"Bridge" structures between nucleic acid molecules fixed in the structure of a liquid crystal

The binding of daunomycin and copper ions to poly(I).poly(C) molecules fixed in a particle of a liquid-crystalline dispersion was studied. A thermodynamic model of adsorption was developed, which makes it possible to describe the formation of complexes of a particular kind, "bridges" that connect adjacent nucleic acid molecules fixed in a liquid crystal. The bridges represent chelate complexes, which incorporate the molecules of the antibiotic daunomycin and copper ions. Equations describing the dependence of the concentration of these bridges in solution on the concentration of their constituents were derived. The family of dependences of experimental amplitudes of bands in CD spectra typical of "bridge" structures on the concentration of copper ions represents a set of S-shaped curves, and, as the concentration of daunomycin in solution increases, the level of saturation of these curves increases. The analysis of experimental data with the use of this model suggests that the structures of this type compete with daunomycin molecules for the binding sites on poly(I).poly(C). By using this model, the energies of formation of bridge structures were calculated.     

Thermodynamic model of the formation of bridges between nucleic acid molecules in a liquid crystal]

A thermodynamic model of the formation of bridges consisting of alternating daunomycin molecules and copper ions and connecting neighboring nucleic acid molecules in a particle of a liquid crystalline dispersion was constructed. The model is based on the conception that ligands are adsorbed on lattices of reaction centers which are formed in a liquid crystal at a particular spatial arrangement of adjacent nucleic acid molecules (phasing). Equations were derived that describe typical experimentally obtained S-shaped dependences of bridge concentration on the concentration of copper ions and daunomycin molecules in an initial solution. It was shown that dependences of this kind take place in two variants of the adsorption model: when the binding of daunomycin with adjacent nucleic acid molecules is considered to be independent on the formation of bridges and when bridges compete with single daunomycin molecules for the sites on adjacent nucleic acid molecules.     

Adjustable ‘cross-linking’ of neighboring DNA molecules in liquid-crystalline dispersions through (daunomycin-copper) polymeric chelate complexes

The interaction of daunomycin molecules with double-stranded DNA in the liquid-crystalline state was investigated. It was shown that at a certain extent of daunomycin binding a change of the mechanism of anthracycline orientation with reference to the DNA chain occurs. This is testified by the alteration of the sense of spatial packing of the DNA molecules in liquid-crystalline dispersions formed as a result of phase separation in poly(ethyleneglycol)-containing solutions, as well as by the onset of the reaction of daunomycin with divalent copper ions. Using this reaction, polymeric (daunomycin-copper) chelate cross-links between the DNA molecules fixed in the liquid-crystalline dispersions were formed. The length of such cross-links is adjusted by the distance between the DNA molecules, which, in turn, depends on the concentration of poly(ethyleneglycol) used for phase separation. The above molecular building mechanism may lead to new interesting applications.     

Molecular construction (superstructures) with adjustable properties based on double-stranded nucleic acids

Formation of molecular construction that consists of double-stranded molecules of nucleic acids (or synthetic polynucleotides) located at the distance 30-50 A in the spatial structure of particles of their cholesteric liquidcrystalline dispersion and crosslinked by polymeric chelate bridges is described. The resulting superstructure, which possesses peculiar physicochemical properties, could be used as integral biosensor whose properties depend on temperature, the presence of chemical or biologically active compounds of different nature, etc.     

Molecular Constructions (Superstructures) with Adjustable Properties Based on Double-Stranded Nucleic Acids

We describe formation of a molecular construction that consists of double-stranded molecules of nucleic acids (or synthetic polynucleotides) located at a distance of 30–50 Å in the spatial structure of particles of their cholesteric liquid-crystalline dispersion and crosslinked by polymeric chelate bridges. The resulting superstructure, which possesses peculiar physicochemical properties, can be used as an integral biosensor whose properties depend on temperature, the presence of chemical or biologically active compounds of different nature, etc.     

Molecular design based on polyribonucleotides fixed in the structure of liquid-crystalline dispersion and cross-linked via polymeric chelate bridges

A method of molecular design based on cross-linking of polyribonucleotide molecules with polymeric chelate bridges (anthracycline-Cu²⁺-…-Cu²⁺-anthracycline) was developed. The formation of polymeric chelate cross-bridges between neighboring polyribonucleotide molecules in the particles of liquid-crystalline dispersions was shown to require the formation of external complex (anthracycline-polyribonucleotide). The properties (shape, size, optical activity, etc.) of molecular constructions composed of different polyribonucleotides were studied and compared. Molecular constructions on the basis of polyribonucleotides could be used as sensing elements with adjustable properties in biosensor technology, nanobiotechnology, and molecular pharmacology.     

Structural studies around cysteine and cystine residues in the “blue” oxidase fungal laccase B. Similarity in amino acid sequence with ceruloplasmin

Fungal laccase B from Polyporus versicolor is a “blue” oxidase containing four copper ions. It consists of a single polypeptide chain of about 545 amino acid residues. The enzyme has been hydrolyzed with pepsin, pronase and thermolysin, and peptides containing the single sulfhydryl group and one of the disulfide bridges have been isolated and characterized. The results show that there is some similarity in amino acid sequence on both sides of the disulfide bridge indicating an internal homology in the laccase molecule. The structure around the single cysteine residue (Leu-His-Cys-His-Ile-Asx-Phe) differs considerably from the cysteine region in low-molecular-weight “blue” proteins like plastocyanin and azurin which contain a single copper ion. However, it shows a pronounced similarity with the sequence around a cysteine residue in human ceruloplasmin suggesting that this structure has an important role in the multi-copper oxidases that is absent or different in the small “blue” proteins. We propose that this role is to constitute a bridge between different copper ions in the molecule and mediate the specific interaction between those which is a crucial feature in the catalytic action of the multi-copper oxidases.     

Comprehensive investigation of a structural variant in a bi-specific,N-and C-terminal Fc-fusion molecule,and its monitoring with LC-MS based method

There is an increasing interest in the generation of Fc-fusion molecules to exploit the effector functions of Fc and the fusion partner, towards improving the therapeutic potential. The Fc-fusion molecules have unique structural and functional attributes that impart various advantages. However, the manufacturing of Fc-fusion molecules possesses certain challenges in the biopharmaceutical development. The fusion of unnaturally occurring two or more domains in a construct can pose problems for proper folding and are prone to aggregation and degradation. Reshuffling of disulfide bridges represents a posttranslational event that affects folding. This can play a critical role in the correct structure of a molecule and leads to structural heterogeneity in biotherapeutics; it may also impact the in vivo biological activities, safety, and efficacy of the biopharmaceutical. Our work presents an investigation case of a doublet band, as observed only in nonreducing sodium dodecyl sulfate - polyacrylamide gel electrophoresis (SDS-PAGE) for a bi-specific, N- and C-terminal Fc-fusion molecule. Other characterization and orthogonal methods from the analytical panel did not indicate the presence of two distinct species, including the orthogonal CE-SDS (Caliper Lab Chip GXII). Therefore, it was necessary to determine if the phenomenon was an analytical artifact or a real variant of our Fc-fusion molecule. With the comprehensive mass spectrometry-based characterization, we were able to determine that the doublet band was related to the reshuffling of one disulfide bridge in one of the fused domains. Our work illustrates the application of nonreducing peptide mapping by mass spectrometry to characterize and identify disulfide variants in a complex N- and C-terminal Fc-fusion molecule, and further adoption to monitor the disulfide structural variants in the intermediate process samples to drive the manufacturing of a consistent product with the desired quality attributes.     

Amino acid sequences of neurotoxic protein variants from the venom of Centruroides sculpturatus Ewing

The venom from the scorpion, Centruroides sculpturatus Ewing (range, Southwestern United States), was fractionated into ten protein zones by chromatography on CM-cellulose. Further purification of three of these zones on DEAE Sephadex in ammonium acetate developers yielded three principal neurotoxins designated variants 1, 2, and 3. Variants 1 and 3 each consist of 65 amino acid residues, variant 2 is composed of 66 residues, and each variant is a single polypeptide chain crosslinked by four disulfide bridges. The three variants have lysine at the amino terminus, serine at the carboxyl terminus, and their sequences exhibit a high degree of homology. The complete structure of variant 2 was deduced from the sequence of its tryptic peptides and overlaps provided by its chymotryptic peptides. The sequences of most of the tryptic peptides of variants 1 and 3 were determined, and the peptides were aligned by comparison with the homologous peptides in variant 2. The results show that there are 4 differences in sequence between variants 2 and 3 and 9 differences between variants 1 and 2. Variants 1 and 3 differ from each other at 5 positions in their sequences. These differences between the three protein variants are found in the amino terminal one-third of the molecules except for the deletion of one seryl residue at the carboxyl terminal of variants 1 and 3.     

Contribution of surface salt bridges to protein stability: guidelines for protein engineering

The small globular protein, ubiquitin, contains a pair of oppositely charged residues, K11 and E34, that according to the three-dimensional structure are located on the surface of this protein with a spatial orientation characteristic of a salt bridge. We investigated the strength of this salt bridge and its contribution to the global stability of the ubiquitin molecule. Using the "double mutant cycle" analysis, the strength of the pairwise interactions between K11 and E34 was estimated to be favorable by 3.6kJ/mol. Further, the salt bridge of the reverse orientation, i.e. E11/K34, can be formed and is found to have a strength (3.8kJ/mol) similar to that of the K11/E34 pair. However, the global stability of the K11/E34 variant of ubiquitin is 2.2kJ/mol higher than that of the E11/K34 variant. The difference in the contribution of the opposing salt bridge orientations to the overall stability of the ubiquitin molecule is attributed to the difference in the charge-charge interactions between residues forming the salt bridge and the rest of the ionizable groups in this protein. On the basis of these results, we concluded that surface salt bridges are stabilizing, but their contribution to the overall protein stability is strongly context-dependent, with charge-charge interactions being the largest determinant. Analysis of 16 salt bridges from six different proteins, for which detailed experimental data on energetics have been reported, support the conclusions made from the analysis of the salt bridge in ubiquitin. Implications of these findings for engineering proteins with enhanced thermostability are discussed.     

Molecular basis of the cooperative binding of Cu(I) and Cu(II) to the CopK protein from Cupriavidus metallidurans CH34

The bacterium Cupriavidus metallidurans CH34 is resistant to high environmental concentrations of many metal ions. Upon copper challenge, it upregulates the periplasmic protein CopK (8.3 kDa). The function of CopK in the copper resistance response is ill-defined, but CopK demonstrates an intriguing cooperativity: occupation of a high-affinity Cu(I) binding site generates a high-affinity Cu(II) binding site, and the high-affinity Cu(II) binding enhances Cu(I) binding. Native CopK and targeted variants were examined by chromatographic, spectroscopic, and X-ray crystallographic probes. Structures of two distinct forms of Cu(I)Cu(II)-CopK were defined, and structural changes associated with occupation of the Cu(II) site were demonstrated. In solution, monomeric Cu(I)Cu(II)-CopK features the previously elucidated Cu(I) site in Cu(I)-CopK, formed from four S(δ) atoms of Met28, -38, -44, and -54 (site 4S). Binding of Cu(I) to apo-CopK induces a conformational change that releases the C-terminal β-strand from the β-sandwich structure. In turn, this allows His70 and N-terminal residues to form a large loop that includes the Cu(II) binding site. In crystals, a polymeric form of Cu(I)Cu(II)-CopK displays a Cu(I) site defined by the S(δ) atoms of Met26, -38, and -54 (site 3S) and an exogenous ligand (modeled as H(2)O) and a Cu(II) site that bridges dimeric CopK molecules. The 3S Cu(I) binding mode observed in crystals was demonstrated in solution in protein variant M44L where site 4S is disabled. The intriguing copper binding chemistry of CopK provides molecular insight into Cu(I) transfer processes. The adaptable nature of the Cu(I) coordination sphere in methionine-rich clusters allows copper to be relayed between clusters during transport across membranes in molecular pumps such as CusA and Ctr1.     

New 9- or 10-dentate luminescent lanthanide chelates

Polyaminocarboxylate-based luminescent lanthanide complexes have unusual emission properties, including millisecond excited-state lifetimes and sharply spiked spectra compared to common organic fluorophores. There are three distinct sections in the structure of the luminescent lanthanide chelates: a polyaminocarboxylate backbone to bind the lanthanide ions tightly, an antenna molecule to sensitize the emission of lanthanide ions, and a reactive group to attach to biomolecules. We have previously reported the modifications on the chelates, on the antenna molecules (commonly cs124), and on the reactive sites. In searching for stronger binding chelates and better protection from solvent hydration, here we report the modification of the coordination number of the chelates. A series of 9- and 10-dentate chelates were synthesized. Among them, the 1-oxa-4,7-diazacyclononane (N2O)-containing chelate provides the best protection to the lanthanide ions from solvent molecule attack, and forms the most stable lanthanide coordination compounds. The TTHA-based chelate provides moderately good protection to the lanthanide ions.     

Comprehensive secondary‐structure analysis of disulfide variants of lysozyme by synchrotron‐radiation vacuum‐ultraviolet circular dichroism

To elucidate the effects of specific disulfide bridges (Cys6‐Cys127, Cys30‐Cys115, Cys64‐Cys80, and Cys76‐Cys94) on the secondary structure of hen lysozyme, the vacuum‐ultraviolet circular dichroism (VUVCD) spectra of 13 species of disulfide‐deficient variants in which Cys residues were replaced with Ala or Ser residues were measured down to 170 nm at pH 2.9 and 25°C using a synchrotron‐radiation VUVCD spectrophotometer. Each variant exhibited a VUVCD spectrum characteristic of a considerable amount of residual secondary structures depending on the positions and numbers of deleted disulfide bridges. The contents of α‐helices, β‐strands, turns, and unordered structures were estimated with the SELCON3 program using the VUVCD spectra and PDB data of 31 reference proteins. The numbers of α‐helix and β‐strand segments were also estimated from the VUVCD data. In general, the secondary structures were more effectively stabilized through entropic forces as the number of disulfide bridges increased and as they were formed over larger distances in the primary structure. The structures of three‐disulfide variants were similar to that of the wild type, but other variants exhibited diminished α‐helices with a border between the ordered and disordered structures around the two‐disulfide variants. The sequences of the secondary structures were predicted for all the variants by combining VUVCD data with a neural‐network method. These results revealed the characteristic role of each disulfide bridge in the formation of secondary structures. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Hydration of oligonucleotides in crystals

The solvent molecules found around crystallized oligonucleotides after X-ray refinement are analysed in terms of interaction sites to bases, phosphates and sugars in the three main forms of nucleic acid structures, the A-form, the B-form and the Z-form. The average numbers of contacts to nucleic acid atoms made by solvent molecules are identical in the three forms, but it appears that the average number of contacts solvent molecules make with each other depends on the resolution of the structure. The phosphate anionic oxygen atoms are the most hydrated, while the O(3′) and O(5′) backbone atoms and the ring oxygen atom O(4′) are the least hydrated. Among the hydrophilic atoms of the bases, there is a modulation of the relative water affinities with the nucleic acid form. Numerous hydration sites are such that water molecules can bridge hydrophilic atoms of the same residue, of adjacent residues on the same strand, of distant residues on the two strands, or belonging to symmetry-related residues. Through the helical periodicity of the nucleic acid structure, those bridges can lead to regular and striking hydration networks involving several water molecules and characteristic of the nucleic acid form. Solvent dynamics, as seen by temperature factor versus occupancy plots, seems intimately related to nucleic acid structure and dynamics, since they depend on hydration sites around the nucleic acids.     

The covalent structure of the elastase inhibitor from Anemonia sulcata--a "non-classical" Kazal-type protein

The amino-acid sequence of the proteinase inhibitor specific for elastases from the sea anemone Anemonia sulcata was determined from performic-acid oxidized inhibitor and from three cyanogen bromide fragments of reduced and carboxymethylated inhibitor. The molecule consists of a single polypeptide chain formed from 48 amino-acid residues and is stabilized by three intramolecular disulfide bridges. After cyanogen bromide cleavage of the native protein at methionines 10 and 28 followed by chymotryptic cleavage two fragments each containing a single disulfide bridge were isolated. These indicated the location of three intramolecular disulfide linkages between Cys4 and Cys34 (part of A-loop), Cys8 and Cys27 (B-loop) and Cys16 and Cys48 (C-loop). The sequential homology and the disulfide pattern identified the elastase inhibitor as a Kazal-type inhibitor in which, however, not only the CysI-CysII segment is rather short but interestingly the Cys4-Cys34 disulfide anchoring point (i.e. CysI-CysV) in the C-loop is shifted by one turn in the alpha-helical segment towards the C-terminus. Thus, the elastase inhibitor is a non-classical Kazal-type inhibitor with respect to the positioning of the half-cystines. The inhibitor molecule was modelled based on the known three-dimensional structure of the silver pheasant ovomucoid third domain. The shortened amino-terminal segment was arranged in such a manner to allow disulfide bridge formation between the first cysteine Cys4 and the replaced Cys34 under maintenance of a suitable binding loop conformation. The characteristic ovomucoid scaffold consisting of a central alpha-helix, an adjacent three-stranded beta-sheet and the proteinase-binding loop cross-connected through disulfide bridges CysI-CysV and CysIII-CysVI was conserved.     

Study of the complex formation of daunomycin with deoxytetranucleotides with bases of differing sequence in an aqueous solution by 1H-NMR spectroscopy

The complex formation of the antibiotic daunomycin with deoxytetranucleotides of different base sequence in the chain, 5'-d(GpCpGpC), 5'-d(CpGpCpG), and 5'-d(TpGpCpA) in aqueous salt solution was studied by 1D and 2D (2M-TOCSY and 2M-NOESY) 1H-NMR spectroscopy. Concentration and temperature dependences of proton chemical shifts of molecules were measured. Based on these dependences, reaction equilibrium constants, relative content of various complexes depending on concentration and temperature, limiting values of chemical shifts of protons of daunomycin incorporated in various complexes, and the thermodynamic parameters delta H and delta S of complex formation were calculated. The analysis of the results enables the conclusion that the sites of predominant intercalation of daunomycin are triplet nucleotide sequences, the binding sites of the antibiotic with three consecutive GC pairs in the tetranucleotide duplex being more preferential. Daunomycin exhibits no sequence specificity upon binding to the single-stranded deoxynucleotide sequence. From the calculated values of induced chemical shifts of daunomycin protons and 2M-NOE data, the most probable spatial structures of complexes (1:2) of the antibiotic with deoxytetranucleotides were constructed. The binding of the second daunomycin molecule to both the single-stranded and duplex form of tetramers is of pronounced anticooperative mode, which is explained by the presence in the antibiotic of a positively charged amino sugar residue, which poses considerable steric constraints for the insertion of the second antibiotic molecule into the short tetranucleotide sequence. The results were compared with the data obtained under identical experimental conditions for typical intercalators proflavine and ethidium bromide.     

Cu2+ Affects Amyloid-β (1–42) Aggregation by Increasing Peptide-Peptide Binding Forces

The link between metals, Alzheimer''s disease (AD) and its implicated protein, amyloid-β (Aβ), is complex and highly studied. AD is believed to occur as a result of the misfolding and aggregation of Aβ. The dyshomeostasis of metal ions and their propensity to interact with Aβ has also been implicated in AD. In this work, we use single molecule atomic force spectroscopy to measure the rupture force required to dissociate two Aβ (1–42) peptides in the presence of copper ions, Cu²⁺. In addition, we use atomic force microscopy to resolve the aggregation of Aβ formed. Previous research has shown that metal ions decrease the lag time associated with Aβ aggregation. We show that with the addition of copper ions the unbinding force increases notably. This suggests that the reduction of lag time associated with Aβ aggregation occurs on a single molecule level as a result of an increase in binding forces during the very initial interactions between two Aβ peptides. We attribute these results to copper ions acting as a bridge between the two peptide molecules, increasing the stability of the peptide-peptide complex.     

The role of copper in cysteine oxidation: study of intra- and inter-molecular reactions in mass spectrometry

Cysteine-containing peptide oxidation was studied both by using an inert platinum electrode and a sacrificial electrode (copper or zinc) generating metallic ions in electrospray ionization mass spectrometry (ESI-MS). Using peptides containing one, two and three cysteines, we have compared the different chemical and electrochemical oxidation pathways of cysteine (RS(-II)H) to cystine (RS(-I)S(-I)R) and to sulfenic, sulfinic and sulfonic acid (RS(0)OH, RS(II)O(2)H and RS(IV)O(3)H, respectively). In the absence of copper ions, intra-molecular reactions were the most abundant, whereas inter-molecular reactions were found to be enhanced by the presence of copper ions. These cations favor the formation of 2 : 1 (peptide : copper) complexes compared to 1 : 1 complexes, thus enhancing the formation of inter-molecular bridges. This study highlights the importance of the position of cysteine inside a peptide during disulfide bridge formation.     

Retarded protein folding of deficient human alpha 1-antitrypsin D256V and L41P variants

alpha(1)-Antitrypsin is the most abundant protease inhibitor in plasma and is the archetype of the serine protease inhibitor superfamily. Genetic variants of human alpha(1)-antitrypsin are associated with early-onset emphysema and liver cirrhosis. However, the detailed molecular mechanism for the pathogenicity of most variant alpha(1)-antitrypsin molecules is not known. Here we examined the structural basis of a dozen deficient alpha(1)-antitrypsin variants. Unlike most alpha(1)-antitrypsin variants, which were unstable, D256V and L41P variants exhibited extremely retarded protein folding as compared with the wild-type molecule. Once folded, however, the stability and inhibitory activity of these variant proteins were comparable to those of the wild-type molecule. Retarded protein folding may promote protein aggregation by allowing the accumulation of aggregation-prone folding intermediates. Repeated observations of retarded protein folding indicate that it is an important mechanism causing alpha(1)-antitrypsin deficiency by variant molecules, which have to fold into the metastable native form to be functional.     

Specific and nonspecific macromolecule-drug conjugates for the improvement of cancer chemotherapy

Antineoplastic drugs such as daunomycin, adriamycin, methotrexate, 5-fluorouridine, cytosine arabinoside, and platinate were bound to antibodies directly or via a polymeric bridge. The drug antibody conjugates retained most of their drug and antibody activities when tested in vitro. Daunomycin–antibody conjugates were shown to penetrate tumor cells in the conjugated form. In animals, daunomycin–antibody conjugates were at least as effective chemotherapeutically as the corresponding free drugs and considerably less toxic. In some tumor systems, the daunomycin–antibody conjugates represented an improvement over the free drug. This improvement was restricted in some tumors to a particular injection route of the tumor and the treatment.