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Search results 6801 to 6900 out of 9662 for Egf

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Type Details Score
Publication
25902507 | J:221328
First Author: Randeria PS
Year: 2015
Journal: Proc Natl Acad Sci U S A
Title: siRNA-based spherical nucleic acids reverse impaired wound healing in diabetic mice by ganglioside GM3 synthase knockdown.
Volume: 112
Issue: 18
Pages: 5573-8
Publication
26282169 | J:225972
First Author: Soucheray M
Year: 2015
Journal: Cancer Res
Title: Intratumoral Heterogeneity in EGFR-Mutant NSCLC Results in Divergent Resistance Mechanisms in Response to EGFR Tyrosine Kinase Inhibition.
Volume: 75
Issue: 20
Pages: 4372-83
Publication
26204818 | J:226273
 
First Author: Tang Y
Year: 2015
Journal: Neuroscience
Title: EGFR signaling upregulates surface expression of the GluN2B-containing NMDA receptor and contributes to long-term potentiation in the hippocampus.
Volume: 304
Pages: 109-21
Publication
15831486 | J:230631
First Author: Van Slyke P
Year: 2005
Journal: Mol Cell Biol
Title: Dok-R mediates attenuation of epidermal growth factor-dependent mitogen-activated protein kinase and Akt activation through processive recruitment of c-Src and Csk.
Volume: 25
Issue: 9
Pages: 3831-41
Publication
26546150 | J:231938
 
First Author: Meabon JS
Year: 2016
Journal: Mol Cell Neurosci
Title: Intracellular LINGO-1 negatively regulates Trk neurotrophin receptor signaling.
Volume: 70
Pages: 1-10
Publication
27335069 | J:236484
First Author: Hao X
Year: 2016
Journal: Biol Reprod
Title: Epidermal Growth Factor-Mobilized Intracellular Calcium of Cumulus Cells Decreases Natriuretic Peptide Receptor 2 Affinity for Natriuretic Peptide Type C and Induces Oocyte Meiotic Resumption in the Mouse.
Volume: 95
Issue: 2
Pages: 45
Publication
28771744 | J:245840
First Author: Jitsukawa S
Year: 2017
Journal: J Pathol
Title: Loss of sorting nexin 5 stabilizes internalized growth factor receptors to promote thyroid cancer progression.
Volume: 243
Issue: 3
Pages: 342-353
Publication
25298208 | J:247261
First Author: Dai K
Year: 2015
Journal: Immunology
Title: Amphiregulin promotes the immunosuppressive activity of intrahepatic CD4+ regulatory T cells to impair CD8+ T-cell immunity against hepatitis B virus infection.
Volume: 144
Issue: 3
Pages: 506-517
Publication
28694172 | J:249784
 
First Author: Zhang W
Year: 2017
Journal: Neuroscience
Title: Macrophage migration inhibitory factor mediates viability and apoptosis of PVM/Ms through PI3K/Akt pathway.
Volume: 360
Pages: 220-229
Publication
28596235 | J:255642
First Author: Hsu JY
Year: 2017
Journal: FASEB J
Title: Epidermal growth factor-induced pyruvate dehydrogenase kinase 1 expression enhances head and neck squamous cell carcinoma metastasis via up-regulation of fibronectin.
Volume: 31
Issue: 10
Pages: 4265-4276
Publication
27300306 | J:253362
First Author: Islam MS
Year: 2016
Journal: Br J Pharmacol
Title: Epidermal growth factor is a critical regulator of the cytokine IL-33 in intestinal epithelial cells.
Volume: 173
Issue: 16
Pages: 2532-42
Publication
20190463 | J:260662
First Author: Ichise T
Year: 2010
Journal: Cell Struct Funct
Title: Humanized gene replacement in mice reveals the contribution of cancer stroma-derived HB-EGF to tumor growth.
Volume: 35
Issue: 1
Pages: 3-13
Publication
29904166 | J:262999
First Author: Dubé PE
Year: 2018
Journal: Sci Rep
Title: Pharmacological activation of epidermal growth factor receptor signaling inhibits colitis-associated cancer in mice.
Volume: 8
Issue: 1
Pages: 9119
Publication
29321207 | J:262782
First Author: Mapes J
Year: 2018
Journal: J Biol Chem
Title: Aberrantly high expression of the CUB and zona pellucida-like domain-containing protein 1 (CUZD1) in mammary epithelium leads to breast tumorigenesis.
Volume: 293
Issue: 8
Pages: 2850-2864
Publication
21653881 | J:263008
First Author: Meza-Carmen V
Year: 2011
Journal: Proc Natl Acad Sci U S A
Title: Regulation of growth factor receptor degradation by ADP-ribosylation factor domain protein (ARD) 1.
Volume: 108
Issue: 26
Pages: 10454-9
Publication
29523688 | J:263696
First Author: Gosney JA
Year: 2018
Journal: J Biol Chem
Title: Proteomics reveals novel protein associations with early endosomes in an epidermal growth factor-dependent manner.
Volume: 293
Issue: 16
Pages: 5895-5908
Publication
30217816 | J:272896
First Author: Breit A
Year: 2018
Journal: J Biol Chem
Title: Insulin-like growth factor-1 acts as a zeitgeber on hypothalamic circadian clock gene expression via glycogen synthase kinase-3β signaling.
Volume: 293
Issue: 44
Pages: 17278-17290
Publication
28608461 | J:273364
First Author: Namba H
Year: 2017
Journal: J Neurochem
Title: Epidermal growth factor signals attenuate phenotypic and functional development of neocortical GABA neurons.
Volume: 142
Issue: 6
Pages: 886-900
Publication
31182802 | J:279859
First Author: Chmielewski M
Year: 2019
Journal: Sci Rep
Title: FimH-based display of functional eukaryotic proteins on bacteria surfaces.
Volume: 9
Issue: 1
Pages: 8410
Publication
32201074 | J:298477
First Author: Ogawa M
Year: 2020
Journal: Biochem Biophys Res Commun
Title: Contribution of extracellular O-GlcNAc to the stability of folded epidermal growth factor-like domains and Notch1 trafficking.
Volume: 526
Issue: 1
Pages: 184-190
Publication
32369572 | J:301390
First Author: Fang T
Year: 2020
Journal: Blood
Title: Epidermal growth factor receptor-dependent DNA repair promotes murine and human hematopoietic regeneration.
Volume: 136
Issue: 4
Pages: 441-454
Publication
24003223 | J:344920
First Author: Taniguchi T
Year: 2013
Journal: J Biol Chem
Title: A brain-specific Grb2-associated regulator of extracellular signal-regulated kinase (Erk)/mitogen-activated protein kinase (MAPK) (GAREM) subtype, GAREM2, contributes to neurite outgrowth of neuroblastoma cells by regulating Erk signaling.
Volume: 288
Issue: 41
Pages: 29934-42
Publication
26055326 | J:317620
First Author: Ha Thi HT
Year: 2015
Journal: Mol Cell Biol
Title: Smad7 Modulates Epidermal Growth Factor Receptor Turnover through Sequestration of c-Cbl.
Volume: 35
Issue: 16
Pages: 2841-50
Publication
31434808 | J:308979
 
First Author: Yu M
Year: 2019
Journal: JCI Insight
Title: Nononcogenic restoration of the intestinal barrier by E. coli-delivered human EGF.
Volume: 4
Issue: 16
Publication
26956044 | J:309327
First Author: Hsu TI
Year: 2016
Journal: Oncotarget
Title: Positive feedback regulation between IL10 and EGFR promotes lung cancer formation.
Volume: 7
Issue: 15
Pages: 20840-54
Publication
23706492 | J:315501
First Author: Marino D
Year: 2013
Journal: J Dermatol Sci
Title: Activation of the epidermal growth factor receptor promotes lymphangiogenesis in the skin.
Volume: 71
Issue: 3
Pages: 184-94
Publication
34169071 | J:314173
 
First Author: Schaberg E
Year: 2021
Journal: Front Cell Dev Biol
Title: Sulfation of Glycosaminoglycans Modulates the Cell Cycle of Embryonic Mouse Spinal Cord Neural Stem Cells.
Volume: 9
Pages: 643060
Publication
28345658 | J:314658
 
First Author: Arai C
Year: 2017
Journal: Sci Rep
Title: Nephronectin plays critical roles in Sox2 expression and proliferation in dental epithelial stem cells via EGF-like repeat domains.
Volume: 7
Pages: 45181
Publication
25072283 | J:316510
First Author: Sreekumar BK
Year: 2014
Journal: Pancreas
Title: Polarization of the vacuolar adenosine triphosphatase delineates a transition to high-grade pancreatic intraepithelial neoplasm lesions.
Volume: 43
Issue: 8
Pages: 1256-63
Publication
26527747 | J:316572
First Author: Bae JA
Year: 2016
Journal: Clin Cancer Res
Title: Elevated Coexpression of KITENIN and the ErbB4 CYT-2 Isoform Promotes the Transition from Colon Adenoma to Carcinoma Following APC loss.
Volume: 22
Issue: 5
Pages: 1284-94
Publication
28186140 | J:312843
 
First Author: Shi Y
Year: 2017
Journal: Sci Rep
Title: Activated niacin receptor HCA2 inhibits chemoattractant-mediated macrophage migration via Gβγ/PKC/ERK1/2 pathway and heterologous receptor desensitization.
Volume: 7
Pages: 42279
Publication
23954207 | J:315790
First Author: Castro-Sánchez L
Year: 2013
Journal: Int J Biochem Cell Biol
Title: Regulation of 15-hydroxyprostaglandin dehydrogenase expression in hepatocellular carcinoma.
Volume: 45
Issue: 11
Pages: 2501-11
Publication
35149991 | J:325427
First Author: Karasawa Y
Year: 2022
Journal: Dev Growth Differ
Title: Growth factor dependence of the proliferation and survival of cultured lacrimal gland epithelial cells isolated from late-embryonic mice.
Volume: 64
Issue: 3
Pages: 138-149
Publication
38746443 | J:358799
     
First Author: Li X
Year: 2024
Journal: bioRxiv
Title: Multi-omics delineate growth factor network underlying exercise effects in an Alzheimer's mouse model.
Publication
23562833 | J:356278
First Author: Daynac M
Year: 2013
Journal: Stem Cell Res
Title: Quiescent neural stem cells exit dormancy upon alteration of GABAAR signaling following radiation damage.
Volume: 11
Issue: 1
Pages: 516-28
Publication
- | J:101679
     
First Author: Deltagen Inc
Year: 2005
Journal: MGI Direct Data Submission
Title: NIH initiative supporting placement of Deltagen, Inc. mice into public repositories
Protein
Q811K6
Organism: Mus musculus/domesticus
Length: 401  
Fragment?: true
Protein
Q8BMI5
Organism: Mus musculus/domesticus
Length: 219  
Fragment?: true
Protein
A0A1Y7VLS8
Organism: Mus musculus/domesticus
Length: 247  
Fragment?: true
Publication
29799838 | J:262823
First Author: Kasowitz SD
Year: 2018
Journal: PLoS Genet
Title: Nuclear m6A reader YTHDC1 regulates alternative polyadenylation and splicing during mouse oocyte development.
Volume: 14
Issue: 5
Pages: e1007412
Protein
P97766
Organism: Mus musculus/domesticus
Length: 202  
Fragment?: false
Publication
20100865 | J:161729
First Author: Kim J
Year: 2010
Journal: Mol Cell Biol
Title: The SAM domains of Anks family proteins are critically involved in modulating the degradation of EphA receptors.
Volume: 30
Issue: 7
Pages: 1582-92
Protein
P51865
Organism: Mus musculus/domesticus
Length: 171  
Fragment?: false
Protein
Q7TQ06
Organism: Mus musculus/domesticus
Length: 171  
Fragment?: false
Protein
A0A0G2JGR6
Organism: Mus musculus/domesticus
Length: 90  
Fragment?: true
Protein
Q3UZP8
Organism: Mus musculus/domesticus
Length: 171  
Fragment?: false
Publication
11373616 | -
First Author: Jeon H
Year: 2001
Journal: Nat Struct Biol
Title: Implications for familial hypercholesterolemia from the structure of the LDL receptor YWTD-EGF domain pair.
Volume: 8
Issue: 6
Pages: 499-504
Publication
15363809 | -
First Author: Yurchenco PD
Year: 2004
Journal: Curr Opin Cell Biol
Title: Assembly and tissue functions of early embryonic laminins and netrins.
Volume: 16
Issue: 5
Pages: 572-9
Publication
3119223 | -
First Author: Kelley MR
Year: 1987
Journal: Cell
Title: Mutations altering the structure of epidermal growth factor-like coding sequences at the Drosophila Notch locus.
Volume: 51
Issue: 4
Pages: 539-48
Publication
7697721 | -
First Author: Lindsell CE
Year: 1995
Journal: Cell
Title: Jagged: a mammalian ligand that activates Notch1.
Volume: 80
Issue: 6
Pages: 909-17
Publication
15862129 | -
First Author: Xu H
Year: 2005
Journal: BMC Cell Biol
Title: A novel EB-1/AIDA-1 isoform, AIDA-1c, interacts with the Cajal body protein coilin.
Volume: 6
Issue: 1
Pages: 23
Protein Domain
IPR004457 | Znf_ZPR1
Type: Domain
Description: Zinc finger (Znf) domains are relatively small protein motifs which contain multiple finger-like protrusions that make tandem contacts with their target molecule. Some of these domains bind zinc, but many do not; instead binding other metals such as iron, or no metal at all. For example, some family members form salt bridges to stabilise the finger-like folds. They were first identified as a DNA-binding motif in transcription factor TFIIIA from Xenopus laevis (African clawed frog), however they are now recognised to bind DNA, RNA, protein and/or lipid substrates [, , , , ]. Their binding properties depend on the amino acid sequence of the finger domains and of the linker between fingers, as well as on the higher-order structures and the number of fingers. Znf domains are often found in clusters, where fingers can have different binding specificities. There are many superfamilies of Znf motifs, varying in both sequence and structure. They display considerable versatility in binding modes, even between members of the same class (e.g. some bind DNA, others protein), suggesting that Znf motifs are stable scaffolds that have evolved specialised functions. For example, Znf-containing proteins function in gene transcription, translation, mRNA trafficking, cytoskeleton organisation, epithelial development, cell adhesion, protein folding, chromatin remodelling and zinc sensing, to name but a few []. Zinc-binding motifs are stable structures, and they rarely undergo conformational changes upon binding their target. This entry represents ZPR1-type zinc finger domains. An orthologous protein found once in each of the completed archaeal genomes corresponds to a zinc finger-containing domain repeated as the N-terminal and C-terminal halves of themouse protein ZPR1. ZPR1 is an experimentally proven zinc-binding protein that binds the tyrosine kinase domain of the epidermal growth factor receptor (EGFR); binding is inhibited by EGF stimulation and tyrosine phosphorylation, and activation by EGF is followed by some redistribution of ZPR1 to the nucleus. By analogy, other proteins with the ZPR1 zinc finger domain may be regulatory proteins that sense protein phosphorylation state and/or participate in signal transduction (see also ).Deficiencies in ZPR1 may contribute to neurodegenerative disorders. ZPR1 appears to be down-regulated in patients with spinal muscular atrophy (SMA), a disease characterised by degeneration of the alpha-motor neurons in the spinal cord that can arise from mutations affecting the expression of Survival Motor Neurons (SMN) []. ZPR1 interacts with complexes formed by SMN [], and may act as a modifier that effects the severity of SMA.
Protein Domain
IPR002172 | LDrepeatLR_classA_rpt
Type: Repeat
Description: The low-density lipoprotein receptor (LDLR) is the major cholesterol-carrying lipoprotein of plasma, acting to regulate cholesterol homeostasis in mammalian cells. The LDL receptor binds LDL and transports it into cells by acidic endocytosis. In order to be internalized, the receptor-ligand complex must first cluster into clathrin-coated pits. Once inside the cell, the LDLR separates from its ligand, which is degraded in the lysosomes, while the receptor returns to the cell surface []. The internal dissociation of the LDLR with its ligand is mediated by proton pumps within the walls of the endosome that lower the pH. The LDLR is a multi-domain protein, containing: The ligand-binding domain contains seven or eight 40-amino acid LDLR class A (cysteine-rich) repeats, each of which contains a coordinated calcium ion and six cysteine residues involved in disulphide bond formation []. Similar domains have been found in other extracellular and membrane proteins []. The second conserved region contains two EGF repeats, followed by six LDLR class B (YWTD) repeats, and another EGF repeat. The LDLR class B repeats each contain a conserved YWTD motif, and is predicted to form a β-propeller structure []. This region is critical for ligand release and recycling of the receptor [].The third domain is rich in serine and threonine residues and contains clustered O-linked carbohydrate chains.The fourth domain is the hydrophobic transmembrane region.The fifth domain is the cytoplasmic tail that directs the receptor to clathrin-coated pits.LDLR is closely related in structure to several other receptors, including LRP1, LRP1b, megalin/LRP2, VLDL receptor, lipoprotein receptor, MEGF7/LRP4, and LRP8/apolipoprotein E receptor2); these proteins participate in a wide range of physiological processes, including the regulation of lipid metabolism, protection against atherosclerosis, neurodevelopment, and transport of nutrients and vitamins [].This entry represents the LDLR class A (cysteine-rich) repeat, which contains 6 disulphide-bound cysteines and a highly conserved cluster of negatively charged amino acids, of which many are clustered on one face of the module []. In LDL receptors, the class A domains form the binding site for LDL and calcium. The acidic residues between the fourth and sixth cysteines are important for high-affinity binding of positively charged sequences in LDLR's ligands. The repeat consists of a β-hairpin structure followed by a series of beta turns. In the absence of calcium, LDL-A domains are unstructured; the bound calcium ion imparts structural integrity. Following these repeats is a 350 residue domain that resembles part of the epidermal growth factor (EGF) precursor. Numerous familial hypercholesterolemia mutations of the LDL receptor alter the calcium coordinating residue of LDL-A domains or other crucial scaffolding residues.
Protein Domain
IPR000033 | LDLR_classB_rpt
Type: Repeat
Description: The low-density lipoprotein receptor (LDLR) is the major cholesterol-carrying lipoprotein of plasma, acting to regulate cholesterol homeostasis in mammalian cells. The LDL receptor binds LDL and transports it into cells by acidic endocytosis. In order to be internalized, the receptor-ligand complex must first cluster into clathrin-coated pits. Once inside the cell, the LDLR separates from its ligand, which is degraded in the lysosomes,while the receptor returns to the cell surface []. The internal dissociation of the LDLR with its ligand is mediated by proton pumps within the walls of the endosome that lower the pH. The LDLR is a multi-domain protein, containing: The ligand-binding domain contains seven or eight 40-amino acid LDLR class A (cysteine-rich) repeats, each of which contains a coordinated calcium ion and six cysteine residues involved in disulphide bond formation []. Similar domains have been found in other extracellular and membrane proteins []. The second conserved region contains two EGF repeats, followed by six LDLR class B (YWTD) repeats, and another EGF repeat. The LDLR class B repeats each contain a conserved YWTD motif, and is predicted to form a β-propeller structure []. This region is critical for ligand release and recycling of the receptor [].The third domain is rich in serine and threonine residues and contains clustered O-linked carbohydrate chains.The fourth domain is the hydrophobic transmembrane region.The fifth domain is the cytoplasmic tail that directs the receptor to clathrin-coated pits.LDLR is closely related in structure to several other receptors, including LRP1, LRP1b, megalin/LRP2, VLDL receptor, lipoprotein receptor, MEGF7/LRP4, and LRP8/apolipoprotein E receptor2); these proteins participate in a wide range of physiological processes, including the regulation of lipid metabolism, protection against atherosclerosis, neurodevelopment, and transport of nutrients and vitamins [].This entry represents the LDLR classB (YWTD) repeat, the structure of which has been solved []. The six YWTD repeats together fold into a six-bladed β-propeller. Each blade of the propeller consists of four antiparallel β-strands; the innermost strand of each blade is labeled 1 and the outermost strand, 4. The sequence repeats are offset with respect to the blades of the propeller, such that any given 40-residue YWTD repeat spans strands 24 of one propeller blade and strand 1 of the subsequent blade. This offset ensures circularization of the propeller because the last strand of the final sequence repeat acts as an innermost strand 1 of the blade that harbors strands 24 from the first sequence repeat. The repeat is found in a variety of proteins that include, vitellogenin receptor from Drosophila melanogaster, low-density lipoprotein (LDL) receptor [], preproepidermal growth factor, and nidogen (entactin).
Publication
30940800 | J:273296
First Author: Kaiser K
Year: 2019
Journal: Nat Commun
Title: WNT5A is transported via lipoprotein particles in the cerebrospinal fluid to regulate hindbrain morphogenesis.
Volume: 10
Issue: 1
Pages: 1498
Publication
32907846 | J:297063
 
First Author: Najarro EH
Year: 2020
Journal: Development
Title: Dual regulation of planar polarization by secreted Wnts and Vangl2 in the developing mouse cochlea.
Volume: 147
Issue: 19
Publication
31152445 | J:282827
First Author: Tulloch AJ
Year: 2019
Journal: J Comp Neurol
Title: Diverse spinal commissural neuron populations revealed by fate mapping and molecular profiling using a novel Robo3Cre mouse.
Volume: 527
Issue: 18
Pages: 2948-2972
Publication
26902285 | J:256712
First Author: Yu C
Year: 2016
Journal: Cell Res
Title: Oocyte-expressed yes-associated protein is a key activator of the early zygotic genome in mouse.
Volume: 26
Issue: 3
Pages: 275-87
Protein
A0A338P795
Organism: Mus musculus/domesticus
Length: 486  
Fragment?: false
Publication
32253237 | J:293624
 
First Author: Lee S
Year: 2020
Journal: Development
Title: Cleft lip and cleft palate in Esrp1 knockout mice is associated with alterations in epithelial-mesenchymal crosstalk.
Volume: 147
Issue: 21
Publication
33141892 | J:298302
First Author: Ru J
Year: 2020
Journal: Invest Ophthalmol Vis Sci
Title: Malformation of Tear Ducts Underlies the Epiphora and Precocious Eyelid Opening in Prickle 1 Mutant Mice: Genetic Implications for Tear Duct Genesis.
Volume: 61
Issue: 13
Pages: 6
Publication
22615412 | J:184840
First Author: Helbig C
Year: 2012
Journal: Proc Natl Acad Sci U S A
Title: Notch controls the magnitude of T helper cell responses by promoting cellular longevity.
Volume: 109
Issue: 23
Pages: 9041-6
Publication
27107132 | J:261833
 
First Author: Koenig SN
Year: 2016
Journal: J Am Heart Assoc
Title: Endothelial Notch1 Is Required for Proper Development of the Semilunar Valves and Cardiac Outflow Tract.
Volume: 5
Issue: 4
Publication
17158336 | J:130243
First Author: Takeshita K
Year: 2007
Journal: Circ Res
Title: Critical role of endothelial Notch1 signaling in postnatal angiogenesis.
Volume: 100
Issue: 1
Pages: 70-8
Publication
26062937 | J:224078
First Author: Liu Z
Year: 2015
Journal: Development
Title: The intracellular domains of Notch1 and Notch2 are functionally equivalent during development and carcinogenesis.
Volume: 142
Issue: 14
Pages: 2452-63
Publication
18297083 | J:233142
First Author: Hilton MJ
Year: 2008
Journal: Nat Med
Title: Notch signaling maintains bone marrow mesenchymal progenitors by suppressing osteoblast differentiation.
Volume: 14
Issue: 3
Pages: 306-14
Publication
24353058 | J:206586
First Author: Boyle SC
Year: 2014
Journal: Development
Title: Notch signaling is required for the formation of mesangial cells from a stromal mesenchyme precursor during kidney development.
Volume: 141
Issue: 2
Pages: 346-54
Publication
22378872 | J:182690
First Author: Shamir A
Year: 2012
Journal: J Neurosci
Title: The importance of the NRG-1/ErbB4 pathway for synaptic plasticity and behaviors associated with psychiatric disorders.
Volume: 32
Issue: 9
Pages: 2988-97
Publication
32636481 | J:294057
First Author: Hastings RL
Year: 2020
Journal: Sci Rep
Title: Morphological remodeling during recovery of the neuromuscular junction from terminal Schwann cell ablation in adult mice.
Volume: 10
Issue: 1
Pages: 11132
Publication
30943416 | J:281302
First Author: Takeoka A
Year: 2019
Journal: Cell Rep
Title: Functional Local Proprioceptive Feedback Circuits Initiate and Maintain Locomotor Recovery after Spinal Cord Injury.
Volume: 27
Issue: 1
Pages: 71-85.e3
Publication
17289941 | J:118365
First Author: Guy J
Year: 2007
Journal: Science
Title: Reversal of neurological defects in a mouse model of Rett syndrome.
Volume: 315
Issue: 5815
Pages: 1143-7
Publication
30802297 | J:277135
First Author: Mamareli P
Year: 2019
Journal: Eur J Immunol
Title: Epithelium-specific MyD88 signaling, but not DCs or macrophages, control acute intestinal infection with Clostridium difficile.
Volume: 49
Issue: 5
Pages: 747-757
Publication
32561725 | J:290119
First Author: Soleilhavoup C
Year: 2020
Journal: Nat Commun
Title: Nolz1 expression is required in dopaminergic axon guidance and striatal innervation.
Volume: 11
Issue: 1
Pages: 3111
Protein
Q6PGD0
Organism: Mus musculus/domesticus
Length: 223  
Fragment?: false
Protein
O35181
Organism: Mus musculus/domesticus
Length: 713  
Fragment?: false
Protein
Q9JI71
Organism: Mus musculus/domesticus
Length: 686  
Fragment?: false
Protein
Q9WTX4
Organism: Mus musculus/domesticus
Length: 115  
Fragment?: false
Publication
10025398 | -
First Author: Munger JS
Year: 1999
Journal: Cell
Title: The integrin alpha v beta 6 binds and activates latent TGF beta 1: a mechanism for regulating pulmonary inflammation and fibrosis.
Volume: 96
Issue: 3
Pages: 319-28
Protein
Q8VEI3
Organism: Mus musculus/domesticus
Length: 412  
Fragment?: false
Protein
Q8BJ48
Organism: Mus musculus/domesticus
Length: 517  
Fragment?: false
Publication
17125258 | -
First Author: Calvanese L
Year: 2006
Journal: J Med Chem
Title: Solution structure of mouse Cripto CFC domain and its inactive variant Trp107Ala.
Volume: 49
Issue: 24
Pages: 7054-62
Protein
B0LAC1
Organism: Mus musculus/domesticus
Length: 65  
Fragment?: true
Protein
Q99PJ3
Organism: Mus musculus/domesticus
Length: 165  
Fragment?: true
Protein
A0A0G2JG15
Organism: Mus musculus/domesticus
Length: 46  
Fragment?: true
Protein
A0A494B9P8
Organism: Mus musculus/domesticus
Length: 109  
Fragment?: true
Protein
A0A087WSS3
Organism: Mus musculus/domesticus
Length: 108  
Fragment?: true
Protein
A2AML9
Organism: Mus musculus/domesticus
Length: 151  
Fragment?: true
Protein
G3V023
Organism: Mus musculus/domesticus
Length: 689  
Fragment?: false
Protein
G3UYV5
Organism: Mus musculus/domesticus
Length: 133  
Fragment?: true
Protein
Q810X2
Organism: Mus musculus/domesticus
Length: 79  
Fragment?: true
Protein
Q3TWM3
Organism: Mus musculus/domesticus
Length: 517  
Fragment?: false
Protein
Q8BX76
Organism: Mus musculus/domesticus
Length: 296  
Fragment?: false
Protein
D3YW49
Organism: Mus musculus/domesticus
Length: 495  
Fragment?: false
Protein
Q8C4T5
Organism: Mus musculus/domesticus
Length: 244  
Fragment?: true
Protein
B9EHF8
Organism: Mus musculus/domesticus
Length: 714  
Fragment?: false
Protein
Q3U273
Organism: Mus musculus/domesticus
Length: 441  
Fragment?: true
Protein
Q3TDF9
Organism: Mus musculus/domesticus
Length: 517  
Fragment?: false
Protein
A0A571BD72
Organism: Mus musculus/domesticus
Length: 239  
Fragment?: true
Protein
B7ZN23
Organism: Mus musculus/domesticus
Length: 699  
Fragment?: false
Protein
Q8BR22
Organism: Mus musculus/domesticus
Length: 80  
Fragment?: false




MouseMine is a collaboration between MGI at The Jackson Laboratory and the InterMine project at the Cambridge Systems Biology Centre. MouseMine is funded through a grant from the NIH/NHGRI.The Jackson Laboratory makes no representation about the suitability or accuracy of this software or data for any purpose, and makes no warranties, either express or implied, including merchantability and fitness for a particular purpose or that the use of this software or data will not infringe any third party patents, copyrights, trademarks, or other rights. the software and data are provided "as is". This software and data are provided to enhance knowledge and encourage progress in the scientific community and are to be used only for research and educational purposes. Any reproduction or use for commercial purpose is prohibited without the prior express written permission of the Jackson Laboratory.

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