Your search keyword '"Frank S. Vago"' showing total 3 results

1. Affinity Capture of p97 with Small-Molecule Ligand Bait Reveals a 3.6 Å Double-Hexamer Cryoelectron Microscopy Structure

Author

David H. Thompson, Wen Jiang, Kunpeng Li, Donna M. Huryn, Rejaul Hoq, Frank S. Vago, Peter Wipf, Robert J Nicholas, and Marina Kovaliov

Subjects

Schiff base, Capture antibody, Cryoelectron Microscopy, General Engineering, Small molecule ligand, General Physics and Astronomy, 02 engineering and technology, Random hexamer, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrostatics, Ligands, 01 natural sciences, AAA proteins, Antibodies, 0104 chemical sciences, Physical Phenomena, chemistry.chemical_compound, chemistry, Microscopy, Biophysics, Humans, General Materials Science, 0210 nano-technology, Histidine

Abstract

Recent progress in the development of affinity grids for cryoelectron microscopy (cryo-EM) typically employs genetic engineering of the protein sample such as histidine or Spy tagging, immobilized antibody capture, or nonselective immobilization via electrostatic interactions or Schiff base formation. We report a powerful and flexible method for the affinity capture of target proteins for cryo-EM analysis that utilizes small-molecule ligands as bait for concentrating human target proteins directly onto the grid surface for single-particle reconstruction. This approach is demonstrated for human p97, captured using two different small-molecule high-affinity ligands of this AAA+ ATPase. Four electron density maps are revealed, each representing a p97 conformational state captured from solution, including a double-hexamer structure resolved to 3.6 A. These results demonstrate that the noncovalent capture of protein targets on EM grids modified with high-affinity ligands can enable the structure elucidation of multiple configurational states of the target and potentially inform structure-based drug design campaigns.

Published

2021

2. Bioengineered Norovirus S60 Nanoparticles as a Multifunctional Vaccine Platform

Author

Weiming Zhong, Ming Xia, Chen Sun, Pengwei Huang, Wen Jiang, Ming Tan, John S. Klassen, Ling Han, Kunpeng Li, Frank S. Vago, and Xi Jiang

Subjects

0301 basic medicine, Chemistry, viruses, Immunogenicity, Antigen presentation, General Engineering, General Physics and Astronomy, Cleavage (embryo), medicine.disease_cause, Virology, 03 medical and health sciences, 030104 developmental biology, Antigen, Capsid, Rotavirus, medicine, Norovirus, General Materials Science, Cysteine

Abstract

Homotypic interactions of viral capsid proteins are common, driving viral capsid self-formation. By taking advantage of such interactions of the norovirus shell (S) domain that naturally builds the interior shells of norovirus capsids, we have developed a technology to produce 60-valent, icosahedral S60 nanoparticles through the E. coli system. This has been achieved by several modifications to the S domain, including an R69A mutation to destruct an exposed proteinase cleavage site and triple cysteine mutations (V57C/Q58C/S136C) to establish inter-S domain disulfide bonds for enhanced inter-S domain interactions. The polyvalent S60 nanoparticle with 60 exposed S domain C-termini offers an ideal platform for antigen presentation, leading to enhanced immunogenicity to the surface-displayed antigens for vaccine development. This was proven by constructing a chimeric S60 nanoparticle displaying 60 rotavirus (RV) VP8* proteins, the major RV-neutralizing antigen. These S60-VP8* particles are easily produced and...

Published

2018

3. Bioengineered Norovirus S

Author

Ming, Xia, Pengwei, Huang, Chen, Sun, Ling, Han, Frank S, Vago, Kunpeng, Li, Weiming, Zhong, Wen, Jiang, John S, Klassen, Xi, Jiang, and Ming, Tan

Subjects

Rotavirus, Mice, Mice, Inbred BALB C, Animals, Nanoparticles, Bioengineering, Viral Vaccines, Article

Abstract

Homotypic interactions of viral capsid proteins are common, driving viral capsid self-formation. By taking advantage of such interactions of norovirus shell (S) domain that naturally builds the interior shells of norovirus capsids, we have developed a technology to produce 60-valent, icosahedral S60 nanoparticles through the E. coli system. This has been achieved by several modifications to the S domain, including an R69A mutation to destruct an exposed proteinase cleavage site and triple cysteine mutations (V57C/Q58C/S136C) to establish inter-S domain disulfide bonds for enhanced inter-S domain interactions. The polyvalent S60 nanoparticle with 60 exposed S domain C-termini offers an ideal platform for antigen presentation, leading to enhanced immunogenicity to the surface-displayed antigens for vaccine development. This was proven by constructing a chimeric S60 nanoparticle displaying 60 rotavirus (RV) VP8* proteins, the major RV neutralizing antigen. These S60-VP8* particles are easily produced and elicited high IgG response in mice toward the displayed VP8* antigens. The mouse antisera after immunization with the S60-VP8* particles exhibited high blockades against RV VP8* binding to its glycan ligands and high neutralizing activities against RV infection in culture cells. The three-dimensional structures of the S60 and S60-VP8* particles were studied. Furthermore, the S60 nanoparticle can display other antigens, supporting the notion that the S60 nanoparticle is a multifunctional vaccine platform. Finally, the intermolecular disulfide bond approach may be used to stabilize other viral-like particles to display foreign antigens for vaccine development.

Published

2018