TGF‐β3–dependent SMAD2 phosphorylation and inhibition of MEE proliferation during palatal fusion

Cui, Xiao Mei; Chai, Yang; Chen, Jucheng; Yamamoto, Tadashi; Ito, Yoshihiro; Bringas, Pablo; Shuler, Charles F.

doi:10.1002/dvdy.10326

Cited by 58 publications

(53 citation statements)

References 28 publications

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“…4A) as a result of MEE seam formation (12 hr), then assume a similar expression level while approaching EMT (24 hr). Smad3 was determined to be absent in each stage (data not shown), confirming that in the palate system, Smad2 is the necessary R-Smad for EMT (Cui et al, 2003). Validation of the expression of Smad2, Smad3, Smad4, and LEF-1 was performed by means of reverse transcriptase-polymerase chain reaction (RT-PCR; Fig.…”

Section: The Tgf-␤ Signaling Pathwaymentioning

confidence: 60%

Microarray analysis of gene expression during epithelial–mesenchymal transformation

LaGamba

Nawshad

Hay

2005

Developmental Dynamics

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One of the most fundamental biological processes in development, as well as a primary mechanism for tumor metastasis, is epithelial-mesenchymal transformation (EMT). To gain a greater understanding of this transition, we have obtained a genomic profile of the critical stages before and during this rapid change in morphology in the developing mouse palate. By isolating the medial edge epithelium of each palatal shelf, we were able to obtain pure gene expression data without contamination from surrounding mesenchymal cells

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Section: The Tgf-␤ Signaling Pathwaymentioning

confidence: 60%

Microarray analysis of gene expression during epithelial–mesenchymal transformation

LaGamba

Nawshad

Hay

2005

Developmental Dynamics

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“…Further, the inhibition of TGF-␤3 results in a failure of plate fusion in vitro (Brunet et al, 1995), and the addition of TGF-␤3 to cultures of palatal shelves from TGF-␤3-deficient mice is able to reverse the phenotype completely (Kaartinen et al, 1997;Taya et al, 1999). TGF-␤3 also induces an epithelial-mesenchymal transdifferentiation of the MEE (Kaartinen et al, 1997;Sun et al, 1998), possibly by regulating the expression of MMPs (Blavier et al, 2001) and proteoglycans (Gato et al, 2002) by Smad2-dependent mechanisms (Cui et al, 2003). These findings have been confirmed recently by Dudas et al (2004), who showed that TGF-␤3-induced palatal fusion was mediated by the Alk-5/Smad pathway.…”

Section: (B) Palatogenesismentioning

confidence: 86%

TGF-β Signal Transduction in Oro-facial Health and Non-malignant Disease (Part I)

Prime

Pring

Davies

et al. 2004

Critical Reviews in Oral Biology & Medicine

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ABSTRACT:The transforming growth factor-beta (TGF-␤) family of cytokines consists of multi-functional polypeptides that regulate a variety of cell processes, including proliferation, differentiation, apoptosis, extracellular matrix elaboration, angiogenesis, and immune suppression, among others. In so doing, TGF-␤ plays a key role in the control of cell behavior in both health and disease. In this report, we review what is known about the mechanisms of activation of the peptide, together with details of TGF-␤ signal transduction pathways. This review summarizes the evidence implicating TGF-␤ in normal physiological processes of the craniofacial complex-such as palatogenesis, tooth formation, wound healing, and scarring-and then evaluates its role in non-malignant disease processes such as scleroderma, submucous fibrosis, periodontal disease, and lichen planus.

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“…Expression of one of the family members, transforming growth factor β 3 (TGFB3), is detected in the epithelial component of the vertical palatal shelf and peaks at day 14 to 14.5, just before immediate contact of the palatal shelves. Potential roles of TGFβ3 in palate formation have been demonstrated both in vitro (Sun and Vanderburg et al, 1998;Gato et al, 2002;Cui et al, 2003) and in vivo (Cui et al, 2003). Using a case-parent study design, Maestri el al.…”

Section: Transforming Growth Factor βmentioning

confidence: 99%

Review on genetic variants and maternal smoking in the etiology of oral clefts and other birth defects

Shi

Wehby

Murray

2008

Birth Defects Research Pt C

152

124

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A spectrum of adverse pregnancy outcomes, including preterm birth, low birth weight, and birth defects has been linked with maternal smoking during pregnancy. This article includes a review of studies investigating interactions between genetic variants and maternal smoking in contributing to birth defects using oral clefting as a model birth defect. The primary gene-smoking studies for other major birth defects are also summarized. Gene-environment interaction studies for birth defects are still at an early stage with several mixed results, but evolving research findings have begun to document clinically and developmentally important interactions. As samples and data become increasingly available, more effort is needed in designing innovative analytical methods to study gene-environment interactions.

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TGF‐β3–dependent SMAD2 phosphorylation and inhibition of MEE proliferation during palatal fusion

Cited by 58 publications

References 28 publications

Microarray analysis of gene expression during epithelial–mesenchymal transformation

Microarray analysis of gene expression during epithelial–mesenchymal transformation

TGF-β Signal Transduction in Oro-facial Health and Non-malignant Disease (Part I)

Review on genetic variants and maternal smoking in the etiology of oral clefts and other birth defects

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