Novel Mechanisms of Transcriptional Repression by the Paired-like Homeodomain Transcription Factor Goosecoid

Izzi, Luisa

31 July 2008

Gastrulation is the process by which the three germ layers are generated during vertebrate development. Nodal ligands, which form a subgroup of the Transforming Growth Factor β (TGFβ) superfamily, regulate the expression several transcription factors implicated in gastrulation. Among these are the paired-like homeodomain transcription factors Goosecoid (Gsc) and Mixl1. At the molecular level, Gsc has been described to function as a transcriptional repressor by directly binding to paired homedomain binding sites on target promoters. Here, I describe a novel mechanism of transcriptional repression by Gsc. Using a molecular and embryological approach, I demonstrate that the forkhead transcription factor Foxh1, a major transducer of Nodal signaling, associates with Gsc which in turn recruits histone deacetylases to negatively regulate Mixl1 expression during early mouse development. Post-translational modification of transcription factors by SUMO proteins represents an important mechanism through which their activity is controlled. Here, I also demonstrate that Gsc is sumoylated in mammalian cells by members of the PIAS family of proteins and this modification potentiates the repressive activity of Gsc on direct targets such as the Xbra and Gsc promoters, but not on indirect targets such as Mixl1. Taken together, work presented in this thesis describes two novel mechanisms of transcriptional repression by Gsc.

Foxh1

Goosecoid

Sumoylation

Transcription

Mixl1

Smads

TGF-beta

0307

0379

Endocytic trafficking is required for neuron cell death through regulating TGF-beta signaling in <i>Drosophila melanogaster</i>

Wang, Zixing

01 August 2011

Programmed cell death (PCD) is an essential feature during the development of the central nervous system in Drosophila as well as in mammals. During metamorphosis, a group of peptidergic neurons (vCrz) are eliminated from the larval central nervous system (CNS) via PCD within 6-7 h after puparium formation. To better understand this process, we first characterized the development of the vCrz neurons including their lineages and birth windows using the MARCM (Mosaic Analysis with a Repressible Cell Marker) assay. Further genetic and MARCM analyses showed that not only Myoglianin (Myo) and its type I receptor Baboon is required for neuron cell death, but also this death signal is extensively regulated by endocytic trafficking in Drosophila melanogaster. We found that clathrin-mediated membrane receptor internalization and subsequent endocytic events involved in Rab5-dependent early endosome and Rab11-dependent recycling endosome differentially participate in TGF-β [beta] signaling. Two early endosome-enriched proteins, SARA and Hrs, are found to act as a cytosolic retention factor of Smad2, indicating that endocytosis mediates TGF-β [beta] signaling through regulating the dissociation of Smad2 and its cytosolic retention factor.

neuronal cell death

TGF-beta

endocytosis

MARCM

Genetics and Genomics

Canonical TGF-β Pathway Activity is a Predictor of Medulloblastoma Survival and Delineates Putative Precursors in Cerebellar Development

Aref, Donya

20 November 2012

Medulloblastoma (MB) is the most common pediatric malignant brain tumor. Little is known about aggressive forms of this disease. In order to identify pathways mediating aggressiveness in MB, we performed microarray experiments. Primary human MBs were compared to their patient matched recurrent or metastatic counterparts. Murine tumors from two MB mouse models that present with differing clinical severities were also evaluated. We identified the Transforming Growth Factor-beta (TGF-β) as a potential contributor to MB pathogenesis in both species. Smad3, a major downstream component of the TGF-β pathway, was shown to correlate with MB metastasis and survival in human tissue. Similarly, Smad3 expression during development identified a subset of cerebellar neuronal precursors as putative cells of origin for the Smad3 positive MBs. To our knowledge, this is the first study that links TGF-β to MB pathogenesis. Our research suggests that canonical activation of this pathway leads to better prognosis for patients.

medulloblastoma

smad3

TGF-beta

prognosis

cerebellar development

0571

0992

Canonical TGF-β Pathway Activity is a Predictor of Medulloblastoma Survival and Delineates Putative Precursors in Cerebellar Development

Aref, Donya

20 November 2012

Medulloblastoma (MB) is the most common pediatric malignant brain tumor. Little is known about aggressive forms of this disease. In order to identify pathways mediating aggressiveness in MB, we performed microarray experiments. Primary human MBs were compared to their patient matched recurrent or metastatic counterparts. Murine tumors from two MB mouse models that present with differing clinical severities were also evaluated. We identified the Transforming Growth Factor-beta (TGF-β) as a potential contributor to MB pathogenesis in both species. Smad3, a major downstream component of the TGF-β pathway, was shown to correlate with MB metastasis and survival in human tissue. Similarly, Smad3 expression during development identified a subset of cerebellar neuronal precursors as putative cells of origin for the Smad3 positive MBs. To our knowledge, this is the first study that links TGF-β to MB pathogenesis. Our research suggests that canonical activation of this pathway leads to better prognosis for patients.

medulloblastoma

smad3

TGF-beta

prognosis

cerebellar development

0571

0992

Keloids - A fibroproliferative disease

Seifert (Bock), Oliver

January 2008

Keloids are a fibroproliferative disorder of unknown etiology developing in the skin after injury or spontaneously. The aim of this thesis is to gain deeper insight into the role of TGF-β and its signaling pathway proteins, SMADs, in the pathogenesis of keloids and describe the gene expression profile in different keloid sites in the search for potential target genes for future treatment. Further aim is to develop an instrument to describe the quality of life of patients with keloids. We find cultured keloid fibroblasts to express an increased level of TGF-β1 mRNA and a decreased level of TGF-β3 mRNA compared to control skin. Keloid derived fibroblasts exhibit significantly decreased mRNA levels of TGF-β receptor type II (TβRII) and the ratio of TβRI/TβRII mRNA expression is increased. This suggests that a certain expression pattern of TGF-β subtypes and receptors may be important in keloid pathogenesis. Analysis of keloid derived fibroblasts reveal decreased SMAD3 mRNA expression and decreased ratio of SMAD2/SMAD3 mRNA implicating a disturbed SMAD signaling. Keloid fibroblasts up-regulate SMAD4 protein after stimulation with TGF-β1 and display diminished levels of the inhibitory proteins SMAD6 and 7. This may contribute to unlimited and deregulated TGF-β signaling leading to increased extracellular matrix production (ECM). The gene expression pattern is described in fibroblasts from different keloid sites using microarrays covering the whole human genome. This study reveals 105 regulated genes (79 genes are up- and 26 down-regulated) resulting in a unique gene expression profile in different sites of keloids, where progression or regression of the keloid process took place. In cells from the central part of keloids with clinical signs of regression, an up-regulation of apoptosis inducing genes as ADAM12 and ECM degrading genes as MMP19 is found. These genes may contribute to regression of keloids and might be possible future target genes for treatment. Overexpression of apoptosis inhibitors as AVEN and down-regulation of angiogenesis inhibiting genes as PTX3 found at the active margin of keloids may be responsible for the invasive character of the keloid margin. We develop a disease specific questionnaire to measure the quality of life of patients with keloids. We find two scales, psychological and physical impairment, describing the dimensions of quality of life in patients with scars. These two scales are independent of each other and show a high test-retest reliability. Single items which clinically characterize the disease show correlations to these scales. The results of this study demonstrate for the first time a severe impairment of quality of life of patients suffering from keloids and hypertrophic scars. In conclusion the described alteration in TGF-β expression and its receptors, the disrupted SMAD signaling pathway and the unique gene expression patterns in different keloid sites provide new knowledge on ECM formation and degradation in keloids. Regulatory genes in ECM homeostasis may be future target genes for keloid prevention, regression and treatment. The disease specific quality of life instrument of patients with keloids and scars is a useful tool to estimate success in future therapeutic efforts over time.

keloid

TGF-beta

SMAD

quality of life

Dermatology and venerology

Dermatologi och venerologi

Initiating Complement-Dependent Synaptic Refinement: Mechanisms of Neuronal C1q Regulation

Bialas, Allison Marilyn

07 June 2014

Immune molecules, including complement proteins, C1q and C3, have emerged as critical mediators of synaptic refinement and plasticity. Complement proteins localize to synapses and refine the developing retinogeniculate system via C3-dependent microglial phagocytosis of synapses. Retinal ganglion cells (RGCs) express C1q, the initiating protein of the classical complement cascade, during retinogeniculate refinement; however, the signals controlling C1q expression and function remain elusive. RGCs grown in the presence of astrocytes significantly upregulated C1q compared to controls, implicating an astrocyte-derived factor in neuronal C1q expression. A major goal of my dissertation research was to identify the signals that regulate C1q expression and function in the developing visual system. In this study, I have identified transforming growth factor beta \((TGF-\beta)\), an astrocyte-secreted cytokine, as both necessary and sufficient for C1q expression in RGCs through an activity-dependent mechanism. Specific disruption of retinal \(TGF-\beta\) signaling resulted in a significant reduction in the deposition of C1q and downstream C3 at retinogeniculate synapses and significant synaptic refinement defects in the retinogeniculate system. Microglia engulfment of RGC inputs in the lateral geniculate nucleus (LGN) was also significantly reduced in retinal \(TGF\beta\)RII KOs, phenocopying the engulfment defects observed in C1q KOs, C3 KOs, and CR3 KOs. Interestingly, in C1q KOs and retinal \(TGF\beta\)RII KOs, microglia also failed to preferentially engulf less active inputs when retinal activity was manipulated, suggesting that retinal activity and \(TGF-\beta\) signaling cooperatively regulate complement mediated synaptic refinement. In support of this hypothesis, blocking spontaneous activity in RGC cultures significantly reduced C1q upregulation by \(TGF-\beta\). Moreover, manipulating spontaneous retinal activity in vivo modulated C1q expression levels in RGCs and C1q deposition in the LGN. Together these findings support a model in which retinal activity and \(TGF-\beta\) signaling control expression and local release of C1q in the LGN to regulate microglia-mediated, complement-dependent synaptic pruning. These results provide mechanistic insight into synaptic refinement and, potentially, pathological synapse loss which occurs in the early stages of neurodegenerative diseases concurrently with aberrant complement expression and reactive gliosis.

Neurosciences

C1q

complement

neuronal activity

retinogeniculate

synaptic refinement

TGF-beta

The Role of Cell-polarity in Development and Disease

Samavarchi-Tehrani, Payman

14 January 2014

From the simplest unicellular organisms to complex metazoans, cell polarity is a widespread characteristic that is essential for almost every aspect of biology. Proper polarization of cells is crucial for the establishment and maintenance of higher order structures such as tissue and organs. Cell polarity refers to the asymmetric distribution of various macromolecules and cellular structures, resulting in polarized architecture and function of the cell. Defects in cell polarity lead to various phenotypes, ranging from aberrant signaling, proliferation, cell adhesion and migration, cell fate determination and pluripotency, as well as embryonic lethality, neoplasia and cancer. Given the various roles for cell polarity in development and disease, the characterization of the components involved in polarity and their mechanisms of function is of great importance. My thesis work has encompassed three major projects, each of which is focused on understanding the role of cell polarity in development and disease. Although genetic screens in invertebrates have led to the identification of a number of cell-polarity proteins, similar systematic approach have not been undertaken in mammalian systems. The goal of my first project was to design and implement a high-throughput screen to systematically knockdown individual genes using siRNA, and then assess cell junction integrity as a measure of cell polarity. Given the importance of cell polarity to signaling pathways, I next sought to determine the mechanism by which cell polarity affects TGFβ and Hippo pathways, two important signaling pathways involved in development and disease. Lastly, by studying the acquisition of pluripotency by somatic cells, I uncovered a central role for cell polarity in the establishment and maintenance of pluripotency. Here I will present and discuss our discovery pertaining to the role of cell polarity in cell signaling and pluripotency.

Polarity

Cancer

Pluripotency

Reprogramming

TGF-beta

Hippo

0379

0307

The Role of Cell-polarity in Development and Disease

Samavarchi-Tehrani, Payman

14 January 2014

From the simplest unicellular organisms to complex metazoans, cell polarity is a widespread characteristic that is essential for almost every aspect of biology. Proper polarization of cells is crucial for the establishment and maintenance of higher order structures such as tissue and organs. Cell polarity refers to the asymmetric distribution of various macromolecules and cellular structures, resulting in polarized architecture and function of the cell. Defects in cell polarity lead to various phenotypes, ranging from aberrant signaling, proliferation, cell adhesion and migration, cell fate determination and pluripotency, as well as embryonic lethality, neoplasia and cancer. Given the various roles for cell polarity in development and disease, the characterization of the components involved in polarity and their mechanisms of function is of great importance. My thesis work has encompassed three major projects, each of which is focused on understanding the role of cell polarity in development and disease. Although genetic screens in invertebrates have led to the identification of a number of cell-polarity proteins, similar systematic approach have not been undertaken in mammalian systems. The goal of my first project was to design and implement a high-throughput screen to systematically knockdown individual genes using siRNA, and then assess cell junction integrity as a measure of cell polarity. Given the importance of cell polarity to signaling pathways, I next sought to determine the mechanism by which cell polarity affects TGFβ and Hippo pathways, two important signaling pathways involved in development and disease. Lastly, by studying the acquisition of pluripotency by somatic cells, I uncovered a central role for cell polarity in the establishment and maintenance of pluripotency. Here I will present and discuss our discovery pertaining to the role of cell polarity in cell signaling and pluripotency.

Polarity

Cancer

Pluripotency

Reprogramming

TGF-beta

Hippo

0379

0307

A Brief Elevation of Serum Amyloid A is Sufficient to Increase Atherosclerosis

Thompson, Joel C

01 January 2014

Cardiovascular disease is now the leading cause of death worldwide. Serum amyloid A (SAA), a positive acute phase reactant, along with C-reactive protein is used clinically as a marker of cardiovascular disease risk. However, recent data has shed light on a possible causal role of SAA in the development of atherosclerosis, the most pervasive form of cardiovascular disease. Several inflammatory diseases such as diabetes and obesity are known to confer increased risk of developing cardiovascular disease. Individuals with these diseases all have modest but persistent elevation of SAA. To determine if SAA caused the development of atherosclerosis, apoe-/-chow fed mice were injected with either an adenoviral vector expressing human SAA1 (ad-hSAA1), a null adenoviral vector (ad-Null) or saline. Human SAA levels rapidly increased, albeit briefly then returned to baseline within 14 days in mice that received ad-hSAA1. After 16 weeks, mice that received ad-hSAA1 had significantly increased atherosclerosis compared to controls on the aortic intimal surface (p<0.0001), aortic sinus (p<0.05) and the brachiocephalic artery (p<0.05). According to the “response to retention” hypothesis; lipoprotein retention by vascular wall proteoglycans is a key initiating event in the development of atherosclerosis. We previously reported that SAA-stimulated vascular smooth muscle cells expressed biglycan with increased glycosaminoglycan chain length and increased binding affinity for low density lipoprotein. To further test the role of biglycan on the development of atherosclerosis we generated biglycan transgenic mice. These mice were crossed to the ldlr-/- mouse on a C57BL/6 background and fed a pro-atherogenic western diet for 12 weeks. There was a significant increase in atherosclerotic lesion area on the aortic intimal surface (p<0.05) and the aortic sinus (p<0.006), as well as a significant correlation between vascular biglycan content and aortic sinus atherosclerotic lesion area (p<0.0001). These data demonstrate that transiently increased SAA resulted in increased atherosclerosis compared to control mice, possibly via increased vascular biglycan content. In support of this we found that biglycan transgenic mice had significantly increased atherosclerosis compared to wildtype controls, likely through increased lipid retention in the vascular wall.

Atherosclerosis

biglycan

TGF-beta

serum amyloid A

Laboratory and Basic Science Research

Novel Mechanisms of Transcriptional Repression by the Paired-like Homeodomain Transcription Factor Goosecoid

Izzi, Luisa

31 July 2008

Gastrulation is the process by which the three germ layers are generated during vertebrate development. Nodal ligands, which form a subgroup of the Transforming Growth Factor β (TGFβ) superfamily, regulate the expression several transcription factors implicated in gastrulation. Among these are the paired-like homeodomain transcription factors Goosecoid (Gsc) and Mixl1. At the molecular level, Gsc has been described to function as a transcriptional repressor by directly binding to paired homedomain binding sites on target promoters. Here, I describe a novel mechanism of transcriptional repression by Gsc. Using a molecular and embryological approach, I demonstrate that the forkhead transcription factor Foxh1, a major transducer of Nodal signaling, associates with Gsc which in turn recruits histone deacetylases to negatively regulate Mixl1 expression during early mouse development. Post-translational modification of transcription factors by SUMO proteins represents an important mechanism through which their activity is controlled. Here, I also demonstrate that Gsc is sumoylated in mammalian cells by members of the PIAS family of proteins and this modification potentiates the repressive activity of Gsc on direct targets such as the Xbra and Gsc promoters, but not on indirect targets such as Mixl1. Taken together, work presented in this thesis describes two novel mechanisms of transcriptional repression by Gsc.

Foxh1

Goosecoid

Sumoylation

Transcription

Mixl1

Smads

TGF-beta

0307

0379