The highly virulent genogroup 2 (G2) porcine epidemic diarrhea virus (PEDV) has become one of the deadliest and economically important swine viruses since its emergence in late 2010. PEDV causes vomiting, diarrhea, and up to 100% mortality rate in neonatal piglets, resulting in tremendous economic losses to the global pig industry. After a decade of efforts aiming to better characterize this important swine pathogen, it is now evident that the desirable maternal immunity induced by live attenuated vaccines (LAV) is essential to provide the neonatal piglets with efficacious protection against PEDV. However, knowledge about the molecular basis of PEDV pathogenesis, specific gene function, and the rational design of PEDV vaccine is yet to be elucidated. Thus, the aim of this dissertation was to develop a reverse genetic system for the G2 PEDV in order to study the molecular mechanism of PEDV attenuation, and thereby propose rational design of safe and effective LAV against PEDV. The first objective was to characterize the genetic, immunoprotective and virulent differences between two autologous Taiwan G2b PEDV strains, the highly virulent PEDV Pintung 52 strain passage 5 (PEDVPT-P5) and its cell culture-adaptive, attenuated counterpart PEDVPT-P96. In the 5-week-old conventional piglet model, oral inoculation with PEDVPT-P5 caused severe watery diarrhea and an early-onset fecal viral shedding that persisted for 26 days. The PEDVPT-P96 induced no to minimal diarrhea and a delayed-onset fecal viral shedding with a lower peak viral load. Both viruses were able to generate protection against challenge with PEDVPT-P5, although the protective efficacy elicited by PEDVPTP96 was slightly lower than that induced by PEDVPT-P5. Sequence analysis of the complete genome of both viruses revealed 23 nucleotide changes and 19 resultant amino acid (a.a.) substitutions with no deletion or insertion. Amongst them, 9 a.a. changes were found in the spike (S) gene, particularly in the S2 subunit. Our data confirmed that PEDVPT-P96 was attenuated compared with PEDVPT-P5 but maintained its immunogenicity despite the presence of several a.a. differences in the immunodominant spike glycoprotein. The second objective was to develop a reverse genetic system of PEDV using PEDVPT-P96 as the backbone. By utilizing the RNA-launched method, we successfully constructed the first infectious cDNA clone of an attenuated G2b PEDV. The rescued recombinant virus (iPEDVPT-P96) exhibited a similar phenotype both in vitro and in vivo, but was further attenuated in the 5-week-old conventional piglet model compared to the parental PEDVPT-P96. Next generation sequencing of both viruses revealed that iPEDVPT-P96 harbored a remarkably decreased level of quasispecies compared to the parental PEDVPT-P96, which may account for the phenotypic differences between the two viruses. The full-length cDNA clone of iPEDVPT-P96 is expected to provide an access to study the attenuation determinants of PEDVPT-P96 and establish an iPEDVPT-P96-based recombinant vector for multivalent vaccine design. Our third objective was to study the role of the S protein in the attenuation process of PEDVPT 52 strain. We generated four infectious cDNA clones, namely the highly virulent iPEDVPT-P5, the attenuated iPEDVPT-P96, and the iPEDVPT-P5-96S and iPEDVPT-P96-5S with substitution of the complete S gene. In 7-day-old piglet model, we found that the replacement of the S gene of PEDVPT-P5 resulted in the complete restoration of the virulence of iPEDVPT-P96 with nearly identical pattern of clinical symptoms, fecal viral shedding, and high mortality rate to the highly virulent iPEDVPT-P5. In contrast, the reciprocal approach only partially attenuated the iPEDVPT-P5 for the iPEDVPT-P5-96S which eventually caused severer histopathological lesions and a higher mortality rate than those induced by the attenuated iPEDVPT-P96. Our data confirmed that the attenuation of the PEDVPT-P96 virus is primarily attributed to mutations in the S gene but other gene(s) might also play a role in determining virulence. To conclude, a reverse genetic system of G2b PEDV was successfully established and its applicability to investigate the attenuating mechanism of PEDV was also demonstrated. The findings and technology obtained herein would facilitate future researches on PEDV pathogenesis as well as safe and effective vaccine development.