The better we understand the structural determinants of broadly neutralizing influenza antibodies, the better vaccines we can design! Project 2 ?Innovative Computational Approaches for Structure Prediction and Design of Novel Human Influenza Antibodies? will develop a suite of in silico tools that will identify and develop such novel antibodies in conjunction with project 1 for influenza as a model system. Several high-resolution structures of antibodies engaging influenza A HA have been determined by X-ray crystallography. The availability of this rich structural base and the experience of our collaborators with the system make influenza a good model system for the present proposal. Influenza is also a good model system for biodefense: H5N1 influenza viruses traditionally infect birds, but have been responsible for several recent outbreaks limited to bird-to- human transmission. Recent research described adaptations of influenza H5N1 that confer respiratory droplet transmissibility from ferret to ferret, which may mimic the future development of a highly pathogenic pandemic human H5 virus in nature. To this end we recently isolated a human neutralizing monoclonal antibody to the H5 head domain that recognizes both wild-type and respiratory droplet transmissible H5 HAs from humans vaccinated with conventional H5 HA protein vaccine. Encouraged by this success, the first objective of this project is to develop computational algorithms that in concert with experimental approaches provided by project 1 and the structure determination core will swiftly identify and structurally characterize human antibodies that broadly neutralize influenza viruses ? an important strategy for the rapid response to emerging threats to human health. Project 1 will sequence the antibody repertoire of humans before and after being challenged with an influenza vaccine or being infected with the virus and pass these to project 2 for identification and prioritization of antibodies for functional and structural characterization in project 1 and the structural biology core. In collaboration with the Crowe laboratory, we recently demonstrated that a new computational method termed ?multi- state design? can recapitulate antibody maturation in silico. The second objective of this project is therefore to apply the newly developed computational tools for (a) in silico maturation of antibodies to increase affinity for the HA antigen of specific virus types and (b) multi-state design to create antibodies that recognize HAs of multiple different clades, subtypes, groups, or even types. Specifically, we will mature antibodies in silico with respect to target HA types and subtypes. Starting from one of 25 HA/antibody co-crystal structures, the HA will be replaced with an HA structure of the desired type or subtype. Then, single-state design will be employed to predict an ideal antibody sequence to bind the respective HA. Similarly, multi-state design will be applied to design novel antibodies that bind multiple HA clades, groups, subtypes and types. For both experiments, a limited number of computational designs with predicted binding affinity as good as, or better than, the starting co- crystal structures will be submitted for experimental validation in project 1 and the structural biology core.

Public Health Relevance

The present project ?Innovative Computational Approaches for Structure Prediction and Design of Novel Human Influenza Antibodies? will develop a suite of computational tools that in conjunction with the other projects will be applied to identify and develop novel influenza therapeutics though a combination of computational biology with hybrid methods in structural biology.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Program--Cooperative Agreements (U19)
Project #
5U19AI117905-04
Application #
9475159
Study Section
Special Emphasis Panel (ZAI1)
Project Start
Project End
Budget Start
2018-05-01
Budget End
2019-04-30
Support Year
4
Fiscal Year
2018
Total Cost
Indirect Cost
Name
Vanderbilt University Medical Center
Department
Type
DUNS #
079917897
City
Nashville
State
TN
Country
United States
Zip Code
37232
Crowe Jr, James E (2018) Is It Possible to Develop a ""Universal"" Influenza Virus Vaccine? Potential for a Universal Influenza Vaccine. Cold Spring Harb Perspect Biol 10:
Bangaru, Sandhya; Zhang, Heng; Gilchuk, Iuliia M et al. (2018) A multifunctional human monoclonal neutralizing antibody that targets a unique conserved epitope on influenza HA. Nat Commun 9:2669
Wijesinghe, Kaveesha J; Urata, Sarah; Bhattarai, Nisha et al. (2017) Detection of lipid-induced structural changes of the Marburg virus matrix protein VP40 using hydrogen/deuterium exchange-mass spectrometry. J Biol Chem 292:6108-6122
Crowe Jr, James E (2017) Principles of Broad and Potent Antiviral Human Antibodies: Insights for Vaccine Design. Cell Host Microbe 22:193-206
Bruhn, Jessica F; Kirchdoerfer, Robert N; Urata, Sarah M et al. (2017) Crystal Structure of the Marburg Virus VP35 Oligomerization Domain. J Virol 91:
Chandra, Vikas; Wu, Dalei; Li, Sheng et al. (2017) The quaternary architecture of RAR?-RXR? heterodimer facilitates domain-domain signal transmission. Nat Commun 8:868
Sangha, Amandeep K; Dong, Jinhui; Williamson, Lauren et al. (2017) Role of Non-local Interactions between CDR Loops in Binding Affinity of MR78 Antibody to Marburg Virus Glycoprotein. Structure 25:1820-1828.e2
Labonte, Jason W; Adolf-Bryfogle, Jared; Schief, William R et al. (2017) Residue-centric modeling and design of saccharide and glycoconjugate structures. J Comput Chem 38:276-287
Tseng, Roger; Goularte, Nicolette F; Chavan, Archana et al. (2017) Structural basis of the day-night transition in a bacterial circadian clock. Science 355:1174-1180
Finn, Jessica A; Koehler Leman, Julia; Willis, Jordan R et al. (2016) Improving Loop Modeling of the Antibody Complementarity-Determining Region 3 Using Knowledge-Based Restraints. PLoS One 11:e0154811

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