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

1. Intermonomer Hydrogen Bonds Enhance GxxxG-Driven Dimerization of the BNIP3 Transmembrane Domain: Roles for Sequence Context in Helix–Helix Association in Membranes

Author

Lawrie, Charles M., Sulistijo, Endah S., and MacKenzie, Kevin R.

Subjects

*HYDROGEN bonding, *BIOLOGICAL assay, *MALTOSE, *CARRIER proteins, *CHLORAMPHENICOL, *MEMBRANE proteins, *PROTEIN folding

Abstract

Abstract: We determined the sequence dependence of human BNIP3 transmembrane domain dimerization using the biological assay TOXCAT. Mutants in which intermonomer hydrogen bonds between Ser172 and His173 are abolished show moderate interaction, indicating that side-chain hydrogen bonds contribute to dimer stability but are not essential to dimerization. Mutants in which a GxxxG motif composed of Gly180 and Gly184 has been abolished show little or no interaction, demonstrating the critical nature of the GxxxG motif to BNIP3 dimerization. These findings show that side-chain hydrogen bonds can enhance the intrinsic dimerization of a GxxxG motif and that sequence context can control how hydrogen bonds influence helix–helix interactions in membranes. The dimer interface mapped by TOXCAT mutagenesis agrees closely with the interfaces observed in the NMR structure and inferred from mutational analysis of dimerization on SDS-PAGE, showing that the native dimer structure is retained in detergents. We show that TOXCAT and SDS-PAGE give complementary and consistent information about BNIP3 transmembrane domain dimerization: TOXCAT is insensitive to mutations that have modest effects on self-association in detergents but readily discriminates among mutations that completely disrupt detergent-resistant dimerization. The close agreement between conclusions reached from TOXCAT and SDS-PAGE data for BNIP3 suggests that accurate estimates of the relative effects of mutations on native-state protein–protein interactions can be obtained even when the detergent environment is strongly disruptive. [Copyright &y& Elsevier]

Published

2010

2. Ionic Interactions Promote Transmembrane Helix–Helix Association Depending on Sequence Context

Author

Herrmann, Jana R., Fuchs, Angelika, Panitz, Johanna C., Eckert, Thomas, Unterreitmeier, Stephanie, Frishman, Dmitrij, and Langosch, Dieter

Subjects

*MEMBRANE proteins, *AMINO acid sequence, *PROTEIN folding, *PROTEIN-protein interactions, *GENETIC mutation, *PROTEIN binding, *BETA-galactosidase, *GENETIC transcription regulation

Abstract

Abstract: Folding and oligomerization of integral membrane proteins frequently depend on specific interactions of transmembrane helices. Interacting amino acids of helix–helix interfaces may form complex motifs and exert different types of molecular forces. Here, a set of strongly self-interacting transmembrane domains (TMDs), as isolated from a combinatorial library, was found to contain basic and acidic residues, in combination with polar nonionizable amino acids and C-terminal GxxxG motifs. Mutational analyses of selected sequences and reconstruction of high-affinity interfaces confirmed the cooperation of these residues in homotypic interactions. Probing heterotypic interaction indicated the presence of interhelical charge–charge interactions. Furthermore, simple motifs of an ionizable residue and GxxxG are significantly overrepresented in natural TMDs, and a specific combination of these motifs exhibits high-affinity heterotypic interaction. We conclude that intramembrane charge–charge interactions depend on sequence context. Moreover, they appear important for homotypic and heterotypic interactions of numerous natural TMDs. [Copyright &y& Elsevier]

Published

2010

3. Mim1 Functions in an Oligomeric Form to Facilitate the Integration of Tom20 into the Mitochondrial Outer Membrane

Author

Popov-Čeleketić, Jelena, Waizenegger, Thomas, and Rapaport, Doron

Subjects

*MITOCHONDRIAL membranes, *MEMBRANE proteins, *ORGANELLES, *CELL membranes

Abstract

Abstract: The translocase of the outer mitochondrial membrane (TOM) complex is the general entry site into the organelle for newly synthesized proteins. Despite its central role in the biogenesis of mitochondria, the assembly process of this complex is not completely understood. Mim1 (mitochondrial import protein 1) is a mitochondrial outer membrane protein with an undefined role in the assembly of the TOM complex. The protein is composed of an N-terminal cytosolic domain, a central putative transmembrane segment (TMS) and a C-terminal domain facing the intermembrane space. Here we show that Mim1 is required for the integration of the import receptor Tom20 into the outer membrane. We further investigated what the structural characteristics allowing Mim1 to fulfil its function are. The N- and C-terminal domains of Mim1 are crucial neither for the function of the protein nor for its biogenesis. Thus, the TMS of Mim1 is the minimal functional domain of the protein. We show that Mim1 forms homo-oligomeric structures via its TMS, which contains two helix-dimerization GXXXG motifs. Mim1 with mutated GXXXG motifs did not form oligomeric structures and was inactive. With all these data taken together, we propose that the homo-oligomerization of Mim1 allows it to fulfil its function in promoting the integration of Tom20 into the mitochondrial outer membrane. [Copyright &y& Elsevier]

Published

2008

4. Solution Structures of the Core Light-harvesting α and β Polypeptides from Rhodospirillum rubrum: Implications for the Pigment–Protein and Protein–Protein Interactions

Author

Wang, Zheng-Yu, Gokan, Kazutaka, Kobayashi, Masayuki, and Nozawa, Tsunenori

Subjects

*RHODOSPIRILLUM rubrum, *PROTEINS, *HIGH performance liquid chromatography, *NUCLEAR magnetic resonance spectroscopy

Abstract

We have determined the solution structures of the core light-harvesting (LH1) α and β-polypeptides from wild-type purple photosynthetic bacterium Rhodospirillum rubrum using multidimensional NMR spectroscopy. The two polypeptides form stable α helices in organic solution. The structure of α-polypeptide consists of a long helix of 32 amino acid residues over the central transmembrane domain and a short helical segment at the N terminus that is followed by a three-residue loop. Pigment-coordinating histidine residue (His29) in the α-polypeptide is located near the middle of the central helix. The structure of β-polypeptide shows a single helix of 32 amino acid residues in the membrane-spanning region with the pigment-coordinating histidine residue (His38) at a position close to the C-terminal end of the helix. Strong hydrogen bonds have been identified for the backbone amide protons over the central helical regions, indicating a rigid property of the two polypeptides. The overall structures of the R.rubrum LH1 α and β-polypeptides are different from those previously reported for the LH1 β-polypeptide of Rhodobacter sphaeroides, but are very similar to the structures of the corresponding LH2 α and β-polypeptides determined by X-ray crystallography. A model constructed for the structural subunit (B820) of LH1 complex using the solution structures reveals several important features on the interactions between the LH1 α and β-polypeptides. The significance of the N-terminal regions of the two polypeptides for stabilizing both B820 and LH1 complexes, as clarified by many experiments, may be attributed to the interactions between the short N-terminal helix (Trp2-Gln6) of α-polypeptide and a GxxxG motif in the β-polypeptide. [Copyright &y& Elsevier]

Published

2005