Targeting "hydrolytic" activity of the S-adenosyl-L-homocysteine hydrolase.

Substrates that are specific for the "hydrolytic" activities of AdoHcy hydrolase have been recently identified. Upon interaction with the AdoHcy hydrolase such substrates generate the "active" electrophiles which then react with the enzyme nucleophiles to produce covalent inhibition. Dihalohomovinyl and haloacetylene analogues derived from adenosine as well 5'-S-allenyl-5'--thioadenosine derivative have been characterized as the first type II mechanism-based inhibitors of AdoHcy hydrolase that rely only on the "hydrolytic" activity. Design and synthesis of the novel adenine nucleosides as well their interaction with AdoHcy hydrolase are discussed in this review.

Mechanisms of inactivation of human S-adenosylhomocysteine hydrolase by 5',5',6',6'-tetradehydro-6'-deoxy-6'-halohomoadenosines.

In an effort to design more specific and potent inhibitors of S-adenosylhomocysteine (AdoHcy) hydrolase, we investigated the mechanisms by which 5',5',6', 6'-tetradehydro-6'-deoxy-6'-halohomoadenosines (X = Cl, Br, I) inactivated this enzyme. The 6'-chloro (a) and 6'-bromo (b) acetylenic nucleoside analogues produced partial ( approximately 50%) loss of enzyme activity with a concomitant ( approximately 50%) reduction of E-NAD(+) to E-NADH. In addition, Ade and halide ions were released from the inhibitors in amounts suggestive of a process involving enzyme catalysis. AdoHcy hydrolase, which was inactivated with compound a, was shown to contain 2 mol of the inhibitor covalently bound to Lys318 of two subunits of the homotetramer. These data suggest that the enzyme-mediated water addition at the 5' position of compound a or b produces an alpha-halomethyl ketone intermediate, which is then attacked by a proximal nucleophile (i.e., Lys318) to form the enzyme-inhibitor covalent adduct (lethal event); in a parallel pathway (nonlethal event), addition of water at the 6' position produces an acyl halide, which is released into solution and chemically degrades into Ade, halide ion, and sugar-derived products. In contrast, compound c completely inactivated AdoHcy hydrolase by converting 2 equiv of E-NAD(+) to E-NADH and causing the release of 2 equiv of E-NAD(+) into solution. Four moles of the inhibitor was shown to be tightly bound to the tetrameric enzyme. These data suggest that compound c inactivates AdoHcy hydrolase by a mechanism similar to the acetylenic analogue of Ado described previously by Parry et al. [(1991) Biochemistry 30, 9988-9997].

Doubly homologated dihalovinyl and acetylene analogues of adenosine: synthesis, interaction with S-adenosyl-L-homocysteine hydrolase, and antiviral and cytostatic effects.

Treatment of the 6-aldehyde derived by Moffatt oxidation of 3-O-benzoyl-1,2-O-isopropylidene-alpha-D-ribo-hexofuranose (2c) with the dibromo- or bromofluoromethylene Wittig reagents generated in situ with tetrabromomethane or tribromofluoromethane, triphenylphosphine, and zinc gave the dihalomethyleneheptofuranose analogues 3b and 3d, respectively. Acetolysis, coupling with adenine, and deprotection gave 9-(7,7-dibromo-5,6, 7-trideoxy-beta-D-ribo-hept-6-enofuranosyl)adenine (5a) or its bromofluoro analogue 5b. Treatment of 5a with excess butyllithium provided the acetylenic derivative 9-(5,6, 7-trideoxy-beta-D-ribo-hept-6-ynofuranosyl)adenine (6). The doubly homologated vinyl halides 5a and 5b and acetylenic 6 adenine nucleosides were designed as putative substrates of the "hydrolytic activity" of S-adenosyl-L-homocysteine (AdoHcy) hydrolase. Incubation of AdoHcy hydrolase with 5a, 5b, and 6 resulted in time- and concentration-dependent inactivation of the enzyme (K(i): 8.5 +/- 0.5, 17 +/- 2, and 8.6 +/- 0.5 microM, respectively), as well as partial reduction of enzyme-bound NAD(+) to E-NADH. However, no products of the "hydrolytic activity" were observed indicating these compounds are type I mechanism-based inhibitors. The compounds displayed minimal antiviral and cytostatic activity, except for 6, against vaccinia virus and vesicular stomatitis virus (IC(50): 15 and 7 microM, respectively). These viruses typically fall within the activity spectrum of AdoHcy hydrolase inhibitors.

Inactivation of S-adenosyl-L-homocysteine hydrolase and antiviral activity with 5',5',6',6'-tetradehydro-6'-deoxy-6'-halohomoadenosine analogues (4'-haloacetylene analogues derived from adenosine).

Treatment of a protected 9-(5, 6-dideoxy-beta-D-ribo-hex-5-ynofuranosyl)adenine derivative with silver nitrate and N-iodosuccinimide (NIS) and deprotection gave the 6'-iodo acetylenic nucleoside analogue 3c. Halogenation of 3-O-benzoyl-5,6-dideoxy-1, 2-O-isopropylidene-alpha-D-ribo-hex-5-enofuranose gave 6-halo acetylenic sugars that were converted to anomeric 1,2-di-O-acetyl derivatives and coupled with 6-N-benzoyladenine. These intermediates were deprotected to give the 6'-chloro 3a, 6'-bromo 3b, and 6'-iodo 3c acetylenic nucleoside analogues. Iodo compound 3c appears to inactivate S-adenosyl-L-homocysteine hydrolase by a type I ("cofactor depletion") mechanism since complete reduction of enzyme-bound NAD+ to NADH was observed and no release of adenine or iodide ion was detected. In contrast, incubation of the enzyme with the chloro 3a or bromo 3b analogues resulted in release of Cl- or Br- and Ade, as well as partial reduction of E-NAD+ to E-NADH. Compounds 3a, 3b, and 3c were inhibitory to replication of vaccinia virus, vesicular stomatitis virus, parainfluenza-3 virus, and reovirus-1 (3a < 3b < 3c, in order of increasing activity). The antiviral effects appear to correlate with type I mechanism-based inhibition of S-adenosyl-L-homocysteine hydrolase. Mechanistic considerations are discussed.

Synthesis of homologated halovinyl derivatives from aristeromycin and their inhibition of human placental S-adenosyl-L-homocysteine hydrolase.

Moffatt oxidation of 2',3'-O-isopropylidenearisteromycin (1a) and treatment of the 5'-carboxaldehyde with [(p-tolylsulfonyl)methylene]triphenylphosphorane gave the homologated vinylsulfone 2. Treatment of 2 with tributylstannane/AIBN gave the (E/Z)-vinylstannanes which were converted into the E and Z fluoro- and iodovinyl analogs. Chain extension via the 5'-cyano-5'-deoxy derivative 10a gave the 6'-carboxaldehyde of homoaristeromycin. S-Adenosyl-L-homocysteine hydrolase was strongly inhibited by the fluorovinyl, 5b, and iodovinyl, 4b and 7b, compounds, and time-dependent kinetics were observed [1-2 microM (Ki) and 0.1-0.2 min-1 (kinact)]. The mechanism of inactivation was shown to involve addition of water at the vinyl 5' or 6' carbons with elimination of halide.

Discovery of type II (covalent) inactivation of S-adenosyl-L-homocysteine hydrolase involving its "hydrolytic activity": synthesis and evaluation of dihalohomovinyl nucleoside analogues derived from adenosine.

Treatment of the 5'-carboxaldehyde derived by Moffatt oxidation of 6-N-benzoyl-2',3'-O-isopropylideneadenosine (1) with the "(bromofluoromethylene)triphenylphosphorane" reagent and deprotection gave 9-(6-bromo-5, 6-dideoxy-6-fluoro-beta-d-ribo-hex-5-enofuranosyl)adenine (4). Parallel treatment with a "dibromomethylene Wittig reagent" and deprotection gave 9-(6,6-dibromo-5, 6-dideoxy-beta-d-ribo-hex-5-enofuranosyl)adenine (7), which also was prepared by successive bromination and dehydrobromination of the 6'-bromohomovinyl nucleoside 8. Bromination-dehydrobromination of the 5'-bromohomovinyl analogue 11 and deprotection gave (E)-9-(5, 6-dibromo-5,6-dideoxy-beta-d-ribo-hex-5-enofuranosyl)adenine (15). Compounds 4, 7, and 15 were designed as putative substrates of the "hydrolytic activity" of S-adenosyl-l-homocysteine (AdoHcy) hydrolase. Enzyme-mediated addition of water across the 5,6-double bond could generate electrophilic acyl halide or alpha-halo ketone species that could undergo nucleophilic attack by proximal groups on the enzyme. Such type II (covalent) mechanism-based inactivation is supported by protein labeling with 8-[3H]-4 and concomitant release of bromide and fluoride ions. Incubation of AdoHcy hydrolase with 7 or 15 resulted in irreversible inactivation and release of bromide ion. In contrast with type I mechanism-based inactivation, reduction of enzyme-bound NAD+ to NADH was not observed. Compounds 4, 7, and 15 were not inhibitory to a variety of viruses in cell culture, and weak cytotoxicity was observed only for CEM cells.

A novel mechanism-based inhibitor (6'-bromo-5', 6'-didehydro-6'-deoxy-6'-fluorohomoadenosine) that covalently modifies human placental S-adenosylhomocysteine hydrolase.

Most inhibitors of S-adenosylhomocysteine (AdoHcy) hydrolase function as substrates for the "3'-oxidative activity" of the enzyme and convert the enzyme from its active form (NAD+) to its inactive form (NADH) (Liu, S., Wolfe, M. S., and Borchardt, R. T. (1992) Antivir. Res. 19, 247-265). In this study, we describe the effects of a mechanism-based inhibitor, 6'-bromo-5', 6'-didehydro-6'-deoxy-6'-fluorohomoadenosine (BDDFHA), which functions as a substrate for the "6'-hydrolytic activity" of the enzyme with subsequent formation of a covalent linkage with the enzyme. Incubation of human placental AdoHcy hydrolase with BDDFHA results in a maximum inactivation of 83% with the remaining enzyme activity exhibiting one-third of the kcat value of the native enzyme. This partial inactivation is concomitant with the release of both Br- and F- ions and the formation of adenine (Ade). The enzyme can be covalently labeled with [8-3H]BDDFHA, resulting in a stoichiometry of 2 mol of BDDFHA/mol of the tetrameric enzyme. The 3H-labeled enzyme retains its original NAD+/NADH content. Tryptic digestion and subsequent protein sequencing of the [8-3H]BDDFHA-labeled enzyme revealed that Arg196 is the residue that is associated with the radiolabeled inhibitor. The partition ratio of the Ade formation (nonlethal event) to covalent acylation (lethal event) is approximately 1:1. From these experimental results, a possible mechanism by which BDDFHA inactivates AdoHcy hdyrolase is proposed: enzyme-mediated water addition at the C-6' position of BDDFHA followed by elimination of Br- ion results in the formation of homoAdo 6'-carboxyl fluoride (HACF). HACF then partitions in two ways: (a) attack by a proximal nucleophile (Arg196) to form an amide bond after expulsion of F- ion (lethal event) or (b) depurination to form Ade and hexose-derived 6-carboxyl fluoride (HDCF), which is further hydrolyzed to hexose-derived 6-carboxylic acid (HDCA) and F- ion (nonlethal event).

The mechanism of inactivation of human placental S-adenosylhomocysteine hydrolase by (E)-4',5'-didehydro-5'-methoxyadenosine and adenosine 5'-carboxaldehyde oxime.

The mechanisms by which (E)-4',5'-didehydro-5'-methoxyadenosine (DMOA) and adenosine 5'-carboxaldehyde oxime (ACAO) inactivate S-adenosylhomocysteine (AdoHcy) hydrolase were elucidated in this study. Their inhibitory activities toward AdoHcy hydrolase were found to be time- and concentration-dependent, and DMOA and ACAO had K(i) and k2 values of 3.0 microM and 0.10 min(-1) and 0.67 microM and 0.16 min(-1), respectively. The inactivation of AdoHcy hydrolase by DMOA (and ACAO) occurs concomitantly with the reduction of the enzyme-bound NAD+ to NADH. The rates of enzyme inactivation correspond to the rates of NADH formation. Incubation of both DMOA and ACAO with the NAD+ form of AdoHcy hydrolase resulted in formation of 3'-ketoadenosine (3'-keto-Ado) 5'-carboxaldehyde and its 4'-epimer. Incubation of DMOA and ACAO with the apo form of the enzyme afforded adenosine (Ado) 5'-carboxaldehyde and its 4'-epimer. These results show that DMOA and ACAO are "proinhibitors" of the enzyme. They are first converted to the inhibitors (Ado 5'-carboxaldehyde and its 4'-epimer) in the active site of the enzyme; these inhibitors then inactivate the enzyme by a type I mechanism. The results from this study demonstrated that this is a common mechanism by which 4',5'-didehydroadenosine analogs, serving as substrates of both the 5'-hydrolytic activity and the 3'-oxidative activity of the enzyme, inactivate AdoHcy hydrolase. The results also provide further evidence supporting the hypothesis that AdoHcy hydrolase possesses a 5'-hydrolytic activity independent of the 3'-oxidation activity.

Anticancer and antiviral effects and inactivation of S-adenosyl-L-homocysteine hydrolase with 5'-carboxaldehydes and oximes synthesized from adenosine and sugar-modified analogues.

Selectively protected adenine nucleosides were converted into 5'-carboxaldehyde analogues by Moffatt oxidation (dimethyl sulfoxide/dicyclohexylcarbodiimide/dichloroacetic acid) or with the Dess-Martin periodinane reagent. Hydrolysis of a 5'-fluoro-5'-S-methyl-5'-thio (alpha-fluoro thioether) arabinosyl derivative also gave the 5'-carboxaldehyde. Treatment of 5'-carboxaldehydes with hydroxylamine [or O-(methyl, ethyl, and benzyl)hydroxylamine] hydrochloride gave E/Z oximes. Treatment of purified oximes with aqueous trifluoroacetic acid and acetone effected trans-oximation to provide clean samples of 5'-carboxaldehydes. Adenosine (Ado)-5'-carboxaldehyde and its 4'-epimer are potent inhibitors of S-adenosyl-L-homocysteine (AdoHcy) hydrolase. They bind efficiently to the enzyme and undergo oxidation at C3' to give 3'-keto analogues with concomitant reduction of the NAD+ cofactor to give an inactive, tightly bound NADH-enzyme complex (type I cofactor-depletion inhibition). Potent type I inhibition was observed with 5'-carboxaldehydes that contain a ribo cis-2',3'-glycol. Their oxime derivatives are "proinhibitors" that undergo enzyme-catalyzed hydrolysis to release the inhibitors at the active site. The 2'-deoxy and 2'-epimeric (arabinosyl) analogues were much weaker inhibitors, and the 3'-deoxy compounds bind very weakly. Ado-5'-carboxaldehyde oxime had potent cytotoxicity in tumor cell lines and was toxic to normal human cells. Analogues had weaker cytotoxic and antiviral potencies, and the 3'-deoxy compounds were essentially devoid of cytotoxic and antiviral activity.

Inactivation of S-adenosyl-L-homocysteine hydrolase by amide and ester derivatives of adenosine-5'-carboxylic acid.

S-Adenosyl-L-homocysteine (AdoHcy) hydrolase has been shown to have (5'/6') hydrolytic activity with vinyl (5') or homovinyl (6') halides derived from adenosine (Ado). This hydrolytic activity is independent of its 3'-oxidative activity. The vinyl (or homovinyl) halides are converted into 5'(or 6')-carboxaldehydes by the hydrolytic activity of the enzyme, and inactivation occurs via the oxidative activity. Amide and ester derivatives of Ado-5'-carboxylic acid were prepared to further probe the hydrolytic capability of AdoHcy hydrolase. The oxidative activity (but not the hydrolytic activity) is involved in the mechanism of inhibition of the enzyme by the ester and amide derivatives of Ado-5'-carboxylic acid, in contrast to the inactivation of this enzyme by adenosine-derived vinyl or homovinyl halide analogues during which both activities are manifested.

(E)-5',6'-didehydro-6'-deoxy-6'-fluorohomoadenosine: a substrate that measures the hydrolytic activity of S-adenosylhomocysteine hydrolase.

(E)-5',6'-Didehydro-6'-deoxy-6'-fluorohomoadenosine (EDDFHA), which is a poor substrate for the oxidative activity of S-adenosyl-L-homocysteine (AdoHcy) hydrolase and thus a poor mechanism-based inhibitor was shown to be a good substrate for the hydrolytic activity of this enzyme. Incubation of EDDFHA with AdoHcy hydrolase (NAD+ form) produces a large molar excess of hydrolytic products [e.g., fluoride ion, adenine (Ade) derived from chemical degradation of homoadenosine 6'-carboxaldehyde (HACA), and 6'-deoxy-6'-fluoro-5'-hydroxyhomoadenosine (DFHHA)] accompanied by a slow irreversible inactivation of the enzyme. The enzyme inactivation was shown to be time-dependent, biphasic, and concomitant with the reduction of the enzyme-bound NAD+ (E.NAD+) to E-NADH. The reaction of EDDFHA with AdoHcy hydrolase was shown to proceed by three pathways: pathway a, water attack at the 6'-position of EDDFHA and elimination of fluoride ion results in the formation of HACA, which degrades chemically to form Ade; pathway b, water attack at the 5'-position of EDDFHA results in the formation of DFHHA; and pathway c, oxidation of EDDFHA results in formation of the NADH form of the enzyme (inactive) and 3'keto-EDDFHA, which could react with water at either the C5' or C6' positions. The partition ratios among the three pathways were determined to be k3':k6':k5' = 1:29:79 with one lethal event (enzyme inactivation) occurring every 108 nonlethal turnovers.(ABSTRACT TRUNCATED AT 250 WORDS)

Nucleic acid related compounds. 84. Synthesis of 6'-(E and Z)-halohomovinyl derivatives of adenosine, inactivation of S-adenosyl-L-homocysteine hydrolase, and correlation of anticancer and antiviral potencies with enzyme inhibition.

Treatment of 9-[6-(E)-(tributylstannyl)-5,6-dideoxy-2,3-O-isopropylidene- beta-D-ribo-hex-5-enofuranosyl]adenine [2b(E)] or the 6-N-benzoyl derivative 2a(E) with iodine (or N-iodosuccinimide) or bromine (or N-bromosuccinimide) gave virtually quantitative and stereospecific conversions to the 6'-(E)-(halohomovinyl)nucleoside analogues. Analogous treatment of the 6'-(Z)-vinyl-stannanes gave the 6'-(Z)-halo compounds. Treatment of 2a or 2b with chlorine or xenon difluoride/silver triflate gave E and Z mixtures of the respective 6'-chloro- or 6'-fluorohomovinyl products. Deprotection gave the 9-[6-(E and Z)-halo-5,6-dideoxy-beta-D-ribo- hex-5-enofuranosyl]-adenines [(E and Z)-5',6'-didehydro-6'-deoxy-6'-halohomoadenosines, EDDHHAs and ZDDHHAs, 4c-7c(E and Z)]. The acetylenic 5',5',6',6'-tetradehydro-6'- deoxyhomoadenosine (3c) and the 5'-bromo-5'-deoxy-5'-methyleneadenosine (10c) regioisomer of EDDBHA [5c(E)] also were obtained from 2. Concentration- and time-dependent inactivations of S-adenosyl-L-homocysteine (AdoHcy) hydrolase were observed with 3c and the 6'-(halohomovinyl)adenosine analogues. The order of inhibitory potency was I > Br > Cl > F and E > Z for the geometric isomers. AdoHcy hydrolase effected "hydrolysis" of the 6'-halogen from the (halohomovinyl)Ado compounds (to give the putative 6'-carboxaldehyde which underwent spontaneous decomposition) independently of its oxidative activity. Partition ratios for these hydrolytic turnovers/lethal inhibitory events were in the order F > Cl > Br > I. Biological activities were evaluated with several viruses and cancer cell lines, and potencies were generally in the order I > Br > Cl > F and E > Z isomers. This represents the first observation of a direct correlation of cytostatic activity with inhibition of AdoHcy hydrolase and highlights the potential of this enzyme as a viable target for chemotherapeutic intervention in anticancer as well as antiviral drug design.

Mechanism of inactivation of S-adenosylhomocysteine hydrolase by (E)-5',6'-didehydro-6'-deoxy-6'-halohomoadenosines.

S-Adenosylhomocysteine (AdoHcy) hydrolase is irreversibly inactivated by (E)-5',6'-didehydro-6'-deoxy-6'-halohomoadenosines (EDDHHAs, halogen = I, Br, and Cl). The inactivation is concomitant with the reduction of the enzyme-bound NAD+ (E.NAD+) to NADH, the release of halide ion, and the formation of adenine (Ade) from the EDDHHAs. The mechanism of this inactivation involves two catalytic pathways. Pathway a involves a rapid addition of water to the 5',6'-bond of EDDHHAs and elimination of halide ion, resulting in the formation of 6'-carboxaldehyde 1 which then degrades chemically, resulting in the formation of Ade. Alternatively, 6'-carboxyaldehyde 1 can be oxidized by E.NAD+ to form 3'-keto-6'-carboxaldehyde 3 and the NADH form (inactive) of the enzyme. Like 6'-carboxaldehyde 1, the 3'-keto derivative 3 degrades chemically to form Ade. Pathway b involves the oxidation of EDDHHAs to 3'-keto-EDDHHAs 2 by E.NAD+, as the first step, and the subsequent release of halide ion to form 3'-keto-6'-carboxaldehyde 3. Evidence in support of these mechanisms includes the observations that incubation of EDDHHAs with AdoHcy hydrolase generated large molar excesses of halide ions and Ade, that Ade was shown to eliminate spontaneously from 6'-carboxaldehyde 1, and that the more rapid the halide ion release (Cl- > Br- > I-) from the EDDHHAs or the greater the partition ratios (nonlethal turnovers/lethal event), the lower the enzyme inactivation efficiency.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescent nucleoside derivatives: Luminescence study of 4-dimethylaminopyridinium chloride derived from guanosine.

Photophysical properties of fluorescentN-[2-amino-9-(2',3',5'-tri-O-acetyl-ß-D-ribofuranosyl)-purin-6-yl]-4-dimethylaminopyridinium chloride (GDMAP) are determined in view of its possible use as a probe in DNA. The fluorescence intensity of GDMAP increases and exhibits doubleexponential decay in the presence of common nucleosides. The formation of ground-state complexes with nucleosides is inferred from absorption and emission measurements.

Adenosine-5'-carboxaldehyde: a potent inhibitor of S-adenosyl-L-homocysteine hydrolase.

Adenosine-5'-carboxaldehyde (3) and its 4'-epimer (4) were synthesized and shown to be potent type I mechanism-based inhibitors of recombinant rat liver AdoHcy hydrolase with k2/KI values of 16.7 x 10(-3) and 5.5 x 10(-3) nM-1 min-1, respectively. The observation that 3 and 4 are potent inhibitors of AdoHcy hydrolase supports the hypothesis that they function as key intermediates in the mechanism by which the (Z)- and (E)-4',5'-didehydro-5'-deoxy-5'-fluoroadenosines 1 and 2 inactivate this enzyme.

Formation of Avenacein Y by Fusarium avenaceum Fries Sacc. isolates from Germany and pathogenicity of the isolates to cereal seedlings.

Twelve isolates ofFusarium avenaceum Fries Sacc. originating from diseased corn plants from Germany produced Avenacein Y in amounts ranging from 0.001 to 1.6 g/kg of wheat grain. The isolates proved most pathogenic to triticale seedlings, less pathogenic to rye seedlings and least to wheat. Pathogenicity of the isolates was not correlated with their ability to produce Avenacein Y.

Formation of Avenacein Y byFusarium avenaceum Fries Sacc. isolates from poland and biological properties of the compound.

Eighteen isolates ofFusarium avenaceum Fries Sacc. originating from cereals, potato and carrot from Poland synthesized Avenacein Y in amounts ranging from 0.01 to 2.0 g/kg of wheat grain. The compound was produced in 1 kg of corn kernels by isolate KF-58, isolated, identified and used to test for antibiotic activity against plant pathogenic fungi of 11 genera. Application of Avenacein Y caused slight decrease of mycelium growth in four species only.

Antibiotic Y: biosynthesis by Fusarium avenaceum (Corda ex Fries) Sacc., isolation, and some physicochemical and biological properties.

A compound very similar to the mycotoxin citrinin was observed on thin-layer chromatographic plates during the screening analysis of grain extracts. This compound was produced by 22 of the tested Fusarium avenaceum (Corda ex Fries) Sacc. strains isolated from wheat, triticale, barley, corn, and potatoes. A chemical test confirmed the presence of an unknown compound, which was given the preliminary name of antibiotic Y (indicating yellow fluorescence). The following properties of the new metabolite are described: spectroscopic (UV, infrared, proton nuclear magnetic resonance, fluorescence, and mass spectrometry), phytotoxic, antibiotic (inhibitory effect of bacterial growth), and toxic (toxicity to Artemia salina, chicken embryos, and mouse fibroblasts). Elemental analysis of the compound showed that it had the general formula C15H10O8, in agreement with the mass spectrometric finding that the molecular ion had a molecular weight of 318. The structure of the compound is presently under study.

Synthesis and analysis of 1-octen-3-ol, the main flavour component of mushrooms.

The most abundant volatile occurring in mushrooms and responsible for the mushroom odour is 1-octen-3-ol. To meet the demand for a flavour compound yielding a mushroom odour a study was carried out on the possibility of obtaining 1-octen-3-ol synthetically. On the basis of literature data and experiments performed, the synthesis of this compound was carried out by two methods, i.e. by Grignard reaction between acrolein and amyl iodide and by selective reduction of 1-octen-3-on. The purity of the 1-octen-3-ol obtained was determined by GLC chromatography and by spectroscopic methods. The compound obtained by Grignard reaction had its IR, 13C NMR spectra and GLC chromatogram identical with those of the standard. The yield of 1-octen-3-ol by Grignard reaction was 65%, while the reduction of the ketone to the alcohol gave a yield of 90%.