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Project description:Double homeobox genes are unique to eutherian mammals, transiently expressed in early blastomere-stage embryos, and comprise 3 clades (DUXA, B, and C) evolved by homeodomain duplication and divergence from an ancestral single homeobox gene, sDUX, present in non-eutherian mammals and other vertebrates.  We test platypus sDUX and find that it drives cellular phenotypes identical to DUX4, the human DUXC gene, including cytotoxicity and inhibition of myogenic differentiation.  sDUX binds DNA as a head-to-head dimer, showing near overlap of protein core and DNA to the DUX4-DNA crystal structure.  DUXA and sDUX bind both palindromic and nonpalindromic TAAT/TGAT double homeodomain motifs against DUX4 preference for non-palindromic.  Although DUXA lacks transcriptional activation potential, we find significant similarities in transcriptional and chromatin profiles of sDUX with DUX4 and DUXA-VP64, including expression of ZGA genes and LTR elements.  Furthermore, DUXA binds to a significant fraction of DUX4 target sites and is able to counteract transcriptional activation of DUX4 on its targets, potentiating a feedback inhibitory loop, including in cells from patients with facioscapulohumeral muscular dystrophy (FSHD).  The DUX gene family therefore comprises cross-regulating members of opposing function, with implications for their roles in ZGA, FSHD, and cancer.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description: Not available

Project description:Double homeobox genes are unique to eutherian mammals, transiently expressed in early blastomere-stage embryos, and comprise 3 clades (DUXA, B, C) evolved by homeobox duplication and divergence from an ancestral single homeobox gene, sDUX, present in other vertebrates. We test platypus sDUX and find that it drives cytotoxicity and inhibition of myogenesis identical to DUX4, the human DUXC gene. sDUX binds DNA as a head-to-head dimer, with protein core and DNA nearly overlapping the DUX4-DNA crystal structure. Although DUXA lacks transcriptional activity, DUXA-VP64 transcriptome and chromatin accessibility profiles significantly overlap those of DUX4 and sDUX, including expression of ZGA genes and LTR elements. Furthermore, DUXA binds DUX4 sites at most DUX4 target genes and counteracts transcriptional activity of DUX4, including in FSHD patient cells, potentiating a feedback inhibitory loop. The DUX gene family therefore comprises cross-regulating members of opposing function, with implications for their roles in ZGA, FSHD, and cancer.

Project description:Double homeobox genes are unique to eutherian mammals, transiently expressed in early blastomere-stage embryos, and comprise 3 clades (DUXA, B, C) evolved by homeobox duplication and divergence from an ancestral single homeobox gene, sDUX, present in other vertebrates. We test platypus sDUX and find that it drives cytotoxicity and inhibition of myogenesis identical to DUX4, the human DUXC gene. sDUX binds DNA as a head-to-head dimer, with protein core and DNA nearly overlapping the DUX4-DNA crystal structure. Although DUXA lacks transcriptional activity, DUXA-VP64 transcriptome and chromatin accessibility profiles significantly overlap those of DUX4 and sDUX, including expression of ZGA genes and LTR elements. Furthermore, DUXA binds DUX4 sites at most DUX4 target genes and counteracts transcriptional activity of DUX4, including in FSHD patient cells, potentiating a feedback inhibitory loop. The DUX gene family therefore comprises cross-regulating members of opposing function, with implications for their roles in ZGA, FSHD, and cancer.