S1 nuclease mapping of viral RNAs from a temperature-sensitive transformation mutant of murine sarcoma virus

The structures of murine sarcoma virus (MuSV) ts110 viral RNA and intracellular RNA present in MuSV ts110-infected cells (6m2 cells) have been examined by S1 nuclease analysis. A previous study involving heteroduplex analysis of MuSV ts110 viral RNAs hybridized to wild-type DNA revealed the presence of two MuSV ts110 RNAs, 4.0 and 3.5 kilobases (kb) in length, containing overlapping central deletions relative to wild-type MuSV 124 viral RNA (Junghans et al., J. Mol. Biol. 161:229-255, 1982). Here we show that the deletion (termed delta 1) in the 4.0-kb RNA has a 5' border located at about nucleotide 2409 (using the numbering system of Van Beveren et al., Cell 27:97-108, 1981), a position 63 bases upstream of the junction of the p30 and p10 coding sequences. The 3' border of the delta 1 deletion is found 1,473 bases downstream at approximately nucleotide 3883, 10 nucleotides downstream of the first mos gene initiation codon. In the 3.5-kb MuSV ts110 RNA, the 5' border of the deleted central region (termed delta 2) is located in a splice consensus donor site at approximately nucleotide 2017, 330 bases downstream from the junction of the p12 and p30 coding sequences, and extends about 1,915 bases in the downstream direction to nucleotide 3935, found in a splice consensus acceptor site about 55 nucleotides downstream of the first mos gene initiation codon and 30 bases upstream of the second initiation codon. No alteration of polyadenylate addition sites was observed in either MuSV ts110 RNA species, as compared with MuSV 349 RNA. The observation that the 5' and 3' borders of the deletion in the 3.5-kb RNA are within in-frame splice donor and acceptor sites suggests strongly that the 3.5-kb RNA is derived from the 4.0-kb RNA by a temperature-sensitive splice mechanism. Data presented here show unequivocally that formation of the 3.5-kb MuSV ts110 RNA from which the P85gag-mos polypeptide is translated is temperature sensitive. At 33 degrees C, with S1 analysis, the 3.5-kb RNA is found readily in 6m2 cells. Within 4 h of a shift to 39 degrees C, however, only trace amounts of this RNA can be found. Moreover, reshifting 6m2 cells to 33 degrees C permits the reappearance of the 3.5-kb RNA at its original level.     

Nonsense mutations in close proximity to the initiation codon fail to trigger full nonsense-mediated mRNA decay

Nonsense-mediated mRNA decay (NMD) is a surveillance mechanism that degrades mRNAs containing premature translation termination codons. In mammalian cells, a termination codon is ordinarily recognized as "premature" if it is located greater than 50-54 nucleotides 5' to the final exon-exon junction. We have described a set of naturally occurring human beta-globin gene mutations that apparently contradict this rule. The corresponding beta-thalassemia genes contain nonsense mutations within exon 1, and yet their encoded mRNAs accumulate to levels approaching wild-type beta-globin (beta(WT)) mRNA. In the present report we demonstrate that the stabilities of these mRNAs with nonsense mutations in exon 1 are intermediate between beta(WT) mRNA and beta-globin mRNA carrying a prototype NMD-sensitive mutation in exon 2 (codon 39 nonsense; beta 39). Functional analyses of these mRNAs with 5'-proximal nonsense mutations demonstrate that their relative resistance to NMD does not reflect abnormal RNA splicing or translation re-initiation and is independent of promoter identity and erythroid specificity. Instead, the proximity of the nonsense codon to the translation initiation AUG constitutes a major determinant of NMD. Positioning a termination mutation at the 5' terminus of the coding region blunts mRNA destabilization, and this effect is dominant to the "50-54 nt boundary rule." These observations impact on current models of NMD.     

Introns are cis effectors of the nonsense-codon-mediated reduction in nuclear mRNA abundance.

The translation of human triosephosphate isomerase (TPI) mRNA normally terminates at codon 249 within exon 7, the final exon. Frameshift and nonsense mutations of the type that cause translation to terminate prematurely at or upstream of codon 189 within exon 6 reduce the level of nuclear TPI mRNA to 20 to 30% of normal by a mechanism that is not a function of the distance of the nonsense codon from either the translation initiation or termination codon. In contrast, frameshift and nonsense mutations of another type that cause translation to terminate prematurely at or downstream of codon 208, also within exon 6, have no effect on the level of nuclear TPI mRNA. In this work, quantitations of RNA that derived from TPI alleles in which nonsense codons had been generated between codons 189 and 208 revealed that the boundary between the two types of nonsense codons resides between codons 192 and 195. The analysis of TPI gene insertions and deletions indicated that the positional feature differentiating the two types of nonsense codons is the distance of the nonsense codon upstream of intron 6. For example, the movement of intron 6 to a position downstream of its normal location resulted in a concomitant downstream movement of the boundary between the two types of nonsense codons. The analysis of intron 6 mutations indicated that the intron 6 effect is stipulated by the 88 nucleotides residing between the 5' and 3' splice sites. Since the deletion of intron 6 resulted in only partial abrogation of the nonsense codon-mediated reduction in the level of TPI mRNA, other sequences within TPI pre-mRNA must function in the effect. One of these sequences may be intron 2, since the deletion of intron 2 also resulted in partial abrogation of the effect. In experiments that switched introns 2 and 6, the replacement of intron 6 with intron 2 was of no consequence to the effect of a nonsense codon within either exon 1 or exon 6. In contrast, the replacement of intron 2 with intron 6 was inconsequential to the effect of a nonsense codon in exon 6 but resulted in partial abrogation of a nonsense codon in exon 1.     

Human metallothionein MT-I and MT-II processed genes

Two intronless pseudogenes, corresponding to the human metallothionein MT-I and MT-II processed genes, have been isolated from a human genomic library. MT-I processed gene has accumulated a number of mutations including a nonsense mutation giving rise to a termination codon at amino acid position 21, and a single base deletion at amino acid position 47 causing a shift in the reading frame. MT-II processed gene is a full-length perfect copy of its corresponding mRNA except for a few mutations. Most of the mutations in MT-II processed gene are silent except that the amino acid glycine (GGT) at position 10 is changed to serine (AGT) due to a transition. Both MT-I and MT-II processed genes possess poly(A) sequences of 21 and 17 nucleotides, respectively, 3' to the consensus AATAAA sequence. While these genes are quite similar in their sequences at the 3'-untranslated region, they show less than 50% homology in the 5'-untranslated sequences. Two direct repeats of 16 and 18 nucleotides in length define the limits of the MT-I and MT-II processed genes, respectively, and have been confirmed by S1 nuclease mapping analysis. In both MT-I and MT-II processed genes these direct repeats towards the 5' end of the gene start with an AhaIII (TTTAAA) restriction site. Our studies suggest that these direct repeats are the results of the insertion site duplication.     

Challenging the Roles of NSP3 and Untranslated Regions in Rotavirus mRNA Translation

Rotavirus NSP3 is a translational surrogate of the PABP-poly(A) complex for rotavirus mRNAs. To further explore the effects of NSP3 and untranslated regions (UTRs) on rotavirus mRNAs translation, we used a quantitative in vivo assay with simultaneous cytoplasmic NSP3 expression (wild-type or deletion mutant) and electroporated rotavirus-like and standard synthetic mRNAs. This assay shows that the last four GACC nucleotides of viral mRNA are essential for efficient translation and that both the NSP3 eIF4G- and RNA-binding domains are required. We also show efficient translation of rotavirus-like mRNAs even with a 5’UTR as short as 5 nucleotides, while more than eleven nucleotides are required for the 3’UTR. Despite the weak requirement for a long 5’UTR, a good AUG environment remains a requirement for rotavirus mRNAs translation.     

Characterization of yeast iso-1-cytochrome c mRNA

The iso-1-cytochrome c mRNA has been identified by hybridization of a 32P probe prepared from a plasmid containing the iso-1-cytochrome c gene to RNA size-fractionated on agarose gels and transferred to paper. A hybridization band was visible with RNA prepared from wild type cells, but not with RNA prepared from an iso-1-cytochrome c deletion mutant. RNA prepared from cells containing a nonsense mutation in the iso-1-cytochrome c gene showed reduced levels of hybridization. The RNA that hybridized to the probe was 700 +/- 50 nucleotides in length and was polyadenylated. The cellular levels of this RNA were repressed by glucose, and this repression was achieved within 5 min after glucose addition to a derepressed culture. No precursors of this RNA were detected in wild type cells or in an RNA1 mutant, temperature-sensitive for RNA metabolism. The length of the 3' noncoding region of this RNA was determined to be 200 +/- 25 nucleotides (excluding the poly(A) tail) and the 5' noncoding region was estimated to be about 120 nucleotides in length.     

A deletion of five nucleotides in the LICAM gene in a Japanese family with X-linked hydrocephalus

X-linked hydrocephalus (HSAS) is the most common form of inherited hydrocephalus characterized by hydrocephalus due to stenosis of the aqueduct of Sylvius, mental retardation, clasped thumbs, and spastic paraparesis. MASA syndrome (mental retardation, aphasia, shuffling gait and adducted thumbs) and SPG1 (X-linked complicated spastic paraplegia) are also X-linked disorders with overlapping clinical signs. Linkage analysis studies implicated the neural cell adhesion molecule L1 (LICAM) gene as a candidate gene for these X-linked disorders. This genetic study analyzes the LICAM gene in a Japanese family with members suffering from HSAS, and describes a deletion of five nucleotides in exon 8. Screening byBg1I digestion of polymerase chain reaction (PCR) products revealed that two siblings have the same mutation and a sister was identified as a heterozygous carrier. The 5 nucleotide deletion causes a shift of the reading frame and introduces a premature stop codon 72 nucleotides downstream, which might result in a truncated protein. The mutation identified herein is a novel L1 CAM mutation, which triggers hydrocephalus. We report a unique LlCAM mutation that causes HSAS: the first report of such a mutation in a Japanese family.     

Influence of the three nucleotides upstream of the initiation codon on expression of the Escherichia coli lacZ gene in Saccharomyces cerevisiae.

By introducing synthetic oligonucleotides into a lacZ-yeast expression vector a set of 47 plasmids (out of 64 possible) was generated, differing only in the three bases immediately upstream of the AUG initiation codon of the Escherichia coli lacZ gene. Expression of the beta-galactosidase fusion protein encoded by the different plasmids was determined in Saccharomyces cerevisiae by immunogel electrophoresis. Among the clones tested we found a factor 3 difference in expression. A slight nucleotide preference was found in positions -3(A > G > C = U) and -2 (G > C = U > A). The choice of the nucleotide at position -1 immediately 5' of the AUG did not effect translation efficiency. Increasing homology to the yeast consensus sequence (AAAAAAAUGUCU) was not concomitant with an increased translation efficiency. Our results indicate that the choice of nucleotides immediately preceding the initiation codon in yeast does not dramatically influence translation efficiency, as in prokaryotes or higher eukaryotes.     

Rous sarcoma virus RNA stability requires an open reading frame in the gag gene and sequences downstream of the gag-pol junction.

The intracellular accumulation of the unspliced RNA of Rous sarcoma virus was decreased when translation was prematurely terminated by the introduction of nonsense codons within its 5' proximal gene, the gag gene. Subcellular fractionation of transfected cells suggested that nonsense codon-mediated instability occurred in the cytoplasm. Analysis of constructs containing an in-frame deletion in the nucleocapsid domain of gag, which prevents interaction between the Gag protein and viral RNA, showed that an open reading frame extending to approximately 30 nucleotides from the natural gag termination codon was needed for RNA stability. Sequences at the gag-pol junction necessary for ribosomal frameshifting were not required for RNA stability; however, sequences located 100 to 200 nucleotides downstream of the natural gag termination codon were found to be necessary for stable RNA. The stability of RNAs lacking this downstream sequence was not markedly affected by premature termination codons. We propose that this downstream RNA sequence may interact with ribosomes translating gag to stabilize the RNA.     

Identification of splicing mutations of the last nucleotides of exons, a nonsense mutation, and a missense mutation of the XPAC gene as causes of group A xeroderma pigmentosum.

Four mutations of the XPAC gene were identified as molecular bases of different UV-sensitive subgroups of xeroderma pigmentosum (XP) group A. One was a G to C transversion at the last nucleotide of exon 4 in GM1630/GM2062, a little less hypersensitive subgroup than the most sensitive XP2OS/XP12RO. The second mutation was a G to A transition at the last nucleotide of exon 3 in GM2033/GM2090, an intermediate subgroup. Both mutations caused almost complete inactivation of the canonical 5' splice donor site and aberrant RNA splicing. The third mutation was a nucleotide transition altering the Arg-211 codon (CGA) to a nonsense codon (TGA) in another allele of GM2062. The fourth mutation was a nucleotide transversion altering the His-244 codon (CAT) to an Arg codon (CGT) in XP8LO, an intermediate subgroup. Our results strongly suggest that the clinical heterogeneity in XP-A is due to different mutations in the XPAC gene.     

Footprinting mRNA-ribosome complexes with chemical probes.

We footprinted the interaction of model mRNAs with 30S ribosomal subunits in the presence or absence of tRNA(fMet) or tRNA(Phe) using chemical probes directed at the sugar-phosphate backbone or bases of the mRNAs. When bound to the 30S subunits in the presence of tRNA(fMet), the sugar-phosphate backbones of gene 32 mRNA and 022 mRNA are protected from hydroxyl radical attack within a region of about 54 nucleotides bounded by positions -35 (+/- 2) and +19, extending to position +22 when tRNA(Phe) is used. In 70S ribosomes, protection is extended in the 5' direction to about position -39 (+/- 2). In the absence of tRNA, the 30S subunit protects only nucleotides -35 (+/- 2) to +5. Introduction of a stable tetraloop hairpin between positions +10 and +11 of gene 32 mRNA does not interfere with tRNA(fMet)-dependent binding of the mRNA to 30S subunits, but results in loss of protection of the sugar-phosphate backbone of the mRNA downstream of position +5. Using base-specific probes, we find that the Shine-Dalgarno sequence (A-12, A-11, G-10 and G-9) and the initiation codon (A+1, U+2 and G+3) of gene 32 mRNA are strongly protected by 30S subunits in the presence of initiator tRNA. In the presence of tRNA(Phe), the same Shine-Dalgarno bases are protected, as are U+4, U+5 and U+6 of the phenylalanine codon. Interestingly, A-1, immediately preceding the initiation codon, is protected in the complex with 30S subunits and initiator tRNA, while U+2 and G+3 are protected in the complex with tRNA(Phe) in the absence of initiator tRNA. Additionally, specific bases upstream from the Shine-Dalgarno region (U-33, G-32 and U-22) as well as 3' to the initiation codon (G+11) are protected by 30S subunits in the presence of either tRNA. These results imply that the mRNA binding site of the 30S subunit covers about 54-57 nucleotides and are consistent with the possibility that the ribosome interacts with mRNA along its sugar-phosphate backbone.     

Delimitation of a DNA sequence which confers inducibility by glucocorticoid hormones

A chimeric long terminal repeat-thymidine kinase (LTR-tk) gene has been used to define the sequence requirements for glucocorticoid induction of gene expression. The original LTR-tk gene contains an entire mouse mammary tumor virus (MMTV) LTR preceding the tk gene. This gene can be expressed in a hormone-responsive fashion upon transfection into L tk--cells to produce a chimeric LTR-tk mRNA. Stepwise deletion of nucleotide sequences 5' of the viral RNA initiation site revealed that 202 nucleotides upstream of the viral cap site are sufficient for the hormonal regulation. Deletion of 5' sequences up to 59 nucleotides upstream of the viral cap site abolished RNA initiation in the LTR and hormonal induction.     

The cytoplasmic domain of simian immunodeficiency virus transmembrane protein modulates infectivity.

A striking characteristic of the simian immunodeficiency virus (SIV) and of the human immunodeficiency virus type 2 (HIV-2) is the presence of a nonsense mutation in the env gene resulting in the synthesis of a truncated transmembrane protein lacking the cytoplasmic domain. By mutagenesis of an infectious molecular clone of SIVmac142, we investigated the function of the cytoplasmic domain and the significance of the env nonsense mutation. When the nonsense codon (TAG) was replaced by a glutamine codon (CAG), the virus infected HUT78 cells with markedly delayed kinetics. This negative effect was counterselected in vitro as reversion of the slow phenotype frequently occurred. The sequencing of one revertant revealed the presence of a new stop codon three nucleotides 5' to the original mutation. Deletions or an additional nonsense mutation introduced 3' to the original stop codon did not modify SIV infectivity. In contrast, the same deletions or nonsense mutation introduced in the clone in which the stop codon was replaced by CAG abolished infectivity. These results indicated that the envelope domain located 3' to the stop codon is not necessary for in vitro replication. However, the presence of this domain in SIV transmembrane protein leads to a reduced infectivity. This negative effect might correspond to a function controlling the rate of spread of the virus during in vivo infection.     

H5N1亚型禽流感病毒NS第263—277位核苷酸缺失提高病毒对鸡的致病力

为研究2000年以来绝大多数H5N1亚型禽流感病毒分离株在非结构基因的第263—277位发生15个碱基缺失现象的生物学意义,构建H5N1A／D／SD／04株HA、NA、NS的全基因表达／转录载体,以及NS的删除突变载体（m248）,A/D/YZ/04株的NS基因表达／转录载体（848）和其补加15个核苷酸的NS突变载体（m848）。构建的载体分别与编码WSN（H1N1）内部基因载体进行组合转染,拯救获得4个具不同NS的重组的H5N1亚型流感病毒：RWSN-848和RWSN—m248在263-277位缺失15个碱基。RWSN-m848和RWSN-248则在相同位置不发生缺失。4个重组病毒的平均鸡胚繁殖效价（HA）、鸡胚的平均死亡时间（MDT）和鸡胚半数感染量（EID50）均无显著差异;但RWSN-848和RWSN-m248对6周龄SPF鸡的致病力明显高于RWSN—m848和RWSN-248。结果说明H5N1的NS基因在263～277位核苷酸发生缺失后,不影响重组H5N1在鸡胚中的繁殖性能,但提高了病毒对鸡的致病力。     

Rotavirus Nonstructural Protein 1 Suppresses Virus-Induced Cellular Apoptosis To Facilitate Viral Growth by Activating the Cell Survival Pathways during Early Stages of Infection

Following virus infection, one of the cellular responses to limit the virus spread is induction of apoptosis. In the present study, we report role of rotavirus nonstructural protein 1 (NSP1) in regulating apoptosis by activating prosurvival pathways such as phosphatidylinositol 3-kinase (PI3K)/Akt and NF-κB (nuclear factor κB) during early hours of infections (2 to 8 hpi). The NSP1 mutant strain A5-16 induces weak and transient activation of Akt (protein kinase B) and p65 NF-κB compared to the isogenic wild-type strain A5-13 in MA104 or HT29 cells. The weak NF-κB promoter activity or Akt phosphorylation after A5-16 infection could be complemented in cells transfected with plasmid expressing NSP1 after infection with the rotavirus A5-16 strain. In cells either infected with A5-13 or transfected with pcD-NSP1, coimmunoprecipitation of NSP1 with phosphoinositide 3-kinase (PI3K) was observed, indicating that strong activation of PI3K/Akt could be due to its interaction with NSP1. In addition, after infection with same multiplicity of infection, A5-16 showed reduced number of viral particles compared to the A5-13 strain at the end of the replication cycle. A lower growth rate could be due to weak induction of PI3K/Akt and NF-κB, since the A5-13 strain also showed reduced growth in the presence of PI3K or NF-κB inhibitors. This effect was interferon independent; however, it was partly due to significantly higher caspase-3 activity, poly-ADP ribose polymerase (PARP) cleavage, and apoptosis during earlier stages of infection with the NSP1 mutant. Thus, our data suggest that NSP1 positively supports rotavirus growth by suppression of premature apoptosis for improved virus growth after infection.Virus infection results in the activation of a variety of cellular signaling pathways that are required not only for mounting an antiviral response to infection but are also exploited by viruses to support their replication in host cells. All stages of viral infection including entry, the production of double-stranded RNA (dsRNA), and the expression of viral proteins can activate innate immune response (35). Viral infection stimulates the phosphorylation and subsequent dimerization of a ubiquitously expressed 55-kDa protein, IFN regulatory factor 3 (IRF3), which then translocates to the nucleus and induces type I interferons (IFNs; IFN-α and -β) as the first line of defense against infections (29, 35). The secreted IFNs signal the production and activation of antiviral proteins in neighboring cells to control the spread of infection. To counteract these antiviral responses, viruses have evolved mechanisms to suppress the IFN-mediated signaling pathways. VP35 of Ebola virus, NS1 and NS2 of respiratory syncytial virus (RSV), NS1 of influenza virus, the E6 protein of human papillomavirus, etc., suppress IFN induction by inhibiting either the activation of IRF3 (5, 23, 50, 52) or the IFN-induced JAK/STAT pathway (30). Other than the inhibition of innate immune responses, it is also important for a virus to keep the infected cell alive to complete its life cycle. Thus, viruses have also evolved mechanisms to modulate the host cellular apoptotic pathways. For example, NS1 and NS2 proteins of RSV suppress premature apoptosis of host cell by a nuclear factor κB (NF-κB)-dependent and IFN-independent mechanism (6), whereas poliovirus, influenza virus, and dengue virus have been shown to limit premature cell death by early activation of phosphoinositide 3-kinase (PI3K)/Akt pathway (2, 17, 39).Rotaviruses, members of the family Reoviridae, are the major cause of severe gastroenteritis in children younger than 5 years of age. Calves, piglets, and other animals of economic importance are also susceptible to rotavirus infection (21). Rotaviruses generally infect the enterocytes of the small intestine; however, there have recently been increasing reports of extraintestinal infections (7), highlighting the importance of better knowledge of the mechanisms of viral pathogenesis and virus-host cell interactions (11, 32).The virus is a icosahedral structure consisting of three concentric layers of proteins and a genome of 11 dsRNA segments (21). In addition to the six structural proteins (VP1 to VP4, VP6, and VP7) which form the virion, the virus also encodes six nonstructural proteins (NSP1 to NSP6). Nonstructural proteins (NSPs) are of great interest since these are translated only in host cells after virus infection and do not form part of the mature infectious virus. In general, the NSPs of viruses have been associated with diverse functions such as interactions of virus with host cell, RNA binding, evasion of immune response, inhibition of cellular translation, etc. (2, 6, 8, 17, 23, 30, 50, 52). There are limited reports regarding the role of rotavirus-encoded NSPs. Rotavirus NSP4 is a putative viral enterotoxin (18), NSP3 has been implicated in PABP binding and nuclear translocation of PABP binding protein (27), NSP3 has been also shown to interact with protein kinase R (PKR) (38), and NSP1 has been shown to inhibit the induction of IFN by inducing the degradation of IRF-3, -5, and -7 (3, 4, 45).Rotavirus NSP1, an RNA-binding protein (21), is the only rotavirus protein implicated in evasion of innate immune response by counteracting induction of IFN to influence virus replication (4, 22); however, whether NSP1 or other rotavirus-encoded proteins modulate any other host cellular signaling pathways is not well understood. Rotaviruses have been shown to activate PI3K-mediated integrin expression and NF-κB (25, 42), but no viral protein has been reported to directly associate with these pathways. Unlike other rotavirus proteins, NSP1 is highly variable among group A rotaviruses (31), except for a conserved N-terminus cysteine-rich motif (C-X2-C-X8-C-X2-C-X3-H-X-C-X2-C-X-5-C), which is a putative zinc finger motif. Since this region is conserved, it has been postulated that it may have an important role in function of the protein. The C terminus of NSP1 has an IRF3 binding site and has been shown to be involved in IRF3 degradation (3, 4). To study the role of NSP1 in modulation of apoptosis, we utilized an NSP1 wild-type (wt) bovine rotavirus strain A5-13 and an isogenic NSP1 mutant strain, A5-16. The NSP1 of A5-16 has a 500-nucleotide deletion (nucleotides 142 to 641) in the N terminus, including the cysteine-rich zinc finger motif (Fig. ​(Fig.11 A), followed by a nonsense codon resulting in lack of detectable functional protein (53). A5-16 is not replication defective, although it has been shown to have smaller plaque size compared to A5-13 (53). This is the first report showing that rotavirus NSP1 helps rotavirus to establish and replicate efficiently in host cells by inhibiting the cellular apoptosis through the activation of the prosurvival pathways PI3K/Akt and NF-κB during the initial stages of infection.Open in a separate windowFIG. 1.(A) Schematic diagram of full-length (1,579 bases; wt A5-13) and deletion mutant (1,087 bases; mutant A5-16) gene segments 5 encoding NSP1 (59 kDa) of rotavirus. In A5-13, nucleotide positions 105 to 246 and 246 to 531 correspond to the deduced RING domain and cytoskeleton localization domain sequence, respectively, whereas position 981 to the rest of the gene implies an IRF3 binding domain. The NSP1 gene of A5-16 has a 500-nucleotide deletion from nucleotides 142 to 641, followed by an immediate stop codon at positions 183 to 185, indicating the lack of a functional RING domain and cytoskeleton localization domain. (B) Immunoblot analyses showing the expression of structural protein VP6 and nonstructural proteins NSP1 and NSP3 of both wt A5-13 and mutant A5-16 strains (MOI of 3, 12 hpi). Both A5-13- and A5-16-infected cells expressed VP6 and NSP3 proteins, but NSP1 expression was observed only in A5-13-infected cells. The blots were reprobed with β-actin antibody to confirm equal protein loading.