Because an amino acid can be encoded by as many as six codons, there are many different ways to encode any particular protein. Biases exist in the way codons are used. A little-studied bias is the codon pair bias, such that some codons prefer to be adjacent to certain other codons. This codon pair bias is completely separate and independent from codon usage. Recently, we have found that when viruses are re-coded to have a bad codon pair bias, the viruses are attenuated, in extreme cases to inviability. It appears that attenuation of a virus via a bad codon pair bias can be used to make a live, attenuated vaccine. However, while the procedure works, nothing whatever is known about the mechanism by which codon pair bias causes attenuation. In this proposal, we will investigate the mechanisms of attenuation by bad codon pair bias. This will be done in yeast, where we have recently shown there are strong codon pair bias effects. We have found two major classes of attenuating codon pairs, and each class may work by a distinct mechanism. Recent results suggest that the attenuating codon pairs are interfering with proper translation, which is triggering translation quality control pathways such as nonsense mediated decay to destroy the recoded mRNAs. Here, we will learn the mechanisms of attenuation by codon pair bias. The significance of this is twofold: from a basic research point-of-view, this research may reveal completely new aspects of RNA processing and translational quality control explaining how a change in the ordering of synonymous codons can drastically affect gene expression; from a medical point-of-view, this research will help us design and synthesize better attenuated viruses for potential use in vaccines. Relevance One way to make an anti-viral vaccine is to mutate the virus to weaken it, and then use this weakened virus as a vaccine (e.g., FluMist, a live Flu vaccine). However there are many difficulties. Recently we have found a new method, codon pair de-optimization, for making live attenuated viral vaccines. Although the method works (for polio, flu, dengue, respiratory syncytial virus), we do not know why it works. Here, we will study the mechanism of attenuation by codon pair de-optimization.

Public Health Relevance

One way to make an anti-viral vaccine is to mutate and weaken the virus, and then use this weakened virus as a vaccine (e.g., FluMist). Recently we have found a new method, codon pair de-optimization, for making live attenuated viral vaccines. Although the method works (for polio, flu, dengue, respiratory syncytial virus), we do not know why it works. Here, we will study the mechanism of attenuation by codon pair de-optimization. This is primarily interesting because it will shed new light on mechanisms of gene express-somehow, codon pair bias is interfering with gene expression, but we don't know how-we don't know what step in gene expression is vulnerable to a bad codon pair bias. It is secondarily interesting because it will allow us to make better, safer, more effective attenuated viruses for vaccines.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM119175-03
Application #
9477035
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Brown, Anissa F
Project Start
2016-08-01
Project End
2020-04-30
Budget Start
2018-05-01
Budget End
2019-04-30
Support Year
3
Fiscal Year
2018
Total Cost
Indirect Cost
Name
State University New York Stony Brook
Department
Genetics
Type
Schools of Medicine
DUNS #
804878247
City
Stony Brook
State
NY
Country
United States
Zip Code
11794