Your search keyword '"Couceiro, José"' showing total 3 results

1. Controlling oncogenic KRAS signaling pathways with a Palladium-responsive peptide.

Author

Learte-Aymamí, Soraya, Martin-Malpartida, Pau, Roldán-Martín, Lorena, Sciortino, Giuseppe, Couceiro, José R., Maréchal, Jean-Didier, Macias, Maria J., Mascareñas, José L., and Vázquez, M. Eugenio

Subjects

RAS oncogenes, RAS proteins, CELLULAR signal transduction, ONCOGENIC proteins, PEPTIDES

Abstract

RAS oncoproteins are molecular switches associated with critical signaling pathways that regulate cell proliferation and differentiation. Mutations in the RAS family, mainly in the KRAS isoform, are responsible for some of the deadliest cancers, which has made this protein a major target in biomedical research. Here we demonstrate that a designed bis-histidine peptide derived from the αH helix of the cofactor SOS1 binds to KRAS with high affinity upon coordination to Pd(II). NMR spectroscopy and MD studies demonstrate that Pd(II) has a nucleating effect that facilitates the access to the bioactive α-helical conformation. The binding can be suppressed by an external metal chelator and recovered again by the addition of more Pd(II), making this system the first switchable KRAS binder, and demonstrates that folding-upon-binding mechanisms can operate in metal-nucleated peptides. In vitro experiments show that the metallopeptide can efficiently internalize into living cells and inhibit the MAPK kinase cascade. Mutations to oncogenic protein KRAS are responsible for some of the deadliest cancers, and KRAS is thus a key target for new antitumour agents. Here, a short bis-histidine peptide derived from the αH helix of the cofactor SOS1 is designed and shown to reversibly bind to KRAS with high affinity upon coordination to Pd(II), inhibiting KRAS-activated pathways in live cells. [ABSTRACT FROM AUTHOR]

Published

2022

2. From Binding-Induced Dynamic Effects in SH3 Structures to Evolutionary Conserved Sectors.

Author

Zafra Ruano, Ana, Cilia, Elisa, Couceiro, José R., Ruiz Sanz, Javier, Schymkowitz, Joost, Rousseau, Frederic, Luque, Irene, and Lenaerts, Tom

Subjects

HOMOLOGY (Biology), LIGAND binding (Biochemistry), CELLULAR signal transduction, AMINO acids, HYDROGEN bonding

Abstract

Src Homology 3 domains are ubiquitous small interaction modules known to act as docking sites and regulatory elements in a wide range of proteins. Prior experimental NMR work on the SH3 domain of Src showed that ligand binding induces long-range dynamic changes consistent with an induced fit mechanism. The identification of the residues that participate in this mechanism produces a chart that allows for the exploration of the regulatory role of such domains in the activity of the encompassing protein. Here we show that a computational approach focusing on the changes in side chain dynamics through ligand binding identifies equivalent long-range effects in the Src SH3 domain. Mutation of a subset of the predicted residues elicits long-range effects on the binding energetics, emphasizing the relevance of these positions in the definition of intramolecular cooperative networks of signal transduction in this domain. We find further support for this mechanism through the analysis of seven other publically available SH3 domain structures of which the sequences represent diverse SH3 classes. By comparing the eight predictions, we find that, in addition to a dynamic pathway that is relatively conserved throughout all SH3 domains, there are dynamic aspects specific to each domain and homologous subgroups. Our work shows for the first time from a structural perspective, which transduction mechanisms are common between a subset of closely related and distal SH3 domains, while at the same time highlighting the differences in signal transduction that make each family member unique. These results resolve the missing link between structural predictions of dynamic changes and the domain sectors recently identified for SH3 domains through sequence analysis. [ABSTRACT FROM AUTHOR]

Published

2016

3. Coronin 1A promotes a cytoskeletal-based feedback loop that facilitates Rac1 translocation and activation.

Author

Castro-Castro, Antonio, Ojeda, Virginia, Barreira, María, Sauzeau, Vincent, Navarro-Lérida, Inmaculada, Muriel, Olivia, Couceiro, José R, Pimentel-Muíños, Felipe X, del Pozo, Miguel A, and Bustelo, Xosé R

Subjects

CARRIER proteins, CYTOSKELETAL proteins, GUANOSINE triphosphatase, CELLULAR signal transduction, CYTOSOL, CELL membranes, CELLULAR control mechanisms

Abstract

The activation of the Rac1 GTPase during cell signalling entails its translocation from the cytosol to membranes, release from sequestering Rho GDP dissociation inhibitors (RhoGDI), and GDP/GTP exchange. In addition to those steps, we show here that optimal Rac1 activation during cell signalling requires the engagement of a downstream, cytoskeletal-based feedback loop nucleated around the cytoskeletal protein coronin 1A and the Rac1 exchange factor ArhGEF7. These two proteins form a cytosolic complex that, upon Rac1-driven F-actin polymerization, translocates to juxtamembrane areas where it expands the pool of activated, membrane-bound Rac1. Such activity requires the formation of an F-actin/ArhGEF7-dependent physical complex of coronin 1A with Pak1 and RhoGDI? that, once assembled, promotes the Pak1-dependent dissociation of Rac1 from the Rac1/RhoGDI? complex and subsequent Rac1 activation. Genetic evidence demonstrates that this relay circuit is essential for generating sustained Rac1 activation levels during cell signalling. [ABSTRACT FROM AUTHOR]

Published

2011