Folding Subdomains Research Articles

A structural basis for prion strain diversity

Recent cryogenic electron microscopy (cryo-EM) studies of infectious, ex vivo, prion fibrils from hamster 263K and mouse RML prion strains revealed a similar, parallel in-register intermolecular β-sheet (PIRIBS) amyloid architecture. Rungs of the fibrils are composed of individual prion protein (PrP) monomers that fold to create distinct N-terminal and C-terminal lobes. However, disparity in the hamster/mouse PrP sequence precludes understanding of how divergent prion strains emerge from an identical PrP substrate. In this study, we determined the near-atomic resolution cryo-EM structure of infectious, ex vivo mouse prion fibrils from the ME7 prion strain and compared this with the RML fibril structure. This structural comparison of two biologically distinct mouse-adapted prion strains suggests defined folding subdomains of PrP rungs and the way in which they are interrelated, providing a structural definition of intra-species prion strain-specific conformations.

Contribution of beta circuit completion towards virulence factor stability and function

As bacterial pathogens gain antibacterial resistance, few mechanisms remain available for halting pathogenicity, giving a frightening glimpse into a post‐antibacterial era. However, the secretion of virulence factors is often imperative to bacterial pathogenesis within the human body and is becoming a larger target for antibiotic treatment. The two‐partner secretion (TPS) pathway, harboring both A (TpsA) and B‐components (TpsB), is the most commonly used gram‐negative virulence factor secretion system currently known. In fact, whooping cough, meningitis, UTIs, and certain food‐borne illnesses have been attributed to gram‐negative bacterial species containing the TPS system. Systematically, TpsA members are activated concomitant with TpsB‐dependent secretion across the outer membrane. Upon secretion, TpsA members elicit a variety of functions including cytolysis, adhesion, contact‐growth inhibition, and iron sequestration thus allowing the pathogen to invade and proliferate within the host, advantageously. Structurally, TpsA members can be divided into a TPS domain and a functional (virulent) domain. All TPS domains are constructed from a ~300‐residue right‐handed, parallel, β‐helix, and recognize their cognate TpsB membrane‐bound partner during secretion. Fundamentally, TpsA β‐helix structures are built from consecutive β‐circuits, where each β‐circuit is constructed from three parallel β‐strands. In order to further understand the relationship between complete TpsA β‐circuit establishment, structural stability and function we have implemented a truncated form of hemolysin A (HpmA265) from Proteus mirabilis. In previous studies, HpmA265 was structurally separated into three sequential folding subdomains: polar core, non‐polar core, and carboxy‐terminus. Structurally, the carboxy‐terminal subdomain harbors a partial, two‐stranded β‐circuit. Previous investigations replaced valine 158 (V158) and phenylalanine 215 (F215), as located within the first and last parallel β‐strands of the non‐polar core subdomain, with polar residues. The site‐selective alteration of V158 demonstrated increased function, while merging the unfolding transitions associated with the non‐polar and carboxy‐terminal subdomains. Alternatively, site‐selective alteration of F215 demonstrated decreased function, while destabilizing the transitions associated with both the non‐polar and carboxy‐terminal subdomains. Ultimately, template‐assisted activity has been interrelated to extent of β‐circuit structural destabilization within the carboxy‐terminal subdomain. Specifically, this research expands upon the previous V158 and F215 results by probing the structural and functional relationship via progressive amino‐acid extension to the HpmA265 carboxy‐terminal subdomain. Ultimately, the structural and functional effects of final β‐circuit completion will be ascertained using protein unfolding and hemolytic functional measurements.This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Site‐selective alterations within the hemolysin A non‐polar core

The secretion of virulence factors often aids bacterial pathogenesis. The two‐partner secretion (TPS) pathway, harboring both A (TpsA) and B‐components (TpsB), is the most commonly used gram‐negative virulence factor secretion system. In fact, whooping cough, meningitis, and certain food‐borne illnesses have been attributed to TPS pathway containing gram‐negative bacterial species. Systematically, TpsA members are activated concomitant with Tps‐dependent secretion across the outer membrane. Upon secretion, TpsA members elicit a variety of functions including cytolysis, adhesion, contact‐growth inhibition, and iron sequestration. Collectively, these TpsA functions provide advantageous invasion and proliferation strategies within host cells. Structurally, TpsA members can be divided into a two‐partner secretion (TPS) domain and a functional domain. All TPS domains are constructed from a 300‐residue right‐handed, parallel β‐helix structure, and recognize their cognate TpsB partner. In order to further understand the relationship between TPS domains and TpsA structure and function, we have implemented a truncated form of hemolysin A (HpmA265), a TpsA member from Proteus mirabilis. In previous studies, HpmA265 was structurally separated into three sequential folding subdomains: polar core, non‐polar core, and carboxy‐terminus. Specifically, these research investigations targeted valine 158 (V158) and phenylalanine 215 (F215) located within the first and last parallel β‐strands of the non‐polar core subdomain. A series of site‐selective variations were established at both V158 and F215. These variant forms of HpmA265 were characterized structurally via protease sensitivity and protein folding techniques, while functionality was ascertained within a template‐assisted hemolysis assay. Structurally, the V158 variants have destabilized the unfolding transitions associated with both the polar and non‐polar core subdomains, while leaving functionality unaffected. Site‐selective variants at F215 have selectively destabilized the non‐polar core subdomain, while leaving the unfolding transition attributed to the polar core subdomain unaffected. Additionally, the F215 variants do not affect template‐assisted hemolysis. Therefore, our results have been able to dissect the structural stability within the non‐polar core subdomain from template‐assisted function. These results have expanded the understanding for the implementation of TPS domains within gram‐negative bacteria.Support or Funding InformationFunding for this research was provided by: University Wisconsin – La Crosse Faculty Research Grant Program (TMW) and University Wisconsin – La Crosse Undergraduate Research and Creativity Grant Program (JDG).This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Repeat proteins challenge the concept of structural domains

Structural domains are believed to be modules within proteins that can fold and function independently. Some proteins show tandem repetitions of apparent modular structure that do not fold independently, but rather co-operate in stabilizing structural forms that comprise several repeat-units. For many natural repeat-proteins, it has been shown that weak energetic links between repeats lead to the breakdown of co-operativity and the appearance of folding sub-domains within an apparently regular repeat array. The quasi-1D architecture of repeat-proteins is crucial in detailing how the local energetic balances can modulate the folding dynamics of these proteins, which can be related to the physiological behaviour of these ubiquitous biological systems.

Dynamics of an ultrafast folding subdomain in the context of a larger protein fold.

Small fast folding subdomains with low contact order have been postulated to facilitate the folding of larger proteins. We have tested this idea by determining how the fastest folding linear β-hairpin, CLN025, which folds on the nanosecond time scale, folds within the context of a two-hairpin WW domain system, which folds on the microsecond time scale. The folding of the wild type FBP28 WW domain was compared to constructs in which each of the loops was replaced by CLN025. A combination of FTIR spectroscopy and laser-induced temperature-jump coupled with infrared spectroscopy was used to probe changes in the peptide backbone. The relaxation dynamics of the β-sheets and β-turn were measured independently by probing the corresponding bands assigned in the amide I region. The folding rate of the CLN025 β-hairpin is unchanged within the larger protein. Insertion of the β-hairpin into the second loop results in an overall stabilization of the WW domain and a relaxation lifetime five times faster than the parent WW domain. In both mutants, folding is initiated in the turns and the β-sheets form last. These results demonstrate that fast folding subdomains can be used to speed the folding of more complex proteins, and that the folding dynamics of the subdomain is unchanged within the context of the larger protein.

Structure of the HIV-1 gp41 Membrane-Proximal Ectodomain Region in a Putative Prefusion Conformation,

The conserved membrane-proximal external region (MPER) of the HIV-1 gp41 envelope protein is the established target for very rare but broadly neutralizing monoclonal antibodies (NAbs) elicited during natural human infection. Nevertheless, attempts to generate an HIV-1 neutralizing antibody response with immunogens bearing MPER epitopes have met with limited success. Here we show that the MPER peptide (residues 662-683) forms a labile alpha-helical trimer in aqueous solution and report the crystal structure of this autonomous folding subdomain stabilized by addition of a C-terminal isoleucine zipper motif. The structure reveals a parallel triple-stranded coiled coil in which the neutralization epitope residues are buried within the interface between the associating MPER helices. Accordingly, both the 2F5 and 4E10 NAbs recognize the isolated MPER peptide but fail to bind the trimeric MPER subdomain. We propose that the trimeric MPER structure represents the prefusion conformation of gp41, preceding the putative prehairpin intermediate and the postfusion trimer-of-hairpins structure. As such, the MPER trimer should inform the design of new HIV-1 immunogens to elicit broadly neutralizing antibodies.

Crystal Structure of a pH-Stabilized Mutant of Villin Headpiece

Villin-type headpiece domains are compact F-actin-binding motifs that have been used extensively as a model system to investigate protein folding by both experimental and computational methods. Villin headpiece (HP67) harbors a highly helical, thermostable, and autonomously folding subdomain in the C terminus (HP35), and because of this feature, HP67 is usually considered to be composed of a N- and C-terminal subdomain. Unlike the C-terminal subdomain, the N-terminal subdomain consists mainly of loops and turns, and the folding is dependent upon the presence of the C-terminal subdomain. The pH sensitivity of this subdomain is thought to arise from, at least partially, protonation of H41 buried in the hydrophobic core. Substitution of this histidine with tyrosine, another permissive residue at this position for naturally occurring sequences, increases not only the pH stability of HP67 but also the thermal stability and the cooperativity of thermal unfolding over a wide pH range (0.9-7.5). The crystal structures of wild-type HP67 and the H41Y mutant, determined under the same conditions, indicate that the H41Y substitution causes only localized rearrangement around the mutated residue. The F-actin-binding motif remains essentially the same after the mutation, accounting for the negligible effect of the mutation on F-actin affinity. The hydrogen bond formed between the imidazole ring of H41 and the backbone carbonyl of E14 of HP67 is eliminated by the H41Y mutation, which renders the extreme N terminus of H41Y more mobile; the hydrogen bond formed between the imidazole ring of H41 and the backbone nitrogen of D34 is replaced with that between the hydroxyl group of Y41 and the backbone nitrogen of D34 after the H41Y substitution. The increased hydrophobicity of tyrosine compensates for the loss of hydrogen bonds in the extreme N terminus and accounts for the increased stability and cooperativity of the H41Y mutant.

Cysteine-scanning analysis of the chemoreceptor-coupling domain of the Escherichia coli chemotaxis signaling kinase CheA.

The C-terminal P5 domain of the histidine kinase CheA is essential for coupling CheA autophosphorylation activity to chemoreceptor control through a binding interaction with the CheW protein. To locate P5 determinants critical for CheW binding and chemoreceptor control, we surveyed cysteine replacements at 39 residues predicted to be at or near the P5 surface in Escherichia coli CheA. Two-thirds of the Cys replacement proteins exhibited in vitro defects in CheW binding, either before or after modification with a bulky fluorescein group. The binding-defective sites were widely distributed on the P5 surface and were often interspersed with sites that caused no functional defects, implying that relatively minor structural perturbations, often far from the actual binding site, can influence its conformation or accessibility. The most likely CheW docking area included loop 2 in P5 folding subdomain 1. All but four of the binding-defective P5-Cys proteins were defective in receptor-mediated activation, suggesting that CheW binding, as measured in vitro, is necessary for assembly of ternary signaling complexes and/or subsequent CheA activation. Other Cys sites specifically affected receptor-mediated activation or deactivation of CheA, demonstrating that CheW binding is not sufficient for assembly and/or operation of receptor signaling complexes. Because P5 is quite similar to CheW, whose structure is known to be dynamic, we suggest that conformational flexibility and dynamic motions govern the signaling activities of the P5 domain. In addition, relative movements of the CheA domains may be involved in CheW binding, in ternary complex assembly, and in subsequent stimulus-induced conformational changes in receptor signaling complexes.

Folding subdomains of thioredoxin characterized by native-state hydrogen exchange.

Native-state hydrogen exchange (HX) studies, used in conjunction with NMR spectroscopy, have been carried out on Escherichia coli thioredoxin (Trx) for characterizing two folding subdomains of the protein. The backbone amide protons of only the slowest-exchanging 24 amino acid residues, of a total of 108 amino acid residues, could be followed at pH 7. The free energy of the opening event that results in an amide hydrogen exchanging with solvent (DeltaG(op)) was determined at each of the 24 amide hydrogen sites. The values of DeltaG(op) for the amide hydrogens belonging to residues in the helices alpha(1), alpha(2), and alpha(4) are consistent with them exchanging with the solvent only when the fully unfolded state is sampled transiently under native conditions. The denaturant-dependences of the values of DeltaG(op) provide very little evidence that the protein samples partially unfolded forms, lower in energy than the unfolded state. The amide hydrogens belonging to the residues in the beta strands, which form the core of the protein, appear to have higher values of DeltaG(op) than amide hydrogens belonging to residues in the helices, suggesting that they might be more stable to exchange. This apparently higher stability to HX of the beta strands might be either because they exchange out their amide hydrogens in a high energy intermediate preceding the globally unfolded state, or, more likely, because they form residual structure in the globally unfolded state. In either case, the central beta strands-beta(3,) beta(2), and beta(4)-would appear to form a cooperatively folding subunit of the protein. The native-state HX methodology has made it possible to characterize the free energy landscape that Trx can sample under equilibrium native conditions.

Local heterogeneity in the pressure denaturation of the coiled-coil tropomyosin because of subdomain folding units.

Coiled-coil domains mediate the oligomerization of many proteins. The assembly of long coiled coils, such as tropomyosin, presupposes the existence of intermediates. These intermediates are not well-known for tropomyosin. Hydrostatic pressure affects the equilibrium between denatured and native forms in the direction of the form that occupies a smaller volume. The hydrophobic core is the region more sensitive to pressure, which leads in most cases to the population of intermediates. Here, we used N-(1-pyrenyl)iodoacetamide covalently bound to cysteine residues of tropomyosin (PIATm) and high hydrostatic pressure to assess the chain interaction and the inherent instability of the coiled-coil molecule. The native and denatured states of tropomyosin were determined from the pyrene excimer fluorescence. The combination of low temperature and high pressure permitted the attainment of the full denaturation of tropomyosin without the separation of the subunits. High-temperature denaturation of Tm leads to a great exchange between labeled and unlabeled Tm subunits, indicating subunit dissociation linked to unfolding. In contrast, under high pressure, unlabeled and labeled tropomyosin molecules do not exchange, demonstrating that the denatured species are dimeric. The decrease of the concentration dependence of PIATm corroborates the idea that pressure produces subdomain denaturation and that the polypeptide chains do not separate. Substantial unfolding of tropomyosin was also verified by measurements of tyrosine fluorescence and bis-ANS binding. Our results indicate the presence of independent folding subdomains with different susceptibilities to pressure along the length of the coiled-coil structure of tropomyosin.

Differential stabilization of two hydrophobic cores in the transition state of the villin 14T folding reaction

We report the distribution of hydrophobic core contacts during the folding reaction transition state for villin 14T, a small 126-residue protein domain. The solution structure of villin 14T contains a central β-sheet with two flanking hydrophobic cores; transition states for this protein topology have not been previously studied. Villin 14T has no disulfide bonds or cis-proline residues in its native state; it folds reversibly, and in an apparently two-state manner under some conditions. To map the hydrophobic core contacts in the transition state, 27 point mutations were generated at positions spread throughout the two hydrophobic cores. After each point mutation, comparison of the change in folding kinetics with the equilibrium destabilization indicates whether the site of mutation is stabilized in the transition state. The results show that the folding nucleus, or the sub-region with the strongest transition state contacts, is located in one of the two hydrophobic cores (the predominantly aliphatic core). The other hydrophobic core, which is mostly aromatic, makes much weaker contacts in the transition state. This work is the first transition state mapping for a protein with multiple major hydrophobic cores in a single folding unit; the hydrophobic cores cannot be separated into individual folding subdomains. The stabilization of only one hydrophobic core in the transition state illustrates that hydrophobic core formation is not intrinsically capable of nucleating folding, but must also involve the right specific interactions or topological factors in order to be kinetically important.

The folding transition state between SH3 domains is conformationally restricted and evolutionarily conserved.

The protein engineering analysis of the alpha-spectrin SH3 domain at three different stability conditions (pH 7.0, 3.5 and 2.5) reveals a folding transition state structured around the distal loop beta-hairpin and the 310-helix. This region is impervious to overall changes in protein stability, suggesting a transition state ensemble with little conformational variability. Comparison with the Src SH3 domain (36% sequence homology) indicates that the transition state in this protein family may be conserved. Discrepancies at some positions can be rationalized in terms of the different interactions made by the different side chains in both domains. Brønsted plot analysis confirms the straight phi(doubledagger-U) results and shows two folding subdomains for this small protein. These results, together with previous data on circular permutants of the alpha-spectrin SH3 domain, indicate that polypeptide topology and chain connectivity play a major role in the folding reaction of this protein family.

Subdomain folding and biological activity of the core structure from human immunodeficiency virus type 1 gp41: implications for viral membrane fusion.

The envelope glycoprotein of human immunodeficiency virus type 1 (HIV-1) consists of two subunits, gp120 and gp41. The extraviral portion (ectodomain) of gp41 contains an alpha-helical domain that likely represents the core of the fusion-active conformation of the molecule. Here we report the identification and characterization of a minimal, autonomous folding subdomain that retains key determinants in specifying the overall fold of the gp41 ectodomain core. This subdomain, designated N34(L6)C28, is formed by covalent attachment of peptides N-34 and C-28 by a short flexible linker in place of the normal disulfide-bonded loop sequence. N34(L6)C28 forms a highly thermostable, alpha-helical trimer. Point mutations within the envelope protein complex that abolish membrane fusion and HIV-1 infectivity also impede the formation of the N34(L6)C28 core. Moreover, N34(L6)C28 is capable of inhibiting HIV-1 envelope-mediated membrane fusion. Taken together, these results indicate that the N34(L6)C28 core plays a direct role in the membrane fusion step of HIV-1 infection and thus provides a molecular target for the development of antiviral pharmaceutical agents.

New enzyme lineages by subdomain shuffling.

Protein functions have evolved in part via domain recombination events. Such events, for example, recombine structurally independent functional domains and shuffle targeting, regulatory, and/or catalytic functions. Domain recombination, however, can generate new functions, as implied by the observation of catalytic sites at interfaces of distinct folding domains. If useful to an evolving organism, such initially rudimentary functions would likely acquire greater efficiency and diversity, whereas the initially distinct folding domains would likely develop into single functional domains. This represents the probable evolution of the S1 serine protease family, whose two homologous beta-barrel subdomains assemble to form the binding sites and the catalytic machinery. Among S1 family members, the contact interface and catalytic residues are highly conserved whereas surrounding surfaces are highly variable. This observation suggests a new strategy to engineer viable proteins with novel properties, by swapping folding subdomains chosen from among protein family members. Such hybrid proteins would retain properties conserved throughout the family, including folding stability as single domain proteins, while providing new surfaces amenable to directed evolution or engineering of specific new properties. We show here that recombining the N-terminal subdomain from coagulation factor X with the C-terminal subdomain from trypsin creates a potent enzyme (fXYa) with novel properties, in particular a broad substrate specificity. As shown by the 2.15-A crystal structure, plasticity at the hydrophobic subdomain interface maintains activity, while surface loops are displaced compared with the parent subdomains. fXYa thus represents a new serine proteinase lineage with hybrid fX, trypsin, and novel properties.

Amide hydrogen exchange and internal dynamics the chemotactic protein CheY from Escherichia coli

The backbone internal dynamics of the wild-type 129 amino acid α/β parallel protein CheY and its double mutant F14N/P110G are analysed here by the hydrogen-exchange method. The F14N mutation is known to stabilise the protein and to accelerate refolding while P110G is destabilising and accelerates unfolding. We first assigned and characterised the double mutant by nuclear magnetic resonance (NMR), to try and discover any possible conformational change induced by the two mutations. The main difference between the two proteins is a favourable N-capping interaction of the newly introduced Asn14 side-chain at the beginning of the first α-helix (α-helix A). Second, we have measured the exchange rates in the wild-type and mutant CheY. In the first case the observed protection factors are slightly dispersed around an average value. According to their distribution in the structure, protein stability is highest on one face of the central β-sheet, in the surroundings of the main hydrophobic core formed by side-chains of residues in β-strands I, II and III and helices A and E. The mutations in the double mutant protein affect two distinct subdomains differently (from β-strand I to III and from α-helix C to the end). In the second subdomain the number of protected protons is reduced with respect to those in the wild-type. This differential behaviour can be explained by a selective decrease in stability of the second folding subdomain produced by the P110G mutation and the opposite effect in the first subdomain, produced by the F14N mutation. α-Helix A, which is involved together with β-strands I and III in the folding nucleus of CheY, shows the largest protection factors in both proteins.

Characterization of “native” apomyoglobin by molecular dynamics simulation

We have used molecular dynamics simulation methods to study the structure and fluctuations of “native” apomyoglobin in aqueous solution for a period of greater than 0.5 nanosecond. This work was motivated by the recent attempts of Hughson et al. to characterize the structure and motion of both this molecule and the less compact, acid stabilized I state, using methods of pulsed H 2 H exchange. The study of these systems provides new insights into protein folding intermediates and our simulation has yielded a detailed model for structure and fluctuations in apomyoglobin which complements the experimental studies. We find that local (short-time) fluctuations agree well with fluctuations observed for the holoprotein in aqueous solution, as well as results from the crystallographic B-factors. In addition, the structural features we observe for native apomyoglobin are very similar to the holoprotein, in basic agreement with the findings of Hughson et al. By examining larger-scale motions, developing only over timescales in excess of a 100 picoseconds, we are able to identify conformationally “labile” and “non-labile” regions within native apomyoglobin. These regions correspond extremely well to those identified in the nuclear magnetic resonance experiments as unstable and stable “'folding subdomains” in the I state of apomyoglobin. Overall we find that helices A, B, E, G and H show the least amount of motion and helices C, D and F move substantially over the timescales examined. The major motions, and the primary difference between the holo and apo structures as we have observed them, are due to the shifting motion of helices C, D and F into the vacant heme cavity. We also find that motions at the interface of helical segments can be large, with one important exception being the chain segment connecting helices G and H. This segment of chain interacts with the conformationally “non-labile” helix A to form a relatively rigid subdomain composed of helices A, G and H. We believe that these findings provide direct support for the suggestion of Hughson et al. that helices A, G and H constitute a compact subdomain that remains in a native-like conformation as the protein begins to unfold in environments of decreasing pH.