SummaryThe influenza virus establishes close functional and structural connections with the nucleus of the infected cell. Thus, viral ribonucleoproteins (RNPs) are closely bound to chromatin components and the main constituent of viral RNPs, the nucleoprotein (NP) protein, interacts with histone tails. Using a yeast two-hybrid screening, we previously found that the PA influenza virus polymerase subunit interacts with the CHD6 protein, a member of the CHD family of chromatin remodelers. Here we show that CHD6 also interacts with the viral polymerase complex and colocalizes with viral RNPs in the infected cells. To study the relationships between RNPs, chromatin and CHD6, we have analysed whether NP and CHD6 binds to peptides representing trimethylated lysines of histone 3 tails that mark transcriptionally active or inactive chromatin. Upon infection, NP binds to marks of repressed chromatin and, interestingly an important recruitment of CHD6 to these heterochromatin marks occurs in this situation. Silencing experiments indicate that CHD6 acts as a negative modulator of influenza virus replication. Hence, the CHD6 association with inactive chromatin could be part of a process where the influenza virus triggers modifications of chromatin-associated proteins that could contribute to the pathogenic events used by the virus to induce host cell shut-off.
The influenza virus mRNAs are structurally similar to cellular mRNAs nevertheless; the virus promotes selective translation of viral mRNAs despite the inhibition of host cell protein synthesis. The infection proceeds normally upon functional impairment of eIF4E cap-binding protein, but requires functional eIF4A helicase and eIF4G factor. Here, we have studied whether the presence of cis elements in viral mRNAs or the action of viral proteins is responsible for this eIF4E-independence. The eIF4E protein is required for viral mRNA translation in vitro, indicating that cis-acting RNA sequences are not involved in this process. We also show that PB2 viral polymerase subunit interacts with the eIF4G protein. In addition, a chimeric mRNA containing viral UTR sequences transcribed by the viral polymerase out of the infection is successfully translated independently of an impaired eIF4E factor. These data support that the viral polymerase is responsible for the eIF4E independence of influenza virus mRNA translation.
The influenza virus polymerase associates to an important number of transcription-related proteins, including the largest subunit of the RNA polymerase II complex (RNAP II). Despite this association, degradation of the RNAP II takes place in the infected cells once viral transcription is completed. We have previously shown that the chromatin remodeler CHD6 protein interacts with the influenza virus polymerase complex, represses viral replication, and relocalizes to inactive chromatin during influenza virus infection. In this paper, we report that CHD6 acts as a negative modulator of the influenza virus polymerase activity and is also subjected to degradation through a process that includes the following characteristics: (i) the cellular proteasome is not implicated, (ii) the sole expression of the three viral polymerase subunits from its cloned cDNAs is sufficient to induce proteolysis, and (iii) degradation is also observed in vivo in lungs of infected mice and correlates with the increase of viral titers in the lungs. Collectively, the data indicate that CHD6 degradation is a general effect exerted by influenza A viruses and suggest that this viral repressor may play an important inhibitory role since degradation and accumulation into inactive chromatin occur during the infection. The influenza virus contains a segmented genome of eight negative-sense and single-stranded RNA molecules, whose expression takes place in the nucleus of the infected cell. Genomic RNAs (vRNAs) form ribonucleoprotein complexes (vRNPs) that are constituted by the three subunits of the polymerase (PB1, PB2, and PA) and the nucleoprotein (NP), which are responsible for genome expression (1-5). For viral replication, the vRNAs are copied to form full-length positive-stranded RNAs (cRNAs), which serve as templates for vRNA synthesis. During transcription, capped and polyadenylated viral mRNAs are synthesized by the viral polymerase. The mRNA synthesis is primed by shortcapped oligonucleotides of around 10 to 12 nucleotides scavenged from de novo synthesized host cell pre-mRNAs by a viral endonuclease activity (6). This transcription strategy involves a functional coupling between viral and cellular transcription for the capsnatching process, but this functional association is broader and applies to different steps of viral mRNA metabolism. Indeed, two of the viral transcripts are spliced (7,8), but the influenza virus does not possess a viral splicing system, since it is dependent on the host splicing machinery (9), an activity related to the RNA polymerase II (RNAP II) transcription. Furthermore, the influenza virus uses the mRNA export machinery of the infected cell at least for some of its mRNAs, and an active RNA polymerase II is required to facilitate nuclear export of selected viral mRNAs (10). In agreement with this transcriptional association, interaction of the viral polymerase with host cell transcription-related factors has been reported, among which the interaction with the largest subunit of the RNAP II (11) should be emphasi...
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