Your search keyword '"biophysical processes"' showing total 2 results

1. Nucleic Acid Binding of the RTN1-C C-Terminal Region: Toward the Functional Role of a Reticulon Protein

Author

Sonia Melino, Stefania Di Marco, Alessia Bellomaria, Ridvan Nepravishta, and Maurizio Paci

Subjects

Secondary, protein synthesis, Amino acid sequences, Peptide, Biochemistry, Consensus sequences, Membrane proteins, genetics, Amines, C-terminal regions, Peptide sequence, chemistry.chemical_classification, zinc, Bacterial, RTN1 protein, Binding properties, Biological functions, Deacetylation, Histone deacetylase, Histone proteins, In-vivo, N terminals, Nervous systems, Spectroscopic techniques, Vesicle trafficking, Acetylation, Amino acids, Binding energy, Nucleic acids, Organic acids, Proteins, Zinc, Biomolecules, histone deacetylase 8, histone H4, membrane protein, nucleic acid, protein RTN1 C, reticulon, unclassified drug, bacterial DNA, bacterial RNA, DNA, nerve protein, protein, RNA, RTN1 protein, human, acetylation, amino acid sequence, article, carboxy terminal sequence, deacetylation, electrophoresis, endoplasmic reticulum, fluorescence, in vivo study, kinetics, membrane vesicle, molecular interaction, priority journal, protein conformation, protein localization, protein protein interaction, regulatory mechanism, sequence homology, binding site, biophysics, chemistry, consensus sequence, Escherichia coli, human, isolation and purification, metabolism, molecular genetics, protein binding, protein motif, protein processing, protein secondary structure, Amino Acid Motifs, Amino Acid Sequence, Binding Sites, Biophysical Processes, Consensus Sequence, DNA, Bacterial, Humans, Molecular Sequence Data, Nerve Tissue Proteins, Protein Binding, Protein Conformation, Protein Processing, Post-Translational, Protein Structure, Secondary, RNA, Bacterial, Histone, Protein Structure, Biophysical Phenomena, Consensus sequence, Settore BIO/10, Post-Translational, Reticulon, biology, Nucleic acid structure, Membrane protein, biology.protein, Nucleic acid

Abstract

RTN1-C protein is a membrane protein localized in the ER and expressed in the nervous system. Its biological role is still unclear, although interactions of the N-terminal region of RTN1-C with proteins involved in vesicle trafficking have been observed, but the role of the C-terminal region of this family protein remains to be investigated. By a homology analysis of the amino acid sequence, we identified in the C-terminal region of RTN1-C a unique consensus sequence characteristic of H4 histone protein. Thus, a 23-mer peptide (RTN1-C(CT)) corresponding to residues 186-208 of RTN1-C was synthesized, and its conformation and its interaction with nucleic acids were investigated. Here we demonstrate the strong ability of RTN1-C(CT) peptide to bind and condense the nucleic acids using electrophoretic and spectroscopic techniques. To determine if the binding of RTN1-C to nucleic acids could be regulated in vivo by an acetylation-deacetylation mechanism, as for the histone proteins, we studied the interaction of RTN1-C with one zinc-dependent histone deacetylase (HDAC) enzyme, HDAC8, with fluorescence and kinetic techniques using an acetylated form of RTN1-C(CT). The results reported here allow us to propose that the nucleic acid binding property of RTN1-C may have an important role in the biological function of this protein, the function of which could be regulated by an acetylation-deacetylation mechanism.

Published

2008

2. STD-NMR Used To Elucidate the Fine Binding Specificity of Pathogenic Anti-Ganglioside Antibodies Directly in Patient Serum

Author

Anne P. Tio-Gillen, Jan J.G.M. Verschuuren, Michel Gilbert, R. Scott Houliston, Bart C. Jacobs, Harold C. Jarrell, Nam H. Khieu, and Neurology

Subjects

binding, autoantibodies, diagnosis, immunoglobulins, Disaccharide, specificity, high-resolution, ligand, Biochemistry, form, immunology, antibodies, anti-idiotypic, chemistry.chemical_compound, Gangliosides, antibody, models, molecular, biophysical processes, epitope, region, ganglioside, sialic, polyneuropathies, acid, Antibody, Polyneuropathy, Canada, sialic-acid, unit, interaction, Biology, Antibodies, Biophysical Phenomena, methods, target, Residue (chemistry), blood, medicine, Humans, fractionation, molecular, Binding selectivity, IGM, Ganglioside, ligands, Autoantibody, nuclear magnetic resonance, biomolecular, epitopes, medicine.disease, Molecular biology, Sialic acid, epitope mapping, chemistry, sensitivity and specificity, biology.protein, enzyme-linked immunosorbent assay, disaccharide, serum, signal

Abstract

High-resolution binding profiles were elucidated for anti-GM I IgM autoantibodies from two patients with a progressive form of paraproteinemic polyneuropathy. Antibody-ligand interaction was characterized by generating STD-NMR signals in target ganglio-oligosaccharides added directly to patient sera, without the requirement of antibody fractionation. Both immunoglobulins were found to have similar binding modalities, with interaction confined to two distinct spatially separated regions of GM1: the terminal beta Gal(1-3)beta GalNAc disaccharide unit and the sialic acid residue. We describe a unique and powerful biophysical technique applied to define the molecular interaction between autoimmune disease-causing antibodies and their ganglioside targets.

Published

2008