Background: The activation of hepatic stellate cells play a pivotal role in the pathogenesis of hepatic fibrosis. However, the current lack of specifically identified targets on these cells poses a significant challenge in developing targeted delivery tools for effective anti-hepatic fibrosis therapeutics in clinical practice.
Methods: Cell-systematic evolution of ligands by exponential enrichment method was conducted on HSC-T6 cell line to screen out activated hepatic stellate cell-specific aptamers. The specificity of the selected aptamers in targeting hepatic stellate cells was confirmed after truncation optimization. Furthermore, the optimal aptamer was conjugated with miR-23b-5p via C6 linkage to evaluate the targeting specificity of this complex and assess its potential in downregulating liver fibrosis-related proteins and slowing down the progression of liver fibrosis.
Results: The present study successful identified 11 highly enriched single-stranded DNA sequences (APT1-11) that specifically target activated hepatic stellate cells. Subsequent affinity detection and optimization truncation led to the selection of APT8(16-34), which effectively targeted activated hepatic stellate cells both in vivo and in vitro. Moreover, when conjugated with miR-23b-5p, APT8(16-34) also exhibited internalization ability into activated hepatic stellate cells. The delivered cargo miR-23b-5p by APT8 (16-34) effectively targeted to mRNA, leading to translational inhibition and subsequent downregulation of related proteins.
Conclusions: We have identified APT8 (16- 34), which exhibits specific targeting and internalization capabilities into activated hepatic stellate cells. Moreover, when conjugated with miR-23b-5p, APT8 (16-34) also internalizes into activated hepatic stellate cells, enabling miR-23b-5p exert their respective functions.
Keywords: Aptamer; Hepatic fibrosis; Hepatic stellate cell; miR-23b-5p.
© 2024. Asian Pacific Association for the Study of the Liver.