Your search keyword '"Jonathan R. Lai"' showing total 4 results

1. Conformational and lipid bilayer-perturbing properties of Marburg virus GP2 segments containing the fusion loop and membrane-proximal external region/transmembrane domain

Author

Nina Liu, Mark E. Girvin, Michael Brenowitz, and Jonathan R. Lai

Subjects

Viral protein, Protein engineering, Protein folding, Lipid bilayer, Virology, Molecular biology, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Fusion of host and viral membranes is a crucial step during infection by enveloped viruses. In the structurally-defined “class I″ viral glycoproteins, the formation of a highly stable α-helical bundle by the ectodomain of the fusion subunit (e.g., GP2 for Marburg virus, MARV) is postulated to provide the energetic driving force to overcome barriers associated with membrane fusion. Upon cell binding, the fusion subunit is proposed to form an extended intermediate that bridges both the viral and host membranes, and collapse of this extended intermediate brings the two membranes into proximity. While there is much high-resolution structural data available for prefusion and post-fusion structures of viral glycoproteins, little information is available about intermediate conformations especially in the context of the fusion loop/peptide (FL or FP) and membrane-proximal external region (MPER)/transmembrane (TM) segments. We present structural and functional studies on segments of MARV GP2 that encompass the FL and MPER/TM in detergent micelles and lipid bicelles. A protein that contains most elements of GP2 (“MGP2-full”) is α-helical in membrane-mimicking environments and has pH-dependent membrane lytic activity. MGP2-full is monomeric under such conditions, contrasting with the trimeric species that has been described previously for MARV GP2 ectodomain in aqueous buffer. Variants of MARV GP2 containing the N- and C-terminal halves (“MGP2-FNL” and “MGP2-CMT”, respectively) have similar properties. This work provides novel insight into conformational and membrane-perturbing properties of the MARV fusion subunit and how they may relate to viral membrane fusion.

Published

2019

2. Antibody Treatment of Ebola and Sudan Virus Infection via a Uniquely Exposed Epitope within the Glycoprotein Receptor-Binding Site

Author

Katie A. Howell, Xiangguo Qiu, Jennifer M. Brannan, Christopher Bryan, Edgar Davidson, Frederick W. Holtsberg, Anna Z. Wec, Sergey Shulenin, Julia E. Biggins, Robin Douglas, Sven G. Enterlein, Hannah L. Turner, Jesper Pallesen, Charles D. Murin, Shihua He, Andrea Kroeker, Hong Vu, Andrew S. Herbert, Marnie L. Fusco, Elisabeth K. Nyakatura, Jonathan R. Lai, Zhen-Yong Keck, Steven K.H. Foung, Erica Ollmann Saphire, Larry Zeitlin, Andrew B. Ward, Kartik Chandran, Benjamin J. Doranz, Gary P. Kobinger, John M. Dye, and M. Javad Aman

Subjects

Biology (General), QH301-705.5

Abstract

Summary: Previous efforts to identify cross-neutralizing antibodies to the receptor-binding site (RBS) of ebolavirus glycoproteins have been unsuccessful, largely because the RBS is occluded on the viral surface. We report a monoclonal antibody (FVM04) that targets a uniquely exposed epitope within the RBS; cross-neutralizes Ebola (EBOV), Sudan (SUDV), and, to a lesser extent, Bundibugyo viruses; and shows protection against EBOV and SUDV in mice and guinea pigs. The antibody cocktail ZMapp™ is remarkably effective against EBOV (Zaire) but does not cross-neutralize other ebolaviruses. By replacing one of the ZMapp™ components with FVM04, we retained the anti-EBOV efficacy while extending the breadth of protection to SUDV, thereby generating a cross-protective antibody cocktail. In addition, we report several mutations at the base of the ebolavirus glycoprotein that enhance the binding of FVM04 and other cross-reactive antibodies. These findings have important implications for pan-ebolavirus vaccine development and defining broadly protective antibody cocktails. : Howell et al. examine a mAb, FVM04, that binds the ebolavirus receptor-binding site and find that FVM04 protects against EBOV and SUDV. When combined with two ZMapp™ components, the antibody cocktail retains EBOV protection similar to that of ZMapp™ and extends protection against SUDV. Specific glycoprotein mutations that enhance the exposure of cross-neutralizing epitopes are described.

Published

2016

3. Contributors

Author

Anthony Bowen, Arturo Casadevall, Gang Chen, David Cowburn, Simon J. Davis, Michael L. Dustin, Ertan Eryilmaz, Marco Fritzsche, Shinji Ikemizu, Jonathan R. Lai, Roy A. Mariuzza, Chaim Putterman, Sneha Rangarajan, Sachdev S. Sidhu, and Yumin Xia

Published

2018

4. Synthetic Antibody Engineering: Concepts and Applications

Author

Jonathan R. Lai, Sachdev S. Sidhu, and Gang Chen

Subjects

0301 basic medicine, Phage display, biology, medicine.drug_class, Computer science, Oligonucleotide, Immunodominance, Protein engineering, Computational biology, Monoclonal antibody, ENCODE, Synthetic antibody, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, 030220 oncology & carcinogenesis, medicine, biology.protein, Antibody

Abstract

Monoclonal antibodies (mAbs) are widely used for diagnostic, research, and therapeutic applications. A critical performance feature of a mAb is its specificity toward a particular target. Here, we discuss the use of protein engineering methods (phage display and structure-based design) to develop novel mAbs, in some cases with exquisite specificity for particular target structural conformations, posttranslation modifications, or point mutations. The phage display libraries are designed and produced using synthetic oligonucleotides (synthetic antibodies), and the mAb identification procedure involves entirely in vitro screening methods. Therefore, the synthetic antibody approach allows stringent control over the state of the target during the antibody selection process. Furthermore, the libraries encode amino acid side chains that are biased toward residues with favorable physicochemical attributes for intermolecular recognition. Thus, the method is not biased by immunodominance and allows for identification of mAbs against targets that are intractable by other methods.

Published

2018