Tumour necrosis factor is a compact trimer

Recombinant produced human tumour necrosis factor (TNF) has been studied to characterise the subunit structure of the protein. TNF is shown to be a trimer Mr 52000 in which the subunits are associated in a compact, triangular form. In secondary structure it belongs to the all-beta class of proteins. It has high thermodynamic stability and the unfolded subunits can fold and associate spontaneously to form native, biologically active TNF.     

Tumour necrosis factor and cancer

TNF is a cytokine whose diverse actions are dependent on the local microenvironment. As a member of the cytokine network, TNF plays an important role in infection and inflammation, but excessive and deregulated production can contribute to disease processes. Likewise in malignant disease, TNF may have a role in cancer therapy and contribute to host response against tumours, but it may also be involved in the progression and spread of the cancer. In experimental models, recombinant TNF can induce significant haemorrhagic necrosis, localised to the tumour vasculature and specific tumour immunity. Although the historical background and preclinical data are promising, systemic therapy with TNF in human cancer has proved highly toxic and is inactive against all tumour types so far tested. Local therapy, particularly isolated limb perfusion, has resulted in complete and long lasting tumour regressions with necrotic activity confined solely to the tumour vascular bed. However, in several animal models, TNF contributes to malignant progression and there is evidence that TNF may have autocrine or paracrine actions in human ovarian cancer.     

Tumour necrosis factor alpha-induced neuronal loss is mediated by microglial phagocytosis

Tumour necrosis factor-α (TNF-α) is a pro-inflammatory cytokine, expressed in many brain pathologies and associated with neuronal loss. We show here that addition of TNF-α to neuronal–glial co-cultures increases microglial proliferation and phagocytosis, and results in neuronal loss that is prevented by eliminating microglia. Blocking microglial phagocytosis by inhibiting phagocytic vitronectin and P2Y₆ receptors, or genetically removing opsonin MFG-E8, prevented TNF-α induced loss of live neurons. Thus TNF-α appears to induce neuronal loss via microglial activation and phagocytosis of neurons, causing neuronal death by phagoptosis.     

Tumour necrosis factor alpha and mucocutaneous leishmaniasis

Allelic associations between polymorphisms at the tumour necrosis factor (TNF) locus within the major histocompatibility complex (MHC) and susceptibility to a range of autoimmune and infectious diseases have been established in humans. Among these is the severe and debilitating mucocutaneous form of leishmaniasis (MCL) caused by Leishmania braziliensis. This was preempted by the demonstration of high levels of circulating TNF-alpha in the sera of patients presenting with clinical mucocutaneous disease. Here, Jennie Blackwell looks at the implications this might have for the diagnosis and treatment of mucocutaneous disease, and the broader implications that the positive and negative immunomodulatory roles of TNF-alpha have in maintaining apparently detrimental alleles in the population.     

Polymorphism in the tumour necrosis factor receptor II gene is associated with circulating levels of soluble tumour necrosis factor receptors in rheumatoid arthritis

Levels of soluble tumour necrosis factor receptors (sTNFRs) are elevated in the circulation of patients with rheumatoid arthritis (RA). Although these receptors can act as natural inhibitors of tumour necrosis factor-α, levels of sTNFRs in RA appear to be insufficient to prevent tumour necrosis factor-α induced inflammation. The factors that regulate circulating levels of sTNFRs are unclear, but polymorphisms in the tumour necrosis factor receptor genes may play a role. We investigated the relationship between polymorphisms in the tumour necrosis factor receptor I (TNF-RI) and II (TNF-RII) genes and levels of sTNFRs in two groups of Caucasian RA patients: one with early (disease duration ≤2 years; n = 103) and one with established disease (disease duration ≥5 years; n = 151). PCR restriction fragment length polymorphism analysis was used to genotype patients for the A36G polymorphism in the TNF-RI gene and the T676G polymorphism in TNF-RII. Levels of sTNFRs were measured using ELISA. We also isolated T cells from peripheral blood of 58 patients with established RA with known TNF-R genotypes, and release of sTNFRs into the culture medium was measured in cells incubated with or without phytohaemagglutinin. Serum levels of the two sTNFRs (sTNF-RI and sTNF-RII) were positively correlated in both populations, and the level of each sTNFR was significantly higher in the patients with established disease (P < 0.0001). Multiple regression analyses corrected for age, sex and disease duration revealed a significant trend toward decreasing sTNF-RI and sTNF-RII levels across the TNF-RII genotypes (TT > TG > GG) of patients with established disease (P for trend = 0.01 and P for trend = 0.03, respectively). A similar nonsignificant trend was seen for early disease. No relationship with the TNF-RI A36G polymorphism was observed. sTNFRs released by isolated T cells exhibited a similar trend toward decreasing levels according to TNF-RII genotype, although only the association with levels of sTNF-RII was significant. Strong correlations were found between levels of circulating sTNFRs and levels released by T cells in vitro. Our data indicate that the T676G polymorphism in TNF-RII is associated with levels of sTNFRs released from peripheral blood T cells, and with circulating levels of sTNFR in patients with RA.     

Clinical applications of tumour necrosis factor

Tumour necrosis factor (TNF) is a polypeptide hormone produced in vivo by activated macrophages and lymphocytes. TNF has diverse effects in vivo and has a physiological role as an immune modulator, as a mediator of the immune response, both through activation of neutrophils and eosinophils, and also affects the vascular endothelium. TNF also has antiviral activity and causes alterations in lipid metabolism. In disease states excessive production of TNF may have adverse affects. TNF has been implicated as a mediator of endotoxic shock, inflammatory joint disease, immune deficiency states, allograft rejection, and in the cachexia associated with malignant disease and some parasitic infections. When used in pharmacological doses, TNF is cytotoxic to many malignant cells in vitro and in vivo. The mechanisms underlying cytotoxicity are not fully elucidated but involve both a direct toxic effect to the cell and an indirect effect on tumour vasculature. Cytotoxicity is not universal and TNF may act as a differentiating agent or growth factor for some haematological cell types. So far the clinical application of TNF has been as a treatment for cancer in Phase I and II trials in patients with advanced disease and its efficacy here is still unproven. TNF may have potential for clinical application in combination therapy for cancer. There is experimental evidence for its interaction with other biological agents and cytotoxic drugs. The use of specific antibodies to inhibit production of TNF, or other agents to antagonise the toxic effects of TNF may have clinical relevance in counteracting septic shock and the clinical manifestations of TNF in inflammatory and neoplastic disease.     

Amyloid precursor protein is trafficked and secreted via synaptic vesicles

A large body of evidence has implicated amyloid precursor protein (APP) and its proteolytic derivatives as key players in the physiological context of neuronal synaptogenesis and synapse maintenance, as well as in the pathology of Alzheimer's Disease (AD). Although APP processing and release are known to occur in response to neuronal stimulation, the exact mechanism by which APP reaches the neuronal surface is unclear. We now demonstrate that a small but relevant number of synaptic vesicles contain APP, which can be released during neuronal activity, and most likely represent the major exocytic pathway of APP. This novel finding leads us to propose a revised model of presynaptic APP trafficking that reconciles existing knowledge on APP with our present understanding of vesicular release and recycling.     

Tumour necrosis factor alpha-induced adipose-related protein (TIARP): co-localization with caveolin-1

We previously identified TIARP (TNF(alpha)-induced adipose-related protein, where TNF(alpha) stands for tumour necrosis factor alpha), a novel plasma-membrane protein that is induced during 3T3-L1 preadipocytes differentiation by TNF(alpha). Whereas the biological function of TIARP is currently unknown, its protein sequence is reminiscent of transporter protein and/or NAD(P)/NAD(P)H-dependent oxidoreductase activities. We hypothesized that TIARP could be associated with the 3T3-L1 adipocyte plasma-membrane caveolae domains that contain many proteins involved in cellular trafficking and signalling processes. Studies by confocal microscopy showed that TIARP and caveolin-1, a major protein of caveolae, co-localized as patches at the plasma membrane. Immunoblot analysis of cell extracts indicated that TIARP was completely detergent-extractible from membranes, whereas caveolin-1 was present as both detergent-extractible and -insoluble pools. Since TIARP is compartmentalized with caveolin-1 within caveolae domains, we suggest this protein to be part of a signalling complex in association with caveolin-1 and regulatory proteins.     

Induction of arthritis by high mobility group box chromosomal protein 1 is independent of tumour necrosis factor signalling

Introduction

TNFα and high mobility group box chromosomal protein 1 (HMGB1) are two potent proinflammatory cytokines implicated as important mediators of arthritis. Increased levels of these cytokines are found in the joints of rheumatoid arthritis patients, and the cytokines trigger arthritis when applied into the joints of naïve mice. HMGB1 is actively released from immune cells in response to TNFα; once released, HMGB1 in turn induces production of several proinflammatory cytokines – including IL-6 and TNFα – by macrophages. Whether HMGB1-induced arthritis is mediated via the TNFα pathway, however, is unknown. The purpose of the present study was to investigate whether the arthritis-inducing effect of HMGB1 is dependent on TNFα expression in vivo and to assess whether TNFα deficiency affects a proinflammatory cytokine response to HMGB1 in vitro.

Methods

TNFα knockout mice and backcrossed control animals on a C57Bl6 background were injected intraarticularly with 5 μg HMGB1. Joints were dissected 3 days after intraarticular injection and were evaluated histologically by scoring the frequency and severity of arthritis. For in vitro studies, mouse spleen cultures from TNFα knockout mice and from control mice were incubated with different doses of HMGB1, and cell culture supernatants were collected at different time points for analysis of IL-6.

Results

Intraarticular injection of HMGB1 into healthy mouse joints resulted in an overall frequency of 32% to 39% arthritic animals. No significant differences were found with respect to the severity and incidence of synovitis between mice deficient for TNFα (seven out of 18 mice with arthritis) in comparison with control TNFα^+/+ animals (six out of 19). No significant differences were detected between spleen cells from TNFα^+/+ mice versus TNFα^-/- mice regarding IL-6 production upon stimulation with highly purified HMGB1 after 24 hours and 48 hours. Upon stimulation with a suboptimal dose of recombinant HMGB1, however, the splenocytes from TNFα^+/+ animals released significantly more IL-6 than cells from the knockout mice (602 ± 112 pg/ml and 304 ± 50 pg/ml, respectively; P < 0.05).

Conclusion

Our data show that HMGB1-triggered joint inflammation is not mediated via the TNF pathway. Combined with our previous study, we suggest that HMGB1-triggered arthritis is probably mediated through IL-1 activation.     

Tumour exosomes inhibit binding of tumour-reactive antibodies to tumour cells and reduce ADCC

In order to grow within an immunocompetent host, tumour cells have evolved various strategies to cope with the host’s immune system. These strategies include the downregulation of surface molecules and the secretion of immunosuppressive factors like IL-10 and PGE2 that impair the maturation of immune effector cells, among other mechanisms. Recently, tumour exosomes (TEX) have also been implicated in tumour-induced immune suppression as it has been shown that TEX can induce apoptosis in T lymphocytes. In this study, we extend our knowledge about immunosuppressive features of these microvesicles in that we show that TEX efficiently bind and sequester tumour-reactive antibodies and dramatically reduce their binding to tumour cells. Moreover, we demonstrate that this antibody sequestration reduces the antibody-dependent cytotoxicity by immune effector cells, which is among the most important anti-tumour reactions of the immune system and a significant activity of therapeutic antibodies. Taken together, these data point to the fact that tumour-derived exosomes interfere with the tumour-specific function of immune cells and constitute an additional mechanism how tumours escape from immune surveillance.     

Tumour necrosis factor induction of ELAM-1 and ICAM-1 on human umbilical vein endothelial cells--analysis of tumour necrosis factor-receptor interactions.

Induction of the adhesion molecules ELAM-1 and ICAM-1 on endothelial cells is a key pro-inflammatory effect of tumour necrosis factor (TNF). Earlier work in non-human systems has suggested that unlike other cell types, endothelial cells interact with the N-terminus of the TNF molecule, thereby implying novel TNF receptors on endothelial cells. This is also supported by 125I-TNF cross-linking studies on bovine endothelial cells. The present study aimed to see whether TNF induction of ELAM-1 and ICAM-1 on human umbilical vein endothelial cells (HUVECs) involved novel TNF-receptor interactions. Three approaches were employed. First, antibodies directed at different sites on the TNF molecule were tested for inhibition of TNF-induction of ELAM-1 and ICAM-1 on HUVECs. Inhibition was seen only with antibodies reacting with epitopes outside the N-terminal region. Second, an N-terminal TNF peptide (residues 1-26) failed to induce ELAM-1 and ICAM-1 on HUVECs or antagonise TNF induction of these molecules. Third, HUVEC/125I-TNF cross-linking revealed a major complex characteristic of the known 55 kDa TNF receptor: this was confirmed with receptor-specific monoclonal antibodies. It is concluded that (a) the same part of the TNF molecule interacts with TNF-receptors on HUVECs and other cell types and (b) TNF induction of ELAM-1 and ICAM-1 on HUVECs is mediated via the well-characterized 55 kDa TNF receptor.     

Characterization of a mitochondrial protein binding to single-stranded DNA.

A DNA-binding protein from Xenopus laevis oocyte mitochondria which has been found associated with the D-loop also shows a strong preference for single-stranded DNA. The binding to polynucleotides is dependent on the base composition, but no sequence specificity was found. This protein, called mtSSB, binds tightly and cooperatively to single-stranded DNA. By its amino-acid composition and its binding properties it appears to be similar to the single-stranded DNA-binding proteins found in prokaryotes.     

Nuclear coded mitochondrial protein prohibitin is an iron regulated iron binding protein

Mitochondria are central to iron homeostasis. However, various proteins involved in iron metabolism inside the mitochondria are still to be identified. Herein we report that nuclear coded mitochondrial protein prohibitin binds to iron and involved in intracellular iron homeostasis. Like other iron regulated proteins, prohibitin mRNA contains functional iron-response element and is regulated by intracellular iron levels. Tyrosine residues involved in iron binding attribute of prohibitin are identified using site-directed mutagenesis. These data together suggest that prohibitin functions as an intracellular iron binding protein and plays a role in intracellular iron homeostasis.     

Tumour necrosis factor alpha as a therapeutic target for immune-mediated inflammatory diseases

Preclinical studies have identified and validated tumour necrosis factor alpha (TNFalpha) as a key disease molecule and therapeutic target for immunotherapeutic intervention in many immune-mediated inflammatory diseases. Clinical indications include rheumatoid arthritis, Crohn's disease, ankylosing spondylitis and psoriasis. Recent clinical findings indicate that many chronic inflammatory disorders share certain pathogenic pathways, whereas others are limited to particular disease phenotypes. Better understanding of these pathogenic pathways will inform the development of new therapeutic approaches leading to more complete and sustained disease remissions.     

Structure of CrmE, a virus-encoded tumour necrosis factor receptor

Vaccinia virus (VACV), the smallpox vaccine, encodes many proteins that subvert the host immune response. One of these, cytokine response modifier E (CrmE), is secreted by infected cells and protects these cells from apoptotic challenge by tumour necrosis factor alpha (TNFalpha). We have expressed recombinant CrmE from VACV strain Lister in Escherichia coli, shown that the purified protein is monomeric in solution and competent to bind TNFalpha, and solved the structure to 2.0 A resolution. This is the first structure of a virus-encoded tumour necrosis factor receptor (TNFR). CrmE shares significant sequence similarity with mammalian type 2 TNF receptors (TNFSFR1B, p75; TNFR type 2). The structure confirms that CrmE adopts the canonical TNFR fold but only one of the two "ligand-binding" loops of TNFRSF1A is conserved in CrmE, suggesting a mechanism for the higher affinity of poxvirus TNFRs for TNFalpha over lymphotoxin-alpha. The roles of dimerisation and pre-ligand-assembly domains (PLADs) in poxvirus and mammalian TNFR activity are discussed.     

Tumour necrosis factor alpha antibody protects against lethal meningococcaemia

Tumour necrosis factor alpha (TNF-alpha) has been shown to be the principal mediator of Gram-negative bacterial endotoxin-induced shock. Nevertheless, evidence suggests that TNF-alpha plays a beneficial role in controlling bacterial infections when multiplication of the microorganism is required to kill the host. Using an infant rat model of Neisseria meningitidis infection, we found that blood TNF-alpha concentration reaches a peak three hours after intraperitoneal injection of 3 x 10(6) bacteria. Thereafter, the level of TNF-alpha decreased and was undetectable six to eight hours after infection. A correlation was observed between the magnitude of initial TNF-alpha response and a fatal outcome. Pretreatment of the animals with polyclonal anti-TNF antiserum significantly reduced mortality relative to animals pretreated with control serum. However, pretreatment of animals with anti-TNF antibody did not alter the bacterial invasion of the cerebrospinal fluid. Injection of heat-killed bacteria did not cause death and induced lower TNF-alpha levels than the same number of live bacteria. This excludes the possibility that the role of TNF-alpha is to mediate a shock induced by the endotoxin component of the bacterial inoculum. These results indicate that TNF-alpha has a deleterious effect in this model of bacteraemia. Identification of the critical factors that determine the action of TNF-alpha during lethal bacteraemia will lead to a better understanding of these diseases and the development of appropriate therapeutic intervention.     

p53 and tumor necrosis factor alpha regulate the expression of a mitochondrial chloride channel protein

A novel chloride intracellular channel (CLIC) gene, clone mc3s5/mtCLIC, has been identified from differential display analysis of differentiating mouse keratinocytes from p53+/+ and p53-/- mice. The 4.2-kilobase pair cDNA contains an open reading frame of 762 base pairs encoding a 253-amino acid protein with two putative transmembrane domains. mc3s5/mtCLIC protein shares extensive homology with a family of intracellular organelle chloride channels but is the first shown to be differentially regulated. mc3s5/mtCLIC mRNA is expressed to the greatest extent in vivo in heart, lung, liver, kidney, and skin, with reduced levels in some organs from p53-/- mice. mc3s5/mtCLIC mRNA and protein are higher in p53+/+ compared with p53-/- basal keratinocytes in culture, and both increase in differentiating keratinocytes independent of genotype. Overexpression of p53 in keratinocytes induces mc3s5/mtCLIC mRNA and protein. Exogenous human recombinant tumor necrosis factor alpha also up-regulates mc3s5/mtCLIC mRNA and protein in keratinocytes. Subcellular fractionation of keratinocytes indicates that both the green fluorescent protein-mc3s5 fusion protein and the endogenous mc3s5/mtCLIC are localized to the cytoplasm and mitochondria. Similarly, mc3s5/mtCLIC was localized to mitochondria and cytoplasmic fractions of rat liver homogenates. Furthermore, mc3s5/mtCLIC colocalized with cytochrome oxidase in keratinocyte mitochondria by immunofluorescence and was also detected in the cytoplasmic compartment. Sucrose gradient-purified mitochondria from rat liver confirmed this mitochondrial localization. This represents the first report of localization of a CLIC type chloride channel in mitochondria and the first indication that expression of an organellular chloride channel can be regulated by p53 and tumor necrosis factor alpha.     

Alpha 2-macroglobulin is a binding protein for basic fibroblast growth factor

After incubation with human serum or plasma, 125I-basic fibroblast growth factor (bFGF) (molecular mass 18.5 kDa) exhibits molecular mass forms greater than 200 kDa as determined by nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by autoradiography. These high molecular mass forms of bFGF are immunoprecipitable with antiserum raised against alpha 2-macroglobulin (alpha 2M). Purified alpha 2M and 125I-bFGF form a covalent complex in a specific, saturable manner. Excess unlabeled bFGF competes with 125I-bFGF for complex formation. Complex formation is complete after 4 h and is inhibited by pretreating alpha 2M with dithiothreitol, iodoacetamide, iodoacetic acid, and N-ethylmaleimide. The complex is resistant to acidic conditions and denaturants such as urea. Heparin, which binds bFGF, has no effect on complex formation. Methylamine, which blocks protease binding to alpha 2M, increases the amount of 125I-bFGF that can be bound 2-fold. Plasmin and trypsin treatment of alpha 2M has no effect on 125I-bFGF binding. The ability of growth factors to compete for binding is specific, as aFGF and TGF-beta compete for binding to alpha 2M, whereas platelet-derived growth factor does not. 125I-bFGF.alpha 2M complexes do not bind to low affinity bFGF binding sites and bind poorly to high affinity bFGF binding sites on BHK-21 cells. In addition, 125I-bFGF bound to alpha 2M has decreased ability to stimulate plasminogen activator production in bovine capillary epithelial cells.