Tertiary Structure Formation Research Articles

Molecular dynamics simulations of the minor ampullate spidroin modular amino acid sequence from Parawixia bistriatra: insights into silk tertiary structure and fibre formation

Spider fibres are primarily composed of proteins that are secreted by specialised glands found in different groups of arthropods. Because of their unique mechanical characteristics, it is of great interest to understand how the influence of repetitive modules within the fibres affects the final protein structure. Because each fibre is composed of a diverse set of repeated modular sequences, the differences between fibres allow for their structural comparison and, thereby, their functional comparison. Herein, we present molecular dynamics simulations of partial sequences from minor ampullate Spidroin (MiSp) silk of the Brazilian species Parawixia bistriata. Our data show that the formation of β-sheet structures is directly related to the N-termini alignment of the modules. The N-terminal alignment gives rise to a high number of hydrogen bonds whose formation is driven by repeated alanine (Ala) sequences, which, in turn, lead to increased fibre strength. This increased fibre strength contributes significantly to the final tertiary structure of the silk.

Extracellular Allosteric Regulatory Subdomain within the γ Subunit of the Epithelial Na+ Channel

The activity of the epithelial Na(+) channel (ENaC) is modulated by Na(+) self-inhibition, a down-regulation of the open probability of ENaC by extracellular Na(+). A His residue within the extracellular domain of gammaENaC (gammaHis(239)) was found to have a critical role in Na(+) self-inhibition. We investigated the functional roles of residues in the vicinity of this His by mutagenesis and analyses of Na(+) self-inhibition responses in Xenopus oocytes. Significant changes in the speed and magnitude of Na(+) self-inhibition were observed in 16 of the 47 mutants analyzed. These 16 mutants were distributed within a 22-residue tract. We further characterized this scanned region by examining the accessibility of introduced Cys residues to the sulfhydryl reagent MTSET. External MTSET irreversibly increased or decreased currents in 13 of 47 mutants. The distribution patterns of the residues where substitutions significantly altered Na(+) self-inhibition or/and conferred sensitivity to MTSET were consistent with the existence of two helices within this region. In addition, single channel recordings of the gammaH239F mutant showed that, in the absence of Na(+) self-inhibition and with an increased open probability, ENaCs still undergo transitions between open and closed states. We conclude that gammaHis(239) functions within an extracellular allosteric regulatory subdomain of the gamma subunit that has an important role in conferring the response of the channel to external Na(+).

Multistage collapse of a bacterial ribozyme observed by time-resolved small-angle X-ray scattering.

Ribozymes must fold into compact, native structures to function properly in the cell. The first step in forming the RNA tertiary structure is the neutralization of the phosphate charge by cations, followed by collapse of the unfolded molecules into more compact structures. The specificity of the collapse transition determines the structures of the folding intermediates and the folding time to the native state. However, the forces that enable specific collapse in RNA are not understood. Using time-resolved SAXS, we report that upon addition of 5 mM Mg(2+) to the Azoarcus group I ribozyme up to 80% of chains form compact structures in less than 1 ms. In 1 mM Mg(2+), the collapse transition produces extended structures that slowly approach the folded state, while > or = 1.5 mM Mg(2+) leads to an ensemble of random coils that fold with multistage kinetics. Increased flexibility of molecules in the intermediate ensemble correlates with a Mg(2+)-dependent increase in the fast folding population and a previously unobserved crossover in the collapse kinetics. Partial denaturation of the unfolded RNA with urea also increases the fraction of chains following the fast-folding pathway. These results demonstrate that the preferred collapse mechanism depends on the extent of Mg(2+)-dependent charge neutralization and that non-native interactions within the unfolded ensemble contribute to the heterogeneity of the ribozyme folding pathways at the very earliest stages of tertiary structure formation.

Thermodynamic stability of polypeptides folding within modeled ribosomal exit tunnel: A density functional study

The mechanism of polypeptide folding, especially for the formation of tertiary structures, within the ribosomal exit tunnel, remains one of the most important unsolved problems in biophysical chemistry and molecular biology. In this work, we use a density functional theory (DFT) to explore the polypeptide folding within a modified nanopore, which mimics the confined environment of ribosomal exit tunnel. Results indicate that too long polypeptides (N>100 cannot fold into a helix state within the nanopore, and the helix polypeptides favor folding into a negative coiled coil rather than a positive one, because the negative coiled coil has a lower grand potential than the positive one, and the polypeptide folding into the negative coiled coil therefore needs less driving force than the positive one. To fold into the positive coiled coil, the helix polypeptides must have a small minor radius or a short chain length, which provides helpful insights into the design of nanodevices for manipulating the positive coiled coil. In the presence of attractive interaction, helices need more driving force to fold into coiled coil. Importantly, we have also proposed a scaling relation to understand the folding behavior. The scaling relation gives a good estimate for the computational results, and provides a reasonable explanation for the folding behavior. In summary, it is expected that the proposed DFT approach and the scaling relation provide alternative means for the investigation of polypeptide folding in confined environment, and these impressive results could give useful insights into nascent polypeptide folding.

Protein structure prediction enhanced with evolutionary diversity: SPEED

For naturally occurring proteins, similar sequence implies similar structure. Consequently, multiple sequence alignments (MSAs) often are used in template-based modeling of protein structure and have been incorporated into fragment-based assembly methods. Our previous homology-free structure prediction study introduced an algorithm that mimics the folding pathway by coupling the formation of secondary and tertiary structure. Moves in the Monte Carlo procedure involve only a change in a single pair of phi,psi backbone dihedral angles that are obtained from a Protein Data Bank-based distribution appropriate for each amino acid, conditional on the type and conformation of the flanking residues. We improve this method by using MSAs to enrich the sampling distribution, but in a manner that does not require structural knowledge of any protein sequence (i.e., not homologous fragment insertion). In combination with other tools, including clustering and refinement, the accuracies of the predicted secondary and tertiary structures are substantially improved and a global and position-resolved measure of confidence is introduced for the accuracy of the predictions. Performance of the method in the Critical Assessment of Structure Prediction (CASP8) is discussed.

Nonlocal Interactions Are Responsible for Tertiary Structure Formation in Staphylococcal Nuclease

Rapid molecular collapse mediated by nonlocal interactions is believed to be a crucial event for protein folding. To investigate the role of nonlocal interactions in tertiary structure formation, we performed a nonlocal interaction substitution mutation analysis on staphylococcal nuclease (SNase). Y54 and I139 of wild-type (WT) SNase and Δ140-149 were substituted by cysteine to form intramolecular disulfide bonds, respectively called WT-SS and Δ140-149-SS. Under physiological conditions, the reduced form of Δ140-149-SS appears to assume a denatured structure; in contrast, the oxidized form of Δ140-149-SS forms a native-like structure. From this result, we conclude that the C-terminal region participates in a nonlocal interaction that is indispensable for the native structure. Although the oxidized form of WT-SS assumes a more compact denatured structure under acidic conditions than the WT, the kinetic measurements reveal that the refolding reactions of both the reduced and oxidized forms of WT-SS are similar to those of the WT, suggesting that an intact nonlocal interaction is established within the dead time (22 ms). On the basis of these results, we propose that the native nonlocal contact established at the early stage of the folding process facilitates further secondary structure formation.

2,2,2-Trifluroethanol induces simultaneous increase in α-helicity and aggregation in alkaline unfolded state of bovine serum albumin

Little work has been done to understand the folding of proteins at alkaline conditions. BSA acquires a partially reversible unfolded state at pH 13.0, devoid of any native structure. Introduction of methanol, ethanol and 2-propanol with the alkaline unfolded protein resulted in β-sheet-like structure formation, and 2,2,2-trifluroethanol found to enhance α-helical conformations with simultaneous increase in aggregation. The extent of secondary and tertiary structure formation is in the order of methanol < ethanol < 2-propanol < 2,2,2-trifluroethanol. Exposure of hydrophobic core of protein molecules in apolar environment of 2,2,2-trifluroethanol seems to promote intermolecular cluster formation. This is one of the very few reports that α-helical structures can also aggregate.

SecB—A chaperone dedicated to protein translocation

SecB is a molecular chaperone in Gram-negative bacteria dedicated to the post-translational translocation of proteins across the cytoplasmic membrane. The entire surface of this chaperone is used for both of its native functions in protein targeting and unfolding. Single molecule studies revealed how SecB affects the folding pathway of proteins and how it prevents the tertiary structure formation and aggregation to support protein translocation.

Site-Specific Phosphorylation Induces Functionally Active Conformation in the Intrinsically Disordered N-Terminal Activation Function (AF1) Domain of the Glucocorticoid Receptor

Intrinsically disordered (ID) regions are disproportionately higher in cell signaling proteins and are predicted to have much larger frequency of phosphorylation sites than ordered regions, suggesting an important role in their regulatory capacity. In this study, we show that AF1, an ID activation domain of the glucocorticoid receptor (GR), adopts a functionally folded conformation due to its site-specific phosphorylation by p38 mitogen-activated protein kinase, which is involved in apoptotic and gene-inductive events initiated by the GR. Further, we show that site-specific phosphorylation-induced secondary and tertiary structure formation specifically facilitates AF1's interaction with critical coregulatory proteins and subsequently its transcriptional activity. These data demonstrate a mechanism through which ID activation domain of the steroid receptors and other similar transcription factors may adopt a functionally active conformation under physiological conditions.

1P078 SNaseの構造形成に関わる非局所相互作用をもたらすC末端領域の探索(蛋白質-物性(安定性,折れたたみなど),第48回日本生物物理学会年会)

1P078 SNaseの構造形成に関わる非局所相互作用をもたらすC末端領域の探索(蛋白質-物性(安定性,折れたたみなど),第48回日本生物物理学会年会)

Thermodynamic analysis of ligand binding and ligand binding-induced tertiary structure formation by the thiamine pyrophosphate riboswitch.

The thi-box riboswitch regulates gene expression in response to the intracellular concentration of thiamine pyrophosphate (TPP) in archaea, bacteria, and eukarya. To complement previous biochemical, genetic, and structural studies of this phylogenetically widespread RNA domain, we have characterized its interaction with TPP by isothermal titration calorimetry. This shows that TPP binding is highly dependent on Mg(2+) concentration. The dissociation constant decreases from approximately 200 nM at 0.5 mM Mg(2+) concentration to approximately 9 nM at 2.5 mM Mg(2+) concentration. Binding is enthalpically driven, but the unfavorable entropy of binding decreases as Mg(2+) concentration rises, suggesting that divalent cations serve to pre-organize the RNA. Mutagenesis, biochemical analysis, and a new crystal structure of the riboswitch suggest that a critical element that participates in organizing the riboswitch structure is the tertiary interaction formed between the P3 and L5 regions. This tertiary contact is distant from the TPP binding site, but calorimetric analysis reveals that even subtle mutations in L5 can have readily detectable effects on TPP binding. The thermodynamic signatures of these mutations, namely decreased favorable enthalpy of binding and small effects on entropy of binding, are consistent with the P3-L5 association contributing allosterically to TPP-induced compaction of the RNA.

Do conformational biases of simple helical junctions influence RNA folding stability and specificity?

Structured RNAs must fold into their native structures and discriminate against a large number of alternative ones, an especially difficult task given the limited information content of RNA's nucleotide alphabet. The simplest motifs within structured RNAs are two helices joined by nonhelical junctions. To uncover the fundamental behavior of these motifs and to elucidate the underlying physical forces and challenges faced by structured RNAs, we computationally and experimentally studied a tethered duplex model system composed of two helices joined by flexible single- or double-stranded polyethylene glycol tethers, whose lengths correspond to those typically observed in junctions from structured RNAs. To dissect the thermodynamic properties of these simple motifs, we computationally probed how junction topology, electrostatics, and tertiary contact location influenced folding stability. Small-angle X-ray scattering was used to assess our predictions. Single- or double-stranded junctions, independent of sequence, greatly reduce the space of allowed helical conformations and influencing the preferred location and orientation of their adjoining helices. A double-stranded junction guides the helices along a hinge-like pathway. In contrast, a single-stranded junction samples a broader set of conformations and has different preferences than the double-stranded junction. In turn, these preferences determine the stability and distinct specificities of tertiary structure formation. These sequence-independent effects suggest that properties as simple as a junction's topology can generally define the accessible conformational space, thereby stabilizing desired structures and assisting in discriminating against misfolded structures. Thus, junction topology provides a fundamental strategy for transcending the limitations imposed by the low information content of RNA primary sequence.

The Unfolding of the Prion Protein Sheds Light on the Mechanisms of Prion Susceptibility and Species Barrier

Prion diseases are a group of fatal neurodegenerative disorders that manifest as infectious, sporadic, or familial and are all associated with the misfolding of the prion protein (PrP). Disease-modulating polymorphisms in the PrP amino acid sequence can make an individual more or less susceptible to infection. One example is the presence of arginine in place of glutamine at position 171 in sheep, which confers resistance to scrapie. To investigate whether the physical folding properties of PrP are influenced by the presence of arginine at codon 171, we have introduced the mutation at the equivalent position (codon 167) in recombinant mouse PrP. We have then compared the unfolding properties of wild-type PrP and the Q167R mutant by monitoring the fluorescence and circular dichroism of folding-sensitive tryptophan mutants. For both wild-type PrP and the Q167R mutant the formation of secondary structure and tertiary structure is concurrent, which indicates that unfolding proceeds without the accumulation of an equilibrium intermediate. The major effect of the mutation is the destabilization of the protein as shown by the shift of the unfolding transition, which can be rationalized from high-resolution structures of PrP. Comparison of the unfolding pathways of mouse and hamster PrP highlights dramatic differences in the mechanisms of folding, which may contribute to the species barrier effect that is observed in the transmission of prion disease.

Multiple Metal-Binding Cores Are Required for Metalloregulation by M-box Riboswitch RNAs

Riboswitches are regulatory RNAs that control downstream gene expression in response to direct association with intracellular metabolites or metals. Typically, riboswitch aptamer domains bind to a single small-molecule metabolite. In contrast, an X-ray crystallographic structural model for the M-box riboswitch aptamer revealed the absence of an organic metabolite ligand but the presence of at least six tightly associated magnesiums. This observation agrees well with the proposed role of the M-box riboswitch in functioning as a sensor of intracellular magnesium, although additional nonspecific metal interactions are also undoubtedly required for these purposes. To gain greater functional insight into the metalloregulatory capabilities of M-box RNAs, we sought to determine whether all or a subset of the RNA-chelated magnesium ions were required for riboswitch function. To accomplish this task, each magnesium-binding site was simultaneously yet individually perturbed through random incorporation of phosphorothioate nucleotide analogues, and RNA molecules were investigated for their ability to fold in varying levels of magnesium. These data revealed that all of the magnesium ions observed in the structural model are important for magnesium-dependent tertiary structure formation. Additionally, these functional data revealed a new core of potential metal-binding sites that are likely to assist formation of key tertiary interactions and were previously unobserved in the structural model. It is clear from these data that M-box RNAs require specific binding of a network of metal ions for partial fulfillment of their metalloregulatory functions.

A Rate-Limiting Conformational Step in the Catalytic Pathway of the glmS Ribozyme

The glmS ribozyme is a conserved riboswitch in numerous Gram-positive bacteria and is located upstream of the glucosamine-6-phosphate (GlcN6P) synthetase reading frame. Binding of GlcN6P activates site-specific self-cleavage of the glmS mRNA, resulting in the downregulation of glmS gene expression. Unlike other riboswitches, the glmS ribozyme does not undergo structural rearrangement upon metabolite binding, indicating that the metabolite binding pocket is preformed in the absence of ligand. This observation led us to test if individual steps in the reaction pathway could be dissected by initiating the cleavage reaction before or after Mg(2+)-dependent folding. Here we show that self-cleavage reactions initiated with simultaneous addition of Mg(2+) and GlcN6P are slow (3 min(-1)) compared to reactions initiated by addition of GlcN6P to glmS RNA that has been prefolded in Mg(2+)-containing buffer (72 min(-1)). These data indicate that some level of Mg(2+)-dependent folding is rate-limiting for catalysis. Reactions initiated by addition of GlcN6P to the prefolded ribozyme also resulted in a 30-fold increase in the apparent ligand K(d) compared to those of reactions initiated by a global folding step. Time-resolved hydroxyl-radical footprinting was employed to determine if global tertiary structure formation is the rate-limiting step. The results of these experiments provided evidence for fast and largely concerted folding of the global tertiary structure (>13 min(-1)). This indicates that the rate-limiting step that we have identified either is a slow folding step between the fast initial folding and ligand binding events or represents the rate of escape from a nativelike folding trap.

Dynamic folding pathway models of the villin headpiece subdomain (HP‐36) structure

We have investigated the folding pathway of the 36-residue villin headpiece subdomain (HP-36) by action-derived molecular dynamics simulations. The folding is initiated by hydrophobic collapse, after which the concurrent formation of full tertiary structure and alpha-helical secondary structure is observed. The collapse is observed to be associated with a couple of specific native contacts contrary to the conventional nonspecific hydrophobic collapse model. Stable secondary structure formation after the collapse suggests that the folding of HP-36 follows neither the framework model nor the diffusion-collision model. The C-terminal helix forms first, followed by the N-terminal helix positioned in its native orientation. The short middle helix is shown to form last. Signs for multiple folding pathways are also observed.

The role of disulfide bond formation in the conformational folding kinetics of denatured/reduced lysozyme

Oxidative folding is of vital importance for producing therapeutic proteins in bacteria via recombinant DNA technology since disulfide bonds exist in most pharmaceutical proteins. Although oxidative protein folding has been extensively investigated in vitro, little is explored concerning the role of disulfide formation to protein conformational folding rate. The effects of oxidized (GSSG)/reduced (GSH) glutathione and pH on the conformational folding kinetics of denatured/reduced lysozyme have been studied herein by fluorescence and circular dichroism. It is found that 83% tryptophan residue burial requires disulfide formation, and increasing GSSG concentration greatly accelerates the tertiary structure formation. The fast phase folding rate constant ( k 1) is linearly related to GSSG concentration, indicating the rate-limiting role of mixed-disulfide formation. Moreover, k 1 = 0.006(±0.001) s −1 is likely to be a critical value for judging the determinant of the slow phase folding rate ( k 2), namely, k 2 is controlled by disulfide formation rate only at k 1 < 0.006 s −1. These findings have elucidated the determinants of different folding stages and thus may be beneficial for more efficient control of the oxidative folding of proteins.

Motions of the substrate recognition duplex in a group I intron assessed by site-directed spin labeling.

The Tetrahymena group I intron recognizes its oligonucleotide substrate in a two-step process. First, a substrate recognition duplex, called the P1 duplex, is formed. The P1 duplex then docks into the prefolded ribozyme core by forming tertiary contacts. P1 docking controls both the rate and the fidelity of substrate cleavage and has been extensively studied as a model for the formation of RNA tertiary structure. However, previous work has been limited to studying millisecond or slower motions. Here we investigated nanosecond P1 motions in the context of the ribozyme using site-directed spin labeling (SDSL) and electron paramagnetic resonance (EPR) spectroscopy. A nitroxide spin label (R5a) was covalently attached to a specific site of the substrate oligonucleotide, the labeled substrate was bound to a prefolded ribozyme to form the P1 duplex, and X-band EPR spectroscopy was used to monitor nitroxide motions in the 0.1-50 ns regime. Using substrates that favor the docked or the undocked states, it was established that R5a was capable of reporting P1 duplex motions. Using R5a-labeled substrates it was found that the J1/2 junction connecting P1 to the ribozyme core controls nanosecond P1 mobility in the undocked state. This may account for previous observations that J1/2 mutations weaken substrate binding and give rise to cryptic cleavage. This study establishes the use of SDSL to probe nanosecond dynamic behaviors of individual helices within large RNA and RNA/protein complexes. This approach may help in understanding the relationship between RNA structure, dynamics, and function.

Dynamics of Intra- and Inter-Helix Contact Formation

The ubiquitous nature of the helical fold and its characteristic physical properties make it one of the first candidates for studies of secondary structure formation in polypeptides, and the thermodynamics of helix formation is a common topic in many classical biophysics textbooks. However, though there is general agreement on the features of the equilibrium properties of the coil-to-helix transition, both experimental and theoretical studies have provided widely varying estimates of helix formation rates from tens of picoseconds to microseconds. We present results of recent molecular simulations of several helix-forming peptides that permit the quantitative study of both intra- and inter-helical contacts in polypeptides. This analysis of local, site-specific formation of intra- and inter-chain interactions is necessary for any quantitative modeling of the elementary steps of secondary and tertiary structure formation in protein folding, and it allows direct comparison to data from recent infrared vibrational spectroscopy studies.

Designable DNA Functions toward New Nanobiotechnology

Abstract DNA has many properties that cannot be attained with other molecules. The ability of DNA to form base pairing and its structural polymorphism allow the formation of distinct secondary and tertiary structures and may have further catalytic or aptamer function. It is also of great advantage that the base pairing of a short oligonucleotide sequence can be well predicted and designed with the thermodynamic parameters of Watson–Crick base pairs, mismatch pairs, and noncanonical base pairs based on the nearest-neighbor model. We have investigated the thermodynamics of various types of oligonucleotide structures, and obtained the nearest-neighbor parameters for Watson–Crick base pair formations and fundamental information regarding the nucleotide interactions. The data of the DNA interaction energy were also applied for molecular design of a DNA logic gate and DNA nanowire. I will further discuss the importance of quantitative data of DNA interaction energy toward the rational design of artificial DNAs carried out by our laboratory, such as base pair-mimic nucleosides and DNA containing bipyridine units, useful as nanobiodevices and nanobiomaterial.