Nuclease activation by double-stranded RNA and by 2',5'-oligoadenylate in extracts of interferon-treated chick cells

Response of Three Different Viruses to Interferon Priming and Dithiothreitol Treatment of Avian Cells

We have previously shown that the replication of avian reovirus (ARV) in chicken cells is much more resistant to interferon (IFN) than the replication of vesicular stomatitis virus (VSV) or vaccinia virus (VV). In this study, we have investigated the role that the double-stranded RNA (dsRNA)-activated protein kinase (PKR) plays in the sensitivity of these three viruses toward the antiviral action of chicken interferon. Our data suggest that while interferon priming of avian cells blocks vaccinia virus replication by promoting PKR activation, the replication of vesicular stomatitis virus appears to be blocked at a pretranslational step. Our data further suggest that the replication of avian reovirus in chicken cells is quite resistant to interferon priming because this virus uses strategies to downregulate PKR activation and also because translation of avian reovirus mRNAs is more resistant to phosphorylation of the alpha subunit of initiation factor eIF2 than translation of their cellular counterparts. Our results further reveal that the avian reovirus protein sigmaA is able to prevent PKR activation and that this function is dependent on its double-stranded RNA-binding activity. Finally, this study demonstrates that vaccinia virus and avian reovirus, but not vesicular stomatitis virus, express/induce factors that counteract the ability of dithiothreitol to promote eIF2 phosphorylation. Our data demonstrate that each of the three different viruses used in this study elicits distinct responses to interferon and to dithiothreitol-induced eIF2 phosphorylation when infecting avian cells.

IMPORTANCE

Type I interferons constitute the first barrier of defense against viral infections, and one of the best characterized antiviral strategies is mediated by the double-stranded RNA-activated protein kinase R (PKR). The results of this study revealed that IFN priming of avian cells has little effect on avian reovirus (ARV) replication but drastically diminishes the replication of vaccinia virus (VV) and vesicular stomatitis virus (VSV) by PKR-dependent and -independent mechanisms, respectively. Our data also demonstrate that the dsRNA-binding ability of ARV protein sigmaA plays a key role in the resistance of ARV toward IFN by preventing PKR activation. Our findings will contribute to improve the current understanding of the interaction of viruses with the host's innate immune system. Finally, it would be of interest to uncover the mechanisms that allow avian reovirus transcripts to be efficiently translated under conditions (moderate eIF2 phosphorylation) that block the synthesis of cellular proteins.

The human 2'-5'oligoadenylate synthetase family: unique interferon-inducible enzymes catalyzing 2'-5' instead of 3'-5' phosphodiester bond formation

The demonstration by Kerr and colleagues that double-stranded (ds) RNA inhibits drastically protein synthesis in cell-free systems prepared from interferon-treated cells, suggested the existence of an interferon-induced enzyme, which is dependent on dsRNA. Consequently, two distinct dsRNA-dependent enzymes were discovered: a serine/threonine protein kinase that nowadays is referred to as PKR and a 2'-5'oligoadenylate synthetase (2'-5'OAS) that polymerizes ATP to 2'-5'-linked oligomers of adenosine with the general formula pppA(2'p5'A)(n), n>or=1. The product is pppG2'p5'G when GTP is used as a substrate. Three distinct forms of 2'-5'OAS exist in human cells, small, medium, and large, which contain one, two, and three OAS units, respectively, and are encoded by distinct genes clustered on the 2'-5'OAS locus on human chromosome 12. OASL is an OAS like IFN-induced protein encoded by a gene located about 8 Mb telomeric from the 2'-5'OAS locus. OASL is composed of one OAS unit fused at its C-terminus with two ubiquitin-like repeats. The human OASL is devoid of the typical 2'-5'OAS catalytic activity. In addition to these structural differences between the various OAS proteins, the three forms of 2'-5'OAS are characterized by different subcellular locations and enzymatic parameters. These findings illustrate the apparent structural and functional complexity of the human 2'-5'OAS family, and suggest that these proteins may have distinct roles in the cell.

Evidence that avian reovirus sigmaA protein is an inhibitor of the double-stranded RNA-dependent protein kinase

The results of a previous study demonstrated that avian reovirus is highly resistant to the antiviral effects of interferon and suggested that the double-stranded RNA (dsRNA)-binding sigmaA protein might play an important role in that resistance. To gather more evidence on the interferon-inhibitory activity of sigmaA protein, its gene was cloned into the prokaryotic maltose-binding protein (MBP) gene fusion vector pMalC and into the recombinant vaccinia virus WRS2. The two recombinant sigmaA proteins displayed a dsRNA-binding affinity similar to that of sigmaA protein synthesized in avian reovirus-infected cells. Interestingly, MBP-sigmaA, but not MBP, was able to relieve the translation-inhibitory activity of dsRNA in reticulocyte lysates by blocking the activation of endogenous dsRNA-dependent enzymes. In addition, transient expression of sigmaA protein in HeLa cells rescued gene expression of a vaccinia virus mutant lacking the E3L gene, and insertion of the sigmaA-encoding gene into vaccinia virus conferred protection for the virus against interferon in chicken cells. Further studies demonstrated that expression of recombinant sigmaA in mammalian cells interfered with dsRNA-dependent protein kinase (PKR) function. From these results we conclude that sigmaA is capable of reversing the interferon-induced antiviral state by down-regulating PKR activity in a manner similar to other virus-encoded dsRNA-binding proteins.

The human 2',5'-oligoadenylate synthetase family: interferon-induced proteins with unique enzymatic properties

2',5'-Oligoadenylate synthetase (2',5'-OAS) was discovered and characterized as an interferon (IFN)-induced enzyme that in the presence of double-stranded (ds) RNA converts ATP into 2',5'-linked oligomers of adenosine with the general formula pppA(2'p'A)n, n > or = 1. The product is pppG2'p5'G when GTP is used as a substrate. Now, 20 years later, this activity is attributed to several well-characterized, homologous, and IFN-induced proteins in human cells. Three distinct forms of 2',5'-OAS exist, small, medium, and large, which contain 1, 2, and 3 OAS units, respectively, and are encoded by distinct genes clustered on the 2',5'-OAS locus on human chromosome 12. Recently, other IFN-induced proteins homologous to the OAS unit but devoid of the typical 2',5'-OAS catalytic activity have been described. These OAS-related proteins are encoded by a gene located at the proximity of the 2',5'-OAS locus. These findings illustrate the apparent structural and functional complexity of the human 2',5'-OAS family.

The 2-5A system: modulation of viral and cellular processes through acceleration of RNA degradation

The 2-5A system is an RNA degradation pathway that can be induced by the interferons (IFNs). Treatment of cells with IFN activates genes encoding several double-stranded RNA (dsRNA)-dependent synthetases. These enzymes generate 5'-triphosphorylated, 2',5'-phosphodiester-linked oligoadenylates (2-5A) from ATP. The effects of 2-5A in cells are transient since 2-5A is unstable in cells due to the activities of phosphodiesterase and phosphatase. 2-5A activates the endoribonuclease 2-5A-dependent RNase L, causing degradation of single-stranded RNA with moderate specificity. The human 2-5A-dependent RNase is an 83.5 kDa polypeptide that has little, if any, RNase activity, unless 2-5A is present. 2-5A binding to RNase L switches the enzyme from its off-state to its on-state. At least three 2',5'-linked oligoadenylates and a single 5'-phosphoryl group are required for maximal activation of the RNase. Even though the constitutive presence of 2-5A-dependent RNase is observed in nearly all mammalian cell types, cellular amounts of 2-5A-dependent mRNA and activity can increase after IFN treatment. One well-established role of the 2-5A system is as a host defense against some types of viruses. Since virus infection of cells results in the production and secretion of IFNs, and since dsRNA is both a frequent product of virus infection and an activator of 2-5A synthesis, the replication of encephalomyocarditis virus, which produces dsRNA during its life cycle, is greatly suppressed in IFN-treated cells as a direct result of RNA decay by the activated 2-5A-dependent RNase. This review covers the organic chemistry, enzymology, and molecular biology of 2-5A and its associated enzymes. Additional possible biological roles of the 2-5A system, such as in cell growth and differentiation, human immunodeficiency virus replication, heat shock, atherosclerotic plaque, pathogenesis of Type I diabetes, and apoptosis, are presented.

Differential activity of the 30-kD and the 100-kD forms of 2'-5'An synthetase induced by recombinant human interferon-alpha and interferon-gamma

Two molecular weight variants of the interferon (IFN)-induced intracellular enzyme 2',5'-oligoadenylate (2-5A) synthetase have been described recently; a 100-kD (cytoplasmic) and a 30-kD (intranuclear) form of the enzyme. The 30-kD form has been located primarily in the nucleus, while the 100-kD enzyme was found mainly in the cytoplasm. We examined 2-5A synthetase activity in extracts of human melanoma (Hs294t) cells treated with either recombinant (r) IFN-alpha A or rIFN-gamma to determine the differential regulation of these enzyme subtypes by treatment with the two types of IFN. Cells were treated (continuous exposure) with doses of rIFN-alpha A (1,000 U/ml) or rIFN-gamma (5,000 U/ml), each of which reduced the number of viable cells to 50% of control values (ED50) by day 3 of treatment. At equieffective doses, the maximal increase in 2-5A synthetase occurred at 48 h for both rIFN-alpha A and rIFN-gamma continuous exposure. The maximal 2-5A intracellular activities at 48 h were 800 +/- 40 and 160 +/- 15 nmoles/mg protein for rIFN-alpha A and rIFN-gamma treatment, respectively. High-performance gel permeation chromatography of cell lysates resolved the 2-5A activity into both 100-kD and 30-kD fractions. At 48 h after treatment with rIFN-alpha A, the activity of the 30-kD synthetase was approximately twofold greater than that of the 100-kD enzyme. In contrast, the activity of both 30- and 100-kD enzymes were equivalent 48 h after treatment with rIFN-gamma.(ABSTRACT TRUNCATED AT 250 WORDS)

(2'-5') Oligoadenylate synthetase in the maturation of rabbit reticulocytes

The (2'-5') oligoadenylate synthetase normally found in interferon-treated cells has also been detected in considerable amounts in normal rabbit reticulocytes not exposed to interferon. The activity of this enzyme has been followed during the development of the reticulocytes to erythrocytes. A high level was found just after the formation of reticulocytes and this activity decayed with a half-life of about 3 days. In lymphocytes the (2'-5') oligoadenylate synthetase was found to stay at a constant level, which indicates the absence of interferon in the plasma.

Increased 2',5'-oligoadenylate synthetase activity in blood mononuclear leukocytes from patients with advanced cutaneous T-cell lymphoma

The activity of the interferon-induced enzyme 2',5'-oligoadenylate synthetase (2',5' An synthetase) was found to be increased in the lysates of peripheral blood mononuclear leukocytes obtained from 10 of 25 (40%) patients with cutaneous T-cell lymphoma (mycosis fungoides and Sézary syndrome). A positive association was found between the level of mean total synthetase activity and extent of involvement (stage) of disease. However, the leukocytes from two patients with relatively high proportions of neoplastic T-cells in the blood (Sézary syndrome) had negligible enzyme activity. It is speculated that increased interferon production in vivo may account for the observed enzyme changes in normal blood leukocytes from these patients, and that the neoplastic T-cell population is the most likely source of the presumed interferon production. Possible mechanisms and biologic consequences of high levels of endogenous interferon in patients with cutaneous T-cell lymphoma are discussed.

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.

Interferon action: two (2'-5')(A)n synthetases specified by distinct mRNAs in Ehrlich ascites tumor cells treated with interferon

(2'-5')(A)n synthetase and RNAase L (a latent endoribonuclease) are among the mediators of interferon action. The product of (2'-5')(A)n synthetase (i.e., (2'-5')(A)n) binds, and thereby activates RNAase L. Interferons induce in Ehrlich ascites tumor (EAT) cells two mRNAs (sizes 1.5 kb and 3.8 kb), which can be translated in Xenopus oocytes into (2'-5')(A)n synthetases of 20,000 to 30,000 daltons and 85,000 to 100,000 daltons, respectively. (2'-5')(A)n synthetases of corresponding sizes are induced by interferons in EAT cells. In the cell extract the bulk of the larger enzyme is in the cytoplasmic fraction, and the bulk of the smaller one in the nuclear fraction. The only known function of (2'-5')(A)n is the activation of RNAase L, and RNAase L can be selectively crosslinked to a (2'-5')(A)n derivative in a cytoplasmic extract from EAT cells. The same (2'-5')(A)n derivative can be crosslinked to several proteins in the nuclear extract of EAT cells, and some of these proteins are induced by interferon.

Xyloadenosine analogue of (A2'p)2A inhibits replication of herpes simplex viruses 1 and 2

Molecules of the structure ppp(A2'p)2A containing a 2' leads to 5' phosphodiester bond, commonly abbreviated as 2-5A, are synthesized in interferon-treated virally-infected cells and have been implicated in several systems as contributing to interferon's antiviral activity. The 2-5A binds to and subsequently activates an endogenous endonuclease, ultimately resulting in degradation of RNA. We have been interested in the use of 2-5A analogues to achieve antiviral activity without the use of interferon. For this approach to be successful, analogues must be synthesized with an increased stability (native 2-5A is rapidly degraded by cellular phosphodiesterases) and with increased ability to enter intact cells. Removal of the highly-negative charged 5' terminal phosphates from ppp(A2'p)2A results in formation of the 'core' species, (A2'p)2A, which should be able to penetrate intact cells more readily. While Kimchi et al. have shown that 2-5A core has an antimitogenic effect in mouse spleen lymphocytes and 3T3 fibroblasts, Williams and Kerr have reported lack of antiviral activity against Semliki Forest virus or encephalomyocarditis virus by exogenously-administered 2-5A core. We have previously determined that (xyloA2'p)2xyloA (abbreviated as xylo 2-5A core), the xyloadenosine analogue of the 5'-terminally dephosphorylated 2-5A core, is over 100 times more stable than the parent 2-5A core species. We now report that this xylo 2-5A core inhibits replication of herpes simplex viruses 1 and 2 in vitro, with greater than 100 times the activity of the parent 2-5A core. The mechanism of antiviral action of the 2-5A core analogue appears to involve a pathway different from that activated by the parent 5' triphosphorylated 2-5A species.

5'-O-Monophosphoryladenylyl(2' goes to 5')adenylyl(2' goes to 5')adenosine is an antagonist of the action of 5'-O-triphosphoryladenylyl-(2' goes to 5')adenylyl(2' goes to 5')adenosine and double-stranded RNA

5'-O-Monophosphoryladenylyl(2' goes to 5')adenylyl-(2' goes to 5')adenosine [(2' goes to 5')(pA)3] antagonizes the protein synthesis inhibitory effects of 5'-O-triphosphoryladenylyl-(2' goes to 5')adenylyl(2' goes to 5')adenosine by preventing activation of the (2' goes to 5')oligo(a)-activated ribonuclease which degrades mRNA. The oligoribonucleotide (2' goes to 5')(pA)3 also antagonizes the translational inhibitory capacity of poly(I).poly(C) in extracts of interferon-treated L cells, suggesting that (2' goes to 5')oligo(A) is the primary mediator of the protein synthesis inhibitory effects of poly(I).poly(C) in this cell-free system.

Accumulation of newly synthesized mRNAs in response to human fibroblast (beta) interferon

Treatment of human fibroblast cells with human fibroblast (beta)interferon for up to 8 hr resulted in the accumulation of at least four mRNAs. The mRNAs were isolated from cellular polysomes and characterized by stimulation of translation in a wheat germ cell-free protein synthesis system. The mRNAs appear as early as 2 hr after exposure to interferon and can be translated in vitro into proteins having molecular weights of 61,000, 62,000, 64,000, and 68,000. The response is not elicited by mouse interferon or insulin and does not occur in the presence of actinomycin D. Chase experiments indicated that the induced mRNAs remain ribosome-associated for at least 3 hr after their synthesis. The appearance of the induced mRNAs correlated directly with the onset of an antiviral state. Velocity sedimentation of the induced mRNAs on sucrose gradients demonstrated that each of the four induced proteins are encoded by different-sized mRNAs.

A mouse cell line, which is unprotected by interferon against lytic virus infection, lacks ribonuclease F activity

A mouse cell line, NIH 3T3, does not respond to some of the activities of interferon. Even after treatment with high concentrations of interferon the replication of lytic viruses, such as encephalomyocarditis virus (EMCV) and vesicular stomatitis virus (VSV) is not inhibited in these cells. In contrast, interferon treatment of these same cells results in the inhibition of Moloney murine leukemia virus (MMuLV) production. We have analyzed enzymatic pathways which are induced by interferon in these cells. After interferon treatment, the level of the (2'-5')oligoadenylate [(2'-5)An] synthetase activity and the phosphorylation of the 67000-dalton protein (P1) are enhanced in NIH 3T3 cells to approximately the same level as interferon-sensitive mouse L-cells. Moreover, NIH 3T3 and L-cells, contain approximately the same levels of enzymes which inactivate (2'-5')An. Both exogenously added (2'-5')A3 or double-stranded RNA (dsRNA) failed to inhibit protein synthesis in NIH 3T3 extracts even though they were potent inhibitors of L-cell extract-directed protein synthesis. Direct measurements of the (2'-5')An-dependent ribonuclease F (RNase F) failed to detect such activity in NIH 3T3 cells. Our results, therefore, suggest that the presence of RNase F activity is necessary for the interferon-induced antiviral activity against EMCV and against VSV. The induction of protein kinase activity by interferon treatment of NIH 3T3 cells appears to have no direct effect on EMCV and VSV replication.

Interferon action--sequence specificity of the ppp(A2'p)nA-dependent ribonuclease

The oligonucleotides pppA2'p5'A2'p5'A and related oligomers (2-5A) are synthesized by an enzyme that is widely distributed in a variety of cells, the activity of which varies with interferon treatment, growth and hormone status. Because significant amounts of 2-5A have recently been detected in interferon-treated cells, it has been suggested that the oligonucleotides may be involved in interferon action and in the control of cell metabolism. In both intact cells and cell-free systems 2-5A has been shown to activate a ribonuclease. We report here investigations of the sequence specificities of the 2-5A-dependent ribonucleases in extracts of rabbit reticulocytes, mouse ascites tumour cells and human lymphoblastoid cells in conditions of partial digestion using terminally labelled RNA substrates. The enzymes cleaved on the 3'-side of UN sequences to yield UpNp terminated products. Cleavage was observed predominantly at UA and UU sequences.

Induction, purification, and properties of 2'5' oligoadenylate synthetase

The results presented above relate to several aspects of the 2-5A system. A simple but insensitive radiochemical assay fro 2-5A and its synthetase is described. Progress towards the molecular characterization of the synthetase suggested that it is composed of a single 56,000 dalton polypeptide chain that is synthesized in response to IF treatment. Degradation of 2-5A occurs at the same rapid rate in extracts of IF-treated and untreated chick cells. However, this breakdown can be inhibited by its end-product, 5'AMP, or by the activated synthetase which can further elongate 2-5A and thereby protect it from degradation. The direction of elongation is from the 5' to the 2' terminus. Molecules other than 2-5A can act as substrates fro 2'-adenylation by the activated synthetase. These include some dinucleoside monophosphates, ADP-ribose and NAD+, and methylene-bridged analogues of ATP. The methylene-bridged analogues of 2-5A that are synthesized in the latter case retain some of the biological activity of authentic 2-5A, indicating that cleavage of the 5'-terminal phosphate group(s) is not involved in the mechanism of nuclease activation by 2-5A.

Elongation mechanism and substrate specificity of 2',5'-oligoadenylate synthetase

2',5'-Oligoadenylate synthetase has been purified from a rabbit reticulocyte lysate to a high degree of purity. The enzyme contained no detectable interfering activities that could degrade the nucleoside triphosphate substrate or the oligomeric products. Two basic properties of this enzyme have been examined: the elongation mechanism for the synthesis of oligoadenylates and the substrate specificity for nucleotides. Kinetic studies on the formation of different oligomeric intermediates show that the dimer pppA2'p5'A is the first product to accumulate in predominant proportion during the first period of reaction; the trimer and other longer oligomers appear after a lag phase. The amount of the trimer increases at the expense of the dimer. Preformed dimers and trimers added to the incubation mixture were readily incorporated into higher oligomers, suggesting the free access of these dimers and trimers to the active center after the onset of polymerization of ATP. The results indicate clearly that the enzyme catalyzes the de novo synthesis of the oligonucleotide from ATP and that the mechanism of elongation of the 2',5'-oligonucleotides catalyzed by the enzyme is not processive. Polymerization of a mixture of ATP and another nucleoside triphosphate shows that the enzyme is not only an ATP polymerase. The 2',5'-oligoadenylate synthetase is in fact a 2',5'-nucleotidyltransferase that catalyzes the formation of co-oligonucleotides. However, the purified reticulocyte enzyme catalyzed only the addition of one unit of GMP, UMP, CMP, 2'-dAMP, 3'-dAMP, dCMP, dGMP, or TMP to the 2'-OH end of a preformed oligoadenylate. A procedure for the separation of 2',5'-oligonucleotides with or without the 5'triphosphate end also is described.

Interferon-induced proteins in human fibroblasts and development of the antiviral state

Treatment of human fibroblasts with interferon induces the synthesis of several proteins, as detected by incorporation of [35S]methionine followed by analysis of cell extracts by polyacrylamide gel electrophoresis. The induction of these proteins had features in common with the development of the antiviral effect of interferon, such as (i) sensitivity to actinomycin D and cycloheximide when these compounds were added together with interferon, (ii) insensitivity to actinomycin D if the actinomycin D was added 2 h after the addition of interferon, (iii) similar dependence on interferon concentration, and (iv) species specificity for interferon. When interferon treatment was given in the presence of cycloheximide and actinomycin D was added before the removal of cycloheximide, all four proteins were induced, thus suggesting that their inductions are coordinated. Labeling for 2-h periods at varying time intervals after the addition of interferon revealed that the synthesis of these proteins was induced within a few hours, peaked at different time intervals, and was soon followed by a marked decline, suggesting that the mRNA's for these proteins have short half-lives. Moreover, this decline occurred despite the fact that the cells were continuously exposed to interferon, and there was no measurable loss of interferon activity in the medium. This suggests that the induction of these proteins is transient and is apparently subject to further control.

Double-stranded RNA inhibits a phosphoprotein phosphatase present in interferon-treated cells

In accord with previous studies, (I)n . (C)n, a potent inhibitor of the cell-free protein-synthesizing system of interferon-treated L cells, stimulates incorporation of 32P from [gamma-32P]ATP into the 67,000-dalton protein, P1. The double-stranded RNA (I)n . (br5C)n, which is inactive as an inhibitory of protein synthesis, does not stimulate phosphorylation of P1 under conditions approximating those of protein synthesis. However, we have found conditions under which (I)n . (br5C)n is approximately as effective as (I)n . (C)n in stimulating incorporation of label from [gamma-32P]ATP into 67,000-dalton protein. Upon transfer of labeled P1 from these conditions to those compatible with protein synthesis, there is a time-dependent decrease in label in the 67,000-dalton protein. This decrease is more rapid in the presence of (I)n . (br5C)n than in the presence of (I)n . (C)n. This differential decrease is also observed when 32P-labeled extracts are diluted into buffer containing 10 mM ATP, hexokinase and 1 and M glucose, or Escherichia coli alkaline phosphatase. A partial proteolytic digest of P1 labeled in the absence of double-stranded RNA or in the presence of (I)n . (C)n or (I)n . (br5C)n gives rise to similar peptide patterns. These results suggest that dephosphorylation as well as phosphorylation determines the net incorporation of 32P into P1. Moreover, these results suggest the existence of a phosphatase activity that may be inhibited more strongly by (I)n . (C)n than by (I)n . (br5C)n.

Kinetics of decay in the expression of interferon-dependent mRNAs responsible for resistance to virus

We used 5,6-dichloro-beta D-ribofuranosyl-benzimidazole (DRB), a selective and reversible inhibitor of mRNA production, to investigate the regulation of the pathway leading to resistance to viruses in cells treated with interferon (IF). DRB allows initiation of transcription but promotes premature termination of the nucleotide chains, so that it abolishes interferon-dependent protection against viruses. When the DRB is removed, synthesis of complete mRNAs can resume. Mouse L-929 cells were exposed to 100 microM DRB before and during a 1-hr pulse of IF followed by treatment with antibody to IF to prevent cell-to-cell spread of IF after that time. At different intervals thereafter the cells were washed and the DRB was replaced by medium; after further incubation, the cells were infected with vesicular stomatitis virus. Resistance to virus was inversely proportional to the duration of the block imposed by DRB. When the DRB was removed soon after the IF pulse, substantial protection from virus ensued, but none developed when removal of the DRB was deferred for 5-6 hr. Cells exposed to DRB for 5 hr, then pulsed with IF for 1 hr, still mounted a strong antiviral response. The data show that the ability of cells to resist viral infection decays within 5-6 hr after treatment with IF. Whether the decay is due to shutoff of transcription of mRNAs, or to their destruction or degradation, or whether regulation takes place at one or more subsequent steps in the antiviral pathway, remains to be determined.