The TNF-TNF receptor system

Different forms of tumor necrosis factor (TNF) interact with two specific receptors for TNF (TNFR) on the cell membrane to induce a variety of effects. While sharing structural similarities in their extracellular domains, the two TNFRs differ in their intracellular domain, their signal transduction, and consequently their function. In addition, one of the two TNFRs can be expressed in two differently located isoforms. This makes the TNF-TNFR system very complex. The dual TNF function for either cell death or survival upon interaction of members of the TNF ligand family with members of the TNF receptor family will be discussed.     

Single chain TNF derivatives with individually mutated receptor binding sites reveal differential stoichiometry of ligand receptor complex formation for TNFR1 and TNFR2

Most members of the tumor necrosis factor ligand family form noncovalently linked homotrimers, capable to bind up to three molecules of the respective membrane receptors. For several receptors a membrane distal homophilic interaction domain has been identified, called pre-ligand binding assembly domain. Accordingly, affinity values determined by typical equilibrium binding studies are likely to be influenced by avidity effects. Using our recently introduced covalently stabilized TNF (single chain TNF, scTNF), we have here investigated receptor–ligand binding stoichiometry in our well characterized system of TNFR–Fas chimeras. We produced scTNF derivatives with functionally deleted individual receptor binding sites, resulting in TNF mutants capable to only bind to one or two receptor molecules, rather than three. Equilibrium binding affinity studies on ice with these molecules revealed no significant changes after a single receptor binding site had been functionally deleted. In contrast, functional abrogation of two receptor binding sites showed a strong decrease in both, affinity and bioactivity on TNFR2–Fas. In contrast, TNFR1–Fas ligand binding and receptor activation was only affected after functional deletion of all three receptor binding sites. Our data demonstrate pivotal differences in ligand/receptor interactions between TNFR1–Fas and TNFR2–Fas, arguing for avidity effects important for TNF binding and downstream signaling of TNFR2, but to a lesser extent of TNFR1. These results are supported by data revealed from chemical crosslinking experiments suggesting the existence of preformed TNFR–Fas homodimers.     

Amelioration of inflammatory arthritis by targeting the pre-ligand assembly domain of tumor necrosis factor receptors

Tumor necrosis factor (TNF)-alpha has an important role in the pathogenesis of autoimmune and inflammatory diseases such as rheumatoid and septic arthritis. The biological effects of TNF-alpha are mediated by binding to TNF receptors TNFR1 (also known as P60) or TNFR2 (also known as P80). The pre-ligand assembly domain (PLAD) is a portion of the extracellular region of TNFRs that mediates receptor-chain association essential for signaling. We found that soluble versions of PLAD, especially those derived from P60, block the biochemical effects of TNF-alpha in vitro and potently inhibit arthritis in animal models. Thus, targeting the PLAD may have clinical value in the treatment of human arthritis and other disorders involving receptors of the TNFR superfamily.     

The tumor necrosis factor receptor stalk regions define responsiveness to soluble versus membrane-bound ligand

The family of tumor necrosis factor receptors (TNFRs) and their ligands form a regulatory signaling network that controls immune responses. Various members of this receptor family respond differently to the soluble and membrane-bound forms of their respective ligands. However, the determining factors and underlying molecular mechanisms of this diversity are not yet understood. Using an established system of chimeric TNFRs and novel ligand variants mimicking the bioactivity of membrane-bound TNF (mTNF), we demonstrate that the membrane-proximal extracellular stalk regions of TNFR1 and TNFR2 are crucial in controlling responsiveness to soluble TNF (sTNF). We show that the stalk region of TNFR2, in contrast to the corresponding part of TNFR1, efficiently inhibits both the receptor's enrichment/clustering in particular cell membrane regions and ligand-independent homotypic receptor preassembly, thereby preventing sTNF-induced, but not mTNF-induced, signaling. Thus, the stalk regions of the two TNFRs not only have implications for additional TNFR family members, but also provide potential targets for therapeutic intervention.     

Apoptosis mediated by the TNF-related cytokine and receptor families

T lymphocytes use several specialized mechanisms to induce apoptotic cell death. The tumor necrosis factor (TNF)-related family of membrane-anchored and secreted ligands represent a major mechanism regulating cell death and cell survival. These ligands also coordinate differentiation of tissue to defend against intracellular pathogens and regulate development of lymphoid tissue. Cellular responses are initiated by a corresponding family of specific receptors that includes two distinct TNFR (TNFR60 and TNFR80), Fas (CD95), CD40, p75NTF, and the recently identified lymphotoxin β-receptor (LTβR), among others. The MHC-encoded cytokines, TNF and LTα, form homomeric trimers, whereas LTβ assembles into heterotrimers with LTα, creating multimeric ligands with distinct receptor specificities. The signal transduction cascade is initiated by transmembrane aggregation (clustering) of receptor cytoplasmic domains induced by binding to their multivalent ligands. The TRAF family of Zn RING/finger proteins bind to TNFR80; CD40 and LTβR are involved in induction NFκB and cell survival. TNFR60 and Fas interact with several distinct cytosolic proteins sharing the “death domain” homology region. TNF binding to TNFR60 activates a serine protein kinase activity and phosphoproteins are recruited to the receptor forming a multicomponent signaling complex. Thus, TNFRs use diverse sets of signaling molecules to initiate and regulate cell death and survival pathways. © 1996 Wiley-Liss, Inc.     

CrmE, a novel soluble tumor necrosis factor receptor encoded by poxviruses

Cytokines and chemokines play a critical role in both the innate and acquired immune responses and constitute prime targets for pathogen sabotage. Molecular mimicry of cytokines and cytokine receptors is a mechanism encoded by large DNA viruses to modulate the host immune response. Three tumor necrosis factor receptors (TNFRs) have been identified in the poxvirus cowpox virus. Here we report the identification and characterization of a fourth distinct soluble TNFR, named cytokine response modifier E (CrmE), encoded by cowpox virus. The crmE gene has been sequenced in strains of the orthopoxviruses cowpox virus, ectromelia virus, and camelpox virus, and was found to be active in cowpox virus. crmE is expressed as a secreted 18-kDa protein with TNF binding activity. CrmE was produced in the baculovirus and vaccinia virus expression systems and was shown to bind human, mouse, and rat TNF, but not human lymphotoxin alpha, conjugates of lymphotoxins alpha and beta, or seven other ligands of the TNF superfamily. However, CrmE protects cells only from the cytolytic activity of human TNF. CrmE is a new member of the TNFR superfamily which is expressed as a soluble molecule that blocks the binding of TNF to high-affinity TNFRs on the cell surface. The remarkable finding of a fourth poxvirus-encoded TNFR suggests that modulation of TNF activity is complex and represents a novel viral immune evasion mechanism.     

Temperature-sensitive differential affinity of TRAIL for its receptors. DR5 is the highest affinity receptor

TRAIL is a member of the tumor necrosis factor (TNF) family of cytokines which induces apoptotic cell death in a variety of tumor cell lines. It mediates its apoptotic effects through one of two receptors, DR4 and DR5, which are members of of the TNF receptor family, and whose cytoplasmic regions contain death domains. In addition, TRAIL also binds to 3 "decoy" receptors, DcR2, a receptor with a truncated death domain, DcR1, a glycosylphosphatidylinositol-anchored receptor, and OPG a secreted protein which is also known to bind to another member of the TNF family, RANKL. However, although apoptosis depends on the expression of one or both of the death domain containing receptors DR4 and/or DR5, resistance to TRAIL-induced apoptosis does not correlate with the expression of the "decoy" receptors. Previously, TRAIL has been described to bind to all its receptors with equivalent high affinities. In the present work, we show, by isothermal titration calorimetry and competitive enzyme-linked immunosorbent assay, that the rank order of affinities of TRAIL for the recombinant soluble forms of its receptors is strongly temperature dependent. Although DR4, DR5, DcR1, and OPG show similar affinities for TRAIL at 4 degrees C, their rank-ordered affinities are substantially different at 37 degrees C, with DR5 having the highest affinity (K(D) 相似文献   

Computational simulations of TNF receptor oligomerization on plasma membrane

The interactions between tumor necrosis factors (TNFs) and their corresponding receptors (TNFRs) play a pivotal role in inflammatory responses. Upon ligand binding, TNFR receptors were found to form oligomers on cell surfaces. However, the underlying mechanism of oligomerization is not fully understood. In order to tackle this problem, molecular dynamics (MD) simulations have been applied to the complex between TNF receptor-1 (TNFR1) and its ligand TNF-α as a specific test system. The simulations on both all-atom (AA) and coarse-grained (CG) levels achieved the similar results that the extracellular domains of TNFR1 can undergo large fluctuations on plasma membrane, while the dynamics of TNFα-TNFR1 complex is much more constrained. Using the CG model with the Martini force field, we are able to simulate the systems that contain multiple TNFα-TNFR1 complexes with the timescale of microseconds. We found that complexes can aggregate into oligomers on the plasma membrane through the lateral interactions between receptors at the end of the CG simulations. We suggest that this spatial organization is essential to the efficiency of signal transduction for ligands that belong to the TNF superfamily. We further show that the aggregation of two complexes is initiated by the association between the N-terminal domains of TNFR1 receptors. Interestingly, the cis-interfaces between N-terminal regions of two TNF receptors have been observed in the previous X-ray crystallographic experiment. Therefore, we provide supportive evidence that cis-interface is of functional importance in triggering the receptor oligomerization. Taken together, our study brings insights to understand the molecular mechanism of TNF signaling.     

Antibodies to a soluble form of a tumor necrosis factor (TNF) receptor have TNF-like activity.

Immunological cross-reactivity between tumor necrosis factor (TNF) binding proteins which are present in human urine (designated TBPI and TBPII) and two molecular species of the cell surface receptors for TNF is demonstrated. The two TNF receptors are shown to be immunologically distinct, to differ in molecular weight (58,000 and 73,000), and to be expressed differentially in different cells. It is further shown that polyclonal antibodies against one of the TNF binding proteins (TBPI) display, by virtue of their ability to bind the TNF receptor, activities which are very similar to those of TNF. These antibodies are cytotoxic to cells which are sensitive to TNF toxicity, induce resistance to TNF toxicity, enhance the incorporation of thymidine into normal fibroblasts, inhibit the growth of chlamydiae, and induce the synthesis of prostaglandin E2. Monovalent F(ab) fragments of the polyclonal antibodies lack TNF-like activities, but acquire them upon cross-linking with anti-F(ab)2 antibodies, suggesting that the ability of the anti-TBPI antibodies to mimic TNF correlates with their ability to cross-link the TNF receptors. This notion was further supported by data obtained in a comparative study of the TNF-like cytotoxicity of a panel of monoclonal antibodies against TBPI. The induction of TNF-like effects by antibodies to a TNF receptor suggests that TNF is not directly involved in intracellular signalling. Rather, it is the receptors to this cytokine which, when properly triggered in a process which appears to involve clustering of these receptors, transduce the signal for response to TNF into the cell's interior.     

Structural basis of BLyS receptor recognition

B lymphocyte stimulator (BLyS), a member of the tumor necrosis factor (TNF) superfamily, is a cytokine that induces B-cell proliferation and immunoglobulin secretion. We have determined the three-dimensional structure of BLyS to 2.0 A resolution and identified receptor recognition segments using limited proteolysis coupled with mass spectrometry. Similar to other structurally determined TNF-like ligands, the BLyS monomer is a beta-sandwich and oligomerizes to form a homotrimer. The receptor-binding region in BLyS is a deeper, more pronounced groove than in other cytokines. The conserved elements on the 'floor' of this groove allow for cytokine recognition of several structurally related receptors, whereas variations on the 'walls' and outer rims of the groove confer receptor specificity.     

Signalling by the βc family of cytokines

The GM-CSF, IL-3 and IL-5 family of cytokines, also known as the βc family due to their receptors sharing the signalling subunit βc, regulates multiple biological processes such as native and adaptive immunity, inflammation, normal and malignant hemopoieis, and autoimmunity. Australian scientists played a major role in the discovery and biological characterisation of the βc cytokines and their recent work is revealing unique features of cytokine receptor assembly and signalling. Furthermore, specific antibodies have been generated to modulate their function. Characterisation of the structural and dynamic requirements for the activation of the βc receptor family and the molecular definition of downstream signalling pathways are providing new insights into cytokine receptor signalling as well as new therapeutic opportunities.     

Characterisation of monoclonal antibodies to the TNF and TNF receptor families

Tumour necrosis factor (TNF) family ligands and their corresponding receptors play important roles in the immune system and are involved in immune regulation such as lymphoid development, cell proliferation, differentiation, activation and death. Antibodies against these ligands and receptors together with Fc-fusion proteins, have been particularly useful as immunological tools in addressing the underlying involvement of these proteins in these contexts and furthermore, have given us hope in using them as potential therapeutic agents. Over last few years, there have been many additions to these ever-growing TNF family ligands and their receptors. Here, we have generated and characterised a set of monoclonal antibodies, together with mAbs from the HLDA workshop, against DcR1, DcR2, DR4, DR5, TRAIL, APRIL, BAFF, BAFF-R, BCMA, and TACI, which may be useful in phenotypic and functional studies of the role of TNF and TNF receptor family in immune function and regulation in relation to health and disease.     

CD 271 (P75 neurotrophin receptor)

P75NTR (or CD271) is a member of the Tumor Necrosis Factor receptor (TNFR) super family of transmembrane proteins that share significant homology in their extracellular domains. Subsets of TNF receptors, including CD271, have a cytoplasmic death domain, although CD271 has unique intracellular structure and downstream signaling partners. CD271 is also differentiated from other members of the TNFR receptor family in that it binds pro and mature neurotrophins and affects the growth, differentiation and death of the nervous system. The ligands for CD271 are neurotrophins, which are Nerve Growth Factor (NGF), Brain-Derived Growth factor (BDNF), Neurotrophin 3 (NT3) and Neurotrophin 4/5 (NT4/5). Recent studies have provided evidence that CD271 also serves as a receptor for the pro-forms of these neurotrophins.     

Tumour necrosis factor alpha receptors: role in the physiopathology of protozoan parasite infections

Tumour necrosis factor alpha (TNF alpha) is an important cytokine in immune regulation and resistance to various micro-organisms. It provides signals to the target cells through two different receptors: TNFR1 and TNFR2. The present report reviews the role of TNF receptors (TNFRs) in the immune response against protozoan parasite infections of medical interest (Toxoplasma gondii, Leishmania major, Trypanosoma cruzi, Plasmodium spp.). TNF alpha has been regarded as a modulator cytokine in host defence against protozoans infections and recent findings on experimental gene-deficient mice have showed that TNF alpha/TNFRs pathway may be beneficial for host protection during these infections.     

肿瘤坏死因子受体超家族成员在免疫系统和疾病中的研究

肿瘤坏死因子受体超家族 (tumor necrosis factor receptor superfamily, TNFRSF) 是细胞因子受体的一个蛋白质超家族，其显著特征是通过细胞外富含半胱氨酸结构域结合肿瘤坏死因子(tumor necrosis factor，TNF)。肿瘤坏死因子受体(tumor necrosis factor receptors，TNFRs)是古老的细胞因子，TNFRs同源基因最早可追溯到节肢动物果蝇中。TNFRs在炎症反应、细胞凋亡、淋巴细胞稳态和组织发育中发挥重要的作用，TNFRs最主要的功能是与免疫系统相关。鉴于其在免疫系统中发挥重要的作用，肿瘤坏死因子受体家族成员已成为治疗糖尿病、动脉粥样硬化、骨质疏松、自身免疫性疾病、移植排斥反应和癌症等人类疾病的靶点。随着科学技术发展，关于TNFRs的功能有了新的进展，在无脊椎动物和低等脊椎动物中已经有大量报道。在本篇综述中，主要总结了在高等哺乳动物中发现的29种TNFR成员的相关报道，包括8种死亡受体和21种非死亡受体，主要涉及在免疫系统以及与疾病相关领域的研究。大多数研究处于基础实验阶段，少数走向临床研究的案例取得的临床效果并不理想，靶向设计针对自身免疫性疾病、炎症和肿瘤疾病的治疗方案需要更深入的理解TNFRs功能。本文旨在对TNFRs成员发挥的功能有进一步的认识。     

肿瘤坏死因子受体超家族成员在免疫系统和疾病中的研究

肿瘤坏死因子受体超家族 (tumor necrosis factor receptor superfamily, TNFRSF) 是细胞因子受体的一个蛋白质超家族,其显著特征是通过细胞外富含半胱氨酸结构域结合肿瘤坏死因子(tumor necrosis factor,TNF)。肿瘤坏死因子受体(tumor necrosis factor receptors,TNFRs)是古老的细胞因子,TNFRs同源基因最早可追溯到节肢动物果蝇中。TNFRs在炎症反应、细胞凋亡、淋巴细胞稳态和组织发育中发挥重要的作用,TNFRs最主要的功能是与免疫系统相关。鉴于其在免疫系统中发挥重要的作用,肿瘤坏死因子受体家族成员已成为治疗糖尿病、动脉粥样硬化、骨质疏松、自身免疫性疾病、移植排斥反应和癌症等人类疾病的靶点。随着科学技术发展,关于TNFRs的功能有了新的进展,在无脊椎动物和低等脊椎动物中已经有大量报道。在本篇综述中,主要总结了在高等哺乳动物中发现的29种TNFR成员的相关报道,包括8种死亡受体和21种非死亡受体,主要涉及在免疫系统以及与疾病相关领域的研究。大多数研究处于基础实验阶段,少数走向临床研究的案例取得的临床效果并不理想,靶向设计针对自身免疫性疾病、炎症和肿瘤疾病的治疗方案需要更深入的理解TNFRs功能。本文旨在对TNFRs成员发挥的功能有进一步的认识。