Electronic structure and molecular design of simplified polyimide systems

The electronic structures of newly designed polyimide systems (ethenetetracarboxylic 1,2:1,2-dianhydride-diaminoethyne (PI-A) and ethenetetracarboxylic 1,1:2,2-dianhydride-diaminoethyne(PI-B)) are studied in detail with respect to their optimized geometries on the basis of the one-dimensional tight-binding self-consistent field crystal-orbital method. The computational results have revealed that PI-B shows intriguing properties such as a very small band gap and a wide bandwidth near the frontier level, compared with PI-A and other polyimides. Since PI-B would be a promising candidate for a new electric conducting material, a reaction diagram for this polymer is also proposed.Also affiliated to Central Research Laboratories, Matsushita Electric Industrial Co., Moriguchi 570, Japan.     

M-DNA: A complex between divalent metal ions and DNA which behaves as a molecular wire

M-DNA is a complex of DNA with divalent metal ions (Zn(2+), Co(2+), or Ni(2+)) which forms at pH conditions above 8. Upon addition of these metal ions to B-DNA at pH 8.5, the pH decreases such that one proton is released per base-pair per metal ion. Together with previous NMR data, this result demonstrated that the imino proton in each base-pair of the duplex was substituted by a metal ion and that M-DNA might possess unusual conductive properties. Duplexes of 20 base-pairs were constructed with fluorescein (donor) at one end and rhodamine (acceptor) at the other. Upon formation of M-DNA (with Zn(2+)) the fluorescence of the donor was 95 % quenched. Fluorescence lifetime measurements showed the presence of a very fast component in the decay kinetics with tau相似文献   

AC impedance spectroscopy of native DNA and M-DNA

Monolayers of thiol-labeled DNA duplexes of 15, 20, and 30 basepairs were assembled on gold electrodes. Electron transfer was investigated by electrochemical impedance spectroscopy with Fe(CN)(6)(3-/4-) as a redox probe. The spectra, in the form of Nyquist plots, were analyzed with a modified Randles circuit which included an additional component in parallel, R(x), for the resistance through the DNA. For native B-DNA R(x) and R(ct), the charge transfer resistance, both increase with increasing length. M-DNA was formed by the addition of Zn(2+) at pH 8.6 and gave rise to characteristic changes in the Nyquist plots which were not observed upon addition of Mg(2+) or at pH 7.0. R(x) and R(ct) also increased with increasing duplex length for M-DNA but both were significantly lower compared to B-DNA. Therefore, electron transfer via the metal DNA film is faster than that of the native DNA film and certain metal ions can modulate the electrochemical properties of DNA monolayers. The results are consistent with an ion-assisted long-range polaron hopping mechanism for electron transfer.     

Cytoplasm-enriched fragments ofChara: structure and electrophysiology

Summary Cytoplasm-enriched fragments prepared from internodal cells ofChara corallina by centrifugation contain membrane bound vesicles ranging in size from a few m to hundreds of m. If the fragments are incubated in artificial pond water (APW) of pH₀ above 6.5, neutral red stains the inside of many vesicles bright crimson, suggesting the presence of inward proton-pumping. In APW of pH₀ below 6 crimson vesicles are found less frequently. Under such conditions most vesicles remain unstained inside and some develop indistinct pink halos. After a few days most fragments form a central vacuole, which stains red, regardless of the pH₀. The cytoplasmic layer still contains vesicles after vacuole formation.In order to identify the membrane bounding the vesicles various fluorescent probes were applied either by injection into the fragment or directly onto the vesicles released into artificial cytoplasm. Lucifer yellow or 6 COOH-F move readily across the tonoplast in intact cells, but did not enter any vesicles. On the other hand, the fluorescent cationic stain DIOC, which is used to highlight mitochondria and especially endoplasmic reticulum, stained the vesicle membrane. Numerous elliptical or kidney shaped nuclei in the flowing cytoplasm were highlighted with DAPI. In some fragments the nuclei formed large agreggates sometimes filling the width of the fragment.Patch-clamping the vesicles in artificial cytoplasm showed the presence of several kinds of channels, some displaying similar behaviour to the K⁺ channels observed in cytoplasmic droplets.Analogous to the plasmalemma of intact cells, the fragments without vacuoles displayed electrophysiological states dominated by either K⁺ conduction, H⁺ (or OH^–) conduction or the proton pump. On the other hand, excitation transients in fragments were of low amplitude or absent altogether. Detailed comparisons of data from fragments and intact cells are shown. The effect of vacuole formation on fragment electrophysiology was also explored.     

Crystal structure and conformational analysis of angiotensinogen fragments

The tripeptide acetyl-L-prolyl-L-phenylalanyl-L-histidine crystallizes in the orthorhombic space group P2(1)2(1)2(1) with eight molecules in a unit cell of dimensions a = 9.028(2), b = 140.54(6) and c = 42.41(1)A. The structure has been solved by direct methods and refined to an R value of 0.056 for 2904 observed reflections. The molecule exists as a zwitterion with terminal (His)CO2- and (imidazole)H+ as charged groups. The two peptide molecules in the structure adopt a type I beta-turn with Pro and Phe as the corner residues. The main conformational difference between the two crystallographically independent molecules is seen to be in the histidine side-chain orientations. The molecules arrange themselves in sheets perpendicular to the c axis. All hydrophobic side chains lie on one side of the sheets thus generated, whereas the hydrophilic groups are located on the other side. An interesting feature of the crystal structure is the existence of a water layer between adjacent peptide sheets. The conformational study of the isolated Ac-His-Pro-Phe-His-MA using energy calculations gives a rather limited number of stable conformers. The most stable corresponds to a type I beta-turn stabilized through two hydrogen bonds, followed by a less stable type II beta-turn (delta E = 2.0 kcal) and a partly helical structure (delta E = 2.6 kcal).     

Electron injection from the side of an M-DNA duplex

M-DNA is a complex formed between duplex DNA and divalent metal ions (Zn²⁺, Cu²⁺ or Ni²⁺) at pHs above 8. Previous results showed that the fluorescence of an electron donor fluorophore was quenched when an acceptor flourophore was placed in the opposite end of an M-DNA duplex suggesting electron transfer through the duplex and indicating M-DNA may operate as a better conductor than B-DNA. To further investigate the properties of M-DNA, oligodeoxynucleotides were prepared with fluorescein (Fl) as an electron donor placed at different positions along the helix. An internal position of the chromophore was made possible by attaching it to the extra hydroxyl arm in the branched monomer 4′-C-hydroxymethylthymidine. Upon excitation of the donor fluorophore, it was demonstrated that electrons could be injected into the side of an M-DNA helix thereby extending the range of nanoelectronic structures that can be prepared from DNA. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Low molecular weight indole fragments as IMPDH inhibitors

The study of non-oxazole containing indole fragments as inhibitors of inosine monophosphate dehydrogenase (IMPDH) is described. The synthesis and in vitro inhibitory values for IMPDH II are discussed.     

Electronic mechanisms of molecular oxygen bioactivation

Electronic mechanisms of reductive activation of O2 by oxidases coenzymes (K) are considered. Activation is induced by triplet-singlet (T-S)-transitions at the charge-transfer stage and K+...O2- radical pair (RP) formation. For flavoproteins the spin reversion is induced by spin-orbit coupling (SOC) in superoxide ion, for metal-oxidases--by exchange interaction with paramagnetic metal ion. Another type of spin activation is connected with the singlet peroxide ion O(2)2- formation in cytochromes (structures of the type Fe(3+)-O- -O-Cu2+).     

Thermodynamic investigation of M-DNA: a novel metal ion-DNA complex

The thermodynamics of formation of a novel divalent metal ion-DNA complex known as M-DNA have been investigated using an ethidium bromide (EB) fluorescence assay, and with isothermal titration calorimetry. The process of M-DNA formation was observed from the EB assay to be strongly temperature-dependent. The binding of Zn(2+) to calf thymus (42% GC content) and Escherichia coli (50% GC content) DNA at pH 8.5 exhibited an endothermic cooperative binding process at Zn(2+) concentrations of approximately 0.1 mM, indicating an entropy driven process. This binding process is consistent with a site-specific binding interaction, similar in nature to Z-DNA formation; however, the interaction occurs at much lower metal ion concentrations. The enthalpy of M-DNA formation for calf thymus DNA was determined to be 10.5+/-0.7 and 9+/-2 kJ/mbp at DNA concentrations of 100 and 50 microg ml(-1), respectively. An enthalpy of 13+/-3 kJ/mbp was obtained for M-DNA formation for 50 microg ml(-1) E. coli DNA. No evidence of M-DNA formation was observed in either DNA at pH 7.5 with Zn(2+) or at either pH 7.5 or 8.5 with Mg(2+).     

Computation of the structure of collagen molecule fragments

Step-by-step computations of octapeptide structures was performed for human collagens I and III. It was shown that computational results (coordinates of atoms) practically coincide with X-ray data for the collagen fragment.     

Electronic structure calculations on the thiazole-containing antibiotic thiostrepton: molecular mechanics, semi-empirical and ab initio analyses

Thiostrepton is a highly complex cyclic thiazoyl peptide antibiotic and is active against Gram-positive bacteria. Molecular mechanics, semi-empirical and ab initio studies were utilized to further understand the structural and electronic properties of this antibiotic.     

Electronic structure and biological activity of steroids

We present the analysis of the electronic structure for 31 steroids by using HeI UV photoelectron spectroscopy (UPS) and MO calculations. The electronic structure of molecules in the gas phase is related directly to steroid-receptor binding measurements. The results indicate that formally 'inert' sigma-skeleton plays a crucial role in diversifying the electronic structures of the title compounds ('ribbon-orbital effect'). This is an attempt to rationalize the biological activity of steroids (represented through steroid-receptor binding) by making direct correlation between spectroscopic and biological data.     

Electronic structure of polysilole and related compounds

The electronic structures, in the optimized geometries, of polysilacyclopentadiene (polysilole), polygermacyclopentadiene, and silole-thiophene alternating copolymer, have been studied theoretically using the one-dimensional tight-binding self-consistent field crystal orbital (SCF-CO) method. It has been found that the band gap values of these polymers are slightly smaller than those of the ordinary five-membered polyheterocycles such as polythiophene. The larger -polarized nature between the Group IV atom and the carbon atom might be expected to exhibit a different behaviour, compared with polythiophene, when they are doped with ann-type dopant.     

Mitochondria can recognize and assemble fragments of a beta-barrel structure

β-barrel proteins are found in the outer membranes of eukaryotic organelles of endosymbiotic origin as well as in the outer membrane of Gram-negative bacteria. Precursors of mitochondrial β-barrel proteins are synthesized in the cytosol and have to be targeted to the organelle. Currently, the signal that assures their specific targeting to mitochondria is poorly defined. To characterize the structural features needed for specific mitochondrial targeting and to test whether a full β-barrel structure is required, we expressed in yeast cells the β-barrel domain of the trimeric autotransporter Yersinia adhesin A (YadA). Trimeric autotransporters are found only in prokaryotes, where they are anchored to the outer membrane by a single 12-stranded β-barrel structure to which each monomer is contributing four β-strands. Importantly, we found that YadA is solely localized to the mitochondrial outer membrane, where it exists in a native trimeric conformation. These findings demonstrate that, rather than a linear sequence or a complete β-barrel structure, four β-strands are sufficient for the mitochondria to recognize and assemble a β-barrel protein. Remarkably, the evolutionary origin of mitochondria from bacteria enables them to import and assemble even proteins belonging to a class that is absent in eukaryotes.     

Influence of molecular size on tissue distribution of antibody fragments

Biodistribution coefficients (BC) allow estimation of the tissue concentrations of proteins based on the plasma pharmacokinetics. We have previously established the BC values for monoclonal antibodies. Here, this concept is extended by development of a relationship between protein size and BC values. The relationship was built by deriving the BC values for various antibody fragments of known molecular weight from published biodistribution studies. We found that there exists a simple exponential relationship between molecular weight and BC values that allows the prediction of tissue distribution of proteins based on molecular weight alone. The relationship was validated by a priori predicting BC values of 4 antibody fragments that were not used in building the relationship. The relationship was also used to derive BC50 values for all the tissues, which is the molecular weight increase that would result in 50% reduction in tissue uptake of a protein. The BC50 values for most tissues were found to be ~35 kDa. An ability to estimate tissue distribution of antibody fragments based on the BC vs. molecular size relationship established here may allow better understanding of the biologics concentrations in tissues responsible for efficacy or toxicity. This relationship can also be applied for rational development of new biotherapeutic modalities with optimal biodistribution properties to target (or avoid) specific tissues.     

Automated molecular library generation of proteic fragments by virtual proteolysis for molecular modelling studies

This paper presents a computer aided design method useful for simulation of a set of proteolytic cleavages upon target proteins obtained from the Brookhaven Data Bank. The method was developed by using algorithms that are able to interface themselves with other software environments, in order to assist computer analyses in the molecular modelling field, and allowing the generation of molecular libraries containing protein fragments produced by simulated proteolysis. These libraries include structures that differ for several amino acid deletions upon specified regions of the primary sequence. Target residues chosen for the simulation are compatible with enzymatic proteolysis methods used in conventional laboratory procedures. Furthermore, algorithms were able to identify a set of chemical-physical properties of the starting proteins, leading the simulation to find out the most suitable residues for proteolysis. The goal of these strategies is to generate fragments that are leaded to maintain the native-like condition of starting molecules, avoiding loss of conformational characteristics of the original tertiary structure. Proteins chosen for generating proteolytic libraries were represented by naphthalene 1,2 dioxygenase and Rigidoporus lignosus laccase.