Summary
Fidelity during information transfer is essential for life, but it pays to be unfaithful if it provides an evolutionary advantage. The immune system continuously generates diversity to put up with recurrent pathogen challenges, and many viruses, in its turn, have evolved mechanisms to generate diversity to evade immune restrictions, even at the cost of enduring high mutation rates.
Synonymous codons are not used at random and are not translated with similar efficiency. A large proportion of viruses infecting humans, especially those causing chronic infections, display a poor adaptation to the codon usage preferences of their host. This observation is a paradox, as viral genes completely depend upon the cellular translation machinery for protein synthesis. The poor match between codon usage preferences of virus and host negatively affects speed and accuracy of viral protein translation. We propose here that maladaptation of codon usage preferences in human viruses may have an adaptive value as it decreases translational fidelity, results in the synthesis of an ill-defined population of viral proteins and provides a way to escape immune surveillance.
We will address the fitness effects of codon usage bias at the molecular and cellular levels, and later at the organism level in a rabbit model of papillomavirus infection. We will apply experimental evolution to analyse genotypic changes by means of next generation sequencing and will monitor phenotypic changes through real-time cell monitoring techniques, comparative proteomics, and anatomopathological analysis of virus-induced lesions.
Our results will help solve the evolutionary puzzle of codon usage bias, and will have implications for the development of therapeutic vaccines to guide the immune response towards the identification and targeting of the main protein species, avoiding the chemical noise generated by protein mistranslation.
Synonymous codons are not used at random and are not translated with similar efficiency. A large proportion of viruses infecting humans, especially those causing chronic infections, display a poor adaptation to the codon usage preferences of their host. This observation is a paradox, as viral genes completely depend upon the cellular translation machinery for protein synthesis. The poor match between codon usage preferences of virus and host negatively affects speed and accuracy of viral protein translation. We propose here that maladaptation of codon usage preferences in human viruses may have an adaptive value as it decreases translational fidelity, results in the synthesis of an ill-defined population of viral proteins and provides a way to escape immune surveillance.
We will address the fitness effects of codon usage bias at the molecular and cellular levels, and later at the organism level in a rabbit model of papillomavirus infection. We will apply experimental evolution to analyse genotypic changes by means of next generation sequencing and will monitor phenotypic changes through real-time cell monitoring techniques, comparative proteomics, and anatomopathological analysis of virus-induced lesions.
Our results will help solve the evolutionary puzzle of codon usage bias, and will have implications for the development of therapeutic vaccines to guide the immune response towards the identification and targeting of the main protein species, avoiding the chemical noise generated by protein mistranslation.
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| Web resources: | https://cordis.europa.eu/project/id/647916 |
| Start date: | 01-01-2016 |
| End date: | 30-06-2022 |
| Total budget - Public funding: | 1 997 100,00 Euro - 1 997 100,00 Euro |
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Original description
Fidelity during information transfer is essential for life, but it pays to be unfaithful if it provides an evolutionary advantage. The immune system continuously generates diversity to put up with recurrent pathogen challenges, and many viruses, in its turn, have evolved mechanisms to generate diversity to evade immune restrictions, even at the cost of enduring high mutation rates.Synonymous codons are not used at random and are not translated with similar efficiency. A large proportion of viruses infecting humans, especially those causing chronic infections, display a poor adaptation to the codon usage preferences of their host. This observation is a paradox, as viral genes completely depend upon the cellular translation machinery for protein synthesis. The poor match between codon usage preferences of virus and host negatively affects speed and accuracy of viral protein translation. We propose here that maladaptation of codon usage preferences in human viruses may have an adaptive value as it decreases translational fidelity, results in the synthesis of an ill-defined population of viral proteins and provides a way to escape immune surveillance.
We will address the fitness effects of codon usage bias at the molecular and cellular levels, and later at the organism level in a rabbit model of papillomavirus infection. We will apply experimental evolution to analyse genotypic changes by means of next generation sequencing and will monitor phenotypic changes through real-time cell monitoring techniques, comparative proteomics, and anatomopathological analysis of virus-induced lesions.
Our results will help solve the evolutionary puzzle of codon usage bias, and will have implications for the development of therapeutic vaccines to guide the immune response towards the identification and targeting of the main protein species, avoiding the chemical noise generated by protein mistranslation.
Status
CLOSEDCall topic
ERC-CoG-2014Update Date
27-04-2024
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