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1.
Coiled coil is a ubiquitous structural motif in proteins, with two to seven alpha helices coiled together like the strands of a rope, and coiled coil folding and assembly is not completely understood. A GCN4 leucine zipper mutant with four mutations of K3A, D7A, Y17W, and H18N has been designed, and the crystal structure has been determined at 1.6 Å resolution. The peptide monomer shows a helix trunk with short curved N‐ and C‐termini. In the crystal, two monomers cross in 35° and form an X‐shaped dimer, and each X‐shaped dimer is welded into the next one through sticky hydrophobic ends, thus forming an extended two‐stranded, parallel, super long coiled coil rather than a discrete, two‐helix coiled coil of the wild‐type GCN4 leucine zipper. Leucine residues appear at every seventh position in the super long coiled coil, suggesting that it is an extended super leucine zipper. Compared to the wild‐type leucine zipper, the N‐terminus of the mutant has a dramatic conformational change and the C‐terminus has one more residue Glu 32 determined. The mutant X‐shaped dimer has a large crossing angle of 35° instead of 18° in the wild‐type dimer. The results show a novel assembly mode and oligomeric state of coiled coil, and demonstrate that mutations may affect folding and assembly of the overall coiled coil. Analysis of the formation mechanism of the super long coiled coil may help understand and design self‐assembling protein fibers.  相似文献   

2.
The coiled‐coil is one of the most common protein structural motifs. Amino acid sequences of regions that participate in coiled‐coils contain a heptad repeat in which every third then forth residue is occupied by a hydrophobic residue. Here we examine the consequences of a “stutter,” a deviation of the idealized heptad repeat that is found in the central coiled‐coil of influenza hemagluttinin HA2. Characterization of a peptide containing the native stutter‐containing HA2 sequence, as well as several variants in which the stutter was engineered out to restore an idealized heptad repeat pattern, revealed that the stutter is important for allowing coiled‐coil formation in the WT HA2 at both neutral and low pH (7.1 and 4.5). By contrast, all variants that contained idealized heptad repeats exhibited marked pH‐dependent coiled‐coil formation with structures forming much more stably at low pH. A crystal structure of one variant containing an idealized heptad repeat, and comparison to the WT HA2 structure, suggest that the stutter distorts the optimal interhelical core packing arrangement, resulting in unwinding of the coiled‐coil superhelix. Interactions between acidic side chains, in particular E69 and E74 (present in all peptides studied), are suggested to play a role in mediating these pH‐dependent conformational effects. This conclusion is partially supported by studies on HA2 variant peptides in which these positions were altered to aspartic acid. These results provide new insight into the structural role of the heptad repeat stutter in HA2. Proteins 2014; 82:2220–2228. © 2014 Wiley Periodicals, Inc.  相似文献   

3.
4.
The structural maintenance of chromosomes (SMC) proteins form the cores of multisubunit complexes that are required for the segregation and global organization of chromosomes in all domains of life. These proteins share a common domain structure in which N‐ and C‐ terminal regions pack against one another to form a globular ATPase domain. This “head” domain is connected to a central, globular, “hinge” or dimerization domain by a long, antiparallel coiled coil. To date, most efforts for structural characterization of SMC proteins have focused on the globular domains. Recently, however, we developed a method to map interstrand interactions in the 50‐nm coiled‐coil domain of MukB, the divergent SMC protein found in γ‐proteobacteria. Here, we apply that technique to map the structure of the Bacillus subtilis SMC (BsSMC) coiled‐coil domain. We find that, in contrast to the relatively complicated coiled‐coil domain of MukB, the BsSMC domain is nearly continuous, with only two detectable coiled‐coil interruptions. Near the middle of the domain is a break in coiled‐coil structure in which there are three more residues on the C‐terminal strand than on the N‐terminal strand. Close to the head domain, there is a second break with a significantly longer insertion on the same strand. These results provide an experience base that allows an informed interpretation of the output of coiled‐coil prediction algorithms for this family of proteins. A comparison of such predictions suggests that these coiled‐coil deviations are highly conserved across SMC types in a wide variety of organisms, including humans. Proteins 2015; 83:1027–1045. © 2015 Wiley Periodicals, Inc.  相似文献   

5.
Short, alpha‐helical coiled coils provide a simple, modular method to direct the assembly of proteins into higher order structures. We previously demonstrated that by genetically fusing de novo–designed coiled coils of the appropriate oligomerization state to a natural trimeric protein, we could direct the assembly of this protein into various geometrical cages. Here, we have extended this approach by appending a coiled coil designed to trimerize in response to binding divalent transition metal ions and thereby achieve metal ion‐dependent assembly of a tetrahedral protein cage. Ni2+, Co2+, Cu2+, and Zn2+ ions were evaluated, with Ni2+ proving the most effective at mediating protein assembly. Characterization of the assembled protein indicated that the metal ion–protein complex formed discrete globular structures of the diameter expected for a complex containing 12 copies of the protein monomer. Protein assembly could be reversed by removing metal ions with ethylenediaminetetraacetic acid or under mildly acidic conditions.  相似文献   

6.
The synthesis of difficult peptide sequences has been a challenge since the very beginning of SPPS. The self‐assembly of the growing peptide chains has been proposed as one of the causes of this synthetic problem. However, there is an increasing need to obtain peptides and proteins that are prone to aggregate. These peptides and proteins are generally associated with diseases known as amyloidoses. We present an efficient SPPS of two homologous peptide fragments of HuPrP (106–126) and MoPrP105–125 based on the use of the PEGA resin combined with proper coupling approaches. These peptide fragments were also studied by CD and TEM to determine their ability to aggregate. On the basis of these results, we support PEG‐based resins as an efficient synthetic tool to prepare peptide sequences prone to aggregate on‐resin. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.  相似文献   

7.
Peptide‐based hydrogels have gained much interest for biomedical applications as a result of their biocompatibility. Herein, we reported a synthetic pH‐sensitive and calcium‐responsive peptide‐amphiphilic hydrogel. The sequences of the peptide amphiphiles were derived from the repeat‐in‐toxin (RTX) motif. At a certain peptide‐amphiphile concentration, self‐assembly was accompanied by the formation of a rigid, viscoelastic hydrogel at low pH or the presence of calcium ions. Circular dichroism spectra showed that the peptide amphiphiles adopted beta‐sheet structure. Meanwhile, as revealed by transmission electron microscopy, the peptide‐amphiphile self‐assembly was accompanied by the formation of long interconnected nanofibrillar superstructure. Material properties of the resulting peptide‐amphiphile hydrogel were characterized using oscillatory sheer rheology, and the storage modulus (G′) was found to be one order of magnitude higher than the loss modulus (G″), indicating a moderately rigid viscoelastic material. Furthermore, with systematical residue substitution, it was found that the aspartic acid within the repeat‐in‐toxin sequence of peptide amphiphiles was responsible for the pH and calcium selectivity. The environmental responsiveness, secondary structure, morphology, and mechanical nature of the peptide‐amphiphile hydrogel make it a possible material candidate for biomedical and engineering application. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.  相似文献   

8.
Prostate apoptosis response factor‐4 (Par‐4) is a pro‐apoptotic and tumor‐suppressive protein. A highly conserved heptad repeat sequence at the Par‐4 C‐terminus suggests the presence of a leucine zipper (LZ). This C‐terminal region is essential for Par‐4 self‐association and interaction with various effector proteins. We have used nuclear magnetic resonance (NMR) spectroscopy to fully assign the chemical shift resonances of a peptide comprising the LZ domain of Par‐4 at neutral pH. Further, we have investigated the properties of the Par‐4 LZ domain and two point mutants under a variety of conditions using NMR, circular dichroism (CD), light scattering, and bioinformatics. Results indicate an environment‐dependent conformational equilibrium between a partially ordered monomer (POM) and a predominantly coiled coil dimer (CCD). The combination of techniques used allows the time scales of the equilibrium to be probed and also helps to identify features of the amino acid sequence that may influence the equilibrium. Proteins 2010. © 2010 Wiley‐Liss, Inc.  相似文献   

9.
The tetratricopeptide repeat (TPR) motif is a protein–protein interaction module that acts as an organizing centre for complexes regulating a multitude of biological processes. Despite accumulating evidence for the formation of TPR oligomers as an additional level of regulation there is a lack of structural and solution data explaining TPR self‐association. In the present work we characterize the trimeric TPR‐containing protein YbgF, which is linked to the Tol system in Gram‐negative bacteria. By subtracting previously identified TPR consensus residues required for stability of the fold from residues conserved across YbgF homologs, we identified residues involved in oligomerization of the C‐terminal YbgF TPR domain. Crafting these residues, which are located in loop regions between TPR motifs, onto the monomeric consensus TPR protein CTPR3 induced the formation of oligomers. The crystal structure of this engineered oligomer shows an asymmetric trimer where stacking interactions between the introduced tyrosines and displacement of the C‐terminal hydrophilic capping helix, present in most TPR domains, are key to oligomerization. Asymmetric trimerization of the YbgF TPR domain and CTPR3Y3 leads to the formation of higher order oligomers both in the crystal and in solution. However, such open‐ended self‐association does not occur in full‐length YbgF suggesting that the protein's N‐terminal coiled‐coil domain restricts further oligomerization. This interpretation is borne out in experiments where the coiled‐coil domain of YbgF was engineered onto the N‐terminus of CTPR3Y3 and shown to block self‐association beyond trimerization. Our study lays the foundations for understanding the structural basis for TPR domain self‐association and how such self‐association can be regulated in TPR domain‐containing proteins. Proteins 2010. © 2010 Wiley‐Liss, Inc.  相似文献   

10.
11.
Homomeric coiled‐coils can self‐assemble into a wide range of structural states with different helix topologies and oligomeric states. In this study, we have combined de novo structure modeling with stability calculations to simultaneously predict structure and oligomeric states of homomeric coiled‐coils. For dimers an asymmetric modeling protocol was developed. Modeling without symmetry constraints showed that backbone asymmetry is important for the formation of parallel dimeric coiled‐coils. Collectively, our results demonstrate that high‐resolution structure of coiled‐coils, as well as parallel and antiparallel orientations of dimers and tetramers, can be accurately predicted from sequence. De novo modeling was also used to generate models of competing oligomeric states, which were used to compare stabilities and thus predict the native stoichiometry from sequence. In a benchmark set of 33 coiled‐coil sequences, forming dimers to pentamers, up to 70% of the oligomeric states could be correctly predicted. The calculations demonstrated that the free energy of helix folding could be an important factor for determining stability and oligomeric state of homomeric coiled‐coils. The computational methods developed here should be broadly applicable to studies of sequence‐structure relationships in coiled‐coils and the design of higher order assemblies with improved oligomerization specificity. Proteins 2015; 83:235–247. © 2014 Wiley Periodicals, Inc.  相似文献   

12.
Human pathogenic gram‐negative bacteria, such as enteropathogenic Escherichia coli (EPEC), rely on type III secretion systems (T3SS) to translocate virulence factors directly into host cells. The coiled‐coil domains present in the structural proteins of T3SS are conformed by amphipathic alpha‐helical structures that play an important role in the protein‐protein interaction and are essential for the assembly of the translocation complex. To investigate the inhibitory capacity of these domains on the T3SS of EPEC, we synthesized peptides between 7 and 34 amino acids based on the coiled‐coil domains of proteins that make up this secretion system. This analysis was performed through in vitro hemolysis assays by assessing the reduction of T3SS‐dependent red blood cell lysis in the presence of the synthesized peptides. After confirming its inhibitory capacity, we performed molecular modeling assays using combined techniques, docking‐molecular dynamic simulations, and quantum‐mechanic calculations of the various peptide‐protein complexes, to improve the affinity of the peptides to the target proteins selected from T3SS. These techniques allowed us to demonstrate that the peptides with greater inhibitory activity, directed against the coiled‐coil domain of the C‐terminal region of EspA, present favorable hydrophobic and hydrogen bond molecular interactions. Particularly, the hydrogen bond component is responsible for the stabilization of the peptide‐protein complex. This study demonstrates that compounds targeting T3SS from pathogenic bacteria can indeed inhibit bacterial infection by presenting a higher specificity than broad‐spectrum antibiotics. In turn, these peptides could be taken as initial structures to design and synthesize new compounds that mimic their inhibitory pharmacophoric pattern.  相似文献   

13.
This work advances bottom‐up design of bioinspired materials built from peptide‐amphiphiles, which are a class of bioconjugates in which a biofunctional peptide is covalently attached to a hydrophobic moiety that drives self‐assembly in aqueous solution. Specifically, this work highlights the importance of peptide contour length in determining the equilibrium secondary structure of the peptide as well as the self‐assembled (i.e., micelle) geometry. Peptides used here repeat a seven‐amino acid sequence between one and four times to vary peptide contour length while maintaining similar peptide‐peptide interactions. Without a hydrophobic tail, these peptides all exhibit a combination of random coil and α‐helical structure. Upon self‐assembly in the crowded environment of a micellar corona, however, short peptides are prone to β‐sheet structure and cylindrical micelle geometry while longer peptides remain helical in spheroidal micelles. The transition to β‐sheets in short peptides is rapid, whereby amphiphiles first self‐assemble with α‐helical peptide structure, then transition to their equilibrium β‐sheet structure at a rate that depends on both temperature and ionic strength. These results identify peptide contour length as an important control over equilibrium peptide secondary structure and micelle geometry. Furthermore, the time‐dependent nature of the helix‐to‐sheet transition opens the door for shape‐changing bioinspired materials with tunable conversion rates. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 573–581, 2013.  相似文献   

14.
Current biotechnological applications such as biosensors, protein arrays, and microchips require oriented immobilization of enzymes. The characteristics of recognition, self‐assembly and ease of genetic manipulation make inorganic binding peptides an ideal molecular tool for site‐specific enzyme immobilization. Herein, we demonstrate the utilization of gold binding peptide (GBP1) as a molecular linker genetically fused to alkaline phosphatase (AP) and immobilized on gold substrate. Multiple tandem repeats (n = 5, 6, 7, 9) of gold binding peptide were fused to N‐terminus of AP (nGBP1‐AP) and the enzymes were expressed in E. coli cells. The binding and enzymatic activities of the bi‐functional fusion constructs were analyzed using quartz crystal microbalance spectroscopy and biochemical assays. Among the multiple‐repeat constructs, 5GBP1‐AP displayed the best bi‐functional activity and, therefore, was chosen for self‐immobilization studies. Adsorption and assembly properties of the fusion enzyme, 5GBP1‐AP, were studied via surface plasmon resonance spectroscopy and atomic force microscopy. We demonstrated self‐immobilization of the bi‐functional enzyme on micro‐patterned substrates where genetically linked 5GBP1‐AP displayed higher enzymatic activity per area compared to that of AP. Our results demonstrate the promising use of inorganic binding peptides as site‐specific molecular linkers for oriented enzyme immobilization with retained activity. Directed assembly of proteins on solids using genetically fused specific inorganic‐binding peptides has a potential utility in a wide range of biosensing and bioconversion processes. Biotechnol. Bioeng. 2009;103: 696–705. © 2009 Wiley Periodicals, Inc.  相似文献   

15.
Osmosensing transporter ProP protects bacteria from osmotically induced dehydration by mediating the uptake of zwitterionic osmolytes. ProP activity is a sigmoidal function of the osmolality. ProP orthologues share an extended, cytoplasmic C‐terminal domain. Orthologues with and without a C‐terminal, α‐helical coiled‐coil domain respond similarly to the osmolality. ProP concentrates at the poles and septa of Escherichia coli cells in a cardiolipin (CL)‐dependent manner. The roles of phospholipids and the C‐terminal domain in subcellular localization of ProP were explored. Liposome association of peptides representing the C‐terminal domains of ProP orthologues and variants in vitro was compared with subcellular localization of the corresponding orthologues and variants in vivo. In the absence of coiled‐coil formation, the C‐terminal domain bound liposomes and ProP concentrated at the cell poles in a CL‐independent manner. The presence of the coiled‐coil replaced those phenomena with CL‐dependent binding and localization. The effects of amino acid replacements on lipid association of the C‐terminal peptide fully recapitulated their effects on the subcellular localization of ProP. These data suggest that polar localization of ProP results from association of its C‐terminal domain with the anionic lipid‐enriched membrane at the cell poles. The coiled‐coil domain present on only some orthologues renders that phenomenon CL‐dependent.  相似文献   

16.
Biofouling, the undesirable accumulation of organisms onto surfaces, affects many areas including health, water, and energy. We previously designed a tripeptide that self‐assembles into a coating that prevents biofouling. The peptide comprises three amino acids: DOPA, which allows its adhesion to the surface, and two fluorinated phenylalanine residues that direct its self‐assembly into a coating and acquire it with antifouling properties. This short peptide has an ester group at its C‐terminus. To examine the importance of this end group for the self‐assembly and antifouling properties of the peptide, we synthesized and characterized tripeptides with different end groups (ester, amide, or carboxylic group). Our results indicate that different groups at the C‐terminus of the peptide can lead to a change in the peptide assembly on the surface and its adsorption process. However, this change only affects the antifouling properties of the coating toward Gram‐positive bacteria (Staphylococcus epidermidis), whereas Gram‐negative bacteria (Escherichia coli) are not affected.  相似文献   

17.
It has proven challenging to obtain collagen‐mimetic fibrils by protein design. We recently reported the self‐assembly of a mini‐fibril showing a 35 nm, D‐period like, axially repeating structure using the designed triple helix Col108. Peptide Col108 was made by bacterial expression using a synthetic gene; its triple helix domain consists of three pseudo‐identical units of amino acid sequence arranged in tandem. It was postulated that the 35 nm d‐period of Col108 mini‐fibrils originates from the periodicity of the Col108 primary structure. A mutual staggering of one sequence unit of the associating Col108 triple helices can maximize the inter‐helical interactions and produce the observed 35 nm d‐period. Based on this unit‐staggered model, a triple helix consisting of only two sequence units is expected to have the potential to form the same d‐periodic mini‐fibrils. Indeed, when such a peptide, peptide 2U108, was made it was found to self‐assemble into mini‐fibrils having the same d‐period of 35 nm. In contrast, no d‐periodic mini‐fibrils were observed for peptide 1U108, which does not have long‐range repeating sequences in its primary structure. The findings of the periodic mini‐fibrils of Col108 and 2U108 suggest a way forward to create collagen‐mimetic fibrils for biomedical and industrial applications.  相似文献   

18.
Coiled‐coils are found in proteins throughout all three kingdoms of life. Coiled‐coil domains of some proteins are almost invariant in sequence and length, betraying a structural and functional role for amino acids along the entire length of the coiled‐coil. Other coiled‐coils are divergent in sequence, but conserved in length, thereby functioning as molecular spacers. In this capacity, coiled‐coil proteins influence the architecture of organelles such as centrioles and the Golgi, as well as permit the tethering of transport vesicles. Specialized coiled‐coils, such as those found in motor proteins, are capable of propagating conformational changes along their length that regulate cargo binding and motor processivity. Coiled‐coil domains have also been identified in enzymes, where they function as molecular rulers, positioning catalytic activities at fixed distances. Finally, while coiled‐coils have been extensively discussed for their potential to nucleate and scaffold large macromolecular complexes, structural evidence to substantiate this claim is relatively scarce.  相似文献   

19.
The centriole is a conserved microtubule‐based organelle essential for both centrosome formation and cilium biogenesis. Five conserved proteins for centriole duplication have been identified. Two of them, SAS‐5 and SAS‐6, physically interact with each other and are codependent for their targeting to procentrioles. However, it remains unclear how these two proteins interact at the molecular level. Here, we demonstrate that the short SAS‐5 C‐terminal domain (residues 390–404) specifically binds to a narrow central region (residues 275–288) of the SAS‐6 coiled coil. This was supported by the crystal structure of the SAS‐6 coiled‐coil domain (CCD), which, together with mutagenesis studies, indicated that the association is mediated by synergistic hydrophobic and electrostatic interactions. The crystal structure also shows a periodic charge pattern along the SAS‐6 CCD, which gives rise to an anti‐parallel tetramer. Overall, our findings establish the molecular basis of the specific interaction between SAS‐5 and SAS‐6, and suggest that both proteins individually adopt an oligomeric conformation that is disrupted upon the formation of the hetero‐complex to facilitate the correct assembly of the nine‐fold symmetric centriole.  相似文献   

20.
FtsZ, the essential regulator of bacterial cell division, is a dynamic cytoskeletal protein that forms helices that condense into the Z‐ring prior to division. Two small coiled‐coil proteins, ZapA and ZapB, are both recruited early to the Z‐ring. We show here that ZapB is recruited to the Z‐ring by ZapA. A direct interaction between ZapA and ZapB is supported by bacterial two‐hybrid and in vitro interaction assays. Using high‐resolution 3‐D reconstruction microscopy, we find that, surprisingly, ZapB is located inside the Z‐ring in virtually all cells investigated. We propose a molecular model in which ZapA increases lateral interactions between FtsZ proto‐filaments and ZapB mediates further stabilization of this interaction by cross‐linking ZapA molecules bound to adjacent FtsZ proto‐filaments. Gene deletion and complementation assays show that ZapB can mitigate cell division and Z‐ring assembly defects even in the absence of ZapA, raising the possibility that ZapB stimulates Z‐ring assembly by two different mechanisms.  相似文献   

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