Your search keyword '"GxxxG motif"' showing total 4 results

1. A conserved GXXXG motif in the transmembrane domain of CLIC proteins is essential for their cholesterol-dependant membrane interaction.

Author

Hossain, Khondker Rufaka, Turkewitz, Daniel R., Holt, Stephen A., Herson, Leonie, Brown, Louise J., Cornell, Bruce A., Curmi, Paul M.G., and Valenzuela, Stella M.

Subjects

*MOLECULAR spectroscopy, *PROTEIN domains, *MEMBRANE proteins, *MUTANT proteins, *CARRIER proteins, *CHOLESTEROL, *ION channels

Abstract

Sterols have been reported to modulate conformation and hence the function of several membrane proteins. One such group is the Chloride Intracellular Ion Channel (CLIC) family of proteins. The CLIC protein family consists of six evolutionarily conserved protein members in vertebrates. These proteins exist as both monomeric soluble proteins and as membrane bound proteins. To date, the structure of their membrane-bound form remains unknown. In addition to several studies indicating cellular redox environment and pH as facilitators of CLIC1 insertion into membranes, we have also demonstrated that the spontaneous membrane insertion of CLIC1 is regulated by membrane cholesterol. We have performed Langmuir-film, Impedance Spectroscopy and Molecular Docking Simulations to study the role of this GXXXG motif in CLIC1 interaction with cholesterol. Unlike CLIC1-wild-type protein, the G18A and G22A mutants, that form part of the GXXXG motif, showed much slower initial kinetics and lower ion channel activity compared to the native protein. This difference can be attributed to the significantly reduced membrane interaction and insertion rate of the mutant proteins and/or slower formation of the final membrane configuration of the mutant proteins once in the membrane. Conclusion: In this study, our findings uncover the identification of a GXXXG motif in CLIC1, which likely serves as the cholesterol-binding domain, that facilitates the protein's membrane interaction and insertion. Furthermore, we were able to postulate a model by which CLIC1 can autonomously insert into membranes to form functional ion channels. Members of the CLIC family of proteins demonstrate unusual structural and dual functional properties – as ion channels and enzymes. Elucidating how the CLIC proteins' interact with membranes, thus allowing them to switch between their soluble and membrane form, will provide key information as to a mechanism of moonlighting activity and a novel regulatory role for cholesterol in such a process. • A mechanism of CLIC1 interaction with membrane cholesterol is summarised. • A GXXXG motif in CLIC1 facilitates the protein's membrane interaction and insertion. • A model by which CLIC1 can autonomously insert into membranes to form functional ion channels has been postulated. [ABSTRACT FROM AUTHOR]

Published

2019

2. A triad of molecular regions contribute to the formation of two distinct MHC class II conformers.

Author

Drake, Lisa A. and Drake, James R.

Subjects

*MAJOR histocompatibility complex, *B cell receptors, *IMMUNE response, *IMMUNE recognition, *MUTAGENESIS

Abstract

MHC class II molecules present antigen-derived peptides to CD4T cells to drive the adaptive immune response. Previous work has established that class II αβ dimers can adopt two distinct conformations, driven by the differential pairing of transmembrane domain GxxxG dimerization motifs. These class II conformers differ in their ability to be loaded with antigen-derived peptide and to effectively engage CD4 T cells. Motif 1 (M1) paired I-A k class II molecules are efficiently loaded with peptides derived from the processing of B cell receptor-bound antigen, have unique B cell signaling properties and high T cell stimulation activity. The 11-5.2 mAb selectively binds M1 paired I-A k class II molecules. However, the molecular determinants of 11-5.2 binding are currently unclear. Here, we report the ability of a human class II transmembrane domain to drive both M1 and M2 class II conformer formation. Protease sensitivity analysis further strengthens the idea that there are conformational differences between the extracellular domains of M1 and M2 paired class II. Finally, MHC class II chain alignments and site directed mutagenesis reveals a triad of molecular regions that contributes to 11-5.2 mAb binding. In addition to transmembrane GxxxG motif domain pairing, 11-5.2 binding is influenced directly by α chain residue Glu-71 and in directly by the region around the inter-chain salt bridge formed by α chain Arg-52 and β chain Glu-86. These findings provide insight into the complexity of 11-5.2 mAb recognition of the M1 paired I-A k class II conformer and further highlight the molecular heterogeneity of peptide-MHC class II complexes that drive T cell antigen recognition. [ABSTRACT FROM AUTHOR]

Published

2016

3. The transmembrane domain of podoplanin is required for its association with lipid rafts and the induction of epithelial-mesenchymal transition

Author

Fernández-Muñoz, Beatriz, Yurrita, María M., Martín-Villar, Ester, Carrasco-Ramírez, Patricia, Megías, Diego, Renart, Jaime, and Quintanilla, Miguel

Subjects

*LIPIDS, *EPITHELIAL cells, *GLYCOPROTEINS, *PHOSPHORYLATION, *GANGLIOSIDES, *CELL migration, *MEMBRANE proteins

Abstract

Abstract: Podoplanin is a transmembrane glycoprotein that is upregulated in cancer and was reported to induce an epithelial-mesenchymal transition (EMT) in MDCK cells. The promotion of EMT was dependent on podoplanin binding to ERM (ezrin, radixin, moesin) proteins through its cytoplasmic (CT) domain, which led to RhoA-associated kinase (ROCK)-dependent ERM phosphorylation. Using detergent-resistant membrane (DRM) assays, as well as transmembrane (TM) interactions and ganglioside GM1 binding, we present evidence supporting the localization of podoplanin in raft platforms important for cell signalling. Podoplanin mutant constructs harbouring a heterologous TM region or lacking the CT tail were unable to associate with DRMs, stimulate ERM phosphorylation and promote EMT or cell migration. Similar effects were observed upon disruption of a GXXXG motif within the TM domain, which is involved in podoplanin self-assembly. In contrast, deletion of the extracellular (EC) domain did not affect podoplanin DRM association. Together, these data suggest that both the CT and TM domains are required for podoplanin localization in raft platforms, and that this association appears to be necessary for podoplanin-mediated EMT and cell migration. [Copyright &y& Elsevier]

Published

2011

4. Design and synthesis of an artificial ladder-shaped polyether that interacts with glycophorin A

Author

Torikai, Kohei, Yari, Hiroshi, Mori, Megumi, Ujihara, Satoru, Matsumori, Nobuaki, Murata, Michio, and Oishi, Tohru

Subjects

*PROTEINS, *BIOSYNTHESIS, *POLYETHERS, *POLYMERS

Abstract

Abstract: Ladder-shaped polyether (LSP) compounds, such as brevetoxins and ciguatoxins, are thought to interact with transmembrane (TM) proteins. As a model LSP compound, we designed and synthesized an artificial tetracyclic ether (1) and evaluated its interaction with glycophorin A (GpA), a membrane protein known to dimerize or oligomerize between membrane-integral α-helical domains. Model compound 1 was found to induce the dissociation of oligomeric GpA in a similar manner to natural LSPs when examined by SDS–PAGE. The results suggest that even an artificial tetracyclic ether possesses the ability to interact with TM proteins, presumably through the intermolecular hydrogen bonds (Cα–H⋯O) with the GXXXG motif. [Copyright &y& Elsevier]

Published

2006