TNF Receptor (肿瘤坏死因子)

Tumor Necrosis Factor Receptor; TNFR

肿瘤坏死因子 (TNF) 是细胞凋亡以及炎症和免疫的主要介质，并且与多种人类疾病的发病机制有关，包括败血症、糖尿病、癌症、骨质疏松症、多发性硬化症、类风湿性关节炎和炎症性肠病。

TNF-α 是一种 17 kDa 蛋白质，由 157 个氨基酸组成，在溶液中为同源三聚体。在人类中，该基因位于 6 号染色体上。其生物活性主要受可溶性 TNF-α 结合受体的调节。TNF-α 主要由活化的巨噬细胞、T 淋巴细胞和自然杀伤细胞产生。已知多种其他细胞的表达较低，包括成纤维细胞、平滑肌细胞和肿瘤细胞。在细胞中，TNF-α 合成为 pro-TNF (26 kDa)，它与膜结合，在 TNF 转换酶 (TACE) 裂解其 pro 结构域后释放。

许多 TNF 诱导的细胞反应是由两种 TNF 受体 TNF-R1 和 TNF-R2 中的任一种介导的，这两种受体都属于 TNF 受体超家族。在 TNF 治疗后，转录因子 NF-κB 和 MAP 激酶（包括 ERK、p38 和 JNK）在大多数类型的细胞中被激活，在某些情况下，也可能诱导细胞凋亡或坏死。然而，诱导细胞凋亡或坏死主要是通过 TNFR1 实现的，TNFR1 也称为死亡受体。NF-κB 和 MAPK 的激活在多种细胞因子和免疫调节蛋白的诱导中起着重要作用，并且对许多炎症反应至关重要。

Tumor necrosis factor (TNF) is a major mediator of apoptosis as well as inflammation and immunity, and it has been implicated in the pathogenesis of a wide spectrum of human diseases, including sepsis, diabetes, cancer, osteoporosis, multiple sclerosis, rheumatoid arthritis, and inflammatory bowel diseases.

TNF-α is a 17-kDa protein consisting of 157 amino acids that is a homotrimer in solution. In humans, the gene is mapped to chromosome 6. Its bioactivity is mainly regulated by soluble TNF-α–binding receptors. TNF-α is mainly produced by activated macrophages, T lymphocytes, and natural killer cells. Lower expression is known for a variety of other cells, including fibroblasts, smooth muscle cells, and tumor cells. In cells, TNF-α is synthesized as pro-TNF (26 kDa), which is membrane-bound and is released upon cleavage of its pro domain by TNF-converting enzyme (TACE).

Many of the TNF-induced cellular responses are mediated by either one of the two TNF receptors, TNF-R1 and TNF-R2, both of which belong to the TNF receptor super-family. In response to TNF treatment, the transcription factor NF-κB and MAP kinases, including ERK, p38 and JNK, are activated in most types of cells and, in some cases, apoptosis or necrosis could also be induced. However, induction of apoptosis or necrosis is mainly achieved through TNFR1, which is also known as a death receptor. Activation of the NF-κB and MAPKs plays an important role in the induction of many cytokines and immune-regulatory proteins and is pivotal for many inflammatory responses.

TNF Receptor 亚型特异性产品:

TNF Receptor Isoform Comparison

TNF Receptor 相关产品 (456)
重组蛋白 (235)
抗体 (20)
TNF Receptor 信号通路
TNF Receptor Isoform Comparison

By Effects:	抑制剂 (331) 激动剂 (8) 拮抗剂 (7) 激活剂 (21) 调节剂 (6) 诱导剂 (5)

Cat. No.	Product Name	Effect	Purity	Chemical Structure

HY-B0190A

Nafamostat mesylate 甲磺酸萘莫司他		99.85%
Nafamostat mesylate (FUT-175)，一种抗凝剂，是一种人工合成的丝氨酸蛋白酶 (serine protease) 抑制剂。 Nafamostat mesylate 具有抗癌和抗病毒作用，Nafamostat mesylate 通过上调肿瘤坏死因子受体 1 (TNFR1) 的表达诱导凋亡 (apoptosis)，可用于动脉壁病理性增厚的发生发展。

HY-13812

QNZ	Inhibitor	99.50%
QNZ (EVP4593) 强抑制 NF-κB 转录激活和 TNF-α 产生，IC₅₀ 分别为 11 和 7 nM。QNZ (EVP4593) 是一种保护神经的钙池操纵的钙通道 (SOC) 抑制剂。

HY-133122

UCB-9260	Inhibitor	98.38%
UCB-9260 是一种口服活性小分子，通过稳定三聚体的不对称形式抑制肿瘤坏死因子 (TNF) 信号传导。UCB-9260 对肿瘤坏死因子的选择性高于其他超家族成员，并与肿瘤坏死因子结合，其 K_d 值为 13 nM。

HY-120934

C25-140	Inhibitor	99.86%
C25-140 是一种首创的，具有口服活性和一定选择性的 TRAF6-Ubc13 相互作用的抑制剂，直接与 TRAF6 结合，阻断 TRAF6 和 Ubc13 的相互作用，从而降低 TRAF6 活性，降低 NF-κB 的活性，并对抗自身免疫。

HY-126360

Oxazolone	Activator	≥98.0%
Oxazolone 是一种半抗原化剂，可诱导急性或慢性大肠炎症，用于构建结肠炎模型。Oxazolone 能够引起 Th1/Th2 依赖性结肠炎，并伴有体重减轻和腹泻。Oxazolone 引起的炎症能够被中和性抗 IL-4 或抗 TNF-α 抗体或诱饵 IL-13R2α-Fc 蛋白减轻。

HY-N0201

Atractylenolide I 白术内酯 I		99.94%
Atractylenolide I 是从白术根中得到的倍半萜烯，具有神经保护、抗过敏、抗炎和抗癌等多种生物活性。Atractylenolide I 为 TLR4 的拮抗剂，同时在 A375 细胞中，能够降低 JAK2 和 STAT3 的磷酸化水平。

HY-P9953

Certolizumab pegol 培塞利珠单抗	Inhibitor	99.30%
Certolizumab pegol (Certolizumab) 是重组、聚乙二醇化、抗原结合片段的人源化单克隆抗体，可选择性靶向和中和肿瘤坏死因子-α (TNF-α)。 Certolizumab pegol 可用于类风湿关节炎和克罗恩病的研究。

HY-N0633

Muscone 麝香酮	Inhibitor	≥98.0%
Muscone 是中药麝香的主要活性单体。Muscone 抑制 NF-κB 和 NLRP3 炎性小体的活化。Muscone 显着降低炎性细胞因子 (IL-1β，TNF-α 和 IL-6) 水平，并最终改善心脏功能和存活率。

HY-P99056

Utomilumab 乌托鲁单抗	Inhibitor	99.33%
Utomilumab (PF 05082566) 是一种人源的 IgG2 mAb 激动剂，靶向T 细胞共刺激受体 4-1BB/CD137。Utomilumab 可用于复发/难治性滤泡性淋巴瘤 (FL) 和其他 CD20⁺ 非霍奇金淋巴瘤 (NHL) 的研究。

HY-N0029

Forsythoside B 连翘酯苷 B		99.99%
Forsythoside B 是传统中药植物连翘的叶子中分离的苯乙醇苷。独一味可用于炎症疾病和促进血液循环的研究。Forsythoside B 可抑制 TNF-alpha，IL-6，IκB，调节 NF-κB。

HY-N0297

Sinensetin 甲基化黄酮	Inhibitor	99.87%
Sinensetin是一个能够在水果中发现的甲基化黄酮，有很强的抗血管和抗炎症的能力。

HY-P9952

Belimumab 贝利尤单抗	Inhibitor	99.40%
Belimumab (LymphoStat B) 是一种人源化抗 B 淋巴细胞刺激因子 (BLyS) 蛋白的 IgG1λ 单克隆抗体。Belimumab 在自身免疫性疾病和 B 淋巴细胞恶性肿瘤中拮抗 BLyS 活性。Belimumab 可用于系统性红斑狼疮 (SLE) 研究。

HY-B0539

Desloratadine 地氯雷他定	Inhibitor	99.83%
Desloratadine (Sch34117) 是一种具有口服活性和选择性的 H1 受体拮抗剂 (K_i=0.9 nM)，具有抗炎和抗过敏活性。Desloratadine 抑制人嗜碱性细胞释放组胺和 LTC4，并靶向嗜碱性细胞中 IL-4 和 IL-13 生成的调控信号。Desloratadine 显著缓解并发哮喘患者的季节性变应性鼻炎症状，可用于哮喘和慢性特发性荨麻疹的研究。

HY-134471

TNF-α-IN-2	Inhibitor	98.75%
TNF-α-IN-2 是一种有效和具有口服活性的肿瘤坏死因子 α (TNFα) 抑制剂，在 HTRF 分析中的 IC₅₀ 值为 25 nM。结合时，TNF-α-IN-2 会使 TNFα 三聚体变形，当三聚体与 TNFR1 结合时会导致异常信号传导。TNF-α-IN-2 可用于类风湿关节炎的研究。

HY-P9979

Rozanolixizumab 洛利昔珠单抗	Inhibitor	99.34%
Rozanolixizumab (UCB7665) 是一种人源化的高亲和力抗人新生儿 Fc 受体 (FcRn) 单克隆抗体 (IgG4P)，用于降低自身免疫和同种免疫疾病中致病性 IgG 的研究。

HY-P9980

Belantamab 贝兰妥单抗	Inhibitor	99.90%
Belantamab (GSK2857914) 是一种人源化 IgG1 抗 BCMA (TNFRSF17) 单克隆抗体。Belantamab 可用于合成抗体-活性分子偶联物 (ADC)，Belantamab mafodotin。

HY-N6796

Manumycin A 手霉素A	Inhibitor	99.27%
Manumycin A 是一种聚酮类抗生素和硫氧还蛋白还原酶-1 (TrxR-1) 抑制剂。Manumycin A 可以通过 LC3 抑制乳腺癌细胞生长并发挥抗肿瘤活性。Manumycin A 可以下调 TNF α 刺激的人单核细胞中促炎细胞因子的释放，具有潜在抗炎活性。Manumycin A 可以抑制去势抵抗性前列腺癌细胞中的 Ras/Raf/ERK1/2 信号和 hnRNP H1 来抑制外泌体生物发生和分泌。

HY-122663A

BIO8898	Inhibitor	99.88%
BIO8898 是一种有效的 CD40-CD154 抑制剂。BIO8898 抑制可溶性 CD40L 与 CD40-Ig 的结合，IC₅₀ 值为 25 µM。BIO8898 抑制 CD40L 诱导的细胞凋亡(apoptosis)。

HY-116522

AR420626		98.29%
AR420626 是游离脂肪酸受体3 (FFAR3) 的选择性激动剂 (IC₅₀=117 nM)。AR420626 具有抗炎，抗癌和抗糖尿病活性。AR420626 通过抑制 nAChR 介导的神经通路，来改善神经源性腹泻疾病。AR420626 抑制 HepG2 异种移植物的生长，并通过诱导细胞凋亡 (apoptosis) 抑制肝癌细胞增殖。AR420626 还能够抑制过敏性哮喘和湿疹并具有激活 GPR41 增加 Ca²⁺ 信号介导的葡萄糖摄取和改善糖尿病的能力。

HY-N0509

Astilbin 落新妇苷	Inhibitor	99.97%
Astilbin 是一种黄酮类化合物，可增强 NRF2 活化。Astilbin 还抑制 TNF-α 表达和 NF-κB 活化。

TNF RIPK1 TRADD TRAF2/5 cIAP1/2 TNFR1 LUBAC TAB2 TAB3 TAK1 IKKβ NEMO IKKα RIPK1 CYLD RIPK1 RIPK1 TRADD FADD FADD Pro-caspase 8 Pro-caspase 8 Pro-caspase 8 Pro-caspase 8 Pro-caspase 8 Pro-caspase 8 Pro-caspase 8 Pro-caspase 8 Pro-caspase 8 Active
Caspase 8 Caspase 3/7 RIPK1 or
RIPK3 RIPK1 RIPK3 Apoptosis FADD RIPK1 RIPK3 FADD FLIP_L FLIP_L RIPK1 or
RIPK3 FLIP_L or FLIP_S FADD FADD RIPK1 RIPK3 RIPK3 RIPK3 MLKL MLKL MLKL AP1 TRAF1/2 cIAP1/2 MKK3 MKK1/7 p38 JNK CYLD IκB p50 p65 IκB NF-κB FLIP Bcl-X_L TNF TNFR2

Download TNF Receptor Signaling Pathway Map.

Following the binding of TNF to TNF receptors, TNFR1 binds to TRADD, which recruits RIPK1, TRAF2/5 and cIAP1/2 to form TNFR1 signaling complex I; TNFR2 binds to TRAF1/2 directly to recruit cIAP1/2. Both cIAP1 and cIAP2 are E3 ubiquitin ligases that add K63 linked polyubiquitin chains to RIPK1 and other components of the signaling complex. The ubiquitin ligase activity of the cIAPs is needed to recruit the LUBAC, which adds M1 linked linear polyubiquitin chains to RIPK1. K63 polyubiquitylated RIPK1 recruits TAB2, TAB3 and TAK1, which activate signaling mediated by JNK and p38, as well as the IκB kinase complex. The IKK complex then activates NF-κB signaling, which leads to the transcription of anti-apoptotic factors-such as FLIP and Bcl-XL-that promote cell survival.

The formation of TNFR1 complex IIa and complex IIb depends on non-ubiquitylated RIPK1. For the formation of complex IIa, ubiquitylated RIPK1 in complex I is deubiquitylated by CYLD. This deubiquitylated RIPK1 dissociates from the membrane-bound complex and moves into the cytosol, where it interacts with TRADD, FADD, Pro-caspase 8 and FLIPL to form complex IIa. By contrast, complex IIb is formed when the RIPK1 in complex I is not ubiquitylated owing to conditions that have resulted in the depletion of cIAPs, which normally ubiquitylate RIPK1. This non-ubiquitylated RIPK1 dissociates from complex I, moves into the cytosol, and assembles with FADD, Pro-caspase 8, FLIPL and RIPK3 (but not TRADD) to form complex IIb. For either complex IIa or complex IIb to prevent necroptosis, both RIPK1 and RIPK3 must be inactivated by the cleavage activity of the Pro-caspase 8-FLIPL heterodimer or fully activated caspase 8. The Pro-caspase 8 homodimer generates active Caspase 8, which is released from complex IIa and complex IIb. This active Caspase 8 then carries out cleavage reactions to activate downstream executioner caspases and thus induce classical apoptosis.

Formation of the complex IIc (necrosome) is initiated either by RIPK1 deubiquitylation mediated by CYLD or by RIPK1 non-ubiquitylation due to depletion of cIAPs, similar to complex IIa and complex IIb formation. RIPK1 recruits numerous RIPK3 molecules. They come together to form amyloid microfilaments called necrosomes. Activated RIPK3 phosphorylates and recruits MLKL, eventually leading to the formation of a supramolecular protein complex at the plasma membrane and necroptosis ^[1][2].

Reference:
[1]. Brenner D, et al. Regulation of tumour necrosis factor signalling: live or let die.Nat Rev Immunol. 2015 Jun;15(6):362-74.
[2]. Conrad M, et al. Regulated necrosis: disease relevance and therapeutic opportunities.Nat Rev Drug Discov. 2016 May;15(5):348-66.

TNF Receptor Isoform Comparison

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