Enzymatic modifications of human fibroblast and leukocyte interferons

The sensitivity of highly purified human fibroblast interferon and partially purified human leukocyte interferon to several proteolytic and glycolytic enzymes was determined with respect to antiviral activity, isoelectric point, molecular weight, and thermal stability. Leucine aminopeptidase altered the distribution of isoelectric points for both interferons but produced little change in molecular weights; this enzyme somewhat reduced the activity of only leukocyte interferon. Treatment of fibroblast interferon with carboxypeptidases A and B did not greatly decrease antiviral activity, but it did slightly reduce the molecular weight of the interferon and substantially altered the distribution of isoelectric point values; similar treatment of leukocyte interferon caused some loss in activity, especially of the 17,000-molecular-weight species. Both interferons were inactivated rapidly by treatment with the endoproteases trypsin, pepsin, bromelain, and subtilisin. Chymotrypsin shifted the isoelectric points of both interferons, but only leukocyte interferon was significantly inactivated. Treatment with neuraminidase and beta-galactosidase changed the isoelectric point distribution but did not affect the activity or thermal stability of either interferon; such a treatment reduced the molecular weight of fibroblast interferon and the size heterogeneity of leukocyte interferon. Treatment with neuraminidase and then leucine aminopeptidase greatly reduced the activity of both interferons, especially leukocyte interferon. The data indicate that biologically active forms of fibroblast and leukocyte interferons can be distinguished by their relative sensitivity to certain proteases.     

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.     

Molecular structure of human fibroblast and leukocyte interferons: probe by lectin and hydrophobic chromatography.

Structural differences between human leukocyte virus-induced interferon and human fibroblast polyinosinic-polycytidylic acid (rIn-rCn)-induced interferon have been noted in previous studies. This study reports the behavior of human leukocyte and fibroblast interferon, induced by virus and by rIn-rCn, in several lectin and hydrophobic chromatographic systems. Differences in both glycosylation and in hydrophobicity of human leukocyte and fibroblast interferons are documented. Human fibroblast interferon is a glycoprotein, whereas our evidence suggests that human leukocyte interferon probably is not. Also, fibroblast interferon is more hydrophobic than leukocyte interferon, as probed on several hydrophobic adsorbents. The possible relationships of these differences to each other and to antigenic variations are discussed. Generally, the differences appear to be attributable to the cell type in which the interferon was induced. However, our results suggest that at least subtle differences in the processing of the induction signal (virus or rIn-rCn) within the same cell type may occur, slightly altering some structural features.     

Purification of acid ethanol-extracted human lymphoid interferons by Blue Sepharose chromatography.

Human leukocyte and lymphoblastoid (Namalva) interferons were purified by a modified acid ethanol extraction procedure and chromatography of the dilute ethanolic interferon solution on Blue Sepharose. Both interferons were purified more than 1000-fold, with recoveries ranging from 35 to 40%.     

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.     

Interferon treatment reduced adherence, invasiveness and intracellular multiplication of Shigella flexneri in coxsackie B1 virus-infected cells.

The effect of interferon treatment on interaction of Shigella flexneri with in vitro cultured cells was investigated. Pretreatment of HEp-2 cells with human interferons had no effect on the susceptibility of cells to S. flexneri, measured by invasiveness and adhesiveness. Human leukocyte interferon and human recombinant interferon-alpha-A reduced adhesiveness, intracellular multiplication and invasiveness of S. flexneri in HEp-2 cells preinfected with coxsackie B1 virus. Also non-receptor mediated-phagocytosis was reduced by interferon treatment in virus infected cells. The interferon effects were dependent on continuous protein synthesis, because they were not expressed when cycloheximide or abrin was added to the virus infected cell cultures. No effect of interferon was detected on intracellular content of Na+ or K+, Na(+)-K+ activated ATPase activity or cytoplasma membrane polarity, in virus infected or control cell cultures. The interferon effect on bacterial invasiveness seems to be dependent on an interferon receptor interaction on cytoplasma membrane level because directly microinjected interferon showed no effect.     

Human leukocyte interferon has no structural or biological relationship to corticotropin

In view of recent reports that certain preparations of human leukocyte interferons are structurally and biologically related to the pituitary hormones corticotropin (ACTH) and β-endorphin, we have investigated the properties of two human leukocyte interferons (IFN-α) prepared by recombinant DNA technology. The antiviral activities of purified IFN-αA and IFN-αD were not affected by a large molar excess of ACTH antiserum nor did ACTH interfere in interferon immunoassays. Neither IFN-αA, IFN-αD nor pepsin digests of these proteins were able to stimulate steroidogenesis in adrenocortical cells. There was no cross reaction between ACTH antiserum and the two leukocyte interferons or the pepsin digests of the interferons. These results cast doubt on recent proposals that some of interferon's biological effects are mediated by ACTH or β-endorphin-related fragments of the interferon molecule.     

Some species of human leukocyte interferon are glycosylated

The carbohydrate content of all of the species of human leukocyte interferon (IFN-alpha) which have been derived from patients with chronic myelogeneous leukemia (CML) and purified to homogeneity has now been determined. Amino sugar content was measured by high-performance liquid chromatography and fluorescamine detection of acid hydrolysates of each sample. Two species showed significant amounts of glucosamine. Most of the purified species of leukocyte interferon from a myeloblast cell line were also tested, and two species were found to contain sugar residues. These forms also differed from the CML interferons in that they revealed the presence of greater amounts of galactosamine. The apparent lack of carbohydrate in some of the higher-molecular-weight species of interferon implicated factors other than glycosylation in the molecular weight differences. The results indicate that some species of IFN-alpha are glycosylated to various degrees.     

Microsequence analysis of peptides and proteins: IV. Structural studies on human leukocyte interferons

The sequence of the tryptic peptides of three major species of human leukocyte interferon was determined by microsequencing procedures. The peptides were aligned by comparison with the amino acid sequences predicted by the DNA sequences of recombinants containing leukocyte interferon-coding inserts. In addition, extended NH₂-terminal amino acid sequences of two human leukocyte interferons produced in Escherichia coli by recombinant DNA methodology are also reported. This report demonstrates application of microsequencing methodology to low nanomole and subnanomole amounts of proteins and peptides of biological interest.     

The nucleotide sequence of a cloned human leukocyte interferon cDNA

We have determined the nucleotide sequence of the human leukocyte interferon cDNA carried in hybrid plasmid Z-pBR322(Pst)/HcIF-2h, which has been shown to direct the formation of a polypeptide with human leukocyte interferon activity (Nagata et al., 1980). The 910 base pair insert contains a 567 (or 543) base pair coding sequence, which determines a putative preinterferon polypeptide consisting of a signal peptide of 23 (or less likely 15) amino acids, followed by an interferon polypeptide of 166 amino acids (calculated molecular weight, 19 390). The coding sequence is preceded by a (most likely incomplete) 56 bp leader and followed by a 242 bp trailer and seven A residues from the poly(A) tail: A comparison of the sequence of 35 amino terminal amino acids of lymphoblastoid interferon (Zoon et al., 1980; M. Hunkapiller and L. Hood, personal communication) and the corresponding sequence deducted for leukocyte interferon revealed 9 differences. This suggests that these two interferons are encoded by two non-allelic genes.     

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.     

Enhancement of T cell cytotoxic responses by purified human fibroblast interferon.

Purified polyribonucleotide-induced human fibroblast interferon (HFIF) was tested for its effects on proliferative and cytotoxic human T cell responses to alloantigens. The addition of HFIF (100 to 400 IFU/ml) to mixed leukocyte cultures decreased alloantigen-induced lymphocyte proliferative responses as determined by both recovery of responding cells and by 3H-thymidine incorporation into responding cells. However, HFIF, but not the mock interferon preparation, increased the cytotoxic response of T cells to allogeneic cells by 4- to 5-fold when expressed in terms of lytic units. Although fibroblast and leukocyte interferons have different physicochemical and biologic properties, the results reported here are in concert with previous findings concerning the effects of virus-induced leukocyte interferon on human T cell functions.     

Antibody to staphylococcal enterotoxin A-induced human immune interferon (IFN gamma)

Antiserum to human gamma interferon (IFN gamma) was produced in rabbits immunized with partially purified (10(4.8) to 10(6.2) antiviral U/mg protein) staphylococcal enterotoxin A-induced IFN gamma. Staphylococcal enterotoxins, phytohemagglutinin M, concanavalin A, and pokeweed mitogen-induced antiviral activity in human leukocyte cultures was neutralized to undetectable levels by the antiserum. However, human leukocyte interferon (IFN alpha), human fibroblast interferon (IFN beta), and mouse interferons were not neutralized by the antiserum. After determining the antiserum was specific for IFN gamma and did not neutralize other known types of interferon, it was used with antibody to human IFN alpha to demonstrate the type(s) of interferon stimulated by some new inducers and antigens. Galactose oxidase- and calcium ionophore-induced interferons were neutralized to undetectable levels by the antiserum to IFN gamma. Interferon produced in leukocyte cultures from tuberculin-negative individuals stimulated with tuberculin-purified protein derivative or old tuberculin was IFN alpha, whereas interferon from tuberculin-positive individuals was a combination of alpha and gamma IFN. In addition, the antiserum neutralized the anticellular and natural killer cell enhancement activities of IFN gamma preparations. The specificity of this antiserum for IFN gamma indicates that it is an additional, powerful tool for identifying and classifying known and new interferons produced in vitro or in vivo and for investigating the role(s) of IFN gamma during the course of infectious, neoplastic, and autoimmune diseases.     

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.     

Antiviral and antiproliferative activity of human interferons and their induction of 2',5'-oligoadenylate synthetase

Native preparations of alpha, beta and gamma-interferons as well as recombinant beta-interferon and purified leukocyte alpha-interferon and purified leukocyte alpha-interferon exert antiviral and antiproliferative activity in CaOv cells. Native interferon preparations were shown to be more antiproliferative than purified interferons per unit of antiviral activity (with EMC as well as with less susceptible VSV used as test viruses). It was shown that level of 2'5' oligoadenylatesynthetase activity induction in general correlates with antiproliferative and pronounced antiviral activity of interferons, besides that, the earlier (by 11 hours) induction of the enzyme activity by beta-interferon correlates with more rapid expression of antiproliferative effects by this interferon in comparison with that of alpha-interferon, the latter inducing the peak of enzyme activity by 24 hours.     

Antiviral and protein-inducing activities of recombinant human leukocyte interferons and their hybrids.

The antiviral activities of recombinant human leukocyte interferons IFN-alpha A and IFN-alpha D as well as five hybrids of these interferons against retroviruses, vesicular stomatitis virus, and encephalomyocarditis virus were studied in feline, human, and murine cells. Although these interferon species had widely different potencies, their activities against these viruses were, in general, proportional. The IFN-alpha A/D (Bgl) hybrid was the most potent species, and the IFN-alpha D/A (Bgl) hybrid was the least potent. However, the latter species did not interfere with the action of the former species. Like natural human leukocyte interferon, each of the seven species of recombinant interferons induced the synthesis of at least five proteins in human fibroblasts, whereas induction of only one such protein was readily detected in a feline fibroblast line in which these interferon species inhibited the replication of all three viruses.     

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.     

Human interferon enhances gunaylate cyclase activity

Partially purified human leukocyte interferons, partially purified human lymphoblastoid interferon, and human fibroblast interferon enhanced rat liver, kidney, and splenic guanylate cyclase {E.C.4.6.1.2.} activity 2–4 fold at 5 μIU concentration. Dose-response relationships revealed that the human leukocyte interferons enhanced splenic guanylate cyclase activity at concentrations as low as 0.01 μIU while a concentration of 1 μIU for partially purified human lymphoblastoid interferon and 10 μIU concentration for human fibroblast interferon were necessary to see any effect on guanylate cyclase activity.     

Molecular weight of the functional unit of human leukocyte, fibroblast, and immune interferons

There is good agreement between the target molecular weight and the known molecular weight of human leukocyte interferons (about 20,000). The target molecular weight of fibroblast interferon, 31,000 to 42,000, is significantly larger than the monomer molecular weight of 21,000 to 24,000, suggesting that the dimer may be the predominant active functional unit in solution. A range from 63,000 to 73,000 for the target molecular weight of several different fractions of immune interferon (including natural crude as well as the recombinant form) indicates that the functional form of the immune interferon may be a trimer or tetramer. Thus, these studies indicate that the functional unit of leukocyte interferon is the monomer, that of fibroblast interferon is a dimer, and that of immune interferon is probably a tetramer (or trimer).     

Hybrid recombinant human leukocyte interferon inhibits differentiation in murine B-16 melanoma cells

We have investigated the effects of recombinant human leukocyte interferons (IFN-alpha A and IFN-alpha D) and various hybrid recombinant human leukocyte interferons on differentiation in B-16 mouse melanoma cells. Inhibition of both spontaneous and melanocyte hormone stimulated differentiation was observed with one hybrid construct, IFN-alpha A/D (Bgl) consisting of amino acids 1 to 62 from IFN-alpha A and amino acids 64 to 166 from IFN-alpha D. In contrast, the parental human interferons, IFN-alpha A and IFN-alpha D, when used alone or in combination, as well as other hybrid human leukocyte interferons, did not cause significant inhibition of melanogenesis in B-16 mouse cells. The tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) also inhibited B-16 differentiation and the combination of TPA with IFN-alpha A/D (Bgl) or mouse L-cell interferon was synergistic in delaying melanogenesis. These studies indicate that the IFN-alpha A/D (Bgl) hybrid that exhibits antiviral activity on mouse cells can also inhibit differentiation of murine cells.