Differential effects of pure human alpha and gamma interferons on fibroblast cell growth and the cell cycle

Pure human alpha and recombinant gamma interferons had differential effects on two strains of fetal lung fibroblasts in vitro. Alpha interferon had little effect on long-term cell growth, whereas gamma interferons, both glycosylated and non-glycosylated, were cytotoxic. However, when synchronized cells were studied, alpha interferon prolonged both G1 and S + G2 phases of the cell cycle, whereas gamma interferon only affected the G1 phase.     

Sequence and acute phase regulation of rat alpha 1-inhibitor III messenger RNA

cDNA clones coding for the plasma proteinase inhibitor alpha 1-inhibitor III were isolated from an acute phase rat liver library. The isolates could be divided into four groups with characteristic BamHI restriction fragment patterns. The identity of the prototype clone pRLA1I3/2J was established by comparison with the published amino acid sequence of the purified protein. It codes for a 1477-amino acid precursor polypeptide with a 24-residue signal peptide. The mature protein shares 58% overall sequence identity with rat alpha 2-macroglobulin and contains a typical internal thiolester sequence. Twenty-two of its twenty-three cysteinyl residues are conserved with alpha 2-macroglobulin implying similar tertiary structure. However, the prototype alpha 1-inhibitor III sequence differed significantly from the rat and human alpha 2-macroglobulin sequences in its bait region suggesting alpha 1-inhibitor III possesses proteinase inhibitory specificities different from those of alpha 2-macroglobulin. The variant alpha 1-inhibitor III clone pRLA1I3/2J from a second cDNA group also differed from the prototype in the bait region coding sequence, although both specify similar signal peptides and NH2 termini. The observation of variant cDNA classes suggests that acute phase rat livers produce a heterogeneous mixture of alpha 1-inhibitor III mRNA molecules. Evidence was obtained for the presence of at least four different alpha 1-inhibitor III-related genes in the rat genome. During the first 24 h of an acute phase response the abundance of hepatic alpha 1-inhibitor III mRNA was decreased 3-4-fold. This decrease was of the same order of magnitude as the reported reduction of the corresponding plasma protein concentration, suggesting that in the early phase of the acute inflammatory response the plasma concentration of this protein is mainly controlled through the abundance of its hepatic mRNA.     

Clonal derivatives of the RD-114 cell line differ in their antiviral and gene-inducing responses to interferons.

The human rhabdomyosarcoma cell line RD-114 is partially responsive to interferons (IFNs). In these cells, alpha interferon (IFN-alpha) or gamma interferon (IFN-gamma) inhibits the replication of some viruses but not of others. Similarly, some of the IFN-inducible mRNAs are induced poorly, whereas others are induced well. Here we report the isolation of clonal derivatives of this line which display different spectra of responses to IFNs. Among the eight extensively characterized clonal lines, one, C10, did not respond to IFN-alpha or IFN-gamma at all. Retrovirus production by each of the seven other lines was inhibited by both IFN-alpha and IFN-gamma. Replication of vesicular stomatitis virus was inhibited strongly by IFN-alpha in clone B1 but not in others, whereas it was not appreciably affected by IFN-gamma in any clone. Replication of encephalomyocarditis virus was inhibited strongly by IFN-gamma in clones A1, A2, A3, B3, and B8 and by IFN-alpha in clone A2. Neither IFN inhibited the multiplication of these clones greatly, although their doubling times were slightly increased. Five mRNAs were induced by IFNs to varying degrees in the seven clones. mRNA 2A was most strongly induced by IFN-gamma in clone A3. mRNA 1-8 was strongly induced by IFN-alpha in clone A1 and by either IFN in clones A2 and A3. The highest concentrations of 2',5'-oligoadenylate synthetase mRNA, mRNA 561, and mRNA 6-16 were in IFN-alpha-treated clones A1 and A2. These results demonstrated the existence of clonal heterogeneity in IFN responses in a cell line and strengthened the view that IFN treatment of cells generates multiple signals leading to a variety of IFN-induced phenotypes.     

Isolation and properties of genetic engineered human leukocyte interferons alphaI1 and alphaN

Using controlled pore glass chromatography and immunoaffinity chromatography on monoclonal antibodies NK-2 immobilized on Sepharose 4B, the electrophoretically homogeneous interferons alpha N and alpha I1 were isolated from the biomass of gene-engineered Pseudomonas sp. strains. In terms of specific activity on human fibroblast diploid cells, interferon alpha I1 does not differ from interferon alpha A, whereas the specific antiviral activity of interferon alpha N is as low as 2.10(7) JU/mg. The procedures for immunometric assay of interferons alpha N and alpha I1 have been elaborated. Various monoclonal antibodies to interferon alpha A and to natural leucocyte interferon were analyzed; among those the antibodies specifically interacting with interferons alpha N and alpha I1 (but not with interferon alpha A) were identified.     

Interferon selectively inhibits the expression of mitochondrial genes: a novel pathway for interferon-mediated responses.

As an approach to identifying genes involved in physiological actions of interferons we used differential probes to screen a cDNA library from mouse L-929 cells treated with interferon alpha/beta. We identified two negatively regulated mRNA species which have been examined by analysis of the corresponding mRNAs and by DNA sequencing. Comparison with the GenBank database showed that these cDNA clones corresponded to mitochondrially encoded genes for cytochrome b and subunit I of cytochrome c oxidase. A further cDNA encompassing three mitochondrial genes was used as a probe to show that a third mRNA, NADH dehydrogenase subunit 5, was also down-regulated by interferon while a fourth, NADH dehydrogenase subunit 6, was unaffected. Expression of cytochrome b was also inhibited in mouse NIH 3T3 cells treated with interferon alpha/beta and in human Daudi lymphoblastoid cells treated with interferon alpha. The ability of interferon to reduce mitochondrial mRNA levels could be blocked by cycloheximide suggesting that these effects are mediated by an interferon-responsive nuclear gene which encodes a product capable of regulating mitochondrial gene expression. Analysis of proteins synthesized in the presence of emetine, a specific inhibitor of cytoplasmic translation, showed that the synthesis of several mitochondrial translation products, including cytochrome b, was reduced after treatment with interferon. Our results reveal a novel effect of interferon on cellular physiology which could have important consequences for understanding the effects of interferons as well as suggesting new mechanisms for the regulation of mitochondrial biogenesis and function.