithium may impart its neuroprotective effect by altering the expression of molecules that regulate cell death.     

Caspase 9及其相关分子基因表达水平改变对同型半胱氨酸内皮凋亡的影响

目的 了解caspase 3信号传导通路中上游分子Bcl 2、细胞色素c（cytochrome-c）、caspase 9在同型半胱氨酸作用下的人脐静脉血管内皮细胞内的mRNA及蛋白表达水平的改变，揭示线粒体参与信号传导链在caspase 3所介导的内皮细胞凋亡过程中的作用。方法 培养人脐静脉内皮细胞，用不同浓度同型半胱氨酸作用于细胞后，用逆转录-聚合酶链反应及Western印迹分别检测各分子基因及蛋白表达水平的改变。结果 Bcl 2、cytochrome-c和caspase 9在同型半胱氨酸作用下mRNA及蛋白表达水平下降，并且随同型半胱氨酸浓度的升高而降低。结论 Bcl 2可能参与了同型半胱氨酸促进细胞凋亡的信号传导途径。Caspase 3没有通过上游分子apoptosome和caspase 9途径活化。这些研究结果提示，同型半胱氨酸诱导细胞凋亡并不是通过以线粒体凋亡通路为主的信号传导通路。     

Rapid regulation of microtubule-associated protein 2 in dendrites of nucleus laminaris of the chick following deprivation of afferent activity

Differential innervation of segregated dendritic domains in the chick nucleus laminaris (NL), composed of third-order auditory neurons, provides a unique model to study synaptic regulation of dendritic structure. Altering the synaptic input to one dendritic domain affects the structure and length of the manipulated dendrites while leaving the other set of unmanipulated dendrites largely unchanged. Little is known about the effects of neuronal input on the cytoskeletal structure of NL dendrites and whether changes in the cytoskeleton are responsible for dendritic remodeling following manipulations of synaptic input. In this study, we investigate changes in the immunoreactivity of high-molecular weight microtubule associated protein 2 (MAP2) in NL dendrites following two different manipulations of their afferent input. Unilateral cochlea removal eliminates excitatory synaptic input to the ventral dendrites of the contralateral NL and the dorsal dendrites of the ipsilateral NL. This manipulation produced a dramatic decrease in MAP2 immunoreactivity in the deafferented dendrites. This decrease was detected as early as 3 h following the surgery, well before any degeneration of afferent axons. A similar decrease in MAP2 immunoreactivity in deafferented NL dendrites was detected following a midline transection that silences the excitatory synaptic input to the ventral dendrites on both sides of the brain. These changes were most distinct in the caudal portion of the nucleus where individual deafferented dendritic branches contained less immunoreactivity than intact dendrites. Our results suggest that the cytoskeletal protein MAP2, which is distributed in dendrites, perikarya, and postsynaptic densities, may play a role in deafferentation-induced dendritic remodeling.     

The differential response of astrocytes within the vestibular and cochlear nuclei following unilateral labyrinthectomy or vestibular afferent activity blockade by transtympanic tetrodotoxin injection in the rat

In this study, we investigated whether changes in the vestibular neuronal activity per se influence the pattern of astrocytes morphology, glial fibrillary acidic protein (GFAP) expression and ultimately their activation within the vestibular nuclei after unilateral transtympanic tetrodotoxin (TTX) injections and after unilateral inner ear lesion. The rationale was that, theoretically the noninvasive pharmacological functional blockade of peripheral vestibular inputs with TTX, allowed us to dissociate the signals exclusively related to the shutdown of the resting activity of the first-order vestibular neurons and from neuronal signals associated with trans-ganglionic changes in first order vestibular neurons induced by unilateral labyrinthectomy (UL). Since the cochlea was removed during the surgical procedure, we also studied the astrocytic reaction within the deafferented cochlear nuclei. No significant changes in the distribution or relative levels of GFAP mRNA expression, relative levels of GFAP protein or immunoreactivity for GFAP were found in the ipsilateral vestibular nuclei at any post-TTX injection times studied. In addition, no sign of microglia activation was observed. In contrast, a robust increase of the distribution and relative levels of GFAP mRNA expression, protein levels and immunoreactivity was observed in the deafferented vestibular and cochlear nuclei beginning at 1 day after inner ear lesion. GFAP mRNA expression and immunoreactivity in the cochlear nucleus was qualitatively stronger than in the ipsilateral vestibular nuclei. The results suggest that astrocyte activation in the vestibular nuclei is not related to drastic changes of vestibular nuclei neuronal activity per se. Early trans-ganglionic changes due to vestibular nerve dendrites lesion provoked by the mechanical destruction of vestibular receptors, most probably induced the glial reaction. Its functional role in the vestibular compensation process remains to be elucidated.     

Fas/CD95-mediated apoptosis of type II cells is blocked by Toxoplasma gondii primarily via interference with the mitochondrial amplification loop

The intracellular protozoan Toxoplasma gondii induces persistent infections in various hosts and is an important opportunistic pathogen of humans with immature or deficient immune responses. The ability to survive intracellularly largely depends on the blocking of different proapoptotic signaling cascades of its host cell. Fas/CD95 triggers an apoptotic cascade that is crucial for immunity and the outcome of infectious diseases. We have determined the mechanism by which T. gondii counteracts death receptor-mediated cell death in type II cells that transduce Fas/CD95 ligation via caspase 8-mediated activation of the mitochondrial amplification loop. The results showed that infection with T. gondii significantly reduced Fas/CD95-triggered apoptosis in HeLa cells by inhibiting the activities of initiator caspases 8 and 9 and effector caspase 3/7. Parasitic infection dose dependently diminished cleavage of caspase 8, the BH3-only protein Bid, and the downstream caspases 9 and 3. Importantly, interference with Fas/CD95-triggered caspase 8 and caspase 3/7 activities after parasitic infection was largely dependent on the presence of caspase 9. Within the mitochondrial amplification loop, T. gondii significantly inhibited the Fas/CD95-triggered release of cytochrome c into the host cell cytosol. These results indicate that T. gondii inhibits Fas/CD95-mediated apoptosis in type II cells primarily by decreasing the apoptogenic function of mitochondria.     

Granzyme A induces caspase-independent mitochondrial damage, a required first step for apoptosis

Granzyme A (GzmA) triggers cell death with apoptotic features by targeting the endoplasmic reticulum-associated SET complex, which contains the GzmA-activated DNase NM23-H1, its inhibitor SET, and Ape1. The SET complex was postulated to translocate to the nucleus in response to oxidative stress and participate in its repair. Because mitochondrial damage is important in apoptosis, we investigated whether GzmA damages mitochondria. GzmA induces a rapid increase in reactive oxygen species and mitochondrial transmembrane potential loss, but does not cleave bid or cause apoptogenic factor release. The mitochondrial effect is direct, does not require cytosol, and is insensitive to bcl-2 and caspase inhibition. SET complex nuclear translocation, which occurs within minutes of peroxide or GzmA treatment, is dependent on superoxide generation since superoxide scavengers block it. Superoxide scavengers also block apoptosis by CTLs expressing GzmA and/or GzmB. Therefore, mitochondrial damage is an essential first step in killer cell granule-mediated pathways of apoptosis.     

Tooth pulp deafferentation is associated with functional alterations in the properties of neurons in the trigeminal spinal tract nucleus

The effects of deafferentation of the tooth pulps of mandibular or maxillary teeth were investigated on the functional properties of single neurons recorded in the subnucleus oralis of the trigeminal (V) spinal tract nucleus of adult cats. Deafferentation was produced by endodontic removal, under sterile conditions, of the coronal pulp of the canine, premolar, and molar teeth. The subnucleus oralis of each animal was then studied electrophysiologically in a series of microelectrode penetrations of the subnucleus at a single postoperative time that varied between 3 days and 2 yr. Data from deafferented cats were compared with those obtained from control (unoperated) animals. The study was based on an examination of over 2,000 single units recorded on the side ipsilateral to the pulp deafferentation. In animals deafferented 7-15 days prior to brain stem neuron recording, tooth pulp deafferentation was associated with a statistically significant decrease compared with control animals in the incidence of neurons having a mechanoreceptive field localized within the mandibular or maxillary division; this decrease in incidence was coincident with a significant increase in the occurrence of neurons having a mechanoreceptive field involving two or three V divisions. Linear trend analysis indicated a progressive return to control values from the 7- to 15-day postoperative period. In deafferented cats there were also statistically significant increases in the incidence of neurons having spontaneous activity or showing rapidly habituating responses to brisk tap stimuli applied to the orofacial region; neurons having a receptive field consisting of discontinuous zones of mechanosensitivity were also encountered. The mean impulse frequency of spontaneous activity was not, however, significantly different between control and deafferented animals. The responsiveness of the habituating tap-sensitive neurons was further quantified and compared with neurons showing normal rapidly adapting (RA) features of their responses to mechanical orofacial stimuli. Whereas most (85%) of the RA neurons could faithfully follow stimuli applied by a mechanical stimulator at a mean maximal following frequency of 6.6 Hz and showed entrainment and 'turning curve' profiles comparable to those previously described for oralis neurons in normal animals, most of the habituating tap-sensitive neurons could not follow mechanical stimulus frequencies greater than 1 Hz (mean maximal following frequency 0.3 Hz) and none could be entrained sufficiently to allow for a determination of their tuning curve.(ABSTRACT TRUNCATED AT 400 WORDS)     

Plastic changes underlying vestibular compensation in the guinea-pig persist in isolated, in vitro whole brain preparations.

Vestibular compensation for the postural and oculomotor deficits induced by unilateral labyrinthectomy is a model of post-lesional plasticity in the central nervous system. Just after the removal of one labyrinth, the deafferented, ipsilateral vestibular nucleus neurons are almost silent, and the discharge of the contralateral vestibular nucleus neurons is increased. The associated static disorders disappear in a few days, as normal activity is restored in both vestibular nuclei. In this study, we searched for traces of vestibular compensation in isolated whole brains taken from adult guinea-pigs. The electrophysiological responses evoked in control brains were compared to those evoked in brains taken from animals that had previously been labyrinthectomized. Guinea-pigs compensated for an initial labyrinthectomy within three days. In vivo, subsequent deafferentation of vestibular nucleus neurons on the intact side triggered "Bechterew's phenomenon": a new postural and oculomotor syndrome appeared, similar to the one induced by the first lesion, but directed to the newly deafferented side. These disturbances would be caused by the new imbalance between the discharges of neurons in the two vestibular nuclei triggered by the second deafferentation. Experiments were designed to search for a similar imbalance in vitro in brains taken from labyrinthectomized animals, where the intact vestibular nerve is cut during the dissection. Isolated whole brains were obtained from young guinea-pigs at various times (one to seven days) following an initial labyrinthectomy. An imbalance between the resting activities of medial vestibular nucleus neurons on both sides of the brainstem was revealed in brains taken more than three days after the lesion: their discharge was higher on the compensated, initially lesioned side than on the newly deafferented side. In some cases, an oscillatory pattern of discharge, reminiscent of the spontaneous nystagmus associated in vivo with Bechterew's syndrome, appeared in both abducens nerves. These data demonstrate that most of the changes underlying vestibular compensation persist, and can thus be investigated in the isolated whole brain preparation. Brains removed only one day after the lesion displayed normal commissural responses and symmetric spinal inputs to vestibular nucleus neurons. However, an unusually large proportion of the neurons recorded on both sides of the preparation had very irregular spontaneous discharge rates. These data suggest that the first stages of vestibular compensation might be associated with transient changes in the membrane properties of vestibular nucleus neurons. Brains taken from compensated animals displayed a significant, bilateral decrease of the inhibitory commissural responses evoked in the medial vestibular nucleus by single-shock stimulation of the contralateral vestibular nerve. The sensitivity of abducens motoneurons on the initially lesioned, compensated side to synaptic activation from the contralesional vestibular nucleus neurons was also decreased. Both changes may explain the long-term, bilateral decrease of vestibular-related reflexes observed following unilateral labyrinthectomy. Spinal inputs to vestibular nucleus neurons became progressively asymmetric: their efficacy was increased on the lesioned side and decreased on the intact one. This last modification may support a functional substitution of the deficient, vestibular-related synergies involved in gaze and posture stabilization by neck-related reflexes.     

Differential involvement of p38 MAP kinase pathway and Bax translocation in the mitochondria-mediated cell death in TCR- and dexamethasone-stimulated thymocytes

Mitochondria play a central role in many apoptotic reactions. Although mitochondrial apoptotic changes and caspase activation have been demonstrated in the apoptotic thymocytes, cell death signal through mitochondria in TCR-stimulated thymocytes has not been fully understood. In this study, we show that TCR stimulation induced disruption of mitochondrial transmembrane potential (Delta Psi(m)), the cytochrome c release from mitochondira, capase-3 activation, and the cell death of thymocytes. Bongkrekic acid, an inhibitor of Delta Psi(m) disruption, blocked the cytochrome c release from mitochondria and the following caspase-3-mediated cell death. Furthermore, a pro-apoptotic Bcl-2 family protein, Bax, but not Bad or Bid, was translocated from cytosol to mitochondria in TCR-stimulated thymocytes. This translocation and the following apoptotic changes were inhibited by SB203580, a p38 kinase inhibitor, in a specific manner. These results suggest that activated p38 kinase pathway by TCR stimulation induces translocation of Bax to mitochondria, causing Delta Psi(m) disruption, and the release of cytochrome c, which finally induces caspase-3-mediated apoptosis in thymocytes.     

Effects of tooth pulp deafferentation on nociceptive and nonnociceptive neurons of the feline trigeminal subnucleus caudalis (medullary dorsal horn)

1. Effects of deafferentation of the tooth pulps of the posterior mandibular teeth were studied in single neurons recorded in the ipsilateral subnucleus caudalis of the trigeminal (V) spinal tract nucleus of adult cats and kittens. The functional properties of neurons in each anesthetized animal were determined electro-physiologically in a series of microelectrode penetrations of the subnucleus. 2. The more than 800 neurons investigated could be subdivided on the basis of their cutaneous mechanoreceptive field properties into low-threshold mechanoreceptive (LTM) neurons, wide dynamic range (WDR) neurons, or nociceptive-specific (NS) neurons. Comparisons of neuronal properties were made between control (intact) cats and 7-15 day deafferented cats studied in a blind design, as well as groups of longer term deafferented cats, and kittens undergoing a "natural" deafferentation as a result of exfoliation of primary teeth. 3. There was no apparent change in the somatotopic pattern of organization of the subnucleus in the kittens and pulp-deafferented cats and no statistically significant differences were noted between kittens and control cats in any property except for alterations in the incidence of spontaneously active neurons. 4. Limited but statistically significant alterations were noted in some of the neuronal properties in the deafferented cats. These changes were especially apparent in the LTM neurons. The incidence of spontaneous activity was significantly decreased in the neurons of most long-term deafferented groups of cats. In the 7-15 day deafferented group, significantly more LTM neurons had a mechanoreceptive field involving all three divisions of the V nerve, and there was a significant increase in the incidence of LTM neurons activated by electrical stimulation of intraoral sites. Mechanosensitive neurons responsive only to tap stimuli were found only in the deafferented groups of cats. 5. These alterations in caudalis contrast with previous reports claiming marked hyperexcitability of caudal V brain stem neurons as a consequence of deafferentation and implicating such effects in the development of pain. However, some of the changes are in general not inconsistent with deafferentation-induced changes reported in spinal somatosensory neurons and with the pulp deafferentation-induced changes that we have recently documented in LTM neurons of subnucleus oralis of the V spinal tract nucleus of adult cats.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunolocalization of caspase proteolysis in situ: evidence for widespread caspase-mediated apoptosis of neurons and glia in the postnatal rat brain.

Activation of a member of the caspase family of cysteine proteases is thought to be required for the execution of apoptosis in neurons and other cell types. We describe here an antibody (Ab127) reactive with a neoantigenic site on caspase substrate proteins degraded during apoptosis, and its characterization as a biochemical and histochemical probe for apoptosis-associated proteolysis in growth factor-deprived neural cells in vitro and the developing postnatal rat brain. Neuronally differentiated PC12 cells became strongly Ab127 immunoreactive only during apoptosis following nerve growth factor withdrawal. Apoptosis-associated caspase proteolysis was detectable on western blots as markedly increased immunoreactivity of a approximately 46,000 mol. wt polypeptide, a product also generated by caspase-3 treatment of cell-free extracts. In the postnatal rat brain, intense immunoreactivity indicative of caspase activation was exhibited by small proportions of neurons and glia in distinct regional and temporal patterns. The degenerating nature of these cells was confirmed by their argyrophilia, cytoplasmic immunoreactivity for c-jun and fragmented processes. Combined immunofluorescence and Hoechst 33342 staining demonstrated that cells immunopositive for caspase activation have apoptotic nuclear morphologies. Caspase proteolysis was observed throughout the neuraxis in a minority of progenitor cells in germinal zones, postmitotic neurons in the parenchyma, and glia in the corpus callosum and other white matter tracts, but was observed rarely in the adult brain. These data characterize a new approach for evaluating apoptosis in physiological and pathological neurodegeneration, and demonstrate that caspase-associated apoptosis is a widespread mechanism for the programmed death of neurons and glia in the postnatal rat brain.     

Mitochondrial anomalies are associated with the induction of intrinsic cell death proteins-Bcl(2), Bax,cytochrome-c and p53 in mice brain during experimental fatal murine cerebral malaria

The levels of apoptosis associated proteins Bcl(2), Bax, cytochrome-c and p53 was investigated in mice cerebral cortex and cerebellum, using an experimental model of fatal murine cerebral malaria (FMCM). Owing to the activation of events central to mitochondrial dysfunctions, we monitored the structural integrity of mitochondria in cerebral malaria (CM) infected brain tissue by transmission EM (TEM) studies. Western blot analysis revealed the induction of Bcl(2), Bax, cytochrome-c and p53 in both cortex and cerebellum. The TEM studies revealed extensive vacuolation and swelling of mitochondria in infected brain suggestive of a late stage of degeneration. Our results underscore the activation of an intrinsic cell death pathway as evinced by the induction of mitochondria associated apoptotic proteins Bcl(2), Bax and cytochrome-c and further envisages the induction of p53 as a possible continuation of the post receptor signaling events associated with tumor necrosis factor induction following inflammatory responses during CM. These findings may be crucial to mitochondrial dysfunctions underlying the pathology of FMCM.     

Molecular aspects of apoptosis

Corresponding to its importance in cell count homeostasis in the body, apoptosis is a tightly regulated phenomenon. Both extracellular and intracellular molecules provide multiple regulatory and counter-regulatory pathways. Cell death is usually a response to the cell microenvironment, where the absence of certain factors (survival factors) or the presence of lethal factors promotes apoptosis. Surrounding cells, soluble mediators and the extracellular matrix regulate cell death and survival. Surrounding cells can synthesize survival or lethal factors. The intracellular regulation of apoptosis is also one of the forefront fields in biomedicine research. During the past five years, tremendous progress has been made in understanding apoptosis as a result of molecular identification of the key components of this intracellular suicide program. Biochemical activation of these key components of the cell death program is responsible for the morphological changes observed in apoptosis, including mitochondrial damage, nuclear membrane breakdown, DNA fragmentation, chromatin condensation and the formation of apoptotic bodies. Caspase activation plays a central role in the execution of apoptosis. Most caspases are constitutively expressed as inactive proenzymes (procaspases) in the cytosol and according to some reports in the mitohondria. Caspases are sequentially activated by proteolysis during apoptosis. In this review, we focus on the biochemical pathways that control caspase activation, particularly the activation pathways that are initiated by cell surface death receptors and mitochondria.     

Immunohistochemical evidence for GABAergic cell bodies in the medial nucleus of the trapezoid body and in the lateral vestibular nucleus in the guinea pig brainstem

The presence of gamma-aminobutyric acid (GABA) in two brainstem nuclei is demonstrated by using a pre-embedding immunohistochemical procedure followed by staining intensification. Firstly, immunoreactivity was found in numerous cell bodies and profiles of the medial nucleus of the trapezoid body (MNTB). Secondly, numerous neurons including giant Deiters' cells, terminals and fibers were strongly labelled within the lateral vestibular nucleus (LVN). These observations suggest that the inhibitory part of the efferent innervation of outer hair cells in the cochlea can originate from the MNTB, and that GABAergic neurons in the LVN may contribute to information processing within this nucleus.     

Embryonic neuronal death due to neurotrophin and neurotransmitter deprivation occurs independent of Apaf-1

Apoptotic protease-activating factor-1 (Apaf-1), dATP, and procaspase-9 form a multimeric complex that triggers programmed cell death through the activation of caspases upon release of cytochrome c from the mitochondria into the cytosol. Although cell death pathways exist that can bypass the requirement for cytochrome c release and caspase activation, several gene knockout studies have shown that the cytochrome c-mediated apoptotic pathway is critical for neural development. Specifically, the number of neuronal progenitor cells is abnormally increased in Apaf-1-, caspase-9-, caspase-3-deficient mice. However, the role of the cytochrome c cell death pathway for apoptosis of postmitotic, differentiated neurons in the developing brain has not been investigated in vivo. In this study we investigated embryonic neuronal cell death caused by trophic factor deprivation or lack of neurotransmitter release by analyzing Apaf-1/tyrosine kinase receptor A (TrkA) and Apaf-1/Munc-18 double mutant mice. Histological analysis of the double mutants' brains (including cell counting and terminal (TdT)-mediated dUTP-biotin nick end labeling (TUNEL) staining) reveals that neuronal cell death caused by these stimuli can proceed independent of Apaf-1.We propose that a switch between apoptotic programs (and their respective proteins) characterizes the transition of a neuronal precursor cell from the progenitor pool to the postmitotic population of differentiated neurons.     

Lack of growth-associated protein-43 reemergence or of growth-associated protein-43 mRNA modulation in deafferented vestibular nuclei during the first 6 weeks after unilateral inner ear lesion

We investigated whether a unilateral inner ear lesion that destroyed the labyrinthine receptors, the cochlear receptors, and the spiral ganglion induced collateral sprouting in rat vestibular and auditory brainstem nuclei, using growth-associated protein-43 (GAP-43) as an indicator of synaptic remodeling. Both immunocytochemistry and in situ hybridization were performed to detect a potential modulation of GAP-43 and of its messenger RNA (mRNA) at different times after surgery. We failed to observe a reemergence of GAP-43 or a modulation of its mRNA in the deafferented vestibular nuclei at all survival times tested. In contrast, a substantial increase in the expression of GAP-43 was observed in the neuropil of the ipsilateral deafferented cochlear nuclei and in cell bodies of the ipsilateral superior olive. This increase was associated with an up- and downregulation of the mRNA coding for GAP-43 in the ipsilateral ventral cochlear nucleus and in the ipsilateral superior olive, respectively. These data indicate that synaptic remodeling, as assessed by GAP-43 expression, does not seem to occur in the deafferented vestibular complex during the first 6 weeks after labyrinthectomy, whereas it occurs within the first deafferented auditory relays at times as early as 4 days following spiral ganglion and cochlear receptors removal. We conclude that recovery of a normal resting discharge of the deafferented central vestibular neurons and consequently recovery of a normal resting posture and eye position may not depend on collateral sprouting of the remaining vestibular afferents. In contrast, we confirmed that a reactive synaptogenesis occurs in the brainstem auditory nuclei following cochlea and spiral ganglion removal. Its functional significance remains an open question.