Interferon Induction by Viruses

Interferons are proteins of cellular origin capable of conferring virus resistance to vertebrate cells. Most cells do not produce interferons except in response to proper stimulation. Clearly, the stimulation of interferon production encompasses two phenomena. When stimulated, some cell systems produce their interferons by synthesizing new proteins. Other cell systems do not require the synthesis of new proteins to produce interferons, and still other cell systems may produce interferons by both means. Before much can be learned from the detailed study of the nature of the molecules which stimulate interferons, the type of phenomenon which the stimulus induces must be identified. Chick embryo tissues apparently make interferons by synthesizing new proteins. Many viruses stimulate interferon production in chick embryo tissues. Data available suggest that neither the protein nor nucleic acid moieties of the added virions act as inducing molecules. Also, double-stranded replicative form is probably not responsible. It is suggested that the inducer molecule may be cellular in nature and may be produced in response to a wide variety of insults among which are viral infections.     

Some biological properties of the human amniotic membrane interferon.

Human amniotic interferon was investigated to define the species specificity of its antiviral action and to compare its anti-cellular and NK cell stimulating activities with those of other human interferons. The antiviral effect was titrated in bovine (RV-IAL) and monkey (VERO) cells. Amniotic interferon exhibited, in bovine cells, 5% of the activity seen in monkey cells, while alpha interferon displayed 200%. No effect was detected with either beta or gamma interferon in bovine cells. Daudi cells were exposed to different concentrations of various interferons and the cell numbers were determined. The anticellular effect of the amniotic interferon reached its peak on the third day of incubation. Results suggested a higher activity for alpha and gamma interferons and a lower activity for beta when compared to amniotic interferon. Using total mononuclear cells as effector cells and K 562 as target cells in a 51Cr release assay, it was demonstrated that low concentrations of amniotic interferon consistently stimulated NK cell activity in cells derived from several donors, the results indicating a higher level of activity with this interferon than with alpha and beta interferons.     

Interferon: pharmacokinetics and toxicity

Interferons disappear rapidly from the serum of animals and man, and the kidney may be the major site of interferon destruction. The relevance of serum levels of interferons to their therapeutic activity has not been clearly established, particularly as the stimulation of host defence mechanisms by interferons may be important. Relatively low serum levels of antiviral activity are seen after intramuscular injections of fibroblast interferon compared with those after the same dose of leucocyte interferon. Injections of very pure leucocyte and lymphoblastoid interferons from several sources cause fever, headaches, malaise and myalgia associated with a corticosteroid response and probably with inflammatory prostaglandin synthesis. These reactions become less with repeated dosing but very large doses of lymphoblastoid interferon have been shown to cause liver damage and serious metabolic disturbances. Treatment with moderate doses of exogenous interferons may occasionally be associated with the development of neutralizing antibodies.     

Regulatory effects of macrophage-secreted factors on T-lymphocyte colony growth.

Human fibroblast and leukocyte interferons were found to suppress lymphocyte mitogenesis induced by optimal doses of phytohemagglutinin and concanavalin A. In certain situations (low doses of mitogen and/or low doses of interferon), however, interferon significantly enhanced mitogenesis. In experiments using varying concentrations of interferon, dose-response curves with different slopes were obtained for fibroblast and leukocyte interferons. The effect of interferon was apparently exerted during early stages of the lymphocyte cell cycle. There was no inhibitory effect of interferon if the lymphocytes were washed with medium before being exposed to mitogen. Interferon increased the binding of radiolabeled mitogens to cells. The results suggest that the immunological effects of interferon are consequences of actions on lymphoid cells. Fibroblast and leukocyte interferons seem to have different modes of action, or to bind differently to target cells. Possible mechanisms for the suppressive and enhancing effects of interferons on lymphoid cells are discussed.     

The interferon receptors

Early studies on the mode of action of interferons have indicated that a receptor system on the cell surface is involved in its action. The first direct evidence to a high-affinity binding site was found only after pure interferon was available. Two different receptors, one specific for interferons-alpha and beta, and the other for interferon-gamma were recognized. A correlation between affinity to the receptor and specific activity was established. Cross-linked complexes of labeled interferons with their receptors were visualized on gel electrophoresis and even partially purified. Internalization of interferons after binding to the receptor was reported. The role of gangliosides as helpers of interferon binding was recently investigated. Fragments of interferons which still retained binding capacity were described and helped in elucidating the binding site on the interferon molecule.     

Immuno-modulating properties of interferons

Interferons (IFNs), by inducing the antiviral state in cells, are in the first line of defence against virus infections and are therefore part of the immune system as defined in its broadest sense. In addition, IFN-alpha and beta can influence specific functions of lymphocytes and macrophages; moreover, a special class of interferons, called IFN-gamma, are produced as a result of antigen recognition by T cells and by the interaction of mitogens and lymphocytes. Interferons influence B and T cell function in vitro and in vivo, as demonstrated by their effects on antibody formation, specific cytotoxicity of sensitized T cells, allograft survival, delayed-type hypersensitivity and graft-host reaction. They stimulate Natural Killer cell activity and induce functional and morphological changes in mononuclear phagocytes. There are many examples of disturbed immune reactions as a result of viral infection, implicating interferons as contributing factors; this is a result of the lack of immunological specificity of interferon action. The extent to which interferons have a truly immunoregulatory role is a question currently receiving a great deal of attention, but is still very much unsettled.     

Additive and synergistic effects of a novel antiestrogen, toremifene (Fc-1157a), and human interferons on estrogen responsive MCF-7 cells in vitro

The effect of human interferons alpha and gamma alone and in combination with a novel antiestrogen toremifene were studied in vitro using MCF-7 cell line, an estrogen receptor positive and antiestrogen sensitive cell line. The effects were evaluated by a simple bioluminescence method with which the number of living cells was obtained as cellular adenosine triphosphate (ATP) content. The growth of MCF-7 cells was inhibited both by interferon alpha and interferon gamma. At least additive effect was evident when the cells were exposed to combination of interferons and toremifene: the combination was additive with interferon gamma + toremifene and synergistic with interferon alpha + toremifene. The combination of toremifene and interferons may have clinical importance.     

Interferons in the management of neuroendocrine tumors and their possible mechanism of action.

Alpha interferons at doses of 3-9 MU subcutaneously, three to seven times/week, have been administered to 32 patients with malignant endocrine pancreatic tumors. The objective biochemical response rate was 63 percent with a median duration of 20.5 months. Significant reduction of tumor size was only noticed in 20 percent of the patients. Alpha interferon administered to 111 patients with malignant carcinoid tumors showed objective biochemical responses in 42 percent of the patients with a median duration of 32 months. Another 39 percent of the patients showed stabilization of disease without any further tumor growth. Subjective improvement was noticed in 70 percent of the patients. When survival data are analyzed in patients with malignant carcinoid tumors, the median survival from start of treatment was 80+ months in the group of patients treated with alpha interferon, which should be compared with only eight months in a historical group treated with chemotherapy (streptozotocin plus 5-fluorouracil). The adverse reactions to alpha-interferon treatment are dose-dependent and include, mainly, flu-like symptoms, fatigue, and low-grade weight loss. Autoimmune reactions are noted in about 20 percent of the patients. Patients treated with recombinant alpha interferons might develop neutralizing interferon antibodies (6-27 percent), which abrogate the anti-tumor response. The anti-tumor effect in neuroendocrine tumors includes anti-proliferation, apoptosis, differentiations, and cytotoxic/cytostatic effects. Furthermore, immunomodulation is obtained by increased expression of class I antigens on tumor cells. Four patients also developed antibodies directed against carcinoid tumor cells. Alpha interferons induce several nuclear enzymes such as 2'-5'-A synthetase, p-68 kinase, and Mx-A proteins, which are involved in a downregulation of expression of growth factors, oncogenes, and peptide hormones, leading to anti-proliferation and/or apoptosis. The response to alpha-interferon treatment might be predicted by analysis of the induction of 2'-5'-A synthetase in samples from neuroendocrine tumors. Stimulatory tests of hormone secretion, such as meal stimulation of pancreatic polypeptide secretion or secretin test, clearly demonstrate a normalization during alpha-interferon treatment, which might depend on reduced peptide production and/or secretion but also on eradication of malignant cell clones. In summary, alpha interferons have demonstrated significant anti-tumor effects in patients with malignant neuroendocrine gut and pancreatic tumors. The adverse reactions are dose-dependent and manageable. The anti-tumor effects of alpha interferons are pleiotropic and include several direct effects on tumor cells but also immunomodulation.     

Effect of interferons on dengue virus multiplication in cultured monocytes/macrophages

The effects of interferons on dengue virus multiplication in cultured human and mouse monocytes/macrophages were studied. Interferon treatment before, but not after virus inoculation suppressed virus multiplication dose-dependently. Recombinant human leukocyte A interferon was as effective as ordinary human fibroblast interferon in suppressing dengue virus multiplication in cultured human monocytes. Human monocytes, a population of non-proliferating cell lineage, maintained their interferon-mediated antiviral state for a few days after removal of the interferons.     

Effect of mouse interferons on the development of Ehrlich ascitic carcinoma

Intraperitoneal injection of various preparations of mouse interferons (L cell tissue culture interferons, concentrated or partly purified, and also serum interferon) significantly inhibited the development of Ehrlich's ascites carcinoma in randombred mice. In view of comparatively low activity of serum interferon, the effect of normal mouse serum on the tumour development and its action on L cell tissue culture interferon was investigated. It was shown that normal mouse serum inhibits the action of L cell tissue culture interferon and promotes the development of Ehrlich's ascites carcinoma.     

Bacteria-derived human leukocyte interferons alter in vitro humoral and cellular immune responses

Cultures of gradient-purified human peripheral blood mononuclear cells (PBMC) have been employed to examine the effects of three bacteria-derived human leukocyte interferon subtypes on certain aspects of in vitro immune responses. The addition of highly purified IFN-alpha 1, -alpha 2, -alpha 2/alpha 1 to PMBC cultures stimulated with phytohemagglutinin (PHA) or pokeweed mitogen resulted in a significant suppression of the mitogenic response. This suppression required the presence of interferon in the cultures because pretreatment of cells and removal of interferon had no effect on their response to PHA. The presence of these interferons at 200 U/ml also caused a substantial reduction of human mixed-lymphocyte reactions (MLR) as measured by [3H]thymidine incorporation by responder cells. Interestingly, pretreatment of stimulator cells was sufficient for this reduction to occur whereas pretreatment of responder cells had no effect on their ability to respond to allogenic stimulation. In contrast to these suppressive effects, the three interferons enhanced human in vitro primary immune response to sheep red blood cells (SRBC). These data demonstrate that both purified interferon subtypes and genetic hybrids of human interferons produced by recombinant DNA technology have effects on in vitro immune responses.     

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.     

Comparative immunochemical analysis of various human leukocyte interferons

Using radioimmunological methods based on the use of mono- and polyclonal antibodies raised against interferon alpha A, it was shown that polyclonal antibodies quantitatively reacted not only with this protein, but also with interferons alpha F and alpha N, whereas all the variants of monoclonal antibodies studied reacted only with interferons alpha A and alpha N. Monoclonal antibodies 5A6, 11E9, 19C10, 258 and 268 are directed against overlapping epitopes of the interferon alpha A molecule, which simultaneously binds not more than two molecules of antibodies with different specificity. The correlation between immunochemical and biological activities of interferon alpha A during temperature denaturation and proteolytic degradation and its ability to form oligomeric complexes were investigated.     

The effect of natural and recombinant leukocyte interferons on DNA repair and the formation of chromosome aberrations induced by N-methyl-N'-nitro-N-nitrosoguanidine

The anticlastogenic action of natural leukocyte and recombinant (alpha 2) interferons was studied in human lymphocyte cultures treated with N-methyl-N'-nitro-N-nitrosoguanidine. The criteria of cell viability, proliferation, chromosome aberrations, frequency of micronucleus formation, formation and repair of DNA breaks were used for estimation of interferons activity. Reduction of the induced chromosomal aberrations was obtained in cells pretreated with interferons. The protective effect of natural leukocytic interferon was more expressed as compared with the effect of recombinant (alpha 2) interferon. The natural interferon was also more efficient than the recombinant one in DNA breaks formation and repair.     

The biochemical mechanisms of action of the interferons

The interferon family of proteins consists of a variety of antigenically distinct types that are encoded by different genes. Several of these genes have been cloned and the availability of large amounts of the recombinant interferons has greatly facilitated characterization of their biochemical and biological activities. The specificity of interaction of interferons with cell surface receptors has been investigated in binding and covalent cross-linking experiments employing 125I-labeled interferons. In addition to their antiviral activity, the interferons have effects on cell growth and differentiation. The interferons also are potent modulators of the immune response. The interferons exert their biological activities by altering the expression of several cellular proteins. Current knowledge about the mechanisms of signal transduction and the regulation of expression of interferon-induced mRNAs and proteins are discussed.     

Orally administered interferons exert their white blood cell suppressive effects via a novel mechanism.

Interferons (IFN) have been approved for a number of clinical uses. The accepted routes of administration are intramuscular, subcutaneous, and intravenous. Recently, interferons administered by the oral route have been shown to exert a systemic effect. Oral administrations of IFN-alpha, IFN-beta, and IFN-gamma have been shown to cause a suppression of the peripheral white blood cell (WBC) count in mice. This study investigates the mechanism by which this suppression occurs. The results show that, in contrast to their intraperitoneal administration, oral administration of rHuIFN-alpha A/D or rMuIFN-gamma does not result in the presence of detectable levels of interferons in the blood. In addition, although the presence of circulating specific antibody to interferon blocks the peripheral WBC suppressive effects of intraperitoneally administered MuIFN-beta or rMuIFN-gamma, the presence of those antibodies does not block the peripheral WBC suppressive effects of the orally administered interferons. The peripheral WBC suppressive effect of orally administered rHuIFN-alpha A/D and rMuIFN-gamma can be transferred by injection of blood from oral interferon-treated donor mice to recipient mice. Recipient mice receiving plasma from donor mice showed no peripheral WBC suppression. Recipient mice receiving blood cells from donor mice showed significant peripheral WBC suppression. No effect of orally administered rHuIFN-alpha A/D on the relative percentages of lymphocytes, neutrophils, and monocytes was noted. These results indicate that the mechanism by which orally administered interferons exert their WBC suppressive effect differs from that of intraperitoneally administered interferons. WBC suppression resulting from orally administered interferons may involve cell to cell transfer of the interferons' effects, rather than the systemic distribution of the interferons in the blood. These studies further suggest that there may be a role for oral administration as a new route of interferon administration and provide a glimpse into the mechanism by which the orally administered interferons exert their systemic effects.     

Purification and characterization of interferons from a continuous myeloblastic cell line

Several leukocyte interferon species have been purified from a continuous human myeloblast cell line. The purification procedure involving selective precipitations, gel chromatography, and several steps of high performance liquid chromatography results in interferons with specific activities of 1 to 4 X 10(8) units/mg on bovine MDBK cells. The total yield of interferon is 23%, with the yield of the individual fractions ranging from 0.2 to 11.4%. Five fractions are homogeneous as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Molecular weights of the interferons were estimated by mobility on the sodium dodecyl sulfate gels and range from 17,600 to 26,200. The species differ in their relative antiviral activities on two cell lines, bovine MDBK and human AG-1732. In addition, the pure species have similar, but distinct, amino acid compositions and tryptic peptide profiles. These result support the conclusion that leukocyte interferon consists of several homologous proteins.     

Effect of remantadine and ribavirin on the production and antiviral action of human interferon types I and II

The results of using human interferon of types I (alpha- and beta-interferons) and II (gamma-interferon) in combination with chemotherapeutic drugs, such as remantadin and ribavirin for the study in human cell cultures are presented. Moderate doses of the drugs (25 microgram/ml) did not eliminate the interferon production. In higher doses (50 microgram/ml) they lowered the interferon production levels 2--3 times. In the presence of ribavirin the level of the interferon production lowering was higher. On the whole the effect of the drugs on production of interferons of types I and II was of a similar character despite the different means of interferon induction. The combined use of interferons of types I and II with the chemotherapeutic drugs in human embryo cultures infected with Semiliki forest virus (SFV) revealed an additive character of the antiviral effect in all combinations tested. The level of the antiviral activity of alpha-, beta- and gamma-interferons against the SFV was practically the same.     

Modification of DNA repair by human interferons

We have found a new biological function of interferons, namely, their capacity to protect human cells from the action of some physical and chemical mutagens. To evaluate the protective effect of interferons the following criteria were applied: formation of sister chromatid exchanges (SCE) and chromosomal aberrations (CA), as well as viability of cells and intensity of DNA repair synthesis. Pretreatment of cells with natural interferon decreased the number of sister chromatid exchanges and chromosomal aberrations, induced by different mutagens, and increased the intensity of DNA repair synthesis. This is attributed to the ability of interferon to enhance certain phases of DNA repair. In the case of photomutagenic action of 8-methoxypsoralen (8-MOP) on the lymphocytes, when monoadducts (MA) only, or both monoadducts and interstrand cross-links (ICL) are formed, the antimutagenic effect of interferon is exhibited only with respect to ICL. Unlike the natural interferon, the recombinant alpha 2-interferon failed to have any effect on the lymphocytes of clinically healthy donors exposed to gamma-radiation. In the repair- deficient cells (Marfan's syndrome) the protection of natural interferon against the action of 4-nitroquinoline-1'-oxide and gamma- radiation was found to be reduced significantly and that of alpha 2-interferon was not manifested at all. Thus, the capacity of interferons to alter the DNA repair, conceivably, depends on the type of interferon and on the cell genotype.