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Yunn, Na-Oh,Kim, Jaeyoon,Kim, Youndong,Leibiger, Ingo,Berggren, Per-Olof,Ryu, Sung Ho Elsevier 2018 Pharmacology & therapeutics Vol.185 No.-
<P><B>Abstract</B></P> <P>The insulin receptor is an important regulator of metabolic processes in the body, and in particular of glucose homeostasis, including glucose uptake into peripheral tissues. Thus, insulin administration is an effective treatment for diabetes, which is characterized by chronic elevation of blood glucose. However, insulin is not only a metabolic regulator, but also functions as a growth hormone. Accordingly, studies of long-term insulin administration and of the hyperinsulinemia associated with type 2 diabetes have raised concerns about possible increases in the risks of cancer and atherosclerosis, due to excessive stimulation of cell proliferation. Interestingly, some insulin receptor ligands that have been developed based on a peptide, an antibody, and an aptamer selectively have metabolic effects exerted through the insulin receptor but do not cause significant cellular proliferation. Although these ligands therefore have potential as anti-diabetic drugs for advanced diabetes care, the mechanism whereby they specifically activate the insulin receptor is still unclear. Recently, studies of the structure of the insulin receptor have progressed considerably, and have provided further mechanistic understanding of insulin receptor activation. Based on this progress, we propose a mechanistic model of this specificity and discuss the potential for the development of novel anti-diabetic drugs that would not have the adverse effects caused by excessive mitogenic action.</P>
Yunn, Na-Oh,Koh, Ara,Han, Seungmin,Lim, Jong Hun,Park, Sehoon,Lee, Jiyoun,Kim, Eui,Jang, Sung Key,Berggren, Per-Olof,Ryu, Sung Ho Oxford University Press 2015 Nucleic acids research Vol.43 No.16
<P>Due to their high affinity and specificity, aptamers have been widely used as effective inhibitors in clinical applications. However, the ability to activate protein function through aptamer-protein interaction has not been well-elucidated. To investigate their potential as target-specific agonists, we used SELEX to generate aptamers to the insulin receptor (IR) and identified an agonistic aptamer named IR-A48 that specifically binds to IR, but not to IGF-1 receptor. Despite its capacity to stimulate IR autophosphorylation, similar to insulin, we found that IR-A48 not only binds to an allosteric site distinct from the insulin binding site, but also preferentially induces Y1150 phosphorylation in the IR kinase domain. Moreover, Y1150-biased phosphorylation induced by IR-A48 selectively activates specific signaling pathways downstream of IR. In contrast to insulin-mediated activation of IR, IR-A48 binding has little effect on the MAPK pathway and proliferation of cancer cells. Instead, AKT S473 phosphorylation is highly stimulated by IR-A48, resulting in increased glucose uptake both <I>in vitro</I> and <I>in vivo</I>. Here, we present IR-A48 as a biased agonist able to selectively induce the metabolic activity of IR through allosteric binding. Furthermore, our study also suggests that aptamers can be a promising tool for developing artificial biased agonists to targeted receptors.</P>
Yunn Na-Oh,Lee Jimin,Lee Hye Sun,Oh Eun Ju,Park Mangeun,Park Seongeun,진서연,Shin Euisu,Lee Jo woon yi,Kim Youndong,배순식,Ryu Sung Ho 생화학분자생물학회 2022 Experimental and molecular medicine Vol.54 No.-
Aptamers are widely used as binders that interact with targets with high affinity or as inhibitors of the function of target molecules. However, they have also been used to modulate target protein function, which they achieve by activating the target or stabilizing its conformation. Here, we report a unique aptamer modulator of the insulin receptor (IR), IR-A62. Alone, IR-A62 acts as a biased agonist that preferentially induces Y1150 monophosphorylation of IR. However, when administered alongside insulin, IR-A62 shows variable binding cooperativity depending on the ligand concentration. At low concentrations, IR-A62 acts as a positive allosteric modulator (PAM) agonist that enhances insulin binding, but at high concentrations, it acts as a negative allosteric modulator (NAM) agonist that competes with insulin for IR. Moreover, the concentration of insulin affects the binding of IR-A62 to IR. Finally, the subcutaneous administration of IR-A62 to diabetic mice reduces blood glucose levels with a longer-lasting effect than insulin administration. These findings imply that aptamers can elicit various responses from receptors beyond those of a simple agonist or inhibitor. We expect further studies of IR-A62 to help reveal the mechanism of IR activation and greatly expand the range of therapeutic applications of aptamers.
A stepwise activation model for the insulin receptor
Yunn Na-Oh,Kim Junhong,Ryu Sung Ho,Cho Yunje 생화학분자생물학회 2023 Experimental and molecular medicine Vol.55 No.-
The binding of insulin to the insulin receptor (IR) triggers a cascade of receptor conformational changes and autophosphorylation, leading to the activation of metabolic and mitogenic pathways. Recent advances in the structural and functional analyses of IR have revealed the conformations of the extracellular domains of the IR in inactive and fully activated states. However, the early activation mechanisms of this receptor remain poorly understood. The structures of partially activated IR in complex with aptamers provide clues for understanding the initial activation mechanism. In this review, we discuss the structural and functional features of IR complexed with various ligands and propose a model to explain the sequential activation mechanism. Moreover, we discuss the structures of IR complexed with biased agonists that selectively activate metabolic pathways and provide insights into the design of selective agonists and their clinical implications.