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.     

Virus replication and high-titered interferon production in human leukocyte cultures inoculated with Newcastle disease virus

Wheelock, Frederick E. (Western Reserve University, Cleveland, Ohio). Virus replication and high-titered interferon production in human leukocyte cultures inoculated with Newcastle disease virus. J. Bacteriol. 92:1415-1421. 1966.-High titers of interferon (20,480 culture-protecting units per ml) are produced in freshly prepared human leukocyte cultures inoculated with a Newcastle disease virus (NDV)-cell multiplicity of 1:1. NDV replicates to low titers in these cultures. Incubation of leukocytes at 37 C for 24 hr prior to inoculation of NDV results in almost complete loss of detectable interferon production, but virus replicates to higher titers than in the freshly prepared cultures. In contrast, no diminution of interferon production in response to phytohemagglutinin (PHA) occurs on 24 hr of incubation of cultures prior to addition of PHA. Experiments with cultures of predominantly pure cell fractions of peripheral blood indicate that the lymphocyte fraction produces interferon in response to either NDV or PHA, and that polymorphonuclear leukocytes produce no interferon in response to these agents. These studies suggest a hitherto unsuspected ability of human lymphocytes to produce high titers of interferon in vivo.     

Plaque Development and Induction of Interferon Synthesis by RMC Poliovirus.

Johnson, Terry C. (University of Minnesota, Minneapolis), and Leroy C. McLaren. Plaque development and induction of interferon synthesis by RMC poliovirus. J. Bacteriol. 90:565-570. 1965.-Plaque development by RMC poliovirus on human amnion cell monolayers was investigated with regard to autointerference and to the effect of acid-agar overlay on plaquing efficiency. The virus was inhibited by acid-agar overlay, thereby exhibiting the d(-) marker typical of attenuated poliovirus strains. In addition, a lack of RMC poliovirus plaque development on HeLa cell monolayers was shown to be the result of an agar inhibitor which could be removed by NaCl extraction. By use of a simplified plaque reduction assay, it was shown that interferon production was responsible for the autointerference phenomenon. Interferon synthesis did not correlate with the ages in vitro of human amnion cell cultures. Fibroblasts originating from the chorionic membrane produced negligible amounts of the inhibitor. Interferon synthesis by human amnion cells infected with RMC poliovirus was inhibited by actinomycin D. The addition of guanidine hydrochloride to infected cultures immediately after RMC poliovirus adsorption markedly inhibited interferon synthesis, although after 2 hr (postadsorption) guanidine had no effect on interferon production.     

The effect of colony stimulating factor on the synthesis of ribonucleic acid by mouse bone marrow cells in vitro.

The effect of granulocyte-macrophage colony stimulating factor (GM-CSF) on the synthesis of RNA in liquid cultures of mouse bone marrow, spleen, thymus, peritoneal, peripheral blood leukocytes and lymph node cells was investigated. GM-CSF appeared to stimulate RNA-synthesis in syngeneic bone marrow cells within ten minutes of adding it to the culture. In the presence of GM-CSF bone marrow cultures maintained their initial rate of RNA synthesis for approximately ten hours. GM-CSF had no apparent effect on the uptake of 3H-uridine into bone marrow cells. This stimulation was still observed in the presence of puromycin and cycloheximide, but was abrogated by actinomycin D. The magnitude of the stimulation was not affected by the density of cells between 1 and 20 x 10(6) cells/ml but was slightly smaller at 0.1 and 40 x 10(6) cells/ml. Increasing concentration of GM-CSF (up to 2 X 105 units per ml) led to increased stimulation of RNA synthesis in bone marrow cells, but a significant stimulation could be detected at concentrations as low as 800 units/ml. GM-CSF did not significantly stimulate RNA synthesis in spleen, thymus, mesenteric or subcutaneous lymph node cells. However a small stimulation was observed in peripheral blood leukocytes and peritoneal cells. Autoradiographic studies showed that GM-CSF stimulated RNA synthesis in blast cells, myelocytes, metamyelocytes and polymorphs. Nucleated erythroid cells showed no increased labeling with GM-CFS. Labeling in lymphoid-like cells was highly variable but the level of labeling did not appear to be influenced by GM-CSF.     

Biosynthesis and main biological properties of human gamma interferon

Conditions for and regularities of gamma-interferon production were elucidated. High interferon inducing activity of the known inductors such as concanavalin A, phytohemagglutinin and lentil lectin was asserted. It was shown that aqueous and alcoholic extracts of legumes seeds were also able to induce interferon synthesis in cultures of human peripheral blood leukocytes. By physicochemical properties such as stability to acids and liability to heating and by antigenic properties, interferon produced under such conditions was of type 2 (gamma). The maximum yield of interferon was observed in stationary and roller leukocyte cultures at a density of 2.10(6)-4.10(6) cells/ml on commercial rich media (IMDM and Eagle medium). Dynamics of gamma-interferon biosynthesis was determined. The peak of interferon production after the leukocyte induction with plant lectins was recorded in 72-96 hours.     

Rapid Sensitive Assay for Interferons Based on the Inhibition of MM Virus Nucleic Acid Synthesis

A method for assaying mouse interferon based on the inhibition of viral ribonucleic acid (RNA) synthesis was devised. The amount of MM virus and RNA synthesized in interferon-treated L-cell cultures was determined by measuring the amount of (3)H-uridine converted into a trichloroacetic acid-insoluble form after treatment of the infected cultures with 2.5 mug of actinomycin D per ml. The amount of RNA synthesized was inversely related to the concentration of interferon used for treatment. A linear dose-response regression curve was obtained by plotting the log of the amount of RNA made, expressed as a percentage of the control, versus the log of the reciprocal of the interferon dilution. A unit of interferon was defined as that concentration which inhibited nucleic acid synthesis by 50% (INAS(50)). The concentration of mouse interferon could be determined within 24 hr. This assay method, on the average, was approximately half as sensitive as the method which measured the 50% reduction of MM virus plaque number (PDD(50)-MM method), but was, on the average, almost 1.7 times as sensitive as the PDD(50)-VSV method. It averaged approximately 20 times the sensitivity of the methods which used as end points the 70% reduction in yield of MM virus or the complete inhibition of cytopathic effect by MM virus. The reproducibility of the INAS(50) technique was tested in two ways. (i) Four independent assays of an interferon specimen were performed with replicate cultures. The standard deviation was 11.2% of the mean titer. (ii) On different dates, one interferon specimen was assayed seven times and another was assayed four times. The standard deviations were 21.5 and 26.6% of the respective mean titers.     

Effect of Puromycin and Actinomycin D on a Persistent Mumps Virus Infection In Vitro

Puromycin and actinomycin D were used to treat a line of human conjunctiva cells persistently infected with mumps virus (C-M cells) in order to determine where virus synthesis is inhibited. Although 90% of the cells in C-M cultures are infected, little or no infectious virus is produced by most cells in a growing culture. Adding puromycin to inhibit protein synthesis resulted in the production of infectious virus. Thus, all the viral proteins needed for virus completion were made in the growing cells. When actinomycin D was added to growing cells, infectious virus was again produced. Since mumps virus synthesis is actinomycin D-insensitive, this suggested a host control of the virus. Interferon was not detected. The possible mechanisms of host control are discussed.     

Poly (adnenosine diphosphoribose) synthase activity of isolated nuclei of normal and leukemic leukocytes.

Poly(adenosine diphosphoribose) (ADPR) synthase activities of nuclei isolated from normal human and leukemic leukocytes were assayed by incubation with radioactive NAD+. The synthase activity of leukemic leukocyte nuclei was significantly higher than that of normal leukocyte nuclei. The average length of polymers formed by isolated leukemic nuclei under the prescribed experimental condition ranged from 3.1 to 5.3 ADPR residues per chain, while those produced by normal leukocytes nuclei was 1.7 and 2.6 residues per chain. Isolated leukemic and normal leukocyte nuclei were incubated with and without NAD+ and the ability to carry out DNA synthesis was measured. The endogenous DNA synthesis of NAD-treated and untreated nuclei was the same. This finding parallels the result obtained with Novikoff hepatoma cell nuclei and differs from the observation with rat liver or testis nuclei.     

Interferon priming. Effects on interferon messenger RNA.

The effects of priming mouse cells with interferon on the production of interferon and its mRNA were investigated. Interferon-treated (primed) mouse L929 cells produce 3 to 10 times more interferon than do nonprimed cells following induction with Newcastle disease virus. Interferon appears 2 to 4 h sooner in the primed cultures than in nonprimed cultures and interferon production by primed cells becomes resistant to inhibition by actinomycin D about 4 h sooner than interferon production in nonprimed cells. Interferon mRNA is detected in primed-induced cells about 2 h earlier than in nonprimed-induced cells. It reaches peak levels about 2 to 4 earlier in primed cells, but it also disappears sooner in primed cells. The total amounts of interferon mRNA isolated from primed-induced cells and nonprimed-induced cells were indistinguishable, by the methods utilized. Therefore, although primed cells can produce significantly more interferon and make interferon mRNA sooner than nonprimed cells, the total amount of interferon mRNA produced is apparently not increased, nor is its half-life prolonged in primed cells. Thus, enhanced interferon production in primed cells may result from enhanced efficiency of translation of interferon mRNA in the primed cells.     

A modified matrix perfusion-microcarrier bead cell culture system. II. Production of human (beta) interferon in a matrix perfusion system

Addition of microcarrier beads to a matrix perfusion cell culture system allowed growth of anchorage dependent human foreskin fibroblasts which would not grow in the culture units alone. The utility of the system for collection of cellular products was demonstrated by the induction and harvesting of human (beta) interferon. Interferon production was highest in perfusion cultures when medium was circulated throughout the induction and when inducer containing 100 mug/mL polyriboinosinic: polyribocytidylic acid was placed directly in contact with cells in the extracapillary space. These conditions provided 4-to-10-fold greater interferon yields per cell, and approximately 12-fold increases per vessel, than monolayer cultures. Perfusion grown cells produced interferon at a maximal level for 20 h postinduction compared to approximately 2 h for monolayer grown cells, thus giving a higher total yield of interferon. Other procedures increasing the efficiency of the system included priming with 50 U/mL interferon standard, reinduction of cells, use of antibiotic free medium, reduced serum concentrations, and in vitro aging of the cells.     

Specific Role of Each Human Leukocyte Type in Viral Infections I. Monocyte as Host Cell for Vesicular Stomatitis Virus Replication In Vitro

Each major leukocyte type of the peripheral blood of healthy donors was studied in vitro for its ability to support vesicular stomatitis virus (VSV) replication. Purified cultures of each white blood cell type were prepared by the selective adsorption and elution of cells from silicone-treated glass beads. It was found that monocytes and macrophages (derived from the rapid transformation of monocytes in vitro) were the principal host cells for VSV replication. Interferon added to mixed leukocyte cultures, prior to virus inoculation, reduced virus yields and prevented destruction of macrophages. Cultures of small lymphocytes, containing no detectable monocytes or macrophages, produced amounts of virus equivalent to 1% of that produced in leukocyte cultures which contained 7% monocytes. Small lymphocytes did not undergo demonstrable cytopathic alterations in virus-infected cultures. VSV neither replicated nor produced cytopathic effects in polymorphonuclear leukocytes.     

Interferon Action on Parental Semliki Forest Virus Ribonucleic Acid

Actinomycin D-treated chick fibroblasts were infected with purified (32)P-labeled Semliki forest virus, and ribonucleic acid (RNA) was extracted after 1 or 2 hr. Within 1 hr, viral RNA forms sedimenting in sucrose gradients at 42S, 30S, and 16S were present. The 42S form corresponded to the RNA of the virion. The 16S form appeared to be a double-stranded template for the formation of new viral RNA, since nascent RNA was associated with it and the molecule could be heat-denatured and subsequently reannealed by slow cooling. Interferon treatment before infection, or puromycin (50 mug/ml) or cycloheximide (200 mug/ml) added at the time of virus infection, had no effect on the formation of the 30S RNA but inhibited the production of the 16S form. Several findings made it unlikely that these results were due to breakdown of parental RNA and reincorporation of (32)P into progeny structures. The results suggested that the mechanism of interferon action involves inhibition of protein synthesis by parental viral RNA, since a specific viral RNA polymerase had previously been demonstrated to be necessary for production of 16S RNA. No protein synthesis appears necessary for formation of 30S RNA from parental virus RNA.     

鱼类培养细胞干扰素的诱导

对紫外线灭活的草鱼出血病病毒（ＧＣＨＶ）－Ｆ９株,在几种鲤科鱼类培养细胞中诱导产生干扰素的能力及影响干扰素产量的各因素进行了研究。纯化的ＧＣＨＶ在紫外线照射５分丧失感染性,但获得了在ＣＡＢ等５种鲤科鱼类培养细胞中高铲诱导产生干扰素的能力。干扰素的诱导需要病毒高复数感染细胞。干扰素主要在诱导后１４小时时内产生。培养上清中的新生牛血清对干扰素的产量有抑制作用。而在ＰＨ６．２－７．８范围内对干扰素产量无     

Modulation of the human in vitro antibody response by human leukocyte interferon preparations

The ability of human leukocyte Interferon to modulate the plaque-forming-cell response of human peripheral blood leukocytes to horse red blood cells was examined. Human peripheral blood mononuclear cells were cultured in vitro with the addition of varying doses of human leukocyte interferon 24 hr prior to, simultaneously with, and 24 hr after sensitization of the cultures with horse red blood cells. Plaque-forming-cell responses were measured 5 days after sensitization with antigen using poly-L-lysine-coupled horse red blood cell monolayers. When human leukocyte interferon preparations were added 24 hr prior to sensitization with antigen, a significant enhancement of the plaque-forming-cell response was observed. When the interferon was added simultaneously with antigen, the plaque-forming-cell response was significantly suppressed. Therefore, human leukocyte interferon appears to have a time-dependent immunomodulatory activity. The kinetics of immunomodulation appear to be different from those of previously described mouse models.     

Suppression of in vitro antibody response by ribosome-associated factor(s) from interferon-treated cells.

Initiation factor preparation (eIF-IF) from mouse L cells treated with virus-type interferon suppressed the in vitro plaque-forming cell (PFC) response to sheep red blood cells. The eIF-IF preparation had previously been shown to block formation of the ternary complex Met-tRNA_f-eIF-GTP. The formation of this complex is a necessary step in initiation of protein synthesis. Initiation factor preparation (eIF) from untreated L cells affected neither the PFC response nor the participation of eIF in the formation of ternary complex. The induced factor was shown not to be Interferon by antibody neutralization experiments with anti-interferon. The factor must be present in the PFC cultures during the early stages of antigen induction in order to suppress the immune response. Speculatively, eIF-IF may act at the level of the macrophage, perhaps entering the cell by pinocytosis. This may account for its inability to inhibit virus replication in L cells. The production of the inhibitory factor is blocked or partially blocked by actinomycin D. It is possible that this factor is a mediator of the immunosuppressive effects of virus-type interferon. This is the first report of biological activity on cells, which is associated with a ribosome-associated factor induced by interferon.     

Human interferon production with diploid fibroblast cells grown on microcarriers.

A variety of diploid human fibroblast lines have been successfully grown to high densities (greater than 10(6) cell/ml) on recently developed microcarriers. Interferon induction using poly I.poly C and a superinduction procedure resulted in yields greater than 10,000 units/ml with one cell line. A direct comparison of microcarrier cultures to roller bottle cultures showed equivalent interferon yields on a per cell basis and some apparent differences relating to optimum inducer concentrations and kinetics of interferon accumulation.     

Inhibition by actinomycin D of ribosomal RNA synthesis in the presynthesis period of the mitotic cycle of Chinese hamster cell cultures]

Using radioautographic technique actinomycin D at a concentration of 0.08 mug/ml was shown to inhibit selectively ribosomal RNA (rRNA) synthesis in monolayer cultures of Chinese hamster cells. The treatment with actinomycin D of cells synchronized by mitotic selection in the beginning of the G1 period causes a delay in the onset of DNA synthesis. However, a similar treatment in the late G1 period does not prevent cells from entering the S-period. The same effect has been produced by 9 mug/ml lucanthone, another inhibitor of rRNA synthesis. The experiments demonstrate a pronounced difference in cell reaction to the depression of rRNA synthesis in early and late G1 period. The data imply that the formation of rRNA, essential for the initiation of DNA synthesis, is accomplished in the first half of the G1 period, while part of rRNA has been already formed in the previous cycle.     

Interference of a human leukocyte interferon preparation with stimulatory activities in leukocyte-conditioned medium for human hematopoietic stem cells

Medium conditioned by leukocytes in the presence of phytohemagglutinin (PHA-LCM) promotes the growth of multilineage hemopoietic progenitors derived from human bone marrow. However, PHA-LCM prepared in the presence of a human leukocyte interferon preparation does not support mixed colony formation. Crude PHA-LCM preparations were characterized by gel filtration, affinity chromatography, and gel electrophoresis. The elution profile on Sephacryl S-300 of PHA-LCM prepared without interferon showed a distinct peak that stimulated the growth of pluripotent stem cells (CFU-gemm) and committed precursors (CFU-c, BFU-e). Gel filtration of PHA-LCM, prepared with 1000 U/ml of interferon, revealed a change in the elution profile. The eluted material demonstrated no growth-promoting activities. We conclude that the abolished stimulatory activity of PHA-LCM, prepared with human leukocyte interferon, might be due to a reduced production of stimulatory molecules, suggesting that interferon interferes with the molecular events required for colony formation of committed and noncommitted hemopoietic progenitors.     

Influence of Macromolecular Biosynthesis on Cellular Autolysis in Streptococcus faecalis

The addition of several different antibiotics to growing cultures of Streptococcus faecalis, ATCC 9790, was found to inhibit autolysis of cells in sodium phosphate buffer. When added to exponential-phase cultures, mitomycin C (0.4 mug/ml) or phenethyl alcohol (3 mg/ml) inhibited deoxyribonucleic acid synthesis, but did not appreciably affect the rate of cellular autolysis. Addition of chloramphenicol (10 mug/ml), tetracycline (0.5 mug/ml), puromycin (25 mug/ml), or 5-azacytidine (5 mug/ml) to exponential-phase cultures inhibited protein synthesis and profoundly decreased the rate of cellular autolysis. Actinomycin D (0.075 mug/ml) and rifampin (0.01 mug/ml), both inhibitors of ribonucleic acid (RNA) synthesis, also reduced the rate of cellular autolysis. However, the inhibitory effect of actinomycin D and rifampin on cellular autolysis was more closely correlated with their concomitant secondary inhibition of protein synthesis than with the more severe inhibition of RNA synthesis. The dose-dependent inhibition of protein synthesis by 5-azacytidine was quickly diluted out of a growing culture. Reversal of inhibition was accompanied by a disproportionately rapid increase in the ability of cells to autolyze. Thus, inhibition of the ability of cells to autolyze can be most closely related to inhibition of protein synthesis. Furthermore, the rapidity of the response of cellular autolysis to inhibitors of protein synthesis suggests that regulation is exerted at the level of autolytic enzyme activity and not enzyme synthesis.     

Inhibition of Arbovirus Protein Synthesis by Interferon

Infection of cells treated with guanidine and actinomycin D and then washed to remove the guanidine inhibition of virus growth had no effect on antiviral activity already established by interferon. Protein synthesis in interferon-treated cells infected under these conditions was decreased as compared to control cells similarly treated but not exposed to interferon. In these control cells, analysis by polyacrylamide gel electrophoresis indicated that six proteins were produced during the first hour after guanidine reversal. Five of these proteins have been previously identified as probably being viral in origin. In interferon-treated cells, only a single major protein was produced. Ribonucleic acid (RNA) synthesis by Semliki Forest virus during the first hour after guanidine reversal was markedly depressed by incubation at 42 C, but no inhibition of total virus protein synthesis was seen; this finding suggested that much of the virus protein produced in the first hour after guanidine reversal was carried out by input virus RNA. Interferon was fully active in cells incubated at 42 C. The results suggested that interferon inhibits the production of Semliki Forest virus proteins ordinarily produced under the direction of the virus genome.