benzimidazol-2-one), either injected intranigrally or given systemically, also elevated striatal dopamine release and facilitated motor activity, confirming that these effects were caused by blockade of endogenous N/OFQ signaling. The inhibitory role played by endogenous N/OFQ on motor activity was additionally strengthened by the finding that mice lacking the NOP receptor gene outperformed wild-type mice on the rotarod. We conclude that NOP receptors in the substantia nigra pars reticulata, activated by endogenous N/OFQ, drive a physiologically inhibitory control on motor behavior, possibly via modulation of the nigrostriatal dopaminergic pathway.
Systemic injections of kainic acid (KA) cause epileptic seizures with delayed neuronal damage in the limbic system, particularly in the hippocampus. KA excitotoxicity activates complex signal transduction events that trigger apoptotic cell death. The c-Jun N-terminal kinase (JNK) pathway plays an important role in cell death, and the peptide D-JNKI1, a competitive JNK inhibitor, is a potent neuroprotective agent. To analyse the role of JNK and the effects of D-JNKI1 administration on excitotoxic neuronal death, we induced epileptic seizures by intraperitoneal (i.p.) injection of KA in adult male Sprague-Dawley rats; a group of rats received i.p. D-JNKI1 2 h after KA. KA caused massive cell death in the hippocampus: in Nissl-stained sections, stereological counts showed a significant decrease in neuronal density in all CA fields, both at 1 and 5 days after seizures, which was partially prevented by D-JNKI1 treatment. These results were confirmed by counts of degenerating neurons in CA3 in FluoroJade B-stained sections. Seizure activity also induced marked gliosis as observed with glial fibrillary acidic protein (GFAP) immunohistochemistry. We also analysed c-Jun activation as a target of JNK and central transcriptional effector in the adult rat brain following KA injection. Phospho-c-Jun immunoreactivity was absent in the hippocampus of untreated animals, whereas strong nuclear neuronal labeling could be observed, starting from 3 h after KA administration, in microtubule-associated protein-2-positive neurons but not in GFAP-positive astrocytes. D-JNKI1 treatment also reduced the positivity for phospho-c-Jun in the hippocampus, thus confirming the specificity of the peptide in blocking JNK. Therefore, JNK is a promising target for blocking seizure-induced cell death.
Beta-amyloid accumulation in brain is a driving force for Alzheimer's disease pathogenesis. Apolipoprotein E (ApoE) represents a critical player in betaamyloid homeostasis, but its role in disease progression is controversial. We previously reported that the acute-phase protein haptoglobin binds ApoE and impairs its function in cholesterol homeostasis. The major aims of this study were to characterize the binding of haptoglobin to beta-amyloid, and to evaluate whether haptoglobin affects ApoE binding to beta-amyloid. Haptoglobin is here reported to form a complex with beta-amyloid as shown by immunoblotting experiments with purified proteins, or by its immunoprecipitation in brain tissues from patients with Alzheimer's disease. The interaction between ApoE and beta-amyloid was previously shown to be crucial for limiting beta-amyloid neurotoxicity and for promoting its clearance. We demonstrate that haptoglobin, rather than impairing ApoE binding to beta-amyloid, promotes to a different extent the formation of the complex between beta-amyloid and ApoE2 or ApoE3 or ApoE4. Our data suggest that haptoglobin and ApoE functions in brain should be evaluated taking into account their mutual interaction with beta-amyloid. Hence, the risk of developing Alzheimer's disease might not only be linked to the different ApoE isoforms, but also rely on the level of critical ligands, such as haptoglobin.
After motor cortex damage, the unaffected homotopic cortex shows changes in motor output. The present experiments were designed to clarify the nature of these interhemispheric effects. We investigate the vibrissa motor cortex (VMC) output after activity suppression of the homotopic area in adult rats. Comparison was made of VMC output after lidocaine inactivation (L-group) or quinolinic acid lesion (Q-group) of the homotopic cortex. In the Q-group, VMC mapping was performed 3 days (Q3Ds group), 2 weeks (Q2Ws group) and 4 weeks (Q4Ws group) after cortical lesion. In each animal, VMC output was assessed by mapping movements induced by intracortical microstimulation (ICMS) in both hemispheres (hemisphere ipsilateral and contralateral to injections). Findings demonstrated that, in the L-group, the size of vibrissal representation was 39.5% smaller and thresholds required to evoke vibrissa movement were 46.3% higher than those in the Control group. There was an increase in the percentage of ineffective sites within the medial part of the VMC and an increase in the percentage of forelimb sites within the lateral part. Both the Q3Ds group and the L-group led to a similar VMC reorganization (Q3Ds vs. L-group, P > 0.05). In the Q2Ws group the VMC representation showed improvement in size (83.4% recovery compared with controls). The VMC showed recovery to normal output at 4 weeks after lesion (Control vs. Q4Ws group, P > 0.05). These results suggest that the VMC of the two hemispheres continuously interact through excitatory influences, preserving the normal output and inhibitory influences defining the border with the forelimb representation
It has been proposed that abnormal vibrissae input to the motor cortex (M1) mediates short-term cortical reorganization after facial nerve lesion. To test this hypothesis, we cut first the infraorbital nerve (ION cut) and then the facial nerve (VII cut) in order to evaluate M1 reorganization without any aberrant, facial-nerve-lesion-induced sensory feedback. In each animal, M1 output was
Using the model of facial nerve injury, we have compared the effect of injury in newborn and adult rats on the adult rat motor cortex (M1). To this end, the facial nerve was severed in 10 newborn rats 2 days after birth (Newborn group) and in 10 adult rats (Adult group). In both the Control (contralateral to untouched nerve) and the Experimental (contralateral to severed nerve) hemisphere of each rat, the M1 output organization was assessed by intracortical microstimulation. Our findings demonstrated that: (i) there is no statistical difference in the percentage of movement sites and in current thresholds required to evoke movement in Control hemispheres between the Adult and Newborn groups of rats; (ii) in Adult Experimental hemispheres, neck sites expand in the medial part of the vibrissae representation more extensively than shown in Newborn Experimental hemispheres; (iii) in Newborn Experimental hemispheres eye sites expand in the medial part of the vibrissae representation more extensively than in Adult Experimental hemispheres (these sites overlap the cortical region where electrical stimulation evokes neck movement in Adult Experimental hemispheres) and (iv) in both Newborn and Adult Experimental hemispheres, forelimb sites expand similarly thereby overlapping the same cortical region, corresponding to the lateral part of the vibrissae representation. We conclude that, when the facial nerve injury is performed in the newborn rat, the pattern of movement representation differs from that obtained with the same lesion in the mature brain only in the frontal cortex corresponding to the medial part of the normal vibrissae representation.
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