Depletion of TAX1BP1 Amplifies Innate Immune Responses during Respiratory Syncytial Virus Infection.

Respiratory syncytial virus (RSV) is the main cause of acute respiratory infections in young children and also has a major impact on the elderly and immunocompromised people. In the absence of a vaccine or efficient treatment, a better understanding of RSV interactions with the host antiviral response during infection is needed. Previous studies revealed that cytoplasmic inclusion bodies (IBs), where viral replication and transcription occur, could play a major role in the control of innate immunity during infection by recruiting cellular proteins involved in the host antiviral response. We recently showed that the morphogenesis of IBs relies on a liquid-liquid-phase separation mechanism depending on the interaction between viral nucleoprotein (N) and phosphoprotein (P). These scaffold proteins are expected to play a central role in the recruitment of cellular proteins to IBs. Here, we performed a yeast two-hybrid screen using RSV N protein as bait and identified the cellular protein TAX1BP1 as a potential partner of this viral protein. This interaction was validated by pulldown and immunoprecipitation assays. We showed that TAX1BP1 suppression has only a limited impact on RSV infection in cell cultures. However, RSV replication is decreased in TAX1BP1-deficient (TAX1BP1 knockout [TAX1BP1KO]) mice, whereas the production of inflammatory and antiviral cytokines is enhanced. In vitro infection of wild-type or TAX1BP1KO alveolar macrophages confirmed that the innate immune response to RSV infection is enhanced in the absence of TAX1BP1. Altogether, our results suggest that RSV could hijack TAX1BP1 to restrain the host immune response during infection. IMPORTANCE Respiratory syncytial virus (RSV), which is the leading cause of lower respiratory tract illness in infants, remains a medical problem in the absence of a vaccine or efficient treatment. This virus is also recognized as a main pathogen in the elderly and immunocompromised people, and the occurrence of coinfections (with other respiratory viruses and bacteria) amplifies the risks of developing respiratory distress. In this context, a better understanding of the pathogenesis associated with viral respiratory infections, which depends on both viral replication and the host immune response, is needed. The present study reveals that the cellular protein TAX1BP1, which interacts with the RSV nucleoprotein N, participates in the control of the innate immune response during RSV infection, suggesting that the N-TAX1BP1 interaction represents a new target for the development of antivirals.

Construction of adenoviral vectors expressing F and G glycoproteins of human respiratory syncytial virus (HRSV)

Human Respiratory Syncytial Virus (HRSV) was first characterized in 1957 and has since been recognized as the most common viral cause of severe respiratory tract infection in young infants worldwide. Despite many years of research there is still no effective treatment or any immediate prospect of a vaccine. The HRSV genome is composed of single stranded negative sense RNA and the virion consists of a nucleocapsid packaged within a lipid envelope. The envelope contains spike-like projections, each being a homo-oligomer of one of three transmembrane viral envelope proteins: the attachment protein G, the fusion protein F involved in viral penetration and the small hydrofobic protein SH. The aim of this work was to construct two recombinant replication-defective adenoviruses carrying separately F and G genes from HRSV. This system was chosen because adenovirus delivers genes into target cells with high efficiency in a variety of cell lines and can be used in vitro and in vivo. In order to obtain the recombinant viruses, we did RT-PCR of RNA extracted from the HRSV A2 strain, the genes F and G were cloned in to pAdeno-X vectors. pAdeno-F and pAdeno-G were transfected in HEK-293 cells for the production of recombinant viruses, that expressed efficiently these two proteins and provide us the means for doing functional assays and immunization tests.

O Vírus Sincicial Respiratório Humano (HRSV) foi isolado e caracterizado pela primeira vez em 1957 e é considerado como o patógeno viral mais freqüente do trato respiratório de bebês e crianças. Apesar de muitos anos de pesquisa, não há ainda um tratamento específico ou uma vacina licenciada. Seu genoma é composto por uma fita simples de RNA polaridade negativa e o vírion consiste em um nucleocapsídeo empacotado por um envelope lipídico. O envelope contém projeções, chamadas espículas, constituídas de homoligômeros de uma das 3 glicoproteínas de membrana: a proteína de ligação G ("attachment"), a proteína de fusão F ("fusion") e a proteína SH ("small hydrofobic"). O objetivo deste trabalho foi construir dois adenovirus recombinantes defectivos em replicação expressando separadamente os genes F e G do HRSV. Este sistema foi escolhido porque os vetores adenovirais possuem a capacidade de inserir genes em uma grande variedade de linhagens celulares in vitro e in vivo. Para obtenção destes vetores adenovirais, um RT-PCR de RNA extraído do protótipo A2 de HRSV foi feito e os genes F e G clonados em vetores pAdeno-X. pAdeno-F e pAdeno-G foram transfectados em células HEK-293 para a produção do vírus recombinante, que expressaram corretamente essas duas proteínas constituem-se ferramentas para imunização e estudos funcionais.