1 / 21

Flu Universal Vaccine London 5 th August 2011

Flu Universal Vaccine London 5 th August 2011. SEEK is a drug-discovery group that uses a pioneering scientific and commercially-driven approach to create breakthrough medicines which address major diseases in order to radically improve human health. 5 th August 2011.

justis
Download Presentation

Flu Universal Vaccine London 5 th August 2011

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Flu Universal Vaccine London 5th August 2011

  2. SEEK is a drug-discovery group that uses a pioneering scientific and commercially-driven approach to create breakthrough medicines which address major diseases in order to radically improve human health. 5th August 2011

  3. Low versus high mutation • Viruses such as chicken pox have a low level of mutation, so people obtain long-term immunity from exposure to the virus • Previous exposure to flu does not provide long-term protection because the virus mutates seasonally • Vaccines are developed to mimic the disease, tricking the immune system to react as if it had encountered the actual virus in order to develop memory against part of the disease • For highly-mutating viruses, this does not work as memory is formed against the variable regions 5th August 2011

  4. Current vaccine approach • Existing influenza vaccines use a weakened strain of the current year’s virus • These vaccines stimulate the immune system to produce antibodies as the first line of defence 5th August 2011

  5. Current vaccine approach (2) • Antibodies attach to the virus via some of the surface proteins. Once attached, the virus is destroyed, creating memory antibodies 5th August 2011

  6. Problem with current approach • Certain proteins of the influenza virus mutate from year to year, particularly those on the surface, therefore, memory antibodies developed from prior years’ exposure are ineffective in dealing with the current year’s virus • This is why annual flu vaccination is necessary and why a vaccine for the pandemic cannot be developed until the strain of the virus is characterised 5th August 2011

  7. Replication of Virus • Since the virus is not destroyed by antibodies, it enters lung cells where it hijacks the cells’ machinery in order to replicate • Once the virus population reaches a critical level, the person will contract the flu 5th August 2011

  8. Cellular Mechanisms • When a virus enters a cell, it breaks down into peptides, some of which are exported to the cell surface via molecules called HLAs 5th August 2011

  9. T cell mediated immunity • T cells form the second line of defence of the immune system. They recognise internal peptides presented by HLAs on the surface of cells • Each T cell will only interact with a specific HLA/peptide combination 5th August 2011

  10. T cell mediated immunity (2) • The more a peptide is presented by HLAs, the more memory T cells are generated that recognise that peptide. The more memory T cells that recognise a peptide, the stronger the immune response to that peptide • Mutating viruses tend to produce more variable peptides. Hence, the majority of newly-created T cells are directed towards highly-variable peptides, which change seasonally. This is how the virus evades this arm of the immune system 5th August 2011

  11. New vaccine approach • In order to overcome the variable surface proteins, scientists targeted the internal proteins of the virus, which are less variable or contain more “conserved” regions • These whole proteins are too large to make synthetically, therefore, scientists delivered them to cells in the form of DNA via a vector, to get the cells to make these proteins • Protein expression levels are difficult to control and the vector used to deliver the DNA tends to favour the cells it was designed to infect, which can cause difficulties such as tolerance induction 5th August 2011

  12. New vaccine approach (2) • The immune system is left to choose which peptides from the whole proteins to memorise • The immune system produces the most memory cells against those virus peptides that are most abundantly presented on surfaces of cells. These tend to be the most variable peptides 5th August 2011

  13. SEEK’s approach • By examining every human and animal influenza A and B strain that has existed over the past 60yrs, certain parts or regions of the viruses’ proteins that are conserved in all strains have been identified • SEEK identified the most highly-binding and reactive of these conserved regions to form the basis of the antigens in its vaccine 5th August 2011

  14. Explanation of SEEK’s approach • A vaccine made using these binding and reactive conserved regions of the virus proteins, the peptides would enter cells and be presented in large volumes to the T cells via the HLAs on the cells surfaces 5th August 2011

  15. Explanation of SEEK’s approach (2) • This approach dictates to the immune system which peptides to memorise • By doing so, it does not allow the normal evading mechanisms of the virus, or whole proteins of the virus, to trick the immune system into remembering the variable peptides 5th August 2011

  16. Immune response • Significant numbers of memory T cells are now created against these constant peptides, as more are presented on the surfaces of the cells by the HLAs 5th August 2011

  17. Immune response (2) • In natural-occurring infection, these constant peptides would have to compete with other peptides for space within the limited number of HLAs on cells’ surfaces, resulting in fewer of the desired memory T cells being produced 5th August 2011

  18. SEEK’s vaccine would eliminate the need for both annual and pandemic vaccinations • The constant peptides found in all animal and human influenza viruses, represented in the vaccine, create sufficient numbers of memory T cells to destroy enough of the cells containing the virus, preventing the contraction of flu • Due to the large number of conserved regions used in the vaccine, the statistical chance of all the regions mutating is negligible and, if certain ones mutated, the virus would be unable to enter lung cells and would no longer be flu Implication of SEEK’s vaccine 5th August 2011

  19. Current vaccine production • Traditional vaccine production involves growing the virus strain in chicken eggs • A limited supply of eggs, and a shortage of factories, limits the maximum production to 350 million doses per annum • Given the time to manufacture, and time to vaccinate, most people could not be protected in a pandemic 5th August 2011

  20. SEEK’s manufacturing approach • A vaccine based on constant peptides can be manufactured in chemical plants • Such a vaccine can be made and administered in large quantities, prior to a pandemic, thereby protecting a large proportion of the population 5th August 2011

  21. SEEK’s antigen selection method • The use of a proprietary computer algorithm has allowed the identification of these constant peptides, making the development of the vaccine feasible • This technology can also be applied to the identification of vaccines for other highly-mutating viruses’ • SEEK has identified vaccine candidates using this technology against HIV, Hepatitis B & C, Rotavirus A, mosquito-borne diseases and others 5th August 2011

More Related