Center for Biopharmaceuticals & Department of Drug Design and Pharmacology, Faculty of Health and Medical Sciences , University of Copenhagen , DK-2100 Copenhagen , Denmark.
Chemical Neurobiology Laboratory, Center for Genomic Medicine, Departments of Neurology & Psychiatry , Massachusetts General Hospital and Harvard Medical School , 185 Cambridge Street , Boston , Massachusetts 02114 , United States.
ACS Chem Neurosci. 2019 Aug 21;10(8):3769-3777. doi: 10.1021/acschemneuro.9b00281. Epub 2019 Aug 5.
Histone deacetylases (HDACs) are enzymes involved in the epigenetic control of gene expression. A handful of HDAC inhibitors have been approved for the treatment of cancer, and HDAC inhibition has also been proposed as a novel therapeutic strategy for neurodegenerative disorders. These disorders include progranulin (PGRN)-deficient forms of frontotemporal dementia caused by mutations in the gene that lead to haploinsufficiency. Hydroxamic-acid-based inhibitors of HDACs 1-3, reported to have fast-on/fast-off binding kinetics, induce increased expression of PGRN in human neuronal models, while the benzamide class of slow-binding HDAC inhibitors does not produce this effect. These observations indicate that the kinetics of HDAC inhibitor binding can be tuned for optimal induction of human PGRN expression in neurons. Here, we further expand on these findings using human cortical-like, glutamatergic neurons. We provide evidence that two prototypical, potent hydroxamic acid HDAC inhibitors that induce PGRN (panobinostat and trichostatin A) exhibit an initial fast-binding step followed by a second, slower step, referred to as mechanism B of slow binding, rather than simpler fast-on/fast-off binding kinetics. In addition, we show that trapoxin A, a macrocyclic, epoxyketone-containing class I HDAC inhibitor, exhibits slow binding with high, picomolar potency and also induces PGRN expression in human neurons. Finally, we demonstrate induction of PGRN expression by fast-on/fast-off, highly potent, macrocyclic HDAC inhibitors with ethyl ketone or ethyl ester Zn binding groups. Taken together, these data expand our understanding of HDAC1-3 inhibitor binding kinetics, and further delineate the specific combinations of structural and kinetic features of HDAC inhibitors that are optimal for upregulating PGRN expression in human neurons and thus may have translational relevance in neurodegenerative disease.
组蛋白去乙酰化酶(HDACs)是参与基因表达表观遗传调控的酶。一些 HDAC 抑制剂已被批准用于癌症治疗,HDAC 抑制也被提议作为神经退行性疾病的新治疗策略。这些疾病包括由导致单倍体不足的基因突变引起的颗粒蛋白前体(PGRN)缺陷型额颞叶痴呆。报道称,HDAC1-3 的基于羟肟酸的抑制剂具有快速结合/快速解离的结合动力学,可诱导人神经元模型中 PGRN 的表达增加,而苯甲酰胺类缓慢结合的 HDAC 抑制剂则不会产生这种效果。这些观察结果表明,可以调整 HDAC 抑制剂结合的动力学,以在神经元中最佳诱导人 PGRN 的表达。在这里,我们使用人皮质样谷氨酸能神经元进一步扩展了这些发现。我们提供的证据表明,两种诱导 PGRN 的典型、强效羟肟酸 HDAC 抑制剂(panobinostat 和 trichostatin A)表现出初始快速结合步骤,随后是第二个较慢的步骤,称为缓慢结合的机制 B,而不是更简单的快速结合/快速解离动力学。此外,我们还表明,微管蛋白 A,一种含有大环、环氧酮的 I 类 HDAC 抑制剂,表现出缓慢结合,具有高皮摩尔效力,并且还诱导人神经元中 PGRN 的表达。最后,我们证明了具有快速结合/快速解离、高效力、大环 HDAC 抑制剂的乙基酮或乙酯 Zn 结合基团诱导 PGRN 表达。总之,这些数据扩展了我们对 HDAC1-3 抑制剂结合动力学的理解,并进一步描绘了最佳上调人神经元中 PGRN 表达的 HDAC 抑制剂的结构和动力学特征的具体组合,因此可能在神经退行性疾病中具有转化相关性。
