ABSTRACT
Differentiation of osteoblasts from mesenchymal stem cells (MSCs) is an integral part of bone development and homeostasis, and may when improperly regulated cause disease such as bone cancer or osteoporosis. Using unbiased high-throughput methods we here characterize the landscape of global changes in gene expression, histone modifications, and DNA methylation upon differentiation of human MSCs to the osteogenic lineage. Furthermore, we provide a first genome-wide characterization of DNA binding sites of the bone master regulatory transcription factor Runt-related transcription factor 2 (RUNX2) in human osteoblasts, revealing target genes associated with regulation of proliferation, migration, apoptosis, and with a significant overlap with p53 regulated genes. These findings expand on emerging evidence of a role for RUNX2 in cancer, including bone metastases, and the p53 regulatory network. We further demonstrate that RUNX2 binds to distant regulatory elements, promoters, and with high frequency to gene 3' ends. Finally, we identify TEAD2 and GTF2I as novel regulators of osteogenesis.
Subject(s)
Cell Differentiation/genetics , Osteogenesis/genetics , Alternative Splicing/genetics , Base Sequence , Binding Sites , Cell Lineage/genetics , Chromatin/metabolism , Core Binding Factor Alpha 1 Subunit/genetics , Core Binding Factor Alpha 1 Subunit/metabolism , Epigenesis, Genetic , Genome, Human/genetics , Humans , Mesenchymal Stem Cells/cytology , Molecular Sequence Data , RNA, Messenger/genetics , RNA, Messenger/metabolismABSTRACT
The Gli proteins are the transcriptional effectors of the mammalian Hedgehog signaling pathway. In an unusual mechanism, the proteasome partially degrades or processes Gli3 in the absence of Hedgehog pathway stimulation to create a Gli3 fragment that opposes the activity of the full-length protein. In contrast, Gli1 is not processed but degraded completely, despite considerable homology with Gli3. We found that these differences in processing can be described by defining a processing signal that is composed of three parts: the zinc finger domain, an adjacent linker sequence, and a degron. Gli3 processing is inhibited when any one component of the processing signal is disrupted. We show that the zinc fingers are required for processing only as a folded structure and that the location but not the identity of the processing degron is critical. Within the linker sequence, regions of low sequence complexity play a crucial role, but other sequence features are also important. Gli1 is not processed because two components of the processing signal, the linker sequence and the degron, are ineffective. These findings provide new insights into the molecular elements that regulate Gli protein processing by the proteasome.
Subject(s)
Kruppel-Like Transcription Factors/metabolism , Nerve Tissue Proteins/metabolism , Proteasome Endopeptidase Complex/metabolism , Protein Processing, Post-Translational/physiology , Proteolysis , Signal Transduction/physiology , Transcription Factors/metabolism , HEK293 Cells , Humans , Proteasome Endopeptidase Complex/genetics , Transcription Factors/genetics , Zinc Finger Protein GLI1 , Zinc Finger Protein Gli3 , Zinc FingersABSTRACT
Protein degradation plays a central role in many cellular functions. Misfolded and damaged proteins are removed from the cell to avoid toxicity. The concentrations of regulatory proteins are adjusted by degradation at the appropriate time. Both foreign and native proteins are digested into small peptides as part of the adaptive immune response. In eukaryotic cells, an ATP-dependent protease called the proteasome is responsible for much of this proteolysis. Proteins are targeted for proteasomal degradation by a two-part degron, which consists of a proteasome binding signal and a degradation initiation site. Here we describe how both components contribute to the specificity of degradation.
