The functional and immunological significance of some schistosome surface molecules

The molecules discussed in this review include some of the leading vaccine candidates in schistosomiasis: the glutathione S-transferases, triose-phosphate isomerase, glyceraldehyde-3-phosphate dehydrogenase and the 23 and 25 kDa surface integral membrane proteins. Mark Wright, Kathy Davem and Graham Mitchell highlight the possible biological roles and immunological relevance of these molecules.     

Conformational analysis of some phenethylamine molecules

A set of empirical potential functions (EPF), previously used in conformational energy calculations of polymers, was employed in the study of the conformational properties of a number of methyl-substituted phenethylmines, as well as phenylmethylamine, phenyl-n-propylamine, and 3,4,5-trimethoxyamphetamine. The conformational free energy was computed for each of these molecular species in four states: neutral charge-vacuo (I), neutral charge-aqueous solution (II), positive charge-vacuo (III), positive charge-aqueous solution (IV). The molecules generally adopt one of two stable conformations: a folded conformation with the amine chain perpendicular to the ring, and the amine group nearest to the ring; and an extended conformation with the amine chain perpendicular to the ring, and the amine group far from the ring. The folded conformation is usually preferred for states I, II and III, while the extended form is adopted for state IV. By using empirical potential functions it was also possible to calculate the conformational entropies associated with the minimum energy conformations, thereby allowing the Boltzmann probabilities to be determined. These probabilities are a measure of the population density of each of the various low energy regions. Some of the molecules studied have a steric “bulge” below the plane of the benzene ring. All of the compounds studied which possess this “bulge” are psychotropically inactive, and, in most cases, also pharmacologically inactive. All active compounds studied do not possess this “bulge”.     

Conformational flexibility in the multidrug efflux system protein AcrA

Intrinsic resistance to multiple drugs in many gram-negative bacterial pathogens is conferred by resistance nodulation cell division efflux pumps, which are composed of three essential components as typified by the extensively characterized Escherichia coli AcrA-AcrB-TolC system. The inner membrane drug:proton antiporter AcrB and the outer membrane channel TolC export chemically diverse compounds out of the bacterial cell, and require the activity of the third component, the periplasmic protein AcrA. The crystal structures of AcrB and TolC have previously been determined, and we complete the molecular picture of the efflux system by presenting the structure of a stable fragment of AcrA. The AcrA fragment resembles the elongated sickle shape of its homolog Pseudomonas aeruginosa MexA, being composed of three domains: beta-barrel, lipoyl, and alpha-helical hairpin. Notably, unsuspected conformational flexibility in the alpha-helical hairpin domain of AcrA is observed, which has potential mechanistic significance in coupling between AcrA conformations and TolC channel opening.     

Conformational flexibility of the furanose ring in DNA and its dipole moment

The influence of conformational rearrangement of the furanose ring in DNA on its dipole moment is studied. The dipole moment of the deoxyribose molecule as a function of its puckered state is calculated by the quantum-mechanical method using the MINDO/3 approximation. The values of the dipole moment and its components are obtained at various magnitudes of the pseudorotation phase angle. The C3'-endo in equilibrium C2'-endo conformational transition of deoxyribose is shown to be accompanied by the change in the dipole moment up to 3D. The results obtained are used to explain the structural properties of the DNA hydration shell.     

Conformational flexibility of alpha-lactalbumin related to its membrane binding capacity

Different folding states of the small, globular milk protein bovine alpha-lactalbumin (BLA) induced by the anionic surfactant sodium dodecylsulphate (SDS) have been examined by fluorescence spectroscopy, CD and NMR. The solution structure of the protein in the absence of SDS was also determined, indicating fluidity even under native conditions. BLA is partly denatured to a molten globule (MG)-like state by micromolar concentrations of SDS, and the transitions from native to MG-like state are dependent on pH, the protein being more sensitive to the surfactant at pH 6.5. As indicated by measurements of the intrinsic emission fluorescence, the tertiary structure disappears at lower concentrations of SDS than most of the secondary structure, as estimated from CD data. The MG-like state induced by low concentrations of SDS is not observable by NMR, and is probably fluctuating and/or aggregating. At higher concentrations of SDS above the critic concentration of micelles, an NMR-observable state reappears. This micelle-associated conformer was partially assigned, and found to bear strong resemblance to the acid-tri-fluoroethanol state, retaining weakened versions of the A and C helix of native BLA. We discuss the results in terms of the inherent flexibility of the protein, and its ability to form multiple folding states and to bind to membranes. Also, we propose that proteins with stable MG-like conformers can have these states stabilized by low levels of compounds with surfactant properties in vivo.     

Conformational flexibility and structural variability of SARS-CoV2 S protein

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Conformational flexibility of a model protein upon immobilization on self-assembled monolayers

The present study reports on the retention of conformational flexibility of a model allosteric protein upon immobilization on self-assembled monolayers (SAMs) on gold. Organothiolated SAMs of different compositions were utilized for adsorptive and covalent attachment of bovine liver glutamate dehydrogenase (GDH), a well-characterized allosteric enzyme. Sensitive fluorimetric assays were developed to determine immobilization capacity, specific activity, and allosteric properties of the immobilized preparations as well as the potential for repeated use and continuous catalytic transformations. The allosteric response of the free and immobilized forms towards ADP, L-leucine and high concentrations of NAD(+), some of the well-known activators for this enzyme, were determined and compared. The enzyme immobilized by adsorption or chemical binding responded similarly to the activators with a greater degree of activation, as compared to the free form. Also loss of activity involving the two immobilization procedures were similar, suggesting that residues essential for catalytic activity or allosteric properties of GDH remained unchanged in the course of chemical modification. A recently established method was used to predict GDH orientation upon immobilization, which was found to explain some of the experimental results presented. The general significance of these observations in connection with retention of native properties of protein structures upon immobilization on SAMs is discussed.     

Conformational flexibility of the hormonal peptide bombesin and its interaction with lipids

The conformational flexibility of the tetradecapeptide hormone bombesin has been studied using circular dichroism and fluorescence of its single tryptophan residue. The spectral changes observed indicate that the peptide changed from a random flexible coil in solution to a helical structure in lysolecithin micelles and dimyristoylphosphatidylserine vesicles. The tryptophan residue in the lipid complexes was located in a hydrophobic environment. The interaction with lipids was shown to involve both hydrophobic and electrostatic forces.     

Variation in foot size and shape in some British land snails and its functional significance

Live weight, and the length, breadth and surface area of the extended foot sole were measured in 24 species of British terrestrial snails. Allometric relationships between these variables are described, concentrating on the relationship between foot surface area and weight. Intraspecific foot area/weight relationships deviate from isometric expectation for several species; this may be attributed to density changes, foot-shape variation or the physical constraint imposed by shell aperture size.
The rate of increase of foot sole area with live weight among species is greater than expected under isometry, indicating that larger species partially compensate for the increase in foot loading (weight per unit foot area). The rate of whorl expansion of the shell is related to the deviations from the interspecific foot area/weight relationship, reinforcing the possibility that shell aperture area may limit foot size in some species. Foot ratio (foot length:foot width) is negatively related to live weight and foot loading.
The findings are discussed in relation to the known behaviour and microdistribution patterns of the species.     

Conformational flexibility of the leucine binding protein examined by protein domain coarse-grained molecular dynamics

Periplasmic binding proteins are the initial receptors for the transport of various substrates over the inner membrane of gram-negative bacteria. The binding proteins are composed of two domains, and the substrate is entrapped between these domains. For several of the binding proteins it has been established that a closed-up conformation exists even without substrate present, suggesting a highly flexible apo-structure which would compete with the ligand-bound protein for the transporter interaction. For the leucine binding protein (LBP), structures of both open and closed conformations are known, but no closed-up structure without substrate has been reported. Here we present molecular dynamics simulations exploring the conformational flexibility of LBP. Coarse grained models based on the MARTINI force field are used to access the microsecond timescale. We show that a standard MARTINI model cannot maintain the structural stability of the protein whereas the ELNEDIN extension to MARTINI enables simulations showing a stable protein structure and nanosecond dynamics comparable to atomistic simulations, but does not allow the simulation of conformational flexibility. A modification to the MARTINI-ELNEDIN setup, referred to as domELNEDIN, is therefore presented. The domELNEDIN setup allows the protein domains to move independently and thus allows for the simulation of conformational changes. Microsecond domELNEDIN simulations starting from either the open or the closed conformations consistently show that also for LBP, the apo-structure is flexible and can exist in a closed form.

Conformational flexibility and kinetic complexity in antibody-antigen interactions

The kinetics of dissociation of three structurally characterized anti-hen egg white lysozyme antibodies (H8, H10, and H26), with hen egg white lysozyme (HEL) and the avian variant Japanese quail lysozyme (JQL) were examined. These antibodies share over 90% sequence identity and recognize the same epitope, but differ in their degree of cross-reactivity and predicted combining site rigidity. Competitive dissociation induced by the addition of excess unlabeled HEL after varied periods of antibody-antigen association was followed in real time using fluorescence anisotropy. Dissociation was in many cases non-single-exponential, and the observed off-rates became slower as the complex age increased, suggesting multi-step association kinetics consistent with an encounter-docking view of protein-protein interactions. The fully docked fraction of the complexes just prior to inducing dissociation was high for the HEL complexes but was dramatically reduced for JQL complexes, that is final docking was antigen-sensitive. Variations among the systems can be understood in terms of the complexes' differing conformational flexibilities, based on the encounter-docking model of protein-protein associations.     

Conformational flexibility of RecA protein filament: transitions between compressed and stretched states

RecA protein is a central enzyme in homologous DNA recombination, repair and other forms of DNA metabolism in bacteria. It functions as a flexible helix-shaped filament bound on stretched single-stranded or double-stranded DNA in the presence of ATP. In this work, we present an atomic level model for conformational transitions of the RecA filament. The model describes small movements of the RecA N-terminal domain due to coordinated rotation of main chain dihedral angles of two amino acid residues (Psi/Lys23 and Phi/Gly24), while maintaining unchanged the RecA intersubunit interface. The model is able to reproduce a wide range of observed helix pitches in transitions between compressed and stretched conformations of the RecA filament. Predictions of the model are in agreement with Small Angle Neutron Scattering (SANS) measurements of the filament helix pitch in RecA::ADP-AlF(4) complex at various salt concentrations.     

Conformational flexibility in physiologically active amines.

Physiologically active amines are flexible molecules which could use this conformational freedom to adapt their shapes when binding to receptor molecules. Calculations of conformational freedom indicate which substituted analogues could serve as experimental tests of the hypothesis that the flexibility of the natural transmitters is an essential feature of activity.     

Conformational and connotational heterogeneity: A surprising relationship between protein structural flexibility and puns

Protein structures are often thought of as static objects, and indeed, the bulk of a protein's sequence forms α‐helices, β‐sheets, and other generally well‐ordered substructures. These portions of the molecule pre‐pay the entropic price of maintaining a globally unique fold, freeing other regions to adopt multiple alternative conformations. In many cases, this localized flexibility is biologically interesting: it may be important for catalytic turnover or for conformational selection before forming an intermolecular complex, for example. Similarly, most of written language is carefully tuned to avoid ambiguity and convey a singular meaning, a cohesive message. This linguistic scaffolding in some sense pre‐pays a rhetorical price, paving the way for punctuated instances in which a given word or phrase can simultaneously adopt multiple alternative connotations—in other words, for puns. Proteins 2015; 83:797–798. © 2015 Wiley Periodicals, Inc.     

Conformational flexibility of four-way junctions in RNA

Helical junctions are common architectural features in RNA. They are particularly important in autonomously folding molecules, as exemplified by the hairpin ribozyme. We have used single-molecule fluorescence spectroscopy to study the dynamic properties of the perfect (4H) four-way helical junction derived from the hairpin ribozyme. In the presence of Mg(2+), the junction samples parallel and antiparallel conformations and both stacking conformers, with a bias towards one antiparallel stacking conformer. There is continual interconversion between the forms, such that there are several transitions per second under physiological conditions. Our data suggest that interconversion proceeds via an open intermediate with reduced cation binding in which coaxial stacking between helices is disrupted. The rate of interconversion becomes slower at higher Mg(2+) concentrations, yet the activation barrier decreases under these conditions, indicating that entropic effects are important. Transitions also occur in the presence of Na(+) only; however, the coaxial stacking appears incomplete under these conditions. The polymorphic and dynamic character of the four-way RNA junction provides a source of structural diversity, from which particular conformations required for biological function might be stabilised by additional RNA interactions or protein binding.     

Conformational flexibility and structure of creatine kinase

The structural flexibility of creatine kinase has been investigated with the covalent hydrophobic probe 2-[4′-(2″-iodoacetamido) phenyl] aminonaphthalene-6-sulfonic acid (IAANS) which reacts at vastly different rates with the two subunits to give a protein conjugate with fluorescence characteristic of reaction with a site in a hydrophobic cleft. Binding of purine nucleotides greatly enhances the probe fluorescence while pyrimidine nucleotides quench the fluorescence. Small anions bind to nucleotide-free creatine kinase near the location of the transferable phosphoryl group and quench both the IAANS fluorescence of modified creatine kinase and the tryptophan fluorescence of native creatine kinase. Chloride and nitrate non-competitively inhibit MgADP binding both with and without creatine. Fluorescence energy transfer demonstrates that the active sites of creatine kinase are well separated and become further apart after the nucleotide-induced conformational change.     

Apoptosis and its functional significance in molluscs

Programmed cell death leading to apoptosis is essential for normal development and homeostasis in plants and throughout the animal kingdom. Although there are differences in apoptotic mechanisms between lower animals and vertebrates, crucial biochemical components of the programmed cell death pathways remained remarkably conserved throughout evolution. Despite decades of studies on the neurobiology and development of mollusks, comparatively little is known about the mechanisms of apoptosis in this phylum. In this review, an attempt is made to summarize data obtained on mollusks so far, and to discuss the molecular mechanisms, the functional and ecological significance of apoptosis and the advantages of snail preparations as tools for programmed cell death research. A definitive comparison of the data obtained on mollusks with those obtained on the more widely studied vertebrates, will contribute to the better understanding of the apoptotic process in general and of its evolutionary development.     

Conformational flexibility of BECN1: Essential to its key role in autophagy and beyond

BECN1 (Beclin 1), a highly conserved eukaryotic protein, is a key regulator of autophagy, a cellular homeostasis pathway, and also participates in vacuolar protein sorting, endocytic trafficking, and apoptosis. BECN1 is important for embryonic development, the innate immune response, tumor suppression, and protection against neurodegenerative disorders, diabetes, and heart disease. BECN1 mediates autophagy as a core component of the class III phosphatidylinositol 3‐kinase complexes. However, the exact mechanism by which it regulates the activity of these complexes, or mediates its other diverse functions is unclear. BECN1 interacts with several diverse protein partners, perhaps serving as a scaffold or interaction hub for autophagy. Based on extensive structural, biophysical and bioinformatics analyses, BECN1 consists of an intrinsically disordered region (IDR), which includes a BH3 homology domain (BH3D); a flexible helical domain (FHD); a coiled‐coil domain (CCD); and a β‐α‐repeated autophagy‐specific domain (BARAD). Each of these BECN1 domains mediates multiple diverse interactions that involve concomitant conformational changes. Thus, BECN1 conformational flexibility likely plays a key role in facilitating diverse protein interactions. Further, BECN1 conformation and interactions are also modulated by numerous post‐translational modifications. A better structure‐based understanding of the interplay between different BECN1 conformational and binding states, and the impact of post‐translational modifications will be essential to elucidating the mechanism of its multiple biological roles.     

Conformational flexibility and biological activity of salmon calcitonin

We have assessed the biological activity of salmon calcitonin I (sCT) using an in vivo biological assay of hypocalcemic activity in rats. The changes in biological activity observed are explained on the basis of changes in the conformational properties of the hormone analogues. Helical content in the presence and absence of lipids and detergents was assessed by using circular dichroism, and the section of the molecule that folds into a helix was predicted on the basis of the helix-coil transition theory of Mattice and co-workers. In the amino acid sequence of sCT, residue 8 is valine and residue 16 is leucine. The synthetic calcitonin derivatives [Gly8]sCT and [Ala16]sCT have higher biological activity than the native hormone although they have a lower helical content. The increased biological activity of these derivatives is ascribed to an increase in their conformational flexibility resulting from the substitution of amino acid residues with less bulky side chains and less tendency to form helical structures. The derivative [Met8]sCT has less substitution than sCT on the beta-carbon at position 8, but it has increased helix-forming potential in the region of residues 8-12. These two factors affect conformational flexibility in opposite ways, resulting in the biological activity of [Met8]sCT being slightly higher than that of sCT. However, increased conformational flexibility does not always increase biological activity. Substitution of the L-arginine at residue 24 for a D-arginine has little effect on the conformational properties or biological activity of sCT. However, [Gly8, D-Arg24]sCT is less active than sCT, [Gly8]sCT, or [D-Arg24]sCT.(ABSTRACT TRUNCATED AT 250 WORDS)