Chemical synthesis and evaluation of a backbone‐cyclized minimized 2‐helix Z‐domain

The Z‐molecule is a small, engineered IgG‐binding affinity protein derived from the immunoglobulin‐binding domain B of Staphylococcus aureus protein A. The Z‐domain consists of 58 amino acids forming a well‐defined antiparallel three‐helix structure. Two of the three helices are involved in ligand binding, whereas the third helix provides structural support to the three‐helix bundle. The small size and the stable three‐helix structure are two attractive properties comprised in the Z‐domain, but a further reduction in size of the protein is valuable for several reasons. Reduction in size facilitates synthetic production of any protein‐based molecule, which is beneficial from an economical viewpoint. In addition, a smaller protein is easier to manipulate through chemical modifications. By omitting the third stabilizing helix from the Z‐domain and joining the N‐ and C‐termini by a native peptide bond, the affinity protein obtains the advantageous properties of a smaller scaffold and in addition becomes resistant to exoproteases. We here demonstrate the synthesis and evaluation of a novel cyclic two‐helix Z‐domain. The molecule has retained affinity for its target protein, is resistant to heat treatment, and lacks both N‐ and C‐termini. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Dimerization of Sir3 via its C‐terminal winged helix domain is essential for yeast heterochromatin formation

Gene silencing in budding yeast relies on the binding of the Silent Information Regulator (Sir) complex to chromatin, which is mediated by extensive interactions between the Sir proteins and nucleosomes. Sir3, a divergent member of the AAA+ ATPase‐like family, contacts both the histone H4 tail and the nucleosome core. Here, we present the structure and function of the conserved C‐terminal domain of Sir3, comprising 138 amino acids. This module adopts a variant winged helix‐turn‐helix (wH) architecture that exists as a stable homodimer in solution. Mutagenesis shows that the self‐association mediated by this domain is essential for holo‐Sir3 dimerization. Its loss impairs Sir3 loading onto nucleosomes in vitro and eliminates silencing at telomeres and HM loci in vivo. Replacing the Sir3 wH domain with an unrelated bacterial dimerization motif restores both HM and telomeric repression in sir3Δ cells. In contrast, related wH domains of archaeal and human members of the Orc1/Sir3 family are monomeric and have DNA binding activity. We speculate that a dimerization function for the wH evolved with Sir3's ability to facilitate heterochromatin formation.     

Noncollagenous region of the streptococcal collagen‐like protein is a trimerization domain that supports refolding of adjacent homologous and heterologous collagenous domains

Proper folding of the (Gly‐Xaa‐Yaa)_n sequence of animal collagens requires adjacent N‐ or C‐terminal noncollagenous trimerization domains which often contain coiled‐coil or beta sheet structure. Collagen‐like proteins have been found recently in a number of bacteria, but little is known about their folding mechanism. The Scl2 collagen‐like protein from Streptococcus pyogenes has an N‐terminal globular domain, designated V_sp, adjacent to its triple‐helix domain. The V_sp domain is required for proper refolding of the Scl2 protein in vitro. Here, recombinant V_sp domain alone is shown to form trimers with a significant α‐helix content and to have a thermal stability of T_m = 45°C. Examination of a new construct shows that the V_sp domain facilitates efficient in vitro refolding only when it is located N‐terminal to the triple‐helix domain but not when C‐terminal to the triple‐helix domain. Fusion of the V_sp domain N‐terminal to a heterologous (Gly‐Xaa‐Yaa)_n sequence from Clostridium perfringens led to correct folding and refolding of this triple‐helix, which was unable to fold into a triple‐helical, soluble protein on its own. These results suggest that placement of a functional trimerization module adjacent to a heterologous Gly‐Xaa‐Yaa repeating sequence can lead to proper folding in some cases but also shows specificity in the relative location of the trimerization and triple‐helix domains. This information about their modular nature can be used in the production of novel types of bacterial collagen for biomaterial applications.     

Crystal structure of the N‐terminal methyltransferase‐like domain of anamorsin

Anamorsin is a recently identified molecule that inhibits apoptosis during hematopoiesis. It contains an N‐terminal methyltransferase‐like domain and a C‐terminal Fe‐S cluster motif. Not much is known about the function of the protein. To better understand the function of anamorsin, we have solved the crystal structure of the N‐terminal domain at 1.8 Å resolution. Although the overall structure resembles a typical S‐adenosylmethionine (SAM) dependent methyltransferase fold, it lacks one α‐helix and one β‐strand. As a result, the N‐terminal domain as well as the full‐length anamorsin did not show S‐adenosyl‐l ‐methionine (AdoMet) dependent methyltransferase activity. Structural comparisons with known AdoMet dependent methyltransferases reveals subtle differences in the SAM binding pocket that preclude the N‐terminal domain from binding to AdoMet. The N‐terminal methyltransferase‐like domain of anamorsin probably functions as a structural scaffold to inhibit methyl transfers by out‐competing other AdoMet dependant methyltransferases or acts as bait for protein–protein interactions.Proteins 2014; 82:1066–1071. © 2013 Wiley Periodicals, Inc.     

Mechanism of formation of the C‐terminal β‐hairpin of the B3 domain of the immunoglobulin‐binding protein G from Streptococcus. IV. Implication for the mechanism of folding of the parent protein

A 34‐residue α/β peptide [IG(28–61)], derived from the C‐terminal part of the B3 domain of the immunoglobulin binding protein G from Streptoccocus, was studied using CD and NMR spectroscopy at various temperatures and by differential scanning calorimetry. It was found that the C‐terminal part (a 16‐residue‐long fragment) of this peptide, which corresponds to the sequence of the β‐hairpin in the native structure, forms structure similar to the β‐hairpin only at T = 313 K, and the structure is stabilized by non‐native long‐range hydrophobic interactions (Val47–Val59). On the other hand, the N‐terminal part of IG(28–61), which corresponds to the middle α‐helix in the native structure, is unstructured at low temperature (283 K) and forms an α‐helix‐like structure at 305 K, and only one helical turn is observed at 313 K. At all temperatures at which NMR experiments were performed (283, 305, and 313 K), we do not observe any long‐range connectivities which would have supported packing between the C‐terminal (β‐hairpin) and the N‐terminal (α‐helix) parts of the sequence. Such interactions are absent, in contrast to the folding pathway of the B domain of protein G, proposed recently by Kmiecik and Kolinski (Biophys J 2008, 94, 726–736), based on Monte‐Carlo dynamics studies. Alternative folding mechanisms are proposed and discussed. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 469–480, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

The three‐dimensional structure of TrmB,a transcriptional regulator of dual function in the hyperthermophilic archaeon Pyrococcus furiosus in complex with sucrose

TrmB is a repressor that binds maltose, maltotriose, and sucrose, as well as other α‐glucosides. It recognizes two different operator sequences controlling the TM (Trehalose/Maltose) and the MD (Maltodextrin) operon encoding the respective ABC transporters and sugar‐degrading enzymes. Binding of maltose to TrmB abrogates repression of the TM operon but maintains the repression of the MD operon. On the other hand, binding of sucrose abrogates repression of the MD operon but maintains repression of the TM operon. The three‐dimensional structure of TrmB in complex with sucrose was solved and refined to a resolution of 3.0 Å. The structure shows the N‐terminal DNA binding domain containing a winged‐helix‐turn‐helix (wHTH) domain followed by an amphipathic helix with a coiled‐coil motif. The latter promotes dimerization and places the symmetry mates of the putative recognition helix in the wHTH motif about 30 Å apart suggesting a canonical binding to two successive major grooves of duplex palindromic DNA. This suggests that the structure resembles the conformation of TrmB recognizing the pseudopalindromic TM promoter but not the conformation recognizing the nonpalindromic MD promoter.     

Crystal structure of the C‐terminal domain of mouse TLR9

Toll‐like receptors (TLRs) are important pattern recognition receptors that function in innate immunity. Elucidating the structure and signaling mechanisms of TLR9, a sensor of foreign and endogenous DNA, is essential for understanding its key role in immunity against microbial pathogens as well as in autoimmunity. Abundant evidence suggests that the TLR9‐CTD (C‐terminal domain) by itself is capable of DNA binding and signaling. The crystal structure of unliganded mouse TLR9‐CTD is presented. TLR9‐CTD exhibits one unique feature, a cluster of stacked aromatic and arginine side chains on its concave face. Overall, its structure is most related to the TLR8‐CTD, suggesting a similar mode of ligand binding and signaling. Proteins 2014; 82:2874–2878. © 2014 Wiley Periodicals, Inc.     

Crystal structure and nucleic acid‐binding activity of the CRISPR‐associated protein Csx1 of Pyrococcus furiosus

In many prokaryotic organisms, chromosomal loci known as clustered regularly interspaced short palindromic repeats (CRISPRs) and CRISPR‐associated (CAS) genes comprise an acquired immune defense system against invading phages and plasmids. Although many different Cas protein families have been identified, the exact biochemical functions of most of their constituents remain to be determined. In this study, we report the crystal structure of PF1127, a Cas protein of Pyrococcus furiosus DSM 3638 that is composed of 480 amino acids and belongs to the Csx1 family. The C‐terminal domain of PF1127 has a unique β‐hairpin structure that protrudes out of an α‐helix and contains several positively charged residues. We demonstrate that PF1127 binds double‐stranded DNA and RNA and that this activity requires an intact β‐hairpin and involve the homodimerization of the protein. In contrast, another Csx1 protein from Sulfolobus solfataricus P2 that is composed of 377 amino acids does not have the β‐hairpin structure and exhibits no DNA‐binding properties under the same experimental conditions. Notably, the C‐terminal domain of these two Csx1 proteins is greatly diversified, in contrast to the conserved N‐terminal domain, which appears to play a common role in the homodimerization of the protein. Thus, although P. furiosus Csx1 is identified as a nucleic acid‐binding protein, other Csx1 proteins are predicted to exhibit different individual biochemical activities. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Structural characterization of the heme‐based oxygen sensor,AfGcHK, its interactions with the cognate response regulator,and their combined mechanism of action in a bacterial two‐component signaling system

The oxygen sensor histidine kinase AfGcHK from the bacterium Anaeromyxobacter sp. Fw 109‐5 forms a two‐component signal transduction system together with its cognate response regulator (RR). The binding of oxygen to the heme iron of its N‐terminal sensor domain causes the C‐terminal kinase domain of AfGcHK to autophosphorylate at His183 and then transfer this phosphate to Asp52 or Asp169 of the RR protein. Analytical ultracentrifugation revealed that AfGcHK and the RR protein form a complex with 2:1 stoichiometry. Hydrogen‐deuterium exchange coupled to mass spectrometry (HDX‐MS) suggested that the most flexible part of the whole AfGcHK protein is a loop that connects the two domains and that the heme distal side of AfGcHK, which is responsible for oxygen binding, is the only flexible part of the sensor domain. HDX‐MS studies on the AfGcHK:RR complex also showed that the N‐side of the H9 helix in the dimerization domain of the AfGcHK kinase domain interacts with the helix H1 and the β‐strand B2 area of the RR protein's Rec1 domain, and that the C‐side of the H8 helix region in the dimerization domain of the AfGcHK protein interacts mostly with the helix H5 and β‐strand B6 area of the Rec1 domain. The Rec1 domain containing the phosphorylable Asp52 of the RR protein probably has a significantly higher affinity for AfGcHK than the Rec2 domain. We speculate that phosphorylation at Asp52 changes the overall structure of RR such that the Rec2 area containing the second phosphorylation site (Asp169) can also interact with AfGcHK. Proteins 2016; 84:1375–1389. © 2016 Wiley Periodicals, Inc.     

Synthesis and conformation of an analog of the helix‐loop‐helix domain of the Id1 protein containing the O‐acyl iso‐prolyl‐seryl switch motif

Synthetic peptides reproducing the helix‐loop‐helix (HLH) domains of the Id proteins fold into highly stable helix bundles upon self‐association. Recently, we have shown that the replacement of the dipeptide Val‐Ser at the loop–helix‐2 junction with the corresponding O‐acyl iso‐dipeptide leads to a completely unfolded state that only refolds after intramolecular O → N acyl migration. Herein, we report on an Id HLH analog based on the substitution of the Pro‐Ser motif at the helix‐1–loop junction with the corresponding O‐acyl iso‐dipeptide. This analog has been successfully synthesized by solid‐phase Fmoc chemistry upon suppression of DKP formation. No secondary structure could be detected for the O‐acyl iso‐peptide before its conversion into the native form by O → N acyl shift. These results show that the loop–helix junctions are determinant for the folded/unfolded state of the Id HLH domain. Further, despite the high risk of DKP formation, peptides containing O‐acyl iso‐Pro‐Ser/Thr units are synthetically accessible by Fmoc chemistry. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Structural characterization of a neurotoxic threonine‐rich peptide corresponding to the human prion protein α2‐helical 180–195 segment,and comparison with full‐length α2‐helix‐derived peptides

The 173–195 segment corresponding to the helix 2 of the globular PrP domain is a good candidate to be one of the several ‘spots’ of intrinsic structural flexibility, which might induce local destabilization and concur to protein transformation, leading to aggregation‐prone conformations. Here, we report CD and NMR studies on the α2‐helix‐derived peptide of maximal length (hPrP[180–195]) that is able to exhibit a regular structure different from the prevalently random arrangement of other α2‐helix‐derived peptides. This peptide, which has previously been shown to be affected by buffer composition via the ion charge density dependence typical of Hofmeister effects, corresponds to the C‐terminal sequence of the PrP^C full‐length α2‐helix and includes the highly conserved threonine‐rich 188–195 segment. At neutral pH, its conformation is dominated by β‐type contributions, which only very strong environmental modifications are able to modify. On TFE addition, an increase of α‐helical content can be observed, but a fully helical conformation is only obtained in neat TFE. However, linking of the 173–179 segment, as occurring in wild‐type and mutant peptides corresponding to the full‐length α2‐helix, perturbs these intrinsic structural propensities in a manner that depends on whether the environment is water or TFE. Overall, these results confirm that the 180–195 parental region in hPrP^C makes a strong contribution to the chameleon conformational behavior of the segment corresponding to the full‐length α2‐helix, and could play a role in determining structural rearrangements of the entire globular domain. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

The solution structure of the forkhead box‐O DNA binding domain of Brugia malayi DAF‐16a

Brugia malayi is a parasitic nematode that causes lymphatic filariasis in humans. Here the solution structure of the forkhead DNA binding domain of Brugia malayi DAF‐16a, a putative ortholog of Caenorhabditis elegans DAF‐16, is reported. It is believed to be the first structure of a forkhead or winged helix domain from an invertebrate. C. elegans DAF‐16 is involved in the insulin/IGF‐I signaling pathway and helps control metabolism, longevity, and development. Conservation of sequence and structure with human FOXO proteins suggests that B. malayi DAF‐16a is a member of the FOXO family of forkhead proteins. Proteins 2014; 82:3490–3496. © 2014 Wiley Periodicals, Inc.     

Crystal structure of JHP933 from Helicobacter pylori J99 shows two‐domain architecture with a DUF1814 family nucleotidyltransferase domain and a helical bundle domain

The jhp0933 gene in the plasticity region of Helicobacter pylori J99 encodes a hypothetical protein (JHP933), which may play some roles in pathogenesis. Here, we have determined the crystal structure of JHP933 at 2.17 Å. It represents the first crystal structure of the DUF1814 protein family. JHP933 consists of two domains: an N‐terminal domain of the nucleotidyltransferase (NTase) fold and a C‐terminal helix bundle domain. A highly positively charged surface patch exists adjacent to the putative NTP binding site. Structural similarity of JHP933 to known NTases is very remote, suggesting that it may function as a novel NTase. Proteins 2014; 82:2275–2281. © 2014 Wiley Periodicals, Inc.     

Structure of the Rad50 DNA double‐strand break repair protein in complex with DNA

The Mre11–Rad50 nuclease–ATPase is an evolutionarily conserved multifunctional DNA double‐strand break (DSB) repair factor. Mre11–Rad50's mechanism in the processing, tethering, and signaling of DSBs is unclear, in part because we lack a structural framework for its interaction with DNA in different functional states. We determined the crystal structure of Thermotoga maritima Rad50^NBD (nucleotide‐binding domain) in complex with Mre11^HLH (helix‐loop‐helix domain), AMPPNP, and double‐stranded DNA. DNA binds between both coiled‐coil domains of the Rad50 dimer with main interactions to a strand‐loop‐helix motif on the NBD. Our analysis suggests that this motif on Rad50 does not directly recognize DNA ends and binds internal sites on DNA. Functional studies reveal that DNA binding to Rad50 is not critical for DNA double‐strand break repair but is important for telomere maintenance. In summary, we provide a structural framework for DNA binding to Rad50 in the ATP‐bound state.     

Crystal structure of Streptococcus pneumoniae Sp1610, a putative tRNA methyltransferase,in complex with S‐adenosyl‐L‐methionine

Streptococcus pneumoniae Sp1610, a Class‐I fold S‐adenosylmethionine (AdoMet)‐dependent methyltransferase, is a member of the COG2384 family in the Clusters of Orthologous Groups database, which catalyzes the methylation of N¹‐adenosine at position 22 of bacterial tRNA. We determined the crystal structure of Sp1610 in the ligand‐free and the AdoMet‐bound forms at resolutions of 2.0 and 3.0 Å, respectively. The protein is organized into two structural domains: the N‐terminal catalytic domain with a Class I AdoMet‐dependent methyltransferase fold, and the C‐terminal substrate recognition domain with a novel fold of four α‐helices. Observations of the electrostatic potential surface revealed that the concave surface located near the AdoMet binding pocket was predominantly positively charged, and thus this was predicted to be an RNA binding area. Based on the results of sequence alignment and structural analysis, the putative catalytic residues responsible for substrate recognition are also proposed.