Retinoic acid (RA) signaling plays an important role in determining the anterior boundary of Hox gene expression in the neural tube during embryogenesis. In particular, RA signaling is implicated in a rostral expansion of the neural expression domain of 5׳ Hoxb genes (Hoxb9-Hoxb5) in mice. However, underlying mechanisms for this gene regulation have remained elusive due to the lack of RA responsive element (RARE) in the 5׳ half of the HoxB cluster. To identify cis-regulatory elements required for the rostral expansion, we developed a recombineering technology to serially label multiple genes with different reporters in a single bacterial artificial chromosome (BAC) vector containing the mouse HoxB cluster. This allowed us to simultaneously monitor the expression of multiple genes. In contrast to plasmid-based reporters, transgenic BAC reporters faithfully recapitulated endogenous gene expression patterns of the Hoxb genes including the rostral expansion. Combined inactivation of two RAREs, DE-RARE and ENE-RARE, in the BAC completely abolished the rostral expansion of the 5׳ Hoxb genes. Knock-out of endogenous DE-RARE lead to significantly reduced expression of multiple Hoxb genes and attenuated Hox gene response to exogenous RA treatment in utero. Regulatory potential of DE-RARE was further demonstrated by its ability to anteriorize 5׳ Hoxa gene expression in the neural tube when inserted into a HoxA BAC reporter. Our data demonstrate that multiple RAREs cooperate to remotely regulate 5׳ Hoxb genes during CNS development, providing a new insight into the mechanisms for gene regulation within the Hox clusters.
Keywords: Central nervous system; Enhancer sharing; Enhancers; Gene regulation; Hox genes; Long-range regulation; Retinoids; Transgenic reporters.
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