about
Blocking of monocyte chemoattractant protein-1 during tubulointerstitial nephritis resulted in delayed neutrophil clearanceFunctions of cell surface heparan sulfate proteoglycansEXTL3 mutations cause skeletal dysplasia, immune deficiency, and developmental delay.Modulation of syndecan-1 shedding after hemorrhagic shock and resuscitation.Molecular and cellular mechanisms of ectodomain sheddingRole of glycosaminoglycans in infectious diseaseProteoglycans in host-pathogen interactions: molecular mechanisms and therapeutic implicationsPlasma-Mediated Gut Protection After Hemorrhagic Shock is Lessened in Syndecan-1-/- Mice.The endothelial glycocalyx in syndecan-1 deficient mice.Staphylococcus aureus beta-toxin induces lung injury through syndecan-1.Fresh frozen plasma lessens pulmonary endothelial inflammation and hyperpermeability after hemorrhagic shock and is associated with loss of syndecan 1Cell surface-anchored syndecan-1 ameliorates intestinal inflammation and neutrophil transmigration in ulcerative colitis.Diverse functions of glycosaminoglycans in infectious diseases.Molecular functions of syndecan-1 in disease.Shedding of cell membrane-bound proteoglycans.Shedding of Syndecan-1/CXCL1 Complexes by Matrix Metalloproteinase 7 Functions as an Epithelial Checkpoint of Neutrophil Activation.Syndecan 1 shedding contributes to Pseudomonas aeruginosa sepsis.Syndecan-1 displays a protective role in aortic aneurysm formation by modulating T cell-mediated responses.Molecular cloning and expression of the gene for elastin-binding protein (ebpS) in Staphylococcus aureus.Alpha-toxin facilitates the generation of CXC chemokine gradients and stimulates neutrophil homing in Staphylococcus aureus pneumonia.Polyclonal antibodies to tropoelastin and the specific detection and measurement of tropoelastin in vitro.Isolation and functional analysis of syndecans.The N-terminal A domain of fibronectin-binding proteins A and B promotes adhesion of Staphylococcus aureus to elastin.Loss of Syndecan-1 Abrogates the Pulmonary Protective Phenotype Induced by Plasma After Hemorrhagic Shock.Activation of syndecan-1 ectodomain shedding by Staphylococcus aureus alpha-toxin and beta-toxin.Syndecan-1 limits the progression of liver injury and promotes liver repair in acetaminophen-induced liver injury in mice.CD138 mediates selection of mature plasma cells by regulating their survival.The elastin-binding protein of Staphylococcus aureus (EbpS) is expressed at the cell surface as an integral membrane protein and not as a cell wall-associated protein.Protamine sulfate reduces the susceptibility of thermally injured mice to Pseudomonas aeruginosa infection.Matrilysin shedding of syndecan-1 regulates chemokine mobilization and transepithelial efflux of neutrophils in acute lung injury.Syndecan-1 and heparanase: potential markers for activity evaluation and differential diagnosis of Crohn's disease.Exploitation of syndecan-1 shedding by Pseudomonas aeruginosa enhances virulenceSyndecan-1 Shedding Is Enhanced by LasA, a Secreted Virulence Factor ofPseudomonas aeruginosaCharacterization of the Elastin Binding Domain in the Cell-surface 25-kDa Elastin-binding Protein ofStaphylococcus aureus(EbpS)Lysozyme Binds to Elastin and Protects Elastin from Elastase-Mediated DegradationBinding and degradation of elastin by the staphylolytic enzyme lysostaphinHost syndecan-1 promotes listeriosis by inhibiting intravascular neutrophil extracellular traps
P50
Q28574502-4EB4E1DD-7FA9-44D8-B143-DC8A6F47F4C8Q29618521-F60AE65D-148C-423F-A93A-E51570017EFDQ33112682-9522D28C-A8D6-491B-A6A4-43D7728EB857Q34008848-BE333602-B9A7-49FC-880B-E938A519EA92Q36210626-AF85747D-1697-47F4-BDC5-CBD1CAC4EC6EQ36220338-DF97C4F2-E1CB-45C3-B8CC-6EC1F02F251FQ36253322-6BF6FCF8-A9EE-451F-B46E-059033B6BC20Q36752489-9E44C889-4FF2-416F-99F8-53C20E03A45FQ36769963-AA028F31-D326-4FC9-A179-57B2B398F5D5Q37071869-B408CD82-C60C-4A42-83AC-2AF6CDC246F2Q37150467-72F051BB-B0C1-4FE7-BF41-F70CC7A700EDQ37539888-47814E8C-C95A-4293-887D-C5EB66B188E6Q37784318-8E13AF3B-8D1D-4946-8ACE-6A9E2461F47AQ37950202-8B47F9B7-1FC0-469B-996B-8F4B360EF687Q37976599-60DFCDA2-5739-48F7-9687-B50ED4B02ADBQ39953992-450D154E-38DD-41CA-80E9-910AF081793EQ40381981-42974447-841B-4419-BB05-D135812412A6Q42249484-2FDF7E59-BD91-4472-ADFF-2070BE59AD10Q42632155-2FE8B6B2-5A9E-441A-9C40-451FC490AC00Q43853782-CE690795-F1C2-4D1D-BFE1-84706116E165Q44273851-89531861-2542-4CA2-9C82-DEBADBA5DFF4Q47223606-96FFEC92-33B4-4166-95B5-7D758AE1C840Q47245768-EEF6F749-19BF-473D-90FD-CDCD618EDDA6Q47339681-07AB6028-441D-4EE2-97C8-5259392388EBQ47428605-4FA509CC-B4CE-48D6-9A95-EC0059F8D480Q47881177-7FDA4766-3769-4B5B-A10B-AFA019ACD4C4Q47927555-484281C2-F16B-4A83-9AD3-7CE3D8789475Q48335553-38BA07BE-B664-44EC-A2E5-65BF463CA4BBQ53628077-8744E5F1-766D-4612-A8A9-FF0487544CCFQ53662097-EBCE9949-3FDC-408C-9BC0-01C5A3BD6096Q54267579-2C029F88-1E01-45FD-ABA2-8F61F39201E5Q59092900-A6ACD998-FDE9-43BA-A9AA-2F955F6A4D0AQ60148130-698A0919-BE9C-46FC-BAAA-30A2F1069FE0Q60148132-17CE3153-33B5-4D09-AEA6-F5397DFE720CQ60148137-106036FA-BBDF-45C3-B809-25B2161DAED3Q60148140-89CCFC36-7276-4CD7-B302-3BD248DAB44CQ95846040-DDA8724E-994F-4BEB-BBEE-04ED7F695A6D
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Pyong Woo Park
@ast
Pyong Woo Park
@en
Pyong Woo Park
@es
Pyong Woo Park
@nl
Pyong Woo Park
@sl
type
label
Pyong Woo Park
@ast
Pyong Woo Park
@en
Pyong Woo Park
@es
Pyong Woo Park
@nl
Pyong Woo Park
@sl
prefLabel
Pyong Woo Park
@ast
Pyong Woo Park
@en
Pyong Woo Park
@es
Pyong Woo Park
@nl
Pyong Woo Park
@sl
P106
P1153
7202425133
P31
P496
0000-0002-7979-4979
P569
2000-01-01T00:00:00Z