Stabilization of short collagen-like triple helices by protein engineering

Recombinant expression of collagens and fragments of collagens is often difficult, as their biosynthesis requires specific post-translational enzymes, in particular prolyl 4-hydroxylase. Although the use of hydroxyproline-deficient variants offers one possibility to overcome this difficulty, these proteins usually differ markedly in stability when compared with the hydroxyproline-containing analogs. Here, we report a method to stabilize collagen-like peptides by fusing them to the N terminus of the bacteriophage T4 fibritin foldon domain. The isolated foldon domain and the chimeric protein (GlyProPro)(10)foldon were expressed in a soluble form in Escherichia coli. The recombinant proteins and the synthetic (ProProGly)(10) peptide were characterized by circular dichroism (CD) spectroscopy, differential scanning calorimetry, and analytical ultracentrifugation. We show that the foldon domain, which comprises only 27 amino acid residues, forms an obligatory trimer with a high degree of thermal stability. The CD thermal unfolding profiles recorded from foldon are monophasic and completely reversible upon cooling. Similar Van't Hoff and calorimertic enthalpy values of trimer formation indicated a cooperative all-or-none transition. As reported previously, (ProProGly)(10) peptides form collagen triple helices of only moderate stability. When fused to the foldon domain, however, triple helix formation of (GlyProPro)(10) is concentration independent, and the midpoint temperature of the triple helix unfolding is significantly increased. The stabilizing function of the trimeric foldon domain is explained by the close vicinity of its N termini, which induce a high local concentration in the range of 1 M for the C termini of the collagen-like-peptide. Collagen-foldon fusion proteins should be potentially useful to study receptor-collagen interactions.     

Sequence-dependent stability of intramolecular DNA triple helices

A set of 21 oligodeoxynucleotides were designed to fold into intramolecular triple helices of the pyrimidine motif under appropriate conditions. UV melting experiments on the triplexes which only differ in the number and distribution of third strand cytosines reveal the influence of sequence and pH on triplex stability and can be summarized as follows: (1) increasing the cytosine content in the third strand results in a higher thermal stability of the triplex at acidic pH but lowers the triplex to duplex melting temperature at neutral pH; (2) cytosines at terminal positions destabilize the triple helical structure as compared to non-terminal positions; (3) contiguous cytosines lead to a pH dependent destabilization of the triplex, the destabilizing effect being more pronounced at higher pH. Analysis of these effects in terms of the various interactions within a triple helical complex indicate that the sequence-dependent stabilities are largely determined by the extent of protonation for individual third strand cytosines.     

Stabilization of conformationally dynamic helices by covalently attached acyl chains

Acylation of proteins is known to mediate membrane attachment and to influence subcellular sorting. Here, we report that acylation can stabilize secondary structure. Circular dichroism spectroscopy showed that N‐terminal attachment of acyl chains decreases the ability of an intrinsically flexible hydrophobic model peptide to refold from an α‐helical state to β‐sheet in response to changing solvent conditions. Acylation also stabilized the membrane‐embedded α‐helix. This increase of global helix stability did not result from decreased local conformational dynamics of the helix backbone as assessed by deuterium/hydrogen‐exchange experiments. We concluded that acylation can stabilize the structure of intrinsically dynamic helices and may thus prevent misfolding.     

Structural heterogeneity in intramolecular DNA triple helices

Oligodeoxynucleotides designed to form intramolecular triple helices are widely used as model systems in thermodynamic and structural studies. We now report results from UV, Raman and NMR experiments demonstrating that the strand polarity, which also determines the orientation of the connecting loops, has a considerable impact on the formation and stability of pyr x pur x pyr triple helices. There are two types of monomolecular triplexes that can be defined by the location of their purine tract at either the 5'- or 3'-end of the sequence. We have examined four pairs of oligonucleotides with the same base composition but with reversed polarity that can fold into intramolecular triple helices with seven base triplets and two T4 loops under appropriate conditions. UV spectroscopic monitoring of thermal denaturation indicates a consistently higher thermal stability for the 5'-sequences at pH 5.0 in the absence of Mg2+ ions. Raman spectra provide evidence for the formation of triple helices at pH 5 for oligomers with purine tracts located at either the 5'- or 3'-end of the sequence. However, NMR measurements reveal considerable differences in the secondary structures formed by the two types of oligonucleotides. Thus, at acidic pH significant structural heterogeneity is observed for the 3'-sequences. Employing selectively 15N-labeled oligomers, NMR experiments indicate a folding pattern for the competing structures that at least partially changes both Hoogsteen and Watson-Crick base-base interactions.     

Stabilization of discordant helices in amyloid fibril-forming proteins

Several proteins and peptides that can convert from alpha-helical to beta-sheet conformation and form amyloid fibrils, including the amyloid beta-peptide (Abeta) and the prion protein, contain a discordant alpha-helix that is composed of residues that strongly favor beta-strand formation. In their native states, 37 of 38 discordant helices are now found to interact with other protein segments or with lipid membranes, but Abeta apparently lacks such interactions. The helical propensity of the Abeta discordant region (K16LVFFAED23) is increased by introducing V18A/F19A/F20A replacements, and this is associated with reduced fibril formation. Addition of the tripeptide KAD or phospho-L-serine likewise increases the alpha-helical content of Abeta(12-28) and reduces aggregation and fibril formation of Abeta(1-40), Abeta(12-28), Abeta(12-24), and Abeta(14-23). In contrast, tripeptides with all-neutral, all-acidic or all-basic side chains, as well as phosphoethanolamine, phosphocholine, and phosphoglycerol have no significant effects on Abeta secondary structure or fibril formation. These data suggest that in free Abeta, the discordant alpha-helix lacks stabilizing interactions (likely as a consequence of proteolytic removal from a membrane-associated precursor protein) and that stabilization of this helix can reduce fibril formation.     

Stabilization of DNA triple helices by a series of mono- and disubstituted amidoanthraquinones.

We have used quantitative DNase I footprinting to measure the relative affinities of four disubstituted and two monosubstituted amidoanthraquinone compounds for intermolecular DNA triplexes, and have examined how the position of the attached base-functionalized substituents affects their ability to stabilize DNA triplexes. All four isomeric disubstituted derivatives examined stabilize DNA triplexes at micromolar or lower concentrations. Of the compounds studied the 2,7-disubstituted amidoanthraquinone displayed the greatest triplex affinity. The order of triplex affinity for the other disubstituted ligands decreases in the order 2,7 > 1,8 = 1,5 > 2,6, with the equivalent monosubstituted compounds being at least an order of magnitude less efficient. The 1,5-disubstituted derivative also shows some interaction with duplex DNA. These results have been confirmed by molecular modelling studies, which provide a rational basis for the structure-activity relationships. These suggest that, although all of the compounds bind through an intercalative mode, the 2,6, 2,7 and 1,5 disubstituted isomers bind with their two side groups occupying adjacent triplex grooves, in contrast with the 1,8 isomer which is positioned with both side groups in the same triplex groove.     

Stabilization of DNA double and triple helices by conjugation of minor groove binders to oligonucleotides

New conjugates containing two parallel or antiparallel carboxamide minor groove binders (MGB) attached to the same terminal phosphate of one oligonucleotide strand were synthesized. The conjugates interact with their target DNA stronger than the individual components. Effect of conjugated MGB on DNA duplex and triplex stability and their sequence specificity was demonstrated on the short oligonucleotide duplexes and on the triplex formed by model 16-mer oligonucleotide with HIV polypurine tract.     

Long membrane helices and short loops predicted less accurately

Low-resolution experiments suggest that most membrane helices span over 17-25 residues and that most loops between two helices are longer than 15 residues. Both constraints have been used explicitly in the development of prediction methods. Here, we compared the largest possible sequence-unique data sets from high- and low-resolution experiments. For the high-resolution data, we found that only half of the helices fall into the expected length interval and that half of the loops were shorter than 10 residues. We compared the accuracy of detecting short loops and long helices for 28 advanced and simple prediction methods: All methods predicted short loops less accurately than longer ones. In particular, loops shorter than 7 residues appeared to be very difficult to detect by current methods. Similarly, all methods tended to be more accurate for longer than for shorter helices. However, helices with more than 32 residues were predicted less accurately than all other helices. Our findings may suggest particular strategies for improving predictions of membrane helices.     

Stabilization of the N-terminal beta-hairpin of ubiquitin by a terminal hydrophobic cluster

Study of model beta-hairpin peptides allows for better understanding of the factors involved in the formation of beta-sheet secondary structure in proteins. It is known that turn sequence, sidechain-sidechain interactions, interstrand hydrogen bonding, and beta-sheet propensity of residues are all important for beta-hairpin stability in aqueous solution. However, interactions of the sidechains of the terminal residues of hairpins are thought to contribute little to overall hairpin stability since these residues are typically frayed. Here, the authors report a stabilizing hydrophobic cluster of residues at the termini of the naturally occurring excised N-terminal beta-hairpin of Ubiquitin that folds autonomously in aqueous solution. Our data show that deletion of Met1 and Val17 from this hairpin destabilized the folded state in both aqueous solution and in aqueous-methanol solutions. These results suggest that interactions of terminal residues which are usually frayed can nonetheless contribute significantly to overall stability of beta-hairpin.     

Sarcomeric pattern formation by actin cluster coalescence

Contractile function of striated muscle cells depends crucially on the almost crystalline order of actin and myosin filaments in myofibrils, but the physical mechanisms that lead to myofibril assembly remains ill-defined. Passive diffusive sorting of actin filaments into sarcomeric order is kinetically impossible, suggesting a pivotal role of active processes in sarcomeric pattern formation. Using a one-dimensional computational model of an initially unstriated actin bundle, we show that actin filament treadmilling in the presence of processive plus-end crosslinking provides a simple and robust mechanism for the polarity sorting of actin filaments as well as for the correct localization of myosin filaments. We propose that the coalescence of crosslinked actin clusters could be key for sarcomeric pattern formation. In our simulations, sarcomere spacing is set by filament length prompting tight length control already at early stages of pattern formation. The proposed mechanism could be generic and apply both to premyofibrils and nascent myofibrils in developing muscle cells as well as possibly to striated stress-fibers in non-muscle cells.     

Spectroscopic studies of chimeric DNA-RNA and RNA 29-base intramolecular triple helices.

Fourier transform infrared (FTIR), UV absorption and exchangeable proton NMR spectroscopies have been used to study the formation and stability of two intramolecular pH-dependent triple helices composed by a chimeric 29mer DNA-RNA (DNA double strand and RNA third strand) or by the analogous 29mer RNA. In both cases decrease of pH induces formation of a triple helical structure containing either rU*dA.dT and rC+*dG.dC or rU*rA.rU and rC+*rG.rC triplets. FTIR spectroscopy shows that exclusively N-type sugars are present in the triple helix formed by the 29mer RNA while both N- and S-type sugars are detected in the case of the chimeric 29mer DNA-RNA triple helix. Triple helix formation with the third strand RNA and the duplex as DNA appears to be associated with the conversion of the duplex part from a B-form secondary structure to one which contains partly A-form sugars. Thermal denaturation experiments followed by UV spectroscopy show that a major stabilization occurs upon formation of the triple helices. Monophasic melting curves indicate a simultaneous disruption of the Hoogsteen and Watson-Crick hydrogen bonds in the intramolecular triplexes when the temperature is increased. This is in agreement with imino proton NMR spectra recorded as a function of temperature. Comparison with experiments concerning intermolecular triplexes of identical base and sugar composition shows the important role played by the two tetrameric loops in the stabilization of the intramolecular triple helices studied.     

Activation of CCR5 by chemokines involves an aromatic cluster between transmembrane helices 2 and 3

CCR5 is a G protein-coupled receptor responding to four natural agonists, the chemokines RANTES (regulated on activation normal T cell expressed and secreted), macrophage inflammatory protein (MIP)-1 alpha, MIP-1 beta, and monocyte chemotactic protein (MCP)-2, and is the main co-receptor for the macrophage-tropic human immunodeficiency virus strains. We have previously identified a structural motif in the second transmembrane helix of CCR5, which plays a crucial role in the mechanism of receptor activation. We now report the specific role of aromatic residues in helices 2 and 3 of CCR5 in this mechanism. Using site-directed mutagenesis and molecular modeling in a combined approach, we demonstrate that a cluster of aromatic residues at the extracellular border of these two helices are involved in chemokine-induced activation. These aromatic residues are involved in interhelical interactions that are key for the conformation of the helices and govern the functional response to chemokines in a ligand-specific manner. We therefore suggest that transmembrane helices 2 and 3 contain important structural elements for the activation mechanism of chemokine receptors, and possibly other related receptors as well.     

Stabilization of two-stranded ribohomopolymer helices and destabilization of a three-stranded helix by ethidium bromide (Short Communication)

Thermal-denaturation profiles of helical polynucleotides have been measured in the presence of increasing concentrations of ethidium bromide. The poly(A).poly(U) helix is strongly stabilized by binding of ethidium, to much the same extent as is DNA, but the stabilizing effect on poly(I).poly(C) is much smaller. In the poly(A).2poly(U) system the drug selectively destabilizes and eventually destroys the triple helix, leaving only the double-helix-to-coil transition.     

Kinetic studies on the formation of intermolecular triple helices.

We have used DNase I footprinting to examine the association kinetics of GA-, GT- and CT-containing oligonucleotides with the target sequence (GGA)5GG. (CCT)5CC. These reactions are slow yielding bimolecular association rate constants between 50 and 2000 M-1s-1. We find that GT-containing oligonucleotides bind much faster than GA- or CT-containing third strands. In each case the observed rate constants are faster at the centre than at the edges of the target site. Although several explanations can be offered for this observation, it is consistent with a model in which triplex formation at this repetitive site is achieved via intermediate complexes in which the third strand is not properly aligned with its target and which subsequently migrate to the correct position.     

Sequence specificity of inter- and intramolecular G-quadruplex formation by human telomeric DNA

Human telomeric DNA consists of tandem repeats of the sequence 5'-d(TTAGGG)-3'. Guanine-rich DNA, such as that seen at telomeres, forms G-quadruplex secondary structures. Alternative forms of G-quadruplex structures can have differential effects on activities involved in telomere maintenance. With this in mind, we analyzed the effect of sequence and length of human telomeric DNA on G-quadruplex structures by native polyacrylamide gel electrophoresis and circular dichroism. Telomeric oligonucleotides shorter than four, 5'-d(TTAGGG)-3' repeats formed intermolecular G-quadruplexes. However, longer telomeric repeats formed intramolecular structures. Altering the 5'-d(TTAGGG)-3' to 5'-d(TTAGAG)-3' in any one of the repeats of 5'-d(TTAGGG)(4)-3' converted an intramolecular structure to intermolecular G-quadruplexes with varying degrees of parallel or anti-parallel-stranded character, depending on the length of incubation time and DNA sequence. These structures were most abundant in K(+)-containing buffers. Higher-order structures that exhibited ladders on polyacrylamide gels were observed only for oligonucleotides with the first telomeric repeat altered. Altering the sequence of 5'-d(TTAGGG)(8)-3' did not result in the substantial formation of intermolecular structures even when the oligonucleotide lacked four consecutive telomeric repeats. However, many of these intramolecular structures shared common features with intermolecular structures formed by the shorter oligonucleotides. The wide variability in structure formed by human telomeric sequence suggests that telomeric DNA structure can be easily modulated by proteins, oxidative damage, or point mutations resulting in conversion from one form of G-quadruplex to another.     

Thermodynamic and kinetic properties of short RNA helices: the oligomer sequence AnGCUn

We studied the thermodynamic, kinetic and optical properties of the double helices formed by the series of self-complementary oligonucleotides, (AP)_nGpC(pU)_n, 2 ≤ n ≤ 4, and found that the shortest helix, containing just 6 base pairs, is less stable than would be predicted from the properties of the larger molecules. It also shows a markedly smaller hyperchromism on melting than expected. These anomalous properties of a short helix indicate that one cannot always assume that base pair free energies and extinction coefficient changes are independent of helix size.     

Stabilization of a novel beta-turn-like motif by nonconventional intramolecular hydrogen-bonding interactions in a model peptide incorporating beta-alanine

The chemical synthesis and x-ray crystal structure analysis of a model peptide incorporating a conformationally adaptable unsubstituted beta-Ala residue: Boc-beta-Ala-Acc6-OCH3 (C16H28N2O5, molecular weight = 328.41; 1) has been described. The peptide crystallized in the space group P2(1)2(1)2(1) a = 8.537 (3), b = 8.872 (10), c = 25.327 (8), alpha = beta = gamma = 90.0 degrees, Z = 4. An attractive feature of the crystal structure analysis of 1 is an accommodation of a significantly folded beta-Ala residue in a short linear peptide. The overall peptide conformation is typically folded into a beta-turn-like motif. The stabilization of the peptide backbone conformation by nonconventional C-H...O weak intramolecular hydrogen-bonding interactions, involving the ester terminal carbon atom and the ethereal oxygen of the Boc group, has been evoked. The conformational constraint that seems most apparent is the phi, psi value of the highly constrained hydrophobic Acc6 ring that may play a key role in inducing or sustaining the observed pseudo type III or III' beta-turn structure. The resulting 12-membered hydrogen bonding ring motif in 1 is distinctly different from the one found in classical beta-turn structures, stabilized by a conventional strong C=O...H-N intramolecular hydrogen bond, comprised of alpha-amino acids. The potential of the conformationally adaptable beta-Ala residue to occupy i + 1 position (left corner) of the folded beta-turn-like structure and to design and construct novel secondary structural features have been emphasized.