Brian L. Murphy scite author profile

Summary The dentate gyrus is hypothesized to function as a “gate”, limiting the flow of excitation through the hippocampus. During epileptogenesis, adult-generated granule cells (DGC) form aberrant neuronal connections with neighboring DGC, disrupting the dentate gate. Hyperactivation of the mTOR signaling pathway is implicated in driving this aberrant circuit formation. While the presence of abnormal DGC in epilepsy has been known for decades, direct evidence linking abnormal DGC to seizures has been lacking. Here, we isolate the effects of abnormal DGC using a transgenic mouse model to selectively delete PTEN from postnatally-generated DGC. PTEN deletion led to hyperactivation of the mTOR pathway, producing abnormal DGC morphologically similar to those in epilepsy. Strikingly, animals in which PTEN was deleted from ≥9% of the DGC population developed spontaneous seizures in about four weeks, confirming that abnormal DGC – which are present in both animals and humans with epilepsy – are capable of causing the disease.

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Pilocarpine-Induced Seizures Cause Selective Time-Dependent Changes to Adult-Generated Hippocampal Dentate Granule Cells

Walter¹,

Murphy²,

Pun³

et al. 2007

J. Neurosci.

163

176

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Aberrantly interconnected granule cells are characteristic of temporal lobe epilepsy. By reducing network stability, these abnormal neurons may contribute directly to disease development. Only subsets of granule cells, however, exhibit abnormalities. Why this is the case is not known. Ongoing neurogenesis in the adult hippocampus may provide an explanation. Newly generated granule cells may be uniquely vulnerable to environmental disruptions relative to their mature neighbors. Here, we determine whether there is a critical period after neuronal birth during which neuronal integration can be disrupted by an epileptogenic insult. By bromodeoxyuridine birthdating cells in green fluorescent protein-expressing transgenic mice, we were able to noninvasively label granule cells born 8 weeks before (mature), 1 week before (immature), or 3 weeks after (newborn) pilocarpineepileptogenesis. Neuronal morphology was examined 4 and 8 weeks after pilocarpine treatment. Strikingly, almost 50% of immature granule cells exposed to pilocarpine-epileptogenesis exhibited aberrant hilar basal dendrites. In contrast, only 9% of mature granule cells exposed to the identical insult possessed basal dendrites. Moreover, newborn cells were even more severely impacted than immature cells, with 40% exhibiting basal dendrites and an additional 20% exhibiting migration defects. In comparison, Ͻ5% of neurons from normal animals exhibited either abnormality, regardless of age. Together, these data demonstrate the existence of a critical period after the birth of adult-generated neurons during which they are vulnerable to being recruited into epileptogenic neuronal circuits. Pathological brain states therefore may pose a significant hurdle for the appropriate integration of newly born endogenous, and exogenous, neurons.

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Heterogeneous Integration of Adult-Generated Granule Cells into the Epileptic Brain

Murphy¹,

Pun²,

Yin³

et al. 2011

J. Neurosci.

100

111

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The functional impact of adult-generated granule cells in the epileptic brain is unclear, with data supporting both protective and maladaptive roles. These conflicting findings could be explained if new granule cells integrate heterogeneously, with some cells taking neutral or adaptive roles and others contributing to recurrent circuitry supporting seizures. Here, we tested this hypothesis by completing detailed morphological characterizations of age-and experience-defined cohorts of adult-generated granule cells from transgenic mice. The majority of newborn cells exposed to an epileptogenic insult exhibited reductions in dendritic spine number, suggesting reduced excitatory input to these cells. A significant subset, however, exhibited higher spine numbers. These latter cells tended to have enlarged cell bodies, long basal dendrites, or both. Moreover, cells with basal dendrites received significantly more recurrent mossy fiber input through their apical dendrites, indicating that these cells are robustly integrated into the pathological circuitry of the epileptic brain. These data imply that newborn cells play complex-and potentially conflicting-roles in epilepsy.

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Silencing of the miR-17∼92 Cluster Family Inhibits Medulloblastoma Progression

et al. 2013

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Medulloblastoma (MB), originating in the cerebellum, is the most common malignant brain tumor in children. MB consists of four major groups where constitutive activation of the Sonic Hedgehog (SHH) signaling pathway is a hallmark of one group. Mouse and human SHH MBs exhibit increased expression of microRNAs encoded by the miR-17~92 and miR-106b~25 clusters compared to granule progenitors and post-mitotic granule neurons. Here, we assessed the therapeutic potential of 8-mer seed-targeting LNA-modified antimiR oligonucleotides, termed tiny LNAs, that inhibit microRNA seed families expressed by miR-17~92 and miR-106b~25 in two mouse models of SHH MB. We found that tumor cells (MB cells) passively took up 8-mer LNA-antimiRs, and specifically inhibited targeted microRNA seed-sharing family members. Inhibition of miR-17 and miR-19a seed families by antimiR-17 and antimiR-19, respectively, resulted in diminished tumor cell proliferation in vitro. Treatment of mice with systemic delivery of antimiR-17 and antimiR-19 reduced tumor growth in flank and brain allografts in vivo and prolonged the survival of mice with intracranial transplants, suggesting that inhibition of the miR-17~92 cluster family by 8-mer LNA-antimiRs might be considered for the treatment of SHH MBs.

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Brian L. Murphy

Excessive Activation of mTOR in Postnatally Generated Granule Cells Is Sufficient to Cause Epilepsy

Pilocarpine-Induced Seizures Cause Selective Time-Dependent Changes to Adult-Generated Hippocampal Dentate Granule Cells

Heterogeneous Integration of Adult-Generated Granule Cells into the Epileptic Brain

Silencing of the miR-17∼92 Cluster Family Inhibits Medulloblastoma Progression

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