A DNA aptamer to c-Met inhibits cancer cell migration

Ueki, Ryosuke; Sando, Shinsuke

doi:10.1039/c4cc06016d

Cited by 90 publications

(119 citation statements)

References 20 publications

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“…The aptamer CLN3 is the only known c‐met‐binding DNA aptamer. The minimal binding domain of CLN3, SL1, was found to retain high binding affinity for c‐met and blocked the HGF/c‐met interaction and c‐met signaling in SNU‐5 cells . In this study, we demonstrate that SL1 has high specificity and affinity to membrane‐bound c‐met in MM.…”

Section: Discussionmentioning

confidence: 61%

“…In addition to binding cellular c‐met, we found that SL1 possesses tumour inhibitory activity. Ueki et al reported that SL1 inhibits metastasis‐related behaviour, such as the scattering and migration of SNU‐5 cells . Similarly, Piater et al described a truncated version of CLN3 (CLN3‐T) that suppressed HGF‐induced migration of NCI‐H441 cells and invasion of MDA‐MB‐231 cells and inhibited c‐met phosphorylation .…”

Section: Discussionmentioning

confidence: 99%

“…Recently, DNA aptamer CLN0003 (CLN3) was isolated from Jurkat cells via Cell‐ SELEX and was found to bind c‐met with high specificity and affinity . Ueki et al identified the 50‐mer minimal binding motif of CLN3 (SL1) that retained high c‐met affinity and interfered with HGF binding to c‐met in SNU‐5 cells . However, whether SL1 can become the first aptamer to target c‐met in MM requires further investigation.…”

Section: Introductionmentioning

confidence: 99%

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Targeting c‐met receptor tyrosine kinase by the DNA aptamer SL1 as a potential novel therapeutic option for myeloma

Zhang

Gao

Zhou

et al. 2018

J Cellular Molecular Medi

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Hepatocyte growth factor (HGF)/c‐met pathway activation has been implicated in the pathogenesis of multiple myeloma (MM), and blocking this pathway has been considered a rational therapeutic strategy for treating MM. Aptamers are single‐stranded nucleic acid molecules that fold into complex 3D structures and bind to a variety of targets. Recently, it was reported that DNA aptamer SL1 exhibited high specificity and affinity for c‐met and inhibited HGF/c‐met signaling in SNU‐5 cells. However, as the first c‐met‐targeted DNA aptamer to be identified, application of SL1 to myeloma treatment requires further investigation. Here, we explore the potential application of SL1 in MM. Our results indicated that c‐met expression is gradually increased in MM patients and contributes to poor outcomes. SL1 selectively bound to c‐met‐positive MM cells but not to normal B cells and suppressed the growth, migration and adhesion of MM cells in vitro in a co‐culture model performed with HS5 cells, wherein SL1 inhibited HGF‐induced activation of c‐met signaling. In vivo and ex vivo fluorescence imaging showed that SL1 accumulated in the c‐met positive tumour areas. In addition, SL1 was active against CD138+ primary MM cells and displayed a synergistic inhibition effect with bortezomib. Collectively, our data suggested that SL1 could be beneficial as a c‐met targeted antagonist in MM.

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Section: Discussionmentioning

confidence: 61%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Targeting c‐met receptor tyrosine kinase by the DNA aptamer SL1 as a potential novel therapeutic option for myeloma

Zhang

Gao

Zhou

et al. 2018

J Cellular Molecular Medi

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“…[5] The functions of RTKs are mainly determined by ligand-dependent receptor dimerization and autophosphorylation to initiate downstream signaling cascades. AD -CID nanodevice is composed of two subunits,asensor (S)and an actuator (A), hooking on the extracellular region of c-Met via the specific aptamer, [11] generating two DNA-based chimeric receptors (Figure 1a;s ee also the Supporting Information, Figure S1). AD -CID nanodevice is composed of two subunits,asensor (S)and an actuator (A), hooking on the extracellular region of c-Met via the specific aptamer, [11] generating two DNA-based chimeric receptors (Figure 1a;s ee also the Supporting Information, Figure S1).…”

mentioning

confidence: 99%

“…[11] Based on the finding that homodimers of c-Met aptamers can activate c-Met, [12] Ueki and co-workers recently proposed an intriguing approach to redefine the ligand specificity of c-Met to other targets by using bi-specific aptamers to form at arget/dual-aptamer ternary complex. [11] Based on the finding that homodimers of c-Met aptamers can activate c-Met, [12] Ueki and co-workers recently proposed an intriguing approach to redefine the ligand specificity of c-Met to other targets by using bi-specific aptamers to form at arget/dual-aptamer ternary complex.…”

mentioning

confidence: 99%

A DNA‐Mediated Chemically Induced Dimerization (D‐CID) Nanodevice for Nongenetic Receptor Engineering To Control Cell Behavior

Wang

Shi

et al. 2018

Angew Chem Int Ed

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Small-molecule regulation is a powerful switching tool to manipulate cell signal transduction for a desired function; however, most available methods usually require genetic engineering to endow cells with responsiveness to user-defined small molecules. Herein, we demonstrate a nongenetic approach for small-molecule-controlled receptor activation and consequent cell behavior manipulation that is based on DNA-mediated chemically induced dimerization (D-CID). D-CID uses a programmable chemical-responsive DNA nanodevice to trigger DNA strand displacement and induce the activation of c-Met, a tyrosine kinase receptor cognate for hepatocyte growth factor, through dimerization. Through the use of various functional nucleic acids, including aptamers and DNAzymes, as recognition modules, the versatility of D-CID in inducing c-Met signaling upon addition of various small-molecular or ionic cues, including ATP, histidine, and Zn , is demonstrated. Moreover, owing its multi-input properties, D-CID can be used to manipulate the behaviors of multiple cell populations simultaneously in a selective and programmable fashion.

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Cell Membrane Functionalization via Nucleic Acid Tools for Visualization and Regulation of Cellular Receptors

Chen,

Li,

Yang

2024

DNA Nanotechnology for Cell Research

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A DNA aptamer to c-Met inhibits cancer cell migration

Abstract: The HGF/c-Met pathway is known to play a key role in cancer metastasis. CLN0003_SL1, a 50-mer DNA aptamer that binds to the c-Met protein, was found to inhibit HGF-induced c-Met activation. This aptamer could suppress cancer cell motility in vitro.

Cited by 90 publications

References 20 publications

Targeting c‐met receptor tyrosine kinase by the DNA aptamer SL1 as a potential novel therapeutic option for myeloma

Targeting c‐met receptor tyrosine kinase by the DNA aptamer SL1 as a potential novel therapeutic option for myeloma

A DNA‐Mediated Chemically Induced Dimerization (D‐CID) Nanodevice for Nongenetic Receptor Engineering To Control Cell Behavior

Cell Membrane Functionalization via Nucleic Acid Tools for Visualization and Regulation of Cellular Receptors

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