Your search keyword '"Dylan T. Boehm"' showing total 3 results

1. Influenza virus strains expressing SARS-CoV-2 receptor binding domain protein confer immunity in K18-hACE2 mice

Author

Nathaniel A. Rader, Katherine S. Lee, Andrea N. Loes, Olivia A. Miller-Stump, Melissa Cooper, Ting Y. Wong, Dylan T. Boehm, Mariette Barbier, Justin R. Bevere, and F. Heath Damron

Subjects

SARS-CoV-2, Delta, Omicron, Influenza virus, Intranasal vaccine, Vaccine, Immunologic diseases. Allergy, RC581-607

Abstract

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the causative agent of coronavirus disease (COVID-19), rapidly spread across the globe in 2019. With the emergence of the Omicron variant, COVID-19 shifted into an endemic phase. Given the anticipated rise in cases during the fall and winter seasons, the strategy of implementing seasonal booster vaccines for COVID-19 is becoming increasingly valuable to protect public health. This practice already exists for seasonal influenza vaccines to combat annual influenza seasons. Our goal was to investigate an easily modifiable vaccine platform for seasonal use against SARS-CoV-2. In this study, we evaluated the genetically modified influenza virus ΔNA(RBD) as an intranasal vaccine candidate for COVID-19. This modified virus was engineered to replace the coding sequence for the neuraminidase (NA) protein with a membrane-anchored form of the receptor binding domain (RBD) protein of SARS-CoV-2. We designed experiments to assess the protection of ΔNA(RBD) in K18-hACE2 mice using lethal (Delta) and non-lethal (Omicron) challenge models. Controls of COVID-19 mRNA vaccine and our lab’s previously described intranasal virus like particle vaccine were used as comparisons. Immunization with ΔNA(RBD) expressing ancestral RBD elicited high anti-RBD IgG levels in the serum of mice, high anti-RBD IgA in lung tissue, and improved survival after Delta variant challenge. Modifying ΔNA(RBD) to express Omicron variant RBD shifted variant-specific antibody responses and limited viral burden in the lungs of mice after Omicron variant challenge. Overall, this data suggests that ΔNA(RBD) could be an effective intranasal vaccine platform that generates mucosal and systemic immunity towards SARS-CoV-2.

Published

2024

2. Multivalent mRNA-DTP vaccines are immunogenic and provide protection from Bordetella pertussis challenge in mice

Author

M. Allison Wolf, Joanne M. O’Hara, Graham J. Bitzer, Elisabeth Narayanan, Dylan T. Boehm, Justin R. Bevere, Megan A. DeJong, Jesse M. Hall, Ting Y. Wong, Samantha Falcone, Cailin E. Deal, Angelene Richards, Shannon Green, Brenda Nguyen, Emily King, Clinton Ogega, Lisa Russo, Emel Sen-Kilic, Obadiah Plante, Sunny Himansu, Mariette Barbier, Andrea Carfi, and F. Heath Damron

Subjects

Immunologic diseases. Allergy, RC581-607, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Acellular multivalent vaccines for pertussis (DTaP and Tdap) prevent symptomatic disease and infant mortality, but immunity to Bordetella pertussis infection wanes significantly over time resulting in cyclic epidemics of pertussis. The messenger RNA (mRNA) vaccine platform provides an opportunity to address complex bacterial infections with an adaptable approach providing Th1-biased responses. In this study, immunogenicity and challenge models were used to evaluate the mRNA platform with multivalent vaccine formulations targeting both B. pertussis antigens and diphtheria and tetanus toxoids. Immunization with mRNA formulations were immunogenetic, induced antigen specific antibodies, as well as Th1 T cell responses. Upon challenge with either historical or contemporary B. pertussis strains, 6 and 10 valent mRNA DTP vaccine provided protection equal to that of 1/20th human doses of either DTaP or whole cell pertussis vaccines. mRNA DTP immunized mice were also protected from pertussis toxin challenge as measured by prevention of lymphocytosis and leukocytosis. Collectively these pre-clinical mouse studies illustrate the potential of the mRNA platform for multivalent bacterial pathogen vaccines.

Published

2024

3. Addition of adjuvant to DTaP modulates vaccine-induced immunological responses but is insufficient to improve protection in CD-1 mice

Author

Kelly L. Weaver, Gage M. Pyles, Spencer R. Dublin, Annalisa B. Huckaby, Sarah J. Miller, Maria De La Paz Gutierrez, Emel Sen-Kilic, William T. Witt, Dylan T. Boehm, F. Heath Damron, and Mariette Barbier

Abstract

3.1AbstractPertussis is a vaccine-preventable respiratory disease caused by the Gram-negative bacteriumBordetella pertussis. While vaccination rates remain high in developed countries, incidence of pertussis has increased following the transition from wP vaccines to aP vaccines. The reemergence of pertussis is attributed, in part, to waning immunity induced by aP vaccination. Therefore, the objective of this work was to determine if addition of adjuvant to DTaP can modulate the immune response and improve protection compared to DTaP alone. In this study we immunized outbred, female CD-1 mice with 1/320ththe human dose of vehicle control, DTaP, and DTaP supplemented with adjuvant. Markers of early vaccine-induced memory were measured using a chemokine assay or by flow cytometry. Protection was assessed by measuring serological responses and quantifying bacterial burden in the respiratory tract at day 3 post-challenge. From this work we identified a partially protective aP vaccine dose to use for vaccination and challenge studies. We observed that MPLA and SWE promote robust anti-B. pertussisantibody responses and stimulate significant increases in early markers of vaccine-induced memory such as CXCL13, FDCs, and TFHcells. Quil-A induced Th1 responses compared to DTaP alone, but none of the adjuvants improved protection against challenge withB. pertussis. Overall, the data suggests that addition of adjuvant modulates the protective immune responses induced by aPs. Further studies are needed to evaluate the B cell compartment and longevity of protection.

Published

2023