Your search keyword '"Mallory L. Myers"' showing total 9 results

1. Commercial influenza vaccines vary in HA-complex structure and in induction of cross-reactive HA antibodies

Author

Mallory L. Myers, John R. Gallagher, Alexander J. Kim, Walker H. Payne, Samantha Maldonado-Puga, Haralabos Assimakopoulos, Kevin W. Bock, Udana Torian, Ian N. Moore, and Audray K. Harris

Subjects

Science

Abstract

Here, Myers and Gallagher et al. characterize the structural organization of commercial influenza vaccines. The vaccines differ in their structural composition and identify a “spiked nanodisc” arrangement of hemagglutinin (HA) with increased display and immunogenicity of the conserved stem region of HA.

Published

2023

2. Corrigendum: Impact of adjuvant: trivalent vaccine with quadrivalent-like protection against heterologous Yamagata-lineage influenza B virus

Author

Mallory L. Myers, John R. Gallagher, De’Marcus D. Woolfork, Regan K. Stradtmann-Carvalho, Samantha Maldonado-Puga, Kevin W. Bock, Seyhan Boyoglu-Barnum, Hubza Syeda, Adrian Creanga, Derron A. Alves, Masaru Kanekiyo, and Audray K. Harris

Subjects

influenza B, MF59 adjuvant, commercial vaccine, challenge, Yamagata lineage, Immunologic diseases. Allergy, RC581-607

Published

2023

3. Impact of adjuvant: Trivalent vaccine with quadrivalent-like protection against heterologous Yamagata-lineage influenza B virus

Author

Mallory L. Myers, John R. Gallagher, De’Marcus D. Woolfork, Regan K. Stradtmann-Carvalho, Samantha Maldonado-Puga, Kevin W. Bock, Seyhan Boyoglu-Barnum, Hubza Syeda, Adrian Creanga, Derron A. Alves, Masaru Kanekiyo, and Audray K. Harris

Subjects

influenza B, MF59 adjuvant, commercial vaccine, challenge, Yamagata lineage, Immunologic diseases. Allergy, RC581-607

Abstract

As new vaccine technologies and platforms, such as nanoparticles and novel adjuvants, are developed to aid in the establishment of a universal influenza vaccine, studying traditional influenza split/subunit vaccines should not be overlooked. Commercially available vaccines are typically studied in terms of influenza A H1 and H3 viruses but influenza B viruses need to be examined as well. Thus, there is a need to both understand the limitations of split/subunit vaccines and develop strategies to overcome those limitations, particularly their ability to elicit cross-reactive antibodies to the co-circulating Victoria (B-V) and Yamagata (B-Y) lineages of human influenza B viruses. In this study, we compared three commercial influenza hemagglutinin (HA) split/subunit vaccines, one quadrivalent (H1, H3, B-V, B-Y HAs) and two trivalent (H1, H3, B-V HAs), to characterize potential differences in their antibody responses and protection against a B-Y challenge. We found that the trivalent adjuvanted vaccine Fluad, formulated without B-Y HA, was able to produce antibodies to B-Y (cross-lineage) on a similar level to those elicited from a quadrivalent vaccine (Flucelvax) containing both B-V and B-Y HAs. Interestingly, Fluad protected mice from a lethal cross-lineage B-Y viral challenge, while another trivalent vaccine, Fluzone HD, failed to elicit antibodies or full protection following challenge. Fluad immunization also diminished viral burden in the lungs compared to Fluzone and saline groups. The success of a trivalent vaccine to provide protection from a cross-lineage influenza B challenge, similar to a quadrivalent vaccine, suggests that further analysis of different split/subunit vaccine formulations could identify mechanisms for vaccines to target antigenically different viruses. Understanding how to increase the breadth of the immune response following immunization will be needed for universal influenza vaccine development.

Published

2022

4. Characterization of Hemagglutinin Antigens on Influenza Virus and within Vaccines Using Electron Microscopy

Author

John R. Gallagher, Dustin M. McCraw, Udana Torian, Neetu M. Gulati, Mallory L. Myers, Michael T. Conlon, and Audray K. Harris

Subjects

influenza, vaccines, structure, electron microscopy, cryo-EM, design, Medicine

Abstract

Influenza viruses affect millions of people worldwide on an annual basis. Although vaccines are available, influenza still causes significant human mortality and morbidity. Vaccines target the major influenza surface glycoprotein hemagglutinin (HA). However, circulating HA subtypes undergo continual variation in their dominant epitopes, requiring vaccines to be updated annually. A goal of next-generation influenza vaccine research is to produce broader protective immunity against the different types, subtypes, and strains of influenza viruses. One emerging strategy is to focus the immune response away from variable epitopes, and instead target the conserved stem region of HA. To increase the display and immunogenicity of the HA stem, nanoparticles are being developed to display epitopes in a controlled spatial arrangement to improve immunogenicity and elicit protective immune responses. Engineering of these nanoparticles requires structure-guided design to optimize the fidelity and valency of antigen presentation. Here, we review electron microscopy applied to study the 3D structures of influenza viruses and different vaccine antigens. Structure-guided information from electron microscopy should be integrated into pipelines for the development of both more efficacious seasonal and universal influenza vaccine antigens. The lessons learned from influenza vaccine electron microscopic research could aid in the development of novel vaccines for other pathogens.

Published

2018

5. Commercial influenza vaccines vary in both the structural arrangements of HA complexes and in induction of antibodies to cross-reactive HA epitopes

Author

Mallory L. Myers, John R. Gallagher, Alexander J. Kim, Walker H. Payne, Kevin W. Bock, Udana Torian, Ian N. Moore, and Audray K. Harris

Abstract

Influenza virus infects millions of people annually and can cause global pandemics. Hemagglutinin (HA) is the primary component of commercial influenza vaccines (CIV), and antibody to HA is a primary correlate of protection. Persistent antigenic variation of HA requires that CIV be reformulated for new strains yearly. Differences in structural organization of HA has not been correlated with induction of broadly reactive antibodies, and CIV formulations can vary in how HA is organized. Using electron microscopy to study four current CIV, we found that these different formulations contained a variety of structures including: individual HAs, starfish-like structures with up to 12 HA molecules, and novel “spiked nanodisc” structures that displayed over 50 HA molecules along the complex’s perimeter. These spiked nanodiscs uniquely exposed conserved stem epitopes and elicited the highest levels of heterosubtypic cross-reactive antibodies. Overall, we found that HA structural organization can be an important CIV parameter and can be associated with the induction of cross-reactive antibodies to conserved HA epitopes.

Published

2022

6. Structural analysis of influenza vaccine virus-like particles reveals a multicomponent organization

Author

Neetu M. Gulati, Audray K. Harris, Mallory L. Myers, Udana Torian, Michael T. Conlon, John R. Gallagher, and Dustin M. McCraw

Subjects

0301 basic medicine, Influenza vaccine, Surface Properties, viruses, Hemagglutinin (influenza), lcsh:Medicine, Hemagglutinin Glycoproteins, Influenza Virus, Biology, medicine.disease_cause, Epitope, Virus, Article, law.invention, 03 medical and health sciences, Imaging, Three-Dimensional, Influenza A Virus, H1N1 Subtype, law, Influenza A virus, medicine, Amino Acid Sequence, Vaccines, Virus-Like Particle, Particle Size, lcsh:Science, Peptide sequence, chemistry.chemical_classification, Multidisciplinary, Cryoelectron Microscopy, lcsh:R, virus diseases, Virology, Recombinant Proteins, 3. Good health, 030104 developmental biology, chemistry, biology.protein, Recombinant DNA, lcsh:Q, Glycoprotein

Abstract

Influenza virus continues to be a major health problem due to the continually changing immunodominant head regions of the major surface glycoprotein, hemagglutinin (HA). However, some emerging vaccine platforms designed by biotechnology efforts, such as recombinant influenza virus-like particles (VLPs) have been shown to elicit protective antibodies to antigenically different influenza viruses. Here, using biochemical analyses and cryo-electron microscopy methods coupled to image analysis, we report the composition and 3D structural organization of influenza VLPs of the 1918 pandemic influenza virus. HA molecules were uniformly distributed on the VLP surfaces and the conformation of HA was in a prefusion state. Moreover, HA could be bound by antibody targeting conserved epitopes in the stem region of HA. Taken together, our analysis suggests structural parameters that may be important for VLP biotechnology such as a multi-component organization with (i) an outer component consisting of prefusion HA spikes on the surfaces, (ii) a VLP membrane with HA distribution permitting stem epitope display, and (iii) internal structural components.

Published

2018

7. Designed Nanoparticles Elicit Cross-Reactive Antibody Responses To Conserved Influenza Virus Hemagglutinin Stem Epitopes

Author

Audray K. Harris, Gallagher, Kim Aj, Udana Torian, Neetu M. Gulati, Mallory L. Myers, and Dustin M. McCraw

Subjects

Antigen, Influenza vaccine, Immunogenicity, Pandemic, biology.protein, Hemagglutinin (influenza), Biology, Antibody, Virology, Virus, Epitope

Abstract

Despite the availability of seasonal vaccines and antiviral medications, influenza virus continues to be a major health concern and pandemic threat due to the continually changing antigenic regions of the major surface glycoprotein, hemagglutinin (HA). One emerging strategy for the development of more efficacious seasonal and universal influenza vaccines is structure-guided design of nanoparticles that display conserved regions of HA, such as the stem. Using the H1 HA subtype to establish proof of concept, we found that an alpha-helical fragment (helix-A) from the conserved stem region can be displayed on nanoparticles. The stem region of HA on these nanoparticles is immunogenic and the nanoparticles are biochemically robust in that heat exposure did not destroy the particles and immunogenicity was retained. Furthermore, H1-nanoparticles protected mice from lethal challenge with H1N1 influenza virus. Importantly, antibodies elicited by these nanoparticles demonstrated homosubtypic and heterosubtypic cross-reactivity. The helix-A stem nanoparticle design represents a novel approach to display several hundred copies of non-trimeric conserved HA stem epitopes on vaccine nanoparticles. This design concept provides a new approach to universal influenza vaccine development strategies and opens up opportunities for the development of nanoparticles with broad coverage over many antigenically diverse influenza HA subtypes.SignificanceInfluenza virus is a public health issue that affects millions of people globally each year. Commercial influenza vaccines are based on the hemagglutinin (HA) surface glycoprotein, which can change antigenically every year, demanding the manufacture of newly matched vaccines annually. HA stem epitopes have a higher degree of conservation than HA molecules contained in conventional vaccine formulations and we demonstrate that we are able to design nanoparticles that display hundreds of HA stem fragments on nanoparticles. These designed nanoparticles are heat-stable, elicit antibodies to the HA stem, confer protection in mouse challenge models, and show cross-reactivity between HA subtypes. This technology provides promising opportunities to improve seasonal vaccines, develop pandemic preparedness vaccines, and facilitate the development of a universal influenza vaccine.

Published

2019

8. Conserved Structural Anatomy Between Divergent Viral Capsid Nanoparticles for Vaccine Design

Author

Dustin M. McCraw, Neetu M. Gulati, Audray K. Harris, and Mallory L. Myers

Subjects

010302 applied physics, Capsid, 0103 physical sciences, 02 engineering and technology, Biology, 021001 nanoscience & nanotechnology, 0210 nano-technology, 01 natural sciences, Instrumentation, Virology, Article

Published

2018

9. Designed nanoparticles elicit cross-reactive antibody responses to conserved influenza virus hemagglutinin stem epitopes.

Author

Dustin M McCraw, Mallory L Myers, Neetu M Gulati, Madhu Prabhakaran, Joshua Brand, Sarah Andrews, John R Gallagher, Samantha Maldonado-Puga, Alexander J Kim, Udana Torian, Hubza Syeda, Seyhan Boyoglu-Barnum, Masaru Kanekiyo, Adrian B McDermott, and Audray K Harris

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

Despite the availability of seasonal vaccines and antiviral medications, influenza virus continues to be a major health concern and pandemic threat due to the continually changing antigenic regions of the major surface glycoprotein, hemagglutinin (HA). One emerging strategy for the development of more efficacious seasonal and universal influenza vaccines is structure-guided design of nanoparticles that display conserved regions of HA, such as the stem. Using the H1 HA subtype to establish proof of concept, we found that tandem copies of an alpha-helical fragment from the conserved stem region (helix-A) can be displayed on the protruding spikes structures of a capsid scaffold. The stem region of HA on these designed chimeric nanoparticles is immunogenic and the nanoparticles are biochemically robust in that heat exposure did not destroy the particles and immunogenicity was retained. Furthermore, mice vaccinated with H1-nanoparticles were protected from lethal challenge with H1N1 influenza virus. By using a nanoparticle library approach with this helix-A nanoparticle design, we show that this vaccine nanoparticle construct design could be applicable to different influenza HA subtypes. Importantly, antibodies elicited by H1, H5, and H7 nanoparticles demonstrated homosubtypic and heterosubtypic cross-reactivity binding to different HA subtypes. Also, helix-A nanoparticle immunizations were used to isolate mouse monoclonal antibodies that demonstrated heterosubtypic cross-reactivity and provided protection to mice from viral challenge via passive-transfer. This tandem helix-A nanoparticle construct represents a novel design to display several hundred copies of non-trimeric conserved HA stem epitopes on vaccine nanoparticles. This design concept provides a new approach to universal influenza vaccine development strategies and opens opportunities for the development of nanoparticles with broad coverage over many antigenically diverse influenza HA subtypes.

Published

2023