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.     

Interferon-induced human protein with homology to protein Mx of influenza virus-resistant mice.

Polyclonal and monoclonal antibodies with specificity for protein Mx (a karyophilic 75,000-dalton protein induced by interferon [IFN] in mouse cells carrying the influenza virus resistance allele Mx+) detected an IFN-induced 80,000-dalton protein in peripheral blood lymphocytes and in fibroblasts of healthy human donors. The human protein, like protein Mx, was induced by IFN-alpha but not by IFN-gamma. Unlike the mouse protein, it was predominantly localized in the cell cytoplasm.     

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.     

Isolation and characterization of a large,neurite-associated glycoconjugate from neuroblastoma cells

A high molecular weight glycoconjugate has been isolated from neurite-producing neuronal tumor cells in culture and has been designated as I(0) based on its elution characteristics in gel filtration chromatography. This molecule cannot be found in a variety of nonneuronal cells. I(0) is found in the substratum-attached material or cell fraction of neurite-producing neuroblastoma cells, depending upon culture conditions. It is found in the substratum-bound fraction of B104 rat neuroblastoma cells during serum starvation and in the EGTA-detached cell fraction of B104 cells grown in chemically defined N2 medium. It occurs only in the cell fraction of the human neuroblastoma line Platt. Examination of behavioral variants of the B104 rat line further strengthens the association of I(0) with neurite production; the constitutive neurite-producing E(R)B9 variant contains I(0) while the non-neurite-producing E(R)A11 variant does not. I(0) is large, eluting in the void volume of sepharose-CL2B columns. Radioiodination of intact cells with lactoperoxidase shows I(0) to be a cell surface component. Metabolic radiolabeling studies show that it contains a high proportion of polysaccharide to protein, does not contain mannose, and is unsulfated. Alkaline borohydride reduction release two size classes of large polysaccharide chain. The alkaline reduction results, along with the mannose incorporation studies, show the presence of O-glycosidic linkages and few, if any, N-linkages. Resistance to nitrous acid deamination, insensitivity to glycosaminoglycan lyases, and the absence of sulfation, indicate that I(0) does not contain the glycosaminoglycans hyaluronic acid, chondroitin-, dermatan-, or heparin- sulfates. Affinity column chromatography reveals high binding affinity of I(0) to polyornithine and no binding to gelatin (collagen) or the glycosaminoglycans hyaluronate and heparin. These studies describe a unique high molecular weight glycoconjugate on the surface of neurite-producing neuroblastoma cell lines from two species.     

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.     

Attenuation stem-loop lesions in the 5' noncoding region of poliovirus RNA: neuronal cell-specific translation defects.

The nucleotide at position 480 in the 5' noncoding region of the viral RNA genome plays an important role in directing the attenuation phenotype of the Sabin vaccine strain of poliovirus type 1. In vitro translation studies have shown that the attenuated viral genomes of the Sabin strains direct levels of viral protein synthesis lower than those of their neurovirulent counterparts. We previously described the isolation of pseudorevertant polioviruses derived from transfections of HeLa cells with genome-length RNA harboring an eight-nucleotide lesion in a stem-loop structure (stem-loop V) that contains the attenuation determinant at position 480 (A. A. Haller and B. L. Semler, J. Virol. 66:5075-5086, 1992). This stem-loop structure is a major component of the poliovirus internal ribosome entry site required for initiation of viral protein synthesis. The eight-nucleotide lesion (X472) was lethal for virus growth and gave rise only to viruses which had partially reverted nucleotides within the original substituted sequences. In this study, we analyzed two of the poliovirus revertants (X472RI and X472R2) for cell-type-specific growth properties. The X472RI and X472R2 RNA templates directed protein synthesis to wild-type levels in in vitro translation reaction mixtures supplemented with crude cytoplasmic HeLa cell extracts. In contrast, the same X472 revertant RNAs displayed a decreased translation initiation efficiency when translated in a cell-free system supplemented with extracts from neuronal cells. This translation initiation defect of the X472R templates correlated with reduced yields of infectious virus particles in neuronal cells compared with those obtained from HeLa cells infected with the X472 poliovirus revertants. Our results underscore the important of RNA secondary structures within the poliovirus internal ribosome entry site in directing translation initiation and suggest that such structures interact with neuronal cell factors in a specific manner.