Chemoenzymatic synthesis, computational investigation, and antitumor activity of monocyclic lankacidin derivatives

Rukman Muslimin, Natsumi Nishiura, Aiko Teshima, Kiep Minh Do, Takeshi Kodama, Hiroyuki Morita, Cody Wayne Lewis, Gordon Chan, Ahmed Taha Ayoub, Kenji Arakawa

研究成果: ジャーナルへの寄稿学術論文査読

抄録

We investigated the importance of the δ-lactone ring (C1–C5) in lankacidin C using chemoenzymatic synthesis and computational prediction and assessing biological activity, including antitumor activity. Pyrroloquinoline quinone-dependent dehydrogenase (Orf23) in Streptomyces rochei was used in the chemoenzymatic synthesis of lankacyclinone C, a novel lankacidin C congener lacking the δ-lactone moiety. Orf23 could convert the monocyclic lankacidinol derivatives, lankacyclinol and 2-epi-lankacyclinol, to the C-24 keto compounds, lankacyclinone C and 2-epi-lankacyclinone C, respectively, elucidating the relaxed substrate specificity of Orf23. Computational prediction using molecular dynamics simulations and the molecular mechanics/generalized Born-surface area protocol indicated that binding energy values of all the monocyclic derivatives are very close to those of lankacidin C, which may reflect a comparable affinity to tubulin. Monocyclic lankacidin derivatives showed moderate antitumor activity when compared with bicyclic lankacidins, suggesting that the δ-lactone moiety is less important for antitumor activity in lankacidin-group antibiotics.
本文言語日本
ジャーナルBioorganic and Medicinal Chemistry
53
DOI
出版ステータス出版済み - 2022/01/01

キーワード

  • Antitumor activity
  • Carbocyclic polyketide
  • Chemoenzymatic synthesis
  • Computational prediction
  • Drug design
  • Pyrroloquinoline quinone-dependent dehydrogenase

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