The zebrafish egr1 gene encodes a highly conserved, zinc-finger transcriptional regulator

Transcriptional regulation of the murine Presenilin-2 gene reveals similarities and differences to its human orthologue

Inherited Presenilin-2 mutations cause familial Alzheimer's disease, and its regulation may play a role in sporadic cases. The human Presenilin-2 (PSEN2) regulatory region includes two separate promoters modulated by Egr-1, a transcription factor involved in learning and memory. To enable in-vivo analysis of Presenilin-2 regulation, we characterized the murine Presenilin-2 (Psen2) promoter. We identified novel Psen2 Transcription start sites (TSSs) 10 kb upstream of previously reported sites, along with two new alternatively transcribed exons (1A, and 1BC) in the 5' untranslated region. Transcripts initiating in Exon 1A are ubiquitous, whereas exon 1BC-initiated transcripts are non-neuronal. Only the sequence surrounding exon 1A, which includes homologous sequences to the human PSEN2 promoter, harbored significant promoter activity. Sequences upstream of exon 1A and a downstream enhancer were specifically important in neuronal cells, but similar to the human promoter, the murine promoter was characteristic of a housekeeping gene, and its activity depended on Sp1 binding. Egr-1 did not bind the murine promoter. Egr-1 over-expression and down-regulation, as well as in-vivo examination of Egr-1 and Psen2 expression during fear conditioning in mice, showed that Egr-1 does not regulate the murine Psen2 promoter. Differential Psen2 regulation in human and mouse has implications for Alzheimer disease mouse models.

The Spemann organizer-expressed zinc finger gene Xegr-1 responds to the MAP kinase/Ets-SRF signal transduction pathway

The transcriptional activity of a set of genes, which are all expressed in overlapping spatial and temporal patterns within the Spemann organizer of Xenopus embryos, can be modulated by peptide growth factors. We identify Xegr-1, a zinc finger protein-encoding gene, as a novel member of this group of genes. The spatial expression characteristics of Xegr-1 during gastrulation are most similar to those of Xbra. Making use of animal cap explants, analysis of the regulatory events that govern induction of Xegr-1 gene activity reveals that, in sharp contrast to transcriptional regulation of Xbra, activation of Ets-serum response factor (SRF) transcription factor complexes is required and sufficient for Xegr-1 gene expression. This finding provides the first indication for Ets-SRF complexes bound to serum response elements to be activated during gastrulation. MAP kinase signalling cascades can induce and sustain expression of both Xegr-1 and Xbra. Ectopic Xbra can induce Xegr-1 transcription by an indirect mechanism that appears to operate via primary activation of fibroblast growth factor secretion. These findings define a cascade of events that links Xbra activity to the signal-regulated control of Xegr-1 transcription in the context of early mesoderm induction in Xenopus laevis.