Biosynthesis of 9-beta-D-arabinofuranosyladenine: hydrogen exchange at C-2' and oxygen exchange at C-3' of adenosine

The data presented here describe new findings related to the bioconversion of adenosine to 9-beta-D-arabinofuranosyladenine (ara-A) by Streptomyces antibioticus by in vivo investigations and with a partially purified enzyme. First, in double label in vivo experiments with [2'-18O]- and [U-14C]adenosine, the 18O:14C ratio of the ara-A isolated does not change appreciably, indicating a stereospecific inversion of the C-2' hydroxyl of adenosine to ara-A with retention of the 18O at C-2'. In experiments with [3'-18O]- and [U-14C]-adenosine, [U-14C]ara-A was isolated; however, the 18O at C-3' is below detection. The adenosine isolated from the RNA from both double label experiments has essentially the same ratio of 18O:14C. Second, an enzyme has been isolated and partially purified from extracts of S. antibioticus that catalyzes the conversion of adenosine, but not AMP, ADP, ATP, inosine, guanosine, or D-ribose, to ara-A. In a single label enzyme-catalyzed experiment with [U-14C]adenosine, there was a 9.9% conversion to [U-14C]ara-A; with [2'-3H]-adenosine, there was a 8.9% release of the C-2' tritium from [2'-3H]adenosine which was recovered as 3H2O. Third, the release of 3H as 3H2O from [2'-3H]adenosine was confirmed by incubations of the enzyme with 3H2O and adenosine. Ninety percent of the tritium incorporated into the D-arabinose of the isolated ara-A was in C-2 and 8% was in C-3. The enzyme-catalyzed conversion of adenosine to ara-A occurs without added cofactors, displays saturation kinetics, a pH optimum of 6.8, a Km of 8 X 10(-4) M, and an inhibition by heavy metal cations. The enzyme also catalyzes the stereospecific inversion of the C-2' hydroxyl of the nucleoside antibiotic, tubercidin to form 7-beta-D-arabinofuranosyl-4-aminopyrrolo[2,3-d]pyrimidine. The nucleoside antibiotic, sangivamycin, in which the C-5 hydrogen is replaced with a carboxamide group, is not a substrate. On the basis of the single and double label experiments in vivo and the in vitro enzyme-catalyzed experiments, two mechanisms involving either a 3'-ketonucleoside intermediate or a radical cation are proposed to explain the observed data.     

Preferential utilization of newly synthesized cholesterol as substrate for bile acid biosynthesis. An in vivo study using 18O2-inhalation technique.

Incorporation of 18O in cholic anc chenodeoxycholic acid was determined after inhalation of 18O2 by rats with biliary fistula. After a 30-min inhalation, the maximal incorporation of 18O in the three hydroxyl groups of cholic acid was about 1.8 atoms, and in the two hydroxyl groups of chenodeoxycholic acid about 1.1 atoms. About 0.4 atom of 18O in the cholic and chenodeoxycholic acid isolated was present at C-3. It was calculated that at least 50% of the biosynthesized bile acids were derived from newly synthesized cholesterol. The time course for the incorporation of 18O at C-3 of chenodeoxycholic acid was slightly different from that of cholic acid, indicating that a small part of chenodeoxycholic acid might have been synthesized from a pool of cholesterol different from that utilized in the biosynthesis of cholic acid. Incorporation of 18O in biliary cholesterol was less than 0.05 atom, indicating that the major part of this cholesterol is derived from a pool different from that utilized in bile acid biosynthesis.     

Biosynthetic studies on the tropane ring system of the tropane alkaloids from Datura stramonium

Isotopic labelling experiments have been carried out in Datura stramonium root cultures with the following isotopically labelled precursors; [2H3]- [2-13C, 2H3]-, [1-13C, 18O2]-acetates, 2H2O, [2H3-methyl]-methionine, [2-13C]-phenyllactate, [3-2H]-tropine and [2'-13C, 3-2H]-littorine. The study explored the incorporation of isotope into the tropane ring system of littorine 1 and hyoscyamine 2 and revealed that deuterium from acetate is incorporated only into C-6 and C-7, and not into C-2 and C-4 as previously reported. Oxygen-18 was not retained at a detectable level into the C(3)-O bond from [1-13C, 18O2]-acetate. The intramolecular nature of the rearrangement of littorine 1 to hyoscyamine 2 is revealed again by a labelling study using [2'-13C, 3-2H]-littorine, [2-13C]-phenyllactate and [3-2H]-tropine.     

Trichothecene Biosynthesis in Fusarium sporotrichioides: Origin of the Oxygen Atoms of T-2 Toxin

Mass spectral analysis of T-2 toxin formed during the growth of Fusarium sporotrichioides (ATCC 24043) in the presence of H₂¹⁸O showed incorporation of up to three ¹⁸O atoms per toxin molecule. The carbonyl oxygens of the acetates at C-4 and C-15 and of the isovalerate at C-8 were derived from H₂O. Toxin formed in the presence of ¹⁸O molecular oxygen incorporated up to six ¹⁸O atoms per toxin molecule. The overall incorporation was 78 and 92% of toxin molecules labeled for H₂¹⁸O and ¹⁸O₂ labeled samples, respectively. The oxygens of position 1, the 12,13-epoxide, and the hydroxyl groups at C-3, C-4, C-8, and C-15 were all derived from molecular oxygen.     

Mass spectrometric study of the enzymatic conversion of cholesterol to (22R)-22-hydroxycholesterol, (20R,22R)-20,22-dihydroxycholesterol, and pregnenolone, and of (22R)-22-hydroxycholesterol to the lgycol and pregnenolone in bovine adrenocortical preparations. Mode of oxygen incorporation.

Incubation of cholesterol with a bovine adrenocortical mitochondrial acetone-dried powder preparation yielded (22R)-22-hydroxycholesterol (I), (20R,22R)-20,22-dihydroxycholesterol(II), and pregnenolone (III) which were conclusively identified by combined gas chromatography-mass spectrometry. Incubations with [4-14C]cholesterol yielded I, II, and III with specific activities (determined from partial mass-spectral scans) not significantly different from those of the used substrate or the cholesterol reisolated after the incubation, demonstrating that the isolated compounds arose mostly, if not entirely, from the substrate cholesterol. Incubations in an 18O-enriched atmosphere yielded I, II, and III with 18O at position C-22, C-20 and C-22, and C-20, respectively, providing evidence that the hydroxyl groups of the side chain of I and II and the C-20 oxygen atom of III originated from molecular oxygen. The distribution of the oxygen atoms in II after incubation with 18O2 and 16O2 (devoid of 16O18O) proved that the hydroxyl groups of the side chain of II were introduced from two different molecules of oxygen, consistent with a sequential hydroxylation of cholesterol. No (20S)-20-hydroxycholesterol was found. Incubation of I in an 18O-enriched atmosphere afforded II and III with 18O at C-20.     

Catabolism of tryptophan, anthranilate, and 2,3-dihydroxybenzoate in Trichosporon cutaneum.

Trichosporon cutaneum degraded L-tryptophan by a reaction sequence that included L-kynurenine, anthranilate, 2,3-dihydroxybenzoate, catechol, and beta-ketoadipate as catabolites. All of the enzymes of the sequence were induced by both L-tryptophan and salicylate, and those for oxidizing kynurenine and its catabolites were induced by anthranilate but not by benzoate; induction was not coordinate. Molecular weights of 66,100 and 36,500 were determined, respectively, for purified 2,3-dihydroxybenzoate decarboxylase and its single subunit. Substrates for this enzyme were restricted to benzoic acids substituted with hydroxyl groups at C-2 and C-3; no added coenzyme was required for activity. Partially purified anthranilate hydroxylase (deaminating) catalyzed the incorporation of one atom of 18O, derived from either 18O2 or H2(18)O, into 2,3-dihydroxybenzoic acid.     

The mechanism of the attachment of esterifying alcohol in bacteriochlorophyll a biosynthesis.

The mechanism through which the C-17(3) carboxy group of bacteriochlorophyllide a is esterified to produce bacteriochlorophyll aphytyl of Rhodopseudomonas spheroides and bacteriochlorophyll ageranylgeranyl of Rhodospirillum rubrum was studied by using 5-aminolaevulinate labelled with 18O at its C-1 carboxy oxygen atoms. The latter species was prepared by an exchange reaction in which 5-aminolaevulinate hydrochloride was heated in H218O in an autoclave. A method for the determination of the 18O content of the C-1 oxygen atoms of 5-aminolaevulinate was developed. As a prelude to the mechanistic work, a systematic study was undertaken to establish the optimal conditions under which a significant proportion of the bacteriochlorophyll a of the two photosynthetic organisms originated from the exogenously added 5-aminolaevulinate. It was found that, when Rps. spheroides and Rsp. rubrum were grown in the presence of about 0.15mM- and 1.2mM-5-aminolaevulinate respectively, 30-40% of their chlorophyll was derived from the added precursor. In these conditions, 5-amino[1,4-18O3]laevulinate was incorporated into bacteriochlorophyll aphytyl and bacteriochlorophyll ageranylgeranyl by the relevant organisms. The samples of chlorophylls were then hydrolysed with alkali to obtain phytol and geranylgeraniol, which were converted into the corresponding trimethylsilyl derivatives and analysed by gas chromatography-mass spectrometry. The data were used to deduce that the alcohols contained 90-95% of the 18O originally present at each of the C-1 oxygen atoms of the precursor 5-aminolaevulinate. In the light of these results it is suggested that the ester bond at C-17(3) is formed, not by a chlorophyllase type of enzymic reaction, but by a process involving the nucleophilic attack by the C-17(3) carboxylate group of the chlorophyllide on the activated form of an isoprenyl alcohol.     

Mechanistic and stereochemical studies of a unique dehydration catalyzed by CDP-4-keto-6-deoxy-D-glucose-3-dehydrase: a pyridoxamine 5'-phosphate dependent enzyme isolated from Yersinia pseudotuberculosis.

CDP-4-keto-6-deoxy-D-glucose-3-dehydrase (E1) purified from Yersinia pseudotuberculosis is a pyridoxamine 5'-phosphate (PMP) dependent enzyme which catalyzes the C-O bond cleavage at C-3 of a CDP-4-keto-6-deoxy-D-glucose substrate, a key step in the formation of 3,6-dideoxyhexoses. Since enzyme E1 utilizes the PMP cofactor in a unique manner, it is essential to establish its role in E1 catalysis. When an incubation was conducted in [18O]H2O, incorporation of 18O into positions C-3 and C-4 of the recovered substrate was observed. This result not only provided the evidence necessary to reveal the reversibility of E1 catalysis but also lent credence to the formation of a delta 3,4-glucoseen intermediate. In view of E1 catalysis being initiated by a C-4' deprotonation of the PMP-substrate complex, the stereochemical course of this step was examined using chemically synthesized (4'S)- and (4'R)-[4'-3H]PMP as probes. Our results clearly demonstrated that the stereochemistry of this deprotonation is pro-S specific, which is in agreement with the stereochemical consistency found with other vitamin B6 phosphate dependent enzymes. The fact that reprotonation at C-4' of the PMP-delta 3,4-glucoseen complex in the reverse direction of E1 catalysis was also found to be pro-S stereospecific strongly suggested that enzyme E1, like most of its counterparts, has the si face of its cofactor-substrate complex exposed to solvent and accessible to active-site catalytic groups as well.(ABSTRACT TRUNCATED AT 250 WORDS)     

Three hydroxylations incorporating molecular oxygen in the aerobic biosynthesis of ubiquinone in Escherichia coli.

The biosynthetic origin of the oxygen atoms of ubiquinone 8 from aerobically grown Escherichia coli was studied by 18O labeling. An apparatus was developed which allowed the growth of cells under a defined atmosphere. Mass spectral analysis of ubiquinone 8 from cells grown under highly enriched 18O2 showed that three oxygen atoms of the quinone are derived from molecular oxygen. It was established that the molecular oxygen is incorporated into the two methoxyl groups (at C-5 and C-6) and one of the carbonyl positions of the ubiquinone molecule by demonstrating that only one of the incorporated oxygens will exchange with water under acidic conditions that specifically catalyze the exchange of carbonyl, but not methoxyl, oxygens. That the C-4 carbonyl oxygen is derived from molecular oxygen was shown by the incorporation of three atoms of 18O2 into ubiquinone 8 biosynthesized from added 4-hydroxybenzoic acid. Comparison of ubiquinone 8 and menaquinone 8 from E. coli grown under 18O2 confirmed that the labeled carbonyl oxygen of the [18O2]ubiquinone 8 is incorporated biosynthetically and not by chemical exchange in the cell. It is concluded that the three hydroxylation reactions involved in the pathway for the aerobic biosynthesis of ubiquinone are all catalyzed by monooxygenases. The implications of this study for the anaerobic biosynthesis of ubiquinone 8 in E coli are discussed.     

Synthesis and in vitro characterization of organometallic rhenium and technetium glucose complexes against Glut 1 and hexokinase

A series of nine organometallic technetium-99m and rhenium complexes of glucose are presented and characterized in vitro regarding their potential as surrogates of [18F]-2-fluoro-desoxy glucose ([18F]-FDG). The glucose derivatives are functionalized at positions C-1, C-2, C-3, and C-6. Different spacer lengths and chelating systems have been introduced at these sites. For the (radio)labeling, the organometallic precursors [99mTc(H2O)3(CO)3]+ and [ReBr3(CO)3](2-) respectively have been used. The resulting complexes have been characterized chemically and radiochemically. The formation of uniform products has been observed on the macroscopic (Re) and no-carrier-added level (99mTc). The Tc-99m complexes revealed good inertness against ligand exchange (Cys and His) and excellent stability in physiological buffered saline as well as in human plasma over a period of 24 h at 37 degrees C. The rhenium complexes have been tested for competitive inhibition of the (yeast) hexokinase. Only for C-2 derivatized glucose complexes with extended spacer functionalities Ki values in the millimolar and sub-millimolar range have been observed. In silico molecular docking experiments supported these experimental findings. However, the competitive inhibitors are not recognized as a pseudosubstrate of hexokinase. The cellular uptake of all 99mTc-complexes into HT-29 colon carcinoma cells via Glut1 was generally low and unspecific independent of the position at the hexose ring, the chelating systems, or the overall charge of the corresponding metal complexes. The current results seem to preclude the use of these compounds as [18F]-FDG surrogates primarily due to the low cellular uptake via Glut1.     

31P and 13C NMR studies of oxygen transfer during catalysis by 3-deoxy-D-manno-octulosonate cytidylyltransferase from Escherichia coli

[18O]3-Deoxy-D-manno-octulosonate (KDO), labeled at the anomeric oxygen, was prepared by exchange with [18O]H2O and used to follow the route of oxygen transfer during cytidine 5'-monophosphate-3-deoxy-D-manno-octulosonate (CMP-KDO) formation catalyzed by 3-deoxy-D-manno-octulosonate cytidylyl-transferase (CMP-KDO synthetase). The 31P-NMR signal of the phosphoryl group of CMP-KDO (-5.85 ppm), which appeared as a single resonance when CMP-KDO formation took place with unenriched KDO, appeared as two peaks when CMP-KDO formation took place in the presence of a mixture of [16O]-and [18O]KDO. These results demonstrate the retention of 18O during CMP-KDO formation. Confirmation that the labeled oxygen in CMP-KDO was retained in the "bridge" position between CMP and KDO came from 13C-NMR studies of CMP-KDO formed in the presence of 90% [2-13C, 18O] KDO. The prominent C-2 KDO resonance in CMP-KDO, which is normally a doublet at 101.4 ppm (Kohlbrenner, W.E., and Fesik, S.W. (1985) J. Biol. Chem. 260, 14695-14700), appeared as four peaks when a mixture of [2-13C,16O]- and [2-13C, 18O]KDO was used, confirming the direct bonding of 18O to the C-2 of KDO in CMP-KDO. These results are consistent with a nucleophilic displacement mechanism for CMP-KDO formation.     

The mechanism of free base formation from DNA by bleomycin. A proposal based on site specific tritium release from Poly(dA.dU)

Poly(dA.dU), which is specifically tritiated at the 1'-, 2'- (ribo configuration), 3'-, or 4'-position of deoxyuridine, has been synthesized and the fate of the tritium has been determined upon degradation of the polymer by bleomycin, Fe(II), and O2. No tritium is labilized from the 1'-3H-labeled polymer as 3H2O; however, the resulting 3-(uridin-1'-yl)-2-propenal (uracil propenal) has the expected specific activity. The 2'-3H-labeled polymer affords 3H2O and no label in the uracil propenal. This result and the lack of solvent incorporation into the uracil propenal suggest that proton abstraction from C-2' to afford the trans-propenal is highly stereospecific. For the 3'-3H-labeled polymer, 3H2O is formed and the specific activity of the uracil propenal is identical to that of the deoxyuridine. This suggests that the labilization of the 3'-H is exclusively associated with free uracil formation. 3H2O is also formed from the 4'-3H-labeled polymer. These findings along with previous studies are consistent with the formation of uracil propenal and free uracil by the trapping of the initially formed 4'-radical species by O2 or by a monooxygen species, respectively.     

Purine nucleoside phosphorylase cleaves the C--O bond of ribose 1-phosphate. Evidence from the 18O shift in 31P NMR.

An equilibrium mixture of highly enriched [18(O)]Pi (represents the mixture of [[18(O)4]Pi, [[18(O)3]Pi, [18(O)2]Pi as represented in the figures, unless otherwise specified), alpha-D-ribose 1-[16(O)]phosphate, and hypoxanthine plus inosine was equilibrated with calf spleen purine-nucleoside phosphorylase (EC 2.4.2.1). The 31P NMR spectrum clearly indicated the formation of alpha-D-ribose 1-[18(O)4]-phosphate and of [16(O)]Pi. Incubation for the same time span in the absence of alpha-D-ribose 1-phosphate left the [18(O)4]Pi isotopic distribution unchanged. The results clearly demonstrated that the C--O bond of alpha-D-ribose 1-phosphate is cleaved in the enzymatic reaction. It is unlikely that the enzyme catalyzes the exchange of oxygen between Pi and H2O. Several possible mechanistic pathways are ruled out by the results, which demand attack by a phosphate oxygen at the anomeric C-1' atom.     

Isotope effects on the crotonase reaction

The primary, alpha-secondary, beta-secondary, and beta'-secondary deuterium and primary 18O kinetic isotope effects on V/K for the dehydration of [(3S)-3-hydroxybutyryl]pantetheine by bovine liver crotonase (enoyl-CoA hydratase, EC 4.2.1.17) have been determined by the equilibrium perturbation method. The primary deuterium and 18O kinetic isotope effects are 1.61 and 1.051, respectively. The secondary deuterium effects at C-2, C-3, and C-4 are 1.12, 1.13, and 1.00 per H, respectively. The large 18O isotope effect suggests C-O bond cleavage is largely rate determining but is consistent with either an E1cb or E2 mechanism with a large amount of carbanion character. The beta-secondary effect is a factor of 1.05 greater than the equilibrium isotope effect, indicating that this C-H bond is less stiff in the affected transition state or that its motion is coupled to the reaction coordinate motion. Analytical solutions to the differential equations describing uni-uni equilibrium perturbations are presented.     

Incorporation of 18O2 into thymidine 5'-aldehyde in neocarzinostatin chromophore-damaged DNA

Strand scission of DNA by the chromophore of neocarzinostatin converts the 5'-hydroxyl of deoxyribose to a 5'-aldehyde. The origin of the aldehydic oxygen has now been elucidated by mass spectrometry. DNA-associated thymidine 5'-aldehyde produced by treatment of DNA with neocarzinostatin chromophore in 2H218O/16O2 or in 2H216O/18O2 was reduced, liberated by nuclease treatment, permethylated, and analyzed by gas chromatography-mass spectrometry. The data clearly show that molecular oxygen is the only source of the 5'-aldehydic oxygen. The addition of molecular oxygen at C-5', possibly via a reactive form of neocarzinostatin chromophore, must be involved; a carbonium ion intermediate at C-5' is ruled out.     

Influence of electron transport proteins on the reactions catalyzed by Fusarium fujikuroi gibberellin monooxygenases

The multifunctional cytochrome P450 monooxygenases P450-1 and P450-2 from Fusarium fujikuroi catalyze the formation of GA14 and GA4, respectively, in the gibberellin (GA)-biosynthetic pathway. However, the activity of these enzymes is qualitatively and quantitatively different in mutants lacking the NADPH:cytochrome P450 oxidoreductase (CPR) compared to CPR-containing strains. 3beta-Hydroxylation, a major P450-1 activity in wild-type strains, was strongly decreased in the mutants relative to oxidation at C-6 and C-7, while synthesis of C19-GAs as a result of oxidative cleavage of C-20 by P450-2 was almost absent whereas the C-20 alcohol, aldehyde and carboxylic acid derivatives accumulated. Interaction of the monooxygenases with alternative electron transport proteins could account for these different product distributions. In the absence of CPR, P450-1 activities were NADH-dependent, and stimulated by cytochrome b5 or by added FAD. These properties as well as the decreased efficiency of P450-1 and P450-2 in the mutants are consistent with the participation of cytochrome b5:NADH cytochrome b5 reductase as redox partner of the gibberellin monooxygenases in the absence of CPR. We provide evidence, from either incubations of GA12 (C-20 methyl) with cultures of the mutant suspended in [18O]H2O or maintained under an atmosphere of [18O]O2:N2 (20:80), that GA15 (C-20 alcohol) and GA24 (C-20 aldehyde) are formed directly from dioxygen and not from hydrolysis of covalently enzyme-bound intermediates. Thus these partially oxidized GAs correspond to intermediates of the sequential oxidation of C-20 catalyzed by P450-2.     

Mechanism of inactivation of chymotrypsin by 3-benzyl-6-chloro-2-pyrone

The mechanism of inactivation of chymotrypsin by 3-benzyl-6-chloro-2-pyrone has been studied. Chloride analysis of the inactivated enzyme suggests that the complex does not contain intact chloropyrone or an acid chloride. 13C NMR studies of the enzyme inactivated with 13C-enriched chloropyrones show that (1) the pyrone ring is no longer intact, (2) C-6 becomes a carboxylate group and C-2 becomes esterified to the enzyme, probably to serine-195, and (3) a double bond is present adjacent to the serine ester. The inactivated enzyme slowly regains catalytic activity with the concomitant release of (E)-4-benzyl-2-pentenedioic acid. It is concluded that double bond migration occurs during reactivation since the position of the double bond in the released diacid product is different than in the inactivator-enzyme complex. When the reactivation is carried out in [18O]H2O-enriched water, a single oxygen-18 is incorporated into the released product and is further evidence that the inactivator is bound to the enzyme only through a single ester linkage. A deuterium isotope effect on reactivation is observed when a chloropyrone deuterated at C-5 is used. This result demonstrates that removal of a proton from C-5 is required for reactivation and that isomerization of the double bond and not hydrolysis of the acyl-enzyme is rate determining. A variety of amines accelerate the rate of reactivation by functioning as general bases and not as nucleophiles. A reaction scheme is presented that accounts for the formation of the stable inactivator-enzyme complex as well as the production of two products derived from enzymatic hydrolysis of the chloropyrone.(ABSTRACT TRUNCATED AT 250 WORDS)     

s-Cis and s-trans isomerism of the His-Pro peptide bond in angiotensin and thyroliberin analogues.

The dipeptide His-Pro isomerizes from all-s-trans to partly s-cis when titrated in D2O from acidic to neutral pD as observed by 13C and 1H nuclear magnetic resonance of the proline side chain. This isomerization is reported by the His C-2 and C-4 protons and carbons which show distinct, well-resolved resonances for each isomer. The influence of the His-Pro peptide bond rotational state on the histidine protons far removed from the bond has not been previously observed in model compounds or peptides. The peptides thyroliberin (TRH), [3-MeHis2]-TRH, and [3-MeHis6]-, [Sar1,Al8]-, and Nalpha-acetylangiotensin II were found to similarly isomerize from all-s-trans to partly s-cis as reported by their His C-2 and C-4 proton resonances. The His C-2 and C-4 protons in the peptides [1,3-diMeHis2]-TRH and [1-MeHis6]-, and [homoHis6]-angiotensin do not report this isomerization. Angiotensin II has previously been found to exhibit the same isomerization. The reporting of the s-trans to s-cis isomerization by the His C-2 proton appears to be correlated with the known potencies of the five angiotensin peptides in rat uterine strips and of the three TRH peptides by radioimmunoassay of released thyrotropin.     

Sequential biosynthesis of sulfated and/or sialylated Lewis x determinants by transferases of the human bronchial mucosa.

The structural determination of sulfated carbohydrate chains from a cystic fibrosis patient respiratory mucins has shown that sulfation may occur either on the C-3 of the terminal Gal, or on the C-6 of the GlcNAc residue of a terminal N -acetyllactosamine unit. The two enzymes responsible for the transfer of sulfate from PAPS to the C-3 of Gal or to the C-6 of GlcNAc residues have been characterized in human respiratory mucosa. These two enzymes, in conjunction with fucosyl- and sialyltransferases, allow the synthesis of different sulfated epitopes such as 3-sulfo Lewis x (with a 3- O -sulfated Gal), 6-sulfo Lewis x and 6-sulfo-sialyl Lewis x (with a 6- O -sulfated GlcNAc). In the present study, the sequential biosynthesis of these epitopes has been investigated using microsomal fractions from human respiratory mucosa incubated with radiolabeled nucleotide-sugars or PAPS, and oligosaccharide acceptors, mostly prepared from human respiratory mucins. The structures of the radiolabeled products have been determined by their coelution in HPAEC with known oligosaccharidic standards. In the biosynthesis of 6- O -sulfated carbohydrate chains by the human respiratory mucosa, the 6- O -sulfation of a terminal nonreducing GlcNAc residue precedes beta1-4-galactosylation, alpha2-3-sialylation (to generate 6-sulfo-sialyl- N -acetyllactosamine), and alpha1-3-fucosylation (to generate the 6-sulfo-sialyl Lewis x determinant). The 3- O -sulfation of a terminal N -acetyllactosamine may occur if this carbohydrate unit is not substituted. Once an N -acetyllactosamine unit is synthesized, alpha1-3-fucosylation of the GlcNAc residue to generate a Lewis x structure blocks any further substitution. Therefore, the present study defines the pathways for the biosynthesis of Lewis x, sialyl Lewis x, sulfo Lewis x, and 6-sulfo-sialyl Lewis x determinants in the human bronchial mucosa.     

The conformation of abscisic acid by n.m.r. and a revision of the proposed mechanism for cyclization during its biosynthesis.

The n.m.r. spectrum of abscisic acid (ABA) formed from [1,2-13C2]acetate by the fungus Cercospora rosicola shows 13C-13C coupling between C-6' (41.7 p.p.m.; 36 Hz) and the downfield 6'-methyl group (6'-Me) (24.3 p.p.m, 36 Hz). This 6'-Me, therefore, is derived from C-3' of mevalonate [Bennett, Norman & Maier (1981) Phytochemistry 20, 2343-2344]. An i.n.e.p.t. (insensitive nuclei enhanced by polarization transfer) pulse sequence demonstrated that the downfield 13C signal is produced by the 6'-Me that gives rise to the upfield 1H 6'-Me signal (23.1 d). The absolute configuration of this, the equatorial 6'-Me group, was determined as 6'-pro-R by decoupling and n.O.e. (nuclear-Overhauser-enhancement) experiments at 300 MHz using ABA, ABA in which the axial 6'-pro-S 5'-hydrogen atom had been exchanged with 2H in NaO2H and the 1',4'-cis- and 1',4'-trans-diols formed from these samples. The configuration at C-1' and at C-6' are now compatible with a chair-folded intermediate during cyclization, as proposed for beta- and epsilon-rings of carotenoids. ABA in solution exists, as in the crystalline form, with the ring in a pseudo-chair conformation. The side chain is axial and the C-3 Me and the C-5 hydrogen atoms are predominantly cis(Z).