Interferon induction by poly(inosinic acid).poly(cytidylic acid) segmented by spin-labels

Poly(inosinic acid).poly(cytidylic acid) [(I)n.(C)n] duplexes of which the (C)n strand was modified to various degrees chemically or enzymatically with nitroxide radicals (spin-labels) were evaluated for interferon-inducing activity. Upon annealing of the chemically modified (C)n, (1C,Cx)n (X = 1000 or 16), with (I)n, the interferon-inducing activity was similar to that of (I)n.(C)n in PRK cell cultures. However, to overcome hydrolysis of the spin-label linkage in (1C,Cx)n, and enzymatic approach was taken to synthesize (1S(4)U,Cx)n copolymers with x = 100, 38, 16, and 8. The (1s(4)U,Cx)n copolymers were chemically stable, and upon annealing with (I)n the correlation time of the nitroxide moiety in (I)n. (1s(4)U,Cx)n was determined. A comparison of this correlation time with that measured for (RUGT,U100)n.(A)n, which contains the nitroxide moiety in position 5 of the U moiety, suggests that the 1s(4)U residue is in a nonintrahelical conformation and partitions the duplex into double-helical segments of varying size. The interferon-inducing activity of (I)n. (1s(4)U,Cx)n was evaluated in primary rabbit kidney, human skin fibroblast (strain VGS), and mouse L-929 cell cultures as well as in rabbits. The 1s(4)U residue did not cause a significant change in the interferon induction as compared to (I)n.(C)n in most systems tested unless x less than 16. These findings indicate that double-helical segments of approximately 16 base pairs partitioned by nonintrahelical 1s(4)U residues suffice to trigger the interferon response in all systems studied.     

Structural requirements of polynucleotides for the activation of (2'' - 5'')An polymerase and protein kinase.

Two enzymatic pathways are involved in the inhibitory effects of double-stranded (ds)RNA on protein synthesis in cell extracts derived from interferon-treated human fibroblasts or HeLa cells, an oligonucleotide polymerase that synthesizes (2'-5')An from ATP and a protein kinase that phosphorylates the alpha subunit of initiation factor eIF-2 as well as a polypeptide of Mr = 72,000. We have now evaluated the activation of both the (2'-5')An polymerase and protein kinase by a large variety of polynucleotides, triple-stranded and synthetic dsRNAs, homopolymers, alternating copolymers, triple-stranded polymers, purine-purine duplexes and purine-pyrimidine duplexes with modifications at either the pyrimidine or ribose moieties. All these polynucleotides have been the subject of previous interferon induction studies. Some polynucleotides, i.e. (I)n.(C)n and mycophage dsRNA, which have been recognized as excellent interferon inducers, were also potent activators of both (2'-5')An polymerase and protein kinase, whereas non-inducers such as (A)n. (X)n and (A)n. (br5U)n did not activate either the kinase or the polymerase. However, some polymers like (I)n.(br5C)n, (difl)n(C)n and (dIcl)n (C)n, while potent interferon inducers and kinase activators, behaved poorly as activators of the (2'-5')An polymerase. Other polymers, i.e. (dAfl)n (U)n and (A)n.(U)nl (I)n, that do not induce interferon, activated the kinase but not the polymerase. Finally, (I)n (s2c)n, a relatively potent interferon inducer, did not activate either kinase or polymerase. These findings indicate that there is no simple relationship between the interferon-inducing ability of dsRNAs and their stimulating effects on (2'-5')An polymerase and protein kinase activity.     

Double-stranded RNA from phage F6: its interferon-inducing and antiviral properties]

Double stranded RNA was isolated from bacteriophage phi 6 parasitizing on phytobacteria. Its interferon-inducing and antiviral activities were shown in vitro and in vivo. In the culture of L-929 cells, interferon resistant to heat and acids was synthesized. The interferon could be practically completely neutralized by specific anti-interferon serum. The phage phi 6 preparation dsRNA in the lyophilized form was studied. The preparation retained its biological activity. It was shown that a preparation containing 30 per cent of dsRNA was less toxic than a preparation containing 100 per cent of dsRNA, the difference in the interferon-inducing activity being insignificant.     

Relation of the biological activity of double helical interferon inducers and their penetration into the cell and suppression of protein synthesis

The quantities of 125I-ds-inductors of interferon penetrating into the cells of transplantable cultures such as M19 (human fibroblast cells) and L-929 (mouse line) were not significant i.e. 10.5-4 per cent of the drug added. Under conditions of transfection with calcium phosphate and in complex with DEAE dextran the quantities of the inductors adhering to the cells and their contents in the cytoplasmic and nuclear fractions markedly increased. During the transfection with calcium phosphate up to 50 per cent of the applied inductor bound to the cells and its content in the cytoplasm and nuclei reached at least 10 per cent. After penetration into the cells poly I.poly C probably maintained its native structure and appeared to be firmly bound to the nuclear material. Preliminarily hydrolyzed inductors showed no such penetrating capacity. Contrary to the human fibroblast cells, in the mouse cells L-929 treated with the ds-inductors there was observed inhibition of the total protein synthesis which was probably due to activation of enzymes such as 2-5A-synthetase and proteinkinase. Increased penetration of the ds-inductors into the cells was accompanied by a marked (from 10- to 1000-fold) rise in their antiviral activity and a 2-4-fold rise in their interferon-inducing activity. It was concluded that there was immediate dependence of ds-inductor biological activity manifestation on the level of the inductor penetration into the cells.     

Interferon induction by mismatched analogues of polyinosinic acid . polycytidylic acid [(Ix,U)n.(C)n].

Interruption of the (I)n strand of (I)n.(C)n by unpaired bases [(U)] yielded mismatched analogues, (Ix,U)n.(C)n which were still effective as inducers of interferon, provided the I:U ratio (x) was equal or greater than 10. In highly sensitive interferon-induction systems such as primary rabbit kidney cells and human skin fibroblasts superinduced with cycloheximide and actinomycin D, (I10,U)n.(C)n and (I50,U)n.(C)n proved nearly as active as (I)n.(C)n. By virtue of their increased susceptibility to degradation by nucleases, (Ix,U)n.(C)n complexes with 10 less than or equal to x less than or equal to 50 may be expected not to persist as long in biological fluids as (I)n.(C)n, hence to induce fewer side effects.     

Induction of interferon and erythropoietic differentiation in cells transformed by Friend virus.

Two lines of Friend virus (FV)-transformed mouse spleen cells have been analyzed in respect to their interferon production capacity: neither F4 cells, which liberate infectious FV when kept under tissue culture conditions, nor the thymidine kinase-deficient B8 cells, which do not produce significant amounts of FV, release detectable amounts of autogenous interferon into cell supernatants. However, interferon is produced in these cells in amounts comparable to that in L-929 cells when interferon induction is initiated with UV-inactivated Newcastle disease virus. Conversely poly(I)-poly(C), a potent interferon inducer in L-929 cells, proved ineffective in this capacity in F4 or B8 cells. When erythropoietic differentiation is induced in these cells by dimethyl sulfoxide, no autogenous interferon production occurs, but with NDV-induction a four- to fivefode increase of interferon production is observed. A similar elevation of interferon production is achieved during 5-bromodeoxyuridine stimulation of differentiation in the thymidine kinase-deficient B8 cells. The refractiveness against poly(I)-poly(C) displayed in unstimulated cells is not overcome at any stage of differentiation, indicating major differences of Newcastle disease virus and poly(I)-poly(C) induction mechanisms.     

Antiviral activity of polynucleotides: copolymers of inosinic acid and N2-dimethylguanylic of 2-methylthioinosinic acid.

Complexes of poly(C) with copolymers of inosinic acid containing various amounts of mismatched bases (see journal for formula) have been examined for direct resistance to virus infection, interferon induction and toxicity in two different cell cultures (primary rabbit kidney cells and mouse L-929 cells). Complexes in which 20% of the hypoxanthine bases were replaced by (see journal for formula) or ms-2I were partially active whereas complexes in which 40% or more of the hypoxanthine bases were replaced by the odd bases were entirely inactive. The decrease in biological activity observed upon intrusion of (see journal for formula) or ms-2I in the poly(I) strand of poly(I) with poly(C) closely paralleled the amount of odd bases introduced irrespective of the system employed to assess the biological activity (resistance to virus infection, interferon induction or toxicity).     

Induction of Interferon and Erythropoietic Differentiation in Cells Transformed by Friend Virus

Two lines of Friend virus (FV)-transformed mouse spleen cells have been analyzed in respect to their interferon production capacity: neither F4 cells, which liberate infectious FV when kept under tissue culture conditions, nor the thymidine kinase-deficient B8 cells, which do not produce significant amounts of FV, release detectable amounts of autogenous interferon into cell supernatants. However, interferon is produced in these cells in amounts comparable to that in L-929 cells when interferon induction is initiated with UV-inactivated Newcastle disease virus. Conversely poly(I) · poly(C), a potent interferon inducer in L-929 cells, proved ineffective in this capacity in F4 or B8 cells. When erythropoietic differentiation is induced in these cells by dimethyl sulfoxide, no autogenous interferon production occurs, but with NDV-induction a four- to fivefold increase of interferon production is observed. A similar elevation of interferon production is achieved during 5-bromodeoxyuridine stimulation of differentiation in the thymidine kinase-deficient B8 cells. The refractiveness against poly(I) · poly(C) displayed in unstimulated cells is not overcome at any stage of differentiation, indicating major differences of Newcastle disease virus and poly(I) · poly(C) induction mechanisms.     

The state of hyporeactivity in interferon production: localization and partial purification of the factor repressing the interferon production

The hyporeactivity factor in interferon production by L-929 cells designated IRP (interferon repressing protein) has been studied. In particular, its localization and methods of its purification have been studied. The kinetics of IRP accumulation by producing cells correlate with the development of hyporeactivity condition. Most of IRP is localized in cell sap and in ribosomal fraction in evidence to regulatory role of repressor at the level of interferon mRNA translation. A 100-fold increase in repressor activity was achieved by IRP concentration by ammonium sulfate precipitation. IRP as well as interferon have been shown to possess high affinity to polyU sepharose. The preparations of IRP and interferon concentrated by ammonium sulfate precipitation were subsequently purified by fractioning in a polyI sepharose column. A 10,000-fold (6 x 10(4) U/mg) purification was achieved for IRP and 250-fold (10(4) U/mg) for interferon.     

Effect of calcium chloride on interferon production and the biosynthesis of cellular macromolecules

The influence of calcium chloride in production of interferon and biosynthesis of cell proteins, RNA and DNA in the cultures of chick embryo fibroblast cells and murine cells L-929 in response to induction of the cells by poly(I).poly(C) was studied. It was shown that calcium ions in concentrations of 10 to 30 mM markedly increased formation of interferon in the cell cultures.     

Interferon: ten stories in one. A short review of some of the highlights in the history of an almost quinquagenarian

This short review article on some pertinent observations in the unfolding story of interferon is dedicated to Professor Ilona Béládi on the occasion of her 80th birthday. This by no means covers the whole story on interferon. It just highlights some of the more striking findings made with interferon (or its inducers) over a time span of almost 50 years since its original discovery (in 1957) by Isaacs and Lindenmann. These observations concern (i) the induction of interferon by synthetic polyanions such as polyacrylic acid and polymethacrylic acid; (ii) the prolonged antiviral activity shown by polyacrylic acid in vivo; (iii) the interferon-inducing ability of double-stranded RNAs such as poly(I) x poly(C) and (iv) mismatched derivatives thereof (i.e. ampligen); (v) the cloning and expression of interferon-beta, and (vi) its usefulness in the treatment of multiple sclerosis; (vii) the potential of (pegylated) interferon-alpha in the treatment of hepatitis C and (viii) the therapy/prophylaxis of SARS; (ix) the efficacy of interferon (inducers) in the experimental treatment of flavivirus encephalitis and enterovirus myocarditis; and, finally, (x) the role of interferon in the activity shown by S-adenosylhomocysteine inhibitors such as 3-deazaneplanocin A against experimental Ebola virus infections in mice.     

Lysis of uninfected and virus-infected cells in vivo: a rejection mechanism in addition to that mediated by natural killer cells

To examine the lysis of virus-infected cells in vivo, uninfected and lymphocytic choriomeningitis virus (LCMV)-infected L-929 cells were labeled in vitro with [125I]-iododeoxyuridine and implanted intravenously into mice. Natural cytotoxicity against both uninfected and virus-infected cells was demonstrated in normal uninfected mice, but LCMV-infected cells were cleared from the lungs and whole bodies more rapidly than uninfected cells. Treatment of L-929 cells with defective interfering LCMV inhibited standard virus synthesis and protected the target cells from enhanced in vivo rejection. The in vivo rejection was apparently mediated by a cellular constituent of the host immune response and not simply a result of virus-induced cytopathic effects on the target cell, as hydrocortisone acetate and cyclophosphamide each reduced rejection of both target cell types and eliminated the enhanced rejection of LCMV-infected cells. The enhanced rejection of LCMV-infected cells was not restricted by histocompatibility antigens, indicating that classic T-cell recognition was not involved in the lysis, and since the enhanced rejection of LCMV-infected cells was mediated by mice treated with cobra venom factor, complement was also not involved in the lysis. Although moderate levels of interferon (102 U/ml) were present in the sera and although there was a modest activation of natural killer (NK) cells in the lungs of LCMV-infected cell recipients but not uninfected cell recipients, the enhanced rejection of virus-infected cells did not appear to be NK cell mediated. Normal mice and mice depleted of NK cell activity by in vivo treatment with antibody to asialo ganglio-n-tetraosylceramide ( AGM1 ) rejected uninfected and LCMV-infected L-929 cells similarly. This antibody markedly inhibited the rejection of NK-sensitive YAC-1 cells. In addition to the natural cytotoxicity directed against virus-infected cells, a second nonspecific rejection mechanism appeared in response to treatment protocols which induced interferon. Polyinosinic-polycytidylic acid and infection with LCMV augmented in vivo rejection of both uninfected and LCMV-infected L-929 cells but eliminated the differential rejection of the virus-infected cells. Infection with LCMV also augmented the in vivo rejection of the NK-sensitive target cell, YAC-1. In vivo treatments with anti- AGM1 sera only moderately inhibited the elevated rejection of uninfected and LCMV-infected L-929 cells, indicating that the enhanced rejection of these target cells was predominantly mediated by a mechanism other than that mediated by NK cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Use of Disposable Micro Tissue Culture Plates for Antiviral and Interferon Induction Studies

A reproducible test system requiring small amounts of test compound was developed for evaluating antiviral and interferon-inducing activity. In the antiviral experiments, KB cells were grown in disposable polystyrene microplates covered with a standard domestic plastic wrap. Viruses used in the system were types 1 and 2 herpes simplex virus, vaccinia virus, type 3 adenovirus, myxoma virus, pseudorabies virus, type 3 parainfluenza virus, types 1A and 13 rhinovirus, vesicular stomatitis virus, coxsackievirus B, and type 2 poliovirus. Inhibition of viral cytopathogenic effect was the primary criterion of evaluation of antiviral activity. Reduction in cell and supernatant fluid virus titers was used as a secondary means of evaluation. The microplate system was adaptable for determining prophylactic, therapeutic, and inactivating effects against viruses. Mouse L-929 cells were used for the interferon induction studies, with vesicular stomatitis virus utilized as the indicator of interferon activity. Known active compounds evaluated in this microplate system had activity similar to that seen in macro in vitro systems.     

Design of nucleoside, oligonucleotide and polynucleotide analogues as antiviral agents

Several approaches can be envisaged in the design of nucleoside and oligo- or polynucleotide analogues with selective antiviral activity: (i) deoxythymidine (dThd) or deoxycytidine (dCyd) analogues which are specifically recognized as substrate by the virus-induced dThd-dCyd kinase; (ii) adenosine analogues which impair transmethylation reactions (or polyamine biosynthesis), by virtue of an inhibition of S-adenosylhomocysteine hydrolase; (iii) (2'-5')-oligonucleotide analogues derived from pppA(2'p5'A)2, an important intermediate in the antiviral action of interferon; (iv) oligo(deoxy)nucleotides that are complementary to a well-defined nucleotide sequence of the viral genome; (v) single-stranded homopolynucleotides that act as antitemplates for virus-associated RNA or DNA polymerases; and (vi) double-stranded homopolynucleotides that may be pursued for their interferon-inducing potentials.     

Recovery of Cell-Bound Interferon

Interferon could be recovered from homologous cells to which it was applied but could not be recovered from heterologous cells. The amount of interferon that could be recovered from cells corresponded to the sensitivity of the cells to the antiviral activity of the interferon: mouse embryo fibroblasts, which were 5 to 10 times as sensitive as L-929 cells to interferon, bound 5 to 10 times more interferon than the latter, whereas Lpa cells, which were only one-third as sensitive as L-929 cells to interferon, bound only one-third as much as the latter. The concentration of cell-bound interferon was as much as 150 times the extracellular concentration of interferon applied to the cells. Interferon bound to cells at 4 C with the same efficiency as it did to cells at 37 C, and actinomycin D-treated cells bound interferon as well as normal cells. Even though the total amount of interferon bound to cells was as much as 30% of the amount of interferon applied to them, no loss of antiviral activity was detectable from the medium.     

Induction of interferon by polyribonucleotides containing thiopyrimidines.

The influence of thioketo substitution in pyrimidine bases of double-stranded polynucleotides on interferon induction was investigated. The stabilizing effect of 2-thioketo substitution was reflected in the increased interferon inducing activity of poly(A-s2U) over that of poly(A-U). Poly(A-s2U) and poly(I)-poly(s2C) were as effective as poly(I)-Poly(C) in rabbit cells. Poly(I)-poly(C) and poly(I)-poly(s2C) were compared in several animal species. No differences in biological effects were observed in rabbits and dogs. In rodents, poly(I)-poly(s2C) was less effective and less toxic.Poly(I)-poly(s2C) was highly resistant against degradation by human serum. Further investigations seem to be justified to elucidate whether this property offers any advantages for the potential clinical utilization of poly(I)-poly(s2C).     

Cellular Alteration by Interferon: a Virus-Free System for Assaying Interferon

A system is described for assaying mouse interferon without using a viral "challenge" agent. Interferon-treated L cells were destroyed by exposure to polyriboinosinic.polyribocytidylic acid [poly(I).poly(C)], and the amount of destruction was dependent on both the concentration of interferon to which the cells were exposed and the amount of poly(I).poly(C) used as the "challenge" material. If the amount of poly(I).poly(C) was constant, the concentration of interferon could be determined by quantitating cell destruction 6 hr after addition of the double-stranded ribonucleic acid. In addition to eliminating the necessity for employing infectious virus for interferon assays, this system has the advantages of being quicker, easier, and more sensitive than other interferon assays. The sensitivity of the assay is related directly to the amount of poly(I).poly(C) applied to the cells, with each fivefold increase of poly(I).poly(C) giving about a fivefold increase of sensitivity.     

Comparative antiviral and interferonogenic activity of natural and synthetic interferon inducers in vitro and in vivo]

Biological activities of the RNA replicative form of phage f2, a natural interferon inductor and poly-I -- poly-C, a synthetic polyribonucleotide complex were studied comparatively. Differences in the comparative interferonogenic and antiviral activity of the inductors were as dependent on the type of the cell system. It was shown that DEAE-dextran increased the interferon-inducing activity of RFf2 in the cell culture by 4 to 8 times. The dynamics of the interferonogenic and antiviral activity of RFf2 in the L-929 cell culture was studied. Interferon appeared in the culture fluid in 6--8 hours and reached its maximum titers (128 IU50/ml) by the 24th hour, the maximum protection of the cells being also developed by the 12th--24th hour, reaching on an average 51 g PFU/ml. It was shown in the experiments with green marmosets that administration of RFf2 in the form of aerosol in a dose of 2.3 mg/kg induced interferon production in the blood serum the titers of which amounted to 80--160 IU50/ml 24 hours after the administration.