The organization of neural progenitors in the developing mammalian neuroepithelium is marked by cadherin-based adherens junctions. Whereas RhoA, a founding member of the small Rho GTPase family, has been shown to play important roles in epithelial adherens junctions, its physiological roles in neural development remain uncertain due to the lack of specific loss-of-function studies. Here, we show that RhoA protein accumulates at adherens junctions in the developing mouse brain and colocalizes to the cadherin–catenin complex. Conditional deletion of
RhoA
in midbrain and forebrain neural progenitors using Wnt1-Cre and Foxg1-Cre mice, respectively, disrupts apical adherens junctions and causes massive dysplasia of the brain. Furthermore,
RhoA
-deficient neural progenitor cells exhibit accelerated proliferation, reduction of cell- cycle exit, and increased expression of downstream target genes of the hedgehog pathway. Consequently, both lines of conditional
RhoA
-deficient embryos exhibit expansion of neural progenitor cells and exencephaly-like protrusions. These results demonstrate a critical role of RhoA in the maintenance of apical adherens junctions and the regulation of neural progenitor proliferation in the developing mammalian brain.
Intrauterine infection exacerbates neonatal hypoxic-ischemic (HI) brain injury and impairs the development of cerebral cortex. Here we used low-dose lipopolysaccharide (LPS) pre-exposure followed by unilateral cerebral HI insult in 7-day-old rats to study the pathogenic mechanisms. We found that LPS pre-exposure blocked the HI-induced proteolytic activity of tissue-type plasminogen activator (tPA), but significantly enhanced NF-κB signaling, microglia activation, and the production of pro-inflammatory cytokines in newborn brains. Remarkably, these pathogenic responses were all blocked by intracerebroventricular injection of a stable-mutant form of plasminogen activator protein-1 called CPAI. Similarly, LPS pre-exposure amplified, while CPAI therapy mitigated HI-induced blood-brain-barrier damage and the brain tissue loss with a therapeutic window at 4 h after the LPS/HI insult. The CPAI also blocks microglia activation following a brain injection of LPS, which requires the contribution by tPA, but not the urinary-type plasminogen activator (uPA), as shown by experiments in tPA-null and uPA-null mice. These results implicate the nonproteolytic tPA activity in LPS/HI-induced brain damage and microglia activation. Finally, the CPAI treatment protects near-normal motor and white matter development despite neonatal LPS/HI insult. Together, because CPAI blocks both proteolytic and nonproteolytic tPA neurotoxicity, it is a promising therapeutics of neonatal HI injury either with or without infection.
Perinatal infection aggravates neonatal hypoxic-ischemic (HI) brain injury and may interfere with therapeutic hypothermia. While the NF-κB signaling pathway has been implicated in microglia activation in infection-sensitized HI, the current therapeutic strategies rely on systemic intervention, which could impair neonatal immunity and increase the risk of severe infection. To devise a brain-targeted anti-NF-κB strategy, we examined the effects of intranasal delivery of tat-NBD peptides in two animal models of neonatal infection-sensitized HI. Kinetics experiments showed that tat-NBD peptides entered the olfactory bulbs rapidly (10-30 min) and peaked in the cerebral cortex around 60 min after intranasal application in P7 rats. Further, intranasal delivery of 1.4 mg/kg tat-NBD, which is only 7% of the intravenous dose in past studies, markedly attenuated NF-κB signaling, microglia activation, and brain damage triggered by HI with 4 or 72 h pre-exposure to the bacterial endotoxin lipopolysaccharide (LPS). In contrast, intranasal delivery of mutant tat-NBD peptides or systemic application of minocycline failed to block LPS-sensitized HI injury. Yet, intranasal delivery of up to 5.6 mg/kg tat-NBD peptides immediately after pure-HI insult showed litter protection, likely due to its rapid clearance from the brain and inability to inhibit parenchymal plasminogen activators. Together, these results suggest a novel therapy of infection-sensitized HI brain injury in newborns.
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