inocycline is a clinically available antibiotic and anti-inflammatory drug that also demonstrates neuroprotective properties in a variety of experimental models of neurological diseases. There have thus far been more than 300 publications on minocycline neuroprotection, including a growing number of human studies. Our objective is to critically review the biological basis and translational potential of this action of minocycline on the nervous system.
Neurogenesis persists throughout life in the rodent subventricular zone (SVZ) and increases in the adult after brain injury. In this study, postnatal day 7 (P7) rats underwent right carotid artery ligation followed by 8% O 2 exposure for 90 min, a lesioning protocol that resulted in ipsilateral forebrain hypoxicischemic (HI) injury. The effects of HI injury on SVZ cell proliferation and neurogenesis were examined 1-3 wk later by morphometric measurement of dorsolateral SVZ size; by immunoassays to detect incorporation of bromodeoxyuridine (BrdU) in proliferating cells; and by immunoassays of doublecortin, a microtubule-associated protein expressed only by immature neurons. For determining the cell phenotypes of newly generated cells, tissue sections were double labeled with antibodies to BrdU and markers of mature neurons (neuronal nuclear protein), astrocytes (glial fibrillary acidic protein), or oligodendroglia (RIP). HI injury resulted in enlargement of the ipsilateral SVZ at P14 -28 and a corresponding increase in BrdU cell numbers both in the ipsilateral SVZ and striatum at P21. HI injury also stimulated SVZ neurogenesis, based on increased doublecortin immunostaining in the SVZ ipsilateral to lesioning at P14 -28. However, 4 wk after HI injury, in the lesioned striatum, although BrdU/glial fibrillary acidic protein and BrdU/RIP-labeled cells were identified, no BrdU/neuronal nuclear protein double-labeled cells were found. These results suggest that although acute neonatal HI injury stimulates SVZ proliferation and neurogenesis, there is inadequate trophic support for survival of newly generated neurons. Identification of the trophic factors that enhance maturation and survival of immature neurons could provide important clues for improving recovery after neonatal brain injury. The striatal subventricular zone (SVZ) adjacent to the lateral ventricle is a forebrain region in which neurogenesis persists postnatally. The SVZ contains a population of stem cells and more mature progenitors of neurons, astrocytes, and oligodendrocytes (1,2). These cells do not express the proteins that distinguish mature neurons or glia. Normally, neural progenitors from the SVZ migrate along the rostral migratory stream into the olfactory bulb, where they differentiate into interneurons (1,3); however, after injury, some of these cells migrate toward damaged areas (4 -7).In adult rodent stroke models, acute ischemic brain injury stimulates neurogenesis in the SVZ adjacent to the infarct (4 -7). Some of the neural precursors migrate toward the striatal infarct core and differentiate into both neurons and glia (4 -7). In contrast with these findings in adult brain injury models, the first study that evaluated the impact of hypoxicischemic (HI) brain injury on SVZ neurogenesis in the neonatal rodent brain reported that HI injury [elicited by unilateral carotid ligation and timed exposure to 8% oxygen in 7-d-old (postnatal day 7 [P7]) rats] acutely depleted neural precursors in the SVZ (8). In contrast, although severe HI insults c...
Conflicting data have emerged regarding the role of complement activation in the pathophysiology of cerebral ischemia. On the basis of considerable evidence implicating inflammatory mediators in the progression of neonatal brain injury, we evaluated the contribution of complement activation to cerebral hypoxic-ischemic (HI) injury in the neonatal rat. To elicit unilateral forebrain HI injury, 7-d-old rats underwent right carotid ligation followed by 1.5-2 hr of exposure to 8% oxygen. Using immunoprecipitation and Western blot assays, we determined that HI induces local complement cascade activation as early as 8 hr post-HI; there was an eightfold increase in the activation fragment inactivated C3b at 16 hr. With immunofluorescence assays and confocal microscopy, both C3 and C9 were localized to injured neurons 16 and 24 hr post-HI. To investigate the contribution of systemic complement to brain injury, we administered the complement-depleting agent cobra venom factor (CVF) 24 hr before HI lesioning and evaluated both acute HI-induced complement deposition and the extent of resulting tissue injury 5 d after lesioning. CVF depleted both systemic and brain C3 by the time of surgery and reduced infarct size. Analysis of lesioned, CVF-treated animals demonstrated minimal neuronal C3 deposition but no reduction in C9 deposition. C3-immunoreactive microglia were identified in injured areas. These results indicate that complement activation contributes to HI injury in neonatal rat brain, systemic administration of CVF does not eliminate complement deposition within injured brain, and microglia may represent an important local source of C3 after acute brain injury.
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