Autophagy is Activated In Vivo during Trimethyltin-Induced Apoptotic Neurodegeneration: A Study in the Rat Hippocampus.

Trimethyltin (TMT) is an organotin compound known to produce significant and selective neuronal degeneration and reactive astrogliosis in the rodent central nervous system. Autophagy is the main cellular mechanism for degrading and recycling protein aggregates and damaged organelles, which in different stress conditions, such as starvation, generally improves cell survival. Autophagy is documented in several pathologic conditions, including neurodegenerative diseases. This study aimed to investigate the autophagy and apoptosis signaling pathways in hippocampal neurons of TMT-treated (Wistar) rats to explore molecular mechanisms involved in toxicant-induced neuronal injury. The microtubule-associated protein light chain (LC3, autophagosome marker) and sequestosome1 (SQSTM1/p62) (substrate of autophagy-mediated degradation) expressions were examined by Western blotting at different time points after intoxication. The results demonstrate that the LC3 II/I ratio significantly increased at 3 and 5 days, and that p62 levels significantly decreased at 7 and 14 days. Immunofluorescence images of LC3/neuronal nuclear antigen (NeuN) showed numerous strongly positive LC3 neurons throughout the hippocampus at 3 and 5 days. The terminal deoxynucleotidyltransferase dUTP nick end labeling (TUNEL) assay indicated an increase in apoptotic cells starting from 5 days after treatment. In order to clarify apoptotic pathway, immunofluorescence images of apoptosis-inducing factor (AIF)/NeuN did not show nuclear translocation of AIF in neurons. Increased expression of cleaved Caspase-3 was revealed at 5-14 days in all hippocampal regions by Western blotting and immunohistochemistry analyses. These data clearly demonstrate that TMT intoxication induces a marked increase in both autophagy and caspase-dependent apoptosis, and that autophagy occurring just before apoptosis could have a potential role in neuronal loss in this experimental model of neurodegeneration.

Lower trunk of brachial plexus injury in the neonate rat: effects of timing repair.

OBJECTIVE: After lesion of a peripheral nerve in neonatal mammals, motoneurons undergo a cell death. We wanted to ascertain if early surgery could influence such post-axotomy motoneuronal death and improve the functional outcome. In this study, we investigated the functional and anatomical results after immediate and delayed repair of the lower trunk of brachial plexus (BP) sectioned at birth in rats. METHODS: In neonate rats, the lower trunk of the left BP was cut. This nerve trunk was repaired either immediately [immediately-reconstructed group of rats (IR), or 30 days after, tardy reconstructed group of rats (TR)]; in the third group of animals, the nerve was not repaired (noreconstructed group of rats, NoR). In each group of animals, functional studies were performed at 90 days of age using the grooming test and the walking tracks analysis. Histologic studies of the C7-T1 spinal cord and lower trunk of BP were performed at 30 and 90 days of age; the numbers of motoneuron and axon were counted. RESULTS: Functional recovery was related to the difference in motoneuron number between the injured and the uninjured sides of the spinal cord of the operated animals. On the one side, only in the rats in which the inferior trunk was immediately repaired, the difference in motoneuron number between the two sides of the spinal cord was not statistically significant; these animals showed a good axonal regeneration and function recovery. On the other side, in the rats in which the inferior trunk was left unrepaired or tardy repaired, the decrease in motoneuron number in the injured side compared with the uninjured side of the spinal cord was statistically significant; these animals showed no axonal regeneration and no function recovery. DISCUSSION: The results cited above suggest that an important role in restoration of good neurological function after section of the lower trunk of BP in neonate rats is played by early nerve repair. Good neurological function was related more to a quite numerical balance of motoneurons between the two anterior gray horns of spinal cord than to the absolute number of rescued motoneurons.

Dysregulation of intracellular calcium homeostasis is responsible for neuronal death in an experimental model of selective hippocampal degeneration induced by trimethyltin.

Trimethyltin (TMT) intoxication is considered a suitable experimental model to study the molecular basis of selective hippocampal neurodegeneration as that occurring in several neurodegenerative diseases. We have previously shown that rat hippocampal neurons expressing the Ca(2+)-binding protein calretinin (CR) are spared by the neurotoxic action of TMT hypothetically owing to their ability to buffer intracellular Ca(2+) overload. The present study was aimed at determining whether intracellular Ca(2+) homeostasis dysregulation is involved in the TMT-induced neurodegeneration and if intracellular Ca(2+)-buffering mechanisms may exert a protective action in this experimental model of neurodegeneration. In cultured rat hippocampal neurons, TMT produced time- and concentration-dependent [Ca(2+)](i) increases that were primarily due to Ca(2+) release from intracellular stores although Ca(2+) entry through Ca(v)1 channels also contributed to [Ca(2+)](i) increases in the early phase of TMT action. Cell pre-treatment with the Ca(2+) chelator, 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid tetrakis(acetoxymethyl ester) (2 muM) significantly reduced the TMT-induced neuronal death. Moreover, CR(+) neurons responded to TMT with smaller [Ca(2+)](i) increases. Collectively, these data suggest that the neurotoxic action of TMT is mediated by Ca(2+) homeostasis dysregulation, and the resistance of hippocampal neurons to TMT (including CR(+) neurons) is not homogeneous among different neuron populations and is related to their ability to buffer intracellular Ca(2+) overload.

Canine cognitive dysfunction and the cerebellum: acetylcholinesterase reduction, neuronal and glial changes.

The specific functional and pathological alterations observed in Alzheimer's disease are less severe in the cerebellum than in other brain areas, particularly the entorhinal cortex and hippocampus. Since dense core amyloid-beta plaque formation has been associated with an acetylcholinesterase heterogeneous nucleator action, we examined if an acetylcholinesterase imbalance was involved in cerebellum plaque deposition. By using the canine counterpart of senile dementia of the Alzheimer's type, a promising model of human brain aging and early phases of Alzheimer's disease, we investigated how cerebellar pathology and acetylcholinesterase density could be related with cognitive dysfunction. As in Alzheimer's disease, the late affectation of the cerebellum was evidenced by its lack of amyloid-beta plaque and the presence of diffuse deposition throughout all cortical grey matter layers. The highest acetylcholinesterase optic density corresponded to cerebellar islands of the granular layer and was predominantly associated with synaptic glomeruli and the somata of Golgi cells. Its reduction correlated with aging and loss of granule cells, whereas cognitive deficit only correlated with loss of Purkinje cells. The observed Bergmann glia alterations may correspond to a reactive response to the loss and damage of the Purkinje cells, their specific neuronal partner. Regarding the role of acetylcholinesterase mediation in amyloid-beta deposition, our data argue against an interaction between these two proteins because acetylcholinesterase reduction correlates with aging but not with cognitive deficit. Finally, our data support the use of companion dogs of all breeds to study aging and early phases of Alzheimer's disease.

Early nuclear factor-kappaB activation and inducible nitric oxide synthase expression in injured spinal cord neurons correlating with a diffuse reduction of constitutive nitric oxide synthase activity.

OBJECT: Because of toxicity at high concentrations, nitric oxide (NO) contributes to spinal cord injury (SCI) secondary lesions. At low concentrations NO modulates nuclear factor-kappaB (NF-kappaB) activation. The authors investigated the activity of neuronal and endothelial NO synthase (nNOS and eNOS) to determine correlations with NF-kappaB activation and inducible NOS (iNOS) expression soon after SCI. METHODS: In 48 adult male Wistar rats clip-based (50 g/mm2/10 seconds) SCI was induced, and spinal cords were removed at different intervals for the following evaluations: 1) assaying specific activity of nNOS and eNOS; 2) electrophoresis mobility shift assay for activated NF-kappaB; 3) Northern blotting for iNOS; 4) immunohistochemistry for iNOS and NF-kappaB; and 5) immunofluorescence for iNOS and NF-kappaB. At 15 minutes postinjury, eNOS activity decreased significantly (p < 0.001), as did nNOS activity at 1 hour compared with these levels in control animals and rats killed at 15 and 30 minutes after SCI (p < 0.001). Basal NF-kappaB levels were variable in controls and at 15 and 30 minutes after injury. One hour postinjury, NF-kappaB activation was diffuse. Inducible NOS messenger RNA localized diffusely, peaking 6 hours after injury and remaining stable until 24 hours postinjury. Immunohistochemical analysis showed diffuse iNOS and NF-kappaB staining, especially in neurons inside and around the lesion. Immunofluorescence demonstrated that injured neurons were a source of NF-kappaB and iNOS soon after injury. CONCLUSIONS: Both nNOS and eNOS exhibited different regulation and roles soon after injury: nNOS correlated with NF-kappaB activation, whereas eNOS may have participated in vascular changes of the injured spinal cord. Neurons seemed to play a pivotal role in modulating and amplifying the inflammatory response in the injured spinal cord.

Reelin is transiently expressed in the peripheral nerve during development and is upregulated following nerve crush.

Reelin is an extracellular matrix protein which is critical for the positioning of migrating post-mitotic neurons and the laminar organization of several brain structures during development. We investigated the expression and localization of Reelin in the rodent peripheral nerve during postnatal development and following crush injury in the adult stage. As shown with Western blotting, immunocytochemistry and RT-PCR, Schwann cells in the developing peripheral nerve and in primary cultures from neonatal nerves produce and secrete Reelin. While Reelin levels are downregulated in adult stages, they are again induced following sciatic nerve injury. A morphometric analysis of sciatic nerve sections of reeler mice suggests that Reelin is not essential for axonal ensheathment by Schwann cells, however, it influences the caliber of myelinated axons and the absolute number of fibers per unit area. This indicates that Reelin may play a role in peripheral nervous system development and repair by regulating Schwann cell-axon interactions.

Reinnervation of extraocular muscles by facial-to-oculomotor nerve anastomosis in rats: anatomic nuclear changes.

OBJECTIVE: Oculomotor nerve palsy greatly impairs the patient's daily life. After oculomotor nerve injury, when the central nerve stump is not available, neurotization of the distal nerve stump with a donor nerve may be performed. Here, we present an experimental anatomic study in rats related to the motor nuclear organization after facial-to-oculomotor nerve anastomosis. METHODS: In adult rats, the right oculomotor nerve was transected at the skull base. Then, the ipsilateral facial nerve was exposed at the stylomastoid foramen and connected side-to-end to one extremity of a peroneal nerve autograft. The other extremity of the nerve autograft was connected end-to-end to the distal stump of the transected oculomotor nerve. Twelve weeks later, axonal regeneration in the autograft and brainstem somatotopic representation of the reinnervated extraocular muscles were investigated by use of histological and retrograde axonal tracing techniques. RESULTS: The autograft was reinnervated by a large number of small axons, 1 to 5 microm in diameter. After tracer injection into the superior rectus and medial rectus muscles, retrogradely labeled neurons were seen not only in the ipsilateral facial nucleus (16%) but also in the contralateral nucleus (8%). Labeled neurons were also seen in the ipsilateral abducens (12%), motor trigeminus (7%), trochlear (23%), and contralateral trochlear (34%) nuclei. In normal rats, the extraocular muscles are innervated by unilateral-ipsilateral brainstem motor nuclei, except for the superior rectus and superior oblique muscles, which are innervated by bilateral, primarily contralateral, nuclei. CONCLUSION: The central rearrangement of the extraocular muscle nuclei after facial-to-oculomotor nerve anastomosis represents an original example of plasticity. Functional studies are needed to demonstrate whether this procedure might serve to restore some degree of eye motility.