about
Electrostatic Similarity Determination Using Multiresolution Analysis.AESOP: A Python Library for Investigating Electrostatics in Protein Interactions.Energetic evaluation of binding modes in the C3d and Factor H (CCP 19-20) complex.An evaluation of Poisson-Boltzmann electrostatic free energy calculations through comparison with experimental mutagenesis data.Hybrid flagellin as a T cell independent vaccine scaffoldMolecular insights into the surface-specific arrangement of complement C5 convertase enzymes.Discovery of Small Molecules for Fluorescent Detection of Complement Activation Product C3d.Molecular dynamics in drug design: new generations of compstatin analogs.Quantitative Modeling of the Alternative Pathway of the Complement SystemPeptide redesign for inhibition of the complement system: Targeting age-related macular degeneration.Electrostatic clustering and free energy calculations provide a foundation for protein design and optimization.Viral regulators of complement activation: structure, function and evolution.Staphylococcal Immune Evasion Proteins: Structure, Function, and Host Adaptation.Let's Tie the Knot: Marriage of Complement and Adaptive Immunity in Pathogen Evasion, for Better or Worse.Molecular analysis of the interaction between staphylococcal virulence factor Sbi-IV and complement C3d.Electrostatic Interactions between Complement Regulator CD46(SCR1-2) and Adenovirus Ad11/Ad21 Fiber Protein Knob.Novel compstatin family peptides inhibit complement activation by drusen-like deposits in human retinal pigmented epithelial cell cultures.A theoretical view of the C3d:CR2 binding controversy.Virtual Screening of Chemical Compounds for Discovery of Complement C3 LigandsThe influence of TAP1 and TAP2 gene polymorphisms on TAP function and its inhibition by viral immune evasion proteinsBacterial killing by complement requires membrane attack complex formation via surface-bound C5 convertasesFunctional Characterization of Alternative and Classical Pathway C3/C5 Convertase Activity and Inhibition Using Purified Models
P50
Q30391110-51CC9E78-38C5-4CAE-84B0-7BA52CB174E5Q30401875-78F53CBF-6231-42AB-B058-45195266B4FDQ33420025-6F991026-0627-4461-BB30-0612480FED40Q33888283-1D211FE7-5591-43A8-9933-7B86B825D17EQ35743398-864C20CD-E3C0-484F-8038-259251CB835FQ35836382-62CFCFF6-63F7-4266-B0BB-AE01B58D9483Q35854378-C8AE181F-AB00-404F-9262-5E374B542E29Q35871691-FFFBE9CC-F55E-4A51-9F24-5735F1BF6FF8Q35975481-44506344-8DE1-422D-8A2D-D10A2CD92DCCQ37371329-5A7C24A9-8F4E-4166-91B3-C784A98ED567Q37817847-5F22ECDB-7B83-4DE0-B012-F7026F392981Q38224425-5D6F4D13-04D5-40CB-B256-7B0B7C87E681Q38751763-C74B9706-6636-4AA2-8307-B11905BCB06BQ38757564-5A49CD2E-BAC2-408B-99CA-6CD7CA3EDD7BQ39760163-33D563DE-6D0D-4564-A111-D12A60DAE33FQ41006747-797D3F2C-3969-4A52-B50A-EFF1B59736D5Q41849353-4D29396C-0BA2-48B4-A4C1-F0ABC93D46DFQ46514641-DB8471FF-4F71-4DCA-897E-DF6067E467DFQ59223627-BDAFFF64-4D67-485B-A194-AB0A8BE9ECA0Q59359570-4EC140D1-0703-4322-9BAC-21A44D00776FQ64245049-481DFC46-060D-42C2-AFB8-8BCC6F2F7AA6Q90790303-25EAFF9E-4E4C-4B5C-83F5-DEF1DBD6EDA8
P50
description
investigador
@es
researcher
@en
wetenschapper
@nl
name
Ronald D Gorham
@en
Ronald D Gorham
@nl
type
label
Ronald D Gorham
@en
Ronald D Gorham
@nl
prefLabel
Ronald D Gorham
@en
Ronald D Gorham
@nl
P31
P496
0000-0002-0261-6699