Your search keyword '"Knapik, Agata"' showing total 3 results

1. Differential regulation of fibroblast growth factor receptor 1 trafficking and function by extracellular galectins

Author

Kucińska, Marika, Porębska, Natalia, Lampart, Agata, Latko, Marta, Knapik, Agata, Zakrzewska, Małgorzata, Otlewski, Jacek, and Opaliński, Łukasz

Published

2019

2. FGF1 Fusions with the Fc Fragment of IgG1 for the Assembly of GFPpolygons-Mediated Multivalent Complexes Recognizing FGFRs.

Author

Poźniak, Marta, Zarzycka, Weronika, Porębska, Natalia, Knapik, Agata, Marczakiewicz-Perera, Paulina, Zakrzewska, Malgorzata, Otlewski, Jacek, and Opaliński, Łukasz

Subjects

CELL receptors, CELL membranes, CELL death, BINDING sites, CELL communication, G proteins

Abstract

FGFRs are cell surface receptors that, when activated by specific FGFs ligands, transmit signals through the plasma membrane, regulating key cellular processes such as differentiation, division, motility, metabolism and death. We have recently shown that the modulation of the spatial distribution of FGFR1 at the cell surface constitutes an additional mechanism for fine-tuning cellular signaling. Depending on the multivalent, engineered ligand used, the clustering of FGFR1 into diverse supramolecular complexes enhances the efficiency and modifies the mechanism of receptor endocytosis, alters FGFR1 lifetime and modifies receptor signaling, ultimately determining cell fate. Here, we present a novel approach to generate multivalent FGFR1 ligands. We functionalized FGF1 for controlled oligomerization by developing N- and C-terminal fusions of FGF1 with the Fc fragment of human IgG1 (FGF1-Fc and Fc-FGF1). As oligomerization scaffolds, we employed GFPpolygons, engineered GFP variants capable of well-ordered multivalent display, fused to protein G to ensure binding of Fc fragment. The presented strategy allows efficient assembly of oligomeric FGFR1 ligands with up to twelve receptor binding sites. We show that multivalent FGFR1 ligands are biologically active and trigger receptor clustering on the cell surface. Importantly, the approach described in this study can be easily adapted to oligomerize alternative growth factors to control the activity of other cell surface receptors. [ABSTRACT FROM AUTHOR]

Published

2021

3. Dissecting biological activities of fibroblast growth factor receptors by the coiled-coil-mediated oligomerization of FGF1.

Author

Porebska, Natalia, Pozniak, Marta, Krzyscik, Mateusz Adam, Knapik, Agata, Czyrek, Aleksandra, Kucinska, Marika, Jastrzebski, Kamil, Zakrzewska, Malgorzata, Otlewski, Jacek, and Opalinski, Lukasz

Subjects

*FIBROBLAST growth factor receptors, *OLIGOMERIZATION, *ENDOCYTOSIS, *MEMBRANE proteins, *DRUG carriers, *HEPARIN

Abstract

Fibroblast growth factor receptors (FGFRs) are integral membrane proteins involved in various biological processes including proliferation, migration and apoptosis. There are a number of regulatory mechanisms of FGFR signaling, which tightly control the specificity and duration of transmitted signals. The effect of the FGFRs spatial distribution in the plasma membrane on receptor-dependent functions is still largely unknown. We have demonstrated that oligomerization of FGF1 with coiled-coil motifs largely improves FGF1 affinity for FGFRs and heparin. Set of developed FGF1 oligomers evoked prolonged activation of FGFR1 and receptor-downstream signaling pathways, as compared to the wild type FGF1. The majority of obtained oligomeric FGF1 variants showed increased stability, enhanced mitogenic activity and largely improved internalization via FGFR1-dependent endocytosis. Importantly, FGF1 oligomers with the highest oligomeric state exhibited reduced ability to stimulate FGFR-dependent glucose uptake, while at the same time remained hyperactive in the induction of cell proliferation. Our data implicate that oligomerization of FGF1 alters the biological activity of the FGF/GFR1 signaling system. Furthermore, developed FGF1 oligomers, due to improved stability and proliferative potential, can be applied in the regenerative medicine or as drug delivery vehicles in the ADC approach against FGFR1-overproducing cancers. [ABSTRACT FROM AUTHOR]

Published

2021