ObjectiveTo investigate the effects of melatonin treatment in a rat model of white matter damage (WMD) in the developing brain. Additionally, we aim to delineate the cellular mechanisms of melatonin effect on the oligodendroglial cell lineage.MethodsA unilateral ligation of the uterine artery in pregnant rat at the embryonic day 17 induces fetal hypoxia and subsequent growth restriction (GR) in neonatal pups. GR and control pups received a daily intra-peritoneal injection of melatonin from birth to post-natal day (P) 3.ResultsMelatonin administration was associated with a dramatic decrease in microglial activation and astroglial reaction compared to untreated GR pups. At P14, melatonin prevented white matter myelination defects with an increased number of mature oligodendrocytes (APC-immunoreactive) in treated GR pups. Conversely, melatonin was not found to be associated with an increased density of total oligodendrocytes (Olig2-immunoreactive), suggesting that melatonin is able to promote oligodendrocyte maturation but not proliferation. These effects appear to be melatonin-receptor dependent and were reproduced in vitro.InterpretationThese data suggest that melatonin has a strong protective effect on developing damaged white matter through decreased microglial activation and oligodendroglial maturation leading to a normalization of the myelination process. Consequently, melatonin should be a considered as an effective neuroprotective candidate not only in perinatal brain damage but also in inflammatory and demyelinating diseases observed in adults.
White-matter damage is a leading cause of neurological handicap. Although hypoxia-ischemia and excitotoxicity are major pathogenic factors, a role for genetic influences was suggested recently. Thus, protracted gestational hypoxia was associated with whitematter damage (WMD) in rat pups but not in mouse pups. Indeed, microglial activation and vessel-wall density on postnatal days (P)1 and P10 were found increased in both mouse and rat pups, but cell death, astrogliosis, and myelination were only significantly altered in hypoxic rat pups. We investigated whether this species-related difference was ascribable to effects of antenatal hypoxia on the expression of glutamate receptor subunits by using immunocytochemistry, PCR, and excitotoxic double hit insult. Quantitative PCR in hypoxic mouse pups on P1 showed 2-to 4-fold down-regulation of the AMPA-receptor subunits -1, 2, and -4; of the kainate-receptor subunit GluR7; and of the metabotropic receptor subunits mGluR1, -2, -3, -5, and -7. None of the glutamate-receptor subunits was down-regulated in the hypoxic rat pups. NR2B was the only NMDA-receptor subunit that was down-regulated in hypoxic mice but not in hypoxic rat on P1. Ifenprodil administration to induce functional inhibition of NMDA containing NR2B-subunit receptors prevented hypoxia-induced myelination delay in rat pups. Intracerebral injection of a glutamate agonist produced a larger decrease in ibotenate-induced excitotoxic lesions in hypoxic mouse pups than in normoxic mouse pups. Gestational hypoxia may regulate the expression of specific glutamate-receptor subunits in fetal mice but not in fetal rats. Therefore, genetic factors may influence the susceptibility of rodents to WMD. brain damage ͉ NMDA receptors ͉ genetic factors ͉ development ͉ prematurity P eriventricular (P) WMD and subsequent cortical damage are the leading causes of cerebral palsy (CP) limited to preterm birth (1, 2). Animal models have been developed to unravel the mechanisms underlying these brain lesions. Factors that seem involved in the pathophysiology of CP in these models include hypoxia and ischemia, infection and inflammation, excitotoxicity, accumulation of reactive oxygen species, and deficiencies in growth factors (3, 4). These factors seem to act in combination to cause damage to the developing white matter.Glutamate accumulation may be a mechanism common to many risk factors for CP. Glutamate, the major excitatory neurotransmitter, acts by means of several groups of receptors, namely, NMDA, AMPA, kainate, and metabotropic receptors (mGluRs). Excessive activation of glutamate receptors may cause cell vulnerability, in part as a result of intracellular calcium influx (5, 6). Intracerebral injection of glutamate agonists into the neocortex and white matter of newborn rodents produces histological lesions that mimic the brain damage observed in preterm neonates (7-10).Several studies suggest that genetic factors may influence the susceptibility of very preterm infants to PWMD. The occurrence of CP may depend, at least in ...
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