McDonald E R, Chui P C, Martelli P F, Dicker D T, El-Deiry W S
Laboratory of Molecular Oncology and Cell Cycle Regulation, Howard Hughes Medical Institute, Departments of Medicine, Genetics, and Pharmacology, and the Cancer Center, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104, USA.
J Biol Chem. 2001 May 4;276(18):14939-45. doi: 10.1074/jbc.M100399200. Epub 2001 Feb 13.
The Fas/tumor necrosis factor (TNF)/TRAIL receptors signal death through a cytoplasmic death domain (DD) containing six alpha-helices with positively charged helix 2 interacting with negatively charged helix 3 of another DD. DD mutation occurs in head/neck and lung cancer (TRAIL receptor KILLER/DR5) and in lpr mice (Fas). We examined the apoptotic potential of known KILLER/DR5 lung tumor-derived mutants (n = 6) and DD mutants (n = 18) generated based on conservation with DR4, Fas, Fas-associated death domain (FADD), and tumor necrosis factor receptor 1 (TNFR1). With the exception of Arg-330 required in Fas or FADD for aggregation or for TNFR1 cytotoxicity, surprisingly major loss-of-function KILLER/DR5 alleles (W325A, L334A (lpr-like), I339A, and W360A) contained hydrophobic residues. Loss-of-function of I339A (highly conserved) has not been reported in DDs. Charged residue mutagenesis revealed the following points. 1) E326A, conserved in DR4, is dispensable for death; the homologous residue is positively charged in Fas, TNFR1, and FADD and is critical for DD interactions. 2) K331A, D336A, E338A, K340A, K343A, and D351A have partial loss-of-function suggesting multiple charges stabilize receptor-adapter interactions. Analysis of the tumor-derived KILLER/DR5 mutants revealed the following. 1) L334F has partial loss-of-function versus L334A, whereas E338K has major loss-of-function versus E338A, examples where alanine and tumor-specific substitutions have divergent phenotypes. 2) Unexpectedly, S324F, E326K, K386N, and D407Y have no loss-of-function with tumor-specific or alanine substitutions. Loss-of-function KILLER/DR5 mutants were deficient in recruitment of FADD and caspase 8 to TRAIL death-inducing signaling complexes. The results reveal determinants within KILLER/DR5 for death signaling and drug design.
Fas/肿瘤坏死因子(TNF)/TRAIL受体通过一个细胞质死亡结构域(DD)发出死亡信号,该结构域包含六个α螺旋,带正电荷的螺旋2与另一个DD的带负电荷的螺旋3相互作用。DD突变发生在头颈癌和肺癌(TRAIL受体KILLER/DR5)以及lpr小鼠(Fas)中。我们检测了已知的源自KILLER/DR5肺肿瘤的突变体(n = 6)和基于与DR4、Fas、Fas相关死亡结构域(FADD)和肿瘤坏死因子受体1(TNFR1)的保守性而产生的DD突变体(n = 18)的凋亡潜力。除了Fas或FADD中聚集或TNFR1细胞毒性所需的Arg-330外,令人惊讶的是,主要的功能丧失型KILLER/DR5等位基因(W325A、L334A(类似lpr)、I339A和W360A)都含有疏水残基。I339A(高度保守)的功能丧失在DD中尚未见报道。带电残基诱变揭示了以下几点。1)在DR4中保守的E326A对死亡是可有可无的;同源残基在Fas、TNFR1和FADD中带正电荷,对DD相互作用至关重要。2)K331A、D336A、E338A、K340A、K343A和D351A具有部分功能丧失,表明多个电荷稳定受体-衔接子相互作用。对源自肿瘤的KILLER/DR5突变体的分析揭示了以下几点。1)与L334A相比,L334F具有部分功能丧失,而与E338A相比,E338K具有主要功能丧失,这是丙氨酸和肿瘤特异性取代具有不同表型的例子。2)出乎意料的是,S324F、E326K、K386N和D407Y在肿瘤特异性或丙氨酸取代时没有功能丧失。功能丧失型KILLER/DR5突变体在将FADD和半胱天冬酶8募集到TRAIL死亡诱导信号复合物方面存在缺陷。结果揭示了KILLER/DR5中死亡信号和药物设计的决定因素。
