Abstract
Hox genes in species across the metazoa encode transcription factors (TFs) containing highly-conserved homeodomains that bind target DNA sequences to regulate batteries of developmental target genes. DNA-bound Hox proteins, together with other TF partners, induce an appropriate transcriptional response by RNA Polymerase II (PolII) and its associated general transcription factors. How the evolutionarily conserved Hox TFs interface with this general machinery to generate finely regulated transcriptional responses remains obscure. One major component of the PolII machinery, the Mediator (MED) transcription complex, is composed of roughly 30 protein subunits organized in modules that bridge the PolII enzyme to DNA-bound TFs. Here, we investigate the physical and functional interplay between Drosophila melanogaster Hox developmental TFs and MED complex proteins. We find that the Med19 subunit directly binds Hox homeodomains, in vitro and in vivo. Loss-of-function Med19 mutations act as dose-sensitive genetic modifiers that synergistically modulate Hox-directed developmental outcomes. Using clonal analysis, we identify a role for Med19 in Hox-dependent target gene activation. We identify a conserved, animal-specific motif that is required for Med19 homeodomain binding, and for activation of a specific Ultrabithorax target. These results provide the first direct molecular link between Hox homeodomain proteins and the general PolII machinery. They support a role for Med19 as a PolII holoenzyme-embedded “co-factor” that acts together with Hox proteins through their homeodomains in regulated developmental transcription.
Highlights
The finely regulated gene transcription permitting development of pluricellular organisms involves the action of transcription factors (TFs) that bind DNA targets and convey this information to RNA polymerase II (PolII)
This occurs at the level of transcription of target gene DNA to messenger RNA by RNA polymerase II and its associated protein machinery (.50 proteins)
We provide an initial response, finding that Hox proteins use their homeodomains to bind one machinery protein, Mediator complex subunit 19 (Med19) through a Med19 sequence that is highly conserved in animal phyla
Summary
The finely regulated gene transcription permitting development of pluricellular organisms involves the action of transcription factors (TFs) that bind DNA targets and convey this information to RNA polymerase II (PolII). Animal orthologs of the Drosophila proteins make use of their homeodomains to play widespread and crucial roles in differentiation programs yielding the very different forms of sea urchins, worms, flies or humans [8] They do so by binding simple TAAT-based sequences within regulatory DNA of developmental target genes [9,10,11,12,13,14]. Known examples include the TALE HD proteins encoded by extradenticle (exd)/Pbx and homothorax (hth)/ Meis, which assist Hox proteins to form stable ternary DNAprotein complexes with much-enhanced specificity This involves contacts with the conserved Hox Hexapeptide (HX) motif near the HD N-terminus, or alternatively, with the paralog-specific UBD-A motif detected in Ubx and Abdominal-A (Abd-A) proteins [15,16]. Other TFs that can serve as positional Hox partners include the segment-polarity gene products Engrailed (En) and Sloppy paired, that collaborate with Ubx and Abd-A to repress abdominal
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