Role of proteases in activation of apoptosis

Programmed cell death, or apoptosis, is a physiological cell suicide mechanism, which is triggered in the cells by different stimuli. It has been shown that proteases play a significant role both in the target cell killing by cytotoxic lymphocytes and in the TNF- or anti-Fas-induced cell death. The proteases involved in the early (induction) and late (cell self-destruction) stages of apoptosis are reviewed. It is suggested that the late stages are connected with the activation of a cascade of intracellular proteases, which leads to massive protein destruction. It is likely that the protein destruction is mainly designed for preventing autoimmune response to proteins released from dying cells.     

Interrelationships of Interferon and Immunity During Viral Infections

Interferon is one determinant of host resistance. The immune responses, cellular or humoral, are other components. Cell-mediated responses appear to be involved in host resistance to certain viral infections, particularly the herpesvirus group and vaccinia virus. It is suggested that immune and interferon responses may complement one another and contribute to host resistance. The relative importance of each component depends upon the virus-host interaction. Finally, evidence has been presented which suggests that production of interferon as a result of antigen-sensitized cell interaction may further link these two components of the host response.     

Release of outer membrane vesicles by Gram-negative bacteria is a novel envelope stress response

Conditions that impair protein folding in the Gram-negative bacterial envelope cause stress. The destabilizing effects of stress in this compartment are recognized and countered by a number of signal transduction mechanisms. Data presented here reveal another facet of the complex bacterial stress response, release of outer membrane vesicles. Native vesicles are composed of outer membrane and periplasmic material, and they are released from the bacterial surface without loss of membrane integrity. Here we demonstrate that the quantity of vesicle release correlates directly with the level of protein accumulation in the cell envelope. Accumulation of material occurs under stress, and is exacerbated upon impairment of the normal housekeeping and stress-responsive mechanisms of the cell. Mutations that cause increased vesiculation enhance bacterial survival upon challenge with stressing agents or accumulation of toxic misfolded proteins. Preferential packaging of a misfolded protein mimic into vesicles for removal indicates that the vesiculation process can act to selectively eliminate unwanted material. Our results demonstrate that production of bacterial outer membrane vesicles is a fully independent, general envelope stress response. In addition to identifying a novel mechanism for alleviating stress, this work provides physiological relevance for vesicle production as a protective mechanism.     

Interferon: effects on the immune response and the mechanism of activation of the cellular response.

The discovery of interferon in 1957 by Drs. Isaacs and Lindenmann led to major revisions in the concepts of man's defenses against viral infections. There are at least two types of interferon. Along with their antiviral properties, they have recently been shown to exert a suppressive effect on the humoral and cellular immune response; they affect both B and T lymphocytes. A variety of substances, including virus, polyribonucleotides, and mitogens for T lymphocytes, are good interferon inducers. T lymphocytes seem to be necessary for these inducers to exert their immunosuppressive effects. The immunosuppressive effects of interferon inducers suggests that interferons may be mediators of suppressor T lymphocyte effects. In the virus system, interferon does not exert its antiviral effects by direct action on the virus, but rather derepresses a cell gene that results in the production of an antiviral protein. This antiviral protein is probably the mediator of inhibition of virus replication. This is a complex sequence of events that results in the interaction of interferon with the cell membrane and the resulting production of the antiviral state in the cell. This review will examine the various steps of this involved process.     

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.     

Natural killing in estrogen-treated mice responds poorly to poly I.C despite normal stimulation of circulating interferon.

Natural killing by mouse spleen cells can be stimulated in vivo by interferon or by agents that stimulate interferon, such as poly I.C. Natural killing can be suppressed in vivo by the sustained administration of 17 beta-estradiol. In BALB/c mice that had been treated with 17 beta-estradiol for 10 weeks, natural killing did not respond to intravenous poly I.C, although stimulation of circulating interferon was equal to controls. Estradiol, then, does not block interferon production but does suppress the response of natural killer cells to interferon. It is suggested that estrogens either block the maturation of natural killer cells or reduce the number of natural killer cell precursors.     

Influenza virus-induced interferon production in mouse spleen cell culture: T cells as the main producer.

Interferon production by spleen cells from unimmunized C3H mice challenged in vitro with influenza virus AO/PR8 was investigated. Glass-nonadherent cells (lymphocytes) produced significant levels of interferon, although cocultivation of glass-adherent macrophages was needed for optimal production. Treatment of the cells with antithymocyte serum and complement markedly reduced the interferon production. When glass-nonadherent cells were fractionated on a nylon wool column, the T-cell-enriched fraction consistently produced more interferon than the B-cell-enriched fraction. It is concluded that T cells are an important producer of interferon in spleen cell cultures from normal mice upon challenge with influenza virus, although non-T cells (macrophages and B cells) also may produce interferon under suitable conditions.     

Alterations of interferon production in a mouse model of thermal injury

The effect of thermal injury on the response of interferon (IFN) production in vivo and in vitro after stimulation with eight representative inducers was investigated in a mouse model. The response of mice to immune IFN (IFN-gamma) inducers, staphylococcal enterotoxin A, concanavalin A, and a specific antigen for BCG-sensitized lymphocytes (purified protein derivative) was impaired after a 30% total body surface area third-degree burn. Suppression of IFN-gamma production was observed at day 2 and persisted until day 7 after burn. Decreased IFN-gamma production correlated closely with the percentage of total body surface area burned. When virus type IFN (IFN-alpha/beta) inducers, Newcastle disease virus, polyriboinosinic-polyribocytidylic acid, 10-carboxymethyl-9-acridanone, and E. coli endotoxin, were administered to mice, no change in IFN response was observed after thermal injury. Similar results were obtained when spleen cells obtained from thermally injured mice were stimulated with IFN-gamma inducers in vitro. These studies suggest that although the capacity for IFN-alpha/beta production remains intact in thermally injured mice, IFN-gamma production may be selectively decreased in burned animals and in their spleen cells.     

Possible causes of fever after interferon administration

Several factors can be responsible for the febrile response evoked by interferon (IF) administration in man. Since different cells and inducers are used for production of IF, the pyrogenic substance may not always be the same. Leucocyte IF (LeIF) may contain endogeneous pyrogen (EP), fibroblast IF (FIF) may contain heterogeneous proteins and/or EP, and lymphoblastoid IF (LyIF) may contain a factor released by the transformed lymphocyte able to induce, in vivo, the release of EP from leucocytes. Finally, IF may be intrinsically pyrogenic and, if this is the case, until homogeneous IF is used, it may potentiate the action of the pyrogenic contaminants.     

Effect of dimethylsulfoxide and hexamethylene bisacetamide on the JOK-1 hairy cell leukemia derived cell line propagated in the nude mouse

The JOK-1 hairy cell leukemia derived cell line has been propagated as a subcutaneous tumor in nude mice. After the tumor had been serially transplanted for at least two successive generations, mice were treated with either dimethylsulfoxide or hexamethylene bisacetamide (HMBA). These agents have been shown to induce terminal leukemic cell differentiation in vitro. Our results indicated that these agents had an in vivo growth inhibitory effect, with HMBA exerting a dose-dependent response. Histopathological examination revealed massive areas of necrosis with no overt signs of cellular differentiation. These data suggest that in vitro inducers of differentiation may act via another mechanism in vivo.     

Regulation of gene expression by cytokines and virus in human cells lacking the type-I interferon locus.

A number of genes that are induced by type-I interferons are also activated by one or more other inducers, including double-stranded RNA, viruses, interferon-gamma, interleukin-1 and tumor necrosis factor. However, these inducers can also activate the expression of type-I interferons. Thus, the activation of type-I interferon-inducible genes by these other inducers could be direct, or a secondary consequence of the induction of interferon. To distinguish between these possibilities, we have used cell lines lacking all type-I interferon genes to study the direct effect of potential inducers on the expression of 14 interferon-inducible human genes. We show that double-stranded RNA, virus, interferon-gamma or tumor necrosis factor-alpha can act directly to induce specific subsets of type-I interferon-inducible genes in the absence of any possible type-I interferon involvement. The cis-acting element which confers inducibility by type-I interferon has been shown in some cases to confer inducibility by interferon-gamma, double-stranded RNA or virus as well. However, not all promoters containing such an element respond to both interferon and other inducers. Thus, the ability of a given gene to respond to different inducers most likely depends on the exact nature and specific combination of cis-acting elements present in its promoter.     

Intracellular redox changes during apoptosis

In the current paradigm for apoptotic cell death, the activity of a family of proteases related to interleukin 1-beta converting enzyme (ICE) orchestrates the multiple downstream events (such as cell shrinkage and chromatin degradation) that comprise apoptosis. A variety of stimuli can induce this type of cell death. One of the most reproducible inducers is mild oxidative stress, although it is unclear how an oxidative stimulus activates ICE-like proteases. Oxidative modification of proteins and lipids have also been observed in cells undergoing apoptosis in response to non-oxidative stimuli, suggesting that intracellular oxidation may be a general feature of the effector phase of apoptosis. However, attempts to consistently detect a requirement for reactive oxygen species in apoptosis have been inconclusive. Recent experiments revealing that apoptosis is typically accompanied by a depletion of intracellular reduced glutathione (GSH) are also discussed. In JURKATT lymphocytes treated with antibodies to the Fas/APO-1 surface receptor, this depletion results from an accelerated efflux of the reduced thiol rather than any intracellular oxidation. As GSH is the most abundant cytosolic reductant, we propose that its efflux may provide a non-oxidative mechanism by which the reducing environment of apoptotic cells is lost. An increase in oxidative damage to proteins and lipids would then result even in the absence of an increase in the production of oxidants. This may explain the seemingly contradictory findings that increased oxidative stress is not required for apoptosis even though antioxidants often inhibit the process and peroxidised products accumulate in apoptotic cells.     

Synergy in cytokine and chemokine networks amplifies the inflammatory response

The inflammatory response is a highly co-ordinated process involving multiple factors acting in a complex network as stimulators or inhibitors. Upon infection, the sequential release of exogenous agents (e.g. bacterial and viral products) and induction of endogenous mediators (e.g. cytokines and chemokines) contribute to the recruitment of circulating leukocytes to the inflamed tissue. Microbial products trigger multiple cell types to release cytokines, which in turn are potent inducers of chemokines. Primary cytokines act as endogenous activators of the immune response, whereas inducible chemokines act as secondary mediators to attract leukocytes. Interaction between exogenous and endogenous mediators thus enhances the inflammatory response. In this review, the synergistic interaction between cytokines to induce chemokine production and the molecular mechanisms of the cooperation amongst co-induced chemokines to further increase leukocyte recruitment to the site of inflammation are discussed.     

The nature of the suppressive effect of interferon and interferon inducers on the in vitro immune response

Viral-induced interferon inhibition of the primary in vitro plaque-formong cell (PFC) response in the mouse (C57B1/6) involves a dynamic relationship between the nature of the antigen, the concentration of interferon added to antigen-stimulated cultures, and the time of addition of interferon relative to antigen addition. The PFC response to a thymus-dependent antigen (sheep red blood cells) was more easily suppressed by viral-induced interferon than was that to a thymus-independent antigen (E. coli 0127 LPS), both in terms of inhibitory concentrations of interferon and the time at which the interferon could be added to cultures after antigen and still inhibit the PFC response. These differential effects of interferon could be related to the difference in cellular requirements (B and T lymphocytes) of the two antigens. Interferon was effective in inhibiting the in vitro PFC response of antigen-primed spleen cells, indicating that it can block the response of memory lymphocytes. By using interferon inducers as inhibitors of the in vitro PFC response, it was possible to show that at least two antigenically distinct interferons may be involved in suppressing the immune response. It is known that one type of interferon is induced by virus and synthetic double-stranded polyribonucleotides. The other type is stimulated by antigen and T cell mitogens. A model is proposed to explain the nature of these interferon inhibitory effects in terms of mediation of immune suppressor cell effects.     

Fluorescence-activated cell sorting of human T and B lymphocytes. II. Identification of the cell type responsible for interferon production and cell proliferation in response to mitogens

We have employed the fluorescence-activated cell sorter to separate pure viable preparations of human T and enriched B lymphocytes. Using such preparations, we have demonstrated that both human T and B cells can respond to PHA and PWM in vitro in the presence of macrophages with proliferation and the production of interferon, a mediator of cellular immunity. However, selective T cell interferon production and proliferative response can be assessed at 3 days in culture; B cell interferon production and proliferative response is delayed to 5 and 7 days. T cells or T cell products are ineffective in inducing or accelerating B cell interferon or proliferative response at 3 days. The use of 3-day T cell interferon production as a new technique for the assessment of T cell effector function and competence is suggested.     

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.     

Statins as a newly recognized type of immunomodulator

Inhibitors of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, or statins, are effective lipid-lowering agents, extensively used in medical practice. Statins have never been shown to be involved in the immune response, although a report has indicated a better outcome of cardiac transplantation in patients under Pravastatin therapy. Major histocompatibility complex class II (MHC-II) molecules are directly involved in the activation of T lymphocytes and in the control of the immune response. Whereas only a limited number of specialized cell types express MHC-II constitutively, numerous other cells become MHC-II positive upon induction by interferon gamma (IFN-gamma). This complex regulation is under the control of the transactivator CIITA (refs 6,7). Here we show that statins act as direct inhibitors of induction of MHC-II expression by IFN-gamma and thus as repressors of MHC-II-mediated T-cell activation. This effect of statins is due to inhibition of the inducible promoter IV of the transactivator CIITA and is observed in several cell types, including primary human endothelial cells (ECs) and monocyte-macrophages (Mstraight phi). It is of note that this inhibition is specific for inducible MHC-II expression and does not concern constitutive expression of CIITA and MHC-II. In repressing induction of MHC-II, and subsequent T-lymphocyte activation, statins therefore provide a new type of immunomodulation. This unexpected effect provides a scientific rationale for using statins as immunosuppressors, not only in organ transplantation but in numerous other pathologies as well.     

Lipopolysaccharide, latex beads and residual bodies are potent activators of Sertoli cell interleukin-1 alpha production.

Several recent studies indicate that interleukin-1 (IL-1) may be one of the major regulators of spermatogenesis. In the present work, the effects of various agents on rat Sertoli cell IL-1 production were investigated in vitro at different ages. In control cultures the IL-1 production by Sertoli cells from immature rats (20 days) was barely detectable; it markedly increased with the advancing age of the donors (35 and 45 days). Lipopolysaccharide and latex beads, two inducers of monocyte-macrophage IL-1 production, were able to stimulate the release of IL-1 by Sertoli cells at all ages studied; a decrease in the relative response to these inducers was noted as the age of the Sertoli cell donors increased. Under all the experimental conditions tested it appeared that the IL-1 produced was IL-1 alpha, not IL-1 beta. Whereas pachytene spermatocytes and early spermatids had no effect on IL-1 alpha production, residual bodies/cytoplasts from elongated spermatids dramatically stimulated Sertoli cell IL-1 production. In addition, FSH had no effect on IL-1 alpha levels. It is concluded that Sertoli cell IL-1 secretion can be stimulated in vitro by well known monocyte-macrophage activators. Furthermore, Sertoli cell IL-1 production is most probably crucially dependent on the phagocytosis of residual bodies in vivo.