Publication date: Available online 26 September 2015
Source:Journal of Molecular Biology

Author(s): G.C.P. van Zundert, J.P.G.L.M. Rodrigues, M. Trellet, C. Schmitz, P.L. Kastritis, E. Karaca, A.S.J. Melquiond, M. van Dijk, S.J. de Vries, A.M.J.J. Bonvin

The prediction of the quaternary structure of biomolecular macromolecules is of paramount importance for fundamental understanding of cellular processes and drug design. In the era of integrative structural biology, one way of increasing the accuracy of modelling methods used to predict the structure of biomolecular complexes is to include as much experimental or predictive information as possible in the process. This has been at the core of our information-driven docking approach HADDOCK. We present here the updated version 2.2 of the HADDOCK portal, which offers new features such as support for mixed molecule types, additional experimental restraints and improved protocols, all of this in a user-friendly interface. With well over 6000 registered users and 108000 jobs served, an increasing fraction of which on grid resources, we hope this timely upgrade will help the community to solve important biological questions and further advance the field. The HADDOCK2.2 web server is freely accessible to non-profit users at http://haddock.science.uu.nl/services/HADDOCK2.2.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Sarah Loerch, Clara L. Kielkopf

Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Markus Blatter, Stanislaw Dunin-Horkawicz, Inna Grishina, Christophe Maris, Stephane Thore, Timm Maier, Albrecht Bindereif, Janusz M. Bujnicki, Frédéric H.-T. Allain

The RNA recognition motif (RRM) is the far most abundant RNA binding domain. In addition to the typical β1α1β2β3α2β4 fold, various sub-structural elements have been described and reportedly contribute to the high functional versatility of RRMs. The heterogeneous nuclear ribonucleoprotein L (hnRNP L) is a highly abundant protein of 64kDa comprising four RRM domains. Involved in many aspects of RNA metabolism, hnRNP L specifically binds to RNAs containing CA repeats or CA-rich clusters. However, a comprehensive structural description of hnRNP L including its sub-structural elements is missing. Here, we present the structural characterization of the RRM domains of hnRNP L and demonstrate their function in repressing exon 4 of SLC2A2. By comparison of the sub-structural elements between the two highly similar paralog families of hnRNP L and PTB, we defined signatures underlying interacting C-terminal coils (ICCs), the RRM34 domain interaction and RRMs with a C-terminal fifth β-strand, a variation we denoted vRRMs. Furthermore, computational analysis revealed new putative ICC-containing RRM families and allowed us to propose an evolutionary scenario explaining the origins of the ICC and fifth β-strand sub-structural extensions. Our studies provide insights of domain requirements in alternative splicing mediated by hnRNP L and molecular descriptions for the sub-structural elements. In addition, the analysis presented may help to classify other abundant RRM extensions and to predict structure–function relationships.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Matthew Greetham, Emmanuel Skordalakes, David Lydall, Bernard A. Connolly

The telomere is present at the ends of all eukaryotic chromosomes and usually consists of repetitive TG-rich DNA that terminates in a single-stranded 3′ TG extension and a 5′ CA-rich recessed strand. A biochemical assay that allows the in vitro observation of exonuclease-catalyzed degradation (resection) of telomeres has been developed. The approach uses an oligodeoxynucleotide that folds to a stem–loop with a TG-rich double-stranded region and a 3′ single-stranded extension, typical of telomeres. Cdc13, the major component of the telomere-specific CST complex, strongly protects the recessed strand from the 5′→3′ exonuclease activity of the model exonuclease from bacteriophage λ. The isolated DNA binding domain of Cdc13 is less effective at shielding telomeres. Protection is specific, not being observed in control DNA lacking the specific TG-rich telomere sequence. RPA, the eukaryotic single-stranded DNA binding protein, also inhibits telomere resection. However, this protein is non-specific, equally hindering the degradation of non-telomere controls.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Thom Vreven, Iain H. Moal, Anna Vangone, Brian G. Pierce, Panagiotis L. Kastritis, Mieczyslaw Torchala, Raphael Chaleil, Brian Jiménez-García, Paul A. Bates, Juan Fernandez-Recio, Alexandre M.J.J. Bonvin, Zhiping Weng

We present an updated and integrated version of our widely used protein–protein docking and binding affinity benchmarks. The benchmarks consist of non-redundant, high-quality structures of protein–protein complexes along with the unbound structures of their components. Fifty-five new complexes were added to the docking benchmark, 35 of which have experimentally measured binding affinities. These updated docking and affinity benchmarks now contain 230 and 179 entries, respectively. In particular, the number of antibody–antigen complexes has increased significantly, by 67% and 74% in the docking and affinity benchmarks, respectively. We tested previously developed docking and affinity prediction algorithms on the new cases. Considering only the top 10 docking predictions per benchmark case, a prediction accuracy of 38% is achieved on all 55 cases and up to 50% for the 32 rigid-body cases only. Predicted affinity scores are found to correlate with experimental binding energies up to r =0.52 overall and r =0.72 for the rigid complexes.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Sachini U. Siriwardena, Thisari A. Guruge, Ashok S. Bhagwat

Human APOBEC3B deaminates cytosines in DNA and belongs to the AID/APOBEC family of enzymes. These proteins are involved in innate and adaptive immunity and may cause mutations in a variety of cancers. To characterize its ability to convert cytosines into uracils, we tested several derivatives of APOBEC3B gene for their ability to cause mutations in Escherichia coli. Through this analysis, a methionine residue at the junction of the amino-terminal domain (NTD) and the carboxy-terminal domain (CTD) was found to be essential for high mutagenicity. Properties of mutants with substitutions at this position, examination of existing molecular structures of APOBEC3 family members and molecular modeling suggest that this residue is essential for the structural stability of this family of proteins. The APOBEC3B CTD with the highest mutational activity was purified to homogeneity and its kinetic parameters were determined. Size-exclusion chromatography of the CTD monomer showed that it is in equilibrium with its dimeric form and matrix-assisted laser desorption ionization time-of-flight analysis of the protein suggested that the dimer may be quite stable. The partially purified NTD did not show intrinsic deamination activity and did not enhance the activity of the CTD in biochemical assays. Finally, APOBEC3B was at least 10-fold less efficient at mutating 5-methylcytosine (5mC) to thymine than APOBEC3A in a genetic assay and was at least 10-fold less efficient at deaminating 5mC compared to C in biochemical assays. These results shed light on the structural organization of APOBEC3B catalytic domain, its substrate specificity and its possible role in causing genome-wide mutations.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Frédérick Bouffard, Karine Plourde, Simon Bélanger, Geneviève Ouellette, Yvan Labrie, Francine Durocher

The FANC-BRCA DNA repair pathway is activated in response to interstrand crosslinks formed in DNA. A homozygous mutation in 1 of the 17 Fanconi anemia (FA) genes results in malfunctions of this pathway and development of FA syndrome. The integrity of this protein network is essential for good maintenance of DNA repair process and genome stability. Following the identification of an alternatively splice isoform of FANCE (Fanconi anemia complementation group E) significantly expressed in breast cancer individuals from high-risk non-BRCA1/2 families, we studied the impact of this FANCE splice isoform (FANCEΔ4) on DNA repair processes. We have demonstrated that FANCEΔ4 mRNA was efficiently translated into a functional protein and expressed in normal and breast cancer cell lines. Following treatment with the crosslinking agent mitomycin C, EUFA130 (FANCE-deficient) cells infected with FANCEΔ4 were blocked into G2/M phase, while cell survival was significantly reduced compared with FANCE-infected EUFA130 cells. In addition, FANCEΔ4 did not allow FANCD2 and FANCI monoubiquitination, which represents a crucial step of the FANC-BRCA functional pathway. As observed for FANCE wild-type protein, localization of FANCEΔ4 protein was confined to the nucleus following mitomycin C treatment. Although FANCEΔ4 protein showed interaction with FANCE, FANCEΔ4 did not support normal function of FANCE protein in this pathway and could have deleterious effects on FANCE protein activity. We have demonstrated that FANCEΔ4 seems to act as a regulator of FANCD2 protein expression level by promoting its degradation. This study highlights the importance of an efficient regulation of alternative splicing expression of FA genes for proper DNA repair.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Sunmin Kim, Hyuk Lee, SangYoun Park

Escherichia coli TcdA (also known as CsdL) was previously shown to catalyze the ATP-dependent dehydration/cyclization of hypermodified tRNA N 6-threonylcarbamoyladenosine into further cyclic N 6-threonylcarbamoyladenosine. In this study, we report the X-ray crystal structures of E. coli TcdA with either AMP or ATP bound. The AMP/ATP-bound N-terminal sub-domain of TcdA resembles the ATP-binding Rossmann fold of E. coli ThiF and MoeB that are enzymes respectively taking part in the biosynthesis of thiamine and molybdopterin; however, the remaining C-terminal sub-domain of TcdA adopts a structure unrelated to any other known folds. In TcdA, the ATP-utilizing adenylation of tRNA N 6-threonylcarbamoyladenosine and a subsequent thioester formation via an active cysteine, similar to the mechanisms in ThiF and MoeB, could take place for the dehydratase function. Analysis of the structure with sequence alignment suggests the disordered Cys234 of TcdA as the most likely catalytic residue. The structure further indicates that the C-terminal sub-domain can provide a binding interface for the tRNA substrate. Binding study using the surface mutants of TcdA and tRNA reveals that the positively charged regions of mainly the C-terminal sub-domain are important for the tRNA recognition.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Valentina Arkhipova, Elena Stolboushkina, Olesya Kravchenko, Vladislav Kljashtorny, Azat Gabdulkhakov, Maria Garber, Stanislav Nikonov, Birgit Märtens, Udo Bläsi, Oleg Nikonov

The heterotrimeric archaeal IF2 orthologue of eukaryotic translation initiation factor 2 consists of the α-subunit, β-subunit and γ-subunit. Previous studies showed that the γ-subunit of aIF2, besides its central role in Met-tRNAi binding, has an additional function: it binds to the 5′-triphosphorylated end of mRNA and protects its 5′-part from degradation. Competition studies with nucleotides and mRNA, as well as structural and kinetic analyses of aIF2γ mutants, strongly implicate the canonical GTP/GDP-binding pocket in binding to the 5′-triphosphate end of mRNAs. The biological implication of these findings is being discussed.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Sukanya Chaudhury, Clarice de Azevedo Souza, Gregory V. Plano, Roberto N. De Guzman

The type III secretion system (T3SS) is essential in the pathogenesis of Yersinia pestis, the causative agent of plague. A small protein, LcrG, functions as a chaperone to the tip protein LcrV, and the LcrG–LcrV interaction is important in regulating protein secretion through the T3SS. The atomic structure of the LcrG family is currently unknown. However, because of its predicted helical propensity, many have suggested that the LcrG family forms a coiled-coil structure. Here, we show by NMR and CD spectroscopy that LcrG lacks a tertiary structure and it consists of three partially folded α-helices spanning residues 7–38, 41–46, and 58–73. NMR titrations of LcrG with LcrV show that the entire length of a truncated LcrG (residues 7–73) is involved in binding to LcrV. However, there is regional variation in how LcrG binds to LcrV. The C-terminal region of a truncated LcrG (residues 52–73) shows tight binding interaction with LcrV while the N-terminal region (residues 7–51) shows weaker interaction with LcrV. This suggests that there are at least two binding events when LcrG binds to LcrV. Biological assays and mutagenesis indicate that the C-terminal region of LcrG (residues 52–73) is important in blocking protein secretion through the T3SS. Our results reveal structural and mechanistic insights into the atomic conformation of LcrG and how it binds to LcrV.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Hans Peter Sørensen, Peng Xu, Longguang Jiang, Tobias Kromann-Hansen, Knud J. Jensen, Mingdong Huang, Peter A. Andreasen

We have developed a new concept for designing peptidic protein modulators, by recombinantly fusing the peptidic modulator, with randomized residues, directly to the target protein via a linker and screening for internal modulation of the activity of the protein. We tested the feasibility of the concept by fusing a 10-residue-long, disulfide-bond-constrained inhibitory peptide, randomized in selected positions, to the catalytic domain of the serine protease murine urokinase-type plasminogen activator. High-affinity inhibitory peptide variants were identified as those that conferred to the fusion protease the lowest activity for substrate hydrolysis. The usefulness of the strategy was demonstrated by the selection of peptidic inhibitors of murine urokinase-type plasminogen activator with a low nanomolar affinity. The high affinity could not have been predicted by rational considerations, as the high affinity was associated with a loss of polar interactions and an increased binding entropy.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Rebecca D. Giuntoli, Nora B. Linzer, Edward J. Banigan, Charles E. Sing, Monica Olvera de la Cruz, John S. Graham, Reid C. Johnson, John F. Marko

The rate of dissociation of a DNA–protein complex is often considered to be a property of that complex, without dependence on other nearby molecules in solution. We study the kinetics of dissociation of the abundant Escherichia coli nucleoid protein Fis from DNA, using a single-molecule mechanics assay. The rate of Fis dissociation from DNA is strongly dependent on the solution concentration of DNA. The off-rate (k off) of Fis from DNA shows an initially linear dependence on solution DNA concentration, characterized by an exchange rate of k ex ≈9×10−4 (ng/μl)−1 s−1 for 100mM univalent salt buffer, with a very small off-rate at zero DNA concentration. The off-rate saturates at approximately k off,max ≈8×10−3 s−1 for DNA concentrations above ≈20ng/μl. This exchange reaction depends mainly on DNA concentration with little dependence on the length of the DNA molecules in solution or on binding affinity, but this does increase with increasing salt concentration. We also show data for the yeast HMGB protein NHP6A showing a similar DNA-concentration-dependent dissociation effect, with faster rates suggesting generally weaker DNA binding by NHP6A relative to Fis. Our results are well described by a model with an intermediate partially dissociated state where the protein is susceptible to being captured by a second DNA segment, in the manner of “direct transfer” reactions studied for other DNA-binding proteins. This type of dissociation pathway may be important to protein–DNA binding kinetics in vivo where DNA concentrations are large.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Mouna A. Mikati, Dennis Breitsprecher, Silvia Jansen, Emil Reisler, Bruce L. Goode

High rates of actin filament turnover are essential for many biological processes and require the activities of multiple actin-binding proteins working in concert. The mechanistic role of the actin filament severing protein cofilin is now firmly established; however, the contributions of other conserved disassembly-promoting factors including coronin have remained more obscure. Here, we have investigated the mechanism by which yeast coronin (Crn1) enhances F-actin turnover. Using multi-color total internal reflection fluorescence microscopy, we show that Crn1 enhances Cof1-mediated severing by accelerating Cof1 binding to actin filament sides. Further, using biochemical assays to interrogate F-actin conformation, we show that Crn1 alters longitudinal and lateral actin–actin contacts and restricts opening of the nucleotide-binding cleft in actin subunits. Moreover, Crn1 and Cof1 show opposite structural effects on F-actin yet synergize in promoting release of phalloidin from filaments, suggesting that Crn1/Cof1 co-decoration may increase local discontinuities in filament topology to enhance severing.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Simon Lindhoud, Menahem Pirchi, Adrie H. Westphal, Gilad Haran, Carlo P.M. van Mierlo

Molten globules (MGs) are compact, partially folded intermediates that are transiently present during folding of many proteins. These intermediates reside on or off the folding pathway to native protein. Conformational evolution during folding of off-pathway MGs is largely unexplored. Here, we characterize the denaturant-dependent structure of apoflavodoxin's off-pathway MG. Using single-molecule fluorescence resonance energy transfer (smFRET), we follow conversion of unfolded species into MG down to denaturant concentrations that favor formation of native protein. Under strongly denaturing conditions, fluorescence resonance energy transfer histograms show a single peak, arising from unfolded protein. The smFRET efficiency distribution shifts to higher value upon decreasing denaturant concentration because the MG folds. Strikingly, upon approaching native conditions, the fluorescence resonance energy transfer efficiency of the MG rises above that of native protein. Thus, smFRET exposes the misfolded nature of apoflavodoxin's off-pathway MG. We show that conversion of unfolded into MG protein is a gradual, second-order-like process that simultaneously involves separate regions within the polypeptide.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Tsuyoshi Konuma, Kazumasa Sakurai, Masanori Yagi, Yuji Goto, Tetsuro Fujisawa, Satoshi Takahashi

In the folding of β-lactoglobulin (βLG), a predominantly β-sheet protein, a transient intermediate possessing an excess amount of non-native α-helix is formed within a few milliseconds. To characterize the early folding dynamics of βLG in terms of secondary structure content and compactness, we performed submillisecond-resolved circular dichroism (CD) and small-angle X-ray scattering (SAXS) measurements. Time-resolved CD after rapid dilution of urea showed non-native α-helix formation within 200μs. Time-resolved SAXS showed that the radius of gyration (R g) of the intermediate at 300μs was 23.3±0.7Å, indicating a considerable collapse from the unfolded state having R g of 35.1±7.1Å. Further compaction to R g of 21.2±0.3Å occurred with a time constant of 28±11ms. Pair distribution functions showed that the intermediate at 300μs comprises a single collapsed domain with a small fluctuating domain, which becomes more compact after the second collapse. Kinetic measurements in the presence of 2,2,2-trifluoroethanol showed that the intermediate at several milliseconds possessed an increased amount of α-helix but similar R g of 23.0±0.8Å, suggesting similarity of the shape of the intermediate in different solvents. Consequently, the initial collapse occurs globally to a compact state with a small fluctuating domain irrespective of the non-native α-helical contents. The second collapse of the fluctuating domain occurs in accordance with the reported stabilization of the non-native helix around strand A. The non-native helix around strand A might facilitate the formation of long-range contacts required for the folding of βLG.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Lipi Thukral, Simone Schwarze, Isabella Daidone, Hannes Neuweiler

Protein denatured states are the origin of both healthy and toxic conformational species. Denatured states of ultrafast folding proteins are of interest in mechanistic studies because they are energetically close to the kinetic bottleneck of folding. However, their transient nature makes them elusive to experiment. Here, we generated the denatured state of the helical domain BBL that is poised to fold in microseconds by a single-point mutation and combined circular dichroism spectroscopy, single-molecule fluorescence fluctuation analysis, and computer simulation to characterize its structure and dynamics. Circular dichroism showed a largely unfolded ensemble with marginal helix but significant β-sheet content. Main-chain structure and dynamics were unaffected by side-chain interactions that stabilize the native state, as revealed by site-directed mutagenesis and nanosecond loop closure kinetics probed by fluorescence correlation spectroscopy. Replica-exchange and constant-temperature molecular dynamics simulations showed a highly collapsed, hydrogen-bonded denatured state containing turn and β-sheet structure and few nucleating helices in an otherwise unfolded ensemble. An irregular β-hairpin element that connects helices in the native fold was poised to be formed. The surprising observation of β-structure in regions that form helices in the native state is reconciled by a generic low-energy pathway from the northwest quadrant of Ramachandran space to the helical basin present under folding conditions, proposed recently. Our results show that, indeed, rapid nucleation of helix emanates from β-structure formed early within a collapsed ensemble of unfolded conformers.
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Publication date: 25 September 2015
Source:Journal of Molecular Biology, Volume 427, Issue 19

Author(s): Hanzhen Wen, Øyvind Strømland, Øyvind Halskau

Human α-lactalbumin made lethal to tumor cells (HAMLET) is a tumoricidal complex consisting of human α-lactalbumin and multiple oleic acids (OAs). OA has been shown to play a key role in the activity of HAMLET and its related complexes, generally known as protein–fatty acid (PFA) complexes. In contrast to what is known about the fate of the protein component of such complexes, information about what happens to OA during their action is still lacking. We monitored the membrane, OA and protein components of bovine α-lactalbumin complexed with OA (BLAOA; a HAMLET-like substance) and how they associate with each other. Using ultracentrifugation, we found that the OA and lipid components follow each other closely. We then firmly identify a transfer of OA from BLAOA to both artificial and erythrocyte membranes, indicating that natural cells respond similarly to BLAOA treatment as artificial membranes. Uncomplexed OA is unable to similarly affect membranes at the conditions tested, even at elevated concentrations. Thus, BLAOA can spontaneously transfer OA to a lipid membrane. After the interaction with the membrane, the protein is likely to have lost most or all of its OA. We suggest a mechanism for passive import of mainly uncomplexed protein into cells, using existing models for OA's effect on membranes. Our results are consistent with a membrane destabilization mediated predominantly by OA insertion being a significant contribution to PFA cytotoxicity.
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Publication date: Available online 25 September 2015
Source:Journal of Molecular Biology

Author(s): Tobias W. Giessen, Pamela A. Silver

Compartmentalization is one of the defining features of life. Through intracellular spatial control, cells are able to organize and regulate their metabolism. One of the most broadly used organizational principles in nature is encapsulation. Cellular processes can either be encapsulated within membrane-bound organelles or proteinaceous compartments that create distinct microenvironments optimized for a given task. Further challenges addressed through intracellular compartmentalization are toxic or volatile pathway intermediates, slow turnover rates, and competing side reactions. This review highlights a selection of naturally occurring membrane- and protein-based encapsulation systems in microbes and their recent applications and emerging opportunities in synthetic biology. We focus on examples that use engineered cellular organization to control metabolic pathway flux for the production of useful compounds and materials.
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