Heterogeneity of mouse lymphocytes in interferon production upon influenza virus challenge in culture

Heterogeneity of mouse lymphocytes with respect to interferon production upon influenza virus challenge in culture was studied. Spleen cells produced much more interferon than thymocytes or mesenteric lymph node cells. Spleen cells mainly responsible for interferon production belonged to the hydrocortisone-sensitive population. When spleen lymphocytes were separated into seven fractions by centrifugation on a serum albumin density gradient, they were found to differ greatly in interferon producing capacity; a small fraction of intermediate density, representing a few percent or less of the total lymphocytes, produced markedly high levels of interferon.     

Induction of interferon production in mouse spleen cell cultures by corynebacterium parvum.

Spleen cells of CS7BL/6 mice produced considerable amounts of interferon (IF) in vitro when tested 5 to 20 days after injection of killed Corynebacterium parvum. Interferon was also produced when C. parvum was added in vitro to spleen cell cultures of previously untreated mice. High levels were detected after 1 day of culture with some increment during subsequent days. In a number of experiments IF was also produced in untreated control cultures but only after prolonged cultivation and not after 1 day. The highest levels of IF were usually obtained when spleen cells of C. parvum-treated mice were challenged with additional C. parvum in vitro. The IF induced by C. parvum shared certain physicochemical properties with a tested immune IF and was not neutralized by an antiserum raised against a type I IF. Spleen cells of nu/nu mice and spleen cells treated by anti-θ serum plus complement did not differ from their respective controls, indicating that production of IF did not require mature T lymphocytes. Removal of B lymphocytes by nylon wool columns abolished the capacity of spleen cells to produce IF. When spleen cells were freed of adherent cells by the use of plastic surfaces, they no longer produced IF. Peritoneal exudate macrophages (PEC), which by themselves did not produce IF, in small numbers reconstituted nonadherent spleen cells. Nylon column-treated spleen cells, however, could not be restored by PEC. It is concluded that IF upon challenge with C. parvum is produced by B lymphocytes and requires the help of macrophages.     

Production of an antiviral factor by murine spleen cells after treatment with Corynebacterium parvum.

We have previously shown that injection of Corynebacterium parvum (CP) in mice protected them against lethal encephalitis induced by herpes simplex virus, (HSV). It is shown here that spleen cells of CP-injected mice in vitro produce a factor capable of inhibiting the replication of HSV in mouse embryo fibroblasts (MEF). A similar activity was produced after in vitro exposure of spleen cells from untreated mice to CP. CP was only slightly mitogenic in contrast to phytohemagglutinin (PHA), concanavalin A (Con A), and bacterial lipopolysaccharide (LPS) which were strongly mitogenic but did not induce antiviral activity high enough to be detected in the HSV-MEF system. The activity produced by CP-treated spleen cells appeared to be interferon since it was trypsin sensitive and species specific and not virus specific, and since preincubation of the cells was required to demonstrate an antiviral effect. However, the identity of CP-induced interferon with any of the previously described subclasses of interferon remains to be determined.     

Mechanism for the suppression of gamma-interferon responsiveness in mice after thermal injury

As reported previously, gamma-interferon production was decreased after the administration of inducers to thermally injured mice as compared with noninjured controls. Similarly, spleen cells from injured mice had decreased ability to produce interferon in vitro after stimulation with inducers. The present study demonstrated that the decrease in interferon production was associated with the presence of suppressor cells in the spleen of burned mice that were capable of inhibiting interferon production by normal splenic lymphocytes in vitro. Passive transfer of spleen cells containing suppressor cell activity derived from injured mice induced suppression in normal mice, and the time of the appearance of suppressor cell activity in injured mouse spleens closely approximated the time of the appearance of the suppression of interferon production observed in mice after thermal injury. The suppressor cells were characterized as a population of macrophages by the following: they adhered to plastic surface and could be removed from spleen cells by carbonyl-iron treatment; treatment of plastic-adherent cells with anti-Thy-1.2 and anti-mouse immunoglobulin antisera followed by complement failed to abrogate the suppression produced by these cells.     

Activity of recombinant human alpha interferon against influenza virus infection in mice

The in vivo antiviral activity of recombinant human leukocyte hybrid interferon, HuIFN-alpha AD, was examined. Results showed that this material in highly purified form did not protect mice against a lethal dose of influenza virus, although administration of natural MuIFN-alpha/beta to mice infected with a lethal dose of influenza virus had a marked protective effect. The effect of alveolar macrophages treated with IFN on influenza virus replication was examined in vitro. The antiviral activity of alveolar macrophages treated with HuIFN-alpha AD was lower than that of MuIFN-alpha/beta. It is concluded that HuIFN-alpha AD is effective in direct inhibition of influenza virus, but not in indirect inhibition mediated by alveolar macrophages or in protection of mice from influenza virus infection.     

Alternative induction of alpha/beta interferons and gamma interferon by listeria monocytogenes in mouse spleen cell cultures

Production of interferon (IFN) by Listeria monocytogenes (LM) in nonimmunized mouse spleen cell cultures was studied. IFN-gamma defined by virtue of its acid stability and antigenicity was produced in spleen cell cultures obtained from ddY mice, C57BL/6 mice, and BALB/c mice in response to heat-killed (HK) LM within 24 hr. On the other hand, production of IFN-alpha/beta was demonstrated in spleen cell cultures obtained from one of four nude mice (BALB/c, nu/nu). Therefore, it is important to know the reason why the spleen cells of mice other than nude mice did produce only IFN-gamma, but did not produce IFN-alpha/beta in response to HK-LM. Spleen cells obtained from ddY mice were fractionated, and the cellular source for IFN production of either IFN-alpha/beta or IFN-gamma induced by HK-LM was investigated. IFN-gamma was produced only by a mixture of T lymphocytes (nylon wool-nonadherent, Thy-1-positive cells) and macrophages by HK-LM. Neither T lymphocytes nor macrophages alone produced IFN by HK-LM. Macrophage-depleted spleen cells produced neither IFN-gamma nor IFN-alpha/beta, but these cells acquired the ability to produce IFN-alpha/beta, not IFN-gamma, only when they had been treated with IFN-alpha/beta. A possible mechanism of both IFN-gamma and IFN-alpha/beta induction by Listeria in mouse spleen cell cultures is discussed.     

Immune interferon production by TH69, a lyophilized preparation of Streptococcus faecalis, in murine spleen cell cultures

In mouse spleen cell cultures, TH69, a live Streptococcus faecalis (ATCC 31663) preparation, at a concentration of 20 micrograms/ml induced immune interferon (IFN gamma) with molecular weight ranging from 20,000 to 40,000 daltons together with a small amount of IFN alpha/beta. By using nonsensitized mouse spleen cells, the fact that both T-cells and macrophages are required for this IFN production was established. When these spleen cells were obtained from mice sensitized 12 days earlier with 4 mg of TH69, twice as much IFN was produced than in cells obtained from nonsensitized mice. This increase was explained by the presence of both sensitized macrophages and T-cells in a reconstitution experiment.     

Use of silica to identify host mechanisms involved in suppression of established Friend virus leukemia.

Silica, an agent predominantly toxic for macrophages, inoculated i.v. to Friend leukemia virus (FLV)-infected mice, blocks the FLV-leukemosuppressive effects of chlorite-oxidized oxyamylose (COAM)-statolon treatment. FLV-infected, COAM-statolon-treated mice that have received silica and have failed to suppress FLV leukemia produced normal amounts of interferon, but did not make antibodies cytotoxic for FLV leukemic cells. Transfer of untreated spleen cells, splenic T cells, or thymocytes from mice with suppressed FLV erythroleukemia to FLV-infected mice treated with silica and COAM-statolon restores the humoral immune response to FLV antigens and results in leukemosuppression. Thus, T lymphocytes from mice with suppressed erythroleukemia participate in FLV leukemosuppression either directly as effector cells, or indirectly as helper cell in the production of antibodies to FLV antigens.     

Resistance of nude mice to herpes simplex virus and correlation with in vitro production of interferon.

Homozygous nude mice and their phenotypically normal littermates were infected intraperitoneally with herpes simplex virus (HSV). Nude mice did not show increased mortality rates. In fact, at lower virus doses they were consistently less susceptible than the controls. Spleen cells from nude mice, when challenged in vitro with HSV, produced equal amounts of interferon as spleen cells from the normal littermates.     

Defense mechanisms against primary influenza virus infection in mice. I. The roles of interferon and neutralizing antibodies and thymus dependence of interferon and antibody production.

To investigate the defensive roles and production of interferon and antibodies, C3H/He mice were subjected to various immunosuppressive treatments and infected with influenza virus. In infected normal control mice the pattern of pulmonary viral growth can be divided into three phases. The first phase is characterized by an exponential increase of virus titer, the second by a rapid decrease, and the third by a moderate decrease. At the time of transition from the first phase to the second in pulmonary virus growth, interferon could be detected in the tracheobronchial washings of infected mice, but neutralizing antibodies could not. In infected B cell-deprived mice and infected anti-mu-treated mice, the transition from the first phase to the second occurred without any detectable antibody production, and interferon could be induced in the early stage of infection. However, the pulmonary virus in these mice increased again exponentially until the death of the mice. In infected T cell-deprived mice which could not induce interferon, but produced IgM-neutralizing antibodies, the second phase was not observed after the first phase, but a transient plateau phase could be demonstrated, and then the pulmonary virus increased again exponentially until the death of the mice. In anti-gamma-treated infected mice, pulmonary virus growth and production of interferon and neutralizing antibody were almost similar to those of infected normal control mice except for the absence of IgG neutralizing antibody production. Although anti-alpha-treated infected mice produced interferon and no IgA antibody, the transition from the first exponential increase of pulmonary virus to the second rapid decrease was seen, but then the virus increased exponentially again until the death of the mice. These results suggest that interferon plays an important role in the transition from the first phase to the second, and that T cells are required for interferon induction in mice infected with influenza virus. These data also suggest that IgA antibodies play an important role in the inhibition of virus propagation in the lungs after the disappearance of interferon. Moreover, infected T cell-deprived mice could produce only IgM neutralizing antibodies, but not IgG and IgA antibodies. Therefore, T cells are required for the production of IgG and IgA antibodies and even     

Enhancement by interferon of natural killer cell activity in mice.

Injection of mice with several interferon inducers, Newcastle Disease virus, polyinosinic-polycytidylic acid and tilorone resulted in an increase in spleen cell cytotoxicity for ⁵¹chromium-labeled mouse YAC tumor target cells in 4-hr in vitro assays. This increase in spleen cell cytotoxicity was abrogated by injection of mice with potent anti-mouse interferon globulin. Inoculation of mice with mouse interferon (but not human leucocyte or mock interferon preparations) also resulted in a marked enhancement of spleen cell cytotoxicity. The extent of enhancement of spleen cell cytotoxicity was directly proportional to the amount of interferon injected and a significant increase was observed after inoculation of as little as 10³ to 10⁴ units of interferon. An effect could be detected as soon as 1 hr after injection of interferon. The increase of spleen cell cytotoxicity after inoculation of an interferon inducer was not due to a localization and accumulation of cytotoxic cells in the spleen but reflected a general increase in cytotoxic cell activity in various lymphoid tissues (except the thymus). The splenic cytotoxic cells from interferon or interferon-inducer-injected mice had the characteristics of natural killer (NK) cells since (i) interferon enhanced spleen cell cytotoxicity in athymic (nu/nu) nude mice, (ii) classical spleen cell fractionation procedures by nylon wool columns, anti-Thy 1.2 serum plus complement, anti-Ig columns, and depletion of FcR+ rosette-forming cells, failed to remove the effector cells generated in vivo or in vitro. Therefore like NK cells, interferon-induced cytotoxic cells lack the surface markers of mature T and B lymphocytes, are not adherent, and are devoid of avid Fc receptors. Furthermore like NK cells, the spleen cells from interferon-treated mice lysed various target cells (known for their sensitivity to NK cells) without H-2 or species restriction. Incubation in vitro of normal spleen cells with interferon also resulted in an increase in cytotoxicity for YAC tumor cells. We conclude that interferon acts directly on NK cells and enhances the inherent cytotoxic activity of these cells.     

Regulation of lymphokine response during reinfection by influenza virus. Production of a factor that inhibits lymphokine activity

Mononuclear cells, obtained from the spleens and lungs of influenza virus-seropositive C57BL/6 mice at 2 to 4 days after re-infection with homologous virus (strain A/Bangkok/1/79), produced a low m.w. factor in vitro that prevents the biologic expression, but not production, of the lymphokine, leukocyte migration inhibition factor (LIF). The low m.w. factor inhibited LIF activity without destroying the LIF molecule inasmuch as simple dialysis restored lymphokine activity to culture supernatants. Production of the low m.w. factor was observed from 2 to 4 days after re-infection, at which time the delayed-type hypersensitivity response to viral Ag was suppressed. In contrast, LIF was produced by splenocytes and lung mononuclear cells obtained at all times tested after re-infection (from 2 to 30 days). Production of the low m.w. factor required re-infection of influenza A virus-seropositive mice with type A virus; re-infection with influenza B virus failed to induce production. Ag specificity was also required in vitro for splenocytes to produce the factor; cells from type A virus-re-infected mice required type A Ag stimulation. Cell depletion studies with mAb plus C revealed that macrophages and T cells along with Ag stimulation were required for factor production by spleen cells. However, mononuclear cells obtained within 4 days from the lungs of re-infected mice did not require in vitro Ag stimulation for production of the low m.w. factor, and factor production was dependent upon the presence of CD4+ (L3T4) cells in the culture. Fractionation of culture supernatants over a Sephadex G-50 column indicated that the factor had a molecular mass of 2 to 3 kDa, and by FPLC chromatofocusing over a Mono P column, the factor eluted at a pH of approximately 8.2. Thus, re-exposure of influenza virus-seropositive mice to homologous virus resulted in the production of a low m.w. factor that prevented the biologic expression of LIF, but not its production. Lymphokines are an important component of the delayed-type hypersensitivity response; the presence of mononuclear cells secreting a low m.w. factor and LIF concomitantly at the site of virus replication (lungs) and the capacity of the factor to block the biologic expression of LIF in vitro suggest that the factor may have a role in the regulation of a delayed-type hypersensitivity response in vivo during re-infection.     

Type I Interferon Induction during Influenza Virus Infection Increases Susceptibility to Secondary Streptococcus pneumoniae Infection by Negative Regulation of γδ T Cells

The majority of deaths following influenza virus infection result from secondary bacterial superinfection, most commonly caused by Streptococcus pneumoniae. Several models have been proposed to explain how primary respiratory viral infections exacerbate secondary bacterial disease, but the mechanistic explanations have been contradictory. In this study, mice were infected with S. pneumoniae at different days after primary influenza A (X31) virus infection. Our findings show that the induction of type I interferons (IFNs) during a primary nonlethal influenza virus infection is sufficient to promote a deadly S. pneumoniae secondary infection. Moreover, mice deficient in type I interferon receptor (IFNAR knockout [KO] mice) effectively cleared the secondary bacterial infection from their lungs, increased the recruitment of neutrophils, and demonstrated an enhanced innate expression of interleukin-17 (IL-17) relative to wild-type (WT) mice. Lung γδ T cells were responsible for almost all IL-17 production, and their function is compromised during secondary S. pneumoniae infection of WT but not IFNAR KO mice. Adoptive transfer of γδ T cells from IFNAR KO mice reduced the susceptibility to secondary S. pneumoniae infection in the lung of WT mice. Altogether, our study highlights the importance of type I interferon as a key master regulator that is exploited by opportunistic pathogens such as S. pneumoniae. Our findings may be utilized to design effective preventive and therapeutic strategies that may be beneficial for coinfected patients during influenza epidemics.     

The effect of the bronchoalveolar fluid of mice infected with the influenza virus on hematopoietic bone marrow precursors]

The influence of bronchoalveolar washing fluid (BAWF), as well as BAWF cells, obtained from mice infected with influenza virus, on the formation of exogenic spleen colony-forming units (CFUs) of lethally irradiated syngeneic recipients was studied. BAWF and BAWF cells of intact syngeneic mice stimulated the growth of CFUs. BAWF of mice infected with nonpathogenic strain A/PR/8/34 lost its capacity for stimulating the growth of colonies, and BAWF cells greatly suppressed colony formation in the spleen of recipients. The participation of interferon, colony-stimulating factor and the virus itself in the process of the modulation of colony formation is discussed.     

Relationship between Immunity and Interferon Production in Macrophages

In vitro interferon (IF) production in peritoneal macrophages of normal and Newcastle disease virus (NDV)-immunized mice was studied. Of ascites cells used, 80% were macrophages, 14% lymphocytes, and 6% polymorphonuclear leukocytes. It was indicated that IF was produced mainly in the macrophages after NDV inoculation. IF production in the macrophages derived from immunized mice was more enhanced than that in those from normal mice. It is not clear at present, however, whether this enhancement is based on immunological specificity. The IF production in the culture of macrophages reached its maximum value in 6 to 9 hr after inoculation of the inducer. After 12 hr, the IF titer in the culture fluid decreased gradually. A possible explanation of this fact is that there may be partial inactivation of IF by some cellular components.     

Effect of mouse genotype on interferon production

Upon induction with Newcastle disease virus, peritoneal macrophages derived from C57BL/6 mice produced ten times as much interferon as macrophages derived from BALB/c mice. This suggested that the alleles of theIf-1 locus are expressed in vitro by these cells. Further evidence for this was obtained by studying interferon production by peritoneal macrophages derived from seven recombinant inbred and one congenic line: in each case there was complete correlation between in vivo and in vitro phenotype: macrophages fromIf-1^l mice were low producers in vitro, and macrophages fromIf-1 ^h mice were high producers in vitro.     

Parasite-mediated upregulation of NK cell-derived gamma interferon protects against severe highly pathogenic H5N1 influenza virus infection

Outbreaks of influenza A viruses are associated with significant human morbidity worldwide. Given the increasing resistance to the available influenza drugs, new therapies for the treatment of influenza virus infection are needed. An alternative approach is to identify products that enhance a protective immune response. In these studies, we demonstrate that infecting mice with the Th1-inducing parasite Toxoplasma gondii prior to highly pathogenic avian H5N1 influenza virus infection led to decreased lung viral titers and enhanced survival. A noninfectious fraction of T. gondii soluble antigens (STAg) elicited an immune response similar to that elicited by live parasites, and administration of STAg 2 days after H5N1 influenza virus infection enhanced survival, lowered viral titers, and reduced clinical disease. STAg administration protected H5N1 virus-infected mice lacking lymphocytes, suggesting that while the adaptive immune response was not required for enhanced survival, it was necessary for STAg-mediated viral clearance. Mechanistically, we found that administration of STAg led to increased production of gamma interferon (IFN-γ) from natural killer (NK) cells, which were both necessary and sufficient for survival. Further, administration of exogenous IFN-γ alone enhanced survival from H5N1 influenza virus infection, although not to the same level as STAg treatment. These studies demonstrate that a noninfectious T. gondii extract enhances the protective immune response against severe H5N1 influenza virus infections even when a single dose is administered 2 days postinfection.     

Influenza virus-induced type I interferon leads to polyclonal B-cell activation but does not break down B-cell tolerance

The link between infection and autoimmunity is not yet well understood. This study was designed to evaluate if an acute viral infection known to induce type I interferon production, like influenza, can by itself be responsible for the breakdown of immune tolerance and for autoimmunity. We first tested the effects of influenza virus on B cells in vitro. We then infected different transgenic mice expressing human rheumatoid factors (RF) in the absence or in the constitutive presence of the autoantigen (human immunoglobulin G [IgG]) and young lupus-prone mice [(NZB x NZW)F(1)] with influenza virus and looked for B-cell activation. In vitro, the virus induces B-cell activation through type I interferon production by non-B cells but does not directly stimulate purified B cells. In vivo, both RF and non-RF B cells were activated in an autoantigen-independent manner. This activation was abortive since IgM and IgM-RF production levels were not increased in infected mice compared to uninfected controls, whether or not anti-influenza virus human IgG was detected and even after viral rechallenge. As in RF transgenic mice, acute viral infection of (NZB x NZW)F(1) mice induced only an abortive activation of B cells and no increase in autoantibody production compared to uninfected animals. Taken together, these experiments show that virus-induced acute type I interferon production is not able by itself to break down B-cell tolerance in both normal and autoimmune genetic backgrounds.     

Suppressive effect of macrophages on interferon-gamma production by human peripheral lymphocytes stimulated with Mycoplasma pneumoniae

Production of interferon (IFN)-gamma was investigated in human peripheral lymphocytes stimulated with Mycoplasma pneumoniae. Lymphocytes obtained from non-immune individuals produced no IFN. IFN-gamma was produced by T cells obtained from immune individuals, and the helper/inducer T cells produced two- to sixfold higher titer of IFN-gamma than the suppressor/cytotoxic T cells. The addition of macrophages in T cell cultures suppressed the production of IFN-gamma; this differs from the previous result wherein the addition of macrophages enhanced the production of IFN-gamma, when stimulated with mumps virus or measles virus.     

Visualizing the Beta Interferon Response in Mice during Infection with Influenza A Viruses Expressing or Lacking Nonstructural Protein 1

The innate host defense against influenza virus is largely dependent on the type I interferon (IFN) system. However, surprisingly little is known about the cellular source of IFN in the infected lung. To clarify this question, we employed a reporter mouse that contains the firefly luciferase gene in place of the IFN-β-coding region. IFN-β-producing cells were identified either by simultaneous immunostaining of lungs for luciferase and cellular markers or by generating conditional reporter mice that express luciferase exclusively in defined cell types. Two different strains of influenza A virus were employed that either do or do not code for nonstructural protein 1 (NS1), which strongly suppresses innate immune responses of infected cells. We found that epithelial cells and lung macrophages, which represent the prime host cells for influenza viruses, showed vigorous IFN-β responses which, however, were severely reduced and delayed if the infecting virus was able to produce NS1. Interestingly, CD11c⁺ cell populations that were either expressing or lacking macrophage markers produced the bulk of IFN-β at 48 h after infection with wild-type influenza A virus. Our results demonstrate that the virus-encoded IFN-antagonistic factor NS1 disarms specifically epithelial cells and lung macrophages, which otherwise would serve as main mediators of the early response against infection by influenza virus.