Proteins induced by the double-stranded interferon inducer poly(I).poly(C)

The possible pathways for realization of antiviral activity of interferon inducer poly (I).poly(C) have been studied. The stimulating effect of interferon inducer on the net protein synthesis in human M19 fibroblasts has been demonstrated. Compositions of the specific proteins induced by poly(I).poly(C) or interferon in human M19 fibroblasts and in monkey cells 4647 have been analyzed by electrophoresis technique. The data obtained suggest the existence of common gene products for interferon and ds-inducer. The ds-inducer requires the synthesis of lesser amounts of proteins for realization of its biological activity as compared with interferon.     

Double-Stranded Polynucleotides as Interferon Inducers

A discussion of factors considered influential in making a polynucleotide an efficient inducer of interferon was presented. These factors were double-strandedness of the polynucleotides, the sugar moiety of the polynucleotides, thermal stability, resistance to enzymatic degradation, and molecular size of the polynucloetides. Recent developments concerning interferon induction during virus infection were also discussed.     

Induction of alpha interferon by membrane interaction between viral surface and peripheral blood mononuclear cells

Cells infected with viruses and fixed when viral antigens appeared at the cell membrane induced much higher alpha interferon (IFN-alpha) levels in human peripheral blood mononuclear cells (PBMC) than free virions. Relatively few inducer cells were sufficient for triggering IFN production. Optimal IFN yields depended on inducer/producer cell ratio. The response was peculiar to PBMC as it was not found in other cells in which IFN can normally be induced by free virions. IFN inducing activity was also exerted by live virus-infected PBMC, showing that this type of induction may have physiological importance. These findings confirm that viral induction of IFN-alpha is activated by some interaction between viral components presented at the cell surface and PBMC membrane. Thus induction of IFN by circulating cells infected by viruses and presenting viral antigens at the surface may be an efficient host defense mechanism. Since IFN yields close to 10(6) international units per milliliter are obtained, this system has potential for large scale production of native IFN-alpha.     

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).     

Isolation and Characterization of a Double-Stranded Ribonucleic Acid from Penicillium chrysogenum

Double-stranded ribonucleic acid has been obtained from cells of the fungus Penicillium chrysogenum. This ribonucleic acid appears to be associated with mycophage and is an efficient inducer of interferon Its. extraction and partial purification are discussed, and evidence for its double-stranded and ribosidal nature is reviewed. The implications of viral nucleic acid in the life processes of fungi are considered.     

Inositol phospholipid turnover and protein kinase C translocation are stimulated by poly(I).poly(C) in human amnion cells (UAC)

Polyinosinic-polycytidylic acid, a potent inducer of inducer of interferon (IFN) production and activator of some IFN-induced enzymes, inhibits [3H]uridine incorporation into the RNA of vesicular stomatitis virus even in the absence of IFN synthesis, transiently triggers the breakdown of inositol phospholipids and activates the translocation of protein kinase C. Since IFNs also have similar activities these results suggest that IFN induction and IFN function are realised through common biochemical pathways.     

Interferon induction and utilization

The interferon mechanism offers the hope for moderate to high level prophylactic immunity of broad antiviral spectrum but of relatively short duration. Economic and biological considerations offer little hope for utilization of exogenous interferon as a prophylactic or therapeutic substance, unless but a small part of the total molecule be found to carry the activity. The real promise for interferon application is in the administration of suitable inducers so as to cause the body to produce and distribute its own interferon. Certain ribonucleic acids (RNA's) offer hope for high level potency as inducers without adverse effect. The condition for interferon induction by ribonucleic acids appears to be double- or multistrandedness and freedom from inhibitors. These can be of biologic or synthetic origin. The mechanism of action of interferon is not fully understood but appears to fit into the Jacob-Monod model involving two phases: first, a derepression by the inducer to cause the cell to form interferon and second, a derepression by interferon to cause recipient cells to form the active substance which acts by preventing translation from viral messenger RNA. Double or multistranded RNA of viral or other origin appears to be unique to the cell and serves as the alert to it to produce interferon in phase 1. Greatest need for interferon is clearly for those diseases in which there is a multiplicity of immunologic types in excess of the numbers which could be put into a vaccine as, e.g., the common cold and enteric viruses. There might be some overall therapeutic benefit also if inducer were given early enough in infection. Special value for interferon induction might derive by administration in early life before the development of immunologic maturity, as a means for preventing infection with oncogenic or other viruses. Additionally, suitable inducers might be capable of interrupting the reinfection cycle in virus-dependent malignancies. The favorable outlook for interferon utilization must always be tempered with the realization that under certain as yet undiscovered situations, adverse rather than beneficial effects might result from indution of interferon. It is not impossible that in certain special circumstances, as in ordinary immunologic responses, it might be more beneficial to negate rather than to promote the effect.     

Relationship between the Molecular Size of Poly I·Poly C and Its Biological Activity1

Seven polyinosinic·polycytidylic acid (poly I·poly C) preparations, ranging from 4.2 S to 21.2 S, prepared from various sizes of polyinosinate and polycytidylate, were examined for toxicity and interferon-inducing activity in mice. The increase in size of poly I·poly C was accompanied by increases both in the maximal amount of interferon produced and in the length of persistence of a high level of interferon in plasma. Toxicity of poly I·poly C was proportional to the molecular size within the range of 8 S to 16 S. The amount of interferon induced by 1/5 LD₅₀ of poly I·poly C depended on the size of the inducer, being increasingly lower with progressively smaller sizes. Next, activities of poly I·poly C in culture cells were examined. The resistance-inducing activity of poly I·poly C in primary chick embryo cells (CEC) increased with the size of the inducer (4.2 S to 11.6 S), whereas the activity in L cells was not so markedly dependent upon its molecular size as in CEC. In the presence of calf serum during induction of resistance the activity was lowered. The activities of preparations with small molecular sizes were affected by calf serum more markedly than those of large molecular sizes. The interferon-inducing activity in RK13 was not appreciably influenced by the size of poly I·poly C, especially in the presence of DEAE-dextran, while the activity in L cells was markedly dependent upon the size of the inducer. These results suggest that the influence of the molecular size of poly I·poly C upon the resistance-inducing and interferon-inducing activities varies among different kinds of cells, and alters in the presence of serum or DEAE-dextran.     

Induction of xanthine oxidase and depression of cytochrome P-450 by interferon inducers: genetic difference in the responses of mice

Interferon and interferon inducing agents depress hepatic cytochrome P-450 systems. They also induce hepatic xanthine oxidase activity. It has been suggested that free radicals produced by xanthine oxidase may cause the loss of P-450. High titers of serum interferon are induced by poly IC (poly riboinosinic acid.polyribocytidylic acid) in both C57Bl/6J and C3H/HeJ mice; Newcastle disease virus (NDV) induces a high titer of interferon in C57Bl/6J mice but not in C3H/HeJ mice. The induction of xanthine oxidase activity by NDV in C3H/HeJ mice was less than half that seen in C57Bl/6J mice, thus demonstrating a relationship between the induction of xanthine oxidase, the depression of P-450 and a genetically determined difference in responsiveness of mice to interferon inducers.     

Recombinant human interferon sensitizes resistant myeloid leukemic cells to induction of terminal differentiation

Recombinant human leukocyte interferon (IFN-alpha A) inhibits growth of the human promyelocytic leukemic cell line HL-60 without inducing these cells to differentiate terminally. When IFN-alpha A is combined with agents capable of inducing differentiation in HL-60 cells, such as 12-O-tetradecanoyl-phorbol-13-acetate (TPA), cis or trans retinoic acid (RA) or dimethylsulfoxide (DMSO), growth suppression and induction of differentiation are dramatically increased. By growing HL-60 cells in increasing concentrations of TPA, RA, or DMSO, a series of sublines have been developed which are resistant to the usual growth inhibition and induction of differentiation seen when wild type HL-60 cells are exposed to these agents. Treatment of these resistant HL-60 cells with the combination of IFN-alpha A and the appropriate inducer results, however, in a synergistic suppression in cell growth and a concomitant induction of terminal differentiation. The ability of interferon to interact synergistically with agents which promote leukemic cell maturation may represents a novel means of reducing resistant leukemic cell populations.     

Nonspecific porins of the outer membrane of Gram-negative bacteria: Structure and functions

The structure and functional properties of nonspecific porins (β-structured integral proteins of the outer membrane of Gram-negative bacteria) are overviewed. The characteristic features of porin spatial structure related to the principles of β-barrel construction and pore geometry are considered. The data concerning nonspecific diffusion of low-molecular substances and dynamic behavior of porin channels dependent on the distribution of charged amino acid residues in different structural domains of the porin molecule are presented. The methods and approaches used in the study of functional activity of porins are surveyed. The data on modulation of pore-forming activity of these proteins by external factors and membrane components are considered separately.     

RNase F and 2′,5′-oligoA synthetase activities in mice after poly(I). poly(C) administration

The present study demonstrates the presence of considerable levels of 2′, 5′-oligoA synthetase activity in tissue extracts from mice. The interferon inducer, poly(I) .poly(C) , induced the synthetase activity in all the tissue extractsin vivo. Similarly, a significant amount of endonuclease RNase F activity is found to be present in these tissue extracts. But interferon induction does not seem to have any significant effect on RNase F activity.     

Induction of interferon by transformed cells: inhibition by retinoic acid

Retinoic acid (RA) inhibited transformed mouse L-929 and human WISH cell induction of interferon alpha/beta production by nonsensitized mouse spleen cells. The RA effect was both time and dose dependent and acted in near physiologic concentrations. The results suggest that the effect is due to a modulation of a previously described transformed cell surface associated glycoprotein IFN inducer.     

Poly(A) polymerase specifically implicated in the mechanism of chemotherapeutic drug action during cell apoptosis

It has recently been established that most anticancer drugs act through the mechanism of apoptosis. It has also been clinically confirmed that drug combinations are more effective than single drugs and various chemotherapeutic strategies have therefore been developed. The experiments described here concern the induction of apoptosis with dimethylsulfoxide (DMSO), a substance with multiple activity especially as an inducer of differentiation, and interferon (IFN), a cytokine well known for its antiviral and antineoplastic effects; they are used alone or in combination. Apoptosis may be regulated at all levels of gene expression including the addition of the poly(A) tail to the 3' end of mRNAs. Poly(A) polymerase (PAP) [EC.2.7.7.19], the enzyme that catalyzes the addition of the poly(A) tail to mRNAs, changes in the process of development, differentiation, transformation and apoptosis. In the present study the induction of HeLa cells to apoptosis (65%) with a DMSO/rIFN-alpha combination resulted in pronounced PAP dephosphorylation and activity reduction. HeLa cells induced to apoptosis (35%) with DMSO gave lower levels of PAP dephosphorylation and reduction of activity and cells induced to apoptosis (18%) with rIFN-alpha gave only limited PAP dephosphorylation and reduction of activity. The implications of these observations for chemotherapeutic drug action at the level of mRNA polyadenylation point to the possible use of PAP as a biological marker for the evaluation of this action.     

Control of Interferon Synthesis: Effect of Diethyl-aminoethyl-Dextran on Induction by Polyinosinic-Polycytidylic Acid

Interferon production in cultures of rabbit kidney cells (RKC) stimulated with 10 to 250 mug of polyinosinic-polycytidylic acid (poly I.poly C) per ml peaked at 3 to 4 hr after the exposure of cells to inducer and rapidly declined thereafter. On the other hand, RKC stimulated with poly I.poly C (10 or 2 mug/ml) in the presence of diethylaminoethyl (DEAE)-dextran (100 or 20 mug/ml, respectively) produced a protracted interferon response, with the release of interferon continuing for over 24 hr. The kinetics of interferon production in RKC stimulated with lower concentrations of the mixture of poly I.poly C and DEAE-dextran were similar to the response produced by poly I.poly C alone (10 to 250 mug/ml). Only the responses that terminated early were paradoxically enhanced by treatment with low doses of actinomycin D or with cycloheximide. Cells stimulated with 50 mug of poly I.poly C/ml showed hyporesponsiveness to a second interferon induction with poly I.poly C when restimulated 7 hr after primary induction. This hyporesponsiveness could be overcome by restimulating with higher concentrations of the poly I.poly C-DEAE-dextran complex. The results are compatible with the hypothesis that the early termination of interferon production and hyporesponsiveness to repeated induction with poly I.poly C are due to a cellular repressor exerting negative control on interferon synthesis, and that the increased cellular uptake of poly I.poly C in the presence of DEAE-dextran may effectively neutralize the repressor. These results also suggested that the often observed different kinetics and the varied effects of inhibitors of ribonucleic acid or protein synthesis on interferon responses in various cells and in cells stimulated with different inducers (such as with viruses as compared with polynucleotides) need not imply the existence of fundamentally different mechanisms of interferon production.     

Characteristics of the factors that suppress and stimulate interferon production

A repressor of interferon production is contained in the hyaloplasm of the chick embryo fibroblast cells in the state of hyporeactivity. A factor stimulating interferon production (FSIP) was found in the hyaloplasm of the cells subjected to single or double induction with poly (pI) x poly (pC) followed by exposure to actinomycin D. Both preparations were of the protein nature and possessed high biological activity. They repressed or stimulatd interferon production at a dilution of 1:512-1:1024. The preparations had tissue and inductor specificity, did not affect the Venezuelan equine encephalomyelitis virus and interferon antiviral activity. Unlike the repressor, the FSIP proved to be thermolabile and pH-sensitive in acid media. The half lives of the repressor and stimulator were about 10 and 5 hours respectively.     

Prevention of the disturbance of protein synthesis is a possible mechanism of the interferon protective activity.

Interferon and interferon inducer (Newcastle disease virus), were shown to enhance the cell resistance against the damaging effects of streptomycin. The preliminary intravenous injection of NDV to mice resulted in a diminishing of both qualitative and quantitative changes in activity of the enzyme myeloperoxydase caused by streptomycin in leucocytes from peritoneal exudate. Protective effect was conferred also by immediate pretreatment of mouse leucocytes with homologous interferon. The data presented suggest that protective action of interferon involves the control of normal protein synthesis in the cell.     

Human fibroblast interferon. An improved purification

Human fibroblast interferon has been purified 2,900-fold to homogeneity. The purification is achieved in two steps by chromatography on blue Sepharose. The specific activity of the homogeneous interferon is 5 X 10(8) units/mg and the yield of biological activity has ranged from 20-40%. The interferon can exist as a monomer (Mr = 20,000) and as a dimer (Mr - 40,000). The dimer can be converted to the monomer by heating in sodium dodecyl sulfate and thioglycolic acid.