The mechanism of inhibition of reovirus replication by interferon

The important roles of type I interferon and interferon-inducible genes in systemic lupus erythematosus

Systemic lupus erythematosus (SLE) is a severe autoimmune disease that causes multiple-organ dysfunction mainly affecting women in their childbearing years. Type I IFN synthesis is usually triggered by viruses, and its production is tightly regulated and limited in time in health individuals. However, many patients with systemic autoimmune diseases including SLE have signs of aberrant production of type I interferon (IFN) and display an increased expression of IFN-inducible genes. Continuous type I IFNs derived from activated plasmacytoid dendritic cells (pDCs) by interferogenic immune complexes (ICs) and migration of these cells to tissues both break immune tolerance and promote an on-going autoimmune reaction in human body. By the means of detecting type I IFNs and IFN-inducible genes, it can help with diagnosis and evaluation of SLE in early stage and more efficiently. Anti-IFN-α monoclonal antibodies in SLE patients were recently reported and is now being investigated in phase II clinical trails. In this review, we focus on recent research progress in type I IFN and IFN-inducible genes. Possible mechanisms behind the dysregulated type I IFN system in SLE and how they contribute to the development of an autoimmune process, and act as a biomarker and therapeutic target will be reviewed.

Avian reovirus: Structure and biology

Avian reoviruses are important pathogens that cause considerable losses to the poultry industry, but they have been poorly characterized at the molecular level in the past, mostly because they have been considered to be very similar to the well-studied mammalian reoviruses. Studies performed over the last 20 years have revealed that avian reoviruses have unique properties and activities, different to those displayed by their mammalian counterparts, and of considerable interest to molecular virologists. Notably, the avian reovirus S1 gene is unique, in that it is a functional tricistronic gene that possesses three out-of-phase and partially overlapping open reading frames; the identification of the mechanisms that govern the initiation of translation of the three S1 cistrons, and the study of the properties and activities displayed by their encoded proteins, are particularly interesting areas of research. For instance, avian reoviruses are one of the few nonenveloped viruses that cause cell-cell fusion, and their fusogenic phenotype has been associated with a nonstructural 10 kDa transmembrane protein, which is expressed by the second cistron of the S1 gene; the small size of this atypical fusion protein offers an interesting model for studying the mechanisms of cell-cell fusion and for identifying fusogenic domains. Finally, avian reoviruses are highly resistant to interferon, and therefore they may be useful for investigating the mechanisms and strategies that viruses utilize to counteract the antiviral actions of interferons.

Correlation between interferon sensitivity of reovirus isolates and ability to discriminate between normal and Ras-transformed cells

Mammalian reoviruses exhibit a propensity to replicate in transformed cells. It is currently believed that the interferon-inducible RNA-dependent protein kinase (PKR), an intracellular host-cell resistance factor that is inhibited by an activated Ras-dependent pathway in transformed cells, is responsible for this discrimination. In the present study, reovirus isolates differing in their sensitivity to interferon were obtained by chemical mutagenesis, and examined for their replicative properties in parental and Ras-transformed mouse NIH-3T3 cells. It was observed that most isolates can bypass resistance mechanisms of parental cells at high m.o.i., and that there is a correlation between the ability to discriminate between transformed and parental cells, and interferon sensitivity. Most interestingly, an interferon-hypersensitive mutant virus was more dependent on Ras activation than any other viral isolate. Altogether, this suggests that optimal reovirus isolates could be selected to attack tumour cells depending on the nature of the alterations in interferon-inducible pathways found in these cells.

Characterization of the thermosensitive ts453 reovirus mutant: increased dsRNA binding of sigma 3 protein correlates with interferon resistance

The mutation harbored by the reovirus ts453 thermosensitive mutant has been assigned to the S4 gene encoding the major outer capsid protein sigma 3. Previous gene sequencing has identified a nonconservative amino acid substitution located near the zinc finger of sigma 3 protein in the mutant. Coexpression in COS cells of the sigma 3 protein presenting this amino acid substitution (N16K), together with the other major capsid protein mu 1, has also revealed an altered interaction between the two proteins; this altered interaction prevents the sigma 3-dependent cleavage of mu 1 to mu 1C. This could explain the lack of outer capsid assembly observed during ts453 virus infection at nonpermissive temperature. In the present study, we pursued the characterization of this mutant sigma 3 protein. Although the N16K mutation is located close to the zinc finger region, it did not affect the ability of the protein to bind zinc. In contrast, this mutation, as well as mutations within the zinc finger motif itself, can increase the binding of the protein to double-stranded RNA (dsRNA). It also appears that the N16K mutant protein is more efficiently transported to the nucleus than the wild-type protein, an observation consistent with the postulated role of dsRNA binding in sigma 3 nuclear presence. The lack of association with mu 1, and/or the increased dsRNA-binding activity of sigma 3, could be responsible for a partial resistance of the ts453 virus to interferon treatment and this could have important consequences in the context of protein synthesis regulation during natural reovirus infection.

Detection of reovirus RNA in hepatobiliary tissues from patients with extrahepatic biliary atresia and choledochal cysts

Extrahepatic biliary atresia (EHBA) and choledochal cysts (CDC) are important causes of obstructive jaundice in pediatric patients. Viruses in general, and reoviruses in particular, have long been considered as possible etiologic agents responsible for inciting the inflammatory process that leads to these infantile obstructive cholangiopathies. In an effort to determine whether reovirus infection is associated with these disorders, we used a sensitive and specific reverse-transcriptase polymerase chain reaction (RT-PCR) technique designed to amplify a portion of the reovirus L1 gene segment from extracts of liver and/or biliary tissues. These tissues were obtained at the time of liver biopsy or surgical procedures from 23 patients with EHBA, 9 patients with CDC, and 33 patients with other hepatobiliary diseases. Hepatic and biliary tissues obtained at autopsy from 17 patients who died without known liver or biliary disease were also analyzed. Reovirus RNA was detected in hepatic and/or biliary tissues from 55% of patients with EHBA and 78% of patients with CDC. Reovirus RNA was found also in extracts of hepatic and/or biliary tissue from 21% of patients with other hepatobiliary diseases and in 12% of autopsy cases. The prevalence of reovirus RNA in tissues from patients with EHBA and CDC was significantly greater than that in patients with other hepatobiliary diseases (chi2 P = .012 EHBA vs. OTHER, P = .001 CDC vs. OTHER), or AUTOPSY cases (chi2 P = .006 EHBA vs. AUTOPSY, P < .001 CDC vs. AUTOPSY).

Reoviruses and the interferon system

Reovirus induces IFN, and reovirus is sensitive to the antiviral actions of IFN. The characteristics of the IFN-inducing capacity of reovirus, and the antiviral actions of IFN exerted against reovirus, are dependent upon the specific combination of reovirus strain, host cell line, and IFN type. Responses, both IFN induction and IFN action, differ quantitatively if not qualitatively and are dependent upon the virus, cell, and IFN combination. Stable natural dsRNA, identified as the form of nucleic acid that constitutes the reovirus genome, is centrally involved in the function of at least three IFN-induced enzymes. Protein phosphorylation by PKR, RNA editing by the ADAR adenosine deaminase, and RNA degradation by the 2',5'-oligoA pathway all involve dsRNA either as an effector or as a substrate. Considerable evidence implicates PKR as a particularly important contributor to the IFN-induced antiviral state displayed at the level of the single virus-infected cell, where the translation of viral mRNA is often observed to be inhibited following treatment with IFN-alpha/beta. In the whole animal infected with reovirus, elevated cellular immune responses mediated by enhanced expression of MHC class I and class II antigens induced by IFN-alpha/beta or IFN-gamma may contribute significantly to the overall antiviral response.

Mechanisms of viral inhibition by interferons

Interferons (IFNs) are a family of related proteins grouped in four species (alpha, beta, gamma and omega) according to their cellular origin, inducing agents and antigenic and functional properties. Their binding to specific receptors leads to the activation of signal transduction pathways that stimulate a defined set of genes, whose products are eventually responsible for the IFN antiviral effects. Their action against viruses is a complex phenomenon. It has been reported that IFNs restrict virus growth at the levels of penetration, uncoating, synthesis of mRNA, protein synthesis and assembly. This review will attempt to evaluate evidence of the involvement of the IFN-inducible proteins in the expression of the antiviral state against RNA or DNA viruses.

The Lang strain of reovirus serotype 1 and the Dearing strain of reovirus serotype 3 differ in their sensitivities to beta interferon

Replication of the Dearing strain of reovirus serotype 3 in mouse L cells was decreased 17- to 100-fold when a saturating dose of beta interferon (1,000 IU/ml) was used. Replication of the Lang strain of reovirus serotype 1 was inhibited only two- to threefold under similar conditions. It therefore appears that closely related strains of reovirus differ in their sensitivities to beta interferon treatment of mouse L cells.

Inhibitory activity for the interferon-induced protein kinase is associated with the reovirus serotype 1 sigma 3 protein

In this report we demonstrate that reovirus serotype 1-infected cells contain an inhibitor of the interferon-induced, double-stranded RNA (dsRNA)-dependent protein kinase. We provide evidence that suggests that the virus-encoded sigma 3 protein is likely responsible for this kinase inhibitory activity. We could not detect activation of the dsRNA-dependent protein kinase in extracts prepared from either interferon-treated or untreated reovirus serotype 1-infected mouse L cells under conditions that led to activation of the kinase in extracts prepared from either interferon-treated or untreated, uninfected cells. Extracts from reovirus-infected cells blocked activation of kinase in extracts from interferon-treated cells when the two were mixed prior to assay. The kinase inhibitory activity in extracts of reovirus-infected cells could be overcome by adding approximately 100-fold excess of dsRNA over the amount required to activate kinase in extracts of uninfected cells. Kinase inhibitory activity in extracts of interferon-treated, virus-infected cells could be overcome with somewhat less dsRNA (approximately 10-fold excess). Most of the inhibitory activity in the extracts could be removed by adsorption with immobilized anti-reovirus sigma 3 serum or immobilized dsRNA, suggesting that the dsRNA-binding sigma 3 protein is necessary for kinase inhibitory activity. Purified sigma 3 protein, when added to reaction mixtures containing partially purified kinase, inhibited enzyme activation. Control of activation of this kinase, which can modify eukaryotic protein synthesis initiation factor 2, may be relevant to the sensitivity of reovirus replication to treatment of cells with interferon and to the shutoff of host protein synthesis in reovirus-infected cells.

Mechanism of interferon action. Expression of reovirus S3 gene in transfected COS cells and subsequent inhibition at the level of protein synthesis by type I but not by type II interferon

The effect of interferon on the expression of the reovirus serotype 1 Lang strain S3 gene was examined in simian COS cells transfected with the expression vector pSVS3 containing the S3 gene under the control of the SV40 late promoter. When COS cells were treated with type I interferon-alpha 24 hr after transfection, the synthesis of the reovirus S3-encoded sigma NS polypeptide was inhibited about 10-fold as compared to that in untreated control cells. By contrast, under the same conditions, neither the plasmid DNA copy number nor the S3 gene mRNA levels were significantly affected by interferon treatment. Type II interferon-gamma, unlike the type I interferons-alpha, did not affect the rate of synthesis of polypeptide sigma NS in pSVS3-transfected cells.

Mechanism of interferon action: studies on the activation of protein phosphorylation and the inhibition of translation in cell-free systems

We describe the ability of reovirus messenger RNA (mRNA) to serve as a template for translation and as an activator of protein phosphorylation in cell-free extracts prepared from untreated and from interferon (IFN)-treated mouse fibroblast L cells. In vitro transcribed reovirus mRNA was purified by column chromatography on CF-11 cellulose. This procedure removed trace amounts of double-stranded RNA (dsRNA) [0.01%-0.1%] present in mRNA preparations purified solely by extensive LiCl precipitation. In the absence of added dsRNA, CF-11 cellulose-purified reovirus mRNA did not detectably activate phosphorylation of either ribosome-associated protein P1 or the alpha subunit of protein synthesis initiation factor eIF-2 in S-10 extracts prepared from L cells; the CF-11 cellulose-purified reovirus mRNA was translated more efficiently than was LiCl-purified reovirus mRNA in these extracts. Highly purified CF-11 reovirus mRNA was, however, translated less efficiently by S-10 extracts prepared from IFN-treated L cells than by extracts prepared from untreated L cells, suggesting that the inefficient translation by IFN-treated extracts was an integral property of reovirus mRNA. Increasing the secondary structure of reovirus mRNA by substituting bromouridine (Br-uridine) for uridine in the mRNA caused an increased inhibition of mRNA binding to ribosomes in extracts prepared from IFN-treated as compared to untreated cells. The mechanism of inhibition of translation of CF-11 cellulose-purified reovirus mRNA in IFN-treated systems remains to be established.

Avian reovirus mRNAs are nonfunctional in infected mouse cells: translational basis for virus host-range restriction

Avian reovirus S1133 penetrates and uncoats in suspension cultures of mouse L cells. The multiple species of viral transcripts are produced in the cytoplasm of the infected cell, but they fail to associate with polysomes, consistent with the absence of viral protein synthesis. The selective block in avian virus mRNA translation is not overcome by coinfection with mammalian reovirus type 3, which replicates in mouse L cells, or by hypertonic shock or exposure to a low concentration of cycloheximide. Although the avian viral transcripts are inactive in vivo, RNA extracted from infected, nonpermissive L cells directs the synthesis of a normal spectrum of viral proteins in rabbit reticulocyte lysates. These results indicate that avian viral transcription is not restricted in mouse cells and that viral replication is prevented at the level of initiation of protein synthesis.

Mechanism of interferon action. Production and characterization of monoclonal and polyclonal antibodies to the interferon-induced phosphoprotein P1

Monoclonal and polyclonal antibodies to the interferon-induced phosphoprotein P1 were prepared using protein P1 purified from human amnion U cells as the immunogen. Rabbit antiserum to protein P1 recognized with comparable efficiency P1 both from human U cells and from mouse L929 cells. Immunoprecipitates that contained protein P1 also possessed a protein kinase activity that catalyzed the phosphorylation of protein P1 and the alpha subunit of initiation factor eIF-2. Three BALB/C mouse monoclonal antibodies efficiently recognized human protein P1, but either did not recognize or recognized very poorly P1 from mouse cells. A fourth monoclonal antibody against human P1 recognized mouse P1 with nearly equal efficiency. Immunoprecipitation of human P1 with different sequential combinations of the monoclonal antibodies suggest that two antigenic classes of protein P1 may exist.

Inhibition of viral mRNA translation in interferon-treated L cells infected with reovirus

Murine L cells were treated with interferon (IFN) concentrations which reduced by 75 to 80% the synthesis of viral mRNA after infection with reovirus. Protein synthesis was not inhibited in these cells up to 6 h after infection, but a large fraction of the viral mRNA was not associated with polyribosomes and sedimented at about 50S. In contrast, most of the reovirus mRNA was associated with polyribosomes in control infected cells. This mRNA was of similar size to non-polyribosomal mRNA from IFN-treated cells when analyzed by Northern blot hybridization with a cloned cDNA for the s2 reovirus mRNA, indicating that the non-polyribosomal mRNA was not appreciably degraded. Viral mRNA was labeled with [3H]uridine and the non-polyribosomal mRNA was isolated from IFN-treated cells. This mRNA could quantitatively bind to 80S initiation complexes when incubated in a rabbit reticulocyte cell-free system. These findings indicated that the non-polyribosomal RNA was translatable, but that its binding to functional initiation complexes was inhibited in IFN-treated cells by a discriminatory mechanism, which did not affect translation of cellular mRNA. Previous experiments showed that mRNA is blocked in 48S complexes when the alpha subunit of initiation factor eIF-2 is phosphorylated by the double-stranded RNA-dependent protein kinase induced by IFN. A localized activation of this kinase could explain the block of viral mRNA in 48S complexes. By labeling the phosphoproteins of IFN-treated cells with 32P, eIF-2 (alpha P) was shown to cosediment with non-polyribosomal mRNA, presumably in 48S complexes.

Interferon--present and future prospects

The interferons are a group of proteins that have inspired a new era of investigation into biological modification. The interferons are now divided into subgroups characterized by chemical means and correspond to different biological responses which can be observed in terms of the inducer used, and the timing of the response. Identified originally as antiviral agents when homologous cell systems were treated prior to infection, new studies have extended these observations to place the interferons in a central role as a strong force in the regulation of immunologic responses. A marriage of interferonology and cell immunology is enlarging both our understanding of the action of these proteins and our ability to follow the course of an illness and eventually to control its outcome . Genetic engineering has provided a way to process quantities of interferon and provided the molecular sequence of all three classes of IFN including a model of the active site for IFN-alpha. The offshot of the technology developed to study the intracellular processes after interferon treatment have already led to increased sensitivity to detect virally treated diseases. Both the variety of the interferon inducers and the scope of parasites in which it can exert its influence provide a frontier of biological investigation which has at the root of its nature the very secret of life. In addition to cellular phenomena, the positive effects on tumor-bearing organisms and the ill effects on infant animals highlight the potential power of the interferons.

Mechanism of interferon action: simian virus 40-specific early polypeptides synthesized in untreated and interferon-treated monkey kidney cells

The effect of interferon treatment on proteins synthesized in simian virus 40 (SV40)-infected cells in the presence of cytosine arabinoside was investigated. The following results were obtained: (i) In addition to previously described large tumor (T) antigen (94 kilodaltons) and small tumor (t) antigen (19 kilodaltons), a 62-kilodalton polypeptide was immunoprecipitated by SV40 anti-T antiserum from extracts of infected CV-1 and BSC-1 monkey kidney cells and transformed SV3T3 mouse cells. The 94-, 62-, and 19-kilodalton polypeptides were not precipitated with normal serum from extracts of infected cells, and they were not present in extracts of uninfected cells. (ii) The de novo synthesis of the 94-, 62-, and 19-kilodalton tumor antigens was inhibited in CV-1 and BSC-1 cells treated with interferon before infection; total cellular protein synthesis was not significantly affected by interferon treatment. The relative interferon sensitivity of the three polypeptides in lytically infected monkey cells was comparable; by contrast, interferon did not affect their synthesis in transformed mouse cells. (iii) The 62-kilodalton polypeptide was detected in monkey cells infected with the following strains of SV40: tsA30 at both 33 degrees C and 41 degrees C; wt 708, the parent of tsA30; dI 884; and wt 830, the parent of dI 884. The amount of the 62-kilodalton species relative to T antigen was significantly greater in tsA30-infected cells as compared to cells infected with other SV40 strains. (iv) T, t, and 62-kilodalton polypeptides were readily labeled with [(35)S]methionine during a 10-min pulse; in a subsequent chase, the (35)S-labeled 94-kilodalton T antigen was apparently converted to 89- and 84-kilodalton polypeptides but not to either the 62-kilodalton polypeptide species or t antigen. (v) Partial peptide maps suggest that the 62-kilodalton polypeptide and T antigen are closely related. (vi) In addition to the above described 62-kilodalton polypeptide, a 54-kilodalton polypeptide was also detected. However, the 54-kilodalton species appears to be of cellular origin because it was immunoprecipitated with both normal and anti-T antiserum from uninfected and lytically infected cells and from virally transformed cells.

Differential effects of fibroblast and leucocyte interferon in HBsAg positive chronic active hepatitis

Six patients with hepatitis B surface antigen, hepatitis B 'e' antigen positive chronic active hepatitis, and elevated hepatitis B specific DNA polymerase activity were treated sequentially with fibroblast and leucocyte interferon. Fibroblast interferon induced a fall in serum transaminase activities in all patients, whereas a consistent decline in DNA polymerase activity was observed during leucocyte interferon administration only. After treatment one patient remained persistently DNA polymerase and hepatitis B 'e' antigen negative, whereas relapse to initial values occurred in others. Side effects included severe but reversible granulocytopenia, and chills responding to promethazine treatment. The differential biologies with their non-identity in in vitro studies.

Inhibition of viral protein synthesis in monkey cells treated with interferon late in simian virus 40 lytic cycle

We have investigated the effect of interferon on SV40 gene expression late in the lytic cycle, after early functions have been expressed and viral DNA replication has been initiated. Whereas pretreatment with interferon prior to infection reduces the amount of early SV40 RNA, post-infection treatment does not inhibit viral RNA synthesis. Viral 19S and 16S RNA species are found undiminished in quantity and poly(A) content. Despite the apparent normalcy of viral RNA classes, however, there is a marked reduction in the synthesis of their protein products, both T antigen and capsid polypeptides. The association of viral RNA with heavy polyribosomes is strongly reduced. On the other hand, there is no degradation of nonviral polyribosomes and the synthesis of most cellular proteins continues. These experiments demonstrate that late in infection, interferon treatment results in an inhibition of viral mRNA translation.

Effect of interferon on dimethyl sulfoxide-stimulated Friend erythroleukemic cells: ultrastructural and biochemical study

Treatment of dimethyl sulfoxide-stimulated Friend erythroleukemic cells (clone 745) with mouse interferon (50 U/ml) led to the following changes: (i) a net decrease (40 to 60%) in both the total number of apparently newly synthesized virion particles per cell section and in the average number of cell sections containing one or more virion particles; (ii) a large decrease (80 to 90%) in the number of particles released into the supernatant fluid, as assayed by reverse transcriptase activity; (iii) an initial increase in the number of "immature" or "enveloped A-type" virions followed by an increase in the accumulation of empty, core shell-like particles; and (iv) a decrease in the number of cytoplasmic vacuolar structures, which have been implicated as a major site of virus production and which we show here by serial sectioning to be, in several instances, invaginations of the plasma membrane. The effects on virus production were noticeable 2 h after interferon addition and reached their full extent by 13 h. We conclude from these observations that interferon acts upon the late stage(s) of virion maturation, leading both to a decrease in virion production as well as to the formation of defective particles. In contrast, a small but significant increase in the rate at which globin mRNA and hemoglobin accumulate is observed after interferon treatment.

The effect of interferon on de novo infection of Moloney murine leukemia virus

The mode of action of interferon in de novo Moloney murine leukemia virus (Mo-MuLV) infection of mouse bone marrow/thymus (TB) cells was studied. Our results indicate that in interferon-treated cells, there is approximately a 2000 fold decrease in the production of infectious MuLV, but only a 10-20 fold decrease in the level of viral specific extracellular reverse transcriptase activity, and only about a 2 fold difference in the number of virus particles observed on the cell membrane as determined by scanning electron microscopic (SEM) studies. Transmission electron microscopic (TEM) studies showed that the proportion of early budding virions, which have shallow crescent-shaped ribonucleoprotein cores (Figure 3A), to virions in later stages of assembly (Figures 3B-3D) is relatively higher in interferon-treated cells than in the untreated controls. From a temperature shift-down experiment on a temperature-sensitive mutant of MuLV, ts 3, which produces viral particles that fail to dissociate from the cell surface at the nonpermissive temperature, we demonstrated that ts 3 virions partially assembled on the cell membrane prior to the addition of interferon are able to complete assembly and to dissociate from the cell membrane on temperature shift-down in the presence of interferon action. Our data suggest that interferon neither inhibits the late stages of virion assembly at which ts 3 virions are arrested at the nonpermissive temperature nor prevents release of the virions. Our findings also indicate that in interferon-treated cells, most of the extracellular virions are noninfectious.

Impairment of reovirus mRNA methylation in extracts of interferon-treated Ehrilich ascites tumor cells: further characteristics of the phenomenon

We reported earlier that the methylation of unmethylated reovirus mRNA (reo mRNAU) by the cellular methylating enzymes is impaired in extracts of uninfected, interferon-treated Ehrilich ascites tumor cells (S30INT). We find now that after the methylation of reo mRNAU has stopped in S30INT, the RNA can be reisolated and further methylated in an extract of control cells (S30C). Thus the impairment of methylation in S30INT cannot be due to cleavage or irreversible inactivation of reo mRNAU. Freshly added reo mRNAU can be methylated in S30INT in which the methylation of previously added reo mRNAU has stopped. This indicates that the impairment is due to the depletion of S-adenosylme thionine (the methyl donor), the accumulation of S-adenosylhomocysteine (an inhibitor of methylation), or the irreversible inactivation of reo mRNAU. Freshly added reo mRNAU can be methylated in S30INT in which the methylation of previously added reo mRNAU has stopped. This indicates that the impairment is not due to the depletion of S-adenosylmethionine (the methyl donor), the accumulation of S-adenoxylhomocysteine (an inhibitor of methylation), or the irreversible inactivation of the methylating enzymes. It may be due, however, to the unavailability of reo mRNAU for methylation. The extent of the impairment of reo mRNAU methylation in S30INT decreases with an increasing concentration of reo mRNAU but is not affected by added poly (U), ribosomal RNA, or encephalomyocarditis virus RNA (an mRNA that is probably not capped or methylated at its 5' end). The methylation of reo mRNAU is also impaired in an extract from cells that have not been treated with interferon but with the interferon inducer poly(I) - poly(C). The inhibitor is apparently a macromolecule that is inactivated during incubation. It decreases the methylation at the 7 position of the 5' terminal guanylate residue. In vitro, the rate of reo mRNA synthesis by reovirus cores in the presence of S30INT is the same as in the presence of S30C. However, the methylation of the de novo synthesized reo mRNA by the core-associated methylating enzyme(s) in vitro is inhibited by S30INT but not by S30C. The relevance of these phenomena to the inhibition of reovirus replication in interferon-treated cells remains to be established.