Katherine L. Shea scite author profile

Emerging evidence suggests that myocyte enhancer factor 2 (MEF2) transcription factors act as effectors of neurogenesis in the brain, with MEF2C the predominant isoform in developing cerebrocortex. Here, we show that conditional knockout of Mef2c in nestin-expressing neural stem/progenitor cells (NSCs) impaired neuronal differentiation in vivo, resulting in aberrant compaction and smaller somal size. NSC proliferation and survival were not affected. Conditional null mice surviving to adulthood manifested more immature electrophysiological network properties and severe behavioral deficits reminiscent of Rett syndrome, an autism-related disorder. Our data support a crucial role for MEF2C in programming early neuronal differentiation and proper distribution within the layers of the neocortex.neurogenesis ͉ synaptogenesis ͉ autism ͉ Rett syndrome K nockdown of the transcription factor MEF2C in mature cerebrocortical neurons results in increased synaptic number and activity (1). To facilitate analysis of MEF2C function in early neuronal development, we engineered a conditional knockout in NSCs by crossing floxed Mef2c mice with Nestin-Cre mice. In contrast to the findings in more mature neurons, we found a striking alteration in the distribution of new neurons in the neocortex and the opposite effect on synaptic activity, i.e., decreased neurotransmission persisting into adulthood.MEF2C belongs to the myocyte enhancer factor 2 (MEF2) subfamily of the MADS (MCM1-agamous-deficiens-serum response factor) gene family (2, 3). We cloned MEF2C from developing mouse brain, and Eric Olson and colleagues then discovered it in the heart (2, 4, 5). In cerebrocortex, MEF2 transcriptional activity is restricted to differentiated cortical neurons in a specific laminar pattern, and its distribution increases along the rostrocaudal axis (2, 4, 6). These features led to speculation on the potential role of MEF2C in the architechtonics of the cerebral cortex (2). Previous studies demonstrated an important role for MEF2C in heart development (7). In the CNS, MEF2C is involved in neuronal apoptosis (8) and synapse formation (1, 9) in vitro or in brain slices. Most recently, our laboratory discovered that a constitutively active form of MEF2C induces embryonic stem cells to commit to a neuronal fate in a virtually exclusive fashion (10). However, studies on the effect of endogenous MEF2C on CNS neurons in vivo were impeded by the embryonic lethality of conventional Mef2c-null mice because of cardiovascular defects at embryonic day (E) 9.5, before brain development (7). Here, we report that conditionally knocking out the Mef2c gene in neural progenitors causes abnormal aggregation and compaction of neurons migrating into the lower layers of the neocortex during development. Knockout mice surviving to adulthood manifest smaller, apparently less mature neurons and smaller whole brain size, with resultant aberrant electrophysiology and behavior.

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Steroid Receptor Coactivator-1 from Brain Physically Interacts Differentially with Steroid Receptor Subtypes

Molenda-Figueira

Murphy

Shea

et al. 2008

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In vitro studies reveal that nuclear receptor coactivators enhance the transcriptional activity of steroid receptors, including estrogen (ER) and progestin receptors (PR), through ligand-dependent interactions. Whereas work from our laboratory and others shows that steroid receptor coactivator-1 (SRC-1) is essential for efficient ER and PR action in brain, very little is known about receptor-coactivator interactions in brain. In the present studies, pull-down assays were used to test the hypotheses that SRC-1 from hypothalamic and hippocampal tissue physically associate with recombinant PR or ER in a ligand-dependent manner. SRC-1, from hypothalamus or hippocampus, interacted with PR-A and PR-B in the presence of an agonist, but not in the absence of ligand or in the presence of a selective PR modulator, RU486. Interestingly, SRC-1 from brain associated more with PR-B, the stronger transcriptional activator, than with PR-A. In addition, SRC-1 from brain, which was confirmed by mass spectrometry, interacted with ERalpha and ERbeta in the presence of agonist but not when unliganded or in the presence of the selective ER modulator, tamoxifen. Furthermore, SRC-1 from hypothalamus, but not hippocampus, interacted more with ERalpha than ERbeta, suggesting distinct expression patterns of other cofactors in these brain regions. These findings suggest that interactions of SRC-1 from brain with PR and ER are dependent on ligand, receptor subtype, and brain region to manifest the pleiotropic functional consequences that underlie steroid-regulated behaviors. The present findings reveal distinct contrasts with previous cell culture studies and emphasize the importance of studying receptor-coactivator interactions using biologically relevant tissue.

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Katherine L. Shea

Transcription factor MEF2C influences neural stem/progenitor cell differentiation and maturation in vivo

Steroid Receptor Coactivator-1 from Brain Physically Interacts Differentially with Steroid Receptor Subtypes

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