TGFβ2 regulates hypothalamic Trh expression through the TGFβ inducible early gene-1 (TIEG1) during fetal development

Martínez-Armenta, Miriam; León-Guerrero, Sol Díaz de; Catalán, Ana Inés; Álvarez-Arellano, Lourdes; Uribe, R.M.; Subramaniam, Malayannan; Charlí, Jean-Louis; Pérez-Martı́nez, Leonor

doi:10.1016/j.mce.2014.10.021

Cited by 7 publications

(6 citation statements)

References 83 publications

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“…does not have a structural but rather a regulatory role when secreted to the ECM) found in basement membranes and is also a TGF-β regulator 39 and STC1 is a secreted glycoprotein found downstream of TGF-β2 in osteoclasts 38 . From the 11 remaining upregulated genes 4 affect gene expression or transcription, namely: ZNF703, a transcriptional co-repressor related to TGF-β 45 ; ZSCAN31, a DNA-binding transcription factor; ID1, a transcriptional regulator 46 ; and KLF10, a zinc finger DNA-binding protein that regulates gene expression and is also known as transforming growth factor-β (TGFβ) inducible early gene-1 ( TIEG1 ) 47 . In addition, we found the following genes to be upregulated: CXCL12, a secreted chemokine that contributes to cancer 48 ; GADD45B an effector of TGF-β signaling 49,50 ; KRT7 a cytoskeletal protein expressed in blood vessels and upregulated in response to TGF-β 51 ; INSR a transmembrane receptor that is activated by insulin 52 ; and EPHA5 a receptor belonging to the protein-tyrosine kinase family 53 .…”

Section: Resultsmentioning

confidence: 99%

Subendothelial stiffness alters endothelial cell traction force generation while exerting a minimal effect on the transcriptome

Bastounis

Yeh

Theriot

2019

Sci Rep

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Endothelial cells respond to changes in subendothelial stiffness by altering their migration and mechanics, but whether those responses are due to transcriptional reprogramming remains largely unknown. We measured traction force generation and also performed gene expression profiling for two endothelial cell types grown in monolayers on soft or stiff matrices: primary human umbilical vein endothelial cells (HUVEC) and immortalized human microvascular endothelial cells (HMEC-1). Both cell types respond to changes in subendothelial stiffness by increasing the traction stresses they exert on stiffer as compared to softer matrices, and exhibit a range of altered protein phosphorylation or protein conformational changes previously implicated in mechanotransduction. However, the transcriptome has only a minimal role in this conserved biomechanical response. Only few genes were differentially expressed in each cell type in a stiffness-dependent manner, and none were shared between them. In contrast, thousands of genes were differentially regulated in HUVEC as compared to HMEC-1. HUVEC (but not HMEC-1) upregulate expression of TGF-β2 on stiffer matrices, and also respond to application of exogenous TGF-β2 by enhancing their endogenous TGF-β2 expression and their cell-matrix traction stresses. Altogether, these findings provide insights into the relationship between subendothelial stiffness, endothelial mechanics and variation of the endothelial cell transcriptome, and reveal that subendothelial stiffness, while critically altering endothelial cells’ mechanical behavior, minimally affects their transcriptome.

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Section: Resultsmentioning

confidence: 99%

Subendothelial stiffness alters endothelial cell traction force generation while exerting a minimal effect on the transcriptome

Bastounis

Yeh

Theriot

2019

Sci Rep

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“…A rat thyroid medullary carcinoma cell line, CA77 [43], is known to synthesize TRH [50][51][52]. According to Martinez-Armenta et al [53], a kruppel-like factor (KLF)/Sp-1 family member, KLF10 (TIEG1), is expressed in CA77 cells and plays a crucial role in the expression of the rat preproTRH gene via its KLF-binding site (KEM1, Fig 2A). As we failed to detect the expression of endogenous GATA2, we transfected a GATA2 expression plasmid into CA77 cells and performed chromatin immunoprecipitation (ChIP) assays with an anti-GATA2 antibody.…”

Section: Plos Onementioning

confidence: 99%

“…site (KEM1, Fig 2A) [53]. In addition, prepro-TRH gene expression is also stimulated by protein kinase C (PKC) signaling via the AP-1 site [71] and, presumably, GATA-RE (dr-GATA) [10].…”

Section: Plos Onementioning

confidence: 99%

G ATA2 mediates the negative regulation of the prepro-thyrotropin-releasing hormone gene by liganded T3 receptor β2 in the rat hypothalamic paraventricular nucleus

et al. 2020

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Thyroid hormone (T3) inhibits thyrotropin-releasing hormone (TRH) synthesis in the hypothalamic paraventricular nucleus (PVN). Although the T3 receptor (TR) β2 is known to mediate the negative regulation of the prepro-TRH gene, its molecular mechanism remains unknown. Our previous studies on the T3-dependent negative regulation of the thyrotropin β subunit (TSHβ) gene suggest that there is a tethering mechanism, whereby liganded TRβ2 interferes with the function of the transcription factor, GATA2, a critical activator of the TSHβ gene. Interestingly, the transcription factors Sim1 and Arnt2, the determinants of PVN differentiation in the hypothalamus, are reported to induce expression of TRβ2 and GATA2 in cultured neuronal cells. Here, we confirmed the expression of the GATA2 protein in the TRH neuron of the rat PVN using immunohistochemistry with an anti-GATA2 antibody. According to an experimental study from transgenic mice, a region of the rat prepro-TRH promoter from nt. -547 to nt. +84 was able to mediate its expression in the PVN. We constructed a chloramphenicol acetyltransferase (CAT) reporter gene containing this promoter sequence (rTRH(547)-CAT) and showed that GATA2 activated the promoter in monkey kidney-derived CV1 cells. Deletion and mutation analyses identified a functional GATA-responsive element (GATA-RE) between nt. -357 and nt. -352. When TRβ2 was co-expressed, T3 reduced GATA2-dependent promoter activity to approximately 30%. Unexpectedly, T3-dependent negative regulation was maintained after mutation of the reported negative T3-responsive element, site 4. T3 also inhibited the GATA2-dependent transcription enhanced by cAMP agonist, 8-bromo-cAMP. A rat thyroid medullary carcinoma cell line, CA77, is known to express the preproTRH mRNA. Using a chromatin immunoprecipitation assay with this cell line where GATA2 expression plasmid was transfected, we observed the recognition of the GATA-RE by GATA2. We also confirmed GATA2 binding using gel shift assay with the probe for the GATA-RE. In CA77 cells, the activity of rTRH(547)-CAT was potentiated by overexpression of GATA2, and it was inhibited in a T3-dependent manner. These results suggest that GATA2 transactivates the rat prepro-TRH gene and that liganded TRβ2 interferes with this activation via a tethering mechanism as in the case of the TSHβ gene.

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“…Interestingly, there are many pathways genes monitored by the nsiGGM, but not by the JGGM. Focusing on the cell signaling pathway, we particularly notice that EREG [ 26 ], SLC1A1 [ 27 ], STC2 [ 28 ], GAD1 [ 29 ], and TRH [ 30 ] are genes not selected by the JGGM but nonetheless previously were monitored in signaling pathways. Importantly, Hou et al [ 28 ] showed that STC2 inhibited tumorigenesis and metastasis of breast cancer cells, indicating that STC2 may inhibit epithelial-mesenchymal transition (EMT) at least partially through the PKC/Claudin-1-mediated signaling in human breast cancer cells.…”

Section: Numerical Studiesmentioning

confidence: 99%

Node-Structured Integrative Gaussian Graphical Model Guided by Pathway Information

Kim

Jhong

Lee

et al. 2017

Computational and Mathematical Methods in Medicine

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Up to date, many biological pathways related to cancer have been extensively applied thanks to outputs of burgeoning biomedical research. This leads to a new technical challenge of exploring and validating biological pathways that can characterize transcriptomic mechanisms across different disease subtypes. In pursuit of accommodating multiple studies, the joint Gaussian graphical model was previously proposed to incorporate nonzero edge effects. However, this model is inevitably dependent on post hoc analysis in order to confirm biological significance. To circumvent this drawback, we attempt not only to combine transcriptomic data but also to embed pathway information, well-ascertained biological evidence as such, into the model. To this end, we propose a novel statistical framework for fitting joint Gaussian graphical model simultaneously with informative pathways consistently expressed across multiple studies. In theory, structured nodes can be prespecified with multiple genes. The optimization rule employs the structured input-output lasso model, in order to estimate a sparse precision matrix constructed by simultaneous effects of multiple studies and structured nodes. With an application to breast cancer data sets, we found that the proposed model is superior in efficiently capturing structures of biological evidence (e.g., pathways). An R software package nsiGGM is publicly available at author's webpage.

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TGFβ2 regulates hypothalamic Trh expression through the TGFβ inducible early gene-1 (TIEG1) during fetal development

Cited by 7 publications

References 83 publications

Subendothelial stiffness alters endothelial cell traction force generation while exerting a minimal effect on the transcriptome

Subendothelial stiffness alters endothelial cell traction force generation while exerting a minimal effect on the transcriptome

G ATA2 mediates the negative regulation of the prepro-thyrotropin-releasing hormone gene by liganded T3 receptor β2 in the rat hypothalamic paraventricular nucleus

Node-Structured Integrative Gaussian Graphical Model Guided by Pathway Information

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