Department of Biochemistry, Eötvös Loránd University, Budapest and Martonvásár, Hungary (M.G., K.O., I.L., Z.B., M.K., A.M.-C.); MTA-ELTE Motor Pharmacology Research Group, Budapest, Hungary (M.G., M.K., A.M.-C.); Motorharma Ltd., Budapest, Hungary (A.Á.R.); Printnet Ltd., Budapest, Hungary (S.K.S., I.L.); Plant Protection Institute, Centre for Agricultural Research, Martonvásár, Hungary (K.Á.H.); Metabolic Drug Interactions Research Group, Institute of Enzymology, Research Centre for Natural Sciences, Budapest, Hungary (M.T.D., Á.F.K., K.M.); Research Centre for Natural Sciences, Instrumentation Center, MS Metabolomic Research Laboratory, Budapest, Hungary (P.T.S.); Department of Biology, MyoKardia Inc., Brisbane, California (S.N., I.T.); Department of Neuroscience, Western New England University, Springfield, Massachusetts (J.K., P.J.T.); and Central Hospital of Southern Pest, National Institute of Hematology and Infectious Diseases, Budapest, Hungary (L.K.).
Department of Biochemistry, Eötvös Loránd University, Budapest and Martonvásár, Hungary (M.G., K.O., I.L., Z.B., M.K., A.M.-C.); MTA-ELTE Motor Pharmacology Research Group, Budapest, Hungary (M.G., M.K., A.M.-C.); Motorharma Ltd., Budapest, Hungary (A.Á.R.); Printnet Ltd., Budapest, Hungary (S.K.S., I.L.); Plant Protection Institute, Centre for Agricultural Research, Martonvásár, Hungary (K.Á.H.); Metabolic Drug Interactions Research Group, Institute of Enzymology, Research Centre for Natural Sciences, Budapest, Hungary (M.T.D., Á.F.K., K.M.); Research Centre for Natural Sciences, Instrumentation Center, MS Metabolomic Research Laboratory, Budapest, Hungary (P.T.S.); Department of Biology, MyoKardia Inc., Brisbane, California (S.N., I.T.); Department of Neuroscience, Western New England University, Springfield, Massachusetts (J.K., P.J.T.); and Central Hospital of Southern Pest, National Institute of Hematology and Infectious Diseases, Budapest, Hungary (L.K.)
J Pharmacol Exp Ther. 2021 Mar;376(3):358-373. doi: 10.1124/jpet.120.000167. Epub 2021 Jan 19.
Blebbistatin, -nitroblebbistatin (NBleb), and -aminoblebbistatin (AmBleb) are highly useful tool compounds as they selectively inhibit the ATPase activity of myosin-2 family proteins. Despite the medical importance of the myosin-2 family as drug targets, chemical optimization has not yet provided a promising lead for drug development because previous structure-activity-relationship studies were limited to a single myosin-2 isoform. Here we evaluated the potential of blebbistatin scaffold for drug development and found that D-ring substitutions can fine-tune isoform specificity, absorption-distribution-metabolism-excretion, and toxicological properties. We defined the inhibitory properties of NBleb and AmBleb on seven different myosin-2 isoforms, which revealed an unexpected potential for isoform specific inhibition. We also found that NBleb metabolizes six times slower than blebbistatin and AmBleb in rats, whereas AmBleb metabolizes two times slower than blebbistatin and NBleb in human, and that AmBleb accumulates in muscle tissues. Moreover, mutagenicity was also greatly reduced in case of AmBleb. These results demonstrate that small substitutions have beneficial functional and pharmacological consequences, which highlight the potential of the blebbistatin scaffold for drug development targeting myosin-2 family proteins and delineate a route for defining the chemical properties of further derivatives to be developed. SIGNIFICANCE STATEMENT: Small substitutions on the blebbistatin scaffold have beneficial functional and pharmacological consequences, highlighting their potential in drug development targeting myosin-2 family proteins.
布莱西斯他汀、-硝基布莱西斯他汀(NBleb)和 -氨基布莱西斯他汀(AmBleb)是非常有用的工具化合物,因为它们选择性地抑制肌球蛋白-2 家族蛋白的 ATP 酶活性。尽管肌球蛋白-2 家族作为药物靶点具有重要的医学意义,但化学优化尚未为药物开发提供有前途的先导化合物,因为之前的结构-活性关系研究仅限于单一的肌球蛋白-2 同工型。在这里,我们评估了布莱西斯他汀骨架在药物开发中的潜力,发现 D 环取代可以微调同工型特异性、吸收分布代谢排泄和毒理学性质。我们定义了 NBleb 和 AmBleb 对七种不同肌球蛋白-2 同工型的抑制特性,这揭示了同工型特异性抑制的意外潜力。我们还发现,NBleb 在大鼠中的代谢速度比布莱西斯他汀和 AmBleb 慢六倍,而 AmBleb 在人体中的代谢速度比布莱西斯他汀和 NBleb 慢两倍,并且 AmBleb 在肌肉组织中积累。此外,AmBleb 的致突变性也大大降低。这些结果表明,小取代具有有益的功能和药理学后果,突出了布莱西斯他汀骨架在针对肌球蛋白-2 家族蛋白的药物开发中的潜力,并为进一步开发的衍生化合物的化学性质定义了一条途径。意义陈述:布莱西斯他汀骨架上的小取代具有有益的功能和药理学后果,突出了它们在针对肌球蛋白-2 家族蛋白的药物开发中的潜力。
