Twisted hyperboloid (strophoid) as a model of β-barrels in proteins

Using a least-squares fitting procedure, polypeptide backbones of one parallel and seven antiparallel β-barrels were approximated with various curved surfaces. Although the hyperboloid gave better approximations to all the β-barrel backbones than the ellipsoid, elliptical cylinder or catenoid, the best approximations were obtained with a novel surface, a twisted hyperboloid (strophoid). The root-mean-square errors between individual β-barrels and the fitted strophoid surfaces ranged from 0.75 Å to 1.64 Å. The parameters which determine the strophoid surface allow groups of β-barrel shapes to be defined according to their barrel twists (i.e. angles subtended by directions of the long axis of cross-section at the top and the bottom of the barrel), course of elliptical cross-sections (either monotonically increasing along the barrel axis, as in cones, or having a middle “waist”, as in hyperboloids), and types of backbone curvatures (either convex or concave). The curvatures at individual points of strophoid surface are local, variable quantities related to the local helicity (coil) of the polypeptide backbone, in contrast to values of β-sheet twist (i.e. dihedral angles subtended by adjacent β-strands) known to be virtually identical in all the β-sheets. The variability found in parameters such as barrel shapes and curvatures suggests that simple models (isotropically stressed surfaces, principle of minimal surface tension) proposed in the past to account for β-barrel shapes are not sufficient. Rather, the complex nature of best-fit theoretical surfaces points to an important role played by a local variability of the forces involved.     

Binding Modes of Thioflavin-T to the Single-Layer β-Sheet of the Peptide Self-Assembly Mimics

Although the amyloid dye thioflavin-T (ThT) is among the most widely used tools in the study of amyloid fibrils, the mechanism by which ThT binds to fibrils and other β-rich peptide self-assemblies remains elusive. The development of the water-soluble peptide self-assembly mimic (PSAM) system has provided a set of ideal model proteins for experimentally exploring the properties and minimal dye-binding requirements of amyloid fibrils. PSAMs consist of a single-layer β-sheet (SLB) capped by two globular domains, which capture the flat, extended β-sheet features common among fibril-like surfaces. Recently, a PSAM that binds to ThT with amyloid-like affinity (low micromolar K_d) has been designed, and its crystal structure in the absence of bound ThT was determined. This PSAM thus provides a unique opportunity to examine the interactions of ThT with a β-rich structure. Here, we present molecular dynamics simulations of the binding of ThT to this PSAM β-sheet. We show that the primary binding site for ThT is along a shallow groove formed by adjacent Tyr and Leu residues on the β-sheet surface. These simulations provide an atomic-scale rationale for this PSAM's experimentally determined dye-binding properties. Together, our results suggest that an aromatic-hydrophobic groove spanning across four consecutive β-strands represents a minimal ThT binding site on amyloid fibrils. Grooves formed by aromatic-hydrophobic residues on amyloid fibril surfaces may therefore offer a generic mode of recognition for amyloid dyes.     

Solution Structure of Histone Chaperone ANP32B: Interaction with Core Histones H3-H4 through Its Acidic Concave Domain

Eukaryotic gene expression is regulated by histone deposition onto and eviction from nucleosomes, which are mediated by several chromatin-modulating factors. Among them, histone chaperones are key factors that facilitate nucleosome assembly. Acidic nuclear phosphoprotein 32B (ANP32B) belongs to the ANP32 family, which shares N-terminal leucine-rich repeats (LRRs) and a C-terminal variable anionic region. The C-terminal region functions as an inhibitor of histone acetylation, but the functional roles of the LRR domain in chromatin regulation have remained elusive. Here, we report that the LRR domain of ANP32B possesses histone chaperone activity and forms a curved structure with a parallel β-sheet on the concave side and mostly helical elements on the convex side. Our analyses revealed that the interaction of ANP32B with the core histones H3-H4 occurs on its concave side, and both the acidic and hydrophobic residues that compose the concave surface are critical for histone binding. These results provide a structural framework for understanding the functional mechanisms of acidic histone chaperones.     

Free energy and structural pathways of base flipping in a DNA GCGC containing sequence

Structural distortions of DNA are essential for its biological function due to the genetic information of DNA not being physically accessible in the duplex state. Base flipping is one of the simplest structural distortions of DNA and may represent an initial event in strand separation required to access the genetic code. Flipping is also utilized by DNA-modifying and repair enzymes to access specific bases. It is typically thought that base flipping (or base-pair opening) occurs via the major groove whereas minor groove flipping is only possible when mediated by DNA-binding proteins. Here, umbrella sampling with a novel center-of-mass pseudodihedral reaction coordinate was used to calculate the individual potentials of mean force (PMF) for flipping of the Watson-Crick (WC) paired C and G bases in the CCATGCGCTGAC DNA dodecamer. The novel reaction coordinate allowed explicit investigation of the complete flipping process via both the minor and major groove pathways. The minor and major groove barriers to flipping are similar for C base flipping while the major groove barrier is slightly lower for G base flipping. Minor groove flipping requires distortion of the WC partner while the flipping base pulls away from its partner during major groove flipping. The flipped states are represented by relatively flat free energy surfaces, with a small, local minimum observed for the flipped G base. Conserved patterns of phosphodiester backbone dihedral distortions during flipping indicate their essential role in the flipping process. During flipping, the target base tracks along the respective grooves, leading to hydrogen-bonding interactions with neighboring base-pairs. Such hydrogen-bonding interactions with the neighboring sequence suggest a novel mechanism of sequence dependence in DNA dynamics.     

Relationship between structure and amino acid sequence of strongly twisted and coiled β-hairpins in globular proteins

β-Hairpins are widespread in proteins, and it is possible to find them both within β-sheets and separately. In this work, a comparative analysis of amino acid sequences of β-strands within strongly twisted β-hairpins from different structural protein subclasses has been conducted. Strongly twisted and coiled β-hairpin generates in the space a right double helix out of β-strands that are connected by a loop region (connections). The frequencies of amino acid residues on the internal (concave) and external (convex) surfaces of strongly twisted β-hairpins have been determined (220 β-hairpins from nonhomologous proteins were studied). The concave surface of these β-hairpins is mainly generated by hydrophobic residues, while the convex surface by hydrophilic residues; accordingly, the alternation of hydrophobic internal and hydrophilic external residues is observed in their amino acid sequences. Amino acid residues of glycine and alanine (especially in places of the largest twisting of the strands) were anomalously frequently found in internal positions of strongly twisted and coiled β-hairpins. It was established that internal positions never contain the proline residues, while external positions in the twisting region contain them in a relatively large amount. It was demonstrated that at least one amino acid residue in α_L- or ε-conformation is required for generation of relatively short (up to 7 amino acid residues) connection. As a rule, these positions are occupied by glycines. Thus, not only the alternation of hydrophobic and hydrophilic amino acid residues, but also the presence of one or two glycine residues in the connection region and the excess of glycines and alanines in the places of the largest strand twisting on the concave surface, as well as the presence of prolines on the convex surface, are required to generate a strongly twisted and coiled β-hairpin.     

Solution structure of the human HSPC280 protein

The human HSPC280 protein belongs to a new family of low molecular weight proteins, which is only present in eukaryotes, and is absent in fungi. The solution structure of HSPC280 was determined using multidimensional NMR spectroscopy. The overall structure consists of three α-helices and four antiparallel β-strands and has a winged helix-like fold. However, HEPC280 is not a typical DNA-binding winged helix protein in that it lacks DNA-binding activity. Unlike most winged-helix proteins, HSPC280 has an unusually long 13-residue (P62-V74) wing 1 loop connecting the β3 and β4 strands of the protein. Molecules of HSPC280 have a positively charged surface on one side and a negatively charged surface on the other side of the protein structure. Comparisons with the C-terminal 80-residue domain of proteins in the Abra family reveal a conserved hydrophobic groove in the HSPC280 family, which may allow HSPC280 to interact with other proteins.     

Interaction of Topotecan,DNA Topoisomerase I Inhibitor,with Double-stranded Polydeoxyribonucleotides. 3. Binding at the Minor Groove

Interaction of topotecan (TPT) with calf thymus DNA, coliphage T4 DNA, and poly(dGdC) · poly(dG-dC) was studied by optical (linear flow dichroism, UV-vis spectroscopy) and quantum chemical methods. The linear dichroism signal of TPT bound to DNA was shown to have positive sign in the range 260–295 nm. This means that the plane of quinoline fragment (rings A and B) of TPT forms an angle less than 54° with the long axis of DNA, and hence the TPT molecule cannot intercalate between DNA base pairs. TPT was established to bind to calf thymus DNA as readily as to coliphage T4 DNA whose cytosines in the major groove were all glycosylated at the 5th position. Consequently, the DNA major groove does not participate in TPT binding. TPT molecule was shown to compete with distamycin for binding sites in the minor groove of DNA and poly(dG-dC) · poly(dG-dC). Thus, it was demonstrated for the first time that TPT binds to DNA at its minor groove.     

DNA recognition by DNase I

Bovine pancreatic DNase I shows a strong preference for double-stranded substrates and cleaves DNA with strongly varying cutting rates suggesting that the enzyme recognises sequence-dependent structural variations of the DNA double helix. The complicated cleavage pattern indicates that several local as well as global helix parameters influences the cutting frequency of DNase I at a given bond. The high resolution crystal structures of two DNase I-DNA complexes showed that the enzyme binds tightly in the minor groove, and to the sugar-phosphate backbones of both strands, and thereby induces a widening of the minor groove and a bending towards the major grooves. In agreement with biochemical data this suggests that flexibility and minor groove geometry are major parameters determining the cutting rate of DNase I. Experimental observations showing that the sequence environmental of a dinucleotide step strongly affects its cleavage efficiency can be rationalized by that fact that six base pair are in contact with the enzyme. Mutational analysis based on the structural results has identified critical residues for DNA binding and cleavage and has lead to a proposal for the catalytic mechanism.     

Conformational entropy limits the transition from nucleation to elongation in amyloid aggregation

The formation of β-sheet-rich amyloid fibrils in Alzheimer’s disease and other neurodegenerative disorders is limited by a slow nucleation event. To understand the initial formation of β-sheets from disordered peptides, we used all-atom simulations to parameterize a lattice model that treats each amino acid as a binary variable with β- and non-β-sheet states. We show that translational and conformational entropy give the nascent β-sheet an anisotropic surface tension that can be used to describe the nucleus with 2D classical nucleation theory. Since translational entropy depends on concentration, the aspect ratio of the critical β-sheet changes with protein concentration. Our model explains the transition from the nucleation phase to elongation as the point where the β-sheet core becomes large enough to overcome the conformational entropy cost to straighten the terminal molecule. At this point the β-strands in the nucleus spontaneously elongate, which results in a larger binding surface to capture new molecules. These results suggest that nucleation is relatively insensitive to sequence differences in coaggregation experiments because the nucleus only involves a small portion of the peptide.     

Packing constraints of hydrophobic side chains in (α/β)8 barrels

An analysis of possible tight packing of hydrophobic groups simultaneously at the both surfaces of β-hyperboloid-8 was conducted. This analysis shows that the disposition of amino acid side chains at the real β-structure's surface is unique. If we sign the mean distance between adjacent β-strands as “a,” and the mean distance along β-strand between C_α atoms, whose side chains are directed to one side of the β-sheet, as “b,” the ratio b/a = √2 very precisely. This ratio ensures the most efficient packing of side hydrophobic groups at the outer surface of β-hyperboloid-8, forming, at the same time, the second by efficiency packing at its inner surface. © 1995 Wiley-Liss, Inc.     

Conformational prediction and circular dichroism studies on the lac repressor

Using the protein predictive model of Chou & Fasman (1974b), the secondary structure of the lac repressor has been elucidated from its amino acid sequence of 347 residues. The conformation is predicted to contain 37% α-helix and 35% β-sheet for the repressor, and 29% helix and 41% β-sheet for the trypsin-resistant core (residues 60 to 327). Circular dichroism studies indicate that native lac repressor contains 40% helix and 42% β-sheet, while the core has 16% helix and 54% β-sheet, in general agreement with the predicted conformation. The sharp reduction in helicity for the trypsinized lac repressor could be due to the loss of two long helical regions, 26–45 and 328–344, predicted at both terminals. There are extensive β-sheets predicted in the 215–324 region, which may be responsible for tetrameric stabilization found in both the lac repressor and the core. Residues 17 to 33 were previously predicted by Adler et al. (1972) to be helical and were proposed to bind in the major groove of DNA. However, the present analysis shows that there are two anti-parallel β-sheet regions: 4–7 and 17–24 at the N-terminal as well as 315–318 and 321–324 at the C-terminal of the lac repressor. These β-sheet pairs may assume the twisted “polypeptide double helix” conformation (Carter & Kraut, 1974) and bind to complementary regions in the major groove of DNA. The OH groups of Tyr at the N-terminal and those of Thr and Ser side chains, in both β-sheets at the N and C-terminal ends, could form hydrogen bonds to specific sites on the lac operator. There are 23 reverse β-turns predicted that may control the tertiary folding of the lac repressor, which is essential for operator binding. The behavior of several lac repressor mutants can be satisfactorily explained in terms of polar to non-polar group replacements as well as conformational changes in light of the present predicted model.     

Minor groove to major groove, an unusual DNA sequence-dependent change in bend directionality by a distamycin dimer

DNA sequence-dependent conformational changes induced by the minor groove binder, distamycin, have been evaluated by polyacrylamide gel electrophoresis. The distamycin binding affinity, cooperativity, and stoichiometry with three target DNA sequences that have different sizes of alternating AT sites, ATAT, ATATA, and ATATAT, have been determined by mass spectrometry and surface plasmon resonance to help explain the conformational changes. The results show that distamycin binds strongly to and bends five or six AT base pair minor groove sites as a dimer with positive cooperativity, while it binds to ATAT as a weak, slightly anticooperative dimer. The bending direction was evaluated with an in phase A-tract reference sequence. Unlike other similar monomer minor groove binding compounds, such as netropsin, the distamycin dimer changes the directionality of the overall curvature away from the minor groove to the major groove. This distinct structural effect may allow designed distamycin derivatives to have selective therapeutic effects.     

Teaching an old scaffold new tricks: monobodies constructed using alternative surfaces of the FN3 scaffold

The fibronectin type III domain (FN3) has become one of the most widely used non-antibody scaffolds for generating new binding proteins. Because of its structural homology to the immunoglobulin domain, combinatorial libraries of FN3 designed to date have primarily focused on introducing amino acid diversity into three loops that are equivalent to antibody complementarity-determining regions. Here, we report an FN3 library that utilizes alternative positions for presenting amino acid diversity. We diversified positions on a β-sheet and surface loops that together form a concave surface. The new library produced binding proteins (termed "monobodies") to multiple target proteins, generally with similar efficacy as the original, loop-focused library. The crystal structure of a monobody generated from the new library in complex with its target, the Abl SH2 domain, revealed that a concave surface of the monobody, as intended in our design, bound to a convex surface of the target with the interface area being among the largest of published structures of monobody-target complexes. This mode of interaction differs from a common binding mode for single-domain antibodies and antibody mimics in which recognition loops recognize clefts in targets. Together, this work illustrates the utilization of different surfaces of a single immunoglobulin-like scaffold to generate binding proteins with distinct characteristics.     

Studies on the rules of β-strand alignment in a protein β-sheet structure

To further disclose the underlying mechanisms of protein β-sheet formation, studies were made on the rules of β-strands alignment forming β-sheet structure using statistical and machine learning approaches. Firstly, statistical analysis was performed on the sum of β-strands between each β-strand pairs in protein sequences. The results showed a propensity of near-neighbor pairing (or called “first come first pair”) in the β-strand pairs. Secondly, based on the same dataset, the pairwise cross-combinations of real β-strand pairs and four pseudo-β-strand contained pairs were classified by support vector machine (SVM). A novel feature extracting approach was designed for classification using the average amino acid pairing encoding matrix (APEM). Analytical results of the classification indicated that a segment of β-strand had the ability to distinguish β-strands from segments of α-helix and coil. However, the result also showed that a β-strand was not strongly conserved to choose its real partner from all the alternative β-strand partners, which was corresponding with the ordination results of the statistical analysis each other. Thus, the rules of “first come first pair” propensity and the non-conservative ability to choose real partner, were possible important factors affecting the β-strands alignment forming β-sheet structures.     

Synthesis and DNA binding profile of monomeric,dimeric, and trimeric derivatives of crystal violet

Monomeric, dimeric, and trimeric derivatives of the triphenylmethane dye crystal violet (1a–1f) have been synthesized for the purpose of evaluating their affinity and sequence selectivity for duplex DNA. Competitive ethidum displacement assays indicate that 1a–1f have apparent association constants for CT DNA in the range of 1.80–16.2 × 10⁷ M⁻¹ and binding site sizes of 10–14 bp. Viscosity experiments performed on ligand 1f confirmed that these dyes associate with duplex DNA by a non-intercalative mode of binding. Circular dichroism and competition binding studies of the tightest binding ligand 1e with known major and minor groove binding molecules suggest that these dye derivatives likely occupy the major groove of DNA. Data from the binding of 1e to polynucleotides indicate close to an order of magnitude preference for associating with AT rich homopolymers over GC rich homopolymers, suggesting a shape-selective match of the sterically bulky ligand with DNA containing a wider major groove.