A conserved trimerization motif controls the topology of short coiled coils

Kammerer, Richard A.; Kostrewa, Dirk; Progias, Pavlos; Honnappa, Srinivas; Ávila, David; Lustig, Ariel; Winkler, Fritz K.; Pieters, Jean; Steinmetz, Michel O.

doi:10.1073/pnas.0502390102

Cited by 90 publications

(115 citation statements)

References 49 publications

Supporting

Mentioning

108

Contrasting

Unclassified

Order By: Relevance

“…3A). These results demonstrate that the basic principles underlying Crick's ''knobs-into-holes''-based manual modeling (15,16), more constrained conformational searches (17), and other phenomenological rules (18) for the simplest coiled coils can be automatically and quite generally applied to the de novo modeling of complex symmetric helix interaction motifs.…”

Section: Resultsmentioning

confidence: 91%

Simultaneous prediction of protein folding and docking at high resolution

Das

André

Shen

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

147

174

View full text Add to dashboard Cite

Interleaved dimers and higher order symmetric oligomers are ubiquitous in biology but present a challenge to de novo structure prediction methodology: The structure adopted by a monomer can be stabilized largely by interactions with other monomers and hence not the lowest energy state of a single chain. Building on the Rosetta framework, we present a general method to simultaneously model the folding and docking of multiple-chain interleaved homo-oligomers. For more than a third of the cases in a benchmark set of interleaved homo-oligomers, the method generates near-native models of large ␣-helical bundles, interlocking ␤ sandwiches, and interleaved ␣/␤ motifs with an accuracy high enough for molecular replacement based phasing. With the incorporation of NMR chemical shift information, accurate models can be obtained consistently for symmetric complexes with as many as 192 total amino acids; a blind prediction was within 1 Å rmsd of the traditionally determined NMR structure, and fit independently collected RDC data equally well. Together, these results show that the Rosetta ''fold-and-dock'' protocol can produce models of homo-oligomeric complexes with nearatomic-level accuracy and should be useful for crystallographic phasing and the rapid determination of the structures of multimers with limited NMR information.homo-oligomers ͉ molecular replacement ͉ NMR structure inference ͉ protein structure prediction ͉ symmetry T he majority of expressed proteins function within symmetrical homomeric complexes (1-3). Although a boon for evolving functional diversity (4), this ubiquity of oligomeric structures poses numerous challenges for modern structural biology. The phasing of crystallographic data by molecular replacement and NMR structural inference are complicated by the increasing number of degrees of freedom and spectral degeneracy, respectively, in multimeric systems. The ability to predict de novo the structures of multiple interacting molecular chains would potentially alleviate these problems, allowing unphased diffraction measurements or ambiguously assigned NMR spectra to be resurrected as constraints or as independent validation for in silico structural inference.Accurate modeling of previously unseen homomeric structures has not been demonstrated at high resolution. Significant progress has occurred in modeling the folds of individual monomeric soluble proteins (5-7) and the docking arrangements of predefined monomers (8, 9). However, as proteins interact with other proteins, nucleic acids, or smaller molecules, their lowest free-energy backbone conformations typically shift in response to their partners. These often dramatic structural changes have been a persistent and unsolved issue in blind prediction trials of recent years (8).In this report, we show how two different methods developed for de novo conformational sampling (for folding and for docking) can be melded into a more general procedure that permits the blind prediction of intertwined complexes of proteins at near-atomic resolution. Some of th...

show abstract

Section: Resultsmentioning

confidence: 91%

Simultaneous prediction of protein folding and docking at high resolution

Das

André

Shen

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

147

174

View full text Add to dashboard Cite

show abstract

“…S1). This revealed conserved RhxxxhE motifs (h, hydrophobic; x, any amino acid) that were demonstrated in other proteins to induce a parallel trimeric coiled coil (42). Consequently, trimerization of type II ORF1p seems conserved for functional reasons.…”

Section: Orf1pmentioning

confidence: 99%

Non-LTR retrotransposons encode noncanonical RRM domains in their first open reading frame

Khazina

Weichenrieder

2009

Proc. Natl. Acad. Sci. U.S.A.

133

198

View full text Add to dashboard Cite

Non-LTR retrotransposons (NLRs) are a unique class of mobile genetic elements that have significant impact on the evolution of eukaryotic genomes. However, the molecular details and functions of their encoded proteins, in particular of the accessory ORF1p proteins, are poorly understood. Here, we identify noncanonical RNA-recognitionmotifs (RRMs) in several phylogenetically unrelated NLR ORF1p proteins. This provides an explanation for their RNA-binding properties and clearly shows that they are not related to the retroviral nucleocapsid protein Gag, despite the frequent presence of CCHC zinc knuckles. In particular, we characterize the ORF1p protein of the human long interspersed nuclear element 1 (LINE-1 or L1). We show that L1ORF1p is a multidomain protein, consisting of a coiled coil (cc), RRM, and C-terminal domain (CTD). Most importantly, we solved the crystal structure of the RRM domain, which is characterized by extended loops stabilized by unique salt bridges. Furthermore, we demonstrate that L1ORF1p trimerizes via its N-terminal cc domain, and we suggest that this property is functionally important for all homologues. The formation of distinct complexes with singlestranded nucleic acids requires the presence of the RRM and CTD domains on the same polypeptide chain as well as their close cooperation. Finally, the phylogenetic analysis of mammalian L1ORF1p shows an ancient origin of the RRM domain and supports a modular evolution of NLRs.genome evolution ͉ LINE-1 ͉ nucleic acid chaperone ͉ RNP ͉ crystal structure

show abstract

“…Straussman et al report that anti-parallel coiled coils in the PDB contain more charged residues in core positions than parallel ones, although it is not yet clear how to interpret this difference [36]. Kammerer et al previously described a short sequence motif that is common in parallel trimers in the PDB but rare in other types of coiled coils, and mutational data support this motif favoring trimer formation [37].…”

Section: Uncovering Relationships Between Sequence Structure and Stamentioning

confidence: 99%

Structural specificity in coiled-coil interactions

Grigoryan

Keating

2008

Current Opinion in Structural Biology

259

278

View full text Add to dashboard Cite

Coiled coils have a rich history in the field of protein design and engineering. Novel structures, such as the first 7-helix coiled coil, continue to provide surprises and insights. Large-scale data sets quantifying the influence of systematic mutations on coiled-coil stability are a valuable new asset to the area. Scoring methods based on sequence and/or structure can predict interaction preferences in coiled-coil-mediated bZIP transcription factor dimerization. Experimental and computational methods for dealing with the near-degeneracy of many coiled-coil structures appear promising for future design applications.

show abstract

A conserved trimerization motif controls the topology of short coiled coils

Cited by 90 publications

References 49 publications

Simultaneous prediction of protein folding and docking at high resolution

Simultaneous prediction of protein folding and docking at high resolution

Non-LTR retrotransposons encode noncanonical RRM domains in their first open reading frame

Structural specificity in coiled-coil interactions

Contact Info

Product

Resources

About