The evolution of the class A scavenger receptorsAn Introduction to Automated Flow Cytometry Gating Tools and Their ImplementationA guide to bioinformatics for immunologistsImmunomodulatory properties of defensins and cathelicidinsBroadly Neutralizing Hemagglutinin Stalk-Specific Antibodies Induce Potent Phagocytosis of Immune Complexes by Neutrophils in an Fc-Dependent Manner.The unique immunological features of heparin-induced thrombocytopenia.An accessory to the 'Trinity': SR-As are essential pathogen sensors of extracellular dsRNA, mediating entry and leading to subsequent type I IFN responses.Age-Associated Microbial Dysbiosis Promotes Intestinal Permeability, Systemic Inflammation, and Macrophage Dysfunction.The relation between DNA methylation patterns and serum cytokine levels in community-dwelling adults: a preliminary study.Characterization of inflammatory responses during intranasal colonization with Streptococcus pneumoniae.Indigenous enteric eosinophils control DCs to initiate a primary Th2 immune response in vivoHost cytokine responses distinguish invasive from airway isolates of the Streptococcus milleri/anginosis group.Standardizing scavenger receptor nomenclatureA naturally occurring transcript variant of MARCO reveals the SRCR domain is critical for function.The polyfunctionality of human memory CD8+ T cells elicited by acute and chronic virus infections is not influenced by ageComposition and immunological significance of the upper respiratory tract microbiota.The loss of topography in the microbial communities of the upper respiratory tract in the elderly.Culture and molecular-based profiles show shifts in bacterial communities of the upper respiratory tract that occur with age.Microneutralization assay titres correlate with protection against seasonal influenza H1N1 and H3N2 in children.The Evolution of the Scavenger Receptor Cysteine-Rich Domain of the Class A Scavenger Receptors.Infection in an aging population.TNF Drives Monocyte Dysfunction with Age and Results in Impaired Anti-pneumococcal Immunity.Streptococcus pneumoniae Colonization Disrupts the Microbial Community within the Upper Respiratory Tract of Aging MiceImpact of LL-37 on anti-infective immunity.A re-evaluation of the role of host defence peptides in mammalian immunity.MARCO is required for TLR2- and Nod2-mediated responses to Streptococcus pneumoniae and clearance of pneumococcal colonization in the murine nasopharynx.Immunosenescence and novel vaccination strategies for the elderly.Blood CD33(+)HLA-DR(-) myeloid-derived suppressor cells are increased with age and a history of cancerMacrophage receptors implicated in the "adaptive" form of innate immunity.The Molecular Structure of Human Red Blood Cell Membranes from Highly Oriented, Solid Supported Multi-Lamellar Membranes.The macrophage.Microvesicles: ubiquitous contributors to infection and immunity.Adenovirus E1A directly targets the E2F/DP-1 complex.Age-associated metabolic dysregulation in bone marrow-derived macrophages stimulated with lipopolysaccharideAn investigation of scavenger receptor A mediated leukocyte binding to polyanionic and uncharged polymer hydrogels.Latent TGF-β1 is compartmentalized between blood and seminal plasma of HIV-positive men and its activation in semen is negatively correlated with viral load and immune activation.A macrophage-stimulating compound from a screen of microbial natural products.On-going Mechanical Damage from Mastication Drives Homeostatic Th17 Cell Responses at the Oral BarrierHIV-1 gp120 induces TLR2- and TLR4-mediated innate immune activation in human female genital epithelium.Comprehensive and simultaneous coverage of lipid and polar metabolites for endogenous cellular metabolomics using HILIC-TOF-MS
P50
Q21284029-AF8F636D-FE92-46CD-B119-5D3F2BEBB8FDQ26797342-6FE0B149-45CF-4B11-A99F-4233DDDE80C5Q27024134-97C8A047-A8AC-484E-9B33-A2C752ECC2C5Q28257840-A6161C68-B53C-4336-B0DB-D803CE6DA890Q30393724-E661E727-9B31-43A5-9CA0-1C888EA82D2AQ33440626-2BBA41BB-E544-447C-833E-69C0A3B0E8E9Q33548730-1E1C0CB7-045C-4F15-84A3-9CC8E2BABDB6Q33567407-B16021C1-2B36-4C4F-9799-48700D99922DQ33823413-53453C03-8DA2-415E-BD5F-68F2318934CEQ33872655-FD9FD0DF-2C69-446F-B7FF-96B8AD621E3BQ33964249-94634E55-D515-47BE-A929-74800B2EF611Q34246158-B988B3C9-F480-4C57-967F-C7330EBFECCDQ34406276-2FA372BE-C220-459E-B011-2D5497E004B4Q34514640-D8BC1A4E-7E97-4F83-B316-772F0F25B211Q34524651-D557A72F-8BE4-4ACE-80A0-64C807D347BEQ34542383-B5B0A350-A59C-42BE-BEF2-5C0A6AC11DEEQ35112367-6AC0951D-87EB-472A-BCEC-6F76B89E23ABQ35536029-8AACE97B-D79F-4DED-BB00-283B8F664FC8Q35673054-35BC488E-26E6-46C2-BCA6-A88B8ED9E05BQ35818249-F2E42637-9A48-4BAB-8B00-56C0E620844EQ35870441-AA358149-010A-4445-A3A2-0C63F25B586AQ35894071-BAEE9515-F44F-4F14-AF17-C66C696106A2Q35898594-5943ACB2-7827-4B75-8D2F-44FE66888551Q35966461-9CAAAE53-ACDA-4373-93D1-FF63F03398B2Q36002887-30533302-61CE-492D-B2B3-6924A5D0CB35Q36487485-A41BF335-C5E0-44AB-A197-ED2AE5410927Q36962721-618B11A1-437E-4886-B09E-EF8729BE27C0Q36981510-24C2FFCE-F921-4CC7-910A-DD065E05E8BEQ37006446-24E97A81-BE22-485C-B914-B0736EBE7A5EQ37550456-6662FBD4-C8F4-479C-A85E-DED55731113AQ37977397-C74E7910-4C75-4AA0-8375-0E01C9D32D87Q38282835-81287B65-AC4A-42D6-B673-21E8F9E26597Q38286311-BF736BED-C340-456E-89D1-75A91C645158Q38774385-FC347007-B94A-42AA-AACD-9A4243BFEC2DQ38969200-C6395293-CC76-4503-8823-0ECD6F7B95FFQ38972685-96C7F0A1-9F03-4929-9127-05AD5003E3B5Q38979051-CCEE0B5A-84CA-4266-827B-D69D41D34208Q39021405-C0D7986B-F899-48E9-9452-E649238E6CD5Q39094777-944CC7CA-3DFF-44C7-ADE3-B96E763B47A0Q39756107-470CDA68-5285-4672-89F3-0EF70D30F4A0
P50
description
Canadian immunologist
@en
immunoloog
@nl
name
Dawn Bowdish
@en
Dawn Bowdish
@es
Dawn M Bowdish
@nl
type
label
Dawn Bowdish
@en
Dawn Bowdish
@es
Dawn M Bowdish
@nl
altLabel
Dawn M. Bowdish
@en
Dawn M. Bowdish
@es
Dawn M. E. Bowdish
@en
prefLabel
Dawn Bowdish
@en
Dawn Bowdish
@es
Dawn M Bowdish
@nl
P69
P101
P1960
p3LAqSAAAAAJ
P2002
MsMacrophage
P21
P27
P31
P496
0000-0001-6823-2957
P551
P569
1976-05-21T00:00:00Z