Molecular Therapy: Nucleic Acids (Dec 2023)

A bimolecular modification strategy for developing long-lasting bone anabolic aptamer

  • Huarui Zhang,
  • Sifan Yu,
  • Shuaijian Ni,
  • Amu Gubu,
  • Yuan Ma,
  • Yihao Zhang,
  • Haitian Li,
  • Yuzhe Wang,
  • Luyao Wang,
  • Zongkang Zhang,
  • Yuanyuan Yu,
  • Aiping Lyu,
  • Baoting Zhang,
  • Ge Zhang

Journal volume & issue
Vol. 34
p. 102073

Abstract

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The molecular weight of nucleic acid aptamers (20 kDa) is lower than the cutoff threshold of the renal filtration (30–50 kDa), resulting in a very short half-life, which dramatically limits their druggability. To address this, we utilized 3-(2,5-dioxo-2,5-dihydro-1H-pyrrol-1-yl)-N-(4-hydroxy-2-oxo-2H-chromen-6-yl)propenamide (HC) and 12-((2,5-dioxopyrrolidin-1-yl)oxy)-12-oxododecanoic acid (DA), two newly designed coupling agents, for synergistic binding to human serum albumin (HSA). Both HC and DA are conjugated to a bone anabolic aptamer (Apc001) against sclerostin to form an Apc001OC conjugate with high binding affinity to HSA. Notably, HC and DA could synergistically facilitate prolonging the half-life of the conjugated Apc001 and promoting its bone anabolic potential. Using the designed blocking peptides, the mechanism studies indicate that the synergistic effect of HC-DA on pharmacokinetics and bone anabolic potential of the conjugated Apc001 is achieved via their synergistic binding to HSA. Moreover, biweekly Apc001OC at 50 mg/kg shows comparable bone anabolic potential to the marketed sclerostin antibody given weekly at 25 mg/kg. This proposed bimolecular modification strategy could help address the druggability challenge for aptamers with a short half-life.

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