Linker Residues Research Articles

Optimal Attachment Position and Linker Length Promote Native‐like Character of Cavitand‐Based Template‐Assembled Synthetic Proteins (TASPs)

We have designed, synthesised and characterised a series of template-assembled de novo four-helix bundles, each differing in the linker length between the template and the peptides. The helix is based on an earlier peptide sequence: EELLKKLEELLKKLG (first-generation sequence), which was designed to link the hydrophilic/hydrophobic interface of the helices. Increasing or decreasing the linker length by one glycine residue had a significant effect on the structure and properties of the template-assembled synthetic proteins (TASPs). Here, the effect of the linker length is further probed by linking the peptides closer to the hydrophobic face by using the second-generation sequence, AEELLKKLEELLKKG, in an effort to improve the packing between the helices and to better understand the helical bundles. The peptides were synthesised with 0-4 Gly linker residues and linked onto a cavitand template. The proteins were found to be alpha-helical, stable to guanidine hydrochloride (GuHCl) and to unfold cooperatively. However, their stabilities toward GuHCl, propensity to self-aggregate and structural specificity differed. The two-glycine variant of the second-generation series demonstrated the highest stability and most native-like character of all the mononeric TASPs in both the first- and second-generation series. The structural specificity of this two glycine variant is comparable to that of other known native-like de novo proteins. Molecular dynamics simulations showed that the two-glycine variant contains helices that are tilted with respect to the cavitand template and may account for its unique properties.

Increase in bioluminescence intensity of firefly luciferase using genetic modification

Firefly luciferase is widely used for enzymatic measurement of ATP, and its gene is used as a reporter for gene expression experiments. From our mutant library, we selected novel mutations in Photinus pyralis luciferase with higher luminescence intensity. These included mutations at Ile423, Asp436, and Leu530. Luciferase is structurally composed of a large N-terminal active site domain (residues 1–436), a flexible linker (residues 436–440) peptide, and a small C-terminal domain (residues 440–550) facing the N domain. Thus, the mutations are located at the junction of the N-terminal domain and the flexible linker, in the flexible linker peptide, and in the tip of the C-terminal domain, respectively. Substitution of Asp436 with a nonbulky amino acid such as Gly remarkably increased the substrate affinity for ATP and d-luciferin. Substitution of Ile423 with a hydrophobic amino acid such as Leu and that of Leu530 with a positively charged amino acid such as Arg increased the substrate affinity and the turnover rate. Combining these mutations, we obtained luciferases that generate more than 10-fold higher luminescence intensity than the wild-type enzyme.

Computer-Assisted Protein Domain Boundary Prediction Using the Dom-Pred Server

Domain prediction from sequence is a particularly challenging task, and currently, a large variety of different methodologies are employed to tackle the task. Here we try to classify these diverse approaches into a number of broad categories. Completely automatic domain prediction from sequence alone is currently fraught with problems, but this should not be so surprising since human experts currently have significant disagreement on domain assignment even when given the structures. It can be argued that we should only test the domain prediction methods on benchmark data that human experts agree upon and this is the approach we take in this paper. Even for the data sets on which human experts agree, automatic structure-based domain assignment still cannot always agree, and so again it is still unlikely that domain prediction methods will reliably obtain correct results completely automatically. We make the argument that computer-assisted domain prediction is a more achievable goal. With this aim in mind, we present the DomPred server. This server provides the user with the results from two completely different categories of method (DPS and DomSSEA). In this paper, each method is individually benchmarked against one of the latest domain prediction benchmarks to provide information about their respective reliabilities. A variety of different benchmark scores are employed since the accuracy of a domain prediction method depends critically on what types of results one wishes to obtain (single/multi-domain classification, domain number, residue linker positions, etc.). Also both of these methods, implemented within the DomPred server, can suggest alternative domain predictions, allowing the user to make the final decision based on these results and applying their own background knowledge to the problem. The DomPred server is available from the URL:http://bioinf.cs.ucl.ac.uk/software.html.

Activity of a Two-Domain Antifreeze Protein Is Not Dependent on Linker Sequence

The reported NMR structure of RD3, a naturally occurring two-domain antifreeze protein, suggests that the two nearly identical domains are oriented to allow simultaneous binding of their active regions to the ice surface. It is implied that the nine residues linking the two domains play a role in this alignment, but this has not been established. We have designed and expressed a modified form of RD3 that replaces the nine-residue linker with a generic sequence of one serine and eight glycine residues to test the importance of the linker amino acid sequence. The modified linker is shown to have significantly different characteristics compared to the original linker. Heteronuclear nuclear Overhauser effect experiments show that the new linker residues have more mobility than the linker residues in the native protein. Further, NMR data show that the folding of the C-terminal domain is somewhat perturbed by the altered linker. Finally, distributions of residual dipolar couplings indicate that the two domains tumble and move independently of each other. Nevertheless, the thermal hysteresis activity of the modified protein is indistinguishable from that of native RD3, proving that increased activity of the two-domain antifreeze protein is not dependent on structure of the linker.

New insights into the role of the thumb-like loop in GH-11 xylanases

GH-11 xylanases are highly specific and possess a thumb-shaped loop, a unique structure among enzymes with a jelly-roll scaffold. To investigate this structure, in vitro mutagenesis was performed on a GH-11 xylanase (Tx-Xyl) from Thermobacillus xylanilyticus. Targets were the conserved amino acids Pro(114)-Ser(115)-Ile(116) that are located at the thumb's tip and Thr(121) and Tyr(111), linker residues that connect the thumb to the main enzyme scaffold. Site-saturation mutagenesis provided an active variant that possesses a new triplet (Pro(114)-Gly(115)-Cys(116)), not found in naturally occurring GH-11 xylanases. The k(cat) value for xylan hydrolysis catalysed by this mutant was increased by 20%. Re-positioning of the thumb through the deletion of the linker residues produced different effects. As predicted by in silico analyses, deletion of Thr(121) had drastic consequences on activity, whereas deletion of Tyr(111) only affected (4-fold decrease) k(cat). Finally, deletion mutagenesis was used to create a thumbless variant that was almost catalytically inactive. Fluorescence titration with xylotetraose and xylopentaose revealed that this thumb-deleted xylanase retained the ability to bind substrates. This binding was comparable to that of the wild-type enzyme. Additionally, unlike wild-type Tx-Xyl, the thumb-deleted xylanase efficiently bound cellotetraose, although no cellulose hydrolysing activity was detected. Overall, these data show that the thumb is a key determinant for substrate selection and support previous data that suggest that it plays a role in the catalytic process.

“Similarity Trap” in Protein-Protein Interactions Could Be Carcinogenic: Simulations of p53 Core Domain Complexed with 53BP1 and BRCA1 BRCT Domains

Similar binding sites often imply similar protein-protein interactions and similar functions; however, similar binding sites may also constitute traps for nonfunctional associations. How are similar sites distinguished to prevent misassociations? BRCT domains from breast cancer-susceptibility gene product BRCA1 and protein 53BP1 have similar structures yet different binding behaviors with p53 core domain. 53BP1-BRCT domain forms a stable complex with p53. In contrast, BRCA1-p53 interaction is weak or other mechanisms operate. To delineate the difference, we designed 13 BRCA1-BRCT mutants and computationally investigated the structural and stability changes compared to the experimental p53-53BP1 structure. Interestingly, of the 13, the 2 mutations that are cancerous and involve nonconserved residues are those that enforced p53 core domain binding with BRCA1-BRCT in a way similar to p53-53BP1 binding. Hence, falling into the "similarity trap" may disrupt normal BRCA1 and p53 functions. Our results illustrate how this trap is avoided in the native state.

The Schizosaccharomyces pombe EB1 Homolog Mal3p Binds and Stabilizes the Microtubule Lattice Seam

End binding 1 (EB1) proteins are highly conserved regulators of microtubule dynamics. Using electron microscopy (EM) and high-resolution surface shadowing we have studied the microtubule-binding properties of the fission yeast EB1 homolog Mal3p. This allowed for a direct visualization of Mal3p bound on the surface of microtubules. Mal3p particles usually formed a single line on each microtubule along just one of the multiple grooves that are formed by adjacent protofilaments. We provide structural data showing that the alignment of Mal3p molecules coincides with the microtubule lattice seam as well as data suggesting that Mal3p not only binds but also stabilizes this seam. Accordingly, Mal3p stabilizes microtubules through a specific interaction with what is potentially the weakest part of the microtubule in a way not previously demonstrated. Our findings further suggest that microtubules exhibit two distinct reaction platforms on their surface that can independently interact with target structures such as microtubule-associated proteins, motors, kinetochores, or membranes.

Linkage between ‘disruption of inactivation’ and ‘reduction of K+ selectivity’ among hERG mutants in the S5‐P linker region

Linkage between ‘disruption of inactivation’ and ‘reduction of K⁺ selectivity’ among hERG mutants in the S5‐P linker region

4-Aminopyridine Prevents the Conformational Changes Associated with P/C-Type Inactivation in Shaker Channels

The effect of 4-aminopyridine (4-AP) on Kv channel activation has been extensively investigated, but its interaction with inactivation is less well understood. Voltage-clamp fluorimetry was used to directly monitor the action of 4-AP on conformational changes associated with slow inactivation of Shaker channels. Tetramethylrhodamine-5-maleimide was used to fluorescently label substituted cysteine residues in the S3-S4 linker (A359C) and pore (S424C). Activation- and inactivation-induced changes in fluorophore microenvironment produced fast and slow phases of fluorescence that were modified by 4-AP. In Shaker A359C, 4-AP block reduced the slow-phase contribution from 61 +/- 3 to 28 +/- 5%, suggesting that binding inhibits the conformational changes associated with slow inactivation and increased the fast phase that reports channel activation from 39 +/- 3 to 72 +/- 5%. In addition, 4-AP enhanced both fast and slow phases of fluorescence return upon repolarization (tau reduced from 87 +/- 15 to 40 +/- 1 ms and from 739 +/- 83 to 291 +/- 21 ms, respectively), suggesting that deactivation and recovery from inactivation were enhanced. In addition, the effect of 4-AP on the slow phase of fluorescence was dramatically reduced in channels with either reduced (T449V) or permanent P-type (W434F) inactivation. Interestingly, the slow phase of fluorescence return of W434F channels was enhanced by 4-AP, suggesting that 4-AP prevents the transition to C-type inactivation in these channels. These data directly demonstrate that 4-AP prevents slow inactivation of Kv channels and that 4-AP can bind to P-type-inactivated channels and selectively inhibit the onset of C-type inactivation.

Binding of human centrin 2 to the centrosomal protein hSfi1

hSfi1, a human centrosomal protein with homologs in other eukaryotic organisms, includes 23 repeats, each of 23 amino acids, separated by 10 residue linkers. The main molecular partner in the centrosome is a small, calcium-binding EF-hand protein, the human centrin 2. Using isothermal titration calorimetry experiments, we characterized the centrin-binding capacity of three isolated hSfi1 repeats, two exhibiting the general consensus motif and the third being the unique Pro-containing human repeat. The two standard peptides bind human centrin 2 and its isolated C-terminal domain with high affinity (approximately 10(7) M(-1)) by an enthalpy-driven mechanism, with a moderate Ca2+ dependence. The Pro-containing repeat shows a binding affinity that is two orders of magnitude lower. The target binding site is localized within the C-terminal domain of human centrin 2. Fluorescence titration and NMR spectroscopy show that the well-conserved Trp residue situated in the C-terminus of each repeat is deeply embedded in a protein hydrophobic cavity, indicating that the peptide direction is reversed relative to previously studied centrin targets. The present results suggest that almost all of the repeats of the Sfi1 protein may independently bind centrin molecules. On the basis of this hypothesis and previous studies on centrin self-assembly, we propose a working model for the role of centrin-Sfi1 interactions in the dynamic structure of centrosome-associated contractile fibers.

The Ig Doublet Z1Z2: A Model System for the Hybrid Analysis of Conformational Dynamics in Ig Tandems from Titin

Titin is a gigantic elastic filament that determines sarcomere ultrastructure and stretch response in vertebrate muscle. It folds into numerous Ig and FnIII domains connected in tandem. Data on interdomain arrangements and dynamics are essential for understanding the function of this filament. Here, we report a mechanistic analysis of the conformational dynamics of two Ig domains from the N terminus of titin, Z1Z2, by using X-ray crystallography, SAXS, NMR relaxation data, and residual dipolar couplings in combination. Z1Z2 preferentially adopts semiextended conformations in solution, with close-hinge arrangements representing low-probability states. Although interdomain contacts are not observed, the linker appears to acquire moderate rigidity via small, local hydrophobic interactions. Thus, Z1Z2 constitutes an adaptable modular system with restricted dynamics. We speculate that its preexistent conformation contributes to the selective recruitment of the binding partner telethonin onto the repetitive surface of the filament. The structural interconversion of four Z1Z2 conformers is analyzed.

Structural Variations in the Catalytic and Ubiquitin-associated Domains of Microtubule-associated Protein/Microtubule Affinity Regulating Kinase (MARK) 1 and MARK2

The microtubule-associated protein (MAP)/microtubule affinity regulating kinase (MARK)/Par-1 phosphorylates microtubule-associated proteins tau, MAP2, and MAP4 and is involved in the regulation of microtubule-based transport. Par-1, a homologue of MARK in Drosophila and Caenorhabditis elegans, is essential for the development of embryonic polarity. Four isoforms of MARK are found in humans. Recently, we reported the crystal structure of the catalytic and ubiquitin-associated domains of MARK2, an isoform enriched in brain (Panneerselvam, S., Marx, A., Mandelkow, E.-M., and Mandelkow, E. (2006) Structure 14, 173-183). It showed that the ubiquitin-associated domain (UBA) domain has an unusual fold and binds to the N-terminal lobe of the catalytic domain. This is at variance with a previous low resolution structure derived from small angle solution scattering (Jaleel, M., Villa, F., Deak, M., Toth, R., Prescott, A. R., Van Aalten, D. M., and Alessi, D. R. (2006) Biochem. J. 394, 545-555), which predicts binding of the UBA domain to the larger, C-terminal lobe. Here we report the crystal structure of the catalytic and UBA domain of another isoform, MARK1. Although the crystal packing of the two isoforms are unrelated, the overall conformations of the molecules are similar. Notably, the UBA domain has the same unusual conformation as in MARK2, and it binds at the same site. Remarkable differences occur in the catalytic domain at helix C, the catalytic loop, and the activation segment.

Structure of the Subunit Binding Domain and Dynamics of the Di-domain Region from the Core of Human Branched Chain α-Ketoacid Dehydrogenase Complex

The homo-24-meric dihydrolipoyl transacylase (E2) scaffold of the human branched-chain alpha-ketoacid dehydrogenase complex (BCKDC) contains the lipoyl-bearing domain (hbLBD), the subunit-binding domain (hbSBD) and the inner core domain that are linked to carry out E2 functions in substrate channeling and recognition. In this study, we employed NMR techniques to determine the structure of hbSBD and dynamics of several truncated constructs from the E2 component of the human BCKDC, including hbLBD (residues 1-84), hbSBD (residues 111-149), and a di-domain (hbDD) (residues 1-166) comprising hbLBD, hbSBD and the interdomain linker. The solution structure of hbSBD consists of two nearly parallel helices separated by a long loop, similar to the structures of the SBD isolated from other species, but it lacks the short 3(10) helix. The NMR results show that the structures of hbLBD and hbSBD in isolated forms are not altered by the presence of the interdomain linker in hbDD. The linker region is not entirely exposed to solvent, where amide resonances associated with approximately 50% of the residues are observable. However, the tethering of these two domains in hbDD significantly retards the overall rotational correlation times of hbLBD and hbSBD, changing from 5.54 ns and 5.73 ns in isolated forms to 8.37 ns and 8.85 ns in the linked hbDD, respectively. We conclude that the presence of the interdomain linker restricts the motional freedom of the hbSBD more significantly than hbLBD, and that the linker region likely exists as a soft rod rather than a flexible string in solution.

Structural Basis for Specificity in the Poxvirus Topoisomerase

Although smallpox has been eradicated from the human population, it is presently feared as a possible agent of bioterrorism. The smallpox virus codes for its own topoisomerase enzyme that differs from its cellular counterpart by requiring a specific DNA sequence for activation of catalysis. Here we present crystal structures of the smallpox virus topoisomerase enzyme bound both covalently and noncovalently to a specific DNA sequence. These structures reveal the basis for site-specific DNA recognition, and they explain how catalysis is likely activated by formation of a specific enzyme-DNA interface. Unexpectedly, the poxvirus enzyme uses a major groove binding alpha helix that is not present in the human enzyme to recognize part of the core recognition sequence and activate the enzyme for catalysis. The topoisomerase-DNA complex structures also provide a three-dimensional framework that may facilitate the rational design of therapeutic agents to treat poxvirus infections.

Disease-associated Sequence Variations Congregate in a Polyanion Recognition Patch on Human Factor H Revealed in Three-dimensional Structure

Mutations and polymorphisms in the regulator of complement activation, factor H, have been linked to atypical hemolytic uremic syndrome (aHUS), membranoproliferative glomerulonephritis, and age-related macular degeneration. Many aHUS patients carry mutations in the two C-terminal modules of factor H, which normally confer upon this abundant 155-kDa plasma glycoprotein its ability to selectively bind self-surfaces and prevent them from inappropriately triggering the complement cascade via the alternative pathway. In the current study, the three-dimensional solution structure of the C-terminal module pair of factor H has been determined. A binding site for a fully sulfated heparin-derived tetrasaccharide has been delineated using chemical shift mapping and the C3d/C3b-binding site inferred from sequence comparisons and computational docking. The resultant information allows assessment of the likely consequences of aHUS-associated amino acid substitutions in this critical region of factor H. It is striking that, excepting those likely to perturb the three-dimensional structure, aHUS-associated missense mutations congregate in the polyanion-binding site delineated in this study, thus potentially disrupting a vital mechanism for control of complement on self-surfaces in the microvasculature of the kidney. It is intriguing that a single nucleotide polymorphism predisposing to age-related macular degeneration occupies another region of factor H that harbors a polyanion-binding site.

The S4-S5 Linker Directly Couples Voltage Sensor Movement to the Activation Gate in the Human Ether-á-go-go-related Gene (hERG) K+ Channel

A key unresolved question regarding the basic function of voltage-gated ion channels is how movement of the voltage sensor is coupled to channel opening. We previously proposed that the S4-S5 linker couples voltage sensor movement to the S6 domain in the human ether-a'-go-go-related gene (hERG) K+ channel. The recently solved crystal structure of the voltage-gated Kv1.2 channel reveals that the S4-S5 linker is the structural link between the voltage sensing and pore domains. In this study, we used chimeras constructed from hERG and ether-a'-go-go (EAG) channels to identify interactions between residues in the S4-S5 linker and S6 domain that were critical for stabilizing the channel in a closed state. To verify the spatial proximity of these regions, we introduced cysteines in the S4-S5 linker and at the C-terminal end of the S6 domain and then probed for the effect of oxidation. The D540C-L666C channel current decreased in an oxidizing environment in a state-dependent manner consistent with formation of a disulfide bond that locked the channel in a closed state. Disulfide bond formation also restricted movement of the voltage sensor, as measured by gating currents. Taken together, these data confirm that the S4-S5 linker directly couples voltage sensor movement to the activation gate. Moreover, rather than functioning simply as a mechanical lever, these findings imply that specific interactions between the S4-S5 linker and the activation gate stabilize the closed channel conformation.

Structural and functional integrity of the coxsackievirus B3 oriR: spacing between coaxial RNA helices

The enterovirus oriR is composed of two helices, X and Y, anchored by a kissing (K) interaction. For proper oriR function, certain areas of these helices should be specifically oriented towards each other. It was hypothesized that the single-stranded nucleotides bridging the coaxial helices (Y-X and K-Y linkers) are important to determine this orientation. Spatial changes were introduced by altering the linker length between the helices of the coxsackievirus B3 oriR. Changing the linker lengths resulted in defective RNA replication, probably because of an altered oriR geometry. The identity of the linker residues also played a role, possibly because of sequence-specific ligand recognition. Although each point mutation altering the primary sequence of the Y-X spacer resulted in defective growth at 36 degrees C, the mutations had a wild-type phenotype at 39 degrees C, indicating a cold-sensitive phenotype. The results show that the intrinsic connection between oriR structure and function is fine-tuned by the spacing between the coaxial RNA helices.

Human C4b-binding Protein, Structural Basis for Interaction with Streptococcal M Protein, a Major Bacterial Virulence Factor

Human C4b-binding protein (C4BP) protects host tissue, and those pathogens able to hijack this plasma glycoprotein, from complement-mediated destruction. We now show that the first two complement control protein (CCP) modules of the C4BP alpha-chain, plus the four residues connecting them, are necessary and sufficient for binding a bacterial virulence factor, the Streptococcus pyogenes M4 (Arp4) protein. Structure determination by NMR reveals two tightly coupled CCP modules in an elongated arrangement within this region of C4BP. Chemical shift perturbation studies demonstrate that the N-terminal, hypervariable region of M4 binds to a site including strand 1 of CCP module 2. This interaction is accompanied by an intermodular reorientation within C4BP. We thus provide a detailed picture of an interaction whereby a pathogen evades complement.

Structure of the Mosquitocidal Toxin from Bacillus sphaericus

The catalytic domain of a mosquitocidal toxin prolonged by a C-terminal 44 residue linker connecting to four ricin B-like domains was crystallized. Three crystal structures were established at resolutions between 2.5A and 3.0A using multi-wavelength and single-wavelength anomalous X-ray diffraction as well as molecular replacement phasing techniques. The chainfold of the toxin fragment corresponds to those of ADP-ribosylating enzymes. At pH 4.3 the fragment is associated in a C(7)-symmetric heptamer in agreement with an aggregate of similar size observed by size-exclusion chromatography. In two distinct crystal forms, the heptamers formed nearly spherical, D(7)-symmetric tetradecamers. Another crystal form obtained at pH 6.3 contained a recurring C(2)-symmetric tetramer, which, however, was not stable in solution. On the basis of the common chainfold and NAD(+)-binding site of all ADP-ribosyl transferases, the NAD(+)-binding site of the toxin was assigned at a high confidence level. In all three crystal forms the NAD(+) site was occupied by part of the 44 residue linker, explaining the known inhibitory effect of this polypeptide region. The structure showed that the cleavage site for toxin activation is in a highly mobile loop that is exposed in the monomer. Since it contains the inhibitory linker as a crucial part of the association contact, the observed heptamer is inactive. Moreover, the heptamer cannot be activated by proteolysis because the activation loop is at the ring center and not accessible for proteases. Therefore the heptamer, or possibly the tetradecamer, seems to represent an inactive storage form of the toxin.

NMR-Derived Dynamic Aspects of N-Type Inactivation of a Kv Channel Suggest a Transient Interaction with the T1 Domain

Some eukaryotic voltage-gated K+ (Kv) channels contain an N-terminal inactivation peptide (IP), which mediates a fast inactivation process that limits channel function during membrane depolarization and thus shapes the action potential. We obtained sequence-specific nuclear magnetic resonance (NMR) assignments for the polypeptide backbone of a tetrameric N-terminal fragment (amino acids 1-181) of the Aplysia Kv1.1 channel. Additional NMR measurements show that the tetramerization domain 1 (T1) has the same globular structure in solution as previously determined by crystallography and that the IP (residues 1-20) and the linker (residues 21-65) are in a flexibly disordered, predominantly extended conformation. A potential contact site between the T1 domain and the flexible tail (residues 1-65) has been identified on the basis of chemical-shift changes of individual T1 domain amino acids, which map to the T1 surface near the interface between adjacent subunits. Paramagnetic perturbation experiments further indicate that, in the ensemble of solution conformers, there is at least a small population of species with the IP localized in close proximity to the proposed interacting residues of the T1 tetramer. Electrophysiological measurements show that all three mutations in this pocket that we tested slow the rate of inactivation and speed up recovery, as predicted from the preinactivation site model. These results suggest that specific, short-lived transient interactions between the T1 domain and the IP or the linker segment may play a role in defining the regulatory kinetics of fast channel inactivation.