Gianfranco Scarsella

Biomolecular modulation of neurodegenerative events during ageing

The objective is to assess the modulation of retinal and optic nerve degenerative events induced by the combination of α-lipoic acid (ALA) and superoxide dismutase (SOD) in an animal model of ageing. For this study, 24 male Wistar-Harlan strain rats were left to age for up to 24 months. One group of rats was subjected to a diet supplemented with ALA and SOD for 8 weeks, while another group was used as a positive control and not subjected to any dietary treatment. To assess the cytoprotective effects of the antioxidants, a morphological analysis was carried out on sections of retina and optic nerve head, stained with haematoxylin-eosin, followed by an analysis of the modifications to nuclear DNA detected by the TUNEL technique. The lipid peroxidation assay was used to assess the damage induced by oxidative stress at cell membrane level. The molecules involved in apoptosis mediated by oxidative stress, such as caspase-3 and inducible nitric oxide synthase, were also assayed by immunolocalization and western blot. ALA and SOD are able to counteract senile neurodegenerative deterioration to the retina and optic nerve. Indeed, the combination of these antioxidant molecules can reduce oxidative stress levels and thus prevent both nuclear degradation and subsequent cell death.

Degenerative and apoptotic events at retinal and optic nerve level after experimental induction of ocular hypertension

Ocular hypertension is a symptom of a glaucomatous condition characterized by a severe vision decrease. Blindness caused by the apoptotic death of the retinal ganglion cells and of the astrocytes of the optic nerve may eventually result. Experimental hypertension was induced by inoculation of methylcellulose in the anterior chamber. Chromatin staining, TUNEL assay, and inter-nucleosomal DNA fragmentation observed in retina and optic nerve strongly suggest that hypertension causes apoptosis. Immunolocalization of the fibrillary acidic glial protein, specific of cell stress, and caspase-3 in the same tissues, further support this mode of cell death. Activation of the ubiquitin dependant proteolytic system was also observed. Protection from apoptosis exerted by administration of the peroxide scavenger trolox, suggests that the apoptotic pathway is activated by an oxidative stress. The data presented here show that the experimental hypertensive insult induces degenerative and apoptotic events comparable to those observed in human glaucoma.

Ubiquitin-Mediated Stress Response in a Rat Model of Brain Transient Ischemia/Hypoxia

Ubiquitin (Ub) is a small 76-residue protein, involved in intracellular protein degradation through a specific ATP-dependent system, which uses Ub as a tag to label proteins committed to be hydrolyzed by a specific 26 S protease. PGP-9.5 is another important component of the Ub system, i.e. a neuron-specific carboxyl-terminal hydrolase, which recycles Ub from Ub-polypeptide complexes. We have investigated the expression of Ub and PGP-9.5 in rat hippocampal neurons in an early phase of reperfusion in a model of transient global brain ischemia/hypoxia (bilateral occlusion of common carotid arteries for 10 min accompanied by mild hypoxia—15% O2—for 20 min), by means of immunohistochemical methods using light and electron microscopy. The intensity of Ub and PGP-9.5 immunoreactivity was evaluated by image analysis. We have detected a marked increase of Ub immunoreactivity (UIR) in neurons of CA1, CA2, CA3, CA4, and dentate gyrus subfields 1 hr after ischemia/hypoxia (but not after hypoxia only), statistically significant as confirmed by image analysis. Such increase in immunoreactivity in ischemic/hypoxic rats was localized essentially in the nuclei of hippocampal neurons. There were no changes in PGP-9.5 immunoreactivity. The data suggest that in the present model of rat brain ischemia/hypoxia Ub is involved in the neuronal stress response.

Acetylcholinesterase in the development of chick dorsal root ganglia

Acetylcholinesterase is expressed in chick dorsal root ganglia neurons very early in development. Since the physiological role of the enzyme in these cells is still obscure, it appeared of interest to investigate its modifications in the course of development.

Effect of different whole body hyperthermic sessions on the heat shock response in mice liver and brain.

We examined by Western blots the effect of variations of the heating sessions, such as duration and intensity on the following aspects: 70-kDa heat shock protein (HSP70) and HSP72 induction. Protein ubiquitination PLCγ PKCε and PKCα levels in murine liver and brain were also studied. Results demonstrated that maximal induction of HSP72 was obtained after heat shock at 43.5°C in both organs. Preconditioning at lower temperatures (either acclimation to 39°C or induction of thermotolerance to 43.5°C with a single exposure to 39°C) attenuated the heat shock response. Hepatic HSP72 induction was elicited only as a consequence of hyperthermia since either fasting or restraint were unable to trigger its synthesis. On the contrary, a ubiquitination decrease of a 31 kDa protein was obtained both after hyperthermia and fasting This indicates that the latter is a more generic response of hepatic cells to noxious stimuli. Analysis of the above mentioned enzymes showed that in liver of naive mice PKCα is barely present while PKCε is quite abundant. All hyperthermic treatments caused a general decrease of the latter, except for the heat shock at 43.5°C that caused an increase. PLCγ decreased after all heating sessions. It is known that hyperthermia in the range of 41-45°C induces apoptotic death in many cell types. Therefore we analyzed the presence of the typical apoptotic DNA ladder. Our data strongly suggest that both hyperthermia and restraint induce necrosis in liver while apoptosis and necrosis become evident in brain. All these effects are still present 24 h from the last heating session: This indicates thatin vivo, hyperthermia produces long term modifications of the hepatic cell.

Cytotoxic and antiproliferative effects induced by a non terpenoid polar extract of A. indica seeds on 3T6 murine fibroblasts in culture

Neem oil is a natural product obtained from the seeds of the tree Azadirachta indica. Its composition is very complex and the oil exhibits a number of biological activities. The most studied component is the terpenoid azadirachtin which is used for its insecticidal and putative antimicrobial properties. In this report we investigate the biological activity of partially purified components of the oil obtained from A. indica. We show that the semi-purified fractions have moderate to strong cytotoxicity. However, this is not attributable to azadirachtin but to other active compounds present in the mixture. Each fraction was further purified by appropriate extraction procedures and we observed a differential cytotoxicity in the various sub-fractions. This led us to investigate the mode of cell death. After treatment with the oil fractions we observed positivity to TUNEL staining and extensive internucleosomal DNA degradation both indicating apoptotic death. The anti-proliferative properties of the neem oil-derived compounds were also assayed by evaluation of the nuclear PCNA levels (Proliferating Cell Nuclear Antigen). PCNA is significantly reduced in cells treated with a specific fraction of neem oil. Finally, our results strongly suggest a possible involvement of the mitochondrial pathway in the apoptotic death.

Membrane acetylcholinesterase in murine muscular dystrophy In vivo and in cultured myotubes

Murine muscular dystrophy is characterized by a reduction of the 10S molecular form of acetylcholinesterase (AChE); this reduction occurs in both strains of dystrophic mice and at the time of the phenotypic appearance of the disease.

Carnitine reduces the lipoperoxidative damage of the membrane and apoptosis after induction of cell stress in experimental glaucoma

The pathological damage caused by glaucoma is associated to a high intraocular pressure. The ocular hypertone is most likely due to a defective efflux of aqueous humor from the anterior chamber of the eye. Ocular hypertension causes apoptotic death of retinal ganglion cells and overexpression of molecular markers typical of cell stress response and apoptosis. In this work, we report on the neuroprotective, antiapoptotic and antioxidant action of a natural substance, -carnitine. This compound is known for its ability to improve the mitochondrial performance. We analyze a number of cellular and molecular markers, typical of ocular hypertension and, in general, of the cell stress response. In particular, L-carnitine reduces the expression of glial fibrillary acidic protein, inducible nitric oxide synthase, ubiquitin and caspase 3 typical markers of cell stress. In addition, the morphological analysis of the optic nerve evidenced a reduction of the pathological excavation of the optic disk. This experimental hypertone protocol induces a severe lipoperoxidation, which is significantly reduced by L-carnitine. The overall interpretation is that mortality of the retinal cells is due to membrane damage.

Characterization of Acetylcholinesterase Secretion in Neuronal Cultures and Regulation by High K+ and Soluble Factors from Target Cells

Abstract: We have observed that cultured neurons from chick spinal cord and the neuroblastoma hybrid line 108CC15 released lower amounts of acetylcholinesterase (AChE) when compared with the parental line, N18TG2. AChE activity extracted by hypotonic buffer, which can be regarded as the source of the released enzyme, was considerably higher in the parental than in the hybrid 108CC15 (respectively, ∼80% and ∼40% of cellular activity). On the other hand, evaluation of ectocellular, with respect to total, AChE activity showed that in N18TG2 cells only 7% of AChE was localized on the plasmalemma, whereas in the hybrid line the percentage of ectocellular activity was 3.7 times higher than in the parental line. We have also examined the effect of cytochalasin B and nocodazole. In the N18TG2 line, the former did not affect AChE release, which was significantly reduced by the latter. High K+ level in the culture medium, of both N18TG2 and hybrid 108CC15 cultures, induced an increase in AChE secretion; Ca2+ presence was required for high K+‐induced release. Muscle extracts increased AChE secretion in both the hybrid 108CC15 and the spinal cord neurons. The present data suggest that AChE secretion during neuronal development is modulated by depolarizing stimuli and by soluble factors produced by target cells and may be involved in the control of neuronal differentiation.

Acute ischemia/hypoxia in rat hippocampal neurons activates nuclear ubiquitin and alters both chromatin and DNA

We investigated early alterations in rat neurons after experimental ischemic stress. Transient ischemia was generated by bilateral occlusion of the carotids after hypoxia. Data show a relevant increase of the nuclear level of ubiquitin 2 h post-stress as evaluated by immuno-cytolocalization. Ubiquitin returns to normal levels after 6 h. The increase in ischemic/hypoxic rats was localized preferentially in nuclei of hippocampal neurons, although some augmentation was also shown essentially in dendrites. The activation of ubiquitin system is related to a defective homeostasis and might trigger different degenerative processes. With respect to this, we observed chromatin alterations by densitometric analysis. The shown extensive DNA degeneration is consistent with the occurrence of necrotic phenomena at an early stage. However the parallel internucleosomal specific DNA fragmentation, strongly suggests that apoptotic events also occur. In any case both necrosis and apoptosis are likely to occur at same time, although apoptosis is less extensive, and two phenomena take place in different neural cells.