Δ98Δ, a minimalist model of antiparallel β‐sheet proteins based on intestinal fatty acid binding protein

The design of β‐barrels has always been a formidable challenge for de novo protein design. For instance, a persistent problem is posed by the intrinsic tendency to associate given by free edges. From the opposite standpoint provided by the redesign of natural motifs, we believe that the intestinal fatty acid binding protein (IFABP) framework allows room for intervention, giving rise to abridged forms from which lessons on β‐barrel architecture and stability could be learned. In this context, Δ98Δ (encompassing residues 29–126 of IFABP) emerges as a monomeric variant that folds properly, retaining functional activity, despite lacking extensive stretches involved in the closure of the β‐barrel. Spectroscopic probes (fluorescence and circular dichroism) support the existence of a form preserving the essential determinants of the parent structure, albeit endowed with enhanced flexibility. Chemical and physical perturbants reveal cooperative unfolding transitions, with evidence of significant population of intermediate species in equilibrium, structurally akin to those transiently observed in IFABP. The recognition by the natural ligand oleic acid exerts a mild stabilizing effect, being of a greater magnitude than that found for IFABP. In summary, Δ98Δ adopts a monomeric state with a compact core and a loose periphery, thus pointing to the nonintuitive notion that the integrity of the β‐barrel can indeed be compromised with no consequence on the ability to attain a native‐like and functional fold.     

Toward a common aggregation mechanism for a β-barrel protein family: Insights derived from a stable dimeric species

Δ78Δ is a second generation functional all-β sheet variant of IFABP (intestinal fatty acid binding protein) corresponding to the fragment 29–106 of the parent protein. This protein and its predecessor, Δ98Δ (segment 29–126 of IFABP), were initially uncovered by controlled proteolysis. Remarkably, although IFABP and Δ98Δ are monomers in solution, Δ78Δ adopts a stable dimeric structure. With the aim of identifying key structural features that modulate the aggregation of β-proteins, we evaluate here the structure and aggregation propensity of Δ78Δ. The 2,2,2-trifluoroethanol (TFE) induced aggregation of this protein shows a primary nucleation–elongation mechanism, characterized by the stabilization of a dimeric nucleus. Its rate of production from the co-solvent induced aggregation prone state governs the kinetics of polymerization. In this context, the value of Δ78Δ lies in the fact that – being a stable dimeric species – it reduces an otherwise bimolecular reaction to a unimolecular one. Interestingly, even though Δ78Δ and IFABP display similar conformational stability, the abrogated form of IFABP shows an enhanced aggregation rate, revealing the ancillary role played on this process by the free energy of the native proteins. Δ78Δ share with IFABP and Δ98Δ a common putative aggregation-prone central peptide. Differences in the exposure/accessibility of this segment dictated by the environment around this region might underlie the observed variations in the speed of aggregation. Lessons learnt from this natural dimeric protein might shed light on the early conformational events leading to β-conversion from barrels to amyloid aggregates.     

Characterization of fatty acid binding and transfer from ∆98∆, a functional all-β abridged form of IFABP

Intestinal fatty acid binding protein (IFABP) is an intracellular lipid binding protein whose specific functions within the cell are still uncertain. An abbreviated version of IFABP encompassing residues 29–126, dubbed Δ98Δ is a stable product of limited proteolysis with clostripain of holo-IFABP. Cumulative evidence shows that Δ98Δ adopts a stable, monomeric and functional fold, with compact core and loose periphery. In agreement with previous results, this abridged variant indicates that the helical domain is not necessary to preserve the general topology of IFABP's β-barrel and that the helix-turn-helix motif is a fundamental element of the portal region involved in ligand binding and protein–membrane interactions. Results presented here suggest that Δ98Δ binds fatty acids with affinities lower than IFABP but higher than those shown by previous helix-less variants, shows a ‘diffusional’ fatty acid transfer mechanism and it interacts with artificial membranes. This work highlights the importance of the β-barrel of IFABP for its specific functions.     

Ab initio folding of a trefoil‐fold motif reveals structural similarity with a β‐propeller blade motif

Many protein architectures exhibit evidence of internal rotational symmetry postulated to be the result of gene duplication/fusion events involving a primordial polypeptide motif. A common feature of such structures is a domain‐swapped arrangement at the interface of the N‐ and C‐termini motifs and postulated to provide cooperative interactions that promote folding and stability. De novo designed symmetric protein architectures have demonstrated an ability to accommodate circular permutation of the N‐ and C‐termini in the overall architecture; however, the folding requirement of the primordial motif is poorly understood, and tolerance to circular permutation is essentially unknown. The β‐trefoil protein fold is a threefold‐symmetric architecture where the repeating ~42‐mer “trefoil‐fold” motif assembles via a domain‐swapped arrangement. The trefoil‐fold structure in isolation exposes considerable hydrophobic area that is otherwise buried in the intact β‐trefoil trimeric assembly. The trefoil‐fold sequence is not predicted to adopt the trefoil‐fold architecture in ab initio folding studies; rather, the predicted fold is closely related to a compact “blade” motif from the β‐propeller architecture. Expression of a trefoil‐fold sequence and circular permutants shows that only the wild‐type N‐terminal motif definition yields an intact β‐trefoil trimeric assembly, while permutants yield monomers. The results elucidate the folding requirements of the primordial trefoil‐fold motif, and also suggest that this motif may sample a compact conformation that limits hydrophobic residue exposure, contains key trefoil‐fold structural features, but is more structurally homologous to a β‐propeller blade motif.     

The minimal α‐crystallin domain of Mj Hsp16.5 is functional at non‐heat‐shock conditions

The small heat shock protein (sHSP) from Methanococcus jannaschii (Mj Hsp16.5) forms a monodisperse 24mer and each of its monomer contains two flexible N‐ and C‐terminals and a rigid α‐crystallin domain with an extruding β‐strand exchange loop. The minimal α‐crystallin domain with a β‐sandwich fold is conserved in sHSP family, while the presence of the β‐strand exchange loop is divergent. The function of the β‐strand exchange loop and the minimal α‐crystallin domain of Mj Hsp16.5 need further study. In the present study, we constructed two fragment‐deletion mutants of Mj Hsp16.5, one with both the N‐ and C‐terminals deleted (ΔNΔC) and the other with a further deletion of the β‐strand exchange loop (ΔNΔLΔC). ΔNΔC existed as a dimer in solution. In contrast, the minimal α‐crystallin domain ΔNΔLΔC became polydisperse in solution and exhibited more efficient chaperone‐like activities to prevent amorphous aggregation of insulin B chain and fibril formation of the amyloidogenic peptide dansyl‐SSTSAA‐W than the mutant ΔNΔC and the wild type did. The hydrophobic probe binding experiments indicated that ΔNΔLΔC exposed much more hydrophobic surface than ΔNΔC. Our study also demonstrated that Mj Hsp16.5 used different mechanisms for protecting different substrates. Though Mj Hsp16.5 formed stable complexes with substrates when preventing thermal aggregation, no complexes were detected when preventing aggregation under non‐heat‐shock conditions. Proteins 2014; 82:1156–1167. © 2013 Wiley Periodicals, Inc.     

Structural motifs in which β‐strands are clipped together with the П‐like module

In this study, the structural motifs that can be represented as combinations of small motifs such as β‐hairpins, S‐, and Z‐like β‐sheets and βαβ‐units, and the П‐like module are described and analyzed. The П‐module consists of connected elements of the β‐strand‐loop‐β‐strand type arranged in space so that its overall fold resembles a clip or the Greek letter П. In proteins, the П‐module itself and the structural motifs containing it exhibit unique overall folds and have specific sequence patterns of the key hydrophobic, hydrophilic and glycine residues. All this together enables us to conclude that these structural motifs can fold independently of the remaining part of the molecule and can act as nuclei and/or “ready‐made” building blocks in protein folding.     

Conserved buried water molecules enable the β‐trefoil architecture

Available high‐resolution crystal structures for the family of β‐trefoil proteins in the structural databank were queried for buried waters. Such waters were classified as either: (a) unique to a particular domain, family, or superfamily or (b) conserved among all β‐trefoil folds. Three buried waters conserved among all β‐trefoil folds were identified. These waters are related by the threefold rotational pseudosymmetry characteristic of this protein architecture (representing three instances of an identical structural environment within each repeating trefoil‐fold motif). The structural properties of this buried water are remarkable and include: residing in a cavity space no larger than a single water molecule, exhibiting a positional uncertainty (i.e., normalized B‐factor) substantially lower than the average Cα atom, providing essentially ideal H‐bonding geometry with three solvent‐inaccessible main chain groups, simultaneously serving as a bridging H‐bond for three different β‐strands at a point of secondary structure divergence, and orienting conserved hydrophobic side chains to form a nascent core‐packing group. Other published work supports an interpretation that these interactions are key to the formation of an efficient folding nucleus and folded thermostability. The fundamental threefold symmetric structural element of the β‐trefoil fold is therefore, surprisingly, a buried water molecule.     

Optimization of a β‐sheet‐cap for long loop closure

Protein loops make up a large portion of the secondary structure in nature. But very little is known concerning loop closure dynamics and the effects of loop composition on fold stability. We have designed a small system with stable β‐sheet structures, including features that allow us to probe these questions. Using paired Trp residues that form aromatic clusters on folding, we are able to stabilize two β‐strands connected by varying loop lengths and composition (an example sequence: R W ITVTI – loop – KKIRV W E). Using NMR and CD, both fold stability and folding dynamics can be investigated for these systems. With the 16 residue loop peptide (sequence: R W ITVTI‐(GGGGKK)₂GGGG‐KKIRV W E) remaining folded (ΔG_U = 1.6 kJ/mol at 295K). To increase stability and extend the series to longer loops, we added an additional Trp/Trp pair in the loop flanking position. With this addition to the strands, the 16 residue loop (sequence: R W ITVRI W ‐(GGGGKK)₂GGGG‐ W KTIRV W E) supports a remarkably stable β‐sheet (ΔG_U = 6.3 kJ/mol at 295 K, T_m = ～55°C). Given the abundance of loops in binding motifs and between secondary structures, these constructs can be powerful tools for peptide chemists to study loop effects; with the Trp/Trp pair providing spectroscopic probes for assessing both stability and dynamics by NMR.     

Structures of single‐layer β‐sheet proteins evolved from β‐hairpin repeats

Free‐standing single‐layer β‐sheets are extremely rare in naturally occurring proteins, even though β‐sheet motifs are ubiquitous. Here we report the crystal structures of three homologous, single‐layer, anti‐parallel β‐sheet proteins, comprised of three or four twisted β‐hairpin repeats. The structures reveal that, in addition to the hydrogen bond network characteristic of β‐sheets, additional hydrophobic interactions mediated by small clusters of residues adjacent to the turns likely play a significant role in the structural stability and compensate for the lack of a compact hydrophobic core. These structures enabled identification of a family of secreted proteins that are broadly distributed in bacteria from the human gut microbiome and are putatively involved in the metabolism of complex carbohydrates. A conserved surface patch, rich in solvent‐exposed tyrosine residues, was identified on the concave surface of the β‐sheet. These new modular single‐layer β‐sheet proteins may serve as a new model system for studying folding and design of β‐rich proteins.     

Delta98delta, a functional all-beta-sheet abridged form of intestinal fatty acid binding protein

Intestinal fatty acid binding protein (IFABP) is a 15 kDa intracellular lipid-binding protein exhibiting a beta-barrel fold that resembles a clamshell. The beta-barrel, which encloses the ligand binding cavity, consists of two perpendicular five-stranded beta-sheets with an intervening helix-turn-helix motif between strands A and B. Delta98delta (fragment 29-126 of IFABP) was obtained either in its recombinant form or by limited proteolysis with clostripain. Despite lacking extensive stretches involved in the closure of the beta-barrel, delta98delta remains soluble and stable in solution. Spectroscopic analyses by circular dichroism, ultraviolet absorption, and intrinsic fluorescence indicate that the fragment retains substantial beta-sheet content and tertiary interactions. In particular, the environment around W82 is identical in both delta98delta and IFABP, a fact consistent with the conservation in the former of all the critical amino acid residues belonging to the hydrophobic core. In addition, the Stokes radius of delta98delta is similar to that of IFABP and 16% larger than that calculated from its molecular weight (11 kDa). The monomeric status of delta98delta was further confirmed by chemical cross-linking experiments. Although lacking 25% of the amino acids of the parent protein, in the presence of GdnHCl, delta98delta unfolds through a cooperative transition showing a midpoint at 0.90 M. Remarkably, it also preserves binding activity for fatty acids (Kd = 5.1 microM for oleic acid and Kd = 0.72 microM for trans-parinaric acid), a fact that exerts a stabilizing effect on its structure. These cumulative evidences show that delta98delta adopts a monomeric state with a compact core and a loose periphery, being so far the smallest structure of its kind preserving binding function.     

Substrate binding drives large-scale conformational changes in the Hsp90 molecular chaperone

Hsp90 is a ubiquitous molecular chaperone. Previous structural analysis demonstrated that Hsp90 can adopt a large number of structurally distinct conformations; however, the functional role of this flexibility is not understood. Here we investigate the structural consequences of substrate binding with a model system in which Hsp90 interacts with a partially folded protein (Δ131Δ), a well-studied fragment of staphylococcal nuclease. SAXS measurements reveal that under apo conditions, Hsp90 partially closes around Δ131Δ, and in the presence of AMPPNP, Δ131Δ binds with increased affinity to Hsp90's fully closed state. FRET measurements show that Δ131Δ accelerates the nucleotide-driven open/closed transition and stimulates ATP hydrolysis by Hsp90. NMR measurements reveal that Hsp90 binds to a specific, highly structured region of Δ131Δ. These results suggest that Hsp90 preferentially binds a locally structured region in a globally unfolded protein, and this binding drives functional changes in the chaperone by lowering a rate-limiting conformational barrier.     

KRE genes are required for β‐1,6‐glucan synthesis,maintenance of capsule architecture and cell wall protein anchoring in Cryptococcus neoformans

The polysaccharide β‐1,6‐glucan is a major component of the cell wall of Cryptococcus neoformans, but its function has not been investigated in this fungal pathogen. We have identified and characterized seven genes, belonging to the KRE family, which are putatively involved in β‐1,6‐glucan synthesis. The H99 deletion mutants kre5Δ and kre6Δskn1Δ contained less cell wall β‐1,6‐glucan, grew slowly with an aberrant morphology, were highly sensitive to environmental and chemical stress and were avirulent in a mouse inhalation model of infection. These two mutants displayed alterations in cell wall chitosan and the exopolysaccharide capsule, a primary cryptococcal virulence determinant. The cell wall content of the GPI‐anchored phospholipase B1 (Plb1) enzyme, which is required for cryptococcal cell wall integrity and virulence, was reduced in kre5Δ and kre6Δskn1Δ. Our results indicate that KRE5, KRE6 and SKN1 are involved in β‐1,6‐glucan synthesis, maintenance of cell wall integrity and retention of mannoproteins and known cryptococcal virulence factors in the cell wall of C. neoformans. This study sets the stage for future investigations into the function of this abundant cell wall polymer.     

β‐Bulges: Extensive structural analyses of β‐sheets irregularities

β‐Sheets are quite frequent in protein structures and are stabilized by regular main‐chain hydrogen bond patterns. Irregularities in β‐sheets, named β‐bulges, are distorted regions between two consecutive hydrogen bonds. They disrupt the classical alternation of side chain direction and can alter the directionality of β‐strands. They are implicated in protein‐protein interactions and are introduced to avoid β‐strand aggregation. Five different types of β‐bulges are defined. Previous studies on β‐bulges were performed on a limited number of protein structures or one specific family. These studies evoked a potential conservation during evolution. In this work, we analyze the β‐bulge distribution and conservation in terms of local backbone conformations and amino acid composition. Our dataset consists of 66 times more β‐bulges than the last systematic study (Chan et al. Protein Science 1993, 2:1574–1590). Novel amino acid preferences are underlined and local structure conformations are highlighted by the use of a structural alphabet. We observed that β‐bulges are preferably localized at the N‐ and C‐termini of β‐strands, but contrary to the earlier studies, no significant conservation of β‐bulges was observed among structural homologues. Displacement of β‐bulges along the sequence was also investigated by Molecular Dynamics simulations.     

Insights into β2‐adrenergic receptor binding from structures of the N‐terminal lobe of ARRDC3

ARRDC3 is one of six known human α‐arrestins, and has been implicated in the downregulation of the β2‐adrenergic receptor (β2AR). ARRDC3 consists of a two‐lobed arrestin fold and a C‐terminal tail containing two PPYX motifs. In the current model for receptor downregulation by ARRDC3, the arrestin fold portion is thought to bind the receptor, while the PPXY motifs recruit ubiquitin ligases of the NEDD4 family. Here we report the crystal structures of the N‐terminal lobe of human ARRDC3 in two conformations, at 1.73 and 2.8 Å resolution, respectively. The structures reveal a large electropositive region that is capable of binding phosphate ions of crystallization. Residues within the basic patch were shown to be important for binding to β2AR, similar to the situation with β‐arrestins. This highlights potential parallels in receptor recognition between α‐ and β‐arrestins.     

High resolution crystal structure of Clostridium propionicum β‐alanyl‐CoA:ammonia lyase,a new member of the “hot dog fold” protein superfamily

Clostridium propionicum is the only organism known to ferment β‐alanine, a constituent of coenzyme A (CoA) and the phosphopantetheinyl prosthetic group of holo‐acyl carrier protein. The first step in the fermentation is a CoA‐transfer to β‐alanine. Subsequently, the resulting β‐alanyl‐CoA is deaminated by the enzyme β‐alanyl‐CoA:ammonia lyase (Acl) to reversibly form ammonia and acrylyl‐CoA. We have determined the crystal structure of Acl in its apo‐form at a resolution of 0.97 Å as well as in complex with CoA at a resolution of 1.59 Å. The structures reveal that the enyzme belongs to a superfamily of proteins exhibiting a so called “hot dog fold” which is characterized by a five‐stranded antiparallel β‐sheet with a long α‐helix packed against it. The functional unit of all “hot dog fold” proteins is a homodimer containing two equivalent substrate binding sites which are established by the dimer interface. In the case of Acl, three functional dimers combine to a homohexamer strongly resembling the homohexamer formed by YciA‐like acyl‐CoA thioesterases. Here, we propose an enzymatic mechanism based on the crystal structure of the Acl·CoA complex and molecular docking. Proteins 2014; 82:2041–2053. © 2014 Wiley Periodicals, Inc.     

Propensities of peptides containing the Asn‐Gly segment to form β‐turn and β‐hairpin structures

The propensities of peptides that contain the Asn‐Gly segment to form β‐turn and β‐hairpin structures were explored using the density functional methods and the implicit solvation model in CH₂Cl₂ and water. The populations of preferred β‐turn structures varied depending on the sequence and solvent polarity. In solution, β‐hairpin structures with βI′ turn motifs were most preferred for the heptapeptides containing the Asn‐Gly segment regardless of the sequence of the strands. These preferences in solution are consistent with the corresponding X‐ray structures. The sequence, H‐bond strengths, solvent polarity, and conformational flexibility appeared to interact to determine the preferred β‐hairpin structure of each heptapeptide, although the β‐turn segments played a role in promoting the formation of β‐hairpin structures and the β‐hairpin propensity varied. In the heptapeptides containing the Asn‐Gly segment, the β‐hairpin formation was enthalpically favored and entropically disfavored at 25°C in water. The calculated results for β‐turns and β‐hairpins containing the Asn‐Gly segment imply that these structural preferences may be useful for the design of bioactive macrocyclic peptides containing β‐hairpin mimics and the design of binding epitopes for protein–protein and protein–nucleic acid recognitions. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 653–664, 2016.     

The differences in binding 12‐carbon aliphatic ligands by bovine β‐lactoglobulin isoform A and B studied by isothermal titration calorimetry and X‐ray crystallography

Isoforms A (LGB‐A) and B (LGB‐B) of bovine lactoglobulin, the milk protein, differ in positions 64 (D?G) and 118 (V?A). Interactions of LGB‐A and LGB‐B with sodium dodecyl sulfate (SDS), dodecyltrimethylammonium chloride (DTAC) and lauric acid (LA), 12‐carbon ligands possessing differently charged polar groups, were investigated using isothermal titration calorimetry and X‐ray crystallography, to study the proton linkage phenomenon and to distinguish between effects related to different isoforms and different ligand properties. The determined values of ΔS and ΔH revealed that for all ligands, binding is entropically driven. The contribution from enthalpy change is lower and shows strong dependence on type of buffer that indicates proton release from the protein varying with protein isoform and ligand type and involvement of LA and Asp64 (in isoform A) in this process. The ligand affinities for both isoforms were arranged in the same order, DTAC < LA < SDS, and were systematically lower for variant B. The entropy change of the complexation process was always higher for isoform A, but these values were compensated by changes in enthalpy, resulting in almost identical ΔG for complexes of both isoforms. The determined crystal structures showed that substitution in positions 64 and 118 did not influence the overall structure of LGB complexes. The chemical character of the ligand polar group did not affect the position of its aliphatic chain in protein β‐barrel, indicating a major role of hydrophobic interactions in ligand binding that prevailed even with the repulsion between positively charged DTAC and lysine residues located at binding site entrance. Copyright © 2013 John Wiley & Sons, Ltd.     

Investigating the binding of β‐1,4‐galactan to Bacillus licheniformis β‐1,4‐galactanase by crystallography and computational modeling

Microbial β‐1,4‐galactanases are glycoside hydrolases belonging to family 53, which degrade galactan and arabinogalactan side chains in the hairy regions of pectin, a major plant cell wall component. They belong to the larger clan GH‐A of glycoside hydrolases, which cover many different poly‐ and oligosaccharidase specificities. Crystallographic complexes of Bacillus licheniformis β‐1,4‐galactanase and its inactive nucleophile mutant have been obtained with methyl‐β(1→4)‐galactotetraoside, providing, for the first time, information on substrate binding to the aglycone side of the β‐1,4‐galactanase substrate binding groove. Using the experimentally determined subsites as a starting point, a β(1→4)‐galactononaose was built into the structure and subjected to molecular dynamics simulations giving further insight into the residues involved in the binding of the polysaccharide from subsite ?4 to +5. In particular, this analysis newly identified a conserved β‐turn, which contributes to subsites ?2 to +3. This β‐turn is unique to family 53 β‐1,4‐galactanases among all clan GH‐A families that have been structurally characterized and thus might be a structural signature for endo‐β‐1,4‐galactanase specificity. Proteins 2009. © 2008 Wiley‐Liss, Inc.