Abstract
The homeobox transcription factor Mohawk (Mkx) is a potent transcriptional repressor expressed in the embryonic precursors of skeletal muscle, cartilage, and bone. MKX has recently been shown to be a critical regulator of musculoskeletal tissue differentiation and gene expression; however, the genetic pathways through which MKX functions and its DNA-binding properties are currently unknown. Using a modified bacterial one-hybrid site selection assay, we determined the core DNA-recognition motif of the mouse monomeric Mkx homeodomain to be A-C-A. Using cell-based assays, we have identified a minimal Mkx-responsive element (MRE) located within the Mkx promoter, which is composed of a highly conserved inverted repeat of the core Mkx recognition motif. Using the minimal MRE sequence, we have further identified conserved MREs within the locus of Sox6, a transcription factor that represses slow fiber gene expression during skeletal muscle differentiation. Real-time PCR and immunostaining of in vitro differentiated muscle satellite cells isolated from Mkx-null mice revealed an increase in the expression of Sox6 and down-regulation of slow fiber structural genes. Together, these data identify the unique DNA-recognition properties of MKX and reveal a novel role for Mkx in promoting slow fiber type specification during skeletal muscle differentiation.
Highlights
Mkx is a transcriptional repressor that regulates muscle and tendon differentiation
Mouse MKX shares the same recognition motif as previously characterized Irx family members but diverges from the recently reported binding site (T-n-A-C-A) of the Drosophila MKX ortholog, which has a strong affinity for a T at position 1 [11]
The Mkx homeobox gene has been shown to be an important regulator of skeletal muscle and tendon differentiation [5, 6]
Summary
Mkx is a transcriptional repressor that regulates muscle and tendon differentiation. Results: MKX binds to nnACA recognition sites as a homodimer. Conclusion: MKX has a novel DNA recognition mode and promotes slow muscle fiber type specification through Sox. Using the minimal MRE sequence, we have further identified conserved MREs within the locus of Sox, a transcription factor that represses slow fiber gene expression during skeletal muscle differentiation. Real-time PCR and immunostaining of in vitro differentiated muscle satellite cells isolated from Mkx-null mice revealed an increase in the expression of Sox and down-regulation of slow fiber structural genes. Together, these data identify the unique DNA-recognition properties of MKX and reveal a novel role for Mkx in promoting slow fiber type specification during skeletal muscle differentiation
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