In the United States alone, annual influenza epidemics cause approximately 30,000 deaths each year, mostly among the elderly. In addition, periodic pandemics result from the emergence of novel influenza viruses through antigenic shift. In pandemic years, the virus efficiently infects most of the human population due to a lack of pre-existing immunity against the hemagglutinin of the pandemic strain. Three influenza pandemics have occurred in the last century, in 1918, 1957 and 1968, and in each case mortality and morbidity far exceeded those in epidemic years. In fact, the most severe of the three pandemic episodes (in1918) is estimated to have caused greater than 40 million deaths. Although it is not possible to predict when the next influenza pandemic will occur, that there will be a new pandemic is almost certain. The potentially devastating effects of this event could be prevented with the fast production and distribution of an effective vaccine designed to protect against the pandemic virus. Prototype pandemic vaccines developed to date require multiple high doses to induce protective responses in humans. With such a vaccine, it would be impossible to generate sufficient supplies to promptly immunize the entire population using current manufacturing technology. In addition, more effective vaccines are needed to control epidemic influenza in high risk populations, where the success rate of vaccination with currently approved vaccines is low. We propose to investigate a novel concept for the design of improved influenza virus vaccines based on modification of the viral NS1 gene to generate live attenuated vaccine strains. We have previously shown that the NS1 gene of influenza virus is responsible for inhibition of type I IFN production. We therefore hypothesize that NS1-modified influenza virus vaccines will be attenuated and will stimulate potent innate and adaptive immune responses due to their IFN-inducing properties. Thus, H3N2 and H5N1 viruses containing truncations of their NS1 genes will be generated by reverse genetics as prototype vaccines against epidemic and pandemic influenza in humans. The recombinant viruses will be evaluated in preclinical models for their ability to protect against influenza virus infection. In addition, H5N1-based vaccines will be tested for their ability to protect poultry, in order to assess their utility on poultry farms. The immune responses induced by NS1-modified influenza virus vaccines will be characterized in detail, providing insight into the mechanisms of virulence of wild-type influenza virus strains. We hypothesize that the NS1 protein of influenza virus is responsible for a suboptimal immune response after virus infection, and that the NS1- muntant viruses will have increased immunogenicity. We will also explore innovative approaches to eliminate the potential for reassortment between live vaccine viruses and circulating strains that could result in the acquisition of virulence. Finally, in collaboration with GreenHills Biotechnology, we will optimize cell culture techniques for the large-scale production of NS1-modified influenza virus vaccines suitable for use in humans.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project--Cooperative Agreements (U01)
Project #
5U01AI070469-05
Application #
7925593
Study Section
Special Emphasis Panel (ZAI1-LR-M (M1))
Program Officer
Salomon, Rachelle
Project Start
2006-08-01
Project End
2012-07-31
Budget Start
2010-08-01
Budget End
2012-07-31
Support Year
5
Fiscal Year
2010
Total Cost
$1,948,534
Indirect Cost
Name
Icahn School of Medicine at Mount Sinai
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
078861598
City
New York
State
NY
Country
United States
Zip Code
10029
Krammer, Florian; Pica, Natalie; Hai, Rong et al. (2013) Chimeric hemagglutinin influenza virus vaccine constructs elicit broadly protective stalk-specific antibodies. J Virol 87:6542-50
Pica, Natalie; Hai, Rong; Krammer, Florian et al. (2012) Hemagglutinin stalk antibodies elicited by the 2009 pandemic influenza virus as a mechanism for the extinction of seasonal H1N1 viruses. Proc Natl Acad Sci U S A 109:2573-8
Perez, Daniel R (2012) Public health and biosecurity. H5N1 debates: hung up on the wrong questions. Science 335:799-801
Vincent, Amy L; Ma, Wenjun; Lager, Kelly M et al. (2012) Live attenuated influenza vaccine provides superior protection from heterologous infection in pigs with maternal antibodies without inducing vaccine-associated enhanced respiratory disease. J Virol 86:10597-605
Maamary, Jad; Pica, Natalie; Belicha-Villanueva, Alan et al. (2012) Attenuated influenza virus construct with enhanced hemagglutinin protein expression. J Virol 86:5782-90
Hai, Rong; García-Sastre, Adolfo; Swayne, David E et al. (2011) A reassortment-incompetent live attenuated influenza virus vaccine for protection against pandemic virus strains. J Virol 85:6832-43
Baum, Alina; García-Sastre, Adolfo (2011) Differential recognition of viral RNA by RIG-I. Virulence 2:166-9
Munoz-Fontela, Cesar; Pazos, Michael; Delgado, Igotz et al. (2011) p53 serves as a host antiviral factor that enhances innate and adaptive immune responses to influenza A virus. J Immunol 187:6428-36
Tisoncik, Jennifer R; Billharz, Rosalind; Burmakina, Svetlana et al. (2011) The NS1 protein of influenza A virus suppresses interferon-regulated activation of antigen-presentation and immune-proteasome pathways. J Gen Virol 92:2093-104
Tscherne, Donna M; García-Sastre, Adolfo (2011) An enzymatic assay for detection of viral entry. Curr Protoc Cell Biol Chapter 26:Unit 26.12

Showing the most recent 10 out of 51 publications