Elda Scherini

Regional alterations of the NO/NOS system in the aging brain: a biochemical, histochemical and immunochemical study in the rat

We have used several approaches (immunohistochemistry and enzyme histochemistry, Western blotting, biochemical assay of Ca(2+)-dependent catalytic activity) in order to detect differences in neuronal nitric oxide synthase (nNOS) expression and activity in various brain regions of young-adult (4-month-old) and aged (28-month-old) rats. In most of the brain regions examined (striatum, neocortex, olfactory cortex and hippocampus) some significant decrease in the density per unit area of nNOS neurons, detected either through immunohistochemistry or enzyme histochemistry, was observed in aged rats. However, only in the striatum and olfactory cortex this was accompanied by a significant decrease of the catalytic activity of the constitutive, Ca(2+)-dependent NOS form. In these two regions, the relative level of expression of nNOS protein was also significantly decreased, as assessed by Western blotting of proteic extracts from young-adult and aged rats. Other observed differences were a paler stain of neurons in some brain areas of the aged rats and differences of cellular compartmentalization of the protein in the same rats, as assessed through confocal microscopy. The present observations demonstrate that the expression and activity of nNOS show regionally-specific alterations in the brain of aged healthy rats, with a trend towards decrease, rather than toward increase as suggested by some previous reports. Therefore, hypotheses implicating nitric oxide increase in brain aging should be reconsidered on the basis of a clear-cut distinction between the physiological and the pathological aspects of the aging process.

Bioactive peptides and serotonin immunocytochemistry in the cerebral ganglia of hibernating Helix aspersa

The role of some neuromodulators and neurotransmitters in the functioning of molluskan cerebral neurons and in their metabolic changes during hibernation has been considered. The cerebral ganglion of mollusks is a center for the integration of different inputs from the sensory areas of the head and for the generation of motor command impulses. During hibernation, animals are deprived of many external sensory stimuli and do not have locomotion and feeding. Immunocytochemistry for bioactive peptides (BAPs), such as SP (Substance P), CCK8 (Cholecystokinin 8/Gastrin), CGRP (Calcitonin-Gene-Related Peptide) and ET (Endothelin), and serotonin was performed on cerebral ganglia of active and hibernating Helix aspersa. The distribution of the immunopositivity was analyzed in different cell-containing areas (procerebrum, mesocerebrum, metacerebrum) and in the neuropiles. With all the antibodies raised against peptides, we observed that only a few neurons, mainly of small and medium size, had immunopositivity during the period of activity, the patterns of distribution being quite similar to those previously described in Helix or other gastropods. Fibers and varicosities with BAP immunopositivity were found in the procerebral and central neuropiles and sometimes around neurons. Serotonin-immunopositive neurons, including the giant neuron, were observed in the metacerebrum; numerous fibers and varicosities immunopositive for serotonin were present in the neuropile areas. In hibernating snails, the number of fibers with BAP and serotonin immunopositivity decreased in several areas of the neuropiles. Moreover, an increased number of neurons of the metacerebrum (two-to four-fold) and mesocerebrum (8- to 28-fold) had BAP-like immunopositivity, and the intensity of the immunoreaction for serotonin of the metacerebral neurons was also higher than in the active snails. These results are discussed, taking into account two hypotheses. The first hypothesis assumes that the increased immunocytochemical staining was really linked to accumulation of BAPs and serotonin. The second hypothesis considers that the antibodies for BAPs recognized a preprotein, the synthesis of BAPs being completed during the active period only. Both the hypotheses account for the co-occurrence and co-localization of two or ore peptides and serotonin and stress that the hibernation condition is of interest for studies on the actual function of single neurons in the cerebral ganglia. Finally, the data are consistent with the changes recently found in other markers of the morphological and functional activity of neurons, demonstrating that the neuromodulation and the neurotransmission are slowed during hibernation.

cisDDP treatment and development of the rat cerebellum.

CONTENTS Abbreviations 161

Nitric oxide‐containing neurons in the nervous ganglia of Helix aspersa during rest and activity: Immunocytochemical and enzyme histochemical detection

Nitric oxide synthase (NOS) immunoreactivity and staining for nicotinamide adenine dinucleotide phosphate‐diaphorase (NADPH‐diaphorase) activity are two cytochemical markers for nitric oxide (NO)‐containing neurons. The authors examined the changes in the distribution of NOS immunolabeling and NADPH‐diaphorase reactivity in the cerebral and buccal ganglia of the terrestrial snail Helix aspersa during resting and active phases. During inactivity and after 1 day of activity, in the mesocerebrum and metacerebrum of the snails, there were several reactive neurons for both markers; after 7 days of activity, the number of reactive neurons was lower. Opposite results were obtained in the buccal ganglia, in which increased staining and numbers of reactive neurons were present in the active snails (after 1 day and 7 days of activity). Although the staining patterns for the two reactions were similar, colocalization was not always observed. The comparison between inactive and active animals provided a more precise survey of NOS‐containing neurons in the snail cerebral ganglia than previously described. Moreover, it suggested that not only is NO involved in distinct nervous circuits, but, as a ubiquitous molecule, it also plays a role in neuroprotection and neuropeptide release. J. Comp. Neurol. 409:274–284, 1999.

Axonal abnormalities in cerebellar Purkinje cells of the Ts65Dn mouse

Ts65Dn mice are a genetic model for Down syndrome. Among others, these mice have cerebellar pathology features which parallel those seen in Down syndrome patients. Both individuals with Down syndrome and Ts65Dn mice have reduced cerebellar volume and numbers of granule and Purkinje cells. In this report, we describe morphological abnormalities of axons of Purkinje cells in the cerebellum of Ts65Dn mice, by using anti-calbindin immunocytochemistry. A consistent number of Purkinje cells shows axons bearing giant varicosities along their transit through the granular layer. The cerebellar arbor vitae made by fasciculated Purkinje cell axons has a patchy appearance, some tracks being devoid of calbindin staining. The infraganglionic plexus, formed by recurrent collaterals of Purkinje cell axons, has enormously increased density, which is evidence for a compensatory reaction to degeneration of distal segments of axons. These alterations are accompanied by strong glial reaction as evidenced by GFAP immunocytochemistry. Moreover, the alterations are more consistent in the anterior lobules of the vermis and intermediate cortex. The axonal pathology of Purkinje cells may explain the impairment in cerebellar functions observed in Ts65Dn mice at the adulthood.

Distribution of calretinin-like immunoreactivity in the brain of Rana esculenta.

The distribution of calretinin-like immunoreactivity has been analyzed in the brain of Rana esculenta. Several neurons of nuclei belonging to sensory pathways, subhabenular area and left habenula were immunopositive. Immunoreactivity was present in fibers of motor and sensory pathways, thalamus, tegmentum and isthmus. The immunolabeling pattern partially overlapped that previously described in the rat. However, in comparison with the rat, fewer cells and fibers were immunoreactive and there were less positive brain nuclei. especially in the pallium, septum and striatum, that were totally negative. Taking into consideration that these regions are rather simple in the frog, the presence of calretinin seems to be consistent with the degree of complexity of brain areas and segregation of different nuclei.

Increase of the ornithine decarboxylase/polyamine system and transglutaminase upregulation in the spinal cord of aged rats.

We have investigated changes in ornithine decarboxylase (ODC) activity and in polyamine levels in the central nervous system of aged rats. We measured a significant increase of ODC catalytic activity in the spinal cord from 30 month-old rats (+105%) as compared to 4 month-old rats. No changes were noticed in the cerebellum, cortex and hippocampus from the same animals. A related putrescine increase was measured in the spinal cord of 30 month-old rats (+168%), together with a smaller increase of spermidine (+33%). A parallel increase (+78%) of the Ca2+-dependent transglutaminase activity was detected in the spinal cord of 30 month-old rats, while no changes were apparent in the cortex and cerebellum. Our observations indicate a possible role of the ODC/polyamine system during the normal process of ageing in rats and point to the spinal cord as the most sensitive area for this kind of modification. A possible role of protein polyamination by transglutaminase is discussed.

The cerebral neurons of Helix aspersa during hibernation. Changes in the cytochemical detection of calmodulin, cytoskeletal components and phosphatases.

Some markers of the intracellular systems that regulate neuronal activity and morphology were analyzed in the cerebral ganglion of hibernating snails (Helix aspersa), in comparison with active animals. The immunocytochemical expression of a calcium-binding protein, i.e. calmodulin, and some cytoskeletal components, i.e. 200 kDa phosphorylated neurofilament protein (pNFH), microtubule associated protein 2 (MAP2) and alpha-tubulin were analyzed by the use of a panel of antibodies raised against mammal antigens. Moreover, by enzymatic reactions the Ca(2+)-ATPase and alkaline phosphatase (AIPase) activities were demonstrated. In comparison with the active phase, the hibernation induced an increase in the immunopositivity for calmodulin in all the neurons. The increase may be linked to unmasking of immunoreactive epitopes due to conformational changes of the protein, which in turn may be a consequence of a reduction or absence of binding with calcium ions or of a real increase in the amount of calmodulin in the somata of neurons. In any event, both the hypotheses indicate that neurons have decreased or suppressed the Ca(2+)-dependent mechanisms as also shown by the lower Ca(2+)-ATPase activity. Nevertheless, the AIPase activity, which was localized in the epineural sheat, was not significantly changed during hibernation and this supports that some metabolic activities are preserved in the hibernated animals. Changes in the immunopositivity for cytoskeletal components were found. There was an increase in the epitopes recognized by the mammalian pNF antibody, that concerned both the positivity of the entire cytoplasm of some clusters of metacerebral neurons and the intensity of the reaction. This would be aimed to improve the stability of the somata and primary neurites. Moreover, the decrease of alpha-tubulin and MAP2 immunopositivity, suggests that a disassembly of microtubules have occurred. The findings indicate that the transport of vesicles in the axons is slowed down during hibernation. In fact, research in progress show that the patterns of neurotransmission and neuromodulation are also deeply modified.

Cytochemical study of chromatin changes in Purkinje cell population as markers of rat cerebellar histogenesis

In the population of rat cerebellum Purkinje cells, Feulgen-DNA contents higher than 2c are present starting from the 9th to the 12th day of postnatal life. This stage of histogenesis corresponds to the time when other histological and cytochemical parameters suggest that important functional changes are taking place in the cerebellum. Hyperdiploid values (H2c) gradually increase during the subsequent histogenesis, involving also the physico-chemical state of chromatin. The key steps of histogenesis suggested by our investigations might be a starting point of reexamine the problem of tritiated thimidine incorporation, in order to demonstrate the possible synthesis of extra-DNA.

Cerebellar Amyloid-β Plaques: Disturbed Cortical Circuitry in AβPP/PS1 Transgenic Mice as a Model of Familial Alzheimer's Disease

Cerebellar amyloid-β (Aβ) deposition in the form of neuritic plaques and Purkinje cell loss are common in certain pedigrees of familial Alzheimers disease (FAD) mainly linked to PS1 mutations. AβPP/PS1 transgenic mice, here used as a model of FAD, show a few Aβ plaques in the molecular layer of the cerebellum at 6 months, and which increase in number with age. Motor impairment is apparent in transgenic mice aged 12 months. Combined methods have shown degenerated parallel fibers as the main component of dystrophic neurites of Aβ plaques, loss of synaptic contacts between parallel fibers and dendritic spines of Purkinje cells, and degeneration of granule cells starting at 12 months and increasing in mice 18/20 months old. In addition, abnormal mitochondria and focal loss of Purkinje and basket cells, together with occasional axonal torpedoes and increased collaterals of Purkinje cells in mice aged 18/20 months, is suggested to be a concomitant defect presumably related to soluble extracellular or intracellular Aβ. These observations demonstrate serious deterioration of the neuronal circuitry in the cerebellum of AβPP/PS1 transgenic mice, and they provide support for the interpretation of similar alterations occurring in certain pedigrees with FAD.