Exploring Baltic Sea cyanobacteria for small-molecule inhibitors of microRNA function: a project description

P. Brzuzan, H. Marzec, F. Stefaniak, M. Woźny, M. Florczyk
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Abstract

Cyanobacteria constitute a rich source of biologically active and structurally diverse compounds. The pharmacological potential of these compounds resides among others in their ability to control the proliferation and growth of cancer cell lines and potent disease-causing microbial agents. Despite recent scientific advances, the way these compounds interact with the body’s molecular structure are still unclear and science still has to discover how the cyanobacterial metabolites interact with cell structures and how cells react to them. In this project, we will study yet unexamined cyanobacterial metabolites, especially the compounds which act as chemical ligands for microRNA (miRNA) -binding sites, making them promising regulators (inhibitors) of gene networks that are involved in various diseases. We will first develop a stable cell line that constitutively expresses a unique miRNA reporter system. Then, we will conduct a screen on chemical compounds discovered in Baltic cyanobacteria to identify small molecules with inhibitory activity and specificity to MIR92b-3p, which has a significant impact on liver cell behavior in humans. We assume that a successful MIR92b-3p inhibitor will bind to the precursors of MIR92b-3p miRNA, disabling the action of either of the two processing enzymes involved in the biogenesis of any miRNA in a cell (Drosha or Dicer), thus affecting the MIR92b function. The discoveries made with these inhibitory chemical molecules could provide insight into the role of the MIR92 pathway in liver diseases and cancer, and possibly, if promising results appear, they may facilitate a strategy for treating some human diseases in the future.
探索波罗的海蓝藻的小分子抑制剂microRNA功能:一个项目描述
蓝藻构成了丰富的生物活性和结构多样的化合物来源。这些化合物的药理潜力在于它们能够控制癌细胞系和强效致病微生物剂的增殖和生长。尽管最近的科学进步,这些化合物与人体分子结构相互作用的方式仍然不清楚,科学仍然需要发现蓝藻代谢物如何与细胞结构相互作用以及细胞如何对它们作出反应。在这个项目中,我们将研究尚未被检测的蓝藻代谢产物,特别是作为microRNA (miRNA)结合位点的化学配体的化合物,使它们成为参与各种疾病的基因网络的有前途的调节剂(抑制剂)。我们将首先开发一个稳定的细胞系,组成表达一个独特的miRNA报告系统。然后,我们将对在波罗的海蓝藻中发现的化合物进行筛选,以确定对MIR92b-3p具有抑制活性和特异性的小分子,MIR92b-3p对人类肝细胞行为有重大影响。我们假设一个成功的MIR92b-3p抑制剂将结合MIR92b-3p miRNA的前体,使细胞中参与任何miRNA生物发生的两种加工酶(Drosha或Dicer)中的任何一种的作用失效,从而影响MIR92b的功能。这些抑制性化学分子的发现可以让我们深入了解MIR92通路在肝脏疾病和癌症中的作用,如果有希望的结果出现,它们可能会促进未来治疗某些人类疾病的策略。
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