Combined action of mouse alpha and beta interferons in influenza virus-infected macrophages carrying the resistance gene Mx

Lactobacillus delbrueckii CRL 581 Differentially Modulates TLR3-Triggered Antiviral Innate Immune Response in Intestinal Epithelial Cells and Macrophages

Lactobacillus delbrueckii subsp. lactis CRL 581 beneficially modulates the intestinal antiviral innate immune response triggered by the Toll-like receptor 3 (TLR3) agonist poly(I:C) in vivo. This study aimed to characterize further the immunomodulatory properties of the technologically relevant starter culture L. delbrueckii subsp. lactis CRL 581 by evaluating its interaction with intestinal epithelial cells and macrophages in the context of innate immune responses triggered by TLR3. Our results showed that the CRL 581 strain was able to adhere to porcine intestinal epithelial (PIE) cells and mucins. The CRL 581 strain also augmented the expression of antiviral factors (IFN-α, IFN-β, Mx1, OAS1, and OAS2) and reduced inflammatory cytokines in PIE cells triggered by TLR3 stimulation. In addition, the influence of L. delbrueckii subsp. lactis CRL 581 on the response of murine RAW macrophages to the activation of TLR3 was evaluated. The CRL 581 strain was capable of enhancing the expression of IFN-α, IFN-β, IFN-γ, Mx1, OAS1, TNF-α, and IL-1β. Of note, the CRL 581 strain also augmented the expression of IL-10 in macrophages. The results of this study show that the high proteolytic strain L. delbrueckii spp. lactis CRL 581 was able to beneficially modulate the intestinal innate antiviral immune response by regulating the response of both epithelial cells and macrophages relative to TLR3 activation.

Mx proteins: antiviral gatekeepers that restrain the uninvited

Fifty years after the discovery of the mouse Mx1 gene, researchers are still trying to understand the molecular details of the antiviral mechanisms mediated by Mx proteins. Mx proteins are evolutionarily conserved dynamin-like large GTPases, and GTPase activity is required for their antiviral activity. The expression of Mx genes is controlled by type I and type III interferons. A phylogenetic analysis revealed that Mx genes are present in almost all vertebrates, usually in one to three copies. Mx proteins are best known for inhibiting negative-stranded RNA viruses, but they also inhibit other virus families. Recent structural analyses provide hints about the antiviral mechanisms of Mx proteins, but it is not known how they can suppress such a wide variety of viruses lacking an obvious common molecular pattern. Perhaps they interact with a (partially) symmetrical invading oligomeric structure, such as a viral ribonucleoprotein complex. Such an interaction may be of a fairly low affinity, in line with the broad target specificity of Mx proteins, yet it would be strong enough to instigate Mx oligomerization and ring assembly. Such a model is compatible with the broad "substrate" specificity of Mx proteins: depending on the size of the invading viral ribonucleoprotein complexes that need to be wrapped, the assembly process would consume the necessary amount of Mx precursor molecules. These Mx ring structures might then act as energy-consuming wrenches to disassemble the viral target structure.

Interferon-inducible protein Mx1 inhibits influenza virus by interfering with functional viral ribonucleoprotein complex assembly

Mx1 is a GTPase that is part of the antiviral response induced by type I and type III interferons in the infected host. It inhibits influenza virus infection by blocking viral transcription and replication, but the molecular mechanism is not known. Polymerase basic protein 2 (PB2) and nucleoprotein (NP) were suggested to be the possible target of Mx1, but a direct interaction between Mx1 and any of the viral proteins has not been reported. We investigated the interplay between Mx1, NP, and PB2 to identify the mechanism of Mx1's antiviral activity. We found that Mx1 inhibits the PB2-NP interaction, and the strength of this inhibition correlated with a decrease in viral polymerase activity. Inhibition of the PB2-NP interaction is an active process requiring enzymatically active Mx1. We also demonstrate that Mx1 interacts with the viral proteins NP and PB2, which indicates that Mx1 protein has a direct effect on the viral ribonucleoprotein complex. In a minireplicon system, avian-like NP from swine virus isolates was more sensitive to inhibition by murine Mx1 than NP from human influenza A virus isolates. Likewise, murine Mx1 displaced avian NP from the viral ribonucleoprotein complex more easily than human NP. The stronger resistance of the A/H1N1 pandemic 2009 virus against Mx1 also correlated with reduced inhibition of the PB2-NP interaction. Our findings support a model in which Mx1 interacts with the influenza ribonucleoprotein complex and interferes with its assembly by disturbing the PB2-NP interaction.

Host factor Ebp1: selective inhibitor of influenza virus transcriptase

Influenza virus RNA polymerase is composed of three virus-coded proteins, and is involved in both transcription and replication of the negative-strand genome RNA. Subunit PB1 plays key roles in both the RNA polymerase assembly and the catalytic function of RNA polymerization. Using yeast two-hybrid screening, a HeLa cell protein with the molecular mass of 45 kDa was identified. After cloning and sequencing, this protein was identified to be Ebp1, ErbB3-binding protein. Epb1 specifically interacts with PB1 both in vitro and in vivo, and Epb1 contact site on PB1 was mapped at its binding site of transcription primers. Ebp1 was found to interfere with in vitro RNA synthesis by influenza virus RNA polymerase (3P complex), but no inhibition was observed for capped RNA endonuclease and RNA-cap binding, the intrinsic activities of RNA polymerase. Since inhibition was not observed against other nucleic acid polymerases tested, we propose that Ebp1 is a selective inhibitor of influenza viral RNA polymerase. Accordingly over-expression of Ebp1 interfered with virus production. The PB1-contact site on Ebp1 overlaps with the interaction site with ErbB3 (epidermal receptor tyrosine kinase), androgen receptor (AR) and retinoblastoma gene product (Rb), which are involved in controlling cell proliferation and differentiation.

Interferon-inducible Mx proteins in fish

Mx proteins are members of a family of interferon-inducible genes expressed when cells are treated with double-stranded RNA or virus infection. These proteins are important components of the antiviral response and form the first line of the body's defense against virus infections. The exact mechanism of action for these proteins has not been discovered, but mice missing the Mx genes are extremely sensitive to influenza virus infection. Mammals have between two and three Mx genes whose functions may vary with regard to the inhibition of a specific virus, cellular localization, and activity. The cDNA of three rainbow trout Mx proteins has been cloned and a comparison of their sequences with that of avian and mammalian species reveals striking conservation of domains. They all maintain the tripartite ATP/GTP binding domain and the dynamin family signature in the amino terminal half of the protein. In the carboxyl terminal half of the Mx proteins are the localization signals and the leucine zipper motifs which account for the trimerization of Mx in the cell. Like the rat and human Mx proteins, the different trout Mx proteins exhibit distinctly different immunohistochemical staining patterns in cells transfected with plasmids expressing RBTMx1, RBTMx2, or RBTMx3. To date, the antiviral function of the trout Mx proteins has not been satisfactorily established.

Effects of 4-ipomeanol on bovine alveolar macrophage function

The objective of this study was to determine whether 4-ipomeanol toxicosis in calves impairs alveolar macrophage functions important in pulmonary defense against infectious agents. Male Holstein calves were given either 4-ipomeanol (3 mg kg-1, i.v.) or vehicle (polyethylene glycol 400). Alveolar macrophages were recovered by pulmonary lavage 3 days later, and their capacities to phagocytose and kill E. coli, migrate toward zymosan-activated immune bovine serum, and produce interferon and interleukin-1 activity were evaluated in vitro. Alveolar macrophages recovered from 4-ipomeanol-treated calves had over a 70% decrease (p < 0.01) in chemotactic activity and over a 37% decrease (p < 0.005) in their capacity to phagocytose E. coli as compared to macrophages from control calves. Interleukin-1 activity in macrophages from 4-ipomeanol-treated calves tended to be higher than that from control calves, but the differences were not statistically significant (p = 0.06). 4-ipomeanol did not affect macrophage bactericidal activity or production of interferon. These results indicate that 4-ipomeanol suppresses select functions of alveolar macrophages in cattle that may be important in pulmonary defense against bacterial pathogens.

Interferons, Mx genes, and resistance to influenza virus

Human influenza is primarily an infection of the upper respiratory tract and central airways. The interferon (IFN) system appears to have a role in limiting viral spread and initiating recovery before the development of T-cell and B-cell responses in primary infection. All cellular responses to IFNs result from interaction with cell surface receptors that trigger the expression of a number of cellular genes. Among the IFN-inducible gene products, the Mx proteins have attracted much attention because they have potential activity against influenza virus and possibly against other viruses. Mx proteins are guanosine triphosphate (GTP)-binding proteins with intrinsic GTPase activity. They seem to act indirectly against viruses by modifying cellular functions needed along the viral replication pathway. In mice the Mx1 protein has been shown to be necessary and sufficient to protect against influenza virus infection because the resistance does not require a functioning immune system. In humans the MxA protein has antiviral activities against influenza viruses. The MxA protein is encoded on the distal part of the long arm of chromosome 21 together with several other proteins implicated in the IFN system. Patients with Down's syndrome (trisomy 21) have an increased expression of MxA protein, and their cells display an increased sensitivity to IFNs in vitro because of gene dosage effects. These patients, however, are more susceptible to upper respiratory infection than normal individuals. This susceptibility has been related to deficiencies in the immune system. Therefore, induction of MxA in man does not sem sufficient to prevent influenza spreading, and, in contrast to the murine Mx system, a functioning immune system is necessary for protection.

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.

MxA-dependent inhibition of measles virus glycoprotein synthesis in a stably transfected human monocytic cell line

The alpha/beta (type I) interferon-inducible human MxA protein confers resistance to vesicular stomatitis virus (VSV) and influenza A virus in MxA-transfected mouse 3T3 cells (3T3/MxA). We investigated the inhibitory effects of the MxA protein on measles virus (MV) and VSV in the human monocytic cell line U937. In transfected U937 clones which constitutively express MxA (U937/MxA), the release of infectious MV and VSV was reduced approximately 100-fold in comparison with control titers. Transcription of VSV was inhibited similar to that observed for 3T3/MxA cells, whereas no difference was detected for MV in the rates of transcription or the levels of MV-specific mRNAs. In contrast, analysis of MV protein expression by immunofluorescence and immunoprecipitation revealed a significant reduction in the synthesis of MV glycoproteins F and H in U937/MxA cells. These data demonstrate a virus-specific effect of MxA which may, in the case of MV, contribute to the establishment of a persistent infection in human monocytic cells.

Localization of dynamin: widespread distribution in mature neurons and association with membranous organelles

Tissue distribution and intracellular localization of dynamin by immunoblotting and immunocytochemistry is investigated in this study. Dynamin was widely expressed in all the neurons we examined, and was especially abundant in the central nervous system after maturation, although its expression presented regional heterogeneity. Dynamin was present most abundantly in cerebellar Purkinje cells and hippocampal pyramidal cells, and to a lesser extent in motor neurons and peripheral nerves. However, dynamin was nearly absent in cells such as anterior pituitary cells and adrenal medullary cells which secrete mainly dense cored vesicles. Dynamin was localized not only in cell bodies, axons, and synapses but also in dendrites. Subcellular fractionation indicated that dynamin existed in the membrane fraction as well as in the soluble fraction. In ligated peripheral nerves, dynamin colocalized with tubulovesicular membranous organelles transported mainly anterogradely. By transfection of dynamin cDNA into mouse fibroblast L-cells, we showed it colocalized with some membranous organelles but not with microtubules. Our results show that dynamin is associated with membranous organelles in vivo, although a certain amount of dynamin also exists in the soluble fraction and is distributed diffusely throughout mature neurons. The data suggest that dynamin's fundamental role involves membrane trafficking in neurons in the central nervous system rather than in sliding microtubules as a motor protein.

Overexpression of the influenza virus polymerase can titrate out inhibition by the murine Mx1 protein

The murine Mx1 protein is an interferon-inducible protein which confers selective resistance to influenza virus infection both in vitro and in vivo. The precise mechanism by which the murine Mx1 specifically inhibits replication of influenza virus is not known. Previously, sensitive replication systems for influenza virus ribonucleoprotein, in which a synthetic influenza virus-like ribonucleoprotein is replicated and transcribed by influenza virus proteins provided in trans, have been developed. With these systems, the antiviral activity of the murine Mx1 protein was examined. It was found that continued expression of influenza polymerase polypeptides via vaccinia virus vectors can titrate out the inhibitory action of the murine Mx1 protein. This titration of inhibitory activity also occurs when the viral PB2 protein alone is overexpressed, suggesting that an antiviral target for the murine Mx1 polypeptide is the viral PB2 protein.

Human and mouse Mx proteins inhibit different steps of the influenza virus multiplication cycle

Human MxA and mouse Mx1 are interferon-induced proteins capable of inhibiting the multiplication of influenza virus. MxA protein is localized in the cytoplasm, whereas Mx1 protein accumulates in the nucleus. Taking advantage of stably transfected cell lines that constitutively express either MxA or Mx1 protein, we examined the steps at which these proteins block influenza A viruses. In infected cells expressing MxA protein, all viral mRNAs synthesized as a result of primary transcription in the nucleus by the virion-associated RNA polymerase accumulated to normal levels. These primary viral transcripts were polyadenylated, were active in directing viral protein synthesis in vitro, and appeared to be efficiently transported to the cell cytoplasm. Yet viral protein synthesis and genome amplification were strongly inhibited, suggesting that MxA protein interfered with either intracytoplasmic transport of viral mRNAs, viral protein synthesis, or translocation of newly synthesized viral proteins to the cell nucleus. However, in infected cells expressing Mx1 protein, the concentrations of the longest primary transcripts encoding the three influenza virus polymerase proteins PB1, PB2, and PA were at least 50-fold reduced. Accumulation of the shorter primary transcripts encoding the other viral proteins was also inhibited but to a lesser extent. These results demonstrate that the mouse Mx1 protein interferes with primary transcription of influenza virus in the nucleus, whereas the human MxA protein inhibits a subsequent step that presumably takes place in the cytoplasm of infected cells.

Disease resistance in farm animals

Genetic variations in disease resistance of farm animals can be observed at all levels of defence against infectious agents. In most cases susceptibility to infections has polygenic origins. In domestic animals only a few instances of a single genetic locus responsible for disease resistance are known. A well-examined example is the Mx1 gene product of certain mice strains conferring selective resistance to influenza virus infections. Attempts to improve disease resistance by gene transfer of different gene constructs into farm animals include the use of monoclonal antibody gene constructs, transgenes consisting of antisense RNA genes directed against viruses and Mx1 cDNA containing transgenes.

Antiviral actions of interferon. Interferon-regulated cellular proteins and their surprisingly selective antiviral activities

Considerable progress has been made in the understanding of the molecular biology of the human interferon system. The genes encoding the interferons, their receptors, and the proteins that mediate many of their biological effects have been molecularly cloned and characterized. The availability of complete cDNA clones of components of the interferon systems has contributed significantly to our understanding of both the biology and the biochemistry of the antiviral actions of interferons. At the biological level, the antiviral effects of interferon may be viewed to be virus-type nonspecific. That is, treatment of cells with one type or even subspecies of interferon often leads to the generation of an antiviral state effective against a wide array of different RNA and DNA animal viruses. However, at the biochemical level, the antiviral action of interferon is often virus-type selective. That is, the apparent molecular mechanism which is primarily responsible for the inhibition of virus replication may differ considerably between virus types, and even host cells. For example, the IFN-regulated Mx protein selectively inhibits influenza virus but not other viruses when constitutively expressed in mouse cells. The IFN-regulated 2',5'-oligoadenylate synthetase selectively inhibits EMC and mengo viruses, two picornaviruses, but not viruses of other families when constitutively expressed in transfected cells. Some viruses are typically insensitive to the antiviral effects of interferon, both in cell culture and in intact animals. This lack of sensitivity to IFN may result from a virus-mediated direct antagonism of the interferon system. For example, in the case of adenovirus, the activation of the IFN-regulated RNA-dependent P1/elF-2 protein kinase is blocked by the virus-associated VA RNA. The relative sensitivity to interferon of different animal viruses varies appreciably. All three of the basic components required to measure an antiviral response may play a role in determining the relative effectiveness of the antiviral response: the species of interferon administered; the kind of cell treated; and, the type of virus used to challenge the interferon-treated host cell. Thus, the relative sensitivity to interferon observed for a particular interferon-cell-virus combination is likely the result of the equilibrium between the many agonists and antagonists which contribute to the overall response. That is, the relative sensitivity of a virus to the inhibitory action of IFN is governed by the qualitative nature and quantitative amount of the individual IFN-regulated cell proteins that may collectively contribute to the inhibition of virus replication.(ABSTRACT TRUNCATED AT 400 WORDS)

Avian cells expressing the murine Mx1 protein are resistant to influenza virus infection

The cDNA encoding the murine Mx1 protein, a mediator of resistance to influenza virus, was inserted into a replication-competent avian retroviral vector in either the sense (referred to as Mx+) or the antisense (referred to as Mx-) orientation relative to the viral structural genes. Both vectors produced virus retaining the Mx insert (Mx recombinant viruses referred to as Mx+ and Mx-) following transfection into chicken embryo fibroblasts (CEF). Mx protein of the appropriate size and nuclear localization was expressed only in CEF cells infected with the Mx+ virus. Mx expression was observed in all Mx(+)-infected cells and was stable during long-term culture. Cells infected with the Mx+ virus were resistant to infection by human influenza A/WSN/33 (H1N1) and avian influenza viruses A/Turkey/Wisconsin/68 (H5N9) and A/Turkey/Massachusetts/65 (H6N2), but were susceptible to infection by the enveloped RNA viruses Sindbis and vesicular stomatitis virus (VSV). Normal CEF and cells infected with the Mx virus were susceptible to influenza A, Sindbis, and VSV. The synthesis of influenza proteins, especially the larger polymerase and hemagglutinin proteins, was reduced in Mx+ retrovirus-infected cells superinfected by influenza A.

Transport of incoming influenza virus nucleocapsids into the nucleus

Upon penetration of the influenza virus nucleocapsid into the host cell cytoplasm, the viral RNA and associated proteins are transported to the nucleus, where viral transcription and replication occur. By using quantitative confocal microscopy, we have found that over half of cell-associated nucleoprotein (NP) entered the nucleus with a half time of 10 min after penetration into CHO cells. Microinjection and immunoelectron microscopy experiments indicated that the NP entered the nucleus through the nuclear pore as part of an intact ribonucleoprotein (RNP) structure and that its transport was an active process. Transport of the incoming RNPs into the nucleus was not dependent on an intact microfilament, microtubule, or intermediate filament network. Subsequent to penetration, the matrix (M1) protein appeared to dissociate from the RNP structure and to enter the nucleus independently of the RNP. We found that 50% of penetrated M1 entered the nucleus with a half time of 25 min after penetration into CHO cells. Nuclear transport of M1 appeared to occur by passive diffusion. Entry of incoming M1 into the nucleus was not a prerequisite for infection.

Activity of rat Mx proteins against a rhabdovirus

Upon stimulation with alpha/beta interferon, rat cells synthesize three Mx proteins. Sequence analysis of corresponding cDNAs reveals that these three proteins are derived from three distinct genes. One of the rat cDNAs is termed Mx1 because it is most closely related to the mouse Mx1 cDNA and because it codes for a nuclear protein that, like the mouse Mx1 protein, inhibits influenza virus growth. However, this protein differs from mouse Mx1 protein, in that it also inhibits vesicular stomatitis virus (VSV), a rhabdovirus. A second rat cDNA is more closely related to the mouse Mx2 cDNA and directs the synthesis of a cytoplasmic protein that inhibits VSV but not influenza virus. The third rat cDNA codes for a cytoplasmic protein that differs from the second one in only eight positions and has no detectable activity against either virus. These results indicate that rat Mx proteins have antiviral specificities not anticipated from the analysis of the murine Mx1 protein.

Transgenic mice with intracellular immunity to influenza virus

We have generated transgenic mice that express the intracellular anti-influenza virus protein Mx1 under control of an interferon-responsive regulatory element. Upon infection with influenza virus, mice of a high responder line produce Mx1 protein locally at the sites of initial viral replication, exhibit little viral spread, and survive infection. Mice of a low responder line show more extensive viral spread and survive infection only when virus is given at high doses. To survive low dose infections, these mice require injection of interferon along with virus. The results show that influenza viral pathogenesis is determined by a subtle balance between the dose of the infecting virus and the levels of the antiviral host factor Mx1 and that mice can be rendered resistant to a virulent infection by "intracellular immunization" achieved through germline transformation.

Resistance to influenza virus and vesicular stomatitis virus conferred by expression of human MxA protein

MxA and MxB are interferon-induced proteins of human cells and are related to the murine protein Mx1, which confers selective resistance to influenza virus. In contrast to the nuclear murine protein Mx1, MxA and MxB are located in the cytoplasm, and their role in the interferon-induced antiviral state was unknown. In this report we show that transfected cell lines expressing MxA acquired a high degree of resistance to influenza A virus. Surprisingly, MxA also conferred resistance to vesicular stomatitis virus. Expression of MxA in transfected 3T3 cells had no effect on the multiplication of two picornaviruses, a togavirus, or herpes simplex virus type 1. Treatment of MxA-expressing cells with antibodies to mouse alpha-beta interferon did not abolish the resistance phenotype. The conclusion that resistance to influenza virus and vesicular stomatitis virus was due to the specific action of MxA is further supported by the observation that transfected 3T3 cell lines expressing the related MxB failed to acquire virus resistance.

A putative GTP binding protein homologous to interferon-inducible Mx proteins performs an essential function in yeast protein sorting

Members of the Mx protein family promote interferon-inducible resistance to viral infection in mammals and act by unknown mechanisms. We identified an Mx-like protein in yeast and present genetic evidence for its cellular function. This protein, the VPS1 product, is essential for vacuolar protein sorting, normal organization of intracellular membranes, and growth at high temperature, implying that Mx-like proteins are engaged in fundamental cellular processes in eukaryotes. Vps1p contains a tripartite GTP binding motif, which suggests that binding to GTP is essential to its role in protein sorting. Vps1p-specific antibody labels punctate cytoplasmic structures that condense to larger structures in a Golgi-accumulating sec7 mutant; thus, Vps1p may associate with an intermediate organelle of the secretory pathway.

cDNA structures and regulation of two interferon-induced human Mx proteins

Human cells treated with interferon synthesize two proteins that exhibit high homology to murine Mx1 protein, which has previously been identified as the mediator of interferon-induced cellular resistance of mouse cells against influenza viruses. Using murine Mx1 cDNA as a hybridization probe, we have isolated cDNA clones originating from two distinct human Mx genes, designated MxA and MxB. In human fibroblasts, expression of MxA and MxB is strongly induced by alpha interferon (IFN-alpha), IFN-beta, Newcastle disease virus, and, to a much lesser extent, IFN-gamma, MxA and MxB proteins have molecular masses of 76 and 73 kilodaltons, respectively, and their sequences are 63% identical. A comparison of human and mouse Mx proteins revealed that human MxA and mouse Mx2 are the most closely related proteins, showing 77% sequence identity. Near their amino termini, human and mouse Mx proteins contain a block of 53 identical amino acids and additional regions of very high sequence similarity. These conserved sequences are also present in a double-stranded RNA-inducible fish gene, which suggests that they may constitute a functionally important domain of Mx proteins. In contrast to mouse Mx1 protein, which accumulates in the nuclei of IFN-treated mouse cells, the two human Mx proteins both accumulate in the cytoplasm of IFN-treated cells.

cDNA structures and regulation of two interferon-induced human Mx proteins

Human cells treated with interferon synthesize two proteins that exhibit high homology to murine Mx1 protein, which has previously been identified as the mediator of interferon-induced cellular resistance of mouse cells against influenza viruses. Using murine Mx1 cDNA as a hybridization probe, we have isolated cDNA clones originating from two distinct human Mx genes, designated MxA and MxB. In human fibroblasts, expression of MxA and MxB is strongly induced by alpha interferon (IFN-alpha), IFN-beta, Newcastle disease virus, and, to a much lesser extent, IFN-gamma, MxA and MxB proteins have molecular masses of 76 and 73 kilodaltons, respectively, and their sequences are 63% identical. A comparison of human and mouse Mx proteins revealed that human MxA and mouse Mx2 are the most closely related proteins, showing 77% sequence identity. Near their amino termini, human and mouse Mx proteins contain a block of 53 identical amino acids and additional regions of very high sequence similarity. These conserved sequences are also present in a double-stranded RNA-inducible fish gene, which suggests that they may constitute a functionally important domain of Mx proteins. In contrast to mouse Mx1 protein, which accumulates in the nuclei of IFN-treated mouse cells, the two human Mx proteins both accumulate in the cytoplasm of IFN-treated cells.

Regulation of the interferon-inducible IFI-78K gene, the human equivalent of the murine Mx gene, by interferons, double-stranded RNA, certain cytokines, and viruses

The interferon-inducible gene (IFI-78K gene) that codes for a human protein, p78, of 78,000 Mr is the equivalent of the mouse Mx gene encoding Mx protein. The IFI-78K gene is located on chromosome 21 together with the alpha/beta interferon (IFN-alpha/beta) receptor. The p78 protein is important since it may be involved in resistance to influenza viruses. The regulation of the IFI-78K gene was studied in human diploid cells by using a cDNA probe to p78 mRNA and specific monoclonal antibodies to p78 protein. The IFI-78K gene, a normally quiescent gene, is transcriptionally regulated by IFN-alpha, and its induction does not require protein synthesis. The rate of transcription measured in a run-on assay increased rapidly but transiently. The level of p78 mRNA increased up to 8 h, declining slowly afterwards. The p78 protein, undetectable in untreated cells, accumulated up to 16 h, and its amount remained stable for at least 36 h after the addition of IFN-alpha. Cytokines such as tumor necrosis factor, interleukin-1 alpha, and interleukin-1 beta activated the IFI-78K gene at concentrations comparable to that of IFN-alpha. However, gene activation by these cytokines required protein synthesis. Poly(rI)-poly(rC) induced the IFI-78K gene directly at the transcriptional level without requirement for protein synthesis. Newcastle disease virus, influenza virus, and to a lesser extent vesicular stomatitis virus also induced the IFI-78K gene in the absence of any protein synthesis. Induction of transcription by viruses was markedly enhanced by pretreatment of cells with IFN-gamma (which by itself is a poor inducer of the IFI-78K gene), resulting in accumulation of p78 protein during the course of infection; this suggests that IFN-gamma programs cells to full antiviral activity upon virus infection.

A family of interferon-induced Mx-related mRNAs encodes cytoplasmic and nuclear proteins in rat cells

Mouse Mx protein, an interferon (IFN)-induced nuclear protein, confers selective resistance to influenza virus. We show here that, as with influenza virus-resistant Mx+ mouse embryo cells, influenza virus mRNA accumulation and protein synthesis are strongly inhibited in rat embryo cells treated with IFN-alpha/beta. IFN-alpha/beta induced in rat cells the synthesis of Mx-related mRNAs migrating on Northern (RNA) gels as two bands of about 3.5 and 2.5 kilobases which directed the synthesis of three electrophoretically distinct proteins called rat Mx proteins 1, 2, and 3. The three rat proteins were antigenically related to the mouse Mx protein but differed in molecular weight and intracellular location. Rat Mx protein 1 was found predominantly in the nucleus and, on the basis of several criteria, resembled the nuclear mouse Mx protein. It was induced by IFN-alpha/beta in all 28 inbred rat strains tested. Rat Mx proteins 2 and 3 differed from protein 1 at the carboxy terminus and were predominantly cytoplasmic like the human Mx homolog. Sequence data of partial cDNA clones indicate that three Mx-related genes, rather than one, exist in the rat.

Antiviral state against influenza virus neutralized by microinjection of antibodies to interferon-induced Mx proteins

In mouse Mx+ cells, interferon alpha/beta induces the synthesis of the nuclear Mx protein, whose accumulation is correlated with specific inhibition of influenza viral protein synthesis. When Mx+ mouse cells are microinjected with the monoclonal anti-Mx antibody 2C12, interferon alpha/beta still induces Mx protein, but no longer inhibits efficiently the expression of influenza viral proteins as visualized by immunofluorescent labeling. However, interferon inhibition of an unrelated control virus, vesicular stomatitis virus, remains unchanged. Proteins with homology to mouse Mx protein are found in interferon-treated cells of a variety of mammalian species. In rat cells, for instance, rat interferon alpha/beta induces three Mx proteins which all cross-react with antibody 2C12 but differ in mol. wt and intracellular location, and it protects these cells well against influenza viruses. However, when rat cells are microinjected with antibody 2C12, interferon alpha/beta cannot induce an efficient antiviral state against influenza virus infection, whereas protection against vesicular stomatitis virus is not altered. These results show that both mouse and rat cells require functional Mx proteins for efficient protection against influenza virus. They further demonstrate that microinjection of antibodies is a promising way of elucidating the role of particular interferon-induced proteins in the intact cell.

The action of recombinant bovine interferons on influenza virus replication correlates with the induction of two Mx-related proteins in bovine cells

Recombinant bovine interferon-alpha and -gamma differ in their action against influenza virus on bovine cells. Bovine IFN-alpha severely impairs early protein synthesis and replication of influenza virus in bovine cells in contrast to bovine IFN-gamma which fails to induce an antiviral state against influenza virus. Otherwise the IFN system seems to function normally in bovine cells since both bovine IFN-alpha and -gamma induce an antiviral state against vesicular stomatitis virus. The establishment of the specific antiviral state against influenza virus correlates with the induction by bovine IFN-alpha, but not -gamma, of two cytoplasmic proteins related to the IFN-induced mouse protein Mx involved in the mechanism of resistance of mice to influenza virus infection. This study suggests that bovines possess a system for resistance to influenza virus similar to the mouse Mx system.

Influenza virus resistance of wild mice: wild-type and mutant Mx alleles occur at comparable frequencies

The laboratory-reared progeny of wild Mus musculus domesticus from several places in Europe and from California were tested for resistance to experimental infection with influenza viruses and for the ability of their explanted macrophages to synthesize Mx protein in response to type I interferon. About 75% of these mice were resistant to influenza viruses and were able to synthesize Mx protein, as expected for mice carrying the influenza virus resistance allele Mx+ in either homozygous or heterozygous form. Resistance of wild mice was inherited as a single autosomal dominant trait which cosegregated with the ability to synthesize Mx protein. About 25% of the randomly bred wild mice failed to synthesize Mx protein and died after infection with influenza virus, very much like inbred mice homozygous for the Mx- allele. We conclude that Mx+ and Mx- alleles occur at roughly equal frequencies in wild mice and that some selective advantage for heterozygous individuals exists in the wild. This finding raises new questions about the physiological role of the Mx locus.

Interferon-regulated influenza virus resistance gene Mx is localized on mouse chromosome 16

Genomic Southern blots of mouse-hamster somatic cell hybrids were analyzed with a probe prepared from a cDNA encoding murine Mx protein, the product of the interferon-regulated influenza virus resistance allele Mx+. Results of this analysis indicate that the Mx gene is located on mouse chromosome 16. In appropriate backcross mice, no linkage was observed between Mx and md, a marker previously mapped close to the centromere of chromosome 16, suggesting a more distal localization of Mx.

Mx protein: constitutive expression in 3T3 cells transformed with cloned Mx cDNA confers selective resistance to influenza virus

Mx+ mice are much more resistant to influenza virus than Mx- strains. The resistance is mediated by interferon (IFN) alpha/beta. After IFN treatment, Mx+ but not Mx- cells accumulate Mx protein and become specifically resistant to orthomyxoviruses. cDNA encoding Mx protein was cloned and sequenced. Southern analyses indicate that Mx- alleles derive from their Mx+ counterpart by deletions. IFN-treated Mx+ cells contained a 3.5 kb Mx mRNA, while Mx- cells showed only traces of shorter Mx RNA. Mx- cells transformed with Mx cDNA expressed Mx protein constitutively to varying extents; resistance of individual cells to influenza virus correlated with Mx protein expression. Thus, specific resistance to influenza virus in vivo may be attributed to Mx protein expression and is independent of other IFN-mediated effects.

Effect of human alpha A interferon on influenza virus replication in MDBK cells

To determine the molecular mechanism whereby interferon induces resistance to influenza virus, we began an investigation of influenza virus replication in MDBK cells treated with recombinant human alpha A interferon. Negative- and positive-strand virus-specific RNA accumulation was monitored by blot hybridization with cloned probes. Primary transcription (transcription of infecting viral negative strands by the virion-associated polymerase) was inhibited by interferon treatment of MDBK cells. At moderate levels of interferon treatment (10 U/ml), this inhibition was restricted to transcripts of polymerase genes, whereas at higher levels of interferon treatment (50 U/ml), accumulation of all primary transcripts was markedly inhibited. Secondary transcripts and viral negative strands did not accumulate to any significant extent in interferon-treated MDBK cells. These results suggest that interferon-induced mechanisms which inhibit influenza virus replication in MDBK cells act at the level of primary transcription.

Inhibition of influenza viral mRNA synthesis in cells expressing the interferon-induced Mx gene product

Interferons alpha and beta induce an efficient antiviral state against influenza virus in mouse cells that possess the Mx gene, but not in mouse cells that lack this gene. In Mx-containing cells treated with interferon the amount of viral mRNA synthesized as a result of primary transcription is drastically reduced. Only two viral mRNAs could be detected by Northern analysis and by translating the poly(A)+ RNA from infected cells in wheat germ extracts: a reduced amount of the mRNA for nonstructural protein 1 and an even lower amount of the mRNA for the matrix protein. The other viral mRNAs were not made in detectable amounts. In addition, the rate of viral mRNA synthesis catalyzed by the inoculum transcriptase, measured by in vitro RNA synthesis catalyzed by permeabilized cells, was severely inhibited. In contrast, interferon treatment of cells lacking the Mx gene had little or no effect on either the steady-state level or the rate of synthesis of viral mRNAs made by the inoculum transcriptase. These results indicate that the interferon-induced Mx gene product, a 75,000-molecular-weight protein that accumulates in the nucleus, inhibits influenza viral mRNA synthesis which occurs in the nucleus. No Mx-specific effect acting directly on viral protein synthesis in the cytoplasm was observed.

Interferon-induced protein Mx accumulates in nuclei of mouse cells expressing resistance to influenza viruses

In mouse cells carrying the dominant influenza resistance allele Mx+ (but not in Mx- cells) interferon-alpha/beta (IFN) induces an efficient antiviral state against influenza viruses and, concomitantly, the synthesis of a 75,000-Da protein (protein Mx). Here, indirect immunofluorescence using monoclonal antibodies was used to demonstrate that protein Mx accumulates in the nucleus of IFN-treated Mx+ cells, suggesting a nuclear site of action. Protein Mx is present in the nucleus of untreated influenza virus-resistant macrophages freshly explanted from the peritoneal cavity of Mx+ mice but is lost with time in culture when peritoneal macrophages become permissive for influenza virus.