School of Physics and Electronics, Shandong Normal University, Jinan, 250014, China.
Phys Chem Chem Phys. 2022 Jul 13;24(27):16799-16815. doi: 10.1039/d2cp01780f.
Inhibitors that competitively bind MDM2/MDMX can block the inhibition of P53 by MDM2/MDMX and restart its tumor-suppressive effect. Molecular studies targeting MDM2/MDMX inhibitors have always been a hot topic in anticancer drug design. Although numerous inhibitors have been designed previously against MDM2/MDMX, their dual inhibition efficacy has not been demonstrated, and few studies assessed the general causes affecting the dual inhibition of MDM2/MDMX by these inhibitors. Here, molecular dynamics simulations and alanine scanning combined with the interaction entropy method were employed to precisely investigate whether 16 inhibitors could dually inhibit MDM2/MDMX and the similarities and differences in the interaction modes. Thereby addressing the key residue sites affecting dual inhibition. Residues L54/M53, I61/60, M62/61, Y67/66, and V93/92 of MDM2/MDMX, which are in corresponding positions in both protein structures, provide significant conditions for these inhibitors to bind to MDM2/MDMX tightly. In addition, most of these inhibitors prefer to bind MDM2 than MDMX, and residues H96 and I99 in MDM2 are attractive targets for inhibitors, resulting in inhibitors binding to MDM2/MDMX with different affinity. These key residues should be considered in the development of dual inhibitors. For these 16 inhibitors, most have dual inhibitory potential for MDM2/MDMX based on the binding affinity of the complexes. Still, it is questionable whether they can exert excellent dual inhibition considering the assessment of the hot-spots. At least their binding affinity for MDMX is not superior to that for MDM2 due to the difference in energy of the van der Waals interactions at the key sites. Furthermore, based on the analysis of three representative inhibitors (TUZ/HRH and HRQ with different binding preferences for MDM2/MDMX), 3-chloropyridine in TUZ leads to the differential binding affinity between the inhibitor and MDM2/MDMX. It readily forms hydrophobic interactions with the surrounding residues H96 and I99. But this phenomenon does not occur in the TUZ-MDMX system, implying the critical role of residues H96/P95 and I99/L98. And the completely different binding mechanism of HRQ binding to MDM2/MDMX explains its inability to inhibit MDM2 well. Thus, we are cautious about its dual inhibitory ability. Besides, HRH is more prone to strong van der Waals interactions with MDM2 than MDMX whereas its 2-chlorofluorobenzene is detrimental to this. We hope that these findings will provide reliable molecular insights for the screening and optimization of targeting MDM2/MDMX dual inhibitors.
能够与 MDM2/MDMX 竞争性结合的抑制剂可以阻断 MDM2/MDMX 对 P53 的抑制作用,从而重新发挥其肿瘤抑制作用。针对 MDM2/MDMX 抑制剂的分子研究一直是抗癌药物设计的热门话题。尽管以前已经设计了许多针对 MDM2/MDMX 的抑制剂,但它们的双重抑制效果尚未得到证实,并且很少有研究评估这些抑制剂对 MDM2/MDMX 双重抑制的一般影响因素。在这里,我们使用分子动力学模拟和丙氨酸扫描结合相互作用熵方法,精确研究了 16 种抑制剂是否能够双重抑制 MDM2/MDMX,以及它们在相互作用模式上的异同,从而确定影响双重抑制的关键残基位点。MDM2/MDMX 的残基 L54/M53、I61/60、M62/61、Y67/66 和 V93/92 位于两种蛋白质结构中的对应位置,为这些抑制剂与 MDM2/MDMX 紧密结合提供了重要条件。此外,这些抑制剂大多数更喜欢与 MDM2 结合,而不是与 MDMX 结合,并且 MDM2 中的残基 H96 和 I99 是抑制剂的有吸引力的靶标,导致抑制剂与 MDM2/MDMX 具有不同的亲和力。在开发双重抑制剂时,这些关键残基都应考虑在内。对于这 16 种抑制剂,大多数基于复合物的结合亲和力都具有 MDM2/MDMX 的双重抑制潜力。但是,考虑到热点评估,它们是否能够发挥出色的双重抑制作用仍值得怀疑。至少由于关键位点范德华相互作用的能量差异,它们对 MDMX 的结合亲和力并不优于对 MDM2 的结合亲和力。此外,基于对三种代表性抑制剂(TUZ/HRH 和 HRQ,它们对 MDM2/MDMX 具有不同的结合偏好)的分析,TUZ 中的 3-氯吡啶导致抑制剂与 MDM2/MDMX 之间的差异结合亲和力。它容易与周围的残基 H96 和 I99 形成疏水相互作用。但是这种现象在 TUZ-MDMX 系统中不会发生,这意味着残基 H96/P95 和 I99/L98 的关键作用。而 HRQ 与 MDM2/MDMX 结合的完全不同的结合机制解释了它不能很好地抑制 MDM2 的原因。因此,我们对其双重抑制能力持谨慎态度。此外,HRH 与 MDM2 比 MDMX 更容易发生强烈的范德华相互作用,而其 2-氯氟苯则不利于这种相互作用。我们希望这些发现为靶向 MDM2/MDMX 双重抑制剂的筛选和优化提供可靠的分子见解。
