Mx gene control of interferon action: different kinetics of the antiviral state against influenza virus and vesicular stomatitis virus.

The allele Mx regulates the extent to which interferon alpha/beta inhibits the growth of influenza viruses in mouse cells such as peritoneal macrophages. The time course of induction of the antiviral state against an influenza A virus is comparable in macrophages with and without Mx and is similar to that found with vesicular stomatitis virus. In contrast, the decay of the antiviral state against influenza virus is markedly slower in Mx-positive cells and slower than that against vesicular stomatitis virus observed in either Mx-positive or Mx-negative cells. Thus, after removal of interferon alpha/beta, Mx-positive cells remain protected against influenza virus at times when they have lost protection against vesicular stomatitis virus. These results suggest that interferon alpha/beta treatment activates different antiviral mechanisms, each acting against distinct groups of viruses and each independently controlled by host genes.     

Resistance to influenza virus infection of Mx transgenic mice expressing Mx protein under the control of two constitutive promoters.

Transgenic mice constitutively expressing in the brain the influenza virus resistance protein Mx1 controlled by the HMG (3-hydroxy-3-methylglutaryl coenzyme A reductase) promoter showed specific resistance against the neurotropic influenza A virus strain NWS. Control mice of the A2G strain express Mx1 protein in all organs, but only after induction by interferon type I upon or without viral infection. The extent of specific resistance in transgenic mice of the best-expressing line reached about two-thirds that of controls, most likely because of considerably less total-body Mx protein activity in the transgenic mice. Thus, the theoretical advantage in these mice of the continuous presence of Mx protein with early inhibitory potential to viral replication was apparently offset by restricted organ expression. Strong evidence that the Mx1 protein on its own is a specific anti-influenza A virus agent and that its efficiency in the experimental setting is independent of interferon actions could be derived from the treatment of experimental and control mice with anti-interferon antibodies at the time of virus tests. Whereas in A2G mice, Mx1 mRNA and Mx1 protein synthesis were abolished and viral resistance was markedly reduced or abolished, resistance in the transgenic mice persisted to almost the same degree. Transgenic mice generated with a mouse albumin/Mx1 cDNA construct showed liver-specific expression. However, in two expressing transgenic lines, Mx1 protein synthesis was suppressed after a few months. The mechanism of suppression could not be elucidated, but increasing methylation of the transgene's coding region was not the cause. It is possible that continuous Mx1 protein expression in the liver is less well tolerated than that in the brain. Whether this partial suppression and, with the HMG promoter, restricted organ expression are the organism's responses to interference of Mx1 with normal cellular activities such as nucleocytoplasmic transport of RNA and proteins cannot be determined until the molecular mechanisms of antiviral activity of Mx1 protein are understood.     

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.     

Identification of the murine Mx2 gene: interferon-induced expression of the Mx2 protein from the feral mouse gene confers resistance to vesicular stomatitis virus

The mouse genome contains two related interferon-regulated genes, Mx1 and Mx2. Whereas Mx1 codes for the nuclear 72-kDa protein that interferes with influenza virus replication after interferon treatment, the Mx2 gene is nonfunctional in all laboratory mouse strains examined, since its open reading frame (ORF) is interrupted by an insertional mutation and a subsequent frameshift mutation. In the present study, we demonstrate that Mx2 mRNA of cells from feral mouse strains NJL (Mus musculus musculus) and SPR (Mus spretus) differs from that of the laboratory mouse strains tested. The Mx2 mRNA of the feral strains contains a single long ORF consisting of 656 amino acids. We further show that Mx2 protein in the feral strains is expressed upon interferon treatment and localizes to the cytoplasm much like the rat Mx2 protein, which inhibits vesicular stomatitis virus replication. Furthermore, transfected 3T3 cell lines of laboratory mouse origin expressing Mx2 from feral strains acquire slight resistance to vesicular stomatitis virus.     

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.     

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.     

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.     

Thogoto virus lacking interferon-antagonistic protein ML is strongly attenuated in newborn Mx1-positive but not Mx1-negative mice

The Thogoto virus ML protein suppresses interferon synthesis in infected cells. Nevertheless, a virus mutant lacking ML remained highly pathogenic in standard laboratory mice. It was strongly attenuated, however, in mice carrying the interferon-responsive Mx1 gene found in wild mice, demonstrating that enhanced interferon synthesis is protective only if appropriate antiviral effector molecules are present. Our study shows that the virulence-enhancing effects of some viral interferon antagonists may escape detection in conventional animal models.     

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.     

Infection of neuroblastoma cells by Semliki Forest virus. The interference of viral capsid protein with the binding of host messenger RNAs into initiation complexes is the cause of the shut-off of host protein synthesis

From ribosomal washes of neuroblastoma cells infected with Semliki Forest virus (SFV) a protein of Mr 33000 was purified, which comigrated with the viral capsid protein on sodium dodecyl sulfate/polyacrylamide gels and was recognized by antibodies against the capsid protein of SFV. This protein selectively inhibits the translation of host and early viral 42S mRNA in vitro, but has no effect on late viral 26S and encephalomyocarditis virus mRNA translation. Eukaryotic initiation factor 4B and cap-binding protein restore the translation of host and 42S mRNA to control levels. The capsid protein specifically prevents the binding of host mRNA into 80S initiation complexes, but has no effect on that of late viral mRNA. We propose that the capsid protein is the component responsible for the shut-off of host protein synthesis in SFV-infected cells and for the decreased translational activity of the crude ribosomal washes from these cells.