Abstract
Human amyloids have been shown to interact with viruses and interfere with viral replication. Based on this observation, we employed a synthetic biology approach in which we engineered virus-specific amyloids against influenza A and Zika proteins. Each amyloid shares a homologous aggregation-prone fragment with a specific viral target protein. For influenza we demonstrate that a designer amyloid against PB2 accumulates in influenza A-infected tissue in vivo. Moreover, this amyloid acts specifically against influenza A and its common PB2 polymorphisms, but not influenza B, which lacks the homologous fragment. Our model amyloid demonstrates that the sequence specificity of amyloid interactions has the capacity to tune amyloid-virus interactions while allowing for the flexibility to maintain activity on evolutionary diverging variants.
Publication types
-
Research Support, Non-U.S. Gov't
MeSH terms
-
Amyloid / genetics
-
Amyloid / pharmacology*
-
Amyloid / therapeutic use
-
Animals
-
Antiviral Agents / pharmacology*
-
Antiviral Agents / therapeutic use
-
Disease Models, Animal
-
Dogs
-
Female
-
HEK293 Cells
-
Host-Pathogen Interactions / drug effects
-
Humans
-
Influenza A virus / drug effects
-
Influenza A virus / genetics
-
Influenza A virus / pathogenicity
-
Influenza, Human / drug therapy
-
Influenza, Human / virology
-
Madin Darby Canine Kidney Cells
-
Mice
-
Polymorphism, Genetic
-
Recombinant Proteins / genetics
-
Recombinant Proteins / pharmacology
-
Recombinant Proteins / therapeutic use
-
Reverse Genetics / methods*
-
Synthetic Biology / methods*
-
Viral Proteins / genetics
-
Viral Proteins / metabolism
-
Virus Replication / drug effects
-
Zika Virus / drug effects
-
Zika Virus / genetics
-
Zika Virus / pathogenicity
-
Zika Virus Infection / drug therapy
-
Zika Virus Infection / virology
Substances
-
Amyloid
-
Antiviral Agents
-
Recombinant Proteins
-
Viral Proteins