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Porcine Circovirus 2 Activates the PERK-Reactive Oxygen Species Axis To Induce p53 Phosphorylation with Subsequent Cell Cycle Arrest at S Phase in Favor of Its Replication.

Zhuofan DengRenjie SunXiao HanYikai ZhangYingshan ZhouYing ShanJidong XuXiaoliang LiFang HeWeihuan Fang
Published in: Journal of virology (2022)
Porcine circovirus type 2 (PCV2), the causative agent of porcine circovirus-associated diseases (PCVAD), is known to induce oxidative stress, activate p53 with induction of cell cycle arrest, and trigger the PERK (protein kinase R-like endoplasmic reticulum kinase) branch of the endoplasmic reticulum (ER) stress pathway. All these cellular responses could enhance PCV2 replication. However, it remains unknown whether PERK activation by PCV2 is involved in p53 signaling with subsequent changes of cell cycle. Here, we demonstrate that PCV2 infection induced cell cycle arrest at S phase to favor its replication via the PERK-reactive oxygen species (ROS)-p53 nexus. PCV2 infection promoted phosphorylation of p53 (p-p53) at Ser15 in porcine alveolar macrophages. Inhibition of PERK by RNA silencing downregulated total p53 (t-p53) and p-p53. Treatment with the MDM2 inhibitor nutlin-3 led to partial recovery of t-p53 in perk -silenced and PCV2-infected cells. perk silencing markedly downregulated ROS production. Scavenging of ROS with N -acetylcysteine (NAC) of PCV2-infected cells downregulated t-p53 and p-p53. Increased accumulation of p-p53 in the nuclei during PCV2 infection could be downregulated by silencing of perk or NAC treatment. Further studies showed that perk silencing or NAC treatment alleviated S phase accumulation and downregulated cyclins E1 and A2 in PCV2-infected cells. These findings indicate that the PCV2-activated PERK-ROS axis promotes p-p53 and contributes to cell cycle accumulation at S phase when more cellular enzymes are available to favor viral DNA synthesis. Overall, our study provides a novel insight into the mechanism how PCV2 manipulates the host PERK-ROS-p53 signaling nexus to benefit its own replication via cell cycle arrest. IMPORTANCE Coinfections or noninfectious triggers have long been considered to potentiate PCV2 infection, leading to manifestation of PCVAD. The triggering mechanisms remain largely unknown. Recent studies have revealed that PERK-mediated ER stress, oxidative stress, and cell cycle arrest during PCV2 infection are conducive to viral replication. However, how PCV2 employs such host cell responses requires further research. Here, we provide a novel mechanism of PCV2-induced ER stress and enhanced viral replication: the PCV2-activated PERK-ROS-p53 nexus increases S phase cell population, a cell cycle period of DNA synthesis favorable for PCV2 replication. The fact that PCV2 deploys the simple ROS molecules to activate p53 to benefit its replication provides novel insights into the triggering factors, that is, certain stimuli or management measures that induce ER stress with subsequent generation of ROS would exacerbate PCVAD. Use of antioxidants is justified on farms where PCVAD is severe.
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