Reverse Genetic Assessment of the Roles Played by the Spike Protein and ORF3 in Porcine Epidemic Diarrhea Virus Pathogenicity

Porcine epidemic diarrhea virus is a swine pathogen that has been responsible for significant animal and economic losses worldwide in recent years. In this manuscript, we report the generation of a reverse genetics system C(RGS) for the highly virulent US PEDV strain Minnesota (PEDV-MN; GenBank acce...

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Published inJournal of virology Vol. 97; no. 7; p. e0196422
Main Authors Kristen-Burmann, Claudia, Rogger, Peter, Veiga, Inês Berenguer, Riebesehl, Stefanie, Rappe, Julie, Ebert, Nadine, Sautter, Carmen A, Kelly, Jenna N, Stalder, Hanspeter, Ehmann, Rosina, Huber, Michael, Posthaus, Horst, Ruggli, Nicolas, Thiel, Volker, Tekes, Gergely
Format Journal Article
LanguageEnglish
Published United States American Society for Microbiology 27.07.2023
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Summary:Porcine epidemic diarrhea virus is a swine pathogen that has been responsible for significant animal and economic losses worldwide in recent years. In this manuscript, we report the generation of a reverse genetics system C(RGS) for the highly virulent US PEDV strain Minnesota (PEDV-MN; GenBank accession number KF468752), which was based on the assembly and cloning of synthetic DNA, using vaccinia virus as a cloning vector. Viral rescue was only possible following the substitution of 2 nucleotides within the 5'UTR and 2 additional nucleotides within the spike gene, based on the sequence of the cell culture-adapted strains. Besides displaying a highly pathogenic phenotype in newborn piglets, in comparison with the parental virus, the rescued recombinant PEDV-MN was used to confirm that the PEDV spike gene has an important role in PEDV virulence and that the impact of an intact PEDV ORF3 on viral pathogenicity is modest. Moreover, a chimeric virus with a TGEV spike gene in the PEDV backbone generated with RGS was able to replicate efficiently and could be readily transmitted between piglets. Although this chimeric virus did not cause severe disease upon the initial infection of piglets, there was evidence of increasing pathogenicity upon transmission to contact piglets. The RGS described in this study constitutes a powerful tool with which to study PEDV pathogenesis and can be used to generate vaccines against porcine enteric coronaviruses. PEDV is a swine pathogen that is responsible for significant animal and economic losses worldwide. Highly pathogenic variants can lead to a mortality rate of up to 100% in newborn piglets. The generation of a reverse genetics system for a highly virulent PEDV strain originating from the United States is an important step in phenotypically characterizing PEDV. The synthetic PEDV mirrored the authentic isolate and displayed a highly pathogenic phenotype in newborn piglets. With this system, it was possible to characterize potential viral virulence factors. Our data revealed that an accessory gene (ORF3) has a limited impact on pathogenicity. However, as it is also now known for many coronaviruses, the PEDV spike gene is one of the main determinants of pathogenicity. Finally, we show that the spike gene of another porcine coronavirus, namely, TGEV, can be accommodated in the PEDV genome background, suggesting that similar viruses can emerge in the field via recombination.
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Present address: Julie Rappe, Scientific Division of Vetoquinol, Lure, France.
Present address: Gergely Tekes, Elanco Animal Health, Germany.
Present address: Claudia Kristen-Burmann, Hessian State Laboratory, Department of Veterinary Medicine, Gießen, Germany.
Present address: Stefanie Riebesehl, Veterinary practice Sandra Meyer, Bad Homburg, Germany.
Present address: Carmen A. Sautter, Livestock animal practice, Drs. Paul and Ursula Trachsel, St. Antoni, Switzerland.
The authors declare no conflict of interest.
Present address: Rosina Ehmann, Bundeswehr Institute of Microbiology, Munich, Germany.
Claudia Kristen-Burmann, Peter Rogger, and Inês Berenguer Veiga contributed equally. The order of names of co-first authors was decided upon agreement between the first authors.
Present address: Peter Rogger, Veterinary Cantonal Office, Zürich, Switzerland.
ISSN:0022-538X
1098-5514
DOI:10.1128/jvi.01964-22