Mechanism of action of the suppression of influenza virus replication by Ko-Ken Tang through inhibition of the phosphatidylinositol 3-kinase/Akt signaling pathway and viral RNP nuclear export.

AIMS OF THE STUDY: Ko-Ken Tang (KKT, aka kakkon-to), a conventional Chinese herbal medicine, has been used for the treatment of the common cold, fever and influenza virus infection. However, the underlying mechanism of its activity against influenza virus infection remains elusive. In this study, the antiviral effect and its underlying mechanism was evaluated, including the investigation of anti-influenza virus activity of KKT on MDCK cells and corresponding mechanism related to phosphatidylinositol 3-kinase (PI3K)/Akt signaling pathway and its consecutive viral RNP nuclear export. MATERIALS AND METHODS: The antiviral activity of non-toxic concentration of KKT was examined against various strains of influenza virus and enterovirus 71 by neutralization assay. PI3K/Akt signaling activated by influenza virus was inspected in A549 cells by western blot. Inhibition of influenza polymerase activity by KKT was measured with plasmid-based reverse genetics using primer extension assay and luciferase reporter assay. Inhibition of viral vRNP nuclear export was demonstrated by laser confocal microscopy and interspecies heterokaryon assay. RESULTS: KKT inhibits influenza virus replication but not entry, and it exhibits a broad spectrum inhibitory activity against human influenza A viruses and enterovirus 71. KKT does not inhibit viral polymerase activity but directly blocks the virus-induced phosphatidylinositol 3-kinase/Akt signaling pathway, which in turns causes retention of viral nucleoprotein in the nucleus, thereby interfering with virus propagation. The inhibition by KKT of the nuclear export of viral protein was further confirmed by heterokaryon assay. CONCLUSIONS: The results obtained in this study give scientific support to KKT for the treatment of influenza virus infection. KKT could be of potential use in the management of seasonal pandemic influenza virus infection in addition to other clinically available drugs.

Functional interplay between viral and cellular SR proteins in control of post-transcriptional gene regulation.

Viruses take advantage of cellular machineries to facilitate their gene expression in the host. SR proteins, a superfamily of cellular precursor mRNA splicing factors, contain a domain consisting of repetitive arginine/serine dipeptides, termed the RS domain. The authentic RS domain or variants can also be found in some virus-encoded proteins. Viral proteins may act through their own RS domain or through interaction with cellular SR proteins to facilitate viral gene expression. Numerous lines of evidence indicate that cellular SR proteins are important for regulation of viral RNA splicing and participate in other steps of post-transcriptional viral gene expression control. Moreover, viral infection may alter the expression levels or modify the phosphorylation status of cellular SR proteins and thus perturb cellular precursor mRNA splicing. We review our current understanding of the interplay between virus and host in post-transcriptional regulation of gene expression via RS domain-containing proteins.

The RNA binding protein hnRNP Q modulates the utilization of exon 7 in the survival motor neuron 2 (SMN2) gene.

Spinal muscular atrophy (SMA) is a recessive neuromuscular disorder caused by the homozygous loss of the SMN1 gene. The human SMN2 gene has a C-to-T transition at position +6 of exon 7 and thus produces exon 7-skipping mRNAs. However, we observed an unexpectedly high level of exon 7-containing SMN2 transcripts as well as SMN protein in testis of smn(-/-) SMN2 transgenic mice. Using affinity chromatography, we identified several SMN RNA-associating proteins in mouse testis and human HeLa cells, including hnRNP Q. The major hnRNP Q isoform, Q1, directly bound SMN exon 7 in the vicinity of nucleotide +6. Overexpression of hnRNP Q1 promoted the inclusion of exon 7 in SMN2, probably by activating the use of its upstream 3' splice site. However, the minor isoforms Q2/Q3 could antagonize the activity of hnRNP Q1 and induced exon 7 exclusion. Intriguingly, enhanced exon 7 inclusion was also observed upon concomitant depletion of three hnRNP Q isoforms. Thus, differential expression of hnRNP Q isoforms may result in intricate control of SMN precursor mRNA splicing. Here, we demonstrate that hnRNP Q is a splicing modulator of SMN, further underscoring the potential of hnRNP Q as a therapeutic target for SMA.

Phosphorylation of the arginine/serine dipeptide-rich motif of the severe acute respiratory syndrome coronavirus nucleocapsid protein modulates its multimerization, translation inhibitory activity and cellular localization.

Coronavirus nucleocapsid protein is abundant in infected cells and participates in viral RNA replication and transcription. The central domain of the nucleocapsid protein contains several arginine/serine (RS) dipeptides, the biological significance of which has not been well investigated. In the present study, we demonstrate that the severe acute respiratory syndrome coronavirus nucleocapsid protein is phosphorylated primarily within the RS-rich region in cells and by SR protein kinase 1 in vitro. The nucleocapsid protein could suppress translation and its RS motif is essential for such an activity. Moreover, phosphorylation of the RS motif could modulate the translation inhibitory activity of the nucleocapsid protein. We further found that RS motif phosphorylation did not significantly affect RNA binding of the nucleocapsid protein but impaired its multimerization ability. We observed that the nucleocapsid protein could translocate to cytoplasmic stress granules in response to cellular stress. Deletion or mutations of the RS motif enhanced stress granule localization of the nucleocapsid protein, whereas overexpression of SR protein kinase 1 inhibited nucleocapsid protein localization to stress granules. The nucleocapsid protein lacking the RS motif formed high-order RNP complexes, which may also account for its enhanced stress granule localization. Taken together, phosphorylation of the severe acute respiratory syndrome-CoV nucleocapsid protein modulates its activity in translation control and also interferes with its oligomerization and aggregation in stress granules.

Association between a novel 11-base pair deletion mutation in the promoter region of the scavenger receptor class B type I gene and plasma HDL cholesterol levels in Taiwanese Chinese.

OBJECTIVE: Scavenger receptor class B type I (SR-BI) is a multiligand cell-surface receptor that mediates the selective uptake of lipid from HDL cholesterol (HDL-C) into cells. This study hypothesized an association between functional variants in the promoter region of SR-BI gene and HDL-C levels. METHODS AND RESULTS: We identified 2 novel mutations in the SR-BI gene promoter region by using single-strand conformation polymorphism. One mutation was an 11-bp CCCCGCCCCGT deletion mutation from positions -140 to -150 relative to the transcription start site, corresponding to an Sp1 binding site; the other was a C-->T substitution at position -142. Twenty-six of 690 unrelated subjects were heterozygous for the -140 to -150 deletion mutation, and the allele frequency in this population was 0.02. This study showed that the deletion variant prevented binding of Sp1 to this region of the SR-BI promoter and effectively reduced transcriptional activities in HepG2 cells. Notably, the -140 to -150 deletion mutation was significantly associated with increased HDL-C levels and explained approximately 0.5% of the variation in HDL-C levels in this population. CONCLUSIONS: A genetic variant at the SR-BI gene promoter region might explain a significant proportion of individual differences in HDL-C levels among Taiwanese Chinese. Our results require further replication in an independent population.