Embryonic origins of the mouse superior olivary complex.

Many areas of the central nervous system are organized into clusters of cell groups, with component cell groups exhibiting diverse but related functions. One such cluster, the superior olivary complex (SOC), is located in the ventral auditory brainstem in mammals. The SOC is an obligatory contact point for most projection neurons of the ventral cochlear nucleus and plays central roles in many aspects of monaural and binaural information processing. Despite their important interrelated functions, little is known about the embryonic origins of SOC nuclei, due in part to a paucity of developmental markers to distinguish individual cell groups. In this report, we present a collection of novel markers for the developing SOC nuclei in mice, including the transcription factors FoxP1, MafB, and Sox2, and the lineage-marking transgenic line En1-Cre. We use these definitive markers to examine the rhombic lip and rhombomeric origins of SOC nuclei and demonstrate that they can serve to uniquely identify SOC nuclei and subnuclei in newborn pups. The markers are also useful in identifying distinct nuclear domains within the presumptive SOC as early as embryonic day (E) 14.5, well before morphological distinction of individual nuclei is evident. These findings indicate that the mediolateral and dorsoventral position of SOC nuclei characteristic of the adult brainstem is established during early neurogenesis.

Induction of myelin protein zero by early growth response 2 through upstream and intragenic elements.

The Mpz (myelin protein zero) gene codes for the principal component of myelin in the peripheral nervous system, and mutations in this gene cause human peripheral myelinopathies. Expression of the Mpz gene is controlled by two major transactivators that coordinate Schwann cell development: Egr2/Krox20 and Sox10. Our in vivo ChIP-chip analysis in myelinating peripheral nerve identified major sites of Egr2 interaction within the first intron of the Mpz gene and approximately 5 kb upstream of the transcription start site. In addition, the sites of Egr2 binding display many of the hallmarks associated with enhancer elements. Interestingly, the upstream Egr2 binding sites lie proximal to the divergently transcribed succinate dehydrogenase C gene, but Sdhc expression was not affected by the massive induction of Mpz mediated by Egr2. Mpz induction was greatly enhanced in the presence of the Egr2 binding sites, and removal of them markedly diminished transgenic expression of a construct derived from the Mpz locus. Sox10 was also found to be associated with the upstream region, and its binding was required for Egr2-mediated activation in this distal regulatory region. Our findings highlight that peripheral nerve-specific expression of Mpz is primarily regulated by both upstream and intron-associated regulatory elements. Overall, these results provide a locus-wide analysis of the role and activity of Egr2 in regulation of the Mpz gene within its native chromosomal context.

Identification of gene networks modulated by activin in LbetaT2 cells using DNA microarray analysis.

Activins, members of the TGFbeta family of proteins, are widely expressed in a variety of tissues. First identified based on their ability to regulate biosynthesis and secretion of follicle-stimulating hormone (FSH), activins have also been shown to modulate development, cell growth, apoptosis, and inflammation. Despite their many known functions, the precise mechanisms and downstream signaling pathways by which activins mediate their diverse effects remain unknown. We have used a DNA microarray assay to identify genes that are regulated by activin, alone or in combination with gonadotropin-releasing hormone (GnRH), another major regulator of FSH, in a murine gonadotrope-derived cell line (LbetaT2). We used mRNA from these cells to screen Affymetrix Mu74av2 mouse Gene Chip oligonucleotide microarrays, representing approximately 12,400 mouse genes. Treatment of LbetaT2 cells with activin A, a gonadotropin-releasing hormone agonist (GnRHA) or activin A plus GnRHA resulted in alterations in levels of gene expression that ranged in magnitude from 15 to 67-fold. Data analysis identified 268 transcripts that were up- or down-regulated by two-fold or more. Distinct sets of genes were affected by treatment with activin, GnRHA and activin plus GnRHA, suggesting interactions between activin and GnRHA. Changes in expression of seven randomly selected representative genes identified by the microarray technique were confirmed by real-time quantitative PCR and semi-quantitative reverse transcription/PCR (RT/PCR). Modulation of expression of genes by activin suggests that activin may mediate its effects through a variety of signaling pathways.