Motor neurons in Cu/Zn superoxide dismutase-deficient mice develop normally but exhibit enhanced cell death after axonal injury.

The discovery that some cases of familial amyotrophic lateral sclerosis (FALS) are associated with mutations in the gene encoding Cu/Zn superoxide dismutase (SOD1) has focused much attention on the function of SOD1 as related to motor neuron survival. Here we describe the creation and characterization of mice completely deficient for this enzyme. These animals develop normally and show no overt motor deficits by 6 months in age. Histological examination of the spinal cord reveals no signs of pathology in animals 4 months in age. However Cu/Zn SOD-deficient mice exhibit marked vulnerability to motor neuron loss after axonal injury. These results indicate that Cu/Zn SOD is not necessary for normal motor neuron development and function but is required under physiologically stressful conditions following injury.

Dendritic changes in Alzheimer's disease and factors that may underlie these changes.

It seems likely that the Alzheimer disease (AD)-related dendritic changes addressed in this article are induced by two principally different processes. One process is linked to the plastic response associated with deafferentation, that is, long-lasting transneuronally induced regressive changes in dendritic geometry and structure. The other process is associated with severe alterations of the dendritic- and perikaryal cytoskeleton as seen in neurons with the neurofibrillary pathology of AD, that is, the formation of paired helical filaments formed by hyperphosphorylated microtubule-associated protein tau. As the development of dendritic and cytoskeletal abnormalities are at least mediated by alterations in signal transduction, this article also reviews changes in signal pathways in AD. We also discuss transgenic approaches developed to model and understand cytoskeletal abnormalities.

Presenilin-1 P264L knock-in mutation: differential effects on abeta production, amyloid deposition, and neuronal vulnerability.

The pathogenic mechanism linking presenilin-1 (PS-1) gene mutations to familial Alzheimer's disease (FAD) is uncertain, but has been proposed to include increased neuronal sensitivity to degeneration and enhanced amyloidogenic processing of the beta-amyloid precursor protein (APP). We investigated this issue by using gene targeting with the Cre-lox system to introduce an FAD-linked P264L mutation into the endogenous mouse PS-1 gene, an approach that maintains normal regulatory controls over expression. Primary cortical neurons derived from PS-1 homozygous mutant knock-in mice exhibit basal neurodegeneration similar to their PS-1 wild-type counterparts. Staurosporine and Abeta1-42 induce apoptosis, and neither the dose dependence nor maximal extent of cell death is altered by the PS-1 knock-in mutation. Similarly, glutamate-induced neuronal necrosis is unaffected by the PS-1P264L mutation. The lack of effect of the PS-1P264L mutation is confirmed by measures of basal- and toxin-induced caspase and calpain activation, biochemical indices of apoptotic and necrotic signaling, respectively. To analyze the influence of the PS-1P264L knock-in mutation on APP processing and the development of AD-type neuropathology, we created mouse lines carrying mutations in both PS-1 and APP. In contrast to the lack of effect on neuronal vulnerability, cortical neurons cultured from PS-1P264L homozygous mutant mice secrete Abeta42 at an increased rate, whereas secretion of Abeta40 is reduced. Moreover, the PS-1 knock-in mutation selectively increases Abeta42 levels in the mouse brain and accelerates the onset of amyloid deposition and its attendant reactive gliosis, even as a single mutant allele. We conclude that expression of an FAD-linked mutant PS-1 at normal levels does not generally increase cortical neuronal sensitivity to degeneration. Instead, enhanced amyloidogenic processing of APP likely is critical to the pathogenesis of PS-1-linked FAD.

The viability of chondrocytes after an in vivo injection of local anaesthetic and/or corticosteroid: a laboratory study using a rat model.

This in vivo controlled laboratory study was performed to evaluate various intra-articular clinical injection regimes that might be less toxic than some in vitro studies suggest. We hypothesised that low-concentration, preservative-free, pH-balanced agents would be less toxic than high-concentration non-pH-balanced agents with preservatives, and that injections of individual agents are less toxic than combined injections. The left knees of 12- to 13-week-old Sprague-Dawley rats were injected once with eight different single agents, including low and high concentrations of ropivacaine and triamcinolone, alone and in combination, as well as negative and positive controls. The rats were killed at one week or five months, and live-dead staining was performed to quantify the death of chondrocytes. All injections except pH-balanced 0.2% ropivacaine combined with preservative-free 1 mg/ml triamcinolone acetonide resulted in statistically significant decreases in chondrocyte viability, compared with control knees, after one week and five months (p < 0.001). After one week there was no significant difference in viability between 0.2% and 0.5% ropivacaine; however, 4 mg/ml triamcinolone resulted in a lower viability than 1 mg/ml triamcinolone. Although many agents commonly injected into joints are chondrotoxic, in this in vivo study diluting preservative-free 10 mg/ml triamcinolone 1:9 in 0.2% pH-balanced ropivacaine resulted in low toxicity.

Profiling of endogenous brain peptides and small proteins: methodology, computer-assisted analysis, and application to aging and lesion models.

Significant advances in the technology for the isolation of peptides and small proteins have permitted their identification as biologic markers and enhanced the study of the posttranslational life of proteins. The protocol described here examined large numbers of tissue-derived peptides and small proteins, extracted in low pH and boiled so that proteolysis was interrupted. These were then fractionated batchwise using size exclusion and ion-exchange chromatography. Profiles of species in the peptide pools were then generated on reverse-phase high-performance liquid chromatography (HPLC). The HPLC profiles were evaluated with chromatographic analysis software to identify and quantify peptide peaks and with data compilation programs to sort this information into spreadsheets for comparison of profiles among groups. Using rodent brain, the effects of postmortem delay or age were examined. Postmortem delay produced limited alterations to the profiles, but the effect of age was more pronounced. Many changes were apparent until 12 months, after which the profiles became more constant. Additional peptide profiling of the hippocampus demonstrated changes in peptide content as a function of perforant pathway ablation. The major strengths of HPLC-mediated peptide profiling are that it lends itself to automation and can be used to detect changes in peptides and small proteins among experimental groups or subjects without any prior assumptions concerning which ones might be altered.

Net dendritic stability of layer II pyramidal neurons in F344 rat entorhinal cortex from 12 to 37 months.

Dendritic extent of Golgi-Cox stained layer II entorhinal cortex pyramidal neurons was quantified in five groups of male F344 rats aged 12, 20, 27, 30 and 37 months. Over the age range studied, neither the apical nor the basal dendritic trees showed any statistically significant change in total dendritic length, numbers of segments or average segment length. This finding of average stability of the dendritic tree does not imply absence of remodelling of connections, but does require that if remodeling does occur, retraction and proliferation of dendrites must, on average, be equal. We hypothesized that in groups of animals with similar genetic and environmental histories neighbor neuron death provides the major stimulus for dendritic proliferation. Since we found dendritic stability in the cells reported here, we would predict that there should be no age-related loss of layer II pyramidal neurons in the entorhinal cortex of the normally aging F344 male rat between 12 and 37 months. This hypothesis may be tested by counting neurons within this region.

Neuron numbers and sizes in aging brain: comparisons of human, monkey, and rodent data.

One of the several sources of interest in aging animal brains is their potential as models of the aging human brain. In this review we examine whether neuron numbers and sizes change similarly in aging human, monkey and rodent brain regions which data are available from more than one species. The number of brain regions studied in more than one species is surprisingly limited. Some regions show correspondence in age-related changes between humans and selected animal models (primary visual cortex, CA1 of hippocampus). For the majority of regions the data are conflicting, even within one species (e.g., somatosensory cortex, frontal cortex, cerebellum, cholinergic forebrain areas, locus coeruleus). Although some of the conflicting data may be attributed to procedural differences, particularly when data are expressed as density changes, much must be attributed to real species and/or strain differences in rodents. We conclude that neuron numbers and sizes may show similar age-related changes in human and animal brains only for sharply defined brain regions, animal species and/or strains, and age ranges.

Dendritic regression dissociated from neuronal death but associated with partial deafferentation in aging rat supraoptic nucleus.

As neurons are lost in normal aging, the dendrites of surviving neighbor neurons may proliferate, regress, or remain unchanged. In the case of age-related dendritic regression, it has been difficult to distinguish whether the regression precedes neuronal death or whether it is a consequence of loss of afferent supply. The rat supraoptic nucleus (SON) represents a model system in which there is no age-related loss of neurons, but in which there is an age-related loss of afferents. The magnocellular neurosecretory neurons of the SON, that produce vasopressin and oxytocin for release in the posterior pituitary, were studied in male Fischer 344 rats at 3, 12, 20, 27, 30, and 32 months of age. Counts in Nissl-stained sections showed no neuronal loss with age, and confirmed similar findings in other strains of rat and in mouse and human. Nucleolar size increased between 3 and 12 months of age, due, in part, to nucleolar fusion, and was unchanged between 12 and 32 months of age, indicating maintenance of general cellular function in old age. Dendritic extent quantified in Golgi-stained tissue increased between 3 and 12 months of age, was stable between 12 and 20 months, and decreased between 20 and 27 months. We interpret the increase between 3 and 12 months as a late maturational change. Dendritic regression between 20 and 27 months was probably the result of deafferentation due to the preceding age-related loss of the noradrenergic input to the SON from the ventral medulla.

Neuron numbers and dendritic extent in normal aging and Alzheimer's disease.

Factors which limit the interpretation of studies of aging brain include: secular trends, species and strain differences, effects of tissue processing, and bias which may be introduced at many levels of an experimental design. With these limitations considered, evidence is reviewed regarding neuron numbers and dendritic extent in normally aging rodent, monkey and human brain and in Alzheimer's disease. It is concluded that neuron loss and change in dendritic extent in normal aging are regionally specific, and that corresponding brain regions do not always change in similar ways in rodents and primates. It is suggested that such differences may, in part, be due to inconsistent definitions of 'aged' among species. In Alzheimer's disease there is excess neuron loss and dendritic regression in some, but not all, brain regions. Measures of the morphological substrates of brain function show appreciable overlap between AD and control groups. It is hypothesized that the static, post-mortem status of brain morphology may not adequately reflect the functional capabilities of the dynamic morphology of the living brain.

Stability of numbers but not size of mouse forebrain cholinergic neurons to 53 months.

In normal mammalian aging there is a reduction of cholinergic markers in a variety of regions. To determine whether this reduction is related to reduced numbers of basal forebrain cholinergic neurons, we counted the number and measured the sizes of the magnocellular acetylcholinesterase-positive neurons in this region of 7, 15, and 53-month-old C57Bl/6NNIA mice. Data were collected from coded slides containing the medial septum, nucleus of the diagonal band, magnocellular preoptic nucleus, and nucleus basalis magnocellularis. There was no decline in numbers of basal forebrain acetylcholinesterase-positive neurons in any of the regions studied. However, cell sizes showed a progressive age-related decline which was greatest in the nucleus basalis magnocellularis.

A Golgi study of hypothalamic transplants in young and old host rats.

The supraoptic nucleus of the F344 rat shows an age-related dendritic regression. In order to determine whether this previously observed dendritic regression may have been related to extrinsic (to the cell) hormonal, neurotoxic, or other circulating factors unique to the hypothalamus of older brains, we conducted a quantitative Golgi study of F344 embryonic anterior hypothalamic transplants into the third ventricle of young adult (5 months) and older (25 months) male F344 rats. Three months following transplantation there were no qualitative effects of host age on neuronal morphology, nor were there quantitative effects on transplant size, dendritic length or branching frequency within the transplanted tissue. These results suggest that either (a) there were no age-related changes in factors in the host brain which were sufficient to significantly affect dendritic extent or, (b) intrinsic connections or other properties within the transplant may be important in moderating the effect of the milieu of the aged brain on the transplanted tissue.

Stability of dendrites in cortical barrels of C57BL/6N mice between 4 and 45 months.

Qualitative and quantitative studies of dendritic parameters were conducted on Golgi-impregnated layer IV spiny stellate neurons in the posteromedial barrel subfield (PMBSF) of somatosensory cortex of the C57B1/6N mouse. Three mice each, at 4, 12, 22, 26, 30, 36 and 45 months of age were studied. No qualitative changes were observed among animals of different ages. The quantitative data indicated that dendritic length and numbers of segments remained unchanged over all ages studied.

Age-related cochlear hair cell loss is enhanced in mice lacking copper/zinc superoxide dismutase.

Age-related hearing loss in humans and many strains of mice is associated with a base-to-apex gradient of cochlear hair cell loss. To determine if copper/zinc superoxide dismutase (Cu/Zn SOD) deficiency influences age-related cochlear pathology, we compared hair cell losses in cochleas obtained from 2-, 7-, and 17- to 19-month-old wild type (WT) mice with normal levels of Cu/Zn SOD and mutant knockout (KO) mice with a targeted deletion of Sod1, the gene that codes for Cu/Zn SOD. WT and KO mice exhibited similar patterns of hair cell loss with age, i.e., a baso-apical progression of hair cell loss, with greater loss of outer hair cells than inner hair cells. Within each age group, the magnitude of loss was much greater in KO mice compared to WT mice. The results indicate that Cu/Zn SOD deficiency potentiates cochlear hair cell degeneration, presumably through metabolic pathways involving the superoxide radical.

Volumes of the components of the hippocampus in the aging F344 rat.

Much of the recent data on cells, synapses, and other structures in the dentate gyrus and hippocampus as a function of age are packing density or volume fraction data. In order to estimate total numbers, volumes, or surface areas of cells, synapses, vessels, etc., as a function of age, the total volumes of the subregions of the dentate gyrus and hippocampus must be known. The volumes of these subregions, visualized with the Timm stain, have been determined in 24 F344 rats from 4 to 37 months of age. Volumes of the various structures showed age-related increases which were statistically significant for the perforant path zone of the dentate gyrus molecular layer, as well as the total molecular layer, the hilus, and regio inferior and total mossy fiber systems. If the 4-month age group is eliminated from consideration, only the ratio of the volume of the mossy fiber zones to the volume of the perforant path zones of the dentate molecular layer increases significantly with age. Our general finding of lack of volumetric reorganization of the subdivisions of the hippocampal region between 12 and 37 months suggests that studies of the packing densities of structures in most of these zones may be considered comparable across ages, assuming comparability of sampling regions.

Immunolocalization of the mitogen-activated protein kinases p42MAPK and JNK1, and their regulatory kinases MEK1 and MEK4, in adult rat central nervous system.

Cell survival, death, and stress signals are transduced from the cell surface to the cytoplasm and nucleus via a cascade of phosphorylation events involving the mitogen-activated protein kinase (MAPK) family. We compared the distribution of p42 mitogen-activated protein kinase (p42MAPK) and its activator MAPK or ERK kinase (MEK1; involved in transduction of growth and differentiation signals), with c-Jun N-terminal kinase (JNK1) and its activator MEK4 (involved in transduction of stress and death signals) in the adult rat central nervous system. All four kinases were present in the cytoplasm, dendrites, and axons of neurons. The presence of p42MAPK and JNK1 in dendrites and axons, as well as in cell bodies, suggests a role for these kinases in phosphorylation and regulation of cytoplasmic targets. A high degree of correspondence was found between the regional distribution of MEK1 and p42MAPK. Immunostaining for MEK1 and p42MAPK was intense in olfactory structures, neocortex, hippocampus, striatum, midline, and interlaminar thalamic nuclei, hypothalamus, brainstem, Purkinje cells, and spinal cord. In addition to neurons, p42MAPK was also present in oligodendrocytes. Whereas MEK4 was ubiquitously distributed, JNK1 was more selective. Immunostaining for MEK4 and JNK1 was intense in the olfactory bulb, lower cortical layers, the cholinergic basal forebrain, most nuclei of the thalamus, medial habenula, and cranial motor nuclei. The distribution of MEK1 and p42MAPK proteins only partially overlapped with that of MEK4 and JNK1. This suggests that the growth/differentiation and death/stress pathways affected by these kinases may not necessarily act to counterbalance each other in response to extracellular stimuli. The differential distribution of these kinases may control the specificity of neuronal function to extracellular signals.

Cu/Zn SOD deficiency potentiates hearing loss and cochlear pathology in aged 129,CD-1 mice.

Copper/zinc superoxide dismutase (Cu/Zn SOD) is a first-line defense against free radical damage in the cochlea and other tissues. To determine whether deficiencies in Cu/Zn SOD increase age-related hearing loss and cochlear pathology, we collected auditory brainstem responses (ABRs) and determined cochlear hair cell loss in 13-month-old 129/CD-1 mice with (a) no measurable Cu/Zn SOD activity (homozygous knockout mice), (b) 50% reduction of Cu/Zn SOD (heterozygous knockout mice), and (c) normal levels of Cu/Zn SOD (wild-type mice). ABRs were obtained by using 4-, 8-, 16-, and 32-kHz tone bursts. Cochleas were harvested immediately after testing, and separate counts were made of inner and outer hair cells. Compared with wild-type mice, homozygous and heterozygous knockout mice exhibited significant threshold elevations and greater hair cell loss. Phenotypic variability was higher among heterozygous knockout mice than among wild-type or homozygous knockout mice. Separate groups of wild-type and homozygous knockout mice were examined for loss of spiral ganglion cells and eighth nerve fibers. At 13 months of age, both wild-type and knockout mice had significantly fewer nerve fibers than did 2-month-old wild-type mice, with significantly greater loss in aged knockout mice than in aged wild-type mice. Thirteen-month-old knockout mice also had a significant loss of spiral ganglion cells compared with 2-month-old wild-type mice. The results indicate that Cu/Zn SOD deficiencies increase the vulnerability of the cochlea to damage associated with normal aging, presumably through metabolic pathways involving the superoxide radical.

Mice lacking cytosolic copper/zinc superoxide dismutase display a distinctive motor axonopathy.

OBJECTIVE: To characterize the motor neuron dysfunction in two models by performing physiologic and morphometric studies. BACKGROUND: Mutations in the gene encoding cytosolic superoxide dismutase 1 (SOD1) account for 25% of familial ALS (FALS). Transgenes with these mutations produce a pattern of lower motor neuron degeneration similar to that seen in patients with FALS. In contrast, mice lacking SOD1 develop subtle motor symptoms by approximately 6 months of age. METHODS: Physiologic measurements, including motor conduction and motor unit estimation, were analyzed in normal mice, mice bearing the human transgene for FALS (mFALS mice), and knockout mice deficient in SOD1 (SOD1-KO). In addition, morphometric analysis was performed on the spinal cords of SOD1-KO and normal mice. RESULTS: In mFALS mice, the motor unit number in the distal hind limb declined before behavioral abnormalities appeared, and motor unit size increased. Compound motor action potential amplitude and distal motor latency remained normal until later in the disease. In SOD1-KO mice, motor unit numbers were reduced early but declined slowly with age. In contrast with the mFALS mice, SOD1-KO mice demonstrated only a modest increase in motor unit size. Morphometric analysis of the spinal cords from normal and SOD1-KO mice showed no significant differences in the number and size of motor neurons. CONCLUSIONS: The physiologic abnormalities in mFALS mice resemble those in human ALS. SOD1-deficient mice exhibit a qualitatively different pattern of motor unit remodeling that suggests that axonal sprouting and reinnervation of denervated muscle fibers are functionally impaired in the absence of SOD1.

Randomized trial of taurine supplementation for infants less than or equal to 1,300-gram birth weight: effect on auditory brainstem-evoked responses.

Taurine may be important to the developing eye and brain of the small preterm infant. A blinded randomized trial was conducted to determine whether taurine supplementation of healthy infants of less than or equal to 1,300 g birth weight until their discharge from the hospital increases their growth rate, neurobehavioral development, electroretinographic development, or maturation of auditory brainstem-evoked responses. Infants were fed with Similac Special Care as desired, which was prepared to contain less than 5 mg/L of taurine or 45 mg/L of taurine, a concentration similar to that of human milk. Infants who did not receive taurine supplementation (n = 19) and those who did (n = 18) were similar with respect to condition at study entry, caloric intake, and growth rates throughout the study, and electroretinographic findings and scores on the Brazelton Behavioral Assessment Scale at 37 weeks' postmenstrual age. Infants who received taurine supplementation had greater overall plasma taurine concentrations. The group receiving taurine supplementation also had more mature auditory-evoked responses at 37 weeks' postmenstrual age with a modest (0.2 to 0.5 ms) but consistent reduction (P less than .05) in the interval between stimulus and response at two different stimulation rates. Although further study is needed, taurine intake appears to influence auditory system maturation of preterm infants.

Hippocampal plasticity in normal aging and decreased plasticity in Alzheimer's disease.

Different patterns of age-related dendritic change have been reported in different zones of the human hippocampal region in the normal and Alzheimer's disease (AD) brain. In normal aging there is an increase in average (net) dendritic extent (which we interpret as plasticity) in the parahippocampal gyrus and dentate gyrus. There is net stability of dendritic extent in CA2-3, CA1, and subiculum. In regions that show plasticity in normal aging, dendrites in AD show reduced or aberrant plasticity. In regions that show stability in normal aging, dendrites either are stable or regress in AD, depending upon how severely involved the region is with the pathology of AD.

Region-specific stability of dendritic extent in normal human aging and regression in Alzheimer's disease. II. Subiculum.

The dendritic trees of pyramidal neurons of layer III or the external pyramidal layer of the subiculum have been studied in Golgi Cox-stained human tissue obtained at autopsy. Fifteen cases were neurologically and psychiatrically normal and ranged in age from 43 to 95 years; and 5 cases had clinically and neuropathologically defined Alzheimer's disease (AD). Measures of dendritic extent did not change in normal aging in either the apical or basal trees. In AD there was a significant reduction in dendritic extent of the apical trees and a non-significant reduction in extent of the basal trees. These alterations of the dendritic trees in AD are consistent with the findings of severe pathology in the subiculum reported by others. Changes in AD were mainly a reduction in numbers of segments, rather than in the lengths of segments.