Koyu Hara

Amino Acid Residues in the N-Terminal Region of the PA Subunit of Influenza A Virus RNA Polymerase Play a Critical Role in Protein Stability, Endonuclease Activity, Cap Binding, and Virion RNA Promoter Binding

ABSTRACT The RNA-dependent RNA polymerase of influenza virus is a heterotrimer formed by the PB1, PB2, and PA subunits. Although PA is known to be required for polymerase activity, its precise role is still unclear. Here, we investigated the function of the N-terminal region of PA. Protease digestion of purified recombinant influenza virus A/PR/8/34 PA initially suggested that its N-terminal region is folded into a 25-kDa domain. We then systematically introduced point mutations into evolutionarily conserved amino acids in the N-terminal region of influenza virus A/WSN/33. Most alanine-scanning mutations between residues L109 and F117 caused PA degradation, mediated by a proteasome-ubiquitin pathway, and as a consequence interfered with polymerase activity. Three further PA mutations, K102A, D108A, and K134A, were investigated in detail. Mutation K102A caused a general decrease both in transcription and replication in vivo, whereas mutations D108A and K134A selectively inhibited transcription. Both the D108A and K134A mutations completely inhibited endonuclease activity in vitro, explaining their selective defect in transcription. K102A, on the other hand, resulted in a significant decrease in both cap binding and viral RNA promoter-binding activity and consequently inhibited both transcription and replication. These results suggest that the N-terminal region of PA is involved in multiple functions of the polymerase, including protein stability, endonuclease activity, cap binding, and promoter binding.

Influenza virus RNA polymerase PA subunit is a novel serine protease with Ser624 at the active site

Influenza virus RNA polymerase is a multifunctional enzyme that catalyses both transcription and replication of the RNA genome. The function of the influenza virus RNA polymerase PA subunit in viral replication is poorly understood, although the enzyme is known to be required for cRNA → vRNA synthesis. The protease related activity of PA has been discussed ever since protease‐inducing activity was demonstrated in transfection experiments.

Caenorhabditis elegans reticulon interacts with RME-1 during embryogenesis

Reticulon (RTN) family proteins are localized in the endoplasmic reticulum (ER). At least four different RTN genes have been identified in mammals, but in most cases, the functions of the encoded proteins except mammalian RTN4-A and RTN4-B are unknown. Each RTN gene produces 1-3 proteins by different promoters and alternative splicing. In Caenorhabditis elegans, there is a single gene (rtn gene) encoding three reticulon proteins, nRTN-A, B, and C. mRNA of nRTN-C is expressed in germ cells and embryos. However, nRTN-C protein is only expressed during embryogenesis and rapidly disappears after hatch. By yeast two-hybrid screening, two clones encoding the same C-terminal region of RME-1, a protein functioning in the endocytic recycling, were isolated. These findings suggest that nRTN-C functions in the endocytic pathway during embryogenesis.

Nosocomial outbreak of epidemic keratoconjunctivitis accompanying environmental contamination with adenoviruses.

An outbreak of acute keratoconjunctivitis involving 27 patients occurred in the Department of Ophthalmology, Kurume University Hospital. Adenoviral DNA was detected in four inpatients, one outpatient and one healthcare worker. Sequence-based typing of adenoviral DNA indicated serotype 3 from one inpatient, the rest being serotype 37. At a later stage of the outbreak adenoviral DNA types 37 and/or 3 were also detected from almost all environmental instruments and commonly used eye drops, despite thorough disinfection of the environment and enforcement of various infection control measures. The detection rate of adenoviral DNA in environmental swabs was 81%. A further second disinfection of the environment reduced the detection rate of adenoviral DNA to 38%. The outbreak ceased after closing the ophthalmology ward and outpatient consulting room, accompanied by enhanced cleaning of environmental instruments and the introduction of disposable eye drops for individual patients.

Inhibition of influenza virus replication in cultured cells by RNA‐cleaving DNA enzyme

Influenza virus replication has been effectively inhibited by antisense phosphothioate oligonucleotides targeting the AUG initiation codon of PB2 mRNA. We designed RNA‐cleaving DNA enzymes from 10‐23 catalytic motif to target PB2‐AUG initiation codon and measured their RNA‐cleaving activity in vitro. Although the RNA‐cleaving activity was not optimal under physiological conditions, DNA enzymes inhibited viral replication in cultured cells more effectively than antisense phosphothioate oligonucleotides. Our data indicated that DNA enzymes could be useful for the control of viral infection.

Promoter/Origin Structure of the Complementary Strand of Hepatitis C Virus Genome

Hepatitis C virus (HCV) NS5B protein encodes an RNA-dependent RNA polymerase (RdRp). Sequences in the 3′ termini of both the plus and minus strand of HCV genomic RNA harbor the activity of a replication origin and a transcription promoter. There are unique stem-loop structures in both termini of the viral RNA. We found that the complementary strand of the internal ribosome-binding site (IRES) showed strong template activity in vitro. The complementary strand RNA of the HCV genome works as a template for mRNA and viral genomic RNA. We analyzed the promoter/origin structure of the complementary sequence of IRES and found that the first and second stem-loops worked as negative and positive elements in RNA synthesis, respectively. The complementary strand of the second stem-loop of IRES was an important element also for binding to HCV RdRp.

Co-incorporation of the PB2 and PA polymerase subunits from human H3N2 influenza virus is a critical determinant of the replication of reassortant ribonucleoprotein complexes.

The influenza virus RNA polymerase, composed of the PB1, PB2 and PA subunits, has a potential role in influencing genetic reassortment. Recent studies on the reassortment of human H3N2 strains suggest that the co-incorporation of PB2 and PA from the same H3N2 strain appears to be important for efficient virus replication; however, the underlying mechanism remains unclear. Here, we reconstituted reassortant ribonucleoprotein (RNP) complexes and demonstrated that the RNP activity was severely impaired when the PA subunit of H3N2 strain A/NT/60/1968 (NT PA) was introduced into H1N1 or H5N1 polymerase. The NT PA did not affect the correct assembly of the polymerase trimeric complex, but it significantly reduced replication-initiation activity when provided with a vRNA promoter and severely impaired the accumulation of RNP, which led to the loss of RNP activity. Mutational analysis demonstrated that PA residues 184N and 383N were the major determinants of the inhibitory effect of NT PA and 184N/383N sequences were unique to human H3N2 strains. Significantly, NT PB2 specifically relieved the inhibitory effect of NT PA, and the PB2 residue 627K played a key role. Our results suggest that PB2 from the same H3N2 strain might be required for overcoming the inhibitory effect of H3N2 PA in the genetic reassortment of influenza virus.

Artificial Hybrids of Influenza A Virus RNA Polymerase Reveal PA Subunit Modulates Its Thermal Sensitivity

Background Influenza A virus can infect a variety of different hosts and therefore has to adapt to different host temperatures for its efficient viral replication. Influenza virus codes for an RNA polymerase of 3 subunits: PB1, PB2 and PA. It is well known that the PB2 subunit is involved in temperature sensitivity, such as cold adaptation. On the other hand the role of the PA subunit in thermal sensitivity is still poorly understood. Methodology/Principal Findings To test which polymerase subunit(s) were involved in thermal stress we reconstituted artificial hybrids of influenza RNA polymerase in ribonucleoprotein (RNP) complexes and measured steady-state levels of mRNA, cRNA and vRNA at different temperatures. The PA subunit was involved in modulating RNP activity under thermal stress. Residue 114 of the PA subunit was an important determinant of this activity. Conclusions/Significance These findings suggested that influenza A virus may acquire an RNA polymerase adapted to different body temperatures of the host by reassortment of the RNA polymerase genes.

Ser624 of the PA subunit of Influenza A virus is not essential for viral growth in cells and mice, but required for the maximal viral growth

Summary. Serine at position 624 of PA subunit of the Influenza A virus RNA polymerase is the active site of a serine protease domain. To examine the role of this protease activity in the viral infection cycle, we compared the growth and the pathogenesis of influenza A/WSN/33 (WSN) and the virus encoding a PA with a S624A mutation (S624A virus), which were generated by the plasmid-based rescue system. The growth of S624A virus was less extensive than that of WSN in cells. The LD50 of S624A virus and WSN for intranasal infection in Balb/C mice was 4.0×104 and 9.3×103 PFU, respectively. That for intracranial infection was 460 and 200 PFU, respectively. These data indicated that Ser624, the active site of the serine protease activity of PA, is not essential for viral growth and pathogenesis, but is required for the maximal viral growth.

Isolation of Amantadine-Resistant Influenza A Viruses (H3N2) from Patients following Administration of Amantadine in Japan

ABSTRACT In Japan, the use of amantadine for treatment of influenza A virus infection was not accepted until November 1998, although it was widely used for treatment of Parkinsonism. Since then, we have monitored the emergence of amantadine-resistant viruses and isolated two viruses from patients on long-term treatment with amantadine.