Measurement of interstrand cross-link frequency and distance between interruptions in DNA exposed to 4,5',8-trimethylpsoralen and near-ultraviolet light

Bifunctional psoralens react photochemically with DNA to form single-strand adducts and interstrand, chemical cross-links. Cross-link formation is first order with [P], the concentration of added psoralen, when [P] much less than Kd, the psoralen-DNA dissociation constant. DNA molecules containing interstrand cross-links are reversibly bihelical and so are readily detected. It was not heretofore possible to determine cross-link frequency in polydisperse DNA from the mass F of DNA spared cross-linkage. We have derived a statistical relation to calculate cross-link frequency at fixed light exposure and variable [P]. We show here that S, the initial slope of the curve described by -ln F as a function of [P], is proportional to Mw, the weight-average molecular weight of nick-free DNA. The cross-link frequency at any [P] can be determined from k, a constant measured for DNA of known Mw at low cross-linkage. This relation is valid for DNA of any molecular weight distribution. In experiments with uniform length DNA, -ln F (cross-link frequency) increased in simple proportion to [P]. Intact and restriction endonuclease HindIII digested phage lambda DNA molecules have discrete lengths. S for each was proportional to Mw of the twin helix even though the molecular weight distribution of the restriction fragments was skewed. S was proportional to Mw and to the median molecular weight of sheared cellular DNA over a wide range. Also, we found that 1/S was linear with exposure of cellular DNA to gamma radiation. S can therefore be used to calculate L, the average distance between interruptions in the double helix.     

Coarse-grained modeling study of nonpeptide RGD ligand density and PEG molecular weight on the conformation of poly(γ-glutamyl-glutamate) paclitaxel conjugates

Molecular shape, flexibility, and surface hydrophilicity are thought to influence the ability of nanoparticles to cross biological barriers during drug delivery. In this study, coarse-grained (CG) molecular dynamics (MD) simulations were used to study these properties of a polymer-drug construct in potential clinical development: poly(γ-glutamyl-glutamate)-paclitaxel-poly(ethylene glycol) nonpeptide RGD (PGG-PTX-PEG-npRGD), a linear glutamyl-glutamate polymer with paclitaxel and poly(ethylene glycol)-nonpeptide RGD side groups. It was hypothesized that the PEG molecular weight (MW) (500 Da; 1,000 Da; and 2,000 Da) and nonpeptide RGD ligand density (4, 8, 12, and 16 per molecule), respectively, may have advantageous effects on the shape, flexibility, and surface hydrophilicity of PGG-PTX-PEG-npRGD. Circular dichroism spectroscopy was used to suggest initial structures for the all-atom (AA) models of PGG-PTX-PEG-npRGD, which were further converted to CG models using a commercially available mapping algorithm. Due to its semi-flexibility, PGG-PTX-PEG-npRGD is not limited to one specific conformation. Thus, CG MD simulations were run until statistical equilibrium, at which PGG-PTX-PEG-npRGD is represented as an ensemble of statistically similar conformations. The size of a PGG-PTX-PEG-npRGD molecule is not affected by the PEG MW or the nonpeptide RGD density, but higher PEG MW results in increased surface density of a PGG-PTX-PEG-npRGD molecule. Most PGG-PTX-PEG-npRGD shapes are globular, although filamentous shapes were also observed in the PEG500 and PEG1000 molecules. PEG500 and PEG1000 molecules are more flexible than PEG2000 systems. A higher presence of npRGD ligands results in decrease surface hydrophilicity of PGG-PTX-PEG-npRGD. These results indicate that the PGG-PTX-PEG1000-npRGD₄ and PGG-PTX-PEG1000-npRGD₈ molecules are the most efficacious candidates and are further recommended for experimental preclinical studies.     

Minimization of protein adsorption on poly(vinylidene fluoride)

Surfaces covered with polyethylene glycol (PEG) have been shown to be biocompatible because PEG yields nonimmunogenicity, nonantigenicity and protein rejection. To produce a biocompatible surface coating, we have developed a method for grafting PEG onto modified poly(vinylidene fluoride) (PVDF) films. The first step was to create carboxy groups on the PVDF surface following covalente coupling of polyethylenimine (PEI) to achieve high density of amino groups. These surface amines were reacted with formyl-terminated PEG's with various molecular weight. The modified PVDF surface was characterized by means of static contact angle measurements, infrared (IR) spectroscopy and X-ray photoelectron spectroscopy (XPS). The influence of the chain length on lysozyme repellence was investigated by means of surface-MALDI-Tof mass spectrometry (Surface-MALDI-Tof-MS). Lysozyme adsorption was significantly suppressed on the PEG 5000 modified PVDF surface.     

Surface structure of in vitro assembled bacteriophage lambda polyheads.

Interstrand cross-links induced by psoralen-plus-light are removed from the DNA of Escherichia coli, and this reaction is effected by the uvrA, uvrB, uvrC and polA (5′ → 3′ exonuclease) gene products. During cross-link removal, cellular DNA strands are cut so that, upon denaturation, the DNA dissociates into segments having an average molecular weight about equal to twice the average distance between cross-links. These strand cuts are persistent in cells, having a half-life of more than 20 minutes.The structure of cross-linked DNA undergoing repair was further investigated by use of density and radioactively labeled isotopes. These experiments demonstrate that two strand cuts are made in one DNA strand near each cross-link, one on each side of one arm of the cross-link. A mechanism is proposed for cross-link removal. The endonuclease coded for by the uvrA and B genes makes an incision on the 5′ side of one arm of a cross-link. Polymerase I (5′ → 3′ exonuclease) then makes a second cut on the 3′ side, in the same strand. This allows the strands to be separated during denaturation, but would leave the second arm of the cross-linking structure still attached to the uncut strand. The persistence of strand cuts at cross-links suggests that rejoining, dependent upon repair polymerization and ligation, is blocked by such a partially excised cross-linking residue. Initial stages of cross-link removal appear to be similar to pyrimidine dimer excision, but intermediates generated by these processes differ substantially in structure and repair must be completed by different mechanisms.     

Polymer fractionation in aqueous two-phase polymer systems.

We consider the effects of the addition of poly(ethylene glycol) (PEG) of different molecular weights to aqueous two-phase system of PEG 8000 and dextran 500. The first purpose of this study was to determine the molecular weight partitioning of the polymers themselves so that, for example, aqueous two-phase separations using affinity ligands can be improved. The second purpose was to examine whether this molecular weight partitioning could be predicted by using solution thermodynamic models so that it would be possible to optimize affinity partitioning without extensive laboratory work. Experimentally, we find that, by increasing the PEG concentration of any molecular weight in the feed, the high molecular weight PEG concentration in the dextran-rich phase is reduced. This observation can be used to reduce the loss of expensive ligated PEG used in affinity partitioning. Further, there is generally good agreement between our experimental data and the predictions of a solution thermodynamic model.     

A designed protein for the specific and covalent heteroconjugation of biomolecules

Bioconjugations often rely on adaptor molecules to cross-link different biomolecules. In this work, we introduce the molecular adaptor covalin, which is a protein chimera of two self-labeling proteins with nonoverlapping substrate specificity. Covalin permits a selective and covalent heteroconjugation of biomolecules displaying appropriate functional groups. Examples for the use of covalin include the specific heteroconjugation of a reporter enzyme to an antibody and of molecular probes to the surface of living cells. The efficiency and specificity of covalin-based bioconjugations together with the availability of a large variety of substrates create immediate and ubiquitous applications for covalin in bioconjugate chemistry.     

Polyethylene glycol as a spacer for solid-phase enzyme immobilization

With the aim to improve the performance of enzyme bound to hydrophilic solid phases, their immobilization with polyethylene glycol (PEG) tether have been studied. Sweet potato β-amylase, which hydrolyses the high molecular weight substrate starch and β-galactosidase, which acts on low molecular weight substrates, were used as model enzymes and beaded thiol–agarose as solid phase. Several two step methods for the introduction of the tether using a bis-oxirane homobifunctional PEG as well as a heterobifunctional derivative with a hydroxysuccinimide ester and a maleimide group have been evaluated. Amino groups, native and de novo thiol groups in the enzymes were utilized for immobilization.

The best approach was found to be to first introduce the PEG derivative via one of its reactive groups to the enzyme. Subsequently the formed conjugate was bound to the solid phase by the remaining reactive group.

Attempts to first introduce the PEG tether into the solid phase were not successful.

A high degree of substitution with PEG chains on the enzyme leads to high immobilization yields for both β-amylase and β-galactosidase, but relatively lower gel-bound activity for the former enzyme which is acting on a high molecular weight substrate and thus more sensitive for steric shielding effects. With optimal degree of PEG substitution (which occurred at five times molar excess of the heterobifunctional reagent) the gel-bound activity of β-amylase was increased from 12% (for the derivative without tether) to 31%.     

Analysis of polymer molecular weight distributions in aqueous two-phase systems.

The partitioning of proteins and other biomaterials between two aqueous phases containing polyethyleneglycol and dextran is a strong function of the molecular weight of the two polymers. Although both polymers are polydispersed (especially Dx) most theoretical treatments refer only to the average molecular weight (number or mass) and assume that the molecular weight distribution of each polymer is the same in both phases. In this work the molecular weight distribution of each polymer is the same in both phases. In this work the molecular weight distributions of four stock solutions of PEG (4000, 6000, 10,000 and 20,000) and four stock solutions of Dx (10,000, 40,000, 110,000 and 500,000) were measured using High Performance Gel Chromatography. The measurements were repeated on the phases formed by the polymer solutions after they were mixed and allowed to equilibrate. The molecular weight distribution of the Dx differed in the top and bottom phase; both differed from that of the stock solution. Although we believe that the molecular weight distribution for PEG also differs in the top and bottom phases, we were unable to determine this within the resolution of our instruments.     

Synthetically simple, highly resilient hydrogels

Highly resilient synthetic hydrogels were synthesized by using the efficient thiol-norbornene chemistry to cross-link hydrophilic poly(ethylene glycol) (PEG) and hydrophobic polydimethylsiloxane (PDMS) polymer chains. The swelling and mechanical properties of the hydrogels were controlled by the relative amounts of PEG and PDMS. The fracture toughness (G(c)) was increased to 80 J/m(2) as the water content of the hydrogel decreased from 95% to 82%. In addition, the mechanical energy storage efficiency (resilience) was more than 97% at strains up to 300%. This is comparable with one of the most resilient materials known: natural resilin, an elastic protein found in many insects, such as in the tendons of fleas and the wings of dragonflies. The high resilience of these hydrogels can be attributed to the well-defined network structure provided by the versatile chemistry, low cross-link density, and lack of secondary structure in the polymer chains.     

State of degradation in archeological oak from the 17th century vasa ship: substantial strength loss correlates with reduction in (holo)cellulose molecular weight

In 1628, the Swedish warship Vasa capsized on her maiden voyage and sank in the Stockholm harbor. The ship was recovered in 1961 and, after polyethylene glycol (PEG) impregnation, it was displayed in the Vasa museum. Chemical investigations of the Vasa were undertaken in 2000, and extensive holocellulose degradation was reported at numerous locations in the hull. We have now studied the longitudinal tensile strength of Vasa oak as a function of distance from the surface. The PEG-content, wood density, and cellulose microfibril angle were determined. The molar mass distribution of holocellulose was determined as well as the acid and iron content. A good correlation was found between the tensile strength of the Vasa oak and the average molecular weight of the holocellulose, where the load-bearing cellulose microfibril is the critical constituent. The mean tensile strength is reduced by approximately 40%, and the most affected areas show a reduction of up to 80%. A methodology is developed where variations in density, cellulose microfibril angle, and PEG content are taken into account, so that cell wall effects can be evaluated in wood samples with different rate of impregnation and morphologies.     

Use of bifunctional cross-linking reagents in mapping genomic distribution of chromatin remodeling complexes

Chromatin remodeling complexes consist of multiple subunits, some of which are in intimate contact with DNA while others are not. The ability to effectively cross-link proteins to DNA with formaldehyde is impacted by the average distance between the two species. Productive cross-linking of proteins not in direct contact with DNA is greatly facilitated by the inclusion of an initial cross-linking reaction using bifunctional imidoester cross-linking reagents.     

Synthesis and application of a poly(ethylene glycol)-antibody affinity ligand for cell separations in aqueous polymer two-phase systems

The possibility of producing biospecific affinity ligands for separating cells in two polymer aqueous phase systems on the basis of cell surface antigens was investigated. Rabbit anti-human erythrocyte IgG was reacted with cyanuric chloride-activated monomethyl poly(ethylene glycol) (PEG) fractions (molecular weights approximately 200, 1900, and 5000) at various molar ratios of PEG to protein lysine groups. The partition coefficient of the protein in a Dextran/PEG two-phase system increased with increasing degree of modification and increasing PEG molecular weight. There was a concomitant loss in ability to agglutinate human erythrocytes. The ability of the modified IgG to bind to a DEAE-cellulose column was almost eliminated by reaction with the PEG 5000, and was decreased to a lesser extent by PEG 1900. This PEG 1900-modified IgG substantially increased the partition of fresh or fixed human erythrocytes into the PEG-rich phase of a suitable phase system, while having no effect on rabbit cell partition. The partition increase could be inhibited by unmodified anti-human red cell IgG but not by nonspecific unmodified human IgG, demonstrating that the ligand effects were specific for the cell type against which the antibody was raised. A mixture of rabbit and human erythrocytes, which ordinarily have very similar partitions in the phase systems used, could be separated on a countercurrent distribution apparatus using the modified IgG. These results demonstrate the feasibility of producing immunologically specific affinity partition ligands for cell separation.     

Relationship between the molecular structure of aqueous solutions of polyethylene glycol and the compactness of double-stranded DNA molecules

The dependence of viscosity of the water solutions of poly(ethylene glycol) (PEG) on the molecular weight has been studied. It has been shown that there is a "transitional" region in PEG properties which accounts for the formation of fluctuation polymer network of the PEG molecules. It has been shown that the "transitional" region in properties of PEG which appears at a certain concentration of PEG (CtrPEG) is characteristic of the PEG preparations with molecular weights exceeding 600 and dependence of the value of CtrPEG on the molecular weight of PEG was obtained. Compactization of double-stranded DNA molecules in PEG-containing water-salt solutions has been studied and the dependence of the value of CcrPEG, . i.e. the concentration of PEG at which the compact particles of DNA appear in the solution, on the molecular weight of PEG was obtained. The correlation between these two dependences reflecting quite different physico-chemical processes shows that the double-stranded DNA molecules are constrained within the polymer network of the PEG molecules. The influence of ionic strength and ionic composition of the solution on the formation of a compact form was investigated. The transition of the DNA molecules from a linear to a compact state may occur only at a definite value of ionic strength of the solution. This transition may occur at the change of K+ for Na+ cations (at a constant value of CPEG). The extent of compactization of the DNA molecules in PEG-containing water-salt solutions is monitored by the molecular structure and by the ionic strength of the solvent. It is supposed that the peculiarities of compactization of the DNA molecules in PEG-containing water-salt solutions reflect some characteristics of conformational transitions of the DNA molecules which occur in vivo.     

Osmoelastic coupling in biological structures: decrease in membrane fluidity and osmophobic association of phospholipid vesicles in response to osmotic stress

Poly(ethylene glycol)- (PEG-) induced change in membrane fluidity and aggregation of phospholipid vesicles were studied. A threshold concentration of PEG was required to induce the aggregation. This concentration increased with a decrease in the molecular weight of PEG, e.g., from 5% (w/w) with PEG 6000 (PEG with an average molecular weight of 7500) to more than 30% (w/w) with PEG 200. The aggregation was reversible upon dilution of PEG if the initial PEG concentration was smaller than a certain value, e.g., 22% (w/w) for PEG 6000. Addition of PEG caused a decrease in membrane fluidity of the vesicles detected by fluorescence anisotropy of diphenylhexatriene and by electron spin resonance of a spin-labeled fatty acid. The anisotropy change of diphenylhexatriene fluidity change had an inflection point at approximately 5% (w/w) of PEG 6000, which might suggest that the aggregation would make the decrease of membrane fluidity smaller. Transfer of lipid molecules between phospholipid vesicles was enhanced by the PEG-induced aggregation. The enhancement occurred not only upon direct addition of PEG to the suspending medium, but also upon dialysis of the vesicle suspension against a high concentration of PEG. All these features are consistent with osmoelastic coupling in the phospholipid membranes and the subsequent osmophobic association of the vesicles. The imbalance of osmolarity between the region adjacent to the vesicle surface (exclusion layer) and the bulk aqueous phase, which results from the preferential exclusion of PEG from the exclusion layer in the case of direct addition of PEG, exerts an osmotic stress on the vesicles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enhancement effect of polyethylene glycol on enzymatic synthesis of cephalexin

In an enzymatic synthesis of cephalexin (CEX) using an acylase from Xanthomonas citri, the effect of polyethylene glycol (PEG) on the synthetic reaction of 7-amino-3-deacetoxycephalosporanic acid (7-ADCA) and D-alpha-phenyl-glycine methyl ester (PGM) to CEX was investigated. The addition of PEG (MW 300-20,000) increased the yield significantly. This yield enhancement effect tended to increase with the increasing molecular weight of PEG. Addition of PEG to the reaction system did not affect both the CEX and PGM hydrolytic reactions. The PEG added to the reaction medium used in these experiments did not depress the water activity significantly, and the product yield improvement could not be explained by the activity alone. The PEG stabilized the enzyme activity to some extent, but this stabilizing effect was only partially attributable to the yield enhancement of CEX. The enhancing effect of PEG on the synthetic yield increased with the increasing PEG molecular weight or the length of the poly(oxy-1,2-ethanediyl) chain, which increases the hydrophobicity of PEG. This finding consequently has led to the conclusion that the PEG structure renders the affinity between enzyme and 7-ADCA, which is a hydrophobic substrate. The microenvironmental hydrophobicity of PEG and its interaction with the hydrophobic substrate was found to be the main reason for the improvement of the CEX yield. In fact, the Michaelis-Menten kinetic constant for 7-ADCA, K(7-ADCA) in the presence of PEG was smaller than that in the control system (without PEG addition). (c) 1993 John Wiley & Sons, Inc.     

Mapping the integrin alpha V beta 3-ligand interface by photoaffinity cross-linking

Integrins are cell surface adhesion molecules involved in mediating cell-extracellular matrix interactions. High-resolution structural data are not available for these heterodimeric receptors. Previous cross-linking studies of integrins aimed at elucidating the nature of the receptor-ligand interface have been limited to identification of relatively large binding domains. To create reagents for "photoaffinity scanning" of the RGD-binding site of human integrin alpha V beta 3, new conformationally constrained ligands were designed. These photoreactive ligands are based on cyclo Ac-[Cys-Asn-Dmt-Arg-Gly-Asp-Cys]-OH, which displays an affinity of 50 nM for alpha V beta 3. This molecular scaffold was modified at the C-terminus by a benzophenone-containing amino acid residue, L-4-benzoylphenylalanine (Bpa). At the N-terminus, a molecular tag was introduced in the form of radioactive iodine or biotin. The newly designed tagged photoreactive RGD-containing ligands display an affinity of 0.5-0.7 microM for alpha V beta 3, and cross-link efficiently and specifically to the receptor. A 100 kDa band corresponding to the beta 3 subunit-ligand conjugate was detected as the major cross-linking product. Cross-linking was dependent upon the presence of Ca2+ and Mg2+ ions, and was competitively inhibited by a nonphotoreactive ligand. Enzymatic and chemical digestions of the radiolabeled photoconjugate enabled identification of a 20-amino acid fragment between positions 99 and 118 in the beta 3 chain of the integrin as the contact domain for ligand at a site adjacent to the C-terminal portion of the RGD triad.     

The structure of the zinc sites of Escherichia coli DNA-dependent RNA polymerase.

X-ray absorption spectroscopy is ideally suited for the investigation of the electronic structure and the local environment (approximately 5 A) of specific atoms in biomolecules. While the edge region provides information about the valence state of the absorbing atom, the chemical identity of neighboring atoms, and the coordination geometry, the extended x-ray absorption fine structure region contains information about the number and average distance of neighboring atoms and their relative disorder. The development of sensitive detection methods has allowed studies using near physiological concentrations (as low as approximately 100 microM). RNA polymerase from Escherichia coli contains two zinc atoms: one tightly bound in the beta' subunit, the subunit that participates in template binding, and the other loosely bound in the beta subunit, the subunit that participates in substrate binding. X-ray absorption studies of these zinc sites in the native protein and of the zinc site in the beta' subunit after removal of the zinc in the beta subunit site by p-(hydroxymercuri)benzenesulfonate (Giedroc, D. P., and Coleman, J. E. (1986) Biochemistry 25, 4969-4978) indicate that both zinc sites have octahedral coordination. The zinc in the beta' subunit site has four sulfur ligands at an average distance of 2.36 +/- 0.02 A and two oxygen (or nitrogen) ligands at an average distance of 2.23 +/- 0.02 A. The beta subunit zinc site has five sulfur ligands at an average distance of 2.38 +/- 0.01 A and one histidine nitrogen ligand at 2.14 +/- 0.02 A. These results are in general agreement with earlier biochemical and spectroscopic studies.     

Predicting molecular formulas of fragment ions with isotope patterns in tandem mass spectra

A number of different approaches have been proposed to predict elemental component formulas (or molecular formulas) of molecular ions in low and medium resolution mass spectra. Most of them rely on isotope patterns, enumerate all possible formulas for an ion, and exclude certain formulas violating chemical constraints. However, these methods cannot be well generalized to the component prediction of fragment ions in tandem mass spectra. In this paper, a new method, FFP (fragment ion formula prediction), is presented to predict elemental component formulas of fragment ions. In the FFP method, the prediction of the best formulas is converted into the minimization of the distance between theoretical and observed isotope patterns. And, then, a novel local search model is proposed to generate a set of candidate formulas efficiently. After the search, FFP applies a new multiconstraint filtering to exclude as many invalid and improbable formulas as possible. FFP is experimentally compared with the previous enumeration methods, and shown to outperform them significantly. The results of this paper can help to improve the reliability of de novo in the identification of peptide sequences.     

Designing Redox‐Stable Cobalt–Polypyridyl Complexes for Redox Flow Batteries: Spin‐Crossover Delocalizes Excess Charge

Redox‐active organometallic molecules offer a promising avenue for increasing the energy density and cycling stability of redox flow batteries. The molecular properties change dramatically as the ligands are functionalized and these variations allow for improving the solubility and controlling the redox potentials to optimize their performance when used as electrolytes. Unfortunately, it has been difficult to predict and design the stability of redox‐active molecules to enhance cyclability in a rational manner, in part because the relationship between electronic structure and redox behavior has been neither fully understood nor systematically explored. In this work, rational strategies for exploiting two common principles in organometallic chemistry for enhancing the robustness of pseudo‐octahedral cobalt–polypyridyl complexes are developed. Namely, the spin‐crossover between low and high‐spin states and the chelation effect emerging from replacing three bidentate ligands with two tridentate analogues. Quantum chemical models are used to conceptualize the approach and make predictions that are tested against experiments by preparing prototype Co‐complexes and profiling them as catholytes and anolytes. In good agreement with the conceptual predictions, very stable cycling performance over 600 cycles is found.