Preferred side-chain constellations at antiparallel coiled-coil interfaces

Interactions between polypeptide chains containing amino acid residues with opposite absolute configurations have long been a source of interest and speculation, but there is very little structural information for such heterochiral associations. The need to address this lacuna has grown in recent years because of increasing interest in the use of peptides generated from d amino acids (d peptides) as specific ligands for natural proteins, e.g., to inhibit deleterious protein–protein interactions. Coiled–coil interactions, between or among α-helices, represent the most common tertiary and quaternary packing motif in proteins. Heterochiral coiled–coil interactions were predicted over 50 years ago by Crick, and limited experimental data obtained in solution suggest that such interactions can indeed occur. To address the dearth of atomic-level structural characterization of heterochiral helix pairings, we report two independent crystal structures that elucidate coiled-coil packing between l- and d-peptide helices. Both structures resulted from racemic crystallization of a peptide corresponding to the transmembrane segment of the influenza M2 protein. Networks of canonical knobs-into-holes side-chain packing interactions are observed at each helical interface. However, the underlying patterns for these heterochiral coiled coils seem to deviate from the heptad sequence repeat that is characteristic of most homochiral analogs, with an apparent preference for a hendecad repeat pattern.

Download Full-text

Determination of the Multimerization State of the Hepatitis Delta Virus Antigens In Vivo

Journal of Virology ◽

10.1128/jvi.77.19.10314-10326.2003 ◽

2003 ◽

Vol 77 (19) ◽

pp. 10314-10326 ◽

Cited By ~ 14

Author(s):

Cromwell T. Cornillez-Ty ◽

David W. Lazinski

Keyword(s):

Crystal Structure ◽

Hepatitis Delta Virus ◽

Coiled Coil ◽

Proper Function ◽

Hepatitis Delta ◽

Amino Terminal ◽

Delta Antigen ◽

Antiparallel Coiled Coil ◽

Delta Virus

ABSTRACT Hepatitis delta virus expresses two essential proteins, the small and large delta antigens, and both are required for viral propagation. Proper function of each protein depends on the presence of a common amino-terminal multimerization domain. A crystal structure, solved using a peptide fragment that contained residues 12 to 60, depicts the formation of an octameric ring composed of antiparallel coiled-coil dimers. Because this crystal structure was solved for only a fragment of the delta antigens, it is unknown whether octamers actually form in vivo at physiological protein concentrations and in the context of either intact delta antigen. To test the relevance of the octameric structure, we developed a new method to probe coiled-coil structures in vivo. We generated a panel of mutants containing cysteine substitutions at strategic locations within the predicted monomer-monomer interface and the dimer-dimer interface. Since the small delta antigen contains no cysteine residues, treatment of cell extracts with a mild oxidizing reagent was expected to induce disulfide bond formation only when the appropriate pairs of cysteine substitution mutants were coexpressed. We indeed found that, in vivo, both the small and large delta antigens assembled as antiparallel coiled-coil dimers. Likewise, we found that both proteins could assume an octameric quaternary structure in vivo. Finally, during the course of these experiments, we found that unprenylated large delta antigen molecules could be disulfide cross-linked via the sole cysteine residue located within the carboxy terminus. Therefore, in vivo, the C terminus likely provides an additional site of protein-protein interaction for the large delta antigen.

Download Full-text

Molecular architecture of a dynamin adaptor: implications for assembly of mitochondrial fission complexes

The Journal of Cell Biology ◽

10.1083/jcb.201005046 ◽

2010 ◽

Vol 191 (6) ◽

pp. 1127-1139 ◽

Cited By ~ 33

Author(s):

Sajjan Koirala ◽

Huyen T. Bui ◽

Heidi L. Schubert ◽

Debra M. Eckert ◽

Christopher P. Hill ◽

...

Keyword(s):

Membrane Protein ◽

Crystal Structures ◽

Binding Sites ◽

Mitochondrial Fission ◽

Coiled Coil ◽

Adaptor Proteins ◽

Molecular Architecture ◽

Cellular Membranes ◽

Membrane Scission ◽

Antiparallel Coiled Coil

Recruitment and assembly of some dynamin-related guanosine triphosphatases depends on adaptor proteins restricted to distinct cellular membranes. The yeast Mdv1 adaptor localizes to mitochondria by binding to the membrane protein Fis1. Subsequent Mdv1 binding to the mitochondrial dynamin Dnm1 stimulates Dnm1 assembly into spirals, which encircle and divide the mitochondrial compartment. In this study, we report that dimeric Mdv1 is joined at its center by a 92-Å antiparallel coiled coil (CC). Modeling of the Fis1–Mdv1 complex using available crystal structures suggests that the Mdv1 CC lies parallel to the bilayer with N termini at opposite ends bound to Fis1 and C-terminal β-propeller domains (Dnm1-binding sites) extending into the cytoplasm. A CC length of appropriate length and sequence is necessary for optimal Mdv1 interaction with Fis1 and Dnm1 and is important for proper Dnm1 assembly before membrane scission. Our results provide a framework for understanding how adaptors act as scaffolds to orient and stabilize the assembly of dynamins on membranes.

Download Full-text

Two cases of congenital dysfibrinogenemia associated with thrombosis – Fibrinogen Praha III and Fibrinogen Plzeň

Thrombosis and Haemostasis ◽

10.1160/th08-11-0771 ◽

2009 ◽

Vol 102 (09) ◽

pp. 479-486 ◽

Cited By ~ 12

Author(s):

Zuzana Reicheltová ◽

Martin Malý ◽

Jiří Suttnar ◽

Alžbòta Sobotková ◽

Peter Salaj ◽

...

Keyword(s):

Platelet Aggregation ◽

Coiled Coil ◽

Helical Conformation ◽

Side Chain ◽

Test Results ◽

Aromatic Side Chain ◽

Sds Page ◽

History Of ◽

Asparagine Residue ◽

Fibrinogen Molecule

SummaryCongenital dysfibrinogenemia is a rare disease characterised by inherited abnormality in the fibrinogen molecule, resulting in functional defects. Two patients, a 26-year-old woman and a 61-year-old man, both with history of thrombotic events, had abnormal coagulation test results. DNA sequencing showed the heterozygous γY363N mutation (Fibrinogen Praha III) and the heterozygous Aα N106D mutation (Fibrinogen Plzeň), respectively. Fibrin polymerisation, after addition of either thrombin or reptilase, showed remarkably delayed polymerisation in both cases. Fibrinolysis experiments showed slower tPA initiated lysis of clots. SDS-PAGE did not show any difference between normal and Praha III and Plzeň fibrinogens. Both mutations had a significant effect on platelet aggregation. In the presence of either ADP or TRAP, both mutations caused the decrease of platelet aggregation. SEM revealed abnormal clot morphology, with a large number of free ends and narrower fibres of both fibrin Praha III and Plzeň. Praha III mutation was situated in the polymerisation pocket “a”. The replacement of the bulky aromatic side chain of tyrosine by the polar uncharged small side chain of asparagine may lead to a conformational change, possibly altering the conformation of the polymerisation pocket. The Plzeň mutation is situated in the coiled-coil connector and this replacement of polar uncharged asparagine residue by polar acidic aspartate changes the alpha-helical conformation of the coiled-coil connector;and may destabilise hydrogen bonds in its neighborhood. Although both mutations are situated in different regions of the molecule, both mutations have a very similar effect on fibrinogen functions and both are connected with thromboses.

Download Full-text