Abstract
BackgroundHigher brain function is supported by the precise temporal and spatial regulation of thousands of genes. The mechanisms that underlie transcriptional regulation in the brain, however, remain unclear. The Ntng1 and Ntng2 genes, encoding axonal membrane adhesion proteins netrin-G1 and netrin-G2, respectively, are paralogs that have evolved in vertebrates and are expressed in distinct neuronal subsets in a complementary manner. The characteristic expression patterns of these genes provide a part of the foundation of the cortical layer structure in mammals.ResultsWe used gene-targeting techniques, bacterial artificial chromosome (BAC)-aided transgenesis techniques, and in vivo enhancer assays to examine transcriptional mechanisms in vivo to gain insight into how the characteristic expression patterns of these genes are acquired. Analysis of the gene expression patterns in the presence or absence of netrin-G1 and netrin-G2 functional proteins allowed us to exclude the possibility that a feedback or feedforward mechanism mediates their characteristic expression patterns. Findings from the BAC deletion series revealed that widely distributed combinations of cis-regulatory elements determine the differential gene expression patterns of these genes and that major cis-regulatory elements are located in the 85–45 kb upstream region of Ntng2 and in the 75–60 kb upstream region and intronic region of Ntng1. In vivo enhancer assays using 2-kb evolutionarily conserved regions detected enhancer activity in the distal upstream regions of both genes.ConclusionsThe complementary expression patterns of Ntng1 and Ntng2 are determined by transcriptional cis-regulatory elements widely scattered in these loci. The cis-regulatory elements characterized in this study will facilitate the development of novel genetic tools for functionally dissecting neural circuits to better understand vertebrate brain function.
Highlights
Higher brain function is supported by the precise temporal and spatial regulation of thousands of genes
Elucidation of the transcriptional mechanisms that regulate the complementary expression of Ntng1 and Ntng2 will help to clarify the mechanisms of vertebrate-specific neural circuit formation and function, and will act as a springboard for novel cutting-edge research designed to gain a better understanding of the basis of higher brain function in vertebrates
E.coli beta-galactosidase (LacZ)-KI mice exhibit complementary expression patterns of Ntng1 and Ntng2 To investigate the spatial distribution of Ntng1 and Ntng2 expression in detail, we generated Ntng1- and Ntng2LacZ-KI mice. These mice carry LacZ fused with a nuclear localization signal and an SV40 polyadenylation signal (NLS-LacZ-Polyadenylation signal (pA)) in-frame in exon 2 of the Ntng1 or Ntng2 gene, and the transcriptional activities of these genes can be monitored by examining LacZ activity at a single cell resolution
Summary
Higher brain function is supported by the precise temporal and spatial regulation of thousands of genes. The Ntng and Ntng genes, encoding axonal membrane adhesion proteins netrin-G1 and netrin-G2, respectively, are paralogs that have evolved in vertebrates and are expressed in distinct neuronal subsets in a complementary manner. Development and function of neural circuits in the vertebrate brain are supported by the orchestration of the spatial and temporal expression of genes in the brain. Elucidation of the transcriptional mechanisms that regulate the complementary expression of Ntng and Ntng will help to clarify the mechanisms of vertebrate-specific neural circuit formation and function, and will act as a springboard for novel cutting-edge research designed to gain a better understanding of the basis of higher brain function in vertebrates
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