Absolute configuration and stereochemical analysis of 3α,6β-dibenzoyloxytropane

Both enantiomers of 3α,6β-dibenzoyloxytropane (1) have been prepared from optical active 6β-hydroxyhyoscyamines establishing their absolute configurations as (?)-(3R,6R) and (+)-(3S,6S)-dibenzoyloxytropane. Independent stereochemical confirmation was obtained by vibrational circular dichroism measurements, since bands characteristic of (3R,6R) and (3S,6S) configurations of tropanediols derivatives were observed. In addition, a chiral HPLC method was developed for determining absolute configurations of tropane-related natural substances at the microgram (μg) level. The complete ¹H NMR characterization of the scaffold of 1 is also reported.     

The constitution and absolute stereochemistry of persicaxanthin

Persicaxanthin, isolated from the fruits of peach, has been obtained in crystalline form. By spectroscopic (MS, ¹H NMR and CD) methods, its constitution and absolute stereochemistry have been determined as (3S,5R,6S)-5,6-epoxy-3-hydroxy-5,6-d The structural conclusions have received full support by comparison with semi-synthetic persicaxanthin obtained from natural violaxanthin.     

Cyanogenic glycosides and menisdaurin from Guazuma ulmifolia, Ostrya virgininana, Tiquilia plicata and Tiquilia canescens

The major cyanogenic glycoside of Guazuma ulmifolia (Sterculiaceae) is (2R)-taxiphyllin (>90%), which co-occurs with (2S)-dhurrin. Few individuals of this species, but occasional other members of the family, have been reported to be cyanogenic. To date, cyanogenic compounds have not been characterized from the Sterculiaceae. The cyanogenic glycosides of Ostrya virginiana (Betulaceae) are (2S)-dhurrin and (2R)-taxiphyllin in an approximate 2:1 ratio. This marks the first report of the identification of cyanogenic compounds from the Betulaceae. Based on NMR spectroscopic and TLC data, the major cyanogenic glucoside of Tiquilia plicata is dhurrin, whereas the major cyanide-releasing compound of Tiquilia canescens is the nitrile glucoside, menisdaurin. NMR and TLC data indicate that both compounds are present in each of these species. The spectrum was examined by CI-MS, ¹H and ¹³C NMR, COSY, 1D selective TOCSY, NOESY, and ¹J/^2,3J HETCOR experiments; all carbons and protons are assigned. The probable absolute configuration of (2R)-dhurrin is established by an X-ray crystal structure. The ¹H NMR spectrum of menisdaurin is more complex than might be anticipated, containing a planar conjugated system in which most elements are coupled to several other atoms in the molecule. The coupling of one vinyl proton to the protons on the opposite side of the ring involves a ⁶J- and a ^5/7J-coupling pathway. A biogenetic pathway for the origin of nitrile glucosides is proposed.     

The structure of Λ-β1-[Co(R,R-picchxn)(S-tyr)]Br2 · 3.5H2O and solution configuration of Λ-β1-[Co(R,R-picchxn)(aromatic S-aminoacidate)] complexes: model systems for the investigation of non-covalent aromatic interactions

Intramolecular non-covalent interactions involving aromatic residues in the ternary species Λ-β₁-[Co(R,R-picchxn)(S-aa)]²⁺ (aa=Tyr, OMe-tyr or Phe) have been investigated. Such interactions are important to discriminatory processes associated with molecular recognition in chemical and biochemical systems. The single-crystal X-ray study of Λ-β₁-[Co(R,R-picchxn)(S-tyr)]Br₂ · 3.5H₂O demonstrates the influence of intramolecular π-π and bifurcated NH-π interactions in determining the molecular conformation of the complex cation in the solid state. The Co(III) complexes synthesised are diamagnetic, and have been fully assigned in solution using multidimensional NMR techniques. Remarkably, the solid state conformation observed for Λ-β₁-[Co(R,R-picchxn)(S-tyr)]²⁺ has been shown to predominate in solutions of all the complexes, as evidenced by appropriate rOe correlations. ¹H NMR measurements carried out in order to determine equilibrium rotamer distributions confirm the dominance of this conformer in solution. NMR measurements also show that rotamer populations are relatively unchanged at elevated temperatures and in a variety of solvents. The results of this detailed study, which demonstrate the significance of non-covalent interactions involving aromatic residues to the determination of the molecular conformation, serve to highlight the suitability of these simple ternary Co(III) complexes to act as models for such interactions.     

Spectroscopic investigation of the interaction of water-soluble azocalix[4]arenes with bovine serum albumin

In this work, three hydrosoluble azocalix[4]arene derivatives, 5-(o-methylphenylazo)-25,26,27-tris(carboxymethoxy)-28-hydroxycalix[4]arene (o-MAC-Calix), 5-(m-methylphenylazo)-25,26,27-tris(carboxymethoxy)-28-hydroxycalix[4]arene (m-MAC-Calix) and 5-(p-methylphenylazo)-25,26,27-tris(carboxymethoxy)-28-hydroxycalix[4]arene (p-MAC-Calix) were synthesized. Their structures were characterized by infrared spectrum (IR), nuclear magnetic resonance spectrum (¹H NMR and ¹³C NMR) and mass spectrum (MS). The interactions between these compounds and bovine serum albumin (BSA) were studied by fluorescence spectroscopy, UV–vis spectrophotometry and circular dichroic spectroscopy. According to experimental results, three azocalix[4]arene derivatives can efficiently bind to BSA molecules and the o-MAC-Calix displays more efficient interactions with BSA molecules than m-MAC-Calix and p-MAC-Calix. Molecular docking showed that the o-MAC-Calix was embedded in the hydrophobic cavity of helical structure of BSA molecular and the tryptophan (Trp) residue of BSA molecular had strong interaction with o-MAC-Calix. The fluorescence quenching of BSA caused by azocalix[4]arene derivatives is attributed to the static quenching process. In addition, the synchronous fluorescence spectroscopy indicates that these azocalix[4]arene derivatives are more accessible to Trp residues of BSA molecules than the tyrosine (Tyr) residues. The circular dichroic spectroscopy further verified the binding of azocalix[4]arene derivatives and BSA.     

Absolute configuration of heteroxanthin and diadinoxanthin

The absolute configurations of heteroxanthin ((3S,5S,6S,3′R)- 7′,8′-didehydro-5,6-dihydro-β,β-carotene-3,5,3′,6′-tetrol) ex Euglena gracilis and of diadinoxanthin ((3S,5R,6S,3′R)-5,6-epoxy-7′,8′-didehydro-5,6-dihydro-β,β-carotene-3,3′-diol) from the same source have been established by chemical reactions, hydrogen bonding studies, ¹H NMR and CD. Two previously unknown carotenoids (artefacts?) from Trollius europaeus, assigned the structures (3S,5S,6S,3′S,5′R,6′R)-6,7-didehydro-5,6,5′,6′-tetrahydro-β,β -carotene-3,5,6,3′,5′-pentol and its 5R epimer, served as useful models.     

Argophyllone-B,a sesquiterpene lactone from Helianthus argophyllus

The sesquiterpene lactone, 2-methyl-2-butenoic acid dodecahydro-4-(hydroxymethyl)-10a-methyl-8-methylene-3,7-dioxooxineno[5,6]cyclodeca[1,2-b]furan-9-yl ester [1aR^*-[1aS^*,4R^*,5aS^*,8aR^*,9R^*(E)]], argophyllone-B, was isolated from acetone extracts from the leaves of Helianthus argophyllus. Its structure has been determined by single crystal X-ray analysis. Complete ¹H NMR and ¹³C NMR assignments have been made.     

Synthesis of heterodinuclear FeRu(CO)6(R-DAB(6e))(R-DABRNC(H)C(H)NR) Part XV. Comparison of the reactivities of heterodinuclear FeRu(CO)6(R-DAB(6e)) and homodinuclear analogues M2(CO)6(R-DAB(6e)) (M = Fe,Ru). Single-crystal x-ray structures of FeRu(CO)6(i-Pr-DAB(6e)) and FeRu(CO)5(i-Pr-DAB(4e))(C3H4)

The reactions of Fe(CO)₃(R-DAB; R¹, H(4e)) (1a: R = i-Pr, R¹ = H; 1b: R = t-Bu, R¹ = H; 1c: R = c-Hex, R¹ = H; 1e: R = p-Tol, R¹ = H; 1f: R = i-Pr, R¹ = Me) with Ru₃(CO)₁₂ and of Ru(CO)₃(R-DAB; R¹, H(4e)) (2a: R = i-Pr, R¹ = H; 2d: R = CH(i-Pr)₂, R¹ = H) with Fe₂(CO)₉ in refluxing heptane both afforded FeRu(CO)₆(R-DAB; R¹, H(6e)) (3) in yields between 50 and 65%.The coordination mode of the ligand has been studied by a single crystal X-ray structure determination of FeRu(CO)₆(i-Pr-DAB(6e)) (3a). Crystals of 3a are monoclinic, space group P2₁/a, with four molecules in a unit cell of dimensions: a = 22.436(3), b = 8.136(3), c = 10.266(1) Å and β = 99.57(1)°. The structure was refined to R = 0.049 and R_w = 0.052 using 3045 reflections above the 2.5σ(I) level. The molecule contains an FeRu bond of 2.6602(9) Å, three terminally bonded carbonyls to Fe, three terminally bonded carbonyls to Ru and bridging 6e donating i-Pr-DAB ligand. The i-Pr-DAB ligand is coordinated to Ru via N(1) and N(2) occupying an apical and equatorial site respectively (RuN(1) = 2.138(4) RuN(2) = 2.102(3) Å). The C(2)N(2) moiety of the ligand is η²-coordinated to Fe with C(2) in an apical and N(2) in an equatorial site (FeC(2) = 2.070(5) and FeN(2) = 1.942(3) Å).The ¹H and ¹³C NMR data indicate that in all FeRu(CO)₆(R-DAB(6e)) complexes (3a to 3f) exclusively η²-CN coordination to the Fe atom and not to the Ru atom is present irrespective of whether 3 was prepared by reaction of Fe(CO)₃(R-DAB(4e)) (1) with Ru₃(CO)₁₂ or by reaction of Ru(CO)₃(R-DAB(4e)) (2) with Fe₂(CO)₉. In the case of FeRu(CO)₆(i-Pr-DAB; Me, H(6e)) (3f) the NMR data show that only the complex with the C(Me)N moiety of the ligand σ-N coordinated to the Ru atom and the C(H)N moiety η²-coordinated to the Fe atom was formed. Variable temperature NMR experiments up to 140 °C showed that the α-diimine ligand in 3a is stereochemically rigid bonded.FeRu(CO)₆(R-DAB(6e)) (3a and 3e) reacted with allene to give FeRu(CO)₅(R-DAB(4e))(C₃H₄) (4a and 4e). A single crystal X-ray structure determination of FeRu(CO)₅(i-Pr-DAB(4e))(C₃H₄) (4a) was performed. Crystals of 4a are triclinic, space group P1, with two molecules in a unit cell of dimensions: a = 9.7882(7), b = 12.2609(9), c = 8.3343(7) Å, α = 99.77(1)°, β = 91.47(1)° and γ = 86.00(1)°. The structure was refined to R = 0.028 and R_w = 0.043 using 4598 reflections above the 2σ(I) level. The molecule contains an FeRu bond of 2.7405(7) Å and three terminally bonded carbonyls to iron. Two carbonyls are terminally bonded to the Ru atom together with a chelating 4e donating i-Pr-DAB ligand [RuN = 2.110(1) (mean)]. The allene ligand is coordinated in an η³-allylic fashion to the Fe atom while the central carbon of the allene moiety is σ-bonded to the Ru atom (FeC(14) = 2.166(3), FeC(15) = 1.970(2), FeC(16) = 2.127(3) and RuC(15) = 2.075(2) Å). The ¹H and ¹³C NMR data show that in solution the coordination modes of the R-DAB and the allene ligands are the same as in the solid state.Thermolysis reactions of 3a with R-DAB or carbodiimides gave decomposition and did not afford C(imine)C(reactant) coupling products. Thermolysis reactions of 3a with M₃(CO)₁₂ (M = Ru, Os) and Me₃NO gave decomposition. When the reaction of 3a with Me₃NO was performed in the presence of dimethylacetylenedicarboxylate (DMADC) the known complex FeRu(CO)₄(i-Pr-DAB(8e))(DMADC) (5a) was formed in low yield. In 5a the R-DAB ligand is in the 8e coordination mode with both the imine bonds η²-coordinated to iron. The acetylene ligand is coordinated in a bridging fashion, parallel with the FeRu bond.     

MonodentateN coordination of 1aza4oxo1,3butadienes [R1NC(R2)C(R3)O] to platinum(II). X-ray structure of trans-[PtCl2(PEt3){σ-N-(t-BuNCHC(Me)O)}]

Reaction of dimeric trans-[PtCl₂(PR₃)]₂ with 1-aza-4-oxo-1,3-butadienes [R¹NC(R²)C(R³)O, R³ = Me, Ph, OMe, NEt₂] in a 1:2 molar ratio results in almost quantitative formation of mononuclear complexes trans·[PtCl₂(PR₃){σ-N-(R¹NC(R²)C(R³)O)}]. The ligands are bonded in the monodentate σ-N bonding mode to the platinum(II) centre. This has been established by an X-ray structure determination of trans-[PtCl₂(PEt₃){σ-N-(t-BuNCHC(Me)O)}]. Crystals of the latter compound are orthorhombic with space group Pc2₁n; cell constants are a = 14.712(3), b = 15.053(2), c = 9.025(5) Å, Z= 4 and R_w = 0.056 for 3281 reflections. The 1aza4oxol,3butadiene (α-iminoketone for R³ is alkyl or aryl) has the E-configuration about the imine bond (CN 1.34(4) Å), with a C(5)C(6) distance of 1.44(5) Å and a NC(5)/ C(6)O torsion angle of 89(4)°. As a result of this ligand conformation, the acetyl hydrogen atoms are positioned (on average) into the neighbourhood of the Pt-atom above the Pt-coordination plane. Infrared and NMR (¹H, ¹³C, ³¹p) data show that these structural features are also predominant in solution.     

(—)-Massoniresinol,a lignan from Pinus massoniana

A new lignan, named (—)-massoniresinol, has been isolated from Pinus massoniana needles. Its structure has been proved to be (2R,3S,4R)-3,4-dihydroxy-2-(4-hydroxy-3-methoxyphenyl)-4-(4-hydroxy-3-methoxybenzyl)-3-tetrahydrofuranmethanol by ¹H NMR, ¹³C NMR, mass and CD spectroscopy.     

Synthesis,characterization and structure of cationic hydrides of rhodium(III). Part II. Crystal structure of dihydride(1,4-biscyclohexyl-diaza-1,3-butadiene)-bis(4-fluor-tristriphenylphosphine)rhodium(III) perchlorate

The reaction between [(R-DAB)Rh(PR₃)₂]⁺ and molecular hydrogen produces cationic cis-dihydride complexes of Rh(III), of general formula [RhH₂(R-DAB)(PR₃)₂]X. They are stable in air, 1:1 conductors and have been characterized by ¹H NMR, ³¹P NMR, IR and elemental analysis. The tertiary phosphines employed were: PPh₃, P(p-C₆H₄F)₃, PMePh₂, PEt₃, and the R-DAB ligands (RN:CR′CR′:NR)¹, Ph-DAB, c-Hex-DAB, NH₂-DAB(CH₃,CH₃), t-but-DAB.The structure of [RhH₂(c-Hex-DAB){P(p-C₆H₄F)₃}₂]ClO₄ has been determined by an X-ray diffraction study. Crystals are orthorhombic, space group Pbnm. Unit cell parameters are: a = 13.032(1), b = 18.166(2), c = 21.449(2) Å, Z = 4, R = 0.081, R_w = 0.082 for 2906 reflections, with I> 3σ(I) the rhodium atom is octahedrally coordinated with the two hydride-hydrogens and c-Hex-DAB in the equatorial plane; the two phosphine ligands are in an axial position bent towards the hydrogens making an angle of 164.9(4)°.     

Configurational studies on red algae carotenoids

The configurations of (6′R)-β,ε-carotene, (3′R,6′R)-β,ε-caroten-3′-ol (α-cryptoxanthin), (3R,3′R,6′R)-β,ε-carotene-3,3′-diol (lutein), (3R)-β,β-caroten-3-ol (β-cryptoxanthin), (3R,3′R)-β,β-carotene-3,3′-diol (zeaxanthin) and all-trans (3S,5R,6S,3′R)-5,6-epoxy-5,6-dihydro-β,β-carotene-3,3′-diol (antheraxanthin) were established by CD and ¹H NMR studies. The red algal carotenoids consequently possessed chiralities at each chiral center (C-3, C-5, C-6, C-3′, C-6′), corresponding to the chiralities established for the same carotenoids in higher plants. Two post mortem artifacts from Erythrotrichia carnea were assigned the chiral structures (3S,5R,8R,3′R)-5,8-epoxy-5,8-dihydro-β,β-carotene-3,3′-diol [(8R)-mutatoxanthin] and (3S,5R,8S,3′R)-5,8-epoxy-5,8-dihydro-β,β-carotene-3,3′-diol [(8S)-mutatoxanthin]. This is the first well documented report of a naturally occurring β,ε-caroten-3′-ol (¹H NMR, CD, chemical derivatization).     

The structures of barium hexafluorosilicate and cesium hexafluororhenate(V)

The crystal structure of CsReF₆, together with a reinvestigation of that of BaSiF₆, is reported. Both have been determined from single crystal three-dimensional X-ray diffraction data. The structure of BaSiF₆ has been found to conform to the initially assigned space group R$\text{3}$m, contrary to the suggestions of other workers. The unit cell of BaSiF₆ has the dimensiona a_hex 7.189(1), c_hex 7.015(1) Å; Z = 3. Refinement by a least squares method gave R 0.0079 and R_w 0.0077. Crystals of CsReF₆ belong to the lower symmetry rhombohedral space group R$\text{3}$. The unit cell has the dimensions a_hex 7.853(1), c_hex 8.140(1) Å; Z = 3. Refinement gave R 0.031 and R_w 0.030. The lowering of symmetry is caused by rotation of the ReF₆^? octahedra about the 3-fold axis through each Re atom, causing CsReF₆ to have the KOsF₆ structure.     

Chiral Metal Complexes. 27. Stereoselectivity in the synthesis and reaction of coordinated aminomalonic acid derivatives

The synthesis is reported of a series of ternary cationic complexes of general form [Co(R,Rpicchxn)(ARMA)⁺ (where picchxn is the N₄ tetradentate N,N′-di(2-picolyl)-1,2-diaminocyclohexane and ARMA is a bidentate α-substituted-α-aminomalonate dianion). The aminomalonic acid (NH₂· C(COOH)₂·R) derivatives investigated have R = -CH₃ (AMMAH₂), -CH₂·CH₃ (AEMAH₂), -CH₂· CH₂·CH₃ (APMAH₂), -CH₂·(CH₂)₂·CH₃ (ABuTMAH₂, -CH₂·C₆H₅ (ABMAH₂), -CH₂·(p-C₆H₄)· C(CH₃)₃ (ABuBMAH₂) and -CH₂·C₁₀H₇ (ANMAH₂). The isomeric species in the complex products have been separated using cation exchange chromatography and each isomer has been characterized using NMR and circular dichroism techniques. In each synthesis the major isomeric product obtained has a Λ-β₁ topology. However, where ARMAH₂ possesses a lengthy alkyl sidechain trace amounts of Δ-α-[Co(R,R-picchxn)(ARMA)]⁺ isomers have been observed during the synthetic reactions. This unusual isomeric form readily undergoes inversion of its absolute configuration in DMSO solution to yield the more thermodynamically stable Λ-β₁-[Co(R,R-picchxn()R-ARMA)]⁺ species stereospecifically.In the case of Λ-β₁-[Co(R,R,-pichxn)(S-APMA)]ClO₄·2NaClO₄·5H₂O the crystal structure has been determined. The compound crystallises in the orthorhombic space group P2₁2₁2₁, with a = 10.056(3),b = 16.475(7),c = 23.370(7)Å and Z = 4. The structure was refined to R = 0.079 for 4460 non-zero reflexions, and confirms the absolute configuration of each chiral centre to be consistent with the NMR and circular dichroism interpretations.The decar☐ylation of these chelate ARMAH₂ derivatives under acid conditions leads to corresponding complexes containing mixtures of coordinated R-andS-α-aminoacids in various ratios. This ratio has been determined in each case, and factors which may influence the degree of chiral induction observed are discussed.     

Absolute configuration of ceriporic acids, the iron redox-silencing metabolites produced by a selective lignin-degrading fungus, Ceriporiopsis subvermispora

Ceriporic acids are a class of alk(en)ylitaconic acids produced by a selective lignin-degrading fungus, Ceriporiopsis subvermispora. The unique function of alkylitaconic acid is the redox silencing of the Fenton reaction system by inhibiting reduction of Fe³⁺. Ceriporic acids have an asymmetric centre at carbon-3, but absolute configuration has not been determined. We have isolated a series of ceriporic acids from the cultures of C. subvermispora, and measured their NMR spectra using a chiral shift reagent. In comparison with NMR spectra of (R)-(−)- and (S)-(+)-methylsuccinic acid and those of natural and chemically synthesized racemic mixtures of ceriporic acids, we have determined the absolute configuration of ceriporic acids as (R)-3-tetradecylitaconic acid (ceriporic acid A), (R)-3-hexadecylitaconic acid (ceriporic acid B) and (R,Z)-2-(hexadec-7-enyl)-3-itaconic acid (ceriporic acid C). We herein discuss their stereoselective biosynthetic pathway and the structural diversity of fungal secondary metabolites.     

Synthesis and spectroscopic properties of CpRuCl(R-DAB(4e)) and CpRuCo(CO)3(R-DAB(6e)). Part XVII. X-ray structure determination of CpRuCo(CO)3(t-Bu-DAB(6e))

CpRuCl(PPh₃)₂ reacted with excess R-DAB in refluxing toluene to give CpRuCl(R-DAB(4e)) (1a: R = i-Pr; 1b: R = t-Bu; 1c: R = neo-Pent; 1d: R =p-Tol). ¹H NMR and ¹³C NMR spectroscopic data indicated that in these complexes the R-DAB ligand is bonded in a chelating 4e coordination mode.Reaction of 1a and 1b with one equivalent of [Co(CO)₄]⁻ afforded CpRuCo(CO)₃(R-DAB(6e)) (2a: R = i-Pr; 2b: R = t-Bu). The structure of 2b was determined by a single crystal X-ray structure determination. Crystals of 2b are monoclinic, space group P2₁/n, with four molecules in a unit cell of dimensions: a = 16.812(4), b = 12.233(3), c = 9.938(3) Å and β = 105.47(3)°. The structure was solved via the heavy atom method and refined to R = 0.060 and R_w = 0.065 for the 3706 observed reflections. The molecule contains a RuCo bond of 2.660(3) Å and a cyclopentadienyl group that is η⁵-coordinated to ruthenium [RuC(cyclopentadienyl) = 2.208(3) Å (mean)]. Two carbonyls are terminally coordinated to cobalt (CoC(1) = 1.746(7) and CoC(2) = 1.715(6) Å) while the third is slightly asymmetrically bridging the RuCo bond (RuC(3) = 2.025(6) and CoC(3) = 1.912(6) Å). The RuC(3)O(3) and CoC(3)O(3) angles are 138.4(5)° and 136.5(5)°, respectively. The t-Bu-DAB ligand is in the bridging 6e coordination mode: σ-N coordinated to Ru (RuN(2) = 2.125(4) Å), μ₂-N′ bridging the RuCo bond and η²-CN coordinated to Co (RuN(1) = 2.113(5), CoN(1) = 1.941(4) and CoC(4) = 2.084(5) Å). The η²-CN′ bonded imine group has a bond length of 1.394(7) Å indicating substantial π-backbonding from Co into the anti-bonding orbital of this CN bond.¹H NMR spectroscopy indicated that 2a and 2b are fluxional on the NMR time scale. The fluxionality of 6e bonded R-DAB ligands is rarely observed and may be explained by the reversible interchange of the σ-N and η²-CN′ coordinated imine parts of the R-DAB ligand.     

Molecular characterization of Penicillium oxalicum 6R,8R-linoleate diol synthase with new regiospecificity

Diol synthase-derived metabolites are involved in the sexual and asexual life cycles of fungi. A putative diol synthase from Penicillium oxalicum was found to convert palmitoleic acid (16:1n-7), oleic acid (18:1n-9), linoleic acid (18:2n-6), and α-linolenic acid (18:3n-3) to 6S,8R-dihydroxy-9(Z)-hexadecenoic acid, 6R,8R-dihydroxy-9(Z)-octadecenoic acid, 6R,8R-dihydroxy-9,12(Z,Z)-octadecadienoic acid, and 6S,8R-dihydroxy-9,12,15(Z,Z,Z)-octadecatrienoic acid, respectively, which were identified by liquid chromatography-tandem mass spectrometry (LC-MS/MS) and nuclear magnetic resonance (NMR) spectroscopy analyses. The specific activity and catalytic efficiency of P. oxalicum 6,8-diol synthase were the highest for 18:2n-6, indicating that the enzyme is a 6R,8R-linoleate diol synthase (6R,8R-LDS) with new regiospecificity. This is the first report of a 6R,8R-LDS. LDS is a fusion protein consisting of a dioxygenase domain at the N-terminus and a cytochrome P450/hydroperoxide isomerase (P450/HPI) domain at the C-terminus. The putative active-site residues in the C-terminal domain of P. oxalicum 6R,8R-LDS were proposed based on a substrate-docking homology model. The results of the site-directed mutagenesis within C-terminal P450 domain suggested that Asn⁸⁸⁶, Arg⁷⁰⁷, and Arg⁹³⁴, are catalytic importance and belong to the catalytic groove. Phe⁷⁹⁴ and Gln⁸⁸⁹ were found to be involved in the regiospecific rearrangement of hydroperoxide, while the F794E and Q889A variants of P. oxalicum 6,8-LDS acted as 7,8- and 8,11-LDSs, respectively. All these mutations critically affected the HPI activity of P. oxalicum 6R,8R-LDS.     

Reactivity of metal chelates of sulphur containing ligands towards Lewis bases. Part III. Reaction of bis(1,2-dimethyl-and 1-phenyl-1,2-ethanediylidene)bis(S-methylhydrazinecarbodithioate)NN′SS′(−2)dizinc(II) with pyridines

The reaction of the dimeric zinc(II) chelates of the type I (R₁ = R₂ = CH₃, R₁ = H, R₂ = Ph) with pyridine, 2-methylpyridine, 3-methylpyridine and 4-methylpyridine afforded the monomeric monobase adducts. The isolated adducts were characterized by their electronic and ¹H NMR spectra, and a five coordinate square pyramidal structure was tentatively assigned for these adducts.The adduct formation reaction was followed spectrophotometrically and the reaction kinetics were studied using a stopped flow technique. From the available kinetic data, as well as the measured activated parameters (ΔH^#, ΔS^#), a mechanism for the adduct formation reaction is proposed.     

29Si and 13C chemical shifts and coupling constants of tris(phenyldimethylsilyl)methyl silicon compounds

Silicon-29 (δ ²⁹Si) NMR chemical shifts are reported for the first time for a number of tris(phenyldimethylsilyl)methyl silicon compounds (disilylated derivatives), (PhMe₂Si^A)₃C_αL, where LSi^BR₁R₂R₃, where R varies widely in electronegativity. δ ²⁹Si^B for these series exhibited to some extent good correlations with the electronegativities of the groups bonded to silicon (particularly, δ ²⁹Si^BMe₂X, X H, OH, OCH₃, COCH₃ and Cl). Substitution with electronegative atoms shifts the chemical shift of silicon to high field.The ¹³C NMR spectra of these compounds have been recorded and assigned. The chemical shifts of the α-carbon (C_α) resonances are shown to depend on the type of substituent on the silicon-B, thus ¹³C_α exhibit downfield shifts when X=oxygen ligand. The ¹³C phenyl resonances have been measured and show the same order of o, m and p signals, viz. δ ortho (downfield)>δ para>δ meta.The variation of ²⁹Si-¹H coupling constants with the electronegativity of X was studied.     

Interaction of [RuCl2(PR3)3] (R = Ph, p-tolyl) with some Rh(III), Ir(III) and Pt(IV) tertiary phosphine complexes

Reactions of RuCl₂(PR₃)₃ [PR₃ = PPh₃ or P(p-tolyl)₃ with several monomeric phosphine complexes of rhodium(III), iridium(III) and platinum(IV) have been studied. The reactions with mer-MCl₃(P′R₃)₃ (M = Rh, P′R₃ = PEt₂Ph, PMe₂Ph, PMe₂Ph; M = Ir, P′R₃ = PBuPh₂, PMePh₂, PEt₂Ph) involves a phosphine ligand transfer between metal atoms to afford novel dark coloured heterobimetallic complexes containing a triple chloro-bridge. The reactions of RuCl₂(PR₃)₃ with PtCl₄(P′R₃)₂ (P′R₃ = PEt₂Ph, PBu₂Ph), however, do not give evidence for the formation of dinuclear complexes containing the (RuCl₃Pt) unit, but a reduction of Pt^IV to Pt^II occurs with transfer of phosphine ligands between the two metals. The formulation of these complexes has been established by ³¹P NMR spectroscopy.