Lipase-catalyzed enantioselective esterification of mono-aza-benzo-15-crown-5-ether derivatives in organic media

For the purpose of developing a new chiral crown ether unit as a chiral synthon, three racemic mono azabenzo-15-crown-5-ethers, i.e. (R,S)-1-(6,7,9,10,12,13,15,16-octahydro-5,8,14,17-tetraoxa-11-aza-benzocyclopentadecen-11-yl)-propan-2-ol, (R,S)-2-(6,7,9,10,12,13,15,16-octahydro-5,8,14,17-tetraoxa-11-aza-benzocyclopentadecen-11-yl)-1-phenyl-ethanol and (R , S)-1-[2-(6,7,9,10,12,13,15,16-octahydro-5,8,14,17-tetraoxa-11-aza-benzocyclopentadecen-11-ylmethyl)-phenyl]-ethanol were esterified with vinyl acetate using a lipase from Candida antarctica. The enzymatic acylation of alcohols produced monoacylated products. Two optically active azacrown ethers, (R)-propionic acid 1-methyl-2-(6,7,9,10,12,13,15,16-octahydro-5,8,14,17-tetraoxa-11-aza-benzocyclopentadecen-11-yl)-ethyl ester and (R)-acetic acid 1-[2-(6,7,9,10,12,13,15,16-octahydro-5,8,14,17-tetraoxa-11-aza-benzocyclopentadecen-11-ylmethyl)-phenyl]-ethyl ester were obtained within 48% and 36% yields, respectively and, at an enantiometric excess of over 99% in each case.     

Preparation of (S)-2,3-dichloro-1-propanol byPseudomonas sp. and its use in the synthesis of (R)-epichlorohydrin

Summary Pseudomonas sp. OS-K-29 assimilated (R)-2,3-dichloro-1-propanol preferentially as the sole source of carbon. Isolation of optically pure (S)-2,3-dichloro-1-propanol with 100% enantiomer excess (e.e.) from the racemate was done based on this bacterial assimilation using immobilized-cells of OS-K-29 with calcium-alginate. The overall examination of the reactor involved 19 batches for 50 days without loss of its activity. Highly pure (R)-epichlorohydrin with 99.5% e.e. was prepared from the (S)-2,3-dichloro-1-propanol with treatment of aqueous NaOH. This new method is simple and useful for manufacturing optically active (S)-2,3-dichloro-1-propanol and (R)-epichlorohydrin.     

Phosphonamidate inhibitors of human neutrophil collagenase

A series of phosphonamidates has been synthesized and shown to inhibit human neutrophil collagenase. The compounds all have sequences patterned after the cleavage site in the alpha 1(I) chain of type I collagen, except that the carbonyl group of the Gly residue in subsite P1 has been replaced by a P(= O)(OH) group (abbreviated GlyP). As the central GlyP-Leu unit is lengthened in the N- and C-terminal directions, in accordance with the cleavage sequence found in collagen, inhibition is systematically improved. The best inhibitor is Cbz-GlyP-Leu-Ala-Gly, which inhibits competitively with a KI value of 14 microM. These phosphonamidates are thought to be acting as transition-state analogues.     

产碱杆菌ECU0401催化拆分扁桃酸及其衍生物

从土壤中分离的1株产碱杆菌Alcaligenes sp.ECU0401具有扁桃酸脱氢酶活性,可以以扁桃酸、苯甲酰甲酸或苯甲酸为唯一C源生长,并且具有较高的脱氢酶活力。以外消旋扁桃酸为C源,采用分批补料策略培养（或反应）99h,扁桃酸累计投入量为30.4g/L,（S）-（＋）-扁桃酸被完全降解,（R）-（-）-扁桃酸回收产率为32.8%,对映体过量值（e.e.）〉99.9%。利用静息细胞作为催化剂不对称降解外消旋扁桃酸的氯代衍生物,制备获得光学活性的（R）-（-）-邻氯扁桃酸、（S）-（＋）-间氯扁桃酸和（S）-（＋）-对氯扁桃酸,光学纯度均超过99.9%e.e.。     

Regio- and stereospecific oxidation of 9,10-dihydroanthracene and 9,10-dihydrophenanthrene by naphthalene dioxygenase: structure and absolute stereochemistry of metabolites.

The oxidation of 9,10-dihydroanthracene and 9,10-dihydrophenanthrene was examined with mutant and recombinant strains expressing naphthalene dioxygenase from Pseudomonas putida (NCIB 9816.4. Salicylate-induced cells of P. putida strain 9816/11 and isopropylthiogalactopyranoside-induced cells of Escherichia coli JM109(DE3)(pDTG141) oxidized 9,10-dihydroanthracene to (+)-cis-1R,2S)-1,2-dihydroxy-1,2,9,10-tetrahydroanthracene (> 95% relative yield; > 95% enantiomeric excess) as the major product. 9-Hydroxy-9,10-dihydroanthracene (< 5% relative yield) was a minor product formed by both organisms. The same cells oxidized 9,10-dihydrophenanthrene to (+)-cis-(3S,4R)-3,4-dihydroxy-3,4,9,10-tetrahydrophenanthrene (70% relative yield; > 95% enantiomeric excess) and (+)-(S)-9-hydroxy-9,10-dihydrophenanthrene (30% relative yield). The major reaction catalyzed by naphthalene dioxygenase with 9,10-dihydroanthracene and 9,10-dihydrophenanthrene was stereospecific dihydroxylation in which both of the previously undescribed cis-diene diols were of R configuration at the benzylic center adjacent to the bridgehead carbon atom. The results suggest that for benzocylic substrates, the location of benzylic carbons influences the type of reaction(s) catalyzed by naphthalene dioxygenase.     

Stereochemical specificity of organophosphorus acid anhydrolase toward p-nitrophenyl analogs of soman and sarin

Organophosphorus acid anhydrolase (OPAA) catalyzes the hydrolysis of p-nitrophenyl analogs of the organophosphonate nerve agents, sarin and soman. The enzyme is stereoselective toward the chiral phosphorus center by displaying a preference for the R(P)-configuration of these analogs. OPAA also exhibits an additional preference for the stereochemical configuration at the chiral carbon center of the soman analog. The preferred configuration of the chiral carbon center is dependent upon the configuration at the phosphorus center. The enzyme displays a two- to four-fold preference for the R(P)-enantiomer of the sarin analog. The k(cat)/K(m) of the R(P)-enantiomer is 250 M(-1) s(-1), while that of the S(P)-enantiomer is 110 M(-1) s(-1). The order of preference for the stereoisomers of the soman analog is R(P)S(C) > R(P)R(C) > S(P)R(C) > S(P)S(C). The k(cat)/K(m) values are 36,300 M(-1)s(-1), 1250 M(-1) s(-1), 80 M(-1) s(-1) and 5 M(-1) s(-1), respectively. The R(P)S(C)-isomer of the soman analog is therefore preferred by a factor of 7000 over the S(P)S(C)-isomer.     

Discrimination in resolving systems. V. Pseudoephedrine - fluoromandelic acid diastereomers

Resolution of the isomeric 2'-, 3'-, and 4'-fluoromandelic acids with (+)-(1S;2S)-pseudoephedrine in 95% ethanol produces both well and poorly discriminating, hydrated and unsolvated binary salts. Seven observed diastereomeric phases are represented by five crystal structure types including three of the four types observed in the pseudoephedrine mandelates. Type a: monoclinic hemihydrate less-soluble (L) (R)-3'-fluoromandelate and more-soluble (M) (R)-4'-fluoromandelate (I); type b: orthorhombic unsolvated M (S)-2'-fluoromandelate; type c: orthorhombic unsolvated L (R)-2'-fluoromandelate; type d: orthorhombic dihydrate M (S)-3'-fluoromandelate and L (S)-4'-fluoromandelate; type e: monoclinic unsolvated M (R)-4'-fluoromandelate (II). Largest (15-fold) discriminating solubilities in 95% ethanol are found between the diastereomers with 2'-fluoromandelic acid, 50% more than in the corresponding ephedrine system. Principle interionic interactions are hydrogen-bonds between protonated secondary ammonium ions and carboxylates. Infinite chains of these are found in type c, with a four-atom repeating unit H-N(+)-H.O(-C(-)-O) [C(2)(1)(4)], and in types b and d, with a six-atom repeating unit H-N(+)-H.O-C(-)-O [C(2)(2)(6)]. Water of crystallization intervenes in the chains of type a but not of type d hydrated salts, according with higher average dehydration temperatures in the former. Hydrated salts in general are excessively soluble in 95% ethanol.     

Regio- and stereospecific oxidation of fluorene, dibenzofuran, and dibenzothiophene by naphthalene dioxygenase from Pseudomonas sp. strain NCIB 9816-4.

The regio- and stereospecific oxidation of fluorene, dibenzofuran, and dibenzothiophene was examined with mutant and recombinant strains expressing naphthalene dioxygenase from Pseudomonas sp. strain NCIB 9816-4. The initial oxidation products were isolated and identified by gas chromatography-mass spectrometry and nuclear magnetic resonance spectrometry. Salicylate-induced cells of Pseudomonas sp. strain 9816/11 and isopropyl-beta-D-thiogalactopyranoside-induced cells of Escherichia coli JM109(DE3)(pDTG141) oxidized fluorene to (+)-(3S,4R)-cis-3,4-dihydroxy-3,4-dihydrofluorene (80 to 90% relative yield; > 95% enantiomeric excess [ee]) and 9-fluorenol (< 10% yield). The same cells oxidized dibenzofuran to (1R,2S)-cis-1,2-dihydroxy-1, 2-dihydrodibenzofuran (60 to 70% yield; > 95% ee) and (3S,4R)-cis-3, 4-dihydroxy-3,4-dihydrodibenzofuran (30 to 40% yield; > 95% ee). Induced cells of both strains, as well as the purified dioxygenase, also oxidized dibenzothiophene to (+)-(1R,2S)-cis-1,2-dihydroxy-1, 2-dihydrodibenzothiophene (84 to 87% yield; > 95% ee) and dibenzothiophene sulfoxide (< 15% yield). The major reaction catalyzed by naphthalene dioxygenase with each substrate was stereospecific dihydroxylation in which the cis-dihydrodiols were of identical regiochemistry and of R configuration at the benzylic center adjacent to the bridgehead carbon atom. The regiospecific oxidation of dibenzofuran differed from that of the other substrates in that a significant amount of the minor cis-3,4-dihydrodiol regioisomer was formed. The results indicate that although the absolute stereochemistry of the cis-diene diols was the same, the nature of the bridging atom or heteroatom influenced the regiospecificity of the reactions catalyzed by naphthalene dioxygenase.     

Preparative Biorganic Chemistry Part 10 Asymmetric Reduction of Bicyclo[2.2.2]Octane-2,6-Diones with Baker's Yeast

Reduction of bicyclo[2.2.2]octane-2,6-dione with baker's yeast gave (lR,4S,6S)-6-hydroxybi-cyclo[2.2.2]octan-2-one (95% e.e.) contaminated with 8% of its (1S,4R,6S)-isomer. Similarly, the yeast reduction of 1-methylbicyclo[2.2.2]octane-2,6-dione furnished (1R,4S,6S)-6-hydroxy-1-methylbi-cyclo[2.2.2.]octan-2-one (99.5% e.e.) in 59% yield. The yeast reduction of 4-methylbi-cyclo[2.2.2.]octane-2,6-dione afforded (1R,4S,6S)-6-hydroxy-4-methylbicyclo[2.2.2.]octan-2-one (98% e.e.) contaminated with 3% of its (1S,4R,6S)-isomer in 58% yield.     

Sesquiterpenes from Cupressus macrocarpa foliage

Ten sesquiterpenes, many with unusual carbon skeletons, were identified in foliage of Cupressus macrocarpa. These are (-)-10-epi-beta-acoradiene; ent-widdra-2,4(14)-diene; (E)-iso-gamma-bisabolene, i.e., (4E)-4-(1,5-dimethylhex-5-enylidene)-1-methylcyclohexene; (-)-cumacrene, i.e., (4S)-4-[(1R,2S)-2-isopropenyl-1-methylcyclobutyl]-1-methylcyclohexene; (-)-alpha-chamipinene, i.e., (1S,6S,7S)-2,2,6,8-tetramethyltricyclo[5.3.1.01,6]undec-8-ene; and five sesquiterpenes with a 3,3,4'-trimethyl-1,1'-bi(cyclohexyl) skeleton for which the trivial name macrocarpane is proposed. The possible single-enzyme biogenesis of these sesquiterpenes is discussed.     

Spontaneous epimerization of (S)-deoxycoformycin and interaction of (R)-deoxycoformycin, (S)-deoxycoformycin, and 8-ketodeoxycoformycin with adenosine deaminase

(R)-Deoxycoformycin (pentostatin), (S)-deoxycoformycin, and 8-ketodeoxycoformycin were compared as inhibitors of calf intestine adenosine deaminase. In contrast to (R)-deoxycoformycin, which had been demonstrated as a tight-binding inhibitor with a dissociation constant of 2.5 X 10(-12) M [Agarwal, R. P., Spector, T., & Parks, R. E., Jr. (1977) Biochem. Pharmacol. 26, 359-367], (S)-deoxycoformycin and 8-ketodeoxycoformycin are slope-linear competitive inhibitors with respect to adenosine. The kinetic constants are 33 microM for inhibition by (S)-deoxycoformycin, 43 microM for 8-ketodeoxycoformycin, and 16 microM for the Km for adenosine. The stereochemistry of carbon 8 of the diazepine ring therefore causes a (1.3 X 10(7]-fold change in the affinity for the enzyme which is specific for the R configuration. This difference is attributed to an induced conformational change which cannot be initiated by the S isomer or the 8-keto analogue of (R)-deoxycoformycin. The studies were complicated by the need to remove traces of tight-binding inhibitor(s) from (S)-deoxycoformycin, since as little as 0.001% of the R isomer causes significant inhibition. The R and S isomers of deoxycoformycin are unstable in neutral or mildly acidic aqueous solutions. Isomerization of the secondary hydroxyl at carbon 8 of the diazepine ring is one of the reactions, resulting in S to R and R to S conversions for deoxycoformycins. Opening of the aglycon is also a major reaction. The tight-binding inhibitor generated from (S)-deoxycoformycin was identified as (R)-deoxycoformycin by high-pressure liquid chromatography, spectroscopy, circular dichroism, and chemical criteria.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biomimetic conversion of (3S)-(-)-neodictyoprolenol to optically pure (1S,2R)-(-)-dictyopterene B,marine algal sex pheromone

Both enantiomers of (3S)-(-)- and (3R)-(+)-Neodictyoprolenol [(3S,5Z,8Z)-(-)-1,5,8-undecatrien-3-ol] were successfully converted to the algal sex pheromone, (1S,2R)-(-)-dictyopterene B and (1R,2S)-(+)-dictyopterene B in high enantiomeric purities (e. e. > 99%), respectively, by the biomimetic reaction involving phosphorylation and elimination under a mild condition.     

Evidence for the involvement of tetrahydrofolate in the demethylation of nicotine by <Emphasis Type="Italic">Nicotiana plumbaginifolia</Emphasis> cell-suspension cultures

The conversion of nicotine to nornicotine by Nicotiana plumbaginifolia Viv. cells was investigated by analysing the redistribution of label during feeding experiments with (R,S)-[2H- methyl]nicotine, (R,S)-[13C- methyl]nicotine and (R,S)-[14C- methyl]nicotine, and the results show that the N-methyl group of nicotine can be recycled into primary metabolism. Nuclear magnetic resonance (NMR) analysis of ethanolic extracts of cells grown in the presence of (R,S)-[13C- methyl]nicotine, using 1H-13C correlation spectroscopy (HMQC, HMBC), revealed the presence of [3-13C]serine and [13C- methyl]methionine. Label was also identified in a cysteinyl derivative and in several methoxylated compounds, but no evidence was obtained with either NMR or ion-trap mass spectrometry for the presence of any intermediate between nicotine and nornicotine. However, experiments with (R,S)-[14C- methyl]nicotine indicated that 70-75% of the metabolised label was released as carbon dioxide. These results are consistent with a pathway in which the oxidative hydrolysis of the nicotine methyl produces an unstable intermediate, N'-hydroxymethylnornicotine, that breaks down spontaneously to nornicotine and formaldehyde, with the formaldehyde being metabolised either directly to formate and carbon dioxide, or through the tetrahydrofolate-mediated pathways of one-carbon metabolism. However since the key intermediate, N-hydroxymethylnornicotine, could not be detected, the possibility of a direct methyl group transfer to tetrahydrofolate cannot be excluded.     

Biochemical approaches to the synthesis of ethyl 5-(s)-hydroxyhexanoate and 5-(s)-hydroxyhexanenitrile

Three different biochemical approaches were used for the synthesis of ethyl 5-(S)-hydroxyhexanoate 1 and 5-(S)-hydroxyhexanenitrile 2. In the first approach, ethyl 5-oxo-hexanoate 3 and 5-oxo-hexanenitrile 4 were reduced by Pichia methanolica (SC 16116) to the corresponding (S)-alcohols, ethyl (S)-5-hydroxyhexanoate 1 and 5-(S)-hydroxyhexanenitrile 2, with an 80-90% yield and >95% enantiomeric excess (e.e). In the second approach, racemic 5-hydroxyhexanenitrile 5 was resolved by enzymatic succinylation, leading to the formation of (R)-5-hydroxyhexanenitrile hemisuccinate and leaving the desired alcohol 5-(S)-hydroxyhexanenitrile 2 with a yield of 34% (50% maximum yield) and >99% e.e. In the third approach, enzymatic hydrolysis of racemic 5-acetoxy hexanenitrile 6 resulted in the hydrolysis of the R-isomer to provide 5-(R)-hydroxyhexanenitrile, leaving 5-(S)-acetoxyhexanenitrile 7 with a 42% yield (50% maximum yield) and >99% e.e.     

Stereoselectivity and enantioselectivity of glutathione S-transferase toward stilbene oxide substrates

Isozyme 4-4 of rat liver glutathione S-transferase catalyzes the stereoselective addition of glutathione to the oxirane carbon of R-absolute configuration of cis-stilbene oxide, 2, to give 98 +/- 2% of the (1S,2S)-1,2-diphenyl-1-(S-glutathionyl)-2-hydroxyethane product with a turnover number (kc) of 0.22 s-1. The two enantiomers of trans-stilbene oxide, 3, are somewhat poorer substrates for the enzyme. Enantioselective addition of glutathione to 3 proceeds with turnover numbers of 0.12 s-1 and 0.023 s-1 for the (R,R,)- and (S,S)-antipodes, respectively.     

Discrimination in resolving systems. VI. Comparison of the diastereomers of deoxyephedrinium and ephedrinium 4'-fluoromandelates

(-)-(R)-Deoxyephedrine forms poorly discriminating diastereomeric salts with 4'-fluoromandelic acid from 95% ethanol. Both less-soluble (L) (S)-4'-fluoromandelate and more-soluble (M) (R)-4'-fluoromandelate phases are monoclinic and unsolvated. Their solubility ratio (M/L) in 95% ethanol is only 1.2, which correlates with the similarity and small differences in their respective heats of fusion and fusion temperatures. The (R)-deoxyephedrinium and the related (1R;2S)-ephedrinium 4'-fluoromandelate systems show L-salts with higher ion-pair volumes and lower densities than their M-salts. (R)-Deoxyephedrinium salts have higher volumes than the comparable (1R;2S)-ephedrinium salts even though the resolving base (R)-deoxyephedrine lacks the benzylic hydroxy. In the solids, bilayered structures segregate polar and nonpolar molecular regions. The principle interionic interactions are hydrogen bonds between protonated secondary ammonium ions and carboxylates forming infinite chains with a six-atom repeating unit H-N(+)-H...O-C(-)-O [C(2)(2)(6)]. These are buttressed by mandelate hydroxy to carboxylate hydrogen bonds. Differing interactions between phenyl and 4'-fluorophenyl rings in the nonpolar layers of the salts correlate with the density and stability inversion.     

Enantiotopic differentiation in horse-liver alcohol-dehydrogenase-catalyzed oxidoreduction studied with novel substrates having organometallic moieties

Horse-liver alcohol-dehydrogenase-catalyzed oxidation of 1,2-bis(hydroxymethyl)ferrocene (1) gave (1R)-(+)-1-formyl-2-hydroxymethylferrocene (3) (86 +/- 2% enantiomeric excess, e.e.), while the reduction of the corresponding dialdehyde 1,2-diformylferrocene (2) gave the antipode (1S)-(-)-3 (94 +/- 2% e.e.). This fact indicates that the pro-R group in both 1 and 2 was preferentially converted by the enzyme. When one of two substituents on the substrate was replaced by a methyl group or moved to the beta-site, the stereoselectivity in the reaction decreased as evidenced by the enantiomeric purity of the products (5-64% e.e.). Treatment of racemic 1-hydroxyethylferrocene (14) with horse-liver alcohol dehydrogenase (HLADH) gave optically pure (R)-(-)-14 together with acetylferrocene. The reduction of 2 with HLADH, NAD and (2H6)ethanol gave (-)-(1S,2R)-1-formyl-2-[(R)-hydroxy(2H1)methyl]ferrocene and that of 1,2-di[(2H)formyl]ferrocene with HLADH, NAD and ethanol gave (-)-(1S,2R)-1-(2H)formyl-2-[(S)-hydroxy(2H1)methyl]ferrocene. These configurations indicate that the enzymic reduction occurred on the re-face of pro-R formyl group. The re-face selectivity was also found in the enzymic reduction of (eta 6-benzaldehyde)tricarbonylchromium and its (2H)formyl analogue. Docking of 2 into the active site of HLADH was examined using computer graphics. It has been suggested that the enantioselectivity to the pro-R side in the oxidoreduction of 1 and 2 by HLADH is a natural consequence of the re-face selectivity, which is caused by a steric interaction between the ligand and the side chain of Phe-93 or the Zn complex and strengthened by an interaction between the unreactive polar alpha-substituent and the protein, probably by hydrogen bond formation.     

Hidden stereospecificity in the biosynthesis of divinyl ether fatty acids

Incubations of [8(R)-2H]9(S)-hydroperoxy-10(E),12(Z)-octadecadienoic acid, [14(R)-2H]13(S)-hydroperoxy-9(Z),11(E)-octadecadienoic acid and [14(S)-2H]13(S)-hydroperoxy-9(Z),11(E)-octadecadienoic acid were performed with preparations of plant tissues containing divinyl ether synthases. In agreement with previous studies, generation of colneleic acid from the 8(R)-deuterated 9(S)-hydroperoxide was accompanied by loss of most of the deuterium label (retention, 8%), however, the opposite result (98% retention) was observed in the generation of 8(Z)-colneleic acid from the same hydroperoxide. Formation of etheroleic acid and 11(Z)-etheroleic acid from the 14(R)-deuterated 13(S)-hydroperoxide was accompanied by loss of most of the deuterium (retention, 7-8%), and, as expected, biosynthesis of these divinyl ethers from the corresponding 14(S)-deuterated hydroperoxide was accompanied by retention of deuterium (retention, 94-98%). Biosynthesis of omega5(Z)-etheroleic acid from the 14(R)- and 14(S)-deuterated 13(S)-hydroperoxides showed the opposite results, i.e. 98% retention and 4% retention, respectively. The experiments demonstrated that biosynthesis of divinyl ether fatty acids from linoleic acid 9- and 13-hydroperoxides takes place by a mechanism that involves stereospecific abstraction of one of the two hydrogen atoms alpha to the hydroperoxide carbon. Furthermore, a consistent relationship between the absolute configuration of the hydrogen atom eliminated (R or S) and the configuration of the introduced vinyl ether double bond (E or Z) emerged from these results. Thus, irrespective of which hydroperoxide regioisomer served as the substrate, divinyl ether synthases abstracting the pro-R hydrogen generated divinyl ethers having an E vinyl ether double bond, whereas enzymes abstracting the pro-S hydrogen produced divinyl ethers having a Z vinyl ether double bond.     

Synthesis of four stereoisomers of 1,4-thiazane-3-carboxylic acid 1-oxide via the asymmetric transformation (combined isomerization-preferential crystallization) of 1,4-thiazane-3-carboxylic acid

In order to synthesize four stereoisomers of 1,4-thiazane-3-carboxylic acid 1-oxide (TCA SO), (S)-1,4thiazane-3-carboxylic acid [(S)-TCA], which is one of the precursors, was prepared by the asymmetric transformation (combined isomerization-preferential crystallization) of (RS)-TCA. This asymmetric transformation was used (2R, 3R)-tartaric acid [(R)-TA] as a resolving agent and salicylaldehyde as the epimerization catalyst in propanoic acid at 110 degrees C to afford a salt of (S)-TCA with (R)-TA in 100% de with a yield of over 90%. Optically pure (S)-TCA was obtained by treating the salt with triethylamine in methanol in a yield of over 80%, based on (RS)-TCA as the starting material. In addition, asymmetric transformation of (R)-TCA gave (S)-TCA in a yield of 60-70%. (S)-TCA was oxidized by hydrogen peroxide in dilute hydrochloric acid to selectively crystallize (1S, 3S)-TCA.SO. (1R, 3S)-TCA SO of 70% de from the filtrate was allowed to form a salt with (R)-TA after a treatment with triethylamine to give (1R, 3S)-TCA SO as a single diastereoisomer. (1R, 3R)- and (1S, 3R)-TCA.SO were also prepared by starting from (R)-TCA that had been synthesized from L-cysteine.     

Tsukamurella sp. E105 as a new biocatalyst for highly enantioselective hydrolysis of ethyl 2-(2-oxopyrrolidin-1-yl) butyrate

A new bacterial strain, E105, has been introduced as a biocatalyst for the enantioselective hydrolysis of ethyl (R,S)-2-(2-oxopyrrolidin-1-yl) butyrate, (R,S)-1, to (S)-2-(2-oxopyrrolidin-1-yl) butyric acid, (S)-2. This strain was isolated from 60 soil samples using (R,S)-1 as the sole carbon source. The isolate was identified as Tsukamurella tyrosinosolvens E105, based on its morphological characteristics, physiological tests, and 16S rDNA sequence analysis. The process of cell growth and hydrolase production for this strain was then investigated. The hydrolase activity reached its maximum after cultivation at 200?rpm and 30?°C for 36?h. Furthermore, the performance of the enantioselective hydrolysis of (R,S)-1 was studied. The optimal reaction temperature, initial pH, substrate concentration, and concentration of suspended cells were 30?°C, 6.8, 10 and 30?g/l (DCW), respectively. Under these conditions, a high conversion (>45?%) of the product (S)-2 with an excellent enantiomeric excess (ee) (>99?%), and a satisfied enantiomeric ratio (E) (>600) as well were obtained. This study showed that the bacterial isolate T. tyrosinosolvens E105 displayed a high enantioselectivity towards the hydrolysis of racemic ethyl 2-(2-oxopyrrolidin-1-yl) butyrate.