[Synaptic plasticity of neocortex of albino rats in diffuse-focal injuries of the brain]

In an experiment conducted using mature albino rats, the regularities of reorganization of synaptic architectonics of cortical layer I of the brain were studied in the areas of diffuse-focal injuries. The models of acute break of systemic circulation (clinical death) as a result of 6-minute-long mechanical asphyxia, compression of common carotid arteries for 20 min (ischemia) and rotatory sublethal injury according to Noble-Collip method (cranial trauma), were used. Using the methods of electron microscopy and morphometric analysis, it was shown that a reduction in a general numerical density of synapses was accompanied by the changes in relative and absolute numbers of major variants of synaptic organization. The content of large simple and perforated contacts was increased, as well as of synapses with invaginated synaptic membranes, containing mitochonria and spine apparatus. The changes detected are considered as a structural basis for realization of the mechanisms of synaptic plasticity in diffuse-focal injuries of the brain.

Microanatomy of the dysplastic neocortex from epileptic patients

Focal cortical dysplasia (FCD) is a pathology that is characterized by the abnormal development of the neocortex. Indeed, a wide range of abnormalities in the cortical mantle have been associated with this pathology, including cytoarchitectonic alterations and the presence of dysmorphic neurons, balloon cells and ectopic neurons in the white matter. FCD is commonly associated with epilepsy, and hence we have studied the ultrastructure of cortical tissue resected from three subjects with intractable epilepsy secondary to cortical dysplasia to identify possible alterations in synaptic circuitry, using correlative light and electron microscopic methods. While the balloon cells found in this tissue do not appear to receive synaptic contacts, the ectopic neurons in the white matter were abnormally large and were surrounded by hypertrophic basket formations immunoreactive for the calcium-binding protein parvalbumin. Furthermore, these basket formations formed symmetrical (inhibitory) synapses with both the somata and the proximal portion of the dendrites of these giant ectopic neurons. A quantitative analysis revealed that in the dysplastic tissue, the density of excitatory and inhibitory synapses was different from that of the normal adjacent cortex. Both increases and decreases in synaptic density were observed, as well as changes in the proportion of excitatory and inhibitory synapses. However, we could not establish a common pattern of changes, either in the same patients or between different patients. These results suggest that cortical dysplasia leads to multiple changes in excitatory and inhibitory synaptic circuits. We discuss the possible relationship between these alterations and epilepsy, bearing in mind the possible limitations that preclude the extrapolation of the results to the whole population of epileptic patients with dysplastic neocortex.

?Dark? (compacted) neurons may not die through the necrotic pathway

"Dark" neurons were produced in the cortex of the rat brain by hypoglycemic convulsions. In the somatodendritic domain of each affected neuron, the ultrastructural elements, except for disturbed mitochondria, were remarkably preserved during the acute stage, but the distances between them were reduced dramatically (ultrastructural compaction). Following a 1-min convulsion period, only a few neurons were involved and their environment appeared undamaged. In contrast, 1-h convulsions affected many neurons and caused swelling of astrocytic processes and neuronal dendrites (excitotoxic neuropil). A proportion of "dark" neurons recovered the normal structure in 2 days. The non-recovering "dark" neurons were removed from the brain cortex through two entirely different pathways. In the case of 1-h convulsions, their organelles swelled, then disintegrated and finally dispersed into the neuropil through large gaps in the plasma membrane (necrotic-like removal). Following a 1-min convulsion period, the non-recovering "dark" neurons fell apart into membrane-bound fragments that retained the compacted interior even after being engulfed by astrocytes or microglial cells (apoptotic-like removal). Consequently, in contrast to what is generally accepted, the "dark" neurons produced by 1-min hypoglycemic convulsions do not die as a consequence of necrosis. As regards the case of 1-h convulsions, it is assumed that a necrotic-like removal process is imposed, by an excitotoxic environment, on "dark" neurons that previously died through a non-necrotic pathway. Apoptotic neurons were produced in the hippocampal dentate gyrus by intraventricularly administered colchicine. After the biochemical processes had been completed and the chromatin condensation in the nucleus had reached an advanced phase, the ultrastructural elements in the somatodendritic cytoplasm of the affected cells became compacted. If present in an apparently undamaged environment such apoptotic neurons were removed from the dentate gyrus through the apoptotic sequence of morphological changes, whereas those present in an impaired environment were removed through a necrotic-like sequence of morphological changes. This suggests that the removal pathway may depend on the environment and not on the death pathway, as also assumed in the case of the "dark" neurons produced by hypoglycemic convulsions.

Rapid deletion of mossy cells does not result in a hyperexcitable dentate gyrus: implications for epileptogenesis

Loss of cells from the hilus of the dentate gyrus is a major histological hallmark of human temporal lobe epilepsy. Hilar mossy cells, in particular, are thought to show dramatic numerical reductions in pathological conditions, and one prominent theory of epileptogenesis is based on the assumption that mossy cell loss directly results in granule cell hyperexcitability. However, whether it is the disappearance of hilar mossy cells from the dentate gyrus circuitry after various insults or the subsequent synaptic-cellular alterations (e.g., reactive axonal sprouting) that lead to dentate hyperexcitability has not been rigorously tested, because of the lack of available techniques to rapidly remove specific classes of nonprincipal cells from neuronal networks. We developed a fast, cell-specific ablation technique that allowed the targeted lesioning of either mossy cells or GABAergic interneurons in horizontal as well as axial (longitudinal) slices of the hippocampus. The results demonstrate that mossy cell deletion consistently decreased the excitability of granule cells to perforant path stimulation both within and outside of the lamella where the mossy cell ablation took place. In contrast, ablation of interneurons caused the expected increase in excitability, and control aspirations of the hilar neuropil or of interneurons in the presence of GABA receptor blockers caused no alteration in granule cell excitability. These data do not support the hypothesis that loss of mossy cells from the dentate hilus after seizures or traumatic brain injury directly results in hyperexcitability.

Slow component of axonal transport is impaired in the proximal axon of transgenic mice with a G93A mutant SOD1 gene

The purpose of this study was to determine whether slow axonal transport of neurofilaments (NFs) is impaired in the spinal cord of G93A Cu/Zn superoxide dismutase (SOD1) mutant transgenic mice expressing a relatively low mutant protein (gene copy 10) and, if so, how the impairment occurs in this animal model. Transgenic mice were killed at the ages of 24, 28 and 32 weeks, and the cervical and lumbar spinal cords were examined under an electron microscope. Age-matched non-transgenic wild-type mice served as controls. At 24 weeks (early presymptomatic stage), anterior horn cells were well preserved. The earliest morphological changes were mild vacuolar changes in the neuronal processes, particularly in proximal axons. At 28 weeks (late presymptomatic stage), mild neuronal loss of anterior horn neurons was observed. Vacuolar changes were more prominent in the proximal axons, including swollen axons (spheroids) and neuropils of the anterior horns. Vacuoles in the axons were frequently large enough to occupy almost the entire axonal caliber. The anterior roots were degenerative, showing vacuolar changes and myelin ovoids. Lewy body-like inclusions (LIs) consisting of filaments thicker than NFs (about 1.5 times larger in diameter) were frequently demonstrated in the neuronal processes including swollen axons (spheroids) and occasionally in the somata. At 32 weeks (symptomatic stage), the anterior horns showed a moderate to severe neuronal loss accompanied by prominent astrogliosis. Cord-like swollen axons consisting of accumulated NFs and many neurofilamentous accumulations were frequently observed in the anterior horn. Vacuolar changes were less prominent or disappeared in the neuropils of the anterior horns and the anterior roots, whereas LIs were frequently demonstrated within the neuronal processes including the cord-like swollen axons. In the anterior roots, degenerative changes such as marked fiber loss and frequent myelin ovoids were remarkable. No accumulation of NFs or mitochondrial vacuolation was detected in somata or proximal dendrites at any stage. These findings suggest that the slow component of axonal transport in the proximal axons is impaired at an early stage in this transgenic mouse model, and that the impairment is probably caused by a mechanical impediment of NFs, or by the accumulation of NFs in the proximal axon, as a result of the obstruction of the axonal flow that initially occurs by vacuolar changes, and is later exacerbated by accumulation of LIs.

Acute ethanol intoxication in a model of traumatic brain injury: the protective role of moderate doses demonstrated by immunoreactivity of synaptophysin in hippocampal neurons

Although ethanol intoxication is reported to be a complicating factor in traumatic brain injury, some recent studies are indicating its possible protective role especially at lower doses. Ethanol inhibition of NMDA-mediated excitotoxicity which predominates at lower doses is believed to be responsible for this protection. The aim of this study was to demonstrate this neuroprotective role of alcohol using immunoreactivity for synaptophysin as an indirect marker for severity of injury. Acute ethanol intoxication at moderate doses was performed 2 h prior to trauma. Severe traumatic brain injury was administrated using an impact acceleration model in Sprague-Dawley rats. At post-traumatic 48th hour, immunorectivity for synapthophysin in the rat hippocampi was evaluated under light microscopy. According to our results there were slight increases in immunoreactivity for synaptophysin in the stratum oriens and striatum radiatum of CA1 subfield of hippocampus when ethanol was administered prior to trauma comparing to moderate increase in the trauma-only group. On the other hand vacuolar degeneration and red neuron formation was more prominent in the pyramidal cell layer of CA1 and CA3 when ethanol was not administered. Ethanol may have a neuroprotective role when administered at moderate doses prior to traumatic brain injury. This effect of ethanol may primarily be due to inhibition of NMDA receptors.

Cytodiagnosis of central neurocytoma in intraoperative preparations

OBJECTIVE

To assess the cytologic features in smear preparations of 3 central neurocytomas.

STUDY DESIGN

Three patients with central neurocytoma underwent intraoperative frozen section diagnoses, and the cytologic evaluations are presented.

RESULTS

The smears typically showed cellular tumors composed of isomorphous, round cells. The tumor cells showed ill-defined cytoplasm oval nuclei with finely granular chromatin and micronucleoli. A fibrillary matrix in the background was noted in all cases. The tumor in the 20-year-old patient exhibited numerous giant cells with phyagocytosed hemosiderin granules between small, round tumor cells. Permanent sections, immunohistochemistry and electron microscopy confirmed that all cases were central neurocytomas.

CONCLUSION

Central neurocytomas can be diagnosed reliably using combined cytologic preparations and frozen sections. The appearance of numerous macrophages that phagocytose hemosiderin between neoplastic cells should also be considered characteristic of the cytomorphology of central neurocytomas.

Neuropil and neuronal changes in hippocampal NADPH-diaphorase histochemistry in the ME7 model of murine prion disease

Nitric oxide (NO) has been implicated in neurotoxicity and cerebral blood flow changes in chronic neurodegeneration, but its activity in the mammalian prion diseases has not been studied in detail. Nicotine adenine dinucleotide phosphate (NADPH)-diaphorase (NADPH-d) histochemistry is a simple and robust histochemical procedure that allows localization of the tissue distribution of NO synthases. The aim of the present study is to assess whether NADPH-d histochemical activity is altered in the hippocampus in the ME7 model of prion disease in C57BL/6J mice. At early and late stages after the initiation of the disease we assessed features of the NADPH-d positive cells and the neuropil histochemical activity in CA1 and dentate gyrus using densitometric analysis. In C57BL/6J mice 13 weeks postinjection of the prion agent ME7, when behavioural changes first become apparent, neuropil NADPH-d histochemical staining increases, whereas at late stages it decreases dramatically. Both type I and type II NADPH-d positive cells were found to survive throughout the hippocampal formation into the late stages of the disease, but diaphorase activity was reduced in dendritic branches and abnormal varicosities were present in both dendritic and axonal processes of NADPH-d positive type I cells. The pathophysiological implications of the results remain to be investigated but both blood flow alteration and NO neurotoxicity may be features of the disease.

Microtubule-associated tau protein positive neuronal and glial inclusions in ALS

BACKGROUND

The authors compared tau protein deposition in the frontal cortex of patients with cognitive impairment of amyotrophic lateral sclerosis (ALSci) (n = 6), cognitively intact patients with ALS (n = 6), and age-matched controls (n = 6) in order to determine the pathologic substrate of ALSci.

METHODS

Archival paraffin-embedded tissue was examined using Gallyas staining and immunostaining for tau-1 (phosphorylation-dependent tau epitope), tau-2 (phosphorylation independent), Alzheimer-specific tau phosphoepitopes (AT 8; ser(396) phosphorylation), beta-amyloid, glial fibrillary acid protein, SMI 31 (recognizing phosphorylated NFH), alpha-synuclein, or ubiquitin.

RESULTS

Tau immunoreactive astrocytic and dense neuronal inclusions were found in both ALS and ALSci, although to a greater extent in ALSci. Superficial linear spongiosis and Gallyas-positive intraneuronal aggregates, immunoreactive with tau-1 and AT 8 but rarely to ser(396) tau, were unique to ALSci. Dense extracellular aggregates were observed by both Gallyas staining and tau-1 immunostaining. Tufted degenerating astrocytes containing tau-1 and AT 8 immunoreactive aggregates and, rarely, dense Gallyas positive neuritic plaques immunoreactive with tau-1 and AT 8, but not with ser(396) tau or beta-amyloid, were observed in ALSci. Tau positive glial coiled bodies were observed in the deep cortical layers and adjacent subcortical white matter in ALSci. Although 3R and 4R tau mRNA isoforms were expressed to similar levels in the frontal cortex of all cases, the total amount of tau mRNA was increased in both ALS and ALSci. Both gray and white matter soluble tau protein expression was similar among control, ALS, and ALSci cases.

CONCLUSIONS

Cognitive dysfunction in ALS may reflect abnormal tau protein metabolism.

Structural involvement of the glutamatergic presynaptic boutons in a transgenic mouse model expressing early onset amyloid pathology

While the cholinergic depletion in Alzheimer's disease (AD) has been known for some time, a definitive involvement of other neurotransmitter systems has been somewhat more elusive. Our study demonstrates a clear involvement of both glutamatergic and, to a lesser extent, GABAergic neurons in an early onset transgenic mouse model of AD-like amyloid pathology. Immunohistochemical staining and subsequent quantification has revealed a statistically significant increased density of glutamatergic and GABAergic presynaptic boutons in both the plaque free and plaque adjacent cortical neuropile areas of transgenic mice as compared to non-transgenic controls. Furthermore, amyloid plaque size was shown to have a statistically significant effect on the relative area occupied by dystrophic glutamatergic neurites in the peri-plaque neuropile. These findings support our hypothesis that the amyloid pathology progresses in a time and neurotransmitter specific manner, first in the cholinergic system which appears to be most vulnerable, followed by the glutamatergic presynaptic boutons and finally the somewhat more resilient GABAergic terminals.

Neuropathology of cognitively normal elderly

Despite general agreement about the boundaries of Alzheimer disease (AD), establishing a maximum limit for Alzheimer-type pathology in cognitively intact individuals might aid in defining more precisely the point at which Alzheimer pathology becomes clinically relevant. In this study, we examined the neuropathological changes in the brains of 39 longitudinally followed. cognitively normal elderly individuals (24 women, 15 men; age range 74-95, median 85 years). Neuropathological changes of the Alzheimer type were quantified by determining neurofibrillary tangle (NFT) staging by the method of Braak and Braak and by quantification of the abundance of diffuse, cored, and neuritic plaque burden using the scheme developed by the Consortium to Establish a Registry for Alzheimer Disease (CERAD). Vascular, Lewy body, and argyrophilic grain pathology were also assessed. We found 34 subjects (87%) with a Braak stage <IV; 32 subjects (82%) with less than moderate numbers of cored plaques and 37 subjects (95%) with less than moderate numbers of tau-positive neuritic plaques. Many subjects had moderate or frequent diffuse plaques (n = 19, 49%). By the National Institute on Aging-Reagan Institute (NIA-RI) criteria, none of our cases met criteria for high "likelihood" of AD. Four met NIA-RI criteria for intermediate "likelihood." Seven cases met CERAD criteria for possible AD. Nineteen met Khachaturian criteria for AD. Only 1 subject had neocortical Lewy bodies. Small, old infarcts were common, but no subjects had more than 2 of these and none had a single large infarction. Thus, the majority of individuals who are cognitively normal near the time of their death have minimal amounts of tau-positive neuritic pathology (Braak stage <IV and neuritic plaques <6 per x100 field in the most affected neocortical region). The few subjects with more severe AD pathology can be expected based on incidence rates of AD in the very elderly.

Atypical late-onset dementia characterized by limbic degeneration with coiled bodies and argyrophilic threads

This report concerns an autopsy case of late-onset dementia with atypical neuropathological features. The patient was a Japanese man who was 83 years old at the age of death. At 73 years, he developed behavioral disorders, including emotional changes, and dementia. He died at the age of 83. A neuropathological study revealed largely confined involvement of the limbic regions, characterized by degeneration consisting of neuronal loss with a spongy state and gliosis. Massive tau-positive oligodendroglial coiled bodies and argyrophilic threads were also observed mainly in these regions. Although the clinicopathological findings of the present case showed some similarities to those of a unique subtype of frontotemporal dementia, including mesolimbocortical dementia, argyrophilic grain disease, corticobasal degeneration and dementia with tangles, there seems to be no suitable category of neurodegenerative disease into which our case can be classified. Further study is needed to determine whether the present case could be classified as an atypical case of these diseases or represents a new entity.

Time course of early motor and neuropathological anomalies in a knock-in mouse model of Huntington's disease with 140 CAG repeats

Huntington's disease (HD) is caused by an abnormal expansion of CAG repeats in the gene encoding huntingtin. The development of therapies for HD requires preclinical testing of drugs in animal models that reproduce the dysfunction and regionally specific pathology observed in HD. We have developed a new knock-in mouse model of HD with a chimeric mouse/human exon 1 containing 140 CAG repeats inserted in the murine huntingtin gene. These mice displayed an increased locomotor activity and rearing at 1 month of age, followed by hypoactivity at 4 months and gait anomalies at 1 year. Behavioral symptoms preceded neuropathological anomalies, which became intense and widespread only at 4 months of age. These consisted of nuclear staining for huntingtin and huntingtin-containing nuclear and neuropil aggregates that first appeared in the striatum, nucleus accumbens, and olfactory tubercle. Interestingly, regions with early pathology all receive dense dopaminergic inputs, supporting accumulating evidence for a role of dopamine in HD pathology. Nuclear staining and aggregates predominated in striatum and layer II/III and deep layer V of the cerebral cortex, whereas neuropil aggregates were found in the globus pallidus and layer IV/superficial layer V of the cerebral cortex. The olfactory system displayed early and marked aggregate accumulation, which may be relevant to the early deficit in odor discrimination observed in patients with HD. Because of their early behavioral anomalies and regionally specific pathology, these mice provide a powerful tool with which to evaluate the effectiveness of new therapies and to study the mechanisms involved in the neuropathology of HD.

Acetylcholinesterase level and molecular isoforms are altered in brain of Reelin Orleans mutant mice

In this study we examined changes in acetylcholinesterase (AChE) pattern in the brain of adult Reelin Orleans (RelnOrl) homozygous mutant mice. The AChE histochemistry firstly revealed an abnormal distribution of AChE-positive cells in several areas of the reeler brain, including cortices; the strongest labelling was observed in cerebellum and hippocampus when compared with controls. Biochemical determinations demonstrated an increase of 80-90% in AChE specific activity from cerebellar and hippocampal extracts. We also report that the AChE tetrameric form (G4) was selectively increased in the RelnOrl brain. The relationship between AChE and Reelin and suggested morphogenetic functions are also discussed.

Measuring the mechanical stress induced by an expanding multicellular tumor system: a case study

Rapid volumetric growth and extensive invasion into brain parenchyma are hallmarks of malignant neuroepithelial tumors in vivo. Little is known, however, about the mechanical impact of the growing brain tumor on its microenvironment. To better understand the environmental mechanical response, we used multiparticle tracking methods to probe the environment of a dynamically expanding, multicellular brain tumor spheroid that grew for 6 days in a three-dimensional Matrigel-based in vitro assay containing 1.0-microm latex beads. These beads act as reference markers for the gel, allowing us to image the spatial displacement of the tumor environment using high-resolution time-lapse video microscopy. The results show that the volumetrically expanding tumor spheroid pushes the gel outward and that this tumor-generated pressure propagates to a distance greater than the initial radius of the tumor spheroid. Intriguingly, beads near the tips of invasive cells are displaced inward, toward the advancing invasive cells. Furthermore, this localized cell traction correlates with a marked increase in total invasion area over the observation period. This case study presents evidence that an expanding microscopic tumor system exerts both significant mechanical pressure and significant traction on its microenvironment.

Automated image analysis of disturbed cytoarchitecture in Brodmann area 10 in schizophrenia

To detect cytoarchitectonic abnormalities in the Brodmann area 10 (BA10) of schizophrenic patients, we applied a newly modified variant of the gray-level index (GLI) method as fully automated image analysis method providing cytoarchitectonic profiles of the whole cortex as a scanning tool. Microscopic images of silver-stained sections of 20 schizophrenic brains compared to 20 control brains were automatically scanned and binarized at an adaptive threshold. In 30 measuring fields through the whole cortical depth, the dependent measure of gray-level index (GLI) as the area-percentage covered by perikarya in a measuring field was obtained providing a cytoarchitectonic profile. GLI is an estimate of the volume density of perikarya. A statistical analysis of mean GLI values was performed for six compartments, separately, approximately corresponding to cortical layers. Results revealed significant GLI reductions in schizophrenic brains in all six compartments suggesting either a decreased perikarya fraction or an increased neuropil fraction. The described automated image analysis method providing cytoarchitectonic profiles can be applied as a fast and observer-independent scanning tool to detect cytoarchitectonic abnormalities in multiple brain regions.

[The importance of interneurons in schizophrenic and affective disorders]

In brains of patients with schizophrenic and affective disorders pathomorphological changes have been shown focussing in frontal and temporal cortex. The volume reduction in prefrontal cortex of schizophrenic patients is hypothesized to be based on a reduction of neuropil. A decrease of synaptic proteins and a decrease of dendritic spines of pyramidal cells can additionally be the origin of disconnections of neurons. Affection of the glutamatergic, GABA-ergic and dopaminergic system and reduction of interneurons could be the correlate of a deficient neuronal network which might be combined with exogen factors generate psychotic symptoms. Reelin and associated proteins are candidate molecules. Their dysregulation might explain essential features of the dysfunctional network of schizophrenia.

Sub-cellular pathology of scrapie: coated pits are increased in PrP codon 136 alanine homozygous scrapie-affected sheep

Sub-cellular studies of transmissible spongiform encephalopathies (TSEs) have been carried out on several animal species and human beings. However, studies of optimal perfusion-fixed tissues have largely been confined to examination of rodents. Using a recently developed technique, heads of scrapie-affected sheep and controls were perfusion fixed with mixed aldehydes. The obexes were immunohistochemically labelled with PrP antibodies, and the dorsal motor nucleus of the vagal nerve was examined by electron microscopy. Irregular neuritic profiles with highly invaginated membranes, associated with coated pits were found in all scrapie-affected sheep, but not in controls. Interestingly, they were consistently more frequent in the homozygous A(136) sheep. This is the first report describing sub-cellular differences in pathology associated with different PrP genotypes. Rarely, amorphous material, or sparse fibrillar structures, were present in the extracellular space. The changes were often associated with irregular plasmalemma and frequent coated pits. Vacuolation typical of TSEs, dystrophic neurites and variable gliosis were present. Herniation of membranes and organelles from apparently healthy processes into adjacent vacuoles and dendrites was also observed. We suggest that the increase in coated pits and plasmalemma invagination is related to an attempted internalisation of aggregated disease-specific PrP, or protofilaments, from the extracellular space.

Does schizophrenia result from developmental or degenerative processes?

The debate as to whether schizophrenia is a neurodevelopmental or a neurodegenerative disorder has its roots in the latter part of the 19th century when authorities such as Clouston (1891) posited that at least some insanities were "developmental" in origin. These views were soon eclipsed by Kraepelin's (1896) concept of dementia praecox as a degenerative disease, and the latter view carried not only the day but also much of the 20th century. Then, in the 1980s several research groups again began to speculate that schizophrenia might have a significant developmental component (Feinberg, 1982-1983; Schulsinger et al., 1984; Murray et al., 1985; Murray and Lewis, 1987; Weinberger et al., 1987). What became known as the "neurodevelopmental hypothesis" received support from neuropathological studies implicating anomalies in early brain development such as aberrant migration of neurons. Unfortunately, these studies proved difficult, if not impossible, to replicate (Harrison, 1999). The pendulum, therefore, began to swing again, and in the latter part of the 1990s came renewed claims that the clinical progression of the illness was accompanied by continued cerebral ventricular enlargement and reduction in the volumes of certain brain structures. Nevertheless, since few doubt that there is a developmental component to schizophrenia, the question which we will address in this paper is whether schizophrenia is a) simply the final consequence of a cascade of increasing developmental deviance (Bramon et al., 2001), or b) whether there is an additional brain degeneration following onset of psychosis which is superimposed on the developmental impairment (Lieberman, 1999).

Deformation of network connectivity in the inferior olive of connexin 36-deficient mice is compensated by morphological and electrophysiological changes at the single neuron level

Compensatory mechanisms after genetic manipulations have been documented extensively for the nervous system. In many cases, these mechanisms involve genetic regulation at the transcription or expression level of existing isoforms. We report a novel mechanism by which single neurons compensate for changes in network connectivity by retuning their intrinsic electrical properties. We demonstrate this mechanism in the inferior olive, in which widespread electrical coupling is mediated by abundant gap junctions formed by connexin 36 (Cx36). It has been shown in various mammals that this electrical coupling supports the generation of subthreshold oscillations, but recent work revealed that rhythmic activity is sustained in knock-outs of Cx36. Thus, these results raise the question of whether the olivary oscillations in Cx36 knock-outs simply reflect the status of wild-type neurons without gap junctions or the outcome of compensatory mechanisms. Here, we demonstrate that the absence of Cx36 results in thicker dendrites with gap-junction-like structures with an abnormally wide interneuronal gap that prevents electrotonic coupling. The mutant olivary neurons show unusual voltage-dependent oscillations and an increased excitability that is attributable to a combined decrease in leak conductance and an increase in voltage-dependent calcium conductance. Using dynamic-clamp techniques, we demonstrated that these changes are sufficient to transform a wild-type neuron into a knock-out-like neuron. We conclude that the absence of Cx36 in the inferior olive is not compensated by the formation of other gap-junction channels but instead by changes in the cytological and electroresponsive properties of its neurons, such that the capability to produce rhythmic activity is maintained.

Immune reactive cells in senile plaques and cognitive decline in Alzheimer's disease

We examined the associations of postmortem neocortical immunoreactivities for microglia, astrocytes, Abeta and Tau with cognitive changes in clinically characterized subjects with pathological diagnoses (CERAD classification) of definite AD (9), possible AD (15) and age-matched controls (11). By measuring the fractional area (FA) of immunoreactivity, we found that Abeta deposits appear early in the pathogenesis of Abeta, but cannot account for cognitive decline. We found a significant increases in FA for microglia in possible AD cases (nondemented) compared to controls (P<0.05) and in FA for astrocytes in definite AD (demented) compared to possible AD (P<0.01). Tau immunoreactivity was observed only in the neuropil of definite AD cases (P<0.001). The significant increase in microglia between controls and AD possible cases suggests that activation of microglia occurs in the early pathogenesis of AD, whereas the significant association between astrocytic reaction and dementia, suggests that these cells play a role in the late stage of the disease, when dementia develops. Tau immunoreactivity appears as the strongest morphological correlate of dementia.

Changes in mouse barrel synapses consequent to sensory deprivation from birth

Neonatal sensory deprivation induced by whisker trimming affects significantly the functional organization of receptive fields in adult barrel cortex. In this study, the effects of deprivation on thalamocortical synapses and on asymmetrical and symmetrical synapses not of thalamic origin were examined. Thalamocortical synapses were labeled by lesion-induced degeneration in adult (postnatal day 60) mice subjected to whisker trimming from birth, other synaptic types were unlabeled. Brains were processed for electron microscopy, and numerical densities of synapses were evaluated by using stereologic approaches for whisker trimmed vs. control animals. Results demonstrated no change in nonthalamic, asymmetrical synapses; however, a decrease of 52% in the numerical density of symmetrical synapses (46.3 vs. 88.5 million per mm(3); Z = -2.121; P < 0.05) and a decrease of 43% in the numerical density of thalamocortical synapses (57.5 vs. 102.33 million per mm(3); Z = -2.121; P < 0.05) were observed after deprivation. Thus, experience-dependent plasticity of receptive fields in barrel cortex involves directly axons of both extrinsic and intracortical origin. The proportion of thalamocortical axospinous to axodendritic synapses was the same in control vs. deprived animals: in each instance, 80% of the synapses were axospinous (Z = 0.85; P = 0.2). These results suggest that neither excitatory neurons, whose thalamocortical synapses are primarily axospinous, nor inhibitory neurons, whose thalamocortical synapses are mainly axodendritic (White [1989] Cortical Circuits. Synaptic Organization of the Cerebral Cortex; Structure, Function, and Theory. 1989; Boston: Birkhauser), are affected preferentially by the deprivation-associated decrease in thalamocortical synapses.

In vivo multiphoton imaging of a transgenic mouse model of Alzheimer disease reveals marked thioflavine-S-associated alterations in neurite trajectories

Postmortem analyses of senile plaques reveal numerous dystrophic processes in their vicinity. We used in vivo multiphoton microscopy of a transgenic model of Alzheimer disease (AD) to simultaneously image senile plaques and nearby neuronal processes. Plaques were labeled by immunofluorescent staining or thioflavine-S and neuronal processes were labeled with a fluorescent dextran conjugate. Imaging of 3-dimensional volumes in the vicinity of plaques revealed subtle changes in neurite geometry in or near diffuse plaques. By contrast, disruptions in neurite morphology, including dystrophic neurites immediately surrounding plaques as well as major alterations in neurite trajectories, were seen in association with thioflavine-S-positive plaques. Nearly half of all labeled processes that came within 50 microm of a thioflavine-S-positive plaque were altered, suggesting a fairly large "halo" of neuropil alterations that extend beyond the discrete border of a thioflavine-S plaque. These results support the hypothesis that compact thioflavine-S-positive plaques disrupt the neuropil in AD.

Early olfactory involvement in Alzheimer's disease

BACKGROUND

In Alzheimer's disease (AD) the olfactory system, including the olfactory bulb, a limbic paleocortex is severely damaged. The occurrence of early olfactory deficits and the presence of senile plaques and neurofibrillary tangles in olfactory bulb were reported previously by a few authors. The goal of the present study was to analyze the occurrence of AD-type degenerative changes in the peripheral part of the olfactory system and to answer the question whether the frequency and severity of changes in the olfactory bulb and tract are associated with those of the cerebral cortex in AD.

MATERIAL AND METHODS

In 110 autopsy cases several cortical areas and the olfactory bulb and tract were analyzed using histo- and immunohistochemical techniques. Based on a semiquantitative analysis of cortical senile plaques, neurofibrillary tangles and curly fibers, the 110 cases were divided into four groups: 19 cases with severe (definite AD), 14 cases with moderate, 58 cases with discrete and 19 control cases without AD-type cortical changes.

RESULTS

The number of cases with olfactory involvement was very high, more than 84% in the three groups with cortical AD-type lesions. Degenerative olfactory changes were present in all 19 definite AD cases, and in two of the 19 controls. The statistical analysis showed a significant association between the peripheral olfactory and cortical degenerative changes with respect to their frequency and severity (P < 0.001). Neurofibrillary tangles and neuropil threads appear in the olfactory system as early as in entorhinal cortex.

CONCLUSION

The results indicate a close relationship between the olfactory and cortical degenerative changes and indicate that the involvement of the olfactory bulb and tract is one of the earliest events in the degenerative process of the central nervous system in AD.