Rujito Lantip, Wardana Tirta, Siswandari Wahyu, Nainggolan Ita Margaretha, Sasongko Teguh Haryo
Department of Genetics and Molecular Medicine, Faculty of Medicine, Universitas Jenderal Soedirman, Purwokerto, Indonesia.
Department of Clinical Pathology, Faculty of Medicine, Universitas Jenderal Soedirman, Purwokerto, Indonesia.
J Clin Med Res. 2024 Sep;16(9):411-422. doi: 10.14740/jocmr5245. Epub 2024 Aug 22.
Thalassemia encompasses a group of inherited hemoglobin disorders characterized by reduced or absent production of the α- or β-globin chains, leading to anemia and other complications. Current management relies on lifelong blood transfusions and iron chelation, which is burdensome for patients. This review summarizes the emerging therapeutic potential of modulating microRNAs (miRNAs) to treat thalassemia. MiRNAs are small non-coding RNAs that regulate gene expression through sequence-specific binding to messenger RNAs (mRNAs). While they commonly repress gene expression by binding to the 3' untranslated regions (UTRs) of target mRNAs, miRNAs can also interact with 5'UTRs and gene promoters to activate gene expression. Many miRNAs are now recognized as critical regulators of erythropoiesis and are abnormally expressed in β-thalassemia. Therapeutically restoring levels of deficient miRNAs or inhibiting overexpression through miRNA mimics or inhibitors (antagomir), respectively, has shown preclinical efficacy in ameliorating thalassemic phenotypes. The miR-144/451 cluster is especially compelling for targeted upregulation to reactivate fetal hemoglobin synthesis. Advances in delivery systems are addressing previous challenges in stability and targeting of miRNA-based drugs. While still early, gene therapy studies suggest combinatorial approaches with miRNA modulation may provide synergistic benefits. Several key considerations remain including enhancing delivery, minimizing off-target effects, and demonstrating long-term safety and efficacy. While no miRNA therapies have yet progressed to clinical testing for thalassemia specifically, important lessons are being learned through clinical trials for other diseases and conditions, such as cancer, cardiovascular diseases, and viral. If limitations can be overcome through multi-disciplinary collaboration, miRNAs hold great promise to expand and transform treatment options for thalassemia in the future by precisely targeting pathogenic molecular networks. Ongoing innovations, such as advancements in miRNA delivery systems, improved targeting mechanisms, and enhanced understanding of miRNA biology, continue to drive progress in this emerging field towards realizing the clinical potential of miRNA-based medicines for thalassemia patients.
地中海贫血是一组遗传性血红蛋白疾病,其特征是α或β珠蛋白链生成减少或缺失,导致贫血和其他并发症。目前的治疗依赖于终身输血和铁螯合,这对患者来说负担沉重。本综述总结了调节微小RNA(miRNA)治疗地中海贫血的新兴治疗潜力。miRNA是小的非编码RNA,通过与信使RNA(mRNA)的序列特异性结合来调节基因表达。虽然它们通常通过与靶mRNA的3'非翻译区(UTR)结合来抑制基因表达,但miRNA也可以与5'UTR和基因启动子相互作用以激活基因表达。现在许多miRNA被认为是红细胞生成的关键调节因子,并且在β地中海贫血中异常表达。分别通过miRNA模拟物或抑制剂(抗miR)治疗性恢复缺陷miRNA的水平或抑制过表达,已在改善地中海贫血表型方面显示出临床前疗效。miR-144/451簇对于靶向上调以重新激活胎儿血红蛋白合成特别有吸引力。递送系统的进展正在解决基于miRNA的药物在稳定性和靶向性方面以前面临的挑战。虽然仍处于早期阶段,但基因治疗研究表明,与miRNA调节的联合方法可能会提供协同效益。仍有几个关键问题需要考虑,包括增强递送、最小化脱靶效应以及证明长期安全性和有效性。虽然尚无miRNA疗法专门进展到地中海贫血的临床试验,但正在通过针对其他疾病和病症(如癌症、心血管疾病和病毒感染)的临床试验吸取重要经验教训。如果能够通过多学科合作克服这些限制,miRNA有望在未来通过精确靶向致病分子网络来扩展和改变地中海贫血的治疗选择。正在进行的创新,如miRNA递送系统的进展、改进的靶向机制以及对miRNA生物学的深入理解,继续推动这一新兴领域的进展,以实现基于miRNA的药物对地中海贫血患者的临床潜力。
