Abstract

The mammalian <i>HoxD</i> cluster lies between two topologically associating domains (TADs) matching distinct enhancer-rich regulatory landscapes. During limb development, the telomeric TAD controls the early transcription of <i>Hoxd</i> genes in forearm cells, whereas the centromeric TAD subsequently regulates more posterior <i>Hoxd</i> genes in digit cells. Therefore, the TAD boundary prevents the terminal <i>Hoxd13</i> gene from responding to forearm enhancers, thereby allowing proper limb patterning. To assess the nature and function of this CTCF-rich DNA region in embryos<i>,</i> we compared chromatin interaction profiles between proximal and distal limb bud cells isolated from mutant stocks where various parts of this boundary region were removed. The resulting progressive release in boundary effect triggered inter-TAD contacts, favored by the activity of the newly accessed enhancers. However, the boundary was highly resilient, and only a 400-kb deletion, including the whole-gene cluster, was eventually able to merge the neighboring TADs into a single structure. In this unified TAD, both proximal and distal limb enhancers nevertheless continued to work independently over a targeted transgenic reporter construct. We propose that the whole <i>HoxD</i> cluster is a dynamic TAD border and that the exact boundary position varies depending on both the transcriptional status and the developmental context.