Regulation of Host Cell Signaling Pathways by Respiratory Syncytial Virus Nonstructural Protein NS1 and NS2

Human Respiratory Syncytial virus (hRSV) is a leading cause of severe lower respiratory tract diseases in the pediatric population.hRSV frequently causes severe morbidity and mortality in high risk groups including infants with congenital heart disease and the immunosuppressed patients. Although hRSV is recognized as a major public health threat and economic burden worldwide, there is no licensed vaccine and effective therapeutic agent. Viral nonstructural (NS) proteins have been known to play multiple functions for efficient viral replication and pathogenesis. Especially, diverse functions of influenza A virus NS1 have been extensively studies. Recent studies demonstrated that NS1 and NS2 of RSV also exert diverse functions to modulate cellular environment and antiviral immune responses. Since NS proteins of RSV are required for efficient replication and pathogenesis, NS mutant viruses have been tested as live-attenuated vaccines. This review will outline the recent progress in understanding the various functions of RSV NS1 and NS2.

Sensing DNA Viruses and Bacteria by Intracellular DNA Sensors

The innate immune system confers first-line defense against various pathogens including bacteria and viruses. Early detection of invading pathogens by the host depends on a limited number of specific pattern recognition receptors (PRRs) that detect pathogen associated molecular patterns (PAMPs) and activate signal transduction cascades that lead to activation of defense mechanisms. Among those sensors, RIG-I-like receptors (RLRs) play crucial roles in the detection of viruses by recognizing intracellular viral patterns such as viral RNAs to induce type-I interferon production. The discovery of intracellular RNA sensing mechanism by RIG-I prompted the investigations to find out intracellular DNA sensors. Recently, several proteins including DAI, AIM2, IFI16, and cGAS have been suggested as DNA sensing molecules to detect DNA viruses and bacteria, suggesting there are multiple receptors for microbial DNA. In this review, we discuss the current our understanding of sensing microbial DNA and subsequent induction of immune responses.