Spelling suggestions: "subject:"fgfr2"" "subject:"tnfr1""
1 |
Developmental genetic analysis of post-axial longitudinal limb reduction defect (PALLRD) in Miller syndrome and nonclassical Miller syndromeAldridge, Kishan Victoria January 2018 (has links)
This project aimed to provide a greater understanding of limb development through the characterisation of Mendelian disorders. The more specific aim was to identify the developmental basis of the Post Axial Longitudinal Limb Reduction Deformity (PALLRD) seen in the autosomal recessive Miller syndrome caused by mutations in Dihydroorotate Dehydrogenase (DHODH)[1]. In addition whole exome sequence analysis was used to identify further causative variants in a group of individuals with Non Classical Miller syndrome. These individuals were negative for mutations in DHODH although they had a clinically overlapping PALLRD. A single novel variant was discovered in Fibroblast Growth Factor Receptor 1 gene (FGF1) in one individual in this cohort. Due to the known vital role of FGF signaling in limb bud development the functional significance of this variant was investigated further[2]. In vitro data suggested that this variant has a dominant negative effect. Finally I compared the differential gene expression profile of embryonic mouse forelimb and hindlimb at a later stage of development. Digital Gene Expression Serial Analysis of Gene Expression (DGE-SAGE) produced gene-expression profiles of the forelimbs and hind limbs from 14.5 days post conception (d.p.c) murine embryos. This data included known differentially expressed genes as well as novel candidate genes that are putative regulators of limb growth. Whole mount In Situ Hybrisation (WISH) and Quantitative Real Time Polymerase Chain Reaction (qRTPCR) provided corroborating evidence for the differential expression of a subset of these genes between the forelimbs and hind limbs. This project suggests a role for DHODH in limb bud cell proliferation. It also demonstrates a novel potentially dominant negative mutation within FGFR1 in an individual with a limb deformity. Finally a subset of genes involved in regulating the differential growth between the forelimb and hindlimb were presented.
|
2 |
Functional and diagnostic relevance of FGFR1-dependent signaling pathways in squamous cell lung cancerElakad, Omar 02 September 2020 (has links)
No description available.
|
3 |
Oncogenic FGFR1 mutation and amplification in common cellular origin in a composite tumor with neuroblastoma and pheochromocytoma / 発がん性FGFR1変異・増幅と共通細胞起源を有する神経芽腫-褐色細胞腫複合腫瘍の解析Tasaka, Keiji 26 September 2022 (has links)
京都大学 / 新制・課程博士 / 博士(医学) / 甲第24189号 / 医博第4883号 / 新制||医||1060(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 小林 恭, 教授 羽賀 博典, 教授 伊藤 貴浩 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
|
4 |
Signaling mechanisms and developmental function of fibroblast growth factor receptors in zebrafishKolanczyk, Maria Elzbieta 19 May 2009 (has links) (PDF)
Fibroblast growth factor (Fgf) signaling plays multiple inductive roles during development of vertebrates (Itoh 2007). Some Fgfs, such as Fgf8, are locally secreted and signal over a long range to provide positional information in the target tissue (Scholpp and Brand 2004). Fgf ligands signal in a receptor-dependent manner via tyrosine kinase receptors, four of which have been so far identified. Fgf8 signaling was shown to depend both on receptor activation as well as endocytosis. The specificity of Fgf ligands and receptors as well as the function of receptors in the control of the Fgf signaling range have been, however, largely unclear. In this study, we show that the putative Fgf8 receptor Fgfr1 is duplicated in zebrafish and that it acts redundantly in the formation of the posterior mesoderm. Also, in overexpression studies we confirm the notion that receptor endocytosis influences Fgf8 signaling range. Through TILLING mutant recovery and morpholino knockdown studies we also show that Fgfr2 is required for growth and skeletal development in zebrafish, whereas Fgfr4 is required for pectoral fin specification and growth.
|
5 |
Signaling mechanisms and developmental function of fibroblast growth factor receptors in zebrafishKolanczyk, Maria Elzbieta 11 May 2009 (has links)
Fibroblast growth factor (Fgf) signaling plays multiple inductive roles during development of vertebrates (Itoh 2007). Some Fgfs, such as Fgf8, are locally secreted and signal over a long range to provide positional information in the target tissue (Scholpp and Brand 2004). Fgf ligands signal in a receptor-dependent manner via tyrosine kinase receptors, four of which have been so far identified. Fgf8 signaling was shown to depend both on receptor activation as well as endocytosis. The specificity of Fgf ligands and receptors as well as the function of receptors in the control of the Fgf signaling range have been, however, largely unclear. In this study, we show that the putative Fgf8 receptor Fgfr1 is duplicated in zebrafish and that it acts redundantly in the formation of the posterior mesoderm. Also, in overexpression studies we confirm the notion that receptor endocytosis influences Fgf8 signaling range. Through TILLING mutant recovery and morpholino knockdown studies we also show that Fgfr2 is required for growth and skeletal development in zebrafish, whereas Fgfr4 is required for pectoral fin specification and growth.
|
6 |
Análisis molecular de la interacción anosmina-1/FGFR1 y efectos de la sobreexpresión de anosmina-1 en el sistema nervioso centralMurcia Belmonte, Verónica 01 March 2013 (has links)
No description available.
|
7 |
The Role of FGF21 in Pancreatic Islet MetabolismSun, Mark Yimeng 20 December 2011 (has links)
The endocrine-like factor FGF21 is a potent regulator of nutrient metabolism. Systemic FGF21 administration to obese animals improves glucose tolerance, lowers blood glucose and triglycerides, and decreases fasting insulin levels. Although FGF21 improves the survival and function of islet β-cells, the mechanisms are currently unknown. This thesis examines mechanisms of FGF21 in the regulation of pancreatic islet metabolism. Biochemistry studies showed FGF21 decreased Acetyl-CoA carboxylase (ACC) and Uncoupling protein-2 (UCP2) protein expression in mouse islets. Autofluorescence microscopy showed difference in NAD(P)H responses when challenged with TCA cycle intermediate citrate. FGF21-treated islets showed significant decreased mitochondrial energetics when acutely stimulated with high concentrations of glucose and palmitate. This decrease in energetics correlated with increased generation of NADPH. Importantly, insulin secretion was lowered but not abolished in this state. These data confirm that FGF21 alters pancreatic islets metabolism during high glucose and high fat loading and reduces insulin during nutrient stress.
|
8 |
The Role of FGF21 in Pancreatic Islet MetabolismSun, Mark Yimeng 20 December 2011 (has links)
The endocrine-like factor FGF21 is a potent regulator of nutrient metabolism. Systemic FGF21 administration to obese animals improves glucose tolerance, lowers blood glucose and triglycerides, and decreases fasting insulin levels. Although FGF21 improves the survival and function of islet β-cells, the mechanisms are currently unknown. This thesis examines mechanisms of FGF21 in the regulation of pancreatic islet metabolism. Biochemistry studies showed FGF21 decreased Acetyl-CoA carboxylase (ACC) and Uncoupling protein-2 (UCP2) protein expression in mouse islets. Autofluorescence microscopy showed difference in NAD(P)H responses when challenged with TCA cycle intermediate citrate. FGF21-treated islets showed significant decreased mitochondrial energetics when acutely stimulated with high concentrations of glucose and palmitate. This decrease in energetics correlated with increased generation of NADPH. Importantly, insulin secretion was lowered but not abolished in this state. These data confirm that FGF21 alters pancreatic islets metabolism during high glucose and high fat loading and reduces insulin during nutrient stress.
|
9 |
Regulation of FGF Receptor 1 by Nedd4-1Persaud, Avinash 19 June 2014 (has links)
The ubiquitin system plays a pivotal role in regulating protein degradation, endocytosis and numerous other cellular functions. E3 ubiquitin ligases, which mediate the final step in the ubiquitylation reaction cascade, are responsible for substrate recognition and ubiquitin attachment to them, underscoring the importance of identifying their substrates. Nedd4 family members are E3 ubiquitin ligases comprised of a C2-WW-HECT domain architecture. This thesis was aimed at first globally delineating the substrate specificity of the closely related Nedd4 family members in humans, hNedd4-1 (Nedd4) and hNedd4-2 (Nedd4L), and second, to follow up on one of the novel hits identified, the FGFR1, and study in detail how it is regulated by its E3 ligase hNedd4-1.
To globally identify substrates for Nedd4 proteins, a high throughput proteomic screening technology using protein microarrays was employed. Despite the obvious homology in their domain architecture, the results presented here suggest that these Nedd4 family members may function non-redundantly, since they demonstrate a selective preference towards substrate ubiquitylation.
Our focus on FGFR1, a substrate identified for hNedd4-1, has revealed an important functional role for this ubiquitin ligase in promoting FGFR1 endocytosis and downregulation of its signaling activity. The evidence presented indicates that this interaction has important consequences for developmental processes that are dependent on FGF signaling: human neural stem cell differentiation and zebrafish embryonic patterning and brain development. We demonstrate that the WW3 domain of Nedd4-1 recognizes a novel, non-canonical binding surface (peptide2) within the juxtamembrane region of FGFR1, and we are currently in the process of solving the 3 dimensional structure of the hNedd4-1 WW3: FGFR1 peptide2 complex using X-ray crystallography.
Furthermore, in characterizing the interaction between hNedd4-1 and FGFR1, we have provided evidence for a novel mechanism for regulating the catalytic activity of hNedd4-1 by FGFR1 activation. This involves the formation of hNedd4-1 dimers upon removal of the autoinhibitory C2 domain from the HECT domain. Dimerized hNedd4-1, in turn, exhibits enhanced interactions with FGFR1 and enhanced receptor ubiquitylation. From these data, we proposed a negative feedback inhibitory model for FGFR1 downregulation, whereby activated receptor enhances the activation of its suppressor, hNedd4-1, to ensure timely termination of receptor signaling.
|
10 |
Regulation of FGF Receptor 1 by Nedd4-1Persaud, Avinash 19 June 2014 (has links)
The ubiquitin system plays a pivotal role in regulating protein degradation, endocytosis and numerous other cellular functions. E3 ubiquitin ligases, which mediate the final step in the ubiquitylation reaction cascade, are responsible for substrate recognition and ubiquitin attachment to them, underscoring the importance of identifying their substrates. Nedd4 family members are E3 ubiquitin ligases comprised of a C2-WW-HECT domain architecture. This thesis was aimed at first globally delineating the substrate specificity of the closely related Nedd4 family members in humans, hNedd4-1 (Nedd4) and hNedd4-2 (Nedd4L), and second, to follow up on one of the novel hits identified, the FGFR1, and study in detail how it is regulated by its E3 ligase hNedd4-1.
To globally identify substrates for Nedd4 proteins, a high throughput proteomic screening technology using protein microarrays was employed. Despite the obvious homology in their domain architecture, the results presented here suggest that these Nedd4 family members may function non-redundantly, since they demonstrate a selective preference towards substrate ubiquitylation.
Our focus on FGFR1, a substrate identified for hNedd4-1, has revealed an important functional role for this ubiquitin ligase in promoting FGFR1 endocytosis and downregulation of its signaling activity. The evidence presented indicates that this interaction has important consequences for developmental processes that are dependent on FGF signaling: human neural stem cell differentiation and zebrafish embryonic patterning and brain development. We demonstrate that the WW3 domain of Nedd4-1 recognizes a novel, non-canonical binding surface (peptide2) within the juxtamembrane region of FGFR1, and we are currently in the process of solving the 3 dimensional structure of the hNedd4-1 WW3: FGFR1 peptide2 complex using X-ray crystallography.
Furthermore, in characterizing the interaction between hNedd4-1 and FGFR1, we have provided evidence for a novel mechanism for regulating the catalytic activity of hNedd4-1 by FGFR1 activation. This involves the formation of hNedd4-1 dimers upon removal of the autoinhibitory C2 domain from the HECT domain. Dimerized hNedd4-1, in turn, exhibits enhanced interactions with FGFR1 and enhanced receptor ubiquitylation. From these data, we proposed a negative feedback inhibitory model for FGFR1 downregulation, whereby activated receptor enhances the activation of its suppressor, hNedd4-1, to ensure timely termination of receptor signaling.
|
Page generated in 0.0363 seconds