Structural coupling of Smad and Runx2 for execution of the BMP2 osteogenic signal.
about
A microRNA signature for a BMP2-induced osteoblast lineage commitment programPotential mechanisms underlying the Runx2 induced osteogenesis of bone marrow mesenchymal stem cellsA pathway to bone: signaling molecules and transcription factors involved in chondrocyte development and maturationRegulation of gene expression in osteoblasts.MicroRNAs regulate bone development and regenerationProspects for osteoprogenitor stem cells in fracture repair and osteoporosisF-spondin deficient mice have a high bone mass phenotype.Definitive hematopoiesis requires Runx1 C-terminal-mediated subnuclear targeting and transactivation.Transforming growth factor-beta regulates basal transcriptional regulatory machinery to control cell proliferation and differentiation in cranial neural crest-derived osteoprogenitor cells.Novel links among Wnt and TGF-beta signaling and Runx2.Melanin extract from Gallus gallus domesticus promotes proliferation and differentiation of osteoblastic MG-63 cells via bone morphogenetic protein-2 signaling.A role for age-related changes in TGFbeta signaling in aberrant chondrocyte differentiation and osteoarthritisRunt-related transcription factors impair activin induction of the follicle-stimulating hormone {beta}-subunit gene.The osteogenic transcription factor Runx2 regulates components of the fibroblast growth factor/proteoglycan signaling axis in osteoblastsGenetic and transcriptional control of bone formationThe cancer-related Runx2 protein enhances cell growth and responses to androgen and TGFbeta in prostate cancer cells.Metastatic bone disease: role of transcription factors and future targets.Calcium-mediated stress kinase activation by DMP1 promotes osteoblast differentiation.Immortalized mouse floxed Bmp2 dental papilla mesenchymal cell lines preserve odontoblastic phenotype and respond to BMP2.The Role of RUNX2 in Osteosarcoma Oncogenesis.Development and characterization of a mouse floxed Bmp2 osteoblast cell line that retains osteoblast genotype and phenotype.Integration of multiple signaling regulates through apoptosis the differential osteogenic potential of neural crest-derived and mesoderm-derived OsteoblastsLoss of Runx2 in committed osteoblasts impairs postnatal skeletogenesis.Runx2-Smad signaling impacts the progression of tumor-induced bone disease1alpha,25-dihydroxy vitamin D(3) induces nuclear matrix association of the 1alpha,25-dihydroxy vitamin D(3) receptor in osteoblasts independently of its ability to bind DNANell-1, a key functional mediator of Runx2, partially rescues calvarial defects in Runx2(+/-) mice.Age-dependent alteration of TGF-β signalling in osteoarthritis.Calvarial cleidocraniodysplasia-like defects with ENU-induced Nell-1 deficiency.Expression of the IL-11 Gene in Metastatic Cells Is Supported by Runx2-Smad and Runx2-cJun Complexes Induced by TGFβ1Runx2 regulates endochondral ossification through control of chondrocyte proliferation and differentiation.Orphan nuclear receptor chicken ovalbumin upstream promoter-transcription factor II (COUP-TFII) protein negatively regulates bone morphogenetic protein 2-induced osteoblast differentiation through suppressing runt-related gene 2 (Runx2) activity.Do epigenetic marks govern bone mass and homeostasis?Signaling networks that control the lineage commitment and differentiation of bone cells.Dysregulation of Mitochondrial Functions and Osteogenic Differentiation in Cisd2-Deficient Murine Induced Pluripotent Stem CellsBioreactors to influence stem cell fate: augmentation of mesenchymal stem cell signaling pathways via dynamic culture systems.Enhancement of osteogenic differentiation of rat adipose tissue-derived mesenchymal stem cells by zinc sulphate under electromagnetic field via the PKA, ERK1/2 and Wnt/β-catenin signaling pathways.MicroRNA control of bone formation and homeostasis.Establishment of Immortalized BMP2/4 Double Knock-Out Osteoblastic Cells Is Essential for Study of Osteoblast Growth, Differentiation, and OsteogenesisIntegration of multiple signaling pathways determines differences in the osteogenic potential and tissue regeneration of neural crest-derived and mesoderm-derived calvarial bonesBiglycan induces the expression of osteogenic factors in human aortic valve interstitial cells via Toll-like receptor-2.
P2860
Q24647487-F17ACB27-74C1-45E8-8AB5-9FD97B87B8A1Q26765276-7673CDC4-2978-460F-89A3-38194B3E32B3Q26995910-BD0C816F-55D9-4949-830A-D6C8AF82327DQ27691363-45889941-6B01-4139-A123-2431E1C7481FQ28081746-5943BE6B-EB60-47FB-ABEA-B10112C9AED3Q30431697-869F2B84-1B11-4B2F-BA35-2E42AA19F00AQ33686140-EC494735-523A-4B45-92DA-26B94A01EAFBQ33697682-81CEF019-5420-44A5-A3D3-CBA7D443AC89Q33717696-DEF51BC5-8517-4F14-9EE1-ED3C2322A7F4Q33735960-ABA06CCF-6E96-4EFD-9E70-102F3C1581F1Q33740287-16DCA98B-78CA-41A2-9109-AE75C1210BC7Q33873604-F914310E-22E0-4046-A4E5-8F07DA3BD7A0Q33874427-8F84C2A4-F3D9-4113-926C-208C75A8CDBEQ34052909-306E4527-433E-46B8-A8FB-72C550A407B1Q34073161-25D775E9-3F99-44C4-98DC-F57F50A03121Q34078444-883715E7-8ED9-4940-9B06-401872080F7CQ34217531-23D70989-C591-42C6-88FB-576B519EA33DQ34298989-41BA394E-8626-4CCC-8F4D-1773EC861BF5Q34307426-AD0F223E-5274-4AED-96C9-F39F70DCA096Q34423871-E9C16C78-30EE-4544-BA10-4FDADFE158BEQ34630345-EFF72ABE-0AF4-421C-B59F-5C683BBBADBFQ34639253-4F94B7CD-16A5-433A-B24B-7C9B38182ED7Q34790965-90B8E01B-CEFA-431F-AC26-340085ADBDF0Q34898865-54DE9A4A-E275-48AA-833C-ED6285251120Q35021003-86F3F52B-4FC5-488D-8535-4A6AECC3CDBCQ35229979-6D9497A5-1EE9-4FB3-A661-77FFDEC780BFQ35649296-496F9379-FBD9-4134-B01C-9A19697A20ABQ35764174-CD0309D7-7B87-45F2-9C52-CD67729676DBQ35889495-08583C8F-5644-4392-BBD3-E8A607FEEE00Q35949809-526B5A64-7BF5-4064-8E3A-5D6FEF70A541Q36003602-32985B01-26AA-4886-80B5-B872C704266CQ36055881-A25A2D2C-9183-4BD6-8028-A64FFE1E6712Q36082866-508EC960-E84D-46ED-93C5-21BDEDC086BEQ36206064-187DB1AA-0E39-4DD7-A44F-B5F4F4B19FF5Q36287687-9970BDF4-6446-4EEA-B8EA-B5286674E0BBQ36322162-315DE1F6-8925-4FF7-8371-DE3EA617E8FAQ36661323-496789DA-72CC-40B1-9D3A-756270DED62FQ36667569-6CF97F88-D433-4262-8C3B-CADBB482DB47Q36790379-F23E25AB-FA76-4CD1-A66D-979FD11DD5F8Q36880524-F4B565D5-1137-42F6-8A72-CB60D2D8F461
P2860
Structural coupling of Smad and Runx2 for execution of the BMP2 osteogenic signal.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh
2008年學術文章
@zh-hant
name
Structural coupling of Smad and Runx2 for execution of the BMP2 osteogenic signal.
@en
type
label
Structural coupling of Smad and Runx2 for execution of the BMP2 osteogenic signal.
@en
prefLabel
Structural coupling of Smad and Runx2 for execution of the BMP2 osteogenic signal.
@en
P2093
P2860
P356
P1476
Structural coupling of Smad and Runx2 for execution of the BMP2 osteogenic signal
@en
P2093
Andre J van Wijnen
Faiza Afzal
Gary S Stein
Jane B Lian
Janet L Stein
Jitesh Pratap
Jong-Sup Bae
Soraya Gutierrez
P2860
P304
P356
10.1074/JBC.M705578200
P407
P577
2008-01-18T00:00:00Z