about
Shear-stress-mediated refolding of proteins from aggregates and inclusion bodiesThe scope of phage display for membrane proteins.Dissecting the streptavidin-biotin interaction by phage-displayed shotgun scanning.Glutamate provides a key structural contact between reticulon-4 (Nogo-66) and phosphocholineA minimized M13 coat protein defines the requirements for assembly into the bacteriophage particle.EF-Tu binding peptides identified, dissected, and affinity optimized by phage display.Exploring biochemistry and cellular biology with protein libraries.A phage display selection of engrailed homeodomain mutants and the importance of residue Q50.Predicting oligonucleotide-directed mutagenesis failures in protein engineering.Bridging the synthetic and biopolymer worlds with peptide-drug conjugates.Library versus library recognition and inhibition of the HIV-1 Nef allelome.Exploring the interaction between the protein kinase A catalytic subunit and caveolin-1 scaffolding domain with shotgun scanning, oligomer complementation, NMR, and dockingM13 bacteriophage coat proteins engineered for improved phage display.Ligand design by a combinatorial approach based on modeling and experiment: application to HLA-DR4.Chemical and genetic wrappers for improved phage and RNA display.Synthesis of a virus electrode for measurement of prostate specific membrane antigen.Dual genetically encoded phage-displayed ligands.Solubilization of a membrane protein by combinatorial superchargingTen-Minute Protein Purification and Surface Tethering for Continuous-Flow Biocatalysis.Hydrazide reactive peptide tags for site-specific protein labeling.Self-made phage libraries with heterologous inserts in the Mtd of Bordetella bronchiseptica.Virus-polymer hybrid nanowires tailored to detect prostate-specific membrane antigenSingle-molecule lysozyme dynamics monitored by an electronic circuitIn vitro evolution of an HIV integrase binding protein from a library of C-terminal domain γS-crystallin variants.Protein engineering with biosynthesized libraries from Bordetella bronchiseptica bacteriophageVirus-PEDOT nanowires for biosensing.In vitro evolution of ligands to the membrane protein caveolinComputational design and selections for an engineered, thermostable terpene synthase.Identifying reactive peptides from phage-displayed libraries.Affinity-Guided Design of Caveolin-1 Ligands for Deoligomerization.Virus-poly(3,4-ethylenedioxythiophene) biocomposite films.Single molecule recordings of lysozyme activityChemically Modifying Viruses for Diverse Applications.Phage wrapping with cationic polymers eliminates nonspecific binding between M13 phage and high pI target proteins.Single Molecule Bioelectronics and Their Application to Amplification-Free Measurement of DNA Lengths.Vortex Fluidic Chemical Transformations.Virus-Enabled Biosensor for Human Serum Albumin.Single-molecule dynamics of lysozyme processing distinguishes linear and cross-linked peptidoglycan substrates.Accelerating Enzymatic Catalysis Using Vortex Fluidics.Harnessing Thin-Film Continuous-Flow Assembly Lines.
P50
Q21559300-98C43BD4-1552-414D-951F-D11AFECF9C00Q30155439-4B93C885-4C4E-475D-A7AA-B7F7E00A66D5Q30165040-3AE3274B-B3D2-4990-944D-27C825C7A307Q30826879-6E5485B6-BC69-4BF6-893C-7AB0AC3E8511Q30846621-926B22F7-96ED-4974-B01F-170095A4F403Q30891418-FB2CF32E-DCFF-4510-A9AD-43201DA0BEC4Q30976775-EE5E7896-A6C6-442C-9E3C-809F6DD6C94DQ31091689-37B44D7A-E02A-4915-BC76-530B5FCB5634Q31134755-79536E1C-C44F-47A8-ACBB-C805E9D0C765Q31137066-619284D5-3263-4865-ACCF-076F67C5F7FCQ33222582-DB5C469A-44D5-4959-BB5B-65A591C288DBQ33232878-868F0A0B-8E85-44A4-A962-9F30768D20BCQ33260422-0AFDA571-0872-4A37-8F62-2E5875ED5EF7Q33291961-18A2D536-B79A-4F16-8734-3F92A5A6D389Q33381323-96A880E5-EA2B-4DC9-8C9D-EBEDEC0C0706Q33401620-E9F3DA66-DEA9-41D8-A47E-A984FEE94360Q33625487-3A46F2FF-265A-410B-A3FE-40A20457B0B6Q33782132-9FB93F1A-2303-4F53-942F-7378660441AFQ33824356-BF92842C-E345-40EF-A289-9F9E6CA6ED4EQ34015052-D049EC51-2DC4-45F0-BA47-9442815D8944Q34143974-241C67CF-6321-4301-BF25-BF7116C457A8Q34160391-ED8F4390-BDA4-43E2-AE2D-FA3C1953DA20Q34248954-1A68709A-44E6-442A-8E3B-CAC4264C2BFEQ34363222-02D87353-F5EB-425D-A89A-C23A336B7B50Q34586128-174BAACB-AAC5-407E-BCAE-8AE8370B51C5Q35050680-D58E959C-874A-4719-B88E-EBF20738220FQ35061886-E61012A4-AF0E-4BC8-B638-CA998909C19BQ35302671-D67EFFA2-A0A1-48F3-9EA2-87C3442FD237Q35548202-73D3990D-55D9-44C1-A36A-A544D759571AQ35968549-CCE3E660-13F9-46F5-88F5-38049A404AF4Q36931737-46A40DDA-1651-4799-A773-B34A38DCB44DQ37112410-B95BF0F3-D6C3-45B2-83E5-DE892CC3E97EQ38756361-25A178DF-4E57-4690-A7B9-41AD72D44D0DQ38760942-875A5DAA-BAED-4D11-BED2-B323C822EC0CQ38878258-41E88BEB-9269-4D5F-9779-41B658615BAAQ39361543-0D63CC09-2F2C-4942-8F83-0F04C4A7576AQ40419486-826DFDAB-6B3E-46D4-BB12-1A7AAA569621Q40816144-3BAC6362-610F-462D-AD4E-DB11284CD8E0Q41107734-2E2FDD3D-315F-4D37-BF83-89DB12D34532Q41456868-667C2CA4-9810-4014-B626-7A7DFEFE3BFD
P50
description
Forscher
@de
chercheur
@fr
investigador
@es
researcher
@en
ricercatore
@it
wetenschapper
@nl
研究者
@zh
name
Gregory A. Weiss
@ast
Gregory A. Weiss
@en
Gregory A. Weiss
@es
Gregory A. Weiss
@nl
type
label
Gregory A. Weiss
@ast
Gregory A. Weiss
@en
Gregory A. Weiss
@es
Gregory A. Weiss
@nl
altLabel
Gregory Weiss
@en
prefLabel
Gregory A. Weiss
@ast
Gregory A. Weiss
@en
Gregory A. Weiss
@es
Gregory A. Weiss
@nl
P214
P1960
RLKmO3MAAAAJ
P21
P214
P31
P496
0000-0003-0296-9846
P734
P7859
lccn-n2012040454