Trans Addition Products Research Articles

Organic Base-Facilitated Thiol-Thioalkyne Reaction with Exclusive Regio- and Stereoselectivity.

Here, we report the regiospecific hydrothiolation of electron-rich thioalkynes with exclusive stereoselectivity facilitated by an organic base, which could proceed exceedingly fast under ambient atmosphere and room temperature, affording β trans addition products in up to nearly quantitative yields. The dual nature of the sulfur atom in attracting and donating electrons is supposed to be pivotal in determining the regio- and stereoselectivity. This system tolerates a wide range of thiols and thioalkynes and shows great potential in polymer synthesis.

Gold(I)/Gold(III) Catalysis that Merges Oxidative Addition and π-Alkene Activation.

Heteroarylation of alkenes with aryl iodides was efficiently achieved with a (MeDalphos)AuCl complex through AuI /AuIII catalysis. The possibility to combine oxidative addition of aryl iodides and π-activation of alkenes at gold is demonstrated for the first time. The reaction is robust and general (>30 examples including internal alkenes, 5-, 6-, and 7-membered rings). It is regioselective and leads exclusively to trans addition products. The (P,N) gold complex is most efficient with electron-rich aryl substrates, which are troublesome with alternative photoredox/oxidative approaches. In addition, it provides a very unusual switch in regioselectivity from 5-exo to 6-endo cyclization between the Z and E isomers of internal alkenols.

Gold(I)/Gold(III) Catalysis that Merges Oxidative Addition and π‐Alkene Activation

AbstractHeteroarylation of alkenes with aryl iodides was efficiently achieved with a (MeDalphos)AuCl complex through AuI/AuIIIcatalysis. The possibility to combine oxidative addition of aryl iodides and π‐activation of alkenes at gold is demonstrated for the first time. The reaction is robust and general (>30 examples including internal alkenes, 5‐, 6‐, and 7‐membered rings). It is regioselective and leads exclusively totransaddition products. The (P,N) gold complex is most efficient with electron‐rich aryl substrates, which are troublesome with alternative photoredox/oxidative approaches. In addition, it provides a very unusual switch in regioselectivity from 5‐exoto 6‐endocyclization between the Z and E isomers of internal alkenols.

Iodofluorination of Alkenes Using IF5–Pyridine–HF

Iodofluorination of alkenes was performed by using IF5–pyridine–HF and a reductant such as potassium iodide or tin powder. The addition of IF to the double bond proceeded with stereo- and regioselectivity. In the reaction with internal alkenes, the trans-addition product was obtained selectively. With terminal alkenes, the addition took place regioselectively to give 1-iodo-2-fluoroalkanes.

Reaction of unsaturated compounds with the thiobisamine-SOHal2 system

A convenient method for the synthesis of di(β-haloalkyl)sulfides based on the reaction of unsaturated compounds with the thiobisamine-SOHal2 (Hal = Cl, Br) system was created. The reaction proceeds through an electrophilic mechanism with the formation of trans-addition products. Reactions with alkynes result in the formation of a mixture of regioisomeric divinyl sulfides.

Metal–Ligand Synergistic Effects in the Complex Ni(η2-TEMPO)2: Synthesis, Structures, and Reactivity

In the current investigation, reactions of the "bow-tie" Ni(η(2)-TEMPO)2 complex with an assortment of donor ligands have been characterized experimentally and computationally. While the Ni(η(2)-TEMPO)2 complex has trans-disposed TEMPO ligands, proton transfer from the C-H bond of alkyne substrates (phenylacetylene, acetylene, trimethylsilyl acetylene, and 1,4-diethynylbenzene) produce cis-disposed ligands of the form Ni(η(2)-TEMPO)(κ(1)-TEMPOH)(κ(1)-R). In the case of 1,4-diethynylbenzene, a two-stage reaction occurs. The initial product Ni(η(2)-TEMPO)(κ(1)-TEMPOH)[κ(1)-CC(C6H4)CCH] is formed first but can react further with another equivalent of Ni(η(2)-TEMPO)2 to form the bridged complex Ni(η(2)-TEMPO)(κ(1)-TEMPOH)[κ(1)-κ(1)-CC(C6H4)CC]Ni(η(2)-TEMPO)(κ(1)-TEMPOH). The corresponding reaction with acetylene, which could conceivably also yield a bridging complex, does not occur. Via density functional theory (DFT), addition mechanisms are proposed in order to rationalize thermodynamic and kinetic selectivity. Computations have also been used to probe the relative thermodynamic stabilities of the cis and trans addition products and are in accord with experimental results. Based upon the computational results and the geometry of the experimentally observed product, a trans-cis isomerization must occur.

The reaction of photochemically generated α-hydroxyalkyl radicals with alkynes: a synthetic route to γ-butenolides

The photomediated generation of α-hydroxyalkyl radicals from simple acyclic and cyclic alcohols, and acyclic diols, and their subsequent carbon-carbon bond forming reaction with propiolate esters and acetylenedicarboxylates, gives a mixture of a β-(hydroxyalkyl)enoate, the result of a formal cis addition, and the unsaturated lactone (γ-butenolide) resulting from the spontaneous cyclization of the corresponding trans addition product. Treatment of the cis adduct with NBS converts it to the same lactone, and so the method overall constitutes a particularly direct route to this important structural unit. Cyclic alcohols give rise to spiro-γ-butenolides. The use of supported photomediators simplifies product isolation and allows for the recovery and reuse of the photomediator.

Hydrogallierungsreaktionen mit den Monoalkinen H5C6-C≡C-SiMe3und H5C6-C≡C-CMe3-cis/trans-Isomerie und Substituentenaustausch

Hydrogallation Reactions Involving the Monoalkynes H5C6-C≡C-SiMe3 and H5C6-C≡C-CMe3 – cis/trans Isomerisation and Substituent Exchange Phenyl-trimethylsilylethyne, H5C6-C≡C-SiMe3, reacted with different dialkylgallium hydrides, R2Ga-H (R = Me, Et, nPr, iPr, tBu), by the addition of one Ga-H bond to its C≡C triple bond (hydrogallation). The gallium atoms attacked selectively those carbon atoms, which were also attached to trimethylsilyl groups. The cis arrangement of Ga and H across the resulting C=C double bonds resulted only for the sterically most shielded di(tert-butyl)gallium derivative, while in all other cases spontaneous cis/trans rearrangement occurred with the quantitative formation of the trans addition products. The diethyl compound Et2Ga-C(SiMe3)=C(H)-C6H5 (2) gave by substituent exchange the secondary products EtGa[C(SiMe3)=C(H)-C6H5]2 (7, Z,Z) and Ga[C(SiMe3)=C(H)-C6H5]3 (8). Interestingly, compound 8 has two alkenyl groups with a Z configuration, while the third C=C double bond has the cis arrangement of Ga and H (E configuration). The reversibility of the cis/trans isomerisation of hydrogallation products was observed for the first time. tert-Butyl-phenylethyne gave the simple addition product, R2Ga(C6H5)=C(H)-CMe3 (9), only with di(n-propyl)gallium hydride.

Reactivity of diacetylplatinum(II) complexes: oxidative addition of alkyl halides and crystal structures of acetyl platinum(IV) complexes

Diacetylplatinum(II) complexes [Pt(COMe)2(N^N)] (N^N = bpy, 3a; 4,4′-t-Bu2-bpy, 3b) were found to undergo oxidative addition reactions with organyl halides. The reaction of 3a with methyl iodide and propargyl bromide led to the formation of the cis addition products (OC-6-34)-[Pt(COMe)2(R)X(bpy)] (R = Me, X = I, 4a; CH2C≡CH, X = Br, 4k). Analogous reactions of 3a with ethyl iodide, benzyl bromide, and substituted benzyl bromides, 3-(bromomethyl)pyridine, 2-(bromomethyl)thiophene, allyl bromide, and cyclohex-2-enyl bromide led to exclusive formation of the trans addition products (OC-6-43)-[Pt(COMe)2(R)X(bpy)] (X = I, R = Et, 4b; X = Br, R = CH2C6H5, 4c; CH2C6H4(o-Br), 4d; CH2C6H4(p-COOH), 4e; CH2-3-py (3-pyridylmethyl), 4f; CH2-2-tp (2-thiophenylmethyl), 4g; CH2CH=CH2, 4h; c-hex-2-enyl (cyclohex-2-enyl), 4i). All complexes 4 were characterized by microanalysis, 1H and 13C NMR and IR spectroscopy. Additionally, complexes 4a, 4f, and 4g were characterized by single-crystal X-ray diffraction analyses. Reactions of 3a and 3b with o-, m- and p-bis(bromomethyl)benzene, respectively, led to the formation of dinuclear platinum(IV) complexes [{Pt(COMe)2Br(N^N)}2-{μ-(CH2)2C6H4}] (5). These complexes were characterized by microanalysis, IR spectroscopy, and depending on their solubility by 1H and 13C NMR spectroscopy, too. A single-crystal X-ray diffraction analysis of complex [{Pt(COMe)2Br(bpy)}2{μ-m-(CH2)2C6H4}] (5b) confirmed its dinuclear composition. The solid-state structures of 4a, 4f, 4g, and 5b are discussed in terms of C–H···O and O–H···O hydrogen bonds as well as π–π stacking between aromatic rings.

Hydrogallation of Trimethylsilylethynylbenzenes: Generation of Potential Di- and Tripodal Chelating Lewis Acids

Hydrogallation of 1,4-bis(trimethylsilylethynyl)benzene and 1,3,5-tris(trimethylsilylethynyl)benzene with dialkylgallium hydrides R2GaH (R = Et, nPr, iPr, neopentyl, tBu) afforded the corresponding addition products with intact GaR2 groups and two or three alkenyl substituents. In all products the gallium atoms attacked those carbon atoms that are attached to the trimethylsilyl groups. The expected cis arrangement of gallium and hydrogen atoms at the CC double bonds was detected only with di(tert-butyl)gallium residues. Smaller alkyl groups gave the spontaneous formation of the trans-addition products. Cis/trans isomerization is an inevitable step for the formation of effective chelating Lewis acids, and in particular the trisalkene derivatives form interesting chalice-like hollows containing three Lewis-acidic centers at their inner surfaces.

A chemoselective reduction of alkynes to (E)-alkenes.

The trans reduction of all types of alkynes to give (E)-olefins is achieved through a two-stage trans hydrosilylation and protodesilylation. Reaction of an alkyne and a silane with the ruthenium catalyst [Cp*Ru(MeCN)3]PF6 results in clean hydrosilylation to give only the (Z)-trans addition product at ambient temperature with catalyst loadings of 1-5 mol %. The crude vinylsilane products are then protodesilylated by the action of cuprous iodide and TBAF at rt-35 degrees C. The reaction is compatible with many sensitive functional groups and provides a general trans-alkyne reduction not possible by other means.

Synthesis of Optically Active 5-(tert-Butyldimethylsiloxy)-2-cyclohexenone and Its 6-Substituted Derivatives as Useful Chiral Building Blocks for the Synthesis of Cyclohexane Rings. Syntheses of Carvone, Penienone, and Penihydrone

Optically active 5-(tert-butyldimethylsiloxy)-2-cyclohexenone (1) and its 6-substituted derivatives 2a,b were synthesized from the readily available optically active ethyl 3-(tert-butyldimethylsiloxy)-5-hexenoate (4), where the Ti(II)-mediated intramolecular nucleophilic acyl substitution reaction and the FeCl3-mediated ring expansion reaction of a 1-hydroxybicyclo[3.1.0]hexane are the key reactions. The enone 1 reacted with higher-order cyanocuprates with excellent diastereoselectivity to afford the trans-addition products, trans-13, in excellent yields. The reaction of 1 with lower-order cyanocuprates proceeded with moderate to excellent syn-selectivity to afford cis-13. Treatment of trans- and cis-13 with DBU (1,8-diazabicyclo[5.4.0]undec-7-ene) or catalyst p-TSA (p-toluenesulfonic acid) resulted in a β-elimination reaction to furnish the corresponding optically active 5-substituted-2-cyclohexenones 14. The 1,4-addition reaction of 2a and 2b with organocyanocuprates followed by treatment of the resulti...

Nitrosylation of Octaethylporphyrin Osmium Complexes with Alkyl Nitrites and Thionitrites: Molecular Structures of Three Osmium Porphyrin Derivatives.

(OEP)Os(CO) reacts with n-butyl nitrite to give, after workup, the (OEP)Os(NO)(O-n-Bu) trans addition product (OEP = octaethylporphyrinato dianion). Similarly, the reaction of (OEP)Os(CO) or [(OEP)Os](2) with isoamyl nitrite gives the corresponding nitrosyl alkoxide, (OEP)Os(NO)(O-i-C(5)H(11)). The related reactions of (OEP)Os(CO) or [(OEP)Os](2) with isoamyl thionitrite gives the (OEP)Os(NO)(S-i-C(5)H(11)) nitrosyl thiolate. The reaction of the [(OEP)Os](2)(PF(6))(2) reagent with isoamyl thionitrite gives the nitrosylation product, [(OEP)Os(NO)]PF(6), which undergoes anion hydrolysis to give the isolable difluorophosphate (OEP)Os(NO)(O(2)PF(2)) derivative. Interestingly, the reaction of O(2)NC(6)H(4)N=NSPh with [(OEP)Os](2) gives the (OEP)Os(SPh)(2) product with loss of the arylazo fragments. The solid-state structures of (OEP)Os(NO)(O-n-Bu), (OEP)Os(NO)(O(2)PF(2)), and (OEP)Os(SPh)(2) have been determined by X-ray crystallography.

Design of optically active selenium reagents having a chiral tertiary amino group and their application to asymmetric inter- and intramolecular oxyselenenylations

A new class of chiral selenium reagents 4–7 was synthesized on the basis of the concept that the strong intramolecular interaction between an electrophilic selenium and an optically modified tertiary amine (Se…N interaction) would induce asymmetric induction in the reaction between the selenium reagent and olefins. When 7, which showed the most powerful asymmetric induction, was applied to asymmetric methoxyselenenylation of ( E)-phenylpropene under optimum reaction conditions, the highest diastereomeric excess (d.e.) of the trans-addition product was obtained (97 % d.e.). The same reaction conditions were employed in asymmetric methoxyselenenylation of various olefins (up to 97 % d.e.) and also in asymmetric intramolecular oxyselenenylation of terminal olefins (up to 59 % d.e.) and internal olefins (up to 98 % d.e.). The results show that this class of selenium reagents with a strong Se…N interaction is useful for asymmetric organic synthesis.

Site-specific adducts derived from the binding of anti-5-methylchrysene diol epoxide enantiomers to DNA: synthesis and characteristics.

The direct synthesis and characterization of site-specific adducts derived from the binding of (+)-1R,2S-dihydroxy-3S,4R-epoxide-1,2,3,4-tetrahydro-5-methylchrysene and the (-)-1S,2R,3R,4S-enantiomer [(+)- and (-)-5-MeCDE, respectively], to the N2-guanine residues in the oligonucleotide d(CCATCGCTACC) are described. The spectroscopic characteristics of the 5-MeCDE-modified oligonucleotides are discussed, and it is shown that their CD characteristics can be used to distinguish between the trans-addition products of the binding of the (+)- and (-)-enantiomers of 5-MeCDE (C4 position). The 11-mer duplexes with the normal complementary strands are destabilized by the site-specific, covalently bound 5-MeCDE residues: the melting points, Tm, are 5-10 degrees lower than in the case of the unmodified duplex. Stereoselective exonuclease enzyme digestion patterns of the single-stranded (+)- and (-)-trans-5-MeCDE-modified oligonucleotides (Mao et al, 1993, Biochemistry, 32, 11785-11793) were used to probe the orientations of the covalently bound 5-MeCDE residues relative to the modified guanine and the 5'-3' strand polarity; the aromatic residues are positioned either on the 5'-side [(+)-5-MeCDE], or the 3'-side [(-)-5-MeCDE adduct] of the modified guanine residues. The electrophoretic mobilities of the (+)-5-MeCDE-modified 11-mer duplexes in native polyacrylamide gels are slower than those of unmodified and modified duplexes containing the stereoisomeric (-)-5-MeCDE-N2-dG lesions. This indicates that the lesions derived from the tumorigenic (+)-5-MeCDE induce greater degrees of bending or local flexibility than the non-tumorigenic (-)-5- MeCDE enantiomer. These differences in the orientational and structural characteristics are similar to those observed with analogous DNA adducts derived from the tumorigenic (+)-7R,8S-dihydroxy-9S,10R-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene and the non-tumorigenic 7S,8R,9R,10S-enantiomer, respectively. The adducts derived from BPDE and 5-MeCDE enantiomers thus display similar characteristics that depend primarily on the PAH diol epoxide enantiomer stereochemistry. This direct synthesis approach can be used to generate milligram quantities of site-specific 5-MeCDE-modified oligonucleotides that are suitable for NMR studies (Cosman, et al., 1995, Biochemistry, 34, 6247-6260).

Chiral Spin Traps. The Spin Trapping Chemistry of 5-Methyl-5-phenylpyrroline-N-oxide (MPPO)

The use of 5,5-dimethylpyrroline-N-oxide (DMPO) as a versatile spin trap was first published in this journal (E. G. Janzen and J. I.-P. Liu,J. Magn. Reson.9, 510–512 (1973). In this paper, the general use of an improved DMPO-type spin trap, namely 5-methyl-5-phenylpyrroline-N-oxide (MPPO), is proposed. MPPO is more stable than DMPO and has an excellent shelf life. Commonly known artifacts of DMPO are not present in MPPO. The EPR spectra of MPPO spin adducts have the same patterns as DMPO spin adducts which users have become familiar with. The lifetimes of spin adducts are longer for MPPO than for DMPO and the rate constants of spin trapping are similar. An interesting additional feature is associated with the detection of two spin-adduct spectra in some cases. The major component is assigned to the trans addition product (with respect to the phenyl group) in the case of carbon-centered radicals. The minor component is assigned to the cis adduct. In the superoxide/peroxyl radical adduct, however, the reverse appears to be the case. Only one EPR spectrum is detected in the hydroxyl radical adduct of MPPO.

The effect of fluoro substituents on reactivity of 7-methylbenz[a]anthracene diol epoxides.

The present study has examined potential mechanisms for the influence of F-substituents on the biologic activity of methylbenz[a]anthracenes. DNA adducts derived from reaction of the racemic bay-region anti-diol epoxides of 7-methylbenz[a]anthracene, and its 9- and 10- fluoro derivatives, with calf thymus DNA in vitro were partially characterized. All three hydrocarbon diol epoxides produced similar DNA adduct profiles upon reaction with calf thymus DNA in vitro that were composed of two deoxyganosine and two deoxyadenosine adducts (tentatively identified as trans addition products). The extent of covalent binding to calf thymus DNA, as estimated by 32P-postlabeling, was similar for all three diol epoxides. The reactivity of the unsubstituted and 10-F-substituted diol epoxide was further assessed by measuring overall pseudo-first-order rate constants for hydrolysis in water or 0.1 M Tris-HCl buffer, pH 7.0, and in the presence or absence of native or denatured DNA. The rate constant for hydrolysis of 7-methylbenz[a]anthracene diol epoxide in the absence of DNA was similar to that of 10-F-7-methylbenz[a]anthracene diol epoxide (t1/2 = 138 min vs 115 min in water, respectively, and 93 vs 83 min in 0.1 M Tris-HCl buffer, respectively). In addition, the presence of DNA accelerated hydrolysis rates to similar extents for both diol expoxides. The skin tumor-initiating activities of the 9- and 10-F-substituted 3,4-diols of 7-methyl-, 12-methyl-, and 7,12-dimethylbenz[a]anthracene were determined in SENCAR mice. The presence of F-substituents in the 9- or 10- position did not enhance or in some cases reduced the tumor-initiating activity of the 3,4-diols of these hydrocarbons. Collectively, these results, as well as previous results from our laboratory, suggest that the influence of a F-substituent at position 10 of the benz[a]anthracene nucleus is not due to increased or altered reactivity of the bay-region diol epoxide but rather likely on the initial formation of the 3,4-diol.

Stereoselective Addition of Carboxylic Acids to Electron Deficient Acetylenes Catalyzed by the PdMo3S4 Cubane-Type Cluster

The mixed-metal sulfide cubane-type cluster complex [PdMo3S4(tacn)3Cl][PF6]3 (1; tacn = 1,4,7-triazacyclononane) was found to be a highly efficient and selective catalyst for the addition of carboxylic acids to acetylenes with electron-withdrawing groups. The corresponding trans addition products were exclusively obtained in good yields under mild reaction conditions in the presence of a catalytic amount of triethylamine.

Stereoselective addition of carboxylic acids to electron deficient acetylenes catalyzed by the PdMo3S4 cubane-type cluster

The mixed-metal sulfide cubane-type cluster complex [PdMo 3 S 4 (tacn) 3 Cl][PF 6 ] 3 ( 1 ; tacn = 1,4,7-triazacyclononane) was found to be a highly efficient and selective catalyst for the addition of carboxylic acids to acetylenes with electron-withdrawing groups. The corresponding trans addition products were exclusively obtained in good yields under mild reaction conditions in the presence of a catalytic amount of triethylamine. Addition of carboxylic acids to electron deficient acetylenes catalyzed by the PdMo 3 S 4 cubane-type cluster gave exclusively Z-vinyl esters in good yields.

Construction of Escherichia coli vectors containing deoxyadenosine and deoxyguanosine adducts from (+)-anti-dibenz[a,j]anthracene diol epoxide at a defined site.

Dibenz[a,j]anthracene (DB[a,j]A) is a carcinogenic polycylic aromatic hydrocarbon, which is metabolically activated through the formation of bay region diol epoxides. Site-specifically modified M13mp19-based vectors containing a single (+)-anti-dibenz[a,j] anthracene diol epoxide [(+)-anti-DB[a,j[A-DE]-deoxyguanosine (dGuo) or -deoxyadenosine (dAdo) adduct were constructed. Four-base oligonucleotides, 5'-HOTGCA-3' and 5'-HOCATG-3', corresponding to the central four base pairs in the PstI and SphI restriction endonuclease sites, respectively, in the multiple cloning region of M13mp19, were reacted in solution with (+/-)-anti-DB[a,j]A-DE. The resulting adducted oligonucleotides were separated and purified using reverse-phase HPLC. Several different singly adducted oligonucleotides were isolated, consisting of the various cis and trans addition products of the (+) and (-) enantiomers of the diol epoxide bound to dGuo or dAdo in the oligonucleotides. 5'-HOTGCA-3' containing the (+)-anti-DB[a,j]A-trans-N2-dGuo adduct [T(DB[a,j]A-N2)GCA] and 5'-HOCATG-3' containing the (+)-anti-DB[a,j]A-trans-N6-dAdo adduct [C(DB[a,j]A-N6)ATG) were selected for subsequent ligation into M13mp19 vectors that had been constructed with a corresponding four base gap in the minus strand. Both unmodified and adducted oligonucleotides were successfully ligated into the M13mp19 vectors, [yields: unmodified -TGCA-M13mp19 (approximately 32%) and -CATG- M13mp19 (approximately 42%); adducted T(DB[a,j]A-N2)GCA-M13mp19 (approximately 13%) and C(DB[a,j]A-N6)ATG-M13mp19 (approximately 12%)]. The dAdo adduct-containing vector was characterized. The presence of a dAdo-DNA adduct at the recognition site of SphI inhibited restriction by SphI.(ABSTRACT TRUNCATED AT 250 WORDS)