SBIR-STTR Award

Development of siRNAs to Prevent and Treat Influenza Infection
Award last edited on: 2/7/2024

Sponsored Program
SBIR
Awarding Agency
NIH : NIAID
Total Award Amount
$1,096,332
Award Phase
2
Solicitation Topic Code
855
Principal Investigator
James Anthony Mcswiggen

Company Information

Adhera Therapeutics Inc (AKA: Marina Biotech Inc~Nastech Pharmaceutical Company Inc~MDRNA Inc~Cequent Pharmaceuticals)

4721 Emperor Boulevard Suite 350
Durham, NC 27702
   (919) 578-5901
   info@adherathera.com
   www.adherathera.com
Location: Multiple
Congr. District: 01
County: Durham

Phase I

Contract Number: 1R01AI069273-01
Start Date: 8/15/2005    Completed: 7/31/2006
Phase I year
2006
Phase I Amount
$375,000
Influenza A virus causes one of the most wide-spread infections in humans. It is also a possible bioterrorism agent. In a typical year, it infects 10-20% of the population in the US, causing up to 40,000 deaths. During the 1918 influenza virus pandemic, over 40 million people died worldwide. The threat of a new pandemic persists because the number of avian influenza outbreaks and deaths is growing and the existing vaccines have numerous drawbacks 1) current vaccines are of limited efficacy in high-risk groups, such as infants and elderly, 2) the influenza viruses they target are determined by "best guess" procedures using recent prevalent strains, 3) the time required for reformulation and large-scale production is relatively long. The four approved antiviral drugs also have limited efficacy due to severe side effects, concern about compliance, and selection for resistance viruses. For these reasons, the National Institutes of Health has designated influenza infection research, which includes therapeutics, as a priority area for biodefense research. RNA interference (RNAi) is a process by which double-stranded RNA directs sequence-specific degradation of messenger RNA in animal and plant cells. RNAi appears to be ideal for interfering with influenza virus infection because 1) short interfering (si) RNA specific for influenza A virus have been shown to potently inhibit virus production (including H1, H5 and H7 virus) in cultured cells, embryonated chicken eggs, and mice, 2) combinations of two or more siRNA specific for conserved region of flu genome will prevent the emergence of resistant virus; 3) RNAi process has less requirement for host immune function. To develop most potent siRNAs as prophylaxis and therapy of influenza virus infection in humans, this phase I application proposes i) to identify most potent influenza-specific siRNAs, ii) to evaluate the capability of siRNAs to silence the target genes with mismatches derived from different virus strains, iii) to identify the best combinations of influenza-specific siRNAs, iv) to identify polymer carriers for most efficient siRNA delivery into airway epithelial cells where influenza virus infection normally occurs, v) to identify lipid carriers for most efficient siRNA delivery, vi) to evaluate efficacies of siRNAs as prophylaxis and therapy of influenza infection in mice. The last aim will be continued in phase II of the project and the lead siRNA carriers will be further modified for efficacy improvement and will be studied for their toxicology and pharmacology.

Thesaurus Terms:
Antiviral Agent, Chemoprevention, Communicable Disease Control, Drug Delivery System, Drug Design /Synthesis /Production, Influenza, Influenzavirus A, Microorganism Disease Chemotherapy, Nonhuman Therapy Evaluation, Small Interfering Rna, Virus Genetics Genetic Strain, Liposome, Polymer, Respiratory Epithelium Rna Interference, Biotechnology, Bioterrorism /Chemical Warfare, Cell Line, Laboratory Mouse, Transfection /Expression Vector

Phase II

Contract Number: 5R01AI069273-02
Start Date: 9/15/2006    Completed: 8/31/2011
Phase II year
2007
(last award dollars: 2008)
Phase II Amount
$721,332

Influenza A virus causes one of the most wide-spread infections in humans. The threat of a flu pandemic looms with the growing number of avian influenza outbreaks and deaths. Given this threat and the drawbacks of existing vaccines and antivirals, the development of new influenza therapies is greatly needed. The National Institutes of Health has therefore designated influenza infection research, including therapeutics research, as a priority area for biodefense research. RNA interference (RNAi) is a process by which double-stranded RNA directs sequence- specific degradation of messenger RNA. We hypothesize that siRNAs specific for conserved regions in the influenza genome will be potent antivirals that will broadly target flu strains and have reduced susceptibility to viral resistance. We further hypothesize that siRNA administered intranasally can be taken up by cells in the lungs and that the efficiency of delivery can be enhanced by the use of carriers. To realize our long term objective of developing prophylactic and therapeutic siRNAs that yield an effective treatment for influenza with a greatly reduced susceptibility to viral resistance, we propose i) to characterize emergence of viral resistance to influenza-specific siRNAs and to study the resistance mechanism, ii) to study the distribution, degradation and cellular uptake of naked siRNA following intranasal delivery to lung, iii) to identify polymers that protect siRNA from degradation and facilitate siRNA lung delivery. In Specific Aim #1, we will investigate in vitro viral resistance induced by individual siRNAs as well as siRNA combinations and compare the best siRNA combination with the neuraminidase inhibitors. We will also test whether siRNAs inhibit viruses that are resistant to the NA inhibitors. In Specific Aim #2 we will determine the tissue distribution of administered siRNA, the specific lung cell types that take up siRNA, and assess the degradation of naked siRNA following intranasal administration. In order to improve the efficiency of siRNA delivery and cell uptake, in Specific Aim #3 we will select up to 10 polymers with known toxicity and disposition that have been used in the clinic, and examine their ability to protect siRNA and facilitate its uptake. It is anticipated that these studies will yield siRNA combinations that are resistant to viral mutations as well as lead siRNA formulations for further study. Progress on this project will significantly advance generation of siRNA flu therapy and, pending successful completion, IND enabling studies of the chosen siRNA combination and delivery method. It is anticipated that Phase I/II clinical studies will follow, ultimately testing an siRNA agent for influenza prophylaxis and therapy, realizing the NIAID's goal of supporting "research on influenza ... to develop new or improved ... treatments..." Tools and knowledge gained from this proposal will also enhance basic understanding of the biology of influenza infection and mechanisms underlying viral resistance to siRNA, as well as advance methodology for nucleic acid delivery to lung.

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