RUNX2

86012393ENSG00000124813ENSMUSG00000039153Q13950Q08775NM_001015051NM_001024630NM_001278478NM_004348NM_001369405NM_001271633NM_009820NP_001015051NP_001019801NP_001265407NP_001356334NP_033950Runt-related transcription factor 2 (RUNX2) also known as core-binding factor subunit alpha-1 (CBF-alpha-1) is a protein that in humans is encoded by the RUNX2 gene. RUNX2 is a key transcription factor associated with osteoblast differentiation.1cmo: IMMUNOGLOBULIN MOTIF DNA-RECOGNITION AND HETERODIMERIZATION FOR THE PEBP2/CBF RUNT-DOMAIN1co1: FOLD OF THE CBFA1e50: AML1/CBF COMPLEX1h9d: AML1/CBF-BETA/DNA COMPLEX1hjb: CRYSTAL STRUCTURE OF RUNX-1/AML1/CBFALPHA RUNT DOMAIN AND C/EBPBETA BZIP DIMERIC BOUND TO A DNA FRAGMENT FROM THE CSF-1R PROMOTER1hjc: CRYSTAL STRUCTURE OF RUNX-1/AML1/CBFALPHA RUNT DOMAIN BOUND TO A DNA FRAGMENT FROM THE CSF-1R PROMOTER1io4: CRYSTAL STRUCTURE OF RUNX-1/AML1/CBFALPHA RUNT DOMAIN-CBFBETA CORE DOMAIN HETERODIMER AND C/EBPBETA BZIP HOMODIMER BOUND TO A DNA FRAGMENT FROM THE CSF-1R PROMOTER1ljm: DNA recognition is mediated by conformational transition and by DNA bending Runt-related transcription factor 2 (RUNX2) also known as core-binding factor subunit alpha-1 (CBF-alpha-1) is a protein that in humans is encoded by the RUNX2 gene. RUNX2 is a key transcription factor associated with osteoblast differentiation. It has also been suggested that Runx2 plays a cell proliferation regulatory role in cell cycle entry and exit in osteoblasts, as well as endothelial cells. Runx2 suppresses pre-osteoblast proliferation by affecting cell cycle progression in the G1 phase. In osteoblasts, the levels of Runx2 is highest in G1 phase and is lowest in S, G2, and M. The comprehensive cell cycle regulatory mechanisms that Runx2 may play are still unknown, although it is generally accepted that the varying activity and levels of Runx2 throughout the cell cycle contribute to cell cycle entry and exit, as well as cell cycle progression. These functions are especially important when discussing bone cancer, particularly osteosarcoma development, that can be attributed to aberrant cell proliferation control. This protein is a member of the RUNX family of transcription factors and has a Runt DNA-binding domain. It is essential for osteoblastic differentiation and skeletal morphogenesis. It acts as a scaffold for nucleic acids and regulatory factors involved in skeletal gene expression. The protein can bind DNA both as a monomer or, with more affinity, as a subunit of a heterodimeric complex. Transcript variants of the gene that encode different protein isoforms result from the use of alternate promoters as well as alternate splicing. The cellular dynamics of Runx2 protein are also important for proper osteoblast differentiation. Runx2 protein is detected in preosteoblasts and the expression is upregulated in immature osteoblasts and downregulated in mature osteoblasts. It is the first transcription factor required for determination of osteoblast commitment, followed by Sp7 and Wnt-signaling. Runx2 is responsible for inducing the differentiation of multipotent mesenchymal cells into immature osteoblasts, as well as activating expression of several key downstream proteins that maintain osteoblast differentiation and bone matrix genes. Knock-out of the DNA-binding activity results in inhibition of osteoblastic differentiation. Because of this, Runx2 is often referred to as the master regulator of bone. In addition to being the master regulator of osteoblast differentiation, Runx2 has also been shown to play several roles in cell cycle regulation. This is due, in part, to the fact that Runx2 interacts with many cellular proliferation genes on a transcription level, such as c-Myb and C/EBP, as well as p53/ These functions are critical for osteoblast proliferation and maintenance. This is often controlled via oscillating levels of Runx2 within throughout cell cycle due to regulated degradation and transcriptional activity. Oscillating levels of Runx2 within the cell contribute to cell cycle dynamics. In the MC3T3-E1 osteoblast cell line, Runx2 levels are a maximum during G1 and a minimum during G2, S, and mitosis. In addition, the oscillations in Runx2 contribute to G1-related anti-proliferative function. It has also been proposed that decreasing levels of Runx2 leads to cell cycle exit for proliferating and differentiating osteoblasts, and that Runx2 plays a role in mediating the final stages of osteoblast via this mechanism. Current research posits that the levels of Runx2 serve various functions. In addition, Runx2 has been shown to interact with several kinases that contribute to facilitate cell-cycle dependent dynamics via direct protein phosphorylation. Furthermore, Runx2 controls the gene expression of cyclin D2, D3, and the CDK inhibitor p21(cip1) in hematopoietic cells. It has been shown that on a molecular level, Runx associates with the cdc2 partner cyclin B1 during mitosis. The phosphorylation state of Runx2 also mediates it’s DNA-binding activity. The Runx2 DNA-binding activity is correlated with cellular proliferation, which suggests Runx2 phosphorylation may also be related to Runx2-mediated cellular proliferation and cell cycle control. To support this, it has been noted that Runx is phosphorylated at Ser451 by cdc2 kinase, which facilitates cell cycle progression through the regulation of G2 and M phases. Mutations in Runx2 are associated with the disease Cleidocranial dysostosis. One study proposes that this phenotype arises partly due to the Runx2 dosage insufficiencies. Because Runx2 promotes exit from the cell cycle, insufficient amounts of Runx2 are related to increased proliferation of osteoblasts observed in patients with cleodocranial disostosis.