Recovery following peripheral destruction of olfactory neurons in young and adult mice

Olfactory neurons (ON) which are located in the olfactory epithelium are responsible of odorous molecule detection. A unique feature of these cells is their continuous replacement throughout life due to the proliferation and differentiation of local neural precursors, the basal cells. Thus, experimental destruction of all ON induces a stimulation of basal cell division followed by tissue regeneration. The fact that ON precursors display such proliferative and neurogenic activity in adults makes these cells particularly attractive as a potential tool for nervous system repair. However, basal cell proliferation and, thus, ON production, decrease in relation to age; mostly during the first months of life. Therefore, we aimed to seek whether the ability of ON precursors to yield new functional ON in regenerative conditions was consequently impaired in adult. ZnSO4 intranasal perfusion administered to young (1 month) and adult (6 months) mice leads in a few days to total ON destruction and to hyposmia. Tissue and function restoration occurred in the following weeks in both mice groups and was preceded by a transient peak of cell division. In adults, although neurogenesis in the impaired olfactory epithelium was less efficient than in young mice, neural precursors retain their ability to provide new functional ON as indicated by the butanol detection recovery. This was achieved more rapidly than total ON regeneration, suggesting that a reduced number of reconnected ON may be sufficient for odor discrimination.     

Lesion response of long-term and recently immigrated resident endoneurial macrophages in peripheral nerve explant cultures from bone marrow chimeric mice

Resident macrophages of the peripheral nervous system have recently been shown to respond rapidly to Wallerian degeneration before the influx of blood-derived macrophages. Because resident endoneurial macrophages are slowly but incompletely exchanged from the blood within 3 months, they could potentially comprise a heterogenous cell population consisting of long-term resident cells and more mobile cells undergoing turnover. We used bone marrow chimeric mice created by transplanting bone marrow from green fluorescent protein-transgenic mice into irradiated wildtype recipients to selectively analyse the response of these two resident macrophage populations to Wallerian degeneration in sciatic nerve explant cultures. In such nerves, recently immigrated macrophages exhibit green fluorescence whereas long-term resident macrophages do not. Studies in cultures from wildtype controls revealed rapid morphological changes of resident macrophages towards a bloated phenotype, a proliferative response resulting in a 3.7-fold increase of macrophage numbers over 2 weeks, and phagocytosis of myelin basic protein-immunoreactive myelin debris. When chimeric mice were analysed, both populations of resident endoneurial macrophages participated in morphological transformation, proliferation and phagocytosis. Quantitative studies revealed a stronger proliferative and phagocytic response in long-term resident endoneurial macrophages compared with recently immigrated macrophages. Our results point towards subtle, but not principal, differences between the two macrophage populations, which might indicate different stages of macrophage differentiation rather than the existence of entirely distinct endoneurial macrophage populations. The results further underline the versatility of resident endoneurial macrophages following peripheral nerve injury, which is reminiscent of the lesion response of microglial cells within the brain.     

Microarray analysis suggests the involvement of proteasomes,lysosomes, and matrix metalloproteinases in the response of motor neurons to root avulsion

We used microarray analysis of RNA expression from punch samples from ventral horn of spinal cord to identify alterations in gene expression in motor neurons 3 days after proximal spinal root avulsion, a traumatic injury that results in the death of 80% of the motor neurons. This analysis identified the anticipated increases in expression of genes coding for proteins involved in the apoptosis cascades and abortive cell cycle re-entry, as well as decreases in expression of genes coding for proteins related to neuronal functional activity, including groups of genes related to energy metabolism, transporter proteins, ion channels, and receptors. It was also found that cathepsins, metalloproteinases, and proteasome-related protein products were highly up-regulated in motor neurons following axotomy. Each of these products represent pathways that have been implicated in other models of neuronal damage, but which have not previously been described as a response to axotomy.     

Morphological alterations in the amygdala and hippocampus of mice during ageing

Declines in memory function and behavioural dysfunction accompany normal ageing in mammals. However, the cellular and morphological basis of this decline remains largely unknown. It was assumed for a long time that cell losses in the hippocampus accompany ageing. However, recent stereological studies have questioned this finding. In addition, the effect of ageing is largely unknown in another key structure of the memory system, the amygdala. In the present study, we have estimated neuronal density and total neuronal numbers as well as density of fragments of degenerated axons in different hippocampal subfields and amygdaloid nuclei. Comparisons were made among aged (21-26 months old) mice and normal adult littermates (8 months old). No significant volume loss occurs in the hippocampus of aged mice. Small but insignificant reductions in total neuronal numbers were found in the hippocampus and in the amygdaloid nuclei. In contrast to the mild effects of ageing upon neuronal numbers, fragments of degenerated axons were increased in both hippocampus and amygdala of aged mice. These data suggest that ageing does not induce prominent cell loss in the hippocampus or amygdala, but leads to degeneration of axons that innervate these forebrain structures. Thus, mechanisms underlying age-related dysfunction depend on parameters other than neuronal numbers, at least in the hippocampal formation and the amygdala.     

M-CSF deficiency leads to reduced metallothioneins I and II expression and increased tissue damage in the brain stem after 6-aminonicotinamide treatment

6-Aminonicotinamide (6-AN) is a niacin antagonist, which leads to degeneration of gray-matter astrocytes followed by a vigorous inflammatory response. Macrophage colony stimulating factor (M-CSF) is important during inflammation, and in order to further clarify the roles for M-CSF in neurodegeneration and brain cell death, we have examined the effect of 6-AN on osteopetrotic mice with genetic M-CSF deficiency (op/op mice). The 6-AN-induced degeneration of gray-matter areas was comparable in control and op/op mice, but the numbers of reactive astrocytes, macrophages, and lymphocytes in the damaged areas were significantly decreased in op/op mice relative to controls. The levels of oxidative stress (as determined by using immunoreactivity for inducible nitric oxide synthase, nitrotyrosine, and malondialdehyde) and apoptotic cell death (as determined by using TUNEL and immunoreactivity for caspases and cytochrome c) were significantly increased in 6-AN-injected op/op mice relative to controls. From a number of antioxidant factors assayed, only metallothioneins I and II (MT-I+II) were decreased in op/op mice in comparison to controls. Thus, the present results indicate that M-CSF is an important growth factor for coping with 6-AN-induced central nervous system damage and suggest that MT-I+II are likely to have a significant role.     

Synaptophysin in the cochlear nucleus following acoustic trauma

Chinchillas are notable for a low-frequency hearing range similar to that of humans and a marked sensitivity to loud noise. A single noise exposure that produces cochlear damage may lead to progressive loss of synaptic endings in the cochlear nucleus, followed by new axonal growth. As an index of synaptic regulation during such changes, we have examined the expression of a synaptic vesicle protein, synaptophysin, in the cochlear nucleus following a damaging acoustic stimulus in adult chinchillas. With one ear protected by a plug, following a 3-h exposure to an octave-band noise of 108 dB sound pressure level, centered at 4 kHz, the unprotected cochlea and the cochlear nuclei exhibited degeneration of hair cells and axons over periods of 7, 14, 30, 90, and 150 days. Axonal degeneration, as revealed by a silver degeneration method, was heavy ipsilateral to the cochlear damage, but sparse degeneration also appeared on the contralateral, unexposed side. Synaptophysin immunostaining underwent a major, bilateral decline in the anteroventral and posteroventral cochlear nuclei, interrupted at intervening periods by transient increases in the numbers of stained structures. A distinction in staining between large perisomatic structures and smaller puncta in the neuropil and between the dorsal and the ventral zones of the ventral cochlear nuclei revealed some variations in the response and degree of recovery of synaptophysin staining. These findings could best be explained by degeneration of synaptic endings followed by new growth of terminals and by regulatory changes in the levels of synaptophysin expression and synaptic vesicle accumulation over time.     

Expression of voltage-dependent potassium channels in the developing visual system of Xenopus laevis

Accumulating evidence suggests that voltage-dependent potassium (Kv) channels have important and varied roles in the development of neuronal and non-neuronal cell types. They have been implicated in processes such as proliferation, cell adhesion, migration, neurite outgrowth, and axon guidance. In this study, we used antibodies against several electrically active Kv channel alpha-subunits (Kv1-4) to describe the spatial and temporal expression patterns of Kv channel subunits in Xenopus laevis retinal ganglion cell (RGC) somata, axons, and growth cones. We found that RGCs express Kv1.3-, Kv1.5-, Kv3.4-, and Kv4.2-like subunits. Each subunit displayed unique cellular and subcellular distributions. Moreover, the expression patterns changed considerably over the major period of Xenopus retinal cell genesis and differentiation. Weak or no immunoreactivity was observed with antibodies against Kv1.1, Kv1.2, Kv1.4, Kv1.6, and Kv3.2 subunits in RGCs or other retinal cell types. In support of our previous pharmacologic evidence implicating Kv channels in RGC axon outgrowth, we found that Kv1.5-, Kv3.4-, and Kv4.2-like proteins, but not Kv1.3-like subunits, are abundantly expressed in RGC growth cones.     

The development of behavioral abnormalities in the motor neuron degeneration (mnd) mouse

The motor neuron degeneration (mnd) mouse, which has widespread abnormal accumulating lipoprotein and neuronal degeneration, has a mutation in CLN8, the gene for human progressive epilepsy with mental retardation (EPMR). EPMR is one of the neuronal ceroid lipofuscinoses (NCLs), a group of neurological disorders characterized by autofluorescent lipopigment accumulation, blindness, seizures, motor deterioration, and dementia. The human phenotype of EPMR suggests that, in addition to the motor symptoms previously categorized, various types of progressive behavioral abnormalities would be expected in mnd mice. We have therefore examined exploratory behavior, fear conditioning, and aggression in 2-3 month and 4-5 month old male mnd mice and age-matched C57BL/6 (B6) controls. The mnd mice displayed increased activity with decreased habituation in the activity monitor, poor contextual and cued memory, and heightened aggression relative to B6 controls. These behavioral deficits were most prominent at 4-5 months of age, which is prior to the onset of gross motor symptoms at 6 months. Our results provide a link from the mutation via pathology to a quantifiable multidimensional behavioral phenotype of this naturally occurring mouse model of NCL.     

丁酰胆碱酯酶与腰椎退行性变的关系研究

目的研究血清丁酰胆碱酯酶与腰椎退行性变的相关性。方法在日立7170全自动生化分析仪上用速率法测定了42例未手术的腰椎退行性变患者和35例正常体检者的血清丁酰胆碱酯酶。对研究组随访,询问其疼痛感,在痛感明显时采血。其中28例在使用麻醉剂后再次采血测定血清丁酰胆碱酯酶。用配对t检验处理数据。结果42例未手术的腰椎退行性变患者的血清丁酰胆碱酯酶(16945;SD=1637)明显高于正常对照组(10831;SD=1096;P<0.001)。28例研究组病人在使用麻醉剂后血清丁酰胆碱酯酶明显下降(12742;1958,P<0.001)。结论血清丁酰胆碱酯酶测定或可用于腰椎退行性变的诊治。