Porcine epidemic diarrhea virus is attenuated upon adaptation to cell culture. Exclusively genomic mutations have been traced to the ORF3 gene of the laboratory strains. Previous attempts to express the protein were unsuccessful. We sought to express the ORF3 protein in both mammalian and bacteria cells as a prerequisite for investigation of the protein's role. For prokaryotic expression, two vector systems, pET28-a(+) and pGEX-4T-1 were constructed and expressed in Escherichia coli cells. For eukaryotic analyses, ORF3/pEGFP-C1 vector constructs were expressed in human embryonic, green monkey kidney and mouse fibrous cells. Intriguingly, there was minimal expression of the ORF3 gene. Following a documented hint that truncated ORF3 revealed higher expression, ORF3 gene was truncated. The simple modular architecture research tool analysis predicted two transmembrane domains between amino acid (aa) 41-63 and aa 76-98. Consequently, we generated two fragments; ORF-N (aa 1-98) inclusive of transmembrane domains and ORF3-C (aa 99-224). These truncated sequences were constructed as the whole gene here referred to as ORF3 wild type (wt). Coomassie blue stained gels revealed bands of ORF3-C expressed as a fusion protein of 17.5 and 39 kDa in pET28-a(+) and pGEX-4T-1 vectors, respectively. In contrast, ORF3-N was not. Additionally, ORF3-N induction decreased total cellular proteins suggesting inhibition of protein synthesis or metabolism. Solubility tests carried out at 30 °C, 25 °C and 18 °C showed that ORF3 formed inclusion bodies. Similar findings were observed in mammalian cells. Noteworthy, morphological distortions appeared in mammalian cells expressing ORF3 protein or its truncated mutants suggesting significance in host viability.
Keywords: Eukaryotic; ORF3; PEDV; Prokaryotic; Protein expression.
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