Joachim Podlech

Origin of organic molecules and biomolecular homochirality.

Abstract. Theories about the origin of biomolecular homochirality, which seems to be a prerequisite for the creation of life, are discussed. First, possible terrestrial and extraterrestrial sources of organic molecules are outlined. Then, mechanisms for the formation of enantiomerically enriched compounds and for the amplification of their chirality are described.

Alternariol acts as a topoisomerase poison, preferentially affecting the IIα isoform

Alternariol (AOH), a mycotoxin formed by Alternaria alternata, has been reported to possess genotoxic properties. However, the underlying mechanism of action is unclear. Here, we tested the hypothesis that interactions with DNA-topoisomerases play a role in the DNA-damaging properties of AOH. First we compared DNA-damaging properties of AOH with other Alternaria mycotoxins such as AOH monomethyl ether (AME), altenuene and isoaltenuene. AOH and AME significantly increased the rate of DNA strand breaks in human carcinoma cells (HT29, A431) at micromolar concentrations, whereas altenuene and isoaltenuene did not affect DNA integrity up to 100 microM. Next, we selected AOH as the most DNA-damaging Alternaria metabolite for further studies of interactions with DNA topoisomerases. In cell-free assays, AOH potently inhibited DNA relaxation and stimulated DNA cleavage activities of topoisomerase I, IIalpha and IIbeta. Stabilisation of covalent topoisomerase II-DNA intermediates by AOH was also detectable in cell culture, and here, the IIalpha isoform was preferentially targeted. AOH is thus characterised as a poison of topoisomerase I and II with a certain selectivity for the IIalpha isoform. Since topoisomerase poisoning and DNA strand breakage occurred within the same concentration range, poisoning of topoisomerase I and II might at least contribute to the genotoxic properties of AOH.

Identification of a polyketide synthase required for alternariol (AOH) and alternariol-9-methyl ether (AME) formation in Alternaria alternata.

Alternaria alternata produces more than 60 secondary metabolites, among which alternariol (AOH) and alternariol-9-methyl ether (AME) are important mycotoxins. Whereas the toxicology of these two polyketide-based compounds has been studied, nothing is known about the genetics of their biosynthesis. One of the postulated core enzymes in the biosynthesis of AOH and AME is polyketide synthase (PKS). In a draft genome sequence of A. alternata we identified 10 putative PKS-encoding genes. The timing of the expression of two PKS genes, pksJ and pksH, correlated with the production of AOH and AME. The PksJ and PksH proteins are predicted to be 2222 and 2821 amino acids in length, respectively. They are both iterative type I reducing polyketide synthases. PksJ harbors a peroxisomal targeting sequence at the C-terminus, suggesting that the biosynthesis occurs at least partly in these organelles. In the vicinity of pksJ we found a transcriptional regulator, altR, involved in pksJ induction and a putative methyl transferase, possibly responsible for AME formation. Downregulation of pksJ and altR caused a large decrease of alternariol formation, suggesting that PksJ is the polyketide synthase required for the postulated Claisen condensations during the biosynthesis. No other enzymes appeared to be required. PksH downregulation affected pksJ expression and thus caused an indirect effect on AOH production.

NEW INSIGHT INTO THE SOURCE OF BIOMOLECULAR HOMOCHIRALITY : AN EXTRATERRESTRIAL ORIGIN FOR MOLECULES OF LIFE?

Circular polarized light in space might be responsible for the fact that amino acids isolated from meteorites are not racemic. For example, 1 has been found with an enantiomeric excess of up to 10.4%. Such radiation has now been observed for the first time.

Glucuronidation of the mycotoxins alternariol and alternariol-9-methyl ether in vitro: chemical structures of glucuronides and activities of human UDP-glucuronosyltransferase isoforms.

Alternariol (AOH) and alternariol-9-methyl ether (AME) are major toxins produced by fungi of the genus Alternaria and are frequently found in various food items. Because AOH has three hydroxyl groups and AME two, the formation of various glucuronides must be expected. When AOH was incubated with hepatic and intestinal microsomes from rats, pigs and humans in the presence of uridine diphosphate glucuronic acid, two glucuronides were detected and tentatively identified as AOH-3-O-glucuronide and AOH-9-O-glucuronide. Under the same conditions, AME yielded predominantly AME-3-O-glucuronide and only small amounts of AME-7-O-glucuronide. The activities of all microsomes for the glucuronidation of AOH and AME were in the same range. Nine out of ten recombinant human UDP-glucuronosyltransferases (UGTs) were able to glucuronidate AOH, and eight out of ten UGTs had activity for AME. These data suggest that AOH and AME are readily glucuronidated in hepatic and extrahepatic tissues, implying that glucuronidation constitutes a major metabolic pathway in the disposition of these mycotoxins.

Neue Einblicke in den Ursprung der Homochiralität biologisch relevanter Moleküle – Grundstoffe des Lebens aus dem All?

ZirkularpolarisierteStrahlungimWeltall konnte dafur verantwortlich sein, das Aminosauren, die aus Meteoriten isoliert wurden, nicht racemisch vorliegen; z. B. wurden fur 1 Enantiomerenuberschusse bis zu 10.4% ee ermittelt. Eine solche Strahlung konnte nun erstmals nachgewiesen werden.

Nucleophilic Additions to Alkylidene Bis(sulfoxides)—Stereoelectronic Effects in Vinyl Sulfoxides

Conjugate additions of nucleophiles (e.g. enolates, amines and malonate anions) to bis(p-tolylsulfinyl)alkenes, alkylidene-1,3-dithiane-1,3-dioxides and alkylidene-1,3-dithiolane-1,3-dioxides have recently been published. Reasons for different selectivities and reaction rates will be discussed by consideration of steric and electronic effects. The preferred mode of attack can be explained by stereoelectronic effects (hyperconjugation) in the primarily carbanion, which is stabilized by n-->S-O-sigma* interaction with an antiperiplanar S=O group. Calculation of the transition states [BP86/aug-TZVP] for the addition of acetone enolate to the dithiane-derived alkylidene bis(sulfoxide) revealed that 6.6-7.3 kJ mol(-1) more energy is needed for an attack leading to a less-stabilized carbanion. Two axial S=O groups in dithiolane-derived alkylidene bis(sulfoxides) lead to a higher reactivity towards nucleophiles.

Stereoelectronic Effects in α-Carbanions of Conformationally Constrained Sulfides, Sulfoxides, and Sulfones

Stabilizing effects in oxygenated thiane- and 1,3-dithiane-derived alpha-carbanions were investigated computationally. All isomers bearing sulfide, sulfoxide, and sulfone functional groups and combinations thereof were investigated by DFT calculations and NBO analyses. Their stabilities and the stereoelectronic effects present in these compounds were compared. Stabilizing effects of the respective functional groups were further estimated by calculation of isodesmic reactions. It turned out that n(C) --> sigma*(S-O) interactions, where both the n(C) and the S=O bond are in an antiperiplanar conformation, have the highest stabilizing effects. Similar stabilizing interactions are effective in carbanions with an equatorial lone pair at the carbon; here a productive n(C) --> sigma*(S-C) interaction is possible. n(C) --> sigma*(S-O) interactions, where the S=O bond is part of a sulfoxide are significantly more effective than in sulfones. Calculations of isodesmic reactions show similar trends but suggest the presence of additional electrostatic effects and possibly, to some extent, steric effects.

Activities of human recombinant cytochrome P450 isoforms and human hepatic microsomes for the hydroxylation ofAlternaria toxins.

TheAlternaria toxins alternariol (AOH), alternariol-9-methyl ether (AME), altenuene (ALT) and isoaltenuene (iALT) undergo extensive oxidative metabolism, but the cytochrome P450 (CYP) isoforms responsible for the reported hydroxylation reactions are yet unknown. In the present study, the activities of twelve human CYP isoforms for the hydroxylation of AOH, AME, ALT and iALT at different positions have been determined. The most active monooxygenase for AOH and AME was CYP1A1, and lower activities were observed for CYP1A2, 2C19 and 3A4. Hydroxylation at C-2 of AOH and AME was the preferred reaction of most isoforms. For ALT and iALT, CYP2C19 had the highest activity, followed by 2C9 and 2D6. The dominating metabolite of all active isoforms was the 8-hydroxylated ALT and iALT. The activities of the CYP isoforms are consistent with the pattern of metabolites of theAlternaria toxins obtained with pooled human hepatic microsomes. Based on the activities of the CYP isoforms, a significant extrahepatic hydroxylation must be expectede.g. in the lung and esophagus for AOH and AME, and in the intestine and ovaries for ALT and iALT. As all major hydroxylation products are catechols, the extrahepatic metabolism ofAlternaria toxins may be of toxicological relevance.

Stereoelectronic Effects in Vinyl Sulfoxides

Though vinyl sulfoxides behave in some respects like alpha,beta-unsaturated carbonyl compounds, the mode of stabilization is significantly different. Interaction of the C=C double bond (acting as a donor) with the electron-withdrawing S=O bond is only possible when the p orbitals of the double bond are collinear with the S-O sigma* orbital. The maximum UV absorbance wavelengths in conformationally constrained substrates bearing an S=O bond collinear with the p orbitals of a C=C double bond are 2-14 nm higher than those in analogous compounds with a roughly orthogonal sulfoxide moiety. Similarly, a lone pair evolving during nucleophilic attack on vinyl sulfoxides is stabilized only if it is oriented anti to a S=O bond, which has significant impact on the stereoselectivities and reaction rates for nucleophilic attack on vinyl sulfoxides. The differing reaction rates of differently configured vinyl sulfoxides were measured in a competition experiment.