Heart and Liver Defects and Reduced Transforming Growth Factor β2 Sensitivity in Transforming Growth Factor β Type III Receptor-Deficient Embryos

Stenvers, Kaye L.; Tursky, Melinda L.; Harder, Kenneth W.; Kountouri, Nicole; Amatayakul-Chantler, Supavadee; Grail, Dianne; Small, Clayton; Weinberg, Robert A.; Sizeland, Andrew; Zhu, Hong

doi:10.1128/mcb.23.12.4371-4385.2003

Cited by 219 publications

(184 citation statements)

References 61 publications

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“…Alternatively, it is also formally possible that the high frequency of VSDs in these mutants may be a secondary consequence of cerebral haemorrhage leading to reduced blood flow that might, in turn, affect maturation of the heart. On the other hand, a primary defect caused by reduced TGFb signalling in the heart would be consistent with the increased frequency of VSDs seen in embryos that are non-haemorrhagic, but are deficient in betaglycan, an auxiliary receptor that promotes TGFb2 signalling (Stenvers et al, 2003;Compton et al, 2007). In one of these studies, Betaglycan null embryos died at E14, which was thought to be a result of lack of coronary vessels (Compton et al, 2007).…”

Section: (Asterisk) Efmentioning

confidence: 64%

The TGFβ type II receptor plays a critical role in the endothelial cells during cardiac development

Robson

Allinson

Anderson

et al. 2010

Developmental Dynamics

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TGFb signalling is required for normal cardiac development. To investigate which cell types are involved, we used mice carrying a floxed Type II TGFb receptor (Tgfbr2fl) allele and Cre-lox genetics to deplete this receptor in different regions of the heart. The three target tissues and corresponding Cre transgenic lines were atrioventricular myocardium (using cGata6-Cre), ventricular myocardium (using Mlc2v-Cre), and vascular endothelium (using tamoxifen-activated Cdh5(PAC)-CreERT2). Spatio-temporal Cre activity in each case was tracked via lacZ activation from the Rosa26R locus. Atrioventricular-myocardial-specific Tgfbr2 knockout (KO) embryos had short septal leaflets of the tricuspid valve, whereas ventricular myocardial-specific KO embryos mainly exhibited a normal cardiac phenotype. Inactivation of Tgfbr2 in endothelial cells from E11.5 resulted in deficient ventricular septation, accompanied by haemorrhage from cerebral blood vessels. We conclude that TGFb signalling through the Tgfbr2 receptor, in endothelial cells, plays an important role in cardiac development, and is essential for cerebral vascular integrity. Developmental Dynamics 239:2435-2442,

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Section: (Asterisk) Efmentioning

confidence: 64%

The TGFβ type II receptor plays a critical role in the endothelial cells during cardiac development

Robson

Allinson

Anderson

et al. 2010

Developmental Dynamics

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“…(Costell et al, 1999) Tenascin C Extracellular matrix Total NC cells fail to disperse laterally (Tucker, 2001) Laminin γ1 Extracellular matrix Total Death at E5.5, lack of basement membranes (Smyth et al, 1999) Laminin β2 Extracellular matrix Total Postnatal death between P15-30, neuromuscular junctions and glomerular defects (Noakes et al, 1995a;Noakes et al, 1995b;Patton et al, 1997) Laminin α2 Extracellular matrix Total Death by 5 weeks postnatal, severe muscular dystrophy and peripheral neurophathy (Miyagoe et al, 1997) Laminin α2 (dy/dy) Extracellular matrix Spontaneous Adult lethality, severe muscular dystrophy and peripheral nerve dysmyelination (Patton et al, 1999;Patton et al, 1997) Laminin α3 Extracellular matrix Total Death at P2-3, epithelial adhesion defect (Ryan et al, 1999) Laminin α4 Extracellular matrix Total Transient microvascular defect with hemorrhages and misalignment of neuromuscular junctions (Patton et al, 2001;Thyboll et al, 2002) Laminin α5 Extracellular matrix Total Death at E14-E17, with placental vessel, neural (Miner et al, 1998;Miner and Li, 2000) Protein Function Type Phenotype Reference tube, limb, and kidney defects Fibronectin Extracellular matrix Total Death before E14.5, shortened anterior-posterior axes, deformed neural tubes, and defects in mesodermally derived tissues. (George et al, 1993) Collagen XVIII Extracellular matrix Total Eye abnormalities modeling Knoblock syndrome (Fukai et al, 2002) Extracellular matrix Total Basement membrane defects (Utriainen et al, 2004) Collagen XV Extracellular matrix Total Skeletal myopathy and cardiovascular defects (Eklund et al, 2001) betaglycan Extracellular matrix Total Embryonic lethality of heart and liver defects (Stenvers et al, 2003) Connexin 43 Cell-cell adhesion In vitro studies of cells from knockout mice…”

Section: Note On Nomenclaturementioning

confidence: 99%

Cell biology of embryonic migration

Kurosaka¹,

Kashina²

2008

Birth Defects Research Pt C

111

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Cell migration is an evolutionarily conserved mechanism that underlies the development and functioning of uni-and multicellular organisms and takes place in normal and pathogenic processes, including various events of embryogenesis, wound healing, immune response, cancer metastases, and angiogenesis. Despite the differences in the cell types that take part in different migratory events, it is believed that all of these migrations occur by similar molecular mechanisms, whose major components have been functionally conserved in evolution and whose perturbation leads to severe developmental defects. These mechanisms involve intricate cytoskeleton-based molecular machines that can sense the environment, respond to signals, and modulate the entire cell behavior. A big question that has concerned the researchers for decades relates to the coordination of cell migration in situ and its relation to the intracellular aspects of the cell migratory mechanisms. Traditionally, this question has been addressed by researchers that considered the intra-and extracellular mechanisms driving migration in separate sets of studies. As more data accumulate researchers are now able to integrate all of the available information and consider the intracellular mechanisms of cell migration in the context of the developing organisms that contain additional levels of complexity provided by extracellular regulation. This review provides a broad summary of the existing and emerging data in the cell and developmental biology fields regarding cell migration during development.

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“…Betaglycan-deficient mouse embryo fibroblasts show reduced Smad2 nuclear translocation and reduced growth suppression in response to TGF-b2 stimulation, but not in response to TGF-b1 and TGF-b3 (Stenvers et al 2003). Betaglycan also binds and promotes signaling by inhibin (Lewis et al 2000;Wiater et al 2006) and BMPs (Kirkbride et al 2008;Lee et al 2009).…”

Section: Betaglycan/tbriiimentioning

confidence: 99%

“…Knockout of the betaglycan gene results in embryonic lethality (Stenvers et al 2003); betaglycan has been shown to interact with the scaffolding protein arrestin and thereby activate Cdc42 and inhibit cell migration (Mythreye and Blobe 2009) and to promote neuronal differentiation by interacting with fibroblast growth factor 2 (FGF-2) and FGF receptor 1 (Knelson et al 2013). Betaglycan has also been shown to affect TbRI and TbRII trafficking and signaling (see further below).…”

Section: Betaglycan/tbriiimentioning

confidence: 99%

Signaling Receptors for TGF-β Family Members

Heldin

Moustakas

2016

Cold Spring Harb Perspect Biol

524

498

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Transforming growth factor b (TGF-b) family members signal via heterotetrameric complexes of type I and type II dual specificity kinase receptors. The activation and stability of the receptors are controlled by posttranslational modifications, such as phosphorylation, ubiquitylation, sumoylation, and neddylation, as well as by interaction with other proteins at the cell surface and in the cytoplasm. Activation of TGF-b receptors induces signaling via formation of Smad complexes that are translocated to the nucleus where they act as transcription factors, as well as via non-Smad pathways, including the Erk1/2, JNK and p38 MAP kinase pathways, and the Src tyrosine kinase, phosphatidylinositol 3 0 -kinase, and Rho GTPases.

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Heart and Liver Defects and Reduced Transforming Growth Factor β2 Sensitivity in Transforming Growth Factor β Type III Receptor-Deficient Embryos

Cited by 219 publications

References 61 publications

The TGFβ type II receptor plays a critical role in the endothelial cells during cardiac development

The TGFβ type II receptor plays a critical role in the endothelial cells during cardiac development

Cell biology of embryonic migration

Signaling Receptors for TGF-β Family Members

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