Type |
Details |
Score |
Publication |
First Author: |
Dumont DJ |
Year: |
1992 |
Journal: |
Oncogene |
Title: |
tek, a novel tyrosine kinase gene located on mouse chromosome 4, is expressed in endothelial cells and their presumptive precursors. |
Volume: |
7 |
Issue: |
8 |
Pages: |
1471-80 |
|
•
•
•
•
•
|
Publication |
First Author: |
Shimizu A |
Year: |
2001 |
Journal: |
J Biol Chem |
Title: |
A novel alternatively spliced fibroblast growth factor receptor 3 isoform lacking the acid box domain is expressed during chondrogenic differentiation of ATDC5 cells. |
Volume: |
276 |
Issue: |
14 |
Pages: |
11031-40 |
|
•
•
•
•
•
|
Publication |
First Author: |
McGowan SE |
Year: |
2015 |
Journal: |
Am J Physiol Lung Cell Mol Physiol |
Title: |
Fibroblast growth factor signaling in myofibroblasts differs from lipofibroblasts during alveolar septation in mice. |
Volume: |
309 |
Issue: |
5 |
Pages: |
L463-74 |
|
•
•
•
•
•
|
Publication |
First Author: |
Kim CS |
Year: |
2007 |
Journal: |
Carcinogenesis |
Title: |
The pituitary tumor-transforming gene promotes angiogenesis in a mouse model of follicular thyroid cancer. |
Volume: |
28 |
Issue: |
5 |
Pages: |
932-9 |
|
•
•
•
•
•
|
Publication |
First Author: |
Xu C |
Year: |
2017 |
Journal: |
EMBO Mol Med |
Title: |
KLB, encoding β-Klotho, is mutated in patients with congenital hypogonadotropic hypogonadism. |
Volume: |
9 |
Issue: |
10 |
Pages: |
1379-1397 |
|
•
•
•
•
•
|
Publication |
First Author: |
Wu AL |
Year: |
2011 |
Journal: |
Sci Transl Med |
Title: |
Amelioration of type 2 diabetes by antibody-mediated activation of fibroblast growth factor receptor 1. |
Volume: |
3 |
Issue: |
113 |
Pages: |
113ra126 |
|
•
•
•
•
•
|
Publication |
First Author: |
Sims-Lucas S |
Year: |
2011 |
Journal: |
Development |
Title: |
Independent roles of Fgfr2 and Frs2alpha in ureteric epithelium. |
Volume: |
138 |
Issue: |
7 |
Pages: |
1275-80 |
|
•
•
•
•
•
|
Publication |
First Author: |
Chen PY |
Year: |
2015 |
Journal: |
J Clin Invest |
Title: |
Endothelial-to-mesenchymal transition drives atherosclerosis progression. |
Volume: |
125 |
Issue: |
12 |
Pages: |
4514-28 |
|
•
•
•
•
•
|
Publication |
First Author: |
Zhou Y |
Year: |
2019 |
Journal: |
J Cell Physiol |
Title: |
Deletion of Axin1 in condylar chondrocytes leads to osteoarthritis-like phenotype in temporomandibular joint via activation of β-catenin and FGF signaling. |
Volume: |
234 |
Issue: |
2 |
Pages: |
1720-1729 |
|
•
•
•
•
•
|
Publication |
First Author: |
Agerstam H |
Year: |
2010 |
Journal: |
Blood |
Title: |
Modeling the human 8p11-myeloproliferative syndrome in immunodeficient mice. |
Volume: |
116 |
Issue: |
12 |
Pages: |
2103-11 |
|
•
•
•
•
•
|
Publication |
First Author: |
Jürgenson M |
Year: |
2012 |
Journal: |
Brain Res |
Title: |
Partial reduction in neural cell adhesion molecule (NCAM) in heterozygous mice induces depression-related behaviour without cognitive impairment. |
Volume: |
1447 |
|
Pages: |
106-18 |
|
•
•
•
•
•
|
Publication |
First Author: |
Kuny S |
Year: |
2012 |
Journal: |
Invest Ophthalmol Vis Sci |
Title: |
Differential gene expression in eyecup and retina of a mouse model of Stargardt-like macular dystrophy (STGD3). |
Volume: |
53 |
Issue: |
2 |
Pages: |
664-75 |
|
•
•
•
•
•
|
Publication |
First Author: |
Bøllehuus Hansen L |
Year: |
2020 |
Journal: |
FASEB J |
Title: |
Influence of FGF23 and Klotho on male reproduction: Systemic vs direct effects. |
Volume: |
34 |
Issue: |
9 |
Pages: |
12436-12449 |
|
•
•
•
•
•
|
Publication |
First Author: |
Nagpal P |
Year: |
2012 |
Journal: |
PLoS One |
Title: |
The ubiquitin ligase Nedd4-1 participates in denervation-induced skeletal muscle atrophy in mice. |
Volume: |
7 |
Issue: |
10 |
Pages: |
e46427 |
|
•
•
•
•
•
|
Publication |
First Author: |
Burt PM |
Year: |
2019 |
Journal: |
J Cell Physiol |
Title: |
Ablation of low-molecular-weight FGF2 isoform accelerates murine osteoarthritis while loss of high-molecular-weight FGF2 isoforms offers protection. |
Volume: |
234 |
Issue: |
4 |
Pages: |
4418-4431 |
|
•
•
•
•
•
|
Publication |
First Author: |
Herburg L |
Year: |
2023 |
Journal: |
Int J Mol Sci |
Title: |
Chronic Voluntary Alcohol Consumption Alters Promoter Methylation and Expression of Fgf-2 and Fgfr1. |
Volume: |
24 |
Issue: |
4 |
|
|
•
•
•
•
•
|
Publication |
First Author: |
Ryu H |
Year: |
2021 |
Journal: |
Nat Commun |
Title: |
The molecular dynamics of subdistal appendages in multi-ciliated cells. |
Volume: |
12 |
Issue: |
1 |
Pages: |
612 |
|
•
•
•
•
•
|
Publication |
First Author: |
Riuzzi F |
Year: |
2017 |
Journal: |
Sci Rep |
Title: |
Levels of S100B protein drive the reparative process in acute muscle injury and muscular dystrophy. |
Volume: |
7 |
Issue: |
1 |
Pages: |
12537 |
|
•
•
•
•
•
|
Publication |
First Author: |
LaConti JJ |
Year: |
2011 |
Journal: |
PLoS One |
Title: |
Tissue and serum microRNAs in the Kras(G12D) transgenic animal model and in patients with pancreatic cancer. |
Volume: |
6 |
Issue: |
6 |
Pages: |
e20687 |
|
•
•
•
•
•
|
Publication |
First Author: |
Pathare G |
Year: |
2018 |
Journal: |
Sci Rep |
Title: |
Elevated FGF23 Levels in Mice Lacking the Thiazide-Sensitive NaCl cotransporter (NCC). |
Volume: |
8 |
Issue: |
1 |
Pages: |
3590 |
|
•
•
•
•
•
|
Publication |
First Author: |
van Rooijen C |
Year: |
2012 |
Journal: |
Development |
Title: |
Evolutionarily conserved requirement of Cdx for post-occipital tissue emergence. |
Volume: |
139 |
Issue: |
14 |
Pages: |
2576-83 |
|
•
•
•
•
•
|
Publication |
First Author: |
Hart AW |
Year: |
2000 |
Journal: |
Nature |
Title: |
Attenuation of FGF signalling in mouse beta-cells leads to diabetes. |
Volume: |
408 |
Issue: |
6814 |
Pages: |
864-8 |
|
•
•
•
•
•
|
Publication |
First Author: |
Tang Q |
Year: |
2024 |
Journal: |
Biochem Pharmacol |
Title: |
FGF1(ΔHBS) ameliorates retinal inflammation via suppressing TSPO signal in a type 2 diabetes mouse model. |
Volume: |
221 |
|
Pages: |
116039 |
|
•
•
•
•
•
|
Publication |
First Author: |
da Silva-Diz V |
Year: |
2016 |
Journal: |
Cancer Res |
Title: |
Cancer Stem-like Cells Act via Distinct Signaling Pathways in Promoting Late Stages of Malignant Progression. |
Volume: |
76 |
Issue: |
5 |
Pages: |
1245-59 |
|
•
•
•
•
•
|
Publication |
First Author: |
Manchado E |
Year: |
2016 |
Journal: |
Nature |
Title: |
A combinatorial strategy for treating KRAS-mutant lung cancer. |
Volume: |
534 |
Issue: |
7609 |
Pages: |
647-51 |
|
•
•
•
•
•
|
Publication |
First Author: |
Li Y |
Year: |
2017 |
Journal: |
Exp Cell Res |
Title: |
Robo signaling regulates the production of cranial neural crest cells. |
Volume: |
361 |
Issue: |
1 |
Pages: |
73-84 |
|
•
•
•
•
•
|
Publication |
First Author: |
Touchberry CD |
Year: |
2013 |
Journal: |
Am J Physiol Endocrinol Metab |
Title: |
FGF23 is a novel regulator of intracellular calcium and cardiac contractility in addition to cardiac hypertrophy. |
Volume: |
304 |
Issue: |
8 |
Pages: |
E863-73 |
|
•
•
•
•
•
|
Publication |
First Author: |
Falardeau J |
Year: |
2008 |
Journal: |
J Clin Invest |
Title: |
Decreased FGF8 signaling causes deficiency of gonadotropin-releasing hormone in humans and mice. |
Volume: |
118 |
Issue: |
8 |
Pages: |
2822-31 |
|
•
•
•
•
•
|
Publication |
First Author: |
Xiao L |
Year: |
2004 |
Journal: |
J Biol Chem |
Title: |
Stat1 controls postnatal bone formation by regulating fibroblast growth factor signaling in osteoblasts. |
Volume: |
279 |
Issue: |
26 |
Pages: |
27743-52 |
|
•
•
•
•
•
|
Publication |
First Author: |
Nakamura T |
Year: |
2001 |
Journal: |
Biochem Biophys Res Commun |
Title: |
Signals via FGF receptor 2 regulate migration of endothelial cells. |
Volume: |
289 |
Issue: |
4 |
Pages: |
801-6 |
|
•
•
•
•
•
|
Publication |
First Author: |
Peters K |
Year: |
1993 |
Journal: |
Dev Biol |
Title: |
Unique expression pattern of the FGF receptor 3 gene during mouse organogenesis. |
Volume: |
155 |
Issue: |
2 |
Pages: |
423-30 |
|
•
•
•
•
•
|
Publication |
First Author: |
Avivi A |
Year: |
1993 |
Journal: |
FEBS Lett |
Title: |
A novel form of FGF receptor-3 using an alternative exon in the immunoglobulin domain III. |
Volume: |
330 |
Issue: |
3 |
Pages: |
249-52 |
|
•
•
•
•
•
|
Publication |
First Author: |
Yoshida S |
Year: |
1996 |
Journal: |
Nihon Sanka Fujinka Gakkai Zasshi |
Title: |
[Effects of basic fibroblast growth factor on the development of mouse preimplantation embryos]. |
Volume: |
48 |
Issue: |
3 |
Pages: |
170-6 |
|
•
•
•
•
•
|
Publication |
First Author: |
GarcÃa-González D |
Year: |
2010 |
Journal: |
Exp Neurol |
Title: |
Dynamic roles of FGF-2 and Anosmin-1 in the migration of neuronal precursors from the subventricular zone during pre- and postnatal development. |
Volume: |
222 |
Issue: |
2 |
Pages: |
285-95 |
|
•
•
•
•
•
|
Publication |
First Author: |
Munnamalai V |
Year: |
2012 |
Journal: |
J Neurosci |
Title: |
Notch prosensory effects in the Mammalian cochlea are partially mediated by Fgf20. |
Volume: |
32 |
Issue: |
37 |
Pages: |
12876-84 |
|
•
•
•
•
•
|
Publication |
First Author: |
Yaqoob U |
Year: |
2014 |
Journal: |
PLoS One |
Title: |
FGF21 promotes endothelial cell angiogenesis through a dynamin-2 and Rab5 dependent pathway. |
Volume: |
9 |
Issue: |
5 |
Pages: |
e98130 |
|
•
•
•
•
•
|
Publication |
First Author: |
Lin L |
Year: |
2014 |
Journal: |
Cancer Discov |
Title: |
A large-scale RNAi-based mouse tumorigenesis screen identifies new lung cancer tumor suppressors that repress FGFR signaling. |
Volume: |
4 |
Issue: |
10 |
Pages: |
1168-81 |
|
•
•
•
•
•
|
Publication |
First Author: |
Fu T |
Year: |
2014 |
Journal: |
Mol Cell Biol |
Title: |
MicroRNA 34a inhibits beige and brown fat formation in obesity in part by suppressing adipocyte fibroblast growth factor 21 signaling and SIRT1 function. |
Volume: |
34 |
Issue: |
22 |
Pages: |
4130-42 |
|
•
•
•
•
•
|
Publication |
First Author: |
Nikolovska K |
Year: |
2017 |
Journal: |
PLoS One |
Title: |
Melanoma Cell Adhesion and Migration Is Modulated by the Uronyl 2-O Sulfotransferase. |
Volume: |
12 |
Issue: |
1 |
Pages: |
e0170054 |
|
•
•
•
•
•
|
Publication |
First Author: |
Chang YT |
Year: |
2015 |
Journal: |
Cardiovasc Res |
Title: |
Perlecan heparan sulfate deficiency impairs pulmonary vascular development and attenuates hypoxic pulmonary hypertension. |
Volume: |
107 |
Issue: |
1 |
Pages: |
20-31 |
|
•
•
•
•
•
|
Publication |
First Author: |
Linscott ML |
Year: |
2019 |
Journal: |
PLoS One |
Title: |
TET1 regulates fibroblast growth factor 8 transcription in gonadotropin releasing hormone neurons. |
Volume: |
14 |
Issue: |
7 |
Pages: |
e0220530 |
|
•
•
•
•
•
|
Publication |
First Author: |
Justesen S |
Year: |
2020 |
Journal: |
Biochem J |
Title: |
The autocrine role of FGF21 in cultured adipocytes. |
Volume: |
477 |
Issue: |
13 |
Pages: |
2477-2487 |
|
•
•
•
•
•
|
Publication |
First Author: |
Roman-Trufero M |
Year: |
2020 |
Journal: |
Mol Biol Evol |
Title: |
Evolution of an Amniote-Specific Mechanism for Modulating Ubiquitin Signaling via Phosphoregulation of the E2 Enzyme UBE2D3. |
Volume: |
37 |
Issue: |
7 |
Pages: |
1986-2001 |
|
•
•
•
•
•
|
Publication |
First Author: |
Grońska-Pęski M |
Year: |
2021 |
Journal: |
Neuroscience |
Title: |
FGFR Regulation of Dendrite Elaboration in Adult-born Granule Cells Depends on Intracellular Mediator and Proximity to the Soma. |
Volume: |
453 |
|
Pages: |
148-167 |
|
•
•
•
•
•
|
Publication |
First Author: |
Ran Q |
Year: |
2021 |
Journal: |
Transplant Cell Ther |
Title: |
Loss of FGFR3 Accelerates Bone Marrow Suppression-Induced Hematopoietic Stem and Progenitor Cell Expansion by Activating FGFR1-ELK1-Cyclin D1 Signaling. |
Volume: |
27 |
Issue: |
1 |
Pages: |
45.e1-45.e10 |
|
•
•
•
•
•
|
Publication |
First Author: |
Liu Z |
Year: |
2021 |
Journal: |
Cell Death Dis |
Title: |
Matrix stiffness modulates hepatic stellate cell activation into tumor-promoting myofibroblasts via E2F3-dependent signaling and regulates malignant progression. |
Volume: |
12 |
Issue: |
12 |
Pages: |
1134 |
|
•
•
•
•
•
|
Publication |
First Author: |
Takaya K |
Year: |
2022 |
Journal: |
Int J Mol Sci |
Title: |
Fibroblast Growth Factor 7 Suppresses Fibrosis and Promotes Epithelialization during Wound Healing in Mouse Fetuses. |
Volume: |
23 |
Issue: |
13 |
|
|
•
•
•
•
•
|
Publication |
First Author: |
Matsiukevich D |
Year: |
2022 |
Journal: |
Front Cardiovasc Med |
Title: |
Fibroblast growth factor receptor signaling in cardiomyocytes is protective in the acute phase following ischemia-reperfusion injury. |
Volume: |
9 |
|
Pages: |
1011167 |
|
•
•
•
•
•
|
Publication |
First Author: |
Goissis MD |
Year: |
2023 |
Journal: |
PLoS One |
Title: |
Influence of FGF4 and BMP4 on FGFR2 dynamics during the segregation of epiblast and primitive endoderm cells in the pre-implantation mouse embryo. |
Volume: |
18 |
Issue: |
7 |
Pages: |
e0279515 |
|
•
•
•
•
•
|
Publication |
First Author: |
Hu MC |
Year: |
1998 |
Journal: |
Mol Cell Biol |
Title: |
FGF-18, a novel member of the fibroblast growth factor family, stimulates hepatic and intestinal proliferation. |
Volume: |
18 |
Issue: |
10 |
Pages: |
6063-74 |
|
•
•
•
•
•
|
Publication |
First Author: |
Moore EE |
Year: |
2005 |
Journal: |
Osteoarthritis Cartilage |
Title: |
Fibroblast growth factor-18 stimulates chondrogenesis and cartilage repair in a rat model of injury-induced osteoarthritis. |
Volume: |
13 |
Issue: |
7 |
Pages: |
623-31 |
|
•
•
•
•
•
|
Publication |
First Author: |
Shimoaka T |
Year: |
2002 |
Journal: |
J Biol Chem |
Title: |
Regulation of osteoblast, chondrocyte, and osteoclast functions by fibroblast growth factor (FGF)-18 in comparison with FGF-2 and FGF-10. |
Volume: |
277 |
Issue: |
9 |
Pages: |
7493-500 |
|
•
•
•
•
•
|
Publication |
First Author: |
Hopper NA |
Year: |
2006 |
Journal: |
Genetics |
Title: |
The adaptor protein soc-1/Gab1 modifies growth factor receptor output in Caenorhabditis elegans. |
Volume: |
173 |
Issue: |
1 |
Pages: |
163-75 |
|
•
•
•
•
•
|
Protein Domain |
Type: |
Family |
Description: |
Fibroblast growth factors (FGFs) [, ]are a family of multifunctional proteins, often referred to as 'promiscuous growth factors' due to their diverse actions on multiple cell types [, ]. FGFs are mitogens, which stimulate growth or differentiation of cells of mesodermal or neuroectodermal origin. The function of FGFs in developmental processes include mesoderm induction, anterior-posterior patterning, limb development, and neural induction and development. In mature tissues, they are involved in diverse processes including keratinocyte organisation and wound healing [, , , , , ]. FGF involvement is critical during normal development of both vertebrates and invertebrates, and irregularities in their function leads to a range of developmental defects [, , , ]. Fibroblast growth factors are heparin-binding proteins and interactions with cell-surface-associated heparan sulfate proteoglycans have been shown to be essential for FGF signal transduction. FGFs have internal pseudo-threefold symmetry (β-trefoil topology) []. There are currently over 20 different FGF family members that have been identified in mammals, all of which are structurally related signaling molecules [, ]. They exert their effects through four distinct membrane fibroblast growth factor receptors (FGFRs), FGFR1 to FGFR4 [], which belong to the tyrosine kinase superfamily. Upon binding to FGF, the receptors dimerize and their intracellular tyrosine kinase domains become active []. |
|
•
•
•
•
•
|
Protein Domain |
Type: |
Family |
Description: |
Fibroblast growth factors (FGFs) [, ]are a family of multifunctional proteins, often referred to as 'promiscuous growth factors' due to their diverse actions on multiple cell types [, ]. FGFs are mitogens, which stimulate growth or differentiation of cells of mesodermal or neuroectodermal origin. The function of FGFs in developmental processes include mesoderm induction, anterior-posterior patterning, limb development, and neural induction and development. In mature tissues, they are involved in diverse processes including keratinocyte organisation and wound healing [, , , , , ]. FGF involvement is critical during normal development of both vertebrates and invertebrates, and irregularities in their function leads to a range of developmental defects [, , , ]. Fibroblast growth factors are heparin-binding proteins and interactions with cell-surface-associated heparan sulfate proteoglycans have been shown to be essential for FGF signal transduction. FGFs have internal pseudo-threefold symmetry (β-trefoil topology) []. There are currently over 20 different FGF family members that have been identified in mammals, all of which are structurally related signaling molecules [, ]. They exert their effects through four distinct membrane fibroblast growth factor receptors (FGFRs), FGFR1 to FGFR4 [], which belong to the tyrosine kinase superfamily. Upon binding to FGF, the receptors dimerize and their intracellular tyrosine kinase domains become active [].This entry represents fibroblast growth factor 18 (FGF18), also referred to ZFGF5. FGF18 is required for normal ossification and bone development and stimulates hepatic and intestinal proliferation [, , , ]. |
|
•
•
•
•
•
|
Protein Domain |
Type: |
Family |
Description: |
Fibroblast growth factors (FGFs) [, ]are a family of multifunctional proteins, often referred to as 'promiscuous growth factors' due to their diverse actions on multiple cell types [, ]. FGFs are mitogens, which stimulate growth or differentiation of cells of mesodermal or neuroectodermal origin. The function of FGFs in developmental processes include mesoderm induction, anterior-posterior patterning, limb development, and neural induction and development. In mature tissues, they are involved in diverse processes including keratinocyte organisation and wound healing [, , , , , ]. FGF involvement is critical during normal development of both vertebrates and invertebrates, and irregularities in their function leads to a range of developmental defects [, , , ]. Fibroblast growth factors are heparin-binding proteins and interactions with cell-surface-associated heparan sulfate proteoglycans have been shown to be essential for FGF signal transduction. FGFs have internal pseudo-threefold symmetry (β-trefoil topology) []. There are currently over 20 different FGF family members that have been identified in mammals, all of which are structurally related signaling molecules [, ]. They exert their effects through four distinct membrane fibroblast growth factor receptors (FGFRs), FGFR1 to FGFR4 [], which belong to the tyrosine kinase superfamily. Upon binding to FGF, the receptors dimerize and their intracellular tyrosine kinase domains become active [].This entry represents fibroblast growth factor 11 (FGF11), also known as fibroblast growth factor homologous factor 3. It currently has no known function, but it is thought to be involved in nervous system development and function []. |
|
•
•
•
•
•
|
Publication |
First Author: |
Kenney-Hunt JP |
Year: |
2006 |
Journal: |
Mamm Genome |
Title: |
Quantitative trait loci for body size components in mice. |
Volume: |
17 |
Issue: |
6 |
Pages: |
526-37 |
|
•
•
•
•
•
|
Protein Coding Gene |
Type: |
protein_coding_gene |
Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
Protein Coding Gene |
Type: |
protein_coding_gene |
Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
Protein Coding Gene |
Type: |
protein_coding_gene |
Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
Protein Coding Gene |
Type: |
protein_coding_gene |
Organism: |
mouse, laboratory |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
724
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
535
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
1319
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
309
|
Fragment?: |
false |
|
•
•
•
•
•
|
Publication |
First Author: |
Miraoui H |
Year: |
2013 |
Journal: |
Am J Hum Genet |
Title: |
Mutations in FGF17, IL17RD, DUSP6, SPRY4, and FLRT3 are identified in individuals with congenital hypogonadotropic hypogonadism. |
Volume: |
92 |
Issue: |
5 |
Pages: |
725-43 |
|
•
•
•
•
•
|
Publication |
First Author: |
Eswarakumar VP |
Year: |
2002 |
Journal: |
Development |
Title: |
The IIIc alternative of Fgfr2 is a positive regulator of bone formation. |
Volume: |
129 |
Issue: |
16 |
Pages: |
3783-93 |
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Publication |
First Author: |
Wheldon LM |
Year: |
2010 |
Journal: |
PLoS One |
Title: |
Critical role of FLRT1 phosphorylation in the interdependent regulation of FLRT1 function and FGF receptor signalling. |
Volume: |
5 |
Issue: |
4 |
Pages: |
e10264 |
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Publication |
First Author: |
Avivi A |
Year: |
1992 |
Journal: |
Oncogene |
Title: |
Promoter region of the murine fibroblast growth factor receptor 2 (bek/KGFR) gene. |
Volume: |
7 |
Issue: |
10 |
Pages: |
1957-62 |
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Publication |
First Author: |
Ding BS |
Year: |
2014 |
Journal: |
Nature |
Title: |
Divergent angiocrine signals from vascular niche balance liver regeneration and fibrosis. |
Volume: |
505 |
Issue: |
7481 |
Pages: |
97-102 |
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Publication |
First Author: |
Huang X |
Year: |
2006 |
Journal: |
Mol Carcinog |
Title: |
Forced expression of hepatocyte-specific fibroblast growth factor 21 delays initiation of chemically induced hepatocarcinogenesis. |
Volume: |
45 |
Issue: |
12 |
Pages: |
934-42 |
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Publication |
First Author: |
Yuan G |
Year: |
2021 |
Journal: |
Nature |
Title: |
Elevated NSD3 histone methylation activity drives squamous cell lung cancer. |
Volume: |
590 |
Issue: |
7846 |
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504-508 |
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Publication |
First Author: |
Li H |
Year: |
2011 |
Journal: |
Am J Physiol Endocrinol Metab |
Title: |
Compound deletion of Fgfr3 and Fgfr4 partially rescues the Hyp mouse phenotype. |
Volume: |
300 |
Issue: |
3 |
Pages: |
E508-17 |
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Publication |
First Author: |
Sun P |
Year: |
2020 |
Journal: |
Circ Res |
Title: |
Endothelium-Targeted Deletion of microRNA-15a/16-1 Promotes Poststroke Angiogenesis and Improves Long-Term Neurological Recovery. |
Volume: |
126 |
Issue: |
8 |
Pages: |
1040-1057 |
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Publication |
First Author: |
Wu S |
Year: |
2013 |
Journal: |
J Biol Chem |
Title: |
Increased expression of fibroblast growth factor 21 (FGF21) during chronic undernutrition causes growth hormone insensitivity in chondrocytes by inducing leptin receptor overlapping transcript (LEPROT) and leptin receptor overlapping transcript-like 1 (LEPROTL1) expression. |
Volume: |
288 |
Issue: |
38 |
Pages: |
27375-83 |
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Publication |
First Author: |
Reed JR |
Year: |
2012 |
Journal: |
PLoS One |
Title: |
Fibroblast growth factor receptor 1 activation in mammary tumor cells promotes macrophage recruitment in a CX3CL1-dependent manner. |
Volume: |
7 |
Issue: |
9 |
Pages: |
e45877 |
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Publication |
First Author: |
Yang M |
Year: |
2012 |
Journal: |
PLoS One |
Title: |
Liraglutide increases FGF-21 activity and insulin sensitivity in high fat diet and adiponectin knockdown induced insulin resistance. |
Volume: |
7 |
Issue: |
11 |
Pages: |
e48392 |
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Publication |
First Author: |
Schmid A |
Year: |
2019 |
Journal: |
Mol Cell Endocrinol |
Title: |
Evidence of functional bile acid signaling pathways in adipocytes. |
Volume: |
483 |
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Pages: |
1-10 |
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Publication |
First Author: |
Lu W |
Year: |
2021 |
Journal: |
Cancer Lett |
Title: |
FGF21 in obesity and cancer: New insights. |
Volume: |
499 |
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Pages: |
5-13 |
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Publication |
First Author: |
Ornitz DM |
Year: |
1996 |
Journal: |
J Biol Chem |
Title: |
Receptor specificity of the fibroblast growth factor family. |
Volume: |
271 |
Issue: |
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Publication |
First Author: |
Beer HD |
Year: |
2005 |
Journal: |
Oncogene |
Title: |
The fibroblast growth factor binding protein is a novel interaction partner of FGF-7, FGF-10 and FGF-22 and regulates FGF activity: implications for epithelial repair. |
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24 |
Issue: |
34 |
Pages: |
5269-77 |
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•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
243
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
207
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
247
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
225
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
78
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
69
|
Fragment?: |
true |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
197
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
205
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
109
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
154
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
112
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
251
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
211
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
115
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
207
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
221
|
Fragment?: |
true |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
157
|
Fragment?: |
false |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
64
|
Fragment?: |
true |
|
•
•
•
•
•
|
Protein |
Organism: |
Mus musculus/domesticus |
Length: |
216
|
Fragment?: |
false |
|
•
•
•
•
•
|