Beta Bond Research Articles

Isovalent Substitution Effects of Arsenic on Structural and Electrical Properties of Iron-Based Superconductor NdFeAsO0.8F0.2

In this paper, nominal compositions of NdFeAsO0.8F0.2, NdFeAs0.95Sb0.05O0.8F0.2 and NdFeAs0.95P0.05O0.8F0.2 were prepared by one step solid state reaction method. The structural, electrical and morphological properties of samples were characterized through the XRD pattern, the 4 probe method and SEM, respectively. The crystal structure of our samples was tetragonal with P4/nmm:2 symmetry group. Also, the (x, y, z) and occupancy of ions and lattice parameters were changed by isovalent substitution of Phosphorus P and Antimony Sb in the NdFeAsO0.8F0.2 sample. The alfa and beta bond angles and Fe-As bond length are changed from the corresponding value of alfa and beta regular FeAs4 tetrahedron by isovalent doping p/As and Sb/As, that they are effective on the superconductivity transition temperature. The microstrain and crystalline size of samples were studied by the Williamson Hall method. The superconducting critical temperatures were attained at 56K and 46K for NdFeAsO0.8F0.2, NdFeAs0.95Sb0.05O0.8F0.2, respectively. The NdFeAs0.95P0.05O0.8F0.2 showed the structural transition temperature at 140K. It seems that there is a relation between the superconductivity and shrinkage of the crystal lattice. The flake type of grains was observed by SEM pictures of samples.

Multichannel decomposition and isomerization of octyl radicals

The thermal cracking patterns from the decomposition and isomerization of octyl-1 radicals have been determined from the pyrolysis of n-octyl iodide in single pulse shock tube experiments at temperatures in the 850–1000K range and pressures near 2bar. Rate constants for the six beta bond scission and five of the six isomerization processes have been derived over all combustion conditions [0.1–100bar, 700–1900K]. Comparisons are made with previous studies on the decomposition of other primary radicals. Results are consistent with similar types of reactions having equal rate constants. The larger size of the octyl radicals makes contributions from secondary to secondary radical isomerization increasingly important. The results confirm that the 1–3 H-transfer process (involving a seven member cyclic transition state) have rate constants that are within a factor of 2 of those for the 1–4 process (six member cyclic transition state) It appears that rate constants for 1–2 H-transfer isomerization, involving an eight member cyclic transition state is unimportant in comparison to contributions from other isomerization processes. The strain energy does not appear to play an important role for these larger transition states. The implications of these results to larger fuel radicals will be discussed.

Modeling of cw-EPR Spectra of Propagating Radicals in Methacrylic Polymerization at Different Temperatures

The temperature dependence of the cw-EPR spectra corresponding to the propagating radical responsible for the polymerization of methacrylic monomers has been simulated by an integrated computational approach that determines the structural and magnetic parameters (via quantum mechanical calculations) and diffusive properties (via hydrodynamic based methods), which represent the overall input of the stochastic Liouville equation that yields the spectrum. The system has been modeled as a rotator with only one relaxation process, the rotation around the C alpha-C beta bond. The simulations clearly indicate that the change of the spectral shape with the temperature is essentially related to the internal flexibility of the radical end.

Investigations of the MceIJ-Catalyzed Posttranslational Modification of the Microcin E492 C-Terminus: Linkage of Ribosomal and Nonribosomal Peptides To Form “Trojan Horse” Antibiotics

MceIJ is a two protein complex responsible for attachment of a C-glycosylated and linearized derivative of enterobactin, an iron scavenger (siderophore) and product of nonribosomal peptide synthetase machinery, to the C-terminal serine residue of microcin E492 (MccE492), an 84 aa ribosomal antibiotic peptide produced by Klebsiella pneumoniae RYC492. The MceIJ-catalyzed formation of the glycosyl ester linkage between MccE492 and the siderophore requires ATP and Mg(II) as cofactors. This work addresses the ATP utilization, mechanism of C-terminal carboxylate activation, and substrate scope of MceIJ. Formation of the ribosomal peptide-nonribosomal peptide linkage between the MccE492 C-terminal decapeptide and monoglycosylated enterobactin (MGE) requires cleavage of the alpha,beta bond of ATP and formation of a putative peptidyl-CO-AMP intermediate. Attack of the peptidyl-CO-AMP carbonyl by the deprotonated C4' hydroxyl of the glucose moiety forms a glycosyl ester linkage with release of AMP. Site-directed mutagenesis of the three cysteines and five histidines in MceI to alanines reveals that these residues are not required structurally or catalytically. MceIJ recognizes all glycosylated enterobactin derivatives formed by the MccE492 gene cluster members MceC ( C-glycosyltransferase) and MceD (esterase) in vitro and a MGE derivative lacking the C6' hydroxyl moiety. The protein complex also accepts and modifies the C-terminal decapeptide substrate fragments of the structurally related microcins H47, I47, and M. MccE492 C-terminal decapeptides bearing fluorescein and biotin moieties on the N-terminus are also substrates for MceIJ, which provides a route for the chemoenzymatic synthesis of enterobactin conjugates with peptide linkages.

Trans-Stilbene degradation by Arthrobacter sp. SL3 cells

trans-Stilbene degradation was examined by the reaction using resting cells of microorganisms isolated through the enrichment culture using trans-stilbene. The strain SL3, showing the highest trans-stilbene-degrading activity, was identified as Arthrobacter sp. One of the reaction products was identified to be cis,cis-muconic acid. Arthrobacter sp. SL3 cells also transformed benzaldehyde, benzoic acid and catechol into cis,cis-muconic acid, suggesting that one benzene ring of trans-stilbene was converted into cis,cis-muconic acid via benzaldehyde formed by its C(alpha)=C(beta) bond cleavage.

A Theoretical Investigation of p-Hydroxyphenacyl Caged Phototrigger Compounds: An Examination of the Excited State Photochemistry of p-Hydroxyphenacyl Acetate

Ab initio and density functional theory methods were employed to study the excited states and potential energy surfaces of the p-hydoxyphenacyl acetate (HPA) phototrigger compound. Complete active space (CAS) ab initio calculations predicted adiabatic electronic transition energies for the HPA-T(1)((3)npi), HPA-T(2)((3)pipi), HPA-S(1)((1)npi), HPA-T(3)((3)npi), HPA-S(2)((1)npi), HPA-S(3)((1)pipi) <-- HPA-S(0) transitions that were similar to and in agreement with those found experimentally for closely related aromatic ketones such as p-hydroxyacetophenone and results from similar calculations for other related aromatic carbonyl systems. The alpha or beta bond cleavage reactions from the S(1) excited state were both found to have relatively high barriers to reaction, and the S(1), T(1), and T(2) states are close in energy with the three S(1)((1)npi), T(1)((3)npi), and T(2)((3)pipi) surfaces intersecting at the same region. The calculations suggest that intersystem crossing (ISC) can occur very fast from the S(1) state to the nearby triplet states. This is consistent with results from ultrafast spectroscopy experiments that observe the S(1) state ISC occurs within about 1-2 ps to produce a triplet state for HPA and related pHP compounds. The alpha and beta bond cleavage reactions for the T(1) state of HPA are both predicted to have fairly high barriers and compete with one another. However, this is not completely consistent with experiments that observe the photodeprotection reactions (e.g. the beta bond cleavage) of HPA and some other pHP phototriggers in largely water containing solvents are predominant and occur very fast to release the leaving group. Comparison of the computational results with experimental results for HPA and related pHP compounds suggests that water molecules likely play an important part in changing the triplet state beta bond cleavage so that it becomes the predominant pathway and occurs very fast to give an efficient deprotection reaction. The results reported here provide new insight into the photophysics, reaction pathways, and photochemistry of the p-hydoxyphenacyl acetate and related pHP caged phototrigger compounds and also provide a benchmark for further and more sophisticated investigations in the future.

Alcohols, ethers, carbohydrates, and related compounds. I. The MM4 force field for simple compounds.

Simple alcohols and ethers have been studied with the MM4 force field. The structures of 13 molecules have been well fit using the MM4 force field. Moments of inertia have been fit with rms percentage errors as indicated: 18 moments for ethers, 0.28%; 21 moments for alcohols, 0.22%. Rotational barriers and conformational equilibria have also been examined, and the experimental and ab initio results are reproduced substantially better with MM4 than they were with MM3. Much of the improvement comes from the use of additional interaction terms in the force constant matrix, of which the torsion-bend and torsion-torsion are particularly important. Induced dipoles are included in the calculation, and dipole moments are reasonably well fit. It has been possible for the first time to fit conformational energetic data for both open chain and cyclic alcohols (e.g., propanol and cyclohexanol) with the same parameter set. For vibrational spectra, over a total of 82 frequencies, the rms error is 27 cm(-1), as opposed to 38 cm(-1) with MM3. Both the alpha and beta bond shortening resulting from the presence of the electronegative oxygen atom in the molecule are well reproduced. The electronegativity of the oxygen is sufficient that one must also include not only the alpha and beta electronegativity effects on bond lengths, but also on angle distortions, if structures are to be well reproduced. The heats of formation of 32 alcohols and ethers were fit overall to within experimental error (weighted standard deviation error 0.26 kcal/mol).

Rates of oxygen and hydrogen exchange as indicators of TPQ cofactor orientation in amine oxidases.

This study presents the first detailed examination by resonance Raman (RR) spectroscopy of the rates of solvent exchange for the C5 and C3 positions of the TPQ cofactor in several wild-type copper-containing amine oxidases and mutants of the amine oxidase from Hansenula polymorpha (HPAO). On the basis of crystal structure analysis and differing rates of C5 [double bond] O and C3 [bond] H exchange within the enzyme systems, but equally rapid rates of C5 [double bond] O and C3 [bond] H exchange in a TPQ model compound, it is proposed that these data can be used to determine the TPQ cofactor orientation within the active site of the resting enzyme. A rapid rate of C5 [double bond] O exchange (t(1/2) < 30 min) and a slow (t(1/2) = 6 h) to nonexistent rate of C3 [bond] H exchange was observed for wild-type HPAO, the amine oxidase from Arthrobacter globiformis, pea seedling amine oxidase at pH 7.1, and the E406Q mutant of HPAO. This pattern is ascribed to a productive TPQ orientation, with the C5 [double bond] O near the substrate-binding site and the C3 [bond] H near the Cu. In contrast, a slow rate of C5 [double bond] O exchange (t(1/2) = 1.6-3.3 h) coupled with a fast rate of C3 [bond] H exchange (t(1/2) < 30 min) was observed for the D319E and D319N catalytic base mutants of HPAO and for PSAO at pH 4.6 (t(1/2) = 4.5 h for C5 [double bond] O exchange). This pattern identifies a flipped orientation, involving 180 degrees rotation about the C alpha-C beta bond, which locates the C3 [bond] H near the substrate-binding site and the C5 double bond] O near the Cu. Finally, fast rates of both C5 [double bond] O and C3 [bond] H exchange (t(1/2) < 30 min) were observed for the amine oxidase from Escherichia coli and the N404A mutant of HPAO, suggesting a mobile cofactor, with multiple TPQ orientations between productive and flipped. These results demonstrate that opposing sides of the TPQ ring possess different degrees of solvent accessibility and that the rates of C5 [double bond] O and C3 [bond] H exchange can be used to predict the TPQ cofactor orientation in the resting forms of these enzymes.

Influence of thermal motion on 1H chemical shifts in proteins: the case of bovine pancreatic trypsin inhibitor.

The possible influence of thermal motion on 1H chemical shifts is discussed for a small stable protein, the bovine pancreatic Kunitz trypsin inhibitor (BPTI). The thermal effects on the aromatic side chains and on the backbone are treated separately. The thermal motion of the aromatic side chains is accounted for in terms of their rotation around the C(alpha)-C(beta) bond and the motion of each individual proton is interpreted as a ratio between the amount of ordered and quite disordered states. The influence of hydrogen bonds is introduced as an extra contribution to the chemical shifts of the bonded proton. Their contribution to the chemical shifts resulting from the polarization of the peptide bond is investigated, as is their influence on local flexibility. Finally, the relative importance of each contribution to the chemical shift information is compared.

Design criteria for molecular mimics of fragments of the beta-turn. 2. C alpha-C beta bond vector analysis.

In a previous paper, we have shown the utility of cluster analysis for identifying patterns in the way the C alpha atoms of fragments of the beta-turn are distributed in three dimensions. This work has been extended to the C alpha-C beta bond vectors of 2- and 3-side-chain fragments. Again, distinct patterns emerge and 10 and 12 classes of vector orientation have been identified for the 2- and 3-vector problem, respectively. These clusters of vector distribution provide an optimal reduced set of design criteria for the de novo generation of novel peptidomimetics for fragments of the beta-turn.

Topographic analysis of the S7 binding subsite of the tachykinin neurokinin-1 receptor.

Conformationally and configurationally restricted rotameric probes of phenylalanine have been incorporated in the sequence of substance P (SP)-Arg-Pro-Lys-Pro-Gln-Gln-Phe-Phe-Gly-Leu-Met-NH2-for analyzing the binding pockets of Phe7 (S7) and Phe8 (S8), in the neurokinin-1 receptor. These analogues of phenylalanine are (2S. 3R)- and (2S, 3S)-indanylglycines, E- and Z-alpha, beta-dehydrophenylalanines, and 2(S)-alpha, beta-cyclopropylphenylalanines [delta E Phe. delta Z Phe. inverted delta E2 (S) Phe, and inverted delta Z 2 (S) Phe]. Binding data obtained with either conformationally (Ing diastereoisomers) or configurationally (delta E Phe, delta Z Phe) probes have unveiled large differences in the binding potencies of these rotameric probes. With the support of nmr data and energy calculations done on these SP-substituted analogues, we attempt to answer questions inherent to such study. First, none of these six probes prevents the formation of bioactive conformation(s) of the backbone of SP. Second, both diastereoisomers (S, S) and (S, R) of indanylglycine preferentially adopt, in the sequence of SP, the gauche (-) and trans side-chain orientations, respectively, as previously postulated from energy calculations with model peptides. However, in solution, the difference in energy between these rotamers included in the sequence of SP, compared to model peptides, is small since the other rotamer can be detected in [(2S, 3R)Ing7]SP. Finally, from this study we can hypothesize that the large variations observed in the affinities of Phe7 substituted analogues of SP must come from steric hindrance in the S7 binding site, which drastically restricts the space filling around the C alpha-C beta bond of residue 7.

Collagen binding induces changes in its platelet integrin receptor alpha2beta1

Integrins can signal upon binding of their ligand, presumably because of conformational changes induced by ligand-binding. It has been postulated that ligand binding causes changes in the affinity of the integrin to its ligand. In order to test for ligand-induced change in the affinity of platelet alpha beta platelets were passaged through a column of fibrillar collagen and stringent lysis conditions were used to remove all low-affinity receptors. A high-affinity fraction left on the collagen could be eluted with dithiothreitol (DTT) and 2% Sodium dodecyl sulfate (SDS). Antibodies raised against this fraction, identified alpha beta Western-blotting. Functional tests performed with the antibodies confirmed the involvement of the high-affinity proteins in platelet-collagen interactions attributed to alpha beta : inhibition of collagen-specific platelet adhesion and aggregation. EDTA, chaotropic agents or low pH did not elute the high affinity fraction of alpha beta. However, DTT followed by acetic acid did, which indicates that the steps necessary to disrupt the high-affinity collagen alpha beta bond are reduction of disulfide bond(s) followed by disruption of electrostatic interactions. Our data 2 1 suggest that (i) ligand binding induces the formation of a new disulfide bond in a fraction of alpha beta, (ii) that this bond is an intrareceptor, and (iii) that this change increases the affinity of the receptor to its ligand. to collagen, labelled viable 2 1 by 2 1 2 1 2 1 2 1

Conformational investigation of alpha,beta-dehydropeptides. VIII. N-acetyl-alpha,beta-dehydroamino acid N'-methylamides: conformation and electron density perturbation from infrared and theoretical studies.

The Fourier transform infrared spectra are analyzed in the regions of Vs(N-H), amide I, amide II and Vs(C alpha = C beta) bands for a series of Ac-delta Xaa-NHMe, where delta Xaa = delta Ala, (Z)-delta Abu, (Z)-delta Leu, (Z)-delta Phe and delta Val, to determine the predominant solution conformation of these alpha,beta-dehydropeptide-related molecules and the electron distribution perturbation in their amide bonds. The measurements were performed in dichloromethane (DCM). To confirm and rationalize the assignments, the spectra of the respective series of saturated Ac-Xaa-NHMe, recorded in DCM, and the spectra of these two series of unsaturated and saturated compounds, recorded in acetonitrile, were examined. To help interpret the spectroscopic results, the equilibrium geometrical parameters for some selected amides were used. These were optimized with ab initio methods in the 6-31G** basis set. Each of the dehydroamides studied adopted a C5 structure, which in Ac-delta Ala-NHMe is fully extended and accompanied by the strong C5 hydrogen bond. Interaction with the C alpha = C beta bond lessened the amidic resonance within each of the flanking amide groups. The N-terminal C = O bond was noticeably shorter, both amide bonds were longer than the corresponding bonds in the saturated entities and the N-terminal amide system was distorted. Ac-delta Ala-NHMe constituted an exception. Its C-terminal amide bond was shorter than the standard one and both amide systems were prototypically planar.

The molecular structure of green fluorescent protein.

The crystal structure of recombinant wild-type green fluorescent protein (GFP) has been solved to a resolution of 1.9 A by multiwavelength anomalous dispersion phasing methods. The protein is in the shape of a cylinder, comprising 11 strands of beta-sheet with an alpha-helix inside and short helical segments on the ends of the cylinder. This motif, with beta-structure on the outside and alpha-helix on the inside, represents a new protein fold, which we have named the beta-can. Two protomers pack closely together to form a dimer in the crystal. The fluorophores are protected inside the cylinders, and their structures are consistent with the formation of aromatic systems made up of Tyr66 with reduction of its C alpha-C beta bond coupled with cyclization of the neighboring glycine and serine residues. The environment inside the cylinder explains the effects of many existing mutants of GFP and suggests specific side chains that could be modified to change the spectral properties of GFP. Furthermore, the identification of the dimer contacts may allow mutagenic control of the state of assembly of the protein.

Effects on protein structure and function of replacing tryptophan with 5-hydroxytryptophan: single-tryptophan mutants of the N-terminal domain of the bacteriophage lambda repressor.

Conformational energy computations have been carried out on the N-acetyl-N'-methylamide of 5-hydroxytryptophan (5OH-Trp) using ECEPP/3. As observed with tryptophan (Trp), the most preferred conformation about the C alpha-C beta bond of the side chain is g+ or t. This preference is reduced to only the t conformational state when 5-hydroxyTrp is in the middle of a right-handed poly(L-alanine) alpha-helix. A similar result has been obtained with Trp [Piela et al. (1987), Biopolymers 1987, 1273-1286]. These results suggest that replacement of Trp by its analog 5-hydroxyTrp may be tolerated in an alpha-helix. To test this hypothesis, we have replaced Trp by 5OH-Trp in the fifth helices of two functionally active mutants of the N-terminal domain of the bacteriophage lambda repressor. Computations on the packing of these helices have shown that no significant structural changes results from the replacement of Trp by 5OH-Trp. The DNA-binding activity of these mutants, as assessed indirectly through geometrical parameters, is also unaltered.

Phe-46(CD4) orients the distal histidine for hydrogen bonding to bound ligands in sperm whale myoglobin.

The role of Phe-46(CD4) in modulating the functional properties of sperm whale myoglobin was investigated by replacing this residue with Leu, Ile, Val, Ala, Trp, Tyr, and Glu. This highly conserved amino acid almost makes direct contact with the distal histidine and has been postulated to affect ligand binding. The overall association rate constants for CO, O2, and NO binding were little affected by decreasing the size of residue 46 step-wise from Phe to Leu to Val to Ala. In contrast, the rates of CO, O2, and NO dissociation increased 4-, 10-, and 25-fold, respectively, for the same series of mutants, causing large decreases in the affinity of myoglobin for all three diatomic gases. The rates of autooxidation at 37 degrees C, pH 7.0 increased dramatically from approximately 0.1-0.3 h-1 for wild-type, Tyr-46, and Trp-46 myoglobins to 1.5, 5.2, 4.9, and 5.0 h-1 for the Leu-46, Ile-46, Val-46 and Ala-46 mutants, respectively. Rates of NO and O2 geminate recombination were measured using 35 ps and 9 ns laser excitation pulses. Decreasing the size of residue 46 causes significant decreases in the extent of both picosecond and nanosecond rebinding processes. High resolution structures of Leu-46 and Val-46 metmyoglobins, Val-46 CO-myoglobin, and Val-46 deoxymyoglobin were determined by X-ray crystallography. When Phe-46 is replaced by Val, the loss of internal packing volume is compensated by (1) contraction of the CD corner toward the core of the protein, (2) movement of the E-helix toward the mutation site, (3) greater exposure of the distal pocket to intruding solvent molecules, and (4) large disorder in the position of the side chain of the distal histidine (His-64). In wild-type myoglobin, the van der Waals contact between C zeta of Phe-46 and C beta of His-64 appears to restrict rotation of the imidazole side chain. Insertion of Val at position 46 relieves this steric restriction, allowing the imidazole side chain to rotate about the C alpha - C beta bond toward the surface of the globin and about the C beta - C gamma bond toward the space previously occupied by the native Phe-46 side chain. This movement disrupts hydrogen bonding with bound ligands, causing significant decreases in affinity, and opens the distal pocket to solvent water molecules, causing marked increases in the rate of autooxidation.(ABSTRACT TRUNCATED AT 400 WORDS)

Two-Dimensional1H NMR Study of a Tetradecapeptide with the Consensus Sequence Arg5-Asp-Val-Arg-Gly9: Structural Effects of the Outside Substitution Ser12by Ala12

Conformation of a tetradecapeptide with a RXVRG consensus sequence, Arg5-Asp-Val-Arg-Gly9, found in several precursors of antibacterian peptides, was investigated in dimethylsulfoxide solution by proton NMR spectroscopy. Complete resonance assignments and conformational parameters were obtained through correlated (COSY) and nuclear Overhauser (NOESY) techniques. The 3J(alpha H, beta H) coupling constants and the intramolecular NOE, NH...beta H, were used to analyse the conformers around the C alpha-C beta bond and, in four cases, to obtain stereospecific assignments. Use of restraints derived from NOE connectivities and 3J(NH, alpha H) coupling constants allows the determination of a range of phi and psi dihedral angles for all the residues in the sequence. The present NMR results provide favourable evidence for the formation of two bends in the consensus sequence of the tetradecapeptide. The first one has most of the features of a Glu4-Val7 beta-turn (low temperature coefficient of the Val7NH chemical shift, Arg5 alpha H...Val7NH and Asp6NH...Val7NH NOE correlations). The second one exhibits only the Asp6 alpha H...Arg7NH and Val7NH...Arg8NH NOE interactions. These consensus sequence organizations proposed were confirmed by molecular modeling based on low potential energy structure on the [4-9] fragment with high agreement of NOE data. Overall, the substitution of Ser12 by Ala12 shifts the conformation of the hydrophobic moiety [10-14] towards a quite random coil structure in this fragment and strongly destabilizes the folded structures of the consensus domain where only one NH (Val7) is solvent-shielded opposed to three (Asp6 to Arg8) in the [Ser12] tetradecapeptide. These conformational changes could be related to the processing enzyme activities on these model oligopeptides.

Architecture of the Yeast Cell Wall: THE LINKAGE BETWEEN CHITIN AND β(1→3)-GLUCAN

To isolate the putative linkage region between chitin and beta(1-->3)-glucan, Saccharomyces cerevisiae cell walls were digested with beta(1-->3)-endoglucanase and the reducing ends of the enzyme-resistant glucose chain stubs were labeled by reduction with borotritide. The radioactive material was further digested with exochitinase to remove the bulk of the chitin, and the liberated oligosaccharides were fractionated on a sizing column. A single peak (compound I) was found to consist of N-acetylglucosamine, glucose, and glucitol residues in the ratio 1:2:1. By digestion with beta-N-acetylglucosaminidase and by NMR spectroscopy, N-acetylglucosamine was identified as the nonreducing terminus, linked to laminaritriitol by a beta(1-->4) bond. Five additional oligosaccharides were recovered, two being analogs of compound I, with 1 or 3 glucose units, respectively; the remaining three were shown to be the reduced analogs of laminaribiose, laminaritriose, and laminaritetraose. The presence of N-acetylglucosamine-containing oligosaccharides arises from the activity of chitinase in cleaving 2 sugar units sequentially in those chains containing an odd number of N-acetylglucosamine residues; correspondingly, oligosaccharides containing only glucose and sorbitol derived from even-numbered chitin chains, a result implying that chitinase can hydrolyze the linkage between N-acetylglucosamine and glucose. It is concluded that the terminal reducing residue of a chitin chain is attached to the nonreducing end of a beta(1-->3)-glucan chain by a beta(1-->4) linkage. Experiments with appropriate mutants showed that synthesis of the chitin combined with glucan is catalyzed by chitin synthetase 3. The timing and possible mechanism of formation of the chitin-glucan linkage is discussed.

Fragmentation reactions of aromatic cation radicals: a tool for the detection of electron transfer mechanisms in biomimetic and enzymatic oxidations.

1. Mechanistic criteria, based on the side-chain fragmentation reactions of aromatic cation radicals, involving the cleavage of a beta bond (i.e. C-H, C-Si and C-S) have been developed for the detection of electron transfer mechanisms in oxidative processes of alkylbenzenes and aromatic sulphides. 2. For benzylic oxidations, the distinction between electron transfer (ET) and hydrogen atom transfer mechanism (HAT) has been based: (a) on studies of intramolecular selectivity, which, with appropriate substrates (5-Z-1,2,3,-trimethylbenzenes and 4-Z-1,2-dimethylbenzenes, where Z = OMe, alkyl), turns out to be much higher in ET than in HAT processes; and (b) on products studies concerning the reactions of bicumyl and benzyltrimethylsilanes since in these systems, the nature of products can be significantly different for ET and HAT mechanisms. 3. These criteria have been applied to the reactions of alkylbenzenes with an NO3 radical (shown to be an ET process) as well as to the microsomal and biomimetic (by iron porphyrins in the presence of PhIO) side-chain oxidation of the same compounds, where the mechanistic probes have suggested a HAT mechanism, with the exception of the biomimetic oxidation of 4-methoxybenzyltrimethylsilane in CH2Cl2-H2O-MeOH, which probably occurs by an ET mechanism. 4. For the enzymatic and biomimetic oxidation of aromatic sulphides an oxygen transfer is suggested, since, with cumyl phenyl sulphide and 4-methoxybenzyl phenyl sulphide, these reactions lead exclusively to the corresponding sulphoxides and sulphones, whereas the same substrates, in genuine ET reactions, form cation radicals which undergo C-H and C-S bond cleavage. 5. An oxygen transfer mechanism is also likely in the biomimetic and enzymatic oxidations of sulphoxides since in these reactions 4-methoxybenzyl phenyl sulphoxide is exclusively converted to sulphone, whereas in ET reactions it forms only C-S bond cleavage products.

Conformational dynamics and relaxation in bulk polybutadienes: A molecular dynamics simulation study

Conformational dynamics and relaxation of the torsional angle autocorrelation (ACF) function in bulk polybutadienes (PBD) have been studied over a wide temperature range via molecular dynamics simulations. All trans, all cis and 70 mol % trans were the configurations of the systems studied. Companion studies of these systems in the phantom state were also carried out to illuminate the effects of packing in the bulk. Conformational transitions at the –CH2–CH= bond alpha to the double bond and at the –CH2–CH2– beta bond were monitored. The activation energies for the overall transition rates for the α bond and for the β bond were found to correspond in both bulk and phantom states to one barrier height in their respective torsional potentials. A considerable degree of correlation was found between second neighbor bonds. At the α bond in trans-PBD correlated conformational changes across the double bond predominated but changes across the β bond when in the trans conformation were common also. In cis-PBD, due to steric hindrance at the α bond when in the cis conformation, correlated changes across the β bond were relatively more common although exchanges across the double bond were common also. In all of the above correlations, the direction of rotation in the two bonds are of opposite sign. In cis-PBD a correlated transition with same sign rotation was also found. The activation energies for relaxation times for the torsional ACF in phantom PBD were also found to correspond to single torsional barrier heights. In bulk PBD, however, the activation energies were significantly higher than single barrier. This behavior is the result of the conformational transitions becoming more heterogeneously distributed spatially over the bonds in the bulk as temperature is lowered. This phenomenon has also been found recently in simulations on polyethylene.