Cell-based screen identifies porphyrins as FGFR3 activity inhibitors with therapeutic potential for achondroplasia and cancer
Yun-Wen Lin, Hsiao-Jung Kao, Wei-Ting Chen, Cheng-Fu Kao, Jer-Yuarn Wu, Yuan-Tsong Chen, Yi-Ching Lee
Yun-Wen Lin, Hsiao-Jung Kao, Wei-Ting Chen, Cheng-Fu Kao, Jer-Yuarn Wu, Yuan-Tsong Chen, Yi-Ching Lee
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Research Article Bone biology Genetics

Cell-based screen identifies porphyrins as FGFR3 activity inhibitors with therapeutic potential for achondroplasia and cancer

Abstract

Overactive fibroblast growth factor receptor 3 (FGFR3) signaling drives pathogenesis in a variety of cancers and a spectrum of short-limbed bone dysplasias, including the most common form of human dwarfism, achondroplasia (ACH). Targeting FGFR3 activity holds great promise as a therapeutic approach for treatment of these diseases. Here, we established a receptor/adaptor translocation assay system that can specifically monitor FGFR3 activation, and we applied it to identify FGFR3 modulators from complex natural mixtures. An FGFR3-suppressing plant extract of Amaranthus viridis was identified from the screen, and 2 bioactive porphyrins, pheophorbide a (Pa) and pyropheophorbide a, were sequentially isolated from the extract and functionally characterized. Further analysis showed that Pa reduced excessive FGFR3 signaling by decreasing its half-life in FGFR3-overactivated multiple myeloma cells and chondrocytes. In an ex vivo culture system, Pa alleviated defective long bone growth in humanized ACH mice (FGFR3ACH mice). Overall, our study presents an approach to discovery and validation of plant extracts or drug candidates that target FGFR3 activation. The compounds identified by this approach may have applications as therapeutics for FGFR3-associated cancers and skeletal dysplasias.

Authors

Yun-Wen Lin, Hsiao-Jung Kao, Wei-Ting Chen, Cheng-Fu Kao, Jer-Yuarn Wu, Yuan-Tsong Chen, Yi-Ching Lee

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Figure 1

SH2 (SH2Bβ)/GFP specifically interacts with activated FGFR3 to generate an internalized cytoplasmic spot pattern in U2OS cells.

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SH2 (SH2Bβ)/GFP specifically interacts with activated FGFR3 to generate ...
(A) Schematic illustration shows the assay design concept by tracking the subcellular localization of an adaptor/GFP fusion protein that specifically interacts and internalizes with activated FGFR3. (B) Schematic representation shows the SH2 domain (underlined) of SH2Bβ and PLCγ proteins fused to the N-terminus of GFP. (C) U2OS cells transiently expressing GFP, SH2(SH2B)/GFP, or SH2(PLCγ)/GFP were observed by confocal live imaging. Scale bars, 10 μm. (D) Schematic representation shows the relative positions of different mutations in FGFR3 known to cause skeletal dysplasias. TDI, thanatophoric dysplasia 1; Ig I, II, and III; immunoglobulin-like domains; TM, transmembrane I domain; TK1 and 2, tyrosine kinase domains. (E) U2OS cells stably coexpress SH2 (SH2B)/GFP and various FGFR3s (WT, ACH, and TDI) or empty vector control (mock). The levels of FGFR3 and SH2 (SH2B)/GFP fusion proteins were detected by immunoblotting. (F) SH2 (SH2B)/GFP fluorescence signals (green) in the indicated cell lines were observed by confocal live imaging. Scale bars, 10 μm. (G) The direct interaction of SH2(SH2B)/GFP and FGFR3 was detected by co-immunoprecipitation (IP) using FGFR3 antibody followed by immunoblotting for FGFR3 and GFP. (HJ) Inhibition of FGFR3 activation by mutated Y724 and Y760 phosphorylation sites in TDI FGFR3 abolished the internalized spot pattern in U2OS cells coexpressing SH2(SH2B)/GFP cells TDI FGFR3. (H) Schematic representation shows the substitution of phenylalanine for tyrosine at Y724F and Y760F in TDI-FGFR3. (I) U2OS-SH2(SH2B)/GFP cells stably expressing empty vector control (mock), TDI-FGFR3, or Y724F/Y760F TDI-FGFR3 were observed by confocal live imaging. Scale bars, 10 μm. (J) The expression of FGFR3 was detected by immunoblotting.