Dynamical Properties of Condensed Charged Polymer Melts

Abstract

Dynamical properties of condensed charged polymer melts are studied with a two-dimensional model and molecular dynamics simulation. Screened Coulombic interactions are assumed for the interactions between the monomer charges as well as the counterions which were introduced to neutralize the total monomer charges of polymer chains. Through molecular dynamics calculations, we have obtained the radial distribution function and velocity auto-correlation function, and their density dependences. As a structural characteristics in condensed charged polymer melts, we find that the monomers tend to form triangular structures locally. The radial distribution function for the center monomers implies that the polymer chains on our two-dimensional model are not entangled. The diffusion properties for both the counter-ions and innermost monomers are studied in detail. In this paper, we have also computed neutral polymer melts to study the effects of the presence of the long-range Coulombic interactions on the dynamical properties of polymer melts. We find that the Coulombic interactions significantly reduce the self diffusion. Snapshots analyses obtained from the molecular dynamics simulation suggest that the reptation model is not a proper model for two-dimensional polymer-chain melts, in which there are little entanglement effects in agreement with the result of the analyses for the radial distribution function.     

DuoMab: a novel CrossMab-based IgG-derived antibody format for enhanced antibody-dependent cell-mediated cytotoxicity

ABSTRACT

High specificity accompanied with the ability to recruit immune cells has made recombinant therapeutic antibodies an integral part of drug development. Here we present a generic approach to generate two novel IgG-derived antibody formats that are based on a modification of the CrossMab technology. MoAbs harbor two heavy chains (HCs) resulting in one binding entity and one fragment crystallizable region (Fc), whereas DuoMabs are composed of four HCs harboring two binding entities and two Fc regions linked at a disulfide-bridged hinge. The latter bivalent format is characterized by avidity-enhanced target cell binding while simultaneously increasing the ‘Fc-load’ on the surface. DuoMabs were shown to be producible in high yield and purity and bind to surface cells with affinities comparable to IgGs. The increased Fc load directed at the surface of target cells by DuoMabs modulates their antibody-dependent cell-mediated cytotoxicity competency toward target cells, making them attractive for applications that require or are modulated by FcR interactions.     

Simulation Studies on the Stabilities of Aggregates Formed by Fibril-Forming Segments of α-Synuclein

Abstract

We performed molecular dynamics simulations for various oligomers with different β-sheet conformations consisting of α-Synuclein 71–82 residues using an all atom force field and explicit water model. Tetramers of antiparallel β-sheet are shown to be stable, whereas parallel sheets are highly unstable due to the repulsive interactions between bulky and polar side chains as well as the weaker backbone hydrogen bonds. We also investigated the stabilities of double antiparallel β-sheets stacked with asymmetric and symmetric geometries. Our results show that this 12 amino acid residue peptide can form stable β-sheet conformers at 320K and higher temperatures. The backbone hydrogen bonds in β-sheet and the steric packing between hydrophobic side chains between β-sheets are shown to give conformational stabilities.     

Analysis of the effect of electrostatic energy truncation in molecular dynamics simulations of immunoglobulin G light chain dimer

Molecular dynamics (MD) simulations of immunoglobulin G (IgG) light chain dimer using particle mesh Ewald (PME) and cutoff methods of treating electrostatic interactions were performed. The results indicate that structural parameters (RMSD, radius of gyration, solvent accessible surface) are very similar for both schemes; however, PME simulation shows increased mobility of side chains. This leads to larger fluctuations in the distance between the monomers in the dimer molecule, and, as a consequence, results in decreased number of interactions across the dimer interface. The wall clock time of the simulations was also compared. It was shown that the PME method is approximately 30% faster than the cutoff method for the system studied on a single processor.Figure Backbone order parameters for PME (red) and cutoff (green) calculations. Thick, horizontal lines show stable secondary structures     

Utilidad clínica de la micafungina en el tratamiento de las candidiasis invasoras en el neonato

BackgroundIn neonatal intensive care units, deep fungal disease due to Candida spp. are an important clinical problem, partly due to the increasing prevalence of Candida disease and also to the high associated and constant morbimortality; both factors are independently maintained though there has been a significant improvement in the management of neonatal patients.AimsTo define the therapeutic use of micafungin for the treatment of neonatal invasive candidiasis.MethodsWe use a review of biomedic data bases namely Medline and EMBASE.ConclusionsMicafungin is the latest introduced echinocandin. It has a wide spectrum of activity and covers Candida albicans and non-albicans Candida species. It has scarce drugs interactions and is devoid of toxicity, being an attractive approach for the treatment of invasive candidiasis (without meningitis, endocarditis and endophthalmitis). Althought the European Medicines Agency approved in 2008 the use of Micafungin for the treatment of invasive candidiasis in children, the available clinical experience is limited and currently more clinical studies are warranted to define its efficacy and safety in neonates.     

Concentration dependent cholesteryl-ester and wax-ester structural relationships and meibomian gland dysfunction

BackgroundWith dry eye, the ratio of cholesteryl ester (CE) to wax ester (WE) decreases substantially in meibum, but the functional and structural consequences of this change are speculative. The aim of this study is to confirm this finding and to bridge this gap in knowledge by investigating the effect of varying CE/WE ratios on lipid structure and thermodynamics.MethodsInfrared spectroscopy was use to quantify CE and WE in human meibum and to measure hydrocarbon chain conformation and thermodynamics in a cholesteryl behenate, stearyl stearate model system.ResultsThe CE/WE molar ratio was 36% lower for meibum from donors with dry eye due to meibomian gland dysfunction compared with meibum from donors without dry eye. CE (5 mol %) dramatically increased the phase transition temperature of pure WE from -0.12 °C to 63 °C in the mixture. Above 5 mol % CB, the phase transition temperature increased linearly, from 68.5 °C to 85 °C. In the ordered state, CE caused an increase in lipid order from about 72% trans rotamers to about 86% trans rotamers. Above 10% CE, the hydrocarbon chains were arranged in a monoclinic geometry.ConclusionsThe CE/WE is lower in meibum from donors with dry eye due to meibomian-gland dysfunction. Major conformational changes in the hydrocarbon chains of wax and cholesteryl ester mixtures begin to occur with just 5% CB and above.General significanceCE-WE interactions may be important for in understanding lipid layer structure and functional relationships on the surface of tears, skin and plants.     

Considerations of the estimation of plasmodesmatal frequencies

The association constants reported for the formation of metal ion : polyampholyte complexes can be in substantial error due to buffer effects. The magnitude of the error is a function of the affinity constants of the metal ion to the polyampholyte and to the buffer, the pH and the concentrations. A mathematical and graphical analysis of the depletion of the free metal ion concentration by formation of multiple metal ion: buffer complexes, MB_i, (where j ranges from 1 to n) is presented. An analysis is made of the dependence of the experimentally determined association constant for the formation of a 1:1 metal ion: polyampholyte complex in a system where a 1:1 complex of metal ion: buffer is also produced. Other sources of error considered include the formation of mixed complexes consisting of polyampholyte, metal ions and buffer components.By determining the pH shift resulting from protein: metal ion coordination in a buffer-free system it is possible to establish the extent of metal ion binding, gain insight about to the mechanism of the association process and ascertain whether certain types of structural transitions occur.     

Nonplanar DNA Base Pairs

Abstract

Three-dimensional structures of a representative set of more than 30 hydrogen-bonded nucleic acids base pairs have been studied by reliable ab initio quantum mechanical methods. We show that many hydrogen-bonded nucleic acid base pairs are intrinsically nonplanar, mainly due to the partial sp³ hybridization of nitrogen atoms of their amino groups and secondary electrostatic interactions. This finding extends the variability of intermolecular interactions of DNA bases in that i) flexibility of the base pairs is larger than has been assumed before, and ii) attractive proton-proton acceptor interactions oriented out of the base pair plane are allowed. For example, all four G…A mismatch base pairs are propeller twisted, and the energy preferences for the nonplanar structures range from less than 0.1 kcal/mol to 1.8 kcal/mol. We predict that nonplanarity of the amino group of guanine in the G(anti)…A(anti) pair of the ApG step of the d(CCAAGATTGG)₂ crystal structure is an important stabilizing factor that improves the energy of this structure by almost 3 kcal/mol. Currently used empirical potentials are not accurate enough to properly cover the interactions associated with amino-group and base-pair nonplanarity.     

Biosensor analysis of the interaction of potential dimerization inhibitors with HIV-1 protease

Inhibitors of protein-protein interactions are currently considered as perspective prototypes of a new generation of drugs. The most attractive targets for such inhibitors are the oligomeric enzymes which active sites are formed by amino acid residues from different subunits. HIV-1 protease (HIVp), which is active only as a homodimer form, is the classic example of such enzymes. We have developed a new approach for experimental screening of HIVp dimerization inhibitors. It is based on an original biosensor test-system for differential analysis of interaction of tested substances with HIVp dimers and monomers. Using this test-system we have analyzed the most perspective candidate substances predicted by the method of virtual screening, and also some derivatives of glycyrrhizin, triterpenic and steroid glycosides. In the results of this study we have found one compound, which preferentially interacts with HIVp monomers and inhibits in vitro activity of this enzyme with the IC₅₀ value of about 10^?6 M.     

Intersubunit Interactions in Human Cytidine Deaminase

Abstract

In order to design new efficient cytidine based drugs, an intersubunit interactions study related to the active site has been performed on the wild-type cytidine deaminase (CDA) and on the mutant enzyme F137W/W113F. F137 is the homologous to the Bacillus subtilis CDA F125 involved in the subunit interactions. In presence of the dissociating agent SDS, wild-type human CDA dissociate into enzymatically inactive monomers without intermediate forms via a non-cooperative transition. Extensive dialysis or dilution of the inactivated monomers restores completely the activity. The presence of the strong human CDA competitive inhibitor 5-fluorozebularine disfavour dissociation of the tetramer into subunits in the wild-type CDA but not in mutant enzyme F137W/W113F.     

Structure and Stability of the Insulin Dimer Investigated by Molecular Dynamics Simulation

Abstract

Molecular dynamics simulation indicates that the dynamical behaviour of the insulin dimer is asymmetric. Atomic level knowledge of the interaction modes and protein conformation in the solvation state identifies dynamical structures, held by hydrogen bonds that stabilize, mainly in one monomer, the interaction between the chains. Dynamic cross-correlation analysis shows that the two insulin monomers behave asymmetrically and are almost independent. Solvation energy, calculated to evaluate the contribute of each interface residue to the dimer association pattern, well compares with the experimental association state found in protein mutants indicating that this parameter is an important factor to explain the association properties of mutated insulin dimers.     

Arrangement of nucleotide sequences in adeno-associated virus DNA

There are two types of adeno-associated virus virions which contain complementary single-stranded DNA genomes of about 1.4 × 10⁶ daltons. The purified complementary single polynucleotide chains anneal to form duplex linear monomers, circular monomers, and linear dimers, in addition to other less well-defined structures, as identified by sedimentation and electron microscopy. All duplex species are formed by linear single polynucleotide chains of unit length, thus duplex circles and linear dimers are assumed to be held together by relatively short overlapping hydrogen-bonded regions. The initial linear monomers present after annealing the complementary single strands do not form duplex circles or oligomers when re-exposed to annealing conditions, but DNA which sediments as linear monomers after heating linear dimers at a temperature from 7 to 25 deg. C below the T_m of duplex AAV² DNA does re-form oligomers and circles when exposed to annealing conditions. Denaturation and reannealing of any duplex species leads to the formation of all forms, indicating that the over-all single strand composition of all species is equivalent. Disruption of duplex circles by limited exonucleolytic digestion using either 3′ or 5′ exonucleases leads to the conclusion that the overlap region may have either 3′ or 5′ termini and that the overlap region represents less than 6% of the length of the genome. Exonucleolytic digestion of linear monomers to the extent of 50% leaves polynucleotide chains which cannot reanneal after denaturation, thus AAV DNA is not randomly circularly permuted. Duplex linear monomers which do not form circles when exposed to annealing conditions do form duplex circles after 1% exonuclease III digestion. A model consistent with these data is one in which the linear single polynucleotide chains present in AAV virions consist of two or more permutations. All of these chains contain terminal repetitions and their start points occur within a limited region, representing < 6% of the length of the genome. According to this interpretation AAV DNA would exist within the virion as a linear single polynucleotide chain or is cleaved at a few specific sites during extraction.     

Molecular Mechanics Studies of Dinucleoside Methylphosphonates: Influence of Methylphosphonate and its Chirality on the Phosphodiester Conformation

Abstract

Molecular mechanics studies are performed on single stranded as well as base paired forms of dinucleoside methylphosphonates comprising different base sequences for both the Sand R-isomers of methylphosphonate (MP). S-MP produces noticeable distortions in the geometry, locally at the phosphate center, and this enables the stereochemical feasibility of compact g^? g^? phosphodiester. Besides, it tends to perturb the conformations around the P- 03′ and glycosyl bonds, causing minor variations in stacking interactions. In single stranded dinucleosides, the gain in adjacent base stacking interaction energies seems to be sufficient to overcome the barrier to P-03′ bond rotation arising due to S-MP…sugar interaction, and this results in transition to a compact phosphodiester (B_I-type) from an initial extended phosphodiester (B_II-type) conformation. Such a thing seems rather difficult in base pair constrained duplexes. Dinucleosides with R-MP behave analogous to normal phosphate duplexes as the methyl group is away from the sugar. It is found that dinucleoside methylphosphonates are energetically less favoured than the corresponding dinucleoside phosphates mainly due to the depletion of contributions from electrostatic attractive interactions involving the base and sugar with the methylphosphonate consequent to the nonionic nature of the latter. Neither S-MP nor R-MP seem to significantly alter the stereochemistry of duplex structure.     

Romanowsky dyes and Romanowsky-Giemsa effect

Summary A reproducible Romanowsky-Giemsa staining (RGS) can be carried out with standardized staining solutions containing the two dyes azure B (AB) and eosin Y (EY). After staining, cell nuclei have a purple coloration generated by DNA-AB-EY complexes. The microspectra of cell nuclei have a sharp and intense absorption band at 18 100 cm^–1 (552 nm), the so called Romanowsky band (RB), which is due to the EY chromophore of the dye complexes. Other absorption bands can be assigned to the DNA-bound AB cations.Artificial DNA-AB-EY complexes can be prepared outside the cell by subsequent staining of DNA with AB and EY. In the first step of our staining experiments we prepared thin films of blue DNA-AB complexes on microslides with 1:1 composition: each anionic phosphodiester residue of the nucleic acid was occupied by one AB cation. Microspectrophotometric investigations of the dye preparations demonstrated that, besides monomers and dimers, mainly higher AB aggregates are bound to DNA by electrostatic and hydrophobic interactions. These DNA-AB complexes are insoluble in water. Therefore it was possible to stain the DNA-AB films with aqueous EY solutions and also to prepare insoluble DNA-AB-EY films in the second step of the staining experiments. After the reaction with EY, thin sites within the dye preparations were purple. The microspectra of the purple spots show a strong Romanowsky band at 18 100 cm^–1. Using a special technique it was possible to estimate the composition of the purple dye complexes. The ratio of the two dyes was approximately EY:AB1:3. The EY anions are mainly bound by hydrophobic interaction to the AB framework of the electrical neutral DNA-AB complexes. The EY absorption is red shifted by the interaction of EY with the AB framework of DNA-AB-EY. We suppose that this red shift is caused by a dielectric polarization of the bound EY dianions.The DNA chains in the DNA-AB complexes can mechanically be aligned in a preferred direction k. Highly orientated dye complexes prepared on microslides were birefringent and dichroic. The orientation is maintained during subsequent staining with aqueous EY solutions. In this way we also prepared highly orientated purple DNA-AB-EY complexes on microslides. The light absorption of both types of dye complexes was studied by means of a microspectrophotometer equipped with a polarizer and an analyser. The sites of best orientation within the dye preparations were selected under crossed nicols according to the quality of birefringence. Subsequently, the absorption spectra of the highly orientated dye complexes were measured with plane polarized light. We found that the transition moments, m _AB, of the bound AB cations in DNA-AB and DNA-AB-EY are orientated almost perpendicular to k, i.e. m _ABk. On the contrary, the transition moments, m _EY, of the bound EY anions in DNA-AB-EY are polarized parallel to k, i.e. m _EY k. The transition moments m _AB and m _EY lay in the direction of the long axes of the AB and EY chromophores. For that reason, in both DNA-AB and DNA-AB-EY the long molecular axes of the AB cations are orientated approximately perpendicular to the DNA chains, while the long molecular axes of the EY chromophores are polarized in the direction of the DNA chains. Therefore, in DNA-AB-EY the long axes of AB and EY are perpendicular to each other, m _ABm _EY. This molecular arrangement fully agrees with our quantitative measurements and with the theory of the absorption of plane polarized light by orientated dye complexes, which has been developed and discussed in detail.     

Aggregation and adsorption at the air-water interface of bacteriophage phiX174 single-stranded DNA

We study the phase behavior of phage phiX174 single-stranded DNA in very dilute solutions in the presence of monovalent and multivalent salts, in both water (H(2)O) and heavy water (D(2)O). DNA solubility depends on the nature of the salts, their concentrations, and the nature of the solvent. The appearance of attractive interactions between the monomers of the DNA chains in the bulk of the solution is correlated with an adsorption of the chains at the air-water interface. We characterize this correlation in two types of aggregation processes: the condensation of DNA induced by the trivalent cation spermidine and its salting out in the presence of high concentrations (molar and above) of monovalent (sodium) cations, both in water and in heavy water. The overall solubility of single-stranded DNA is decreased in D(2)O compared to H(2)O, pointing to a role of DNA hydration in addition to electrostatic factors in the observed phase separations. DNA adsorption involves attractive van der Waals forces, and these forces are also operating in the bulk aggregation process.     

Molecular dynamic simulations study of the effect of salt valency on structure and thermodynamic solvation behaviour of anionic polyacrylate PAA in aqueous solutions

The effect of salt concentration and valency on intermolecular structure and solvation thermodynamic properties of aqueous solution containing polyacrylicacid (PAA) chains and multi-valent salts calcium chloride (CaCl₂) and aluminium chloride (AlCl₃) as a function of charge density was investigated using atomistic molecular dynamic simulations with explicit solvent. Salt-free solution favours the self-association of uncharged (acidic form) PAA chains facilitated by inter-chain hydrogen bonds. The ionised (charged) PAA chains are not associated in salt-free aqueous solutions and undergo self-association in the salt solutions due to bridging effect induced by condensed salt ions in agreement with scattering investigations available in literature. The collapse behaviour of PAA in presence of CaCl₂ and re-expansion behaviour of PAA chains in case of AlCl₃ salt solutions are observed. The rigidity of PAA chains decrease with increase in salt concentration, in agreement with experimental results available in literature. The trivalent salt favours relatively the greater extent of shrinking of PAA chains as well as inter-chain interactions as compared to divalent salts as evident from radius-of-gyration, H-bond and pair-wise solvation enthalpy data. The conformation and hydration behaviour of the acid form of PAA chains are not significantly altered by added salt ions. The hydration behaviour of ionised PAA chains is significantly reduced by added salts due to screening effect of the condensed salt ions. The pair correlation functions of solutions species such as Ca²⁺, Al³⁺, Na⁺ and Cl^? with respect to PAA oxygen show the greater affinity of PAA units with the higher valency Al³⁺ ions over Ca²⁺ and Na⁺ in solution. With increase in concentration of AlCl₃ and CaCl₂ salts, a decrease in effective charge density of ionised PAA chains is observed from the existence of unfavourable PAA–water, PAA–Ca²⁺ and PAA–Al³⁺ interactions.     

Interactions between adsorbed layers of alphaS1-casein with covalently bound side chains: a self-consistent field study

The effect on the adsorbed layer properties of the modification of alpha S1-casein by covalent bonding with an uncharged polysaccharide side chain has been investigated using lattice-based self-consistent field (SCF) theory. Interactions between two hydrophobic planar surfaces coated by a layer of adsorbed modified alpha S1-casein have been studied as a function of pH and ionic strength. While the interactions of the unmodified alpha S1-casein layers become attractive at high ionic strength, it has been shown that the presence of polysaccharide attachment to the alpha S1-casein molecule can confer net repulsive interactions over a wide range of salt concentration. The disordered protein is represented as a linear flexible polyampholyte with a sequence of hydrophobic, polar, and charged units based on the known alpha S1-casein primary structure. The hydrophilic side chain is attached at various fixed positions along the casein backbone. Different lengths and locations of the attached polysaccharide side chain are examined. Interfacial structures and colloidal stability properties of the system are determined, including the surface-surface interaction potential, the extent of protein bridging, and the distribution of protein segments from the surface under different conditions of pH and ionic strength. It has been found that the covalent bonding of short hydrophilic chains may not only enhance but can also worsen the colloidal stabilizing properties of the modified protein, depending on the position of the attachment.     

A Molecular Dynamics Simulation of a Polyamine-Induced Conformational Change of DNA. A Possible Mechanism for the B to Z Transition

Abstract

A 75ps molecular dynamics simulation has been performed on a fully solvated complex of spermine with the B DNA decamer (dGdC)₅ · (dGdC)₅. The simulation indicates a possible mechanism by which polyamines might induce the formation of a left-handed helix, the B to Z transition. Spermine was initially located in the major groove, hydrogen bonded to the helix. During the simulation the ligand migrates deeper into the DNA, maintaining strong hydrogen bonding to the central guanine bases and destroying the Watson-Crick base pairing with their respective cytosines. Significant rotation of these and other cytosine bases was observed, in part due to interactions of the helix with the aminopropyl chains of spermine. An intermediate B_II conformation might be of importance in this process.     

Aliphatic Amino Acid Side Chains Associate with the “Face” of the Adenine Ring

Abstract

We have synthesized the free amino acid adenylate anydrides of phenylalanine, leucine, isoleucine and valine. These activated compounds are very labile at high pH, but at low pH they become more stable. Proton NMR spectra of these adenylates show that, in every case, the hydrophobic side chains, even in these small molecules at low pH and low concentration, are associated with the “face” of the adenine ring. Although aromatic rings are known to associate with adenine in this fashion, to our knowledge this is the first report of an intercalative-type interaction of aliphatic side chains with nucleic acid bases. Since adenine is the most hydrophobic base, these interactions are of a hydrophobic character, and occur in spite of the fact that the adenine ring is protonated. These results may have implications regarding recognition processes in DNA-protein and RNA-protein interactions.     

Mixed Mode of Ligand-DNA Binding Results in S-Shaped Binding Curves

Abstract

S-shaped binding curves often characterize interactions of ligands with nucleic acid molecules as analyzed by different physicochemical and biophysical techniques. S-shaped experimental binding curves are usually interpreted as indicative of the positive cooperative interactions between the bound ligand molecules. This paper demonstrates that S-shaped binding curves may occur as a result of the “mixed mode” of DNA binding by the same ligand molecule. Mixed mode of the ligand-DNA binding can occur, for example, due to 1) isomerization or dimerization of the ligands in solution or on the DNA lattice, 2) their ability to intercalate the DNA and to bind it within the minor groove in different orientations. DNA- ligand complexes are characterized by the length of the ligand binding site on the DNA lattice (so-called “multiple-contact” model). We show here that if two or more complexes with different lengths of the ligand binding sites could be produced by the same ligand, the dependence of the concentration of the complex with the shorter length of binding site on the total concentration of ligand should be S-shaped. Our theoretical model is confirmed by comparison of the calculated and experimental CD binding curves for bis-netropsin binding to poly(dA-dT) poly(dA-dT). Bis-netropsin forms two types of DNA complexes due to its ability to interact with the DNA as monomers and trimers. Experimental S-shaped bis-netropsin-DNA binding curve is shown to be in good correlation with those calculated on the basis of our theoretical model. The present work provides new insight into the analysis of ligand-DNA binding curves.