The yellow toxins produced by Cercospora beticola. V. Structure of beticolins 2 and 4

A versatile Diels-Alder approach to functionalized hydroanthraquinones

The synthesis of highly substituted hydroanthraquinone derivatives with up to three stereogenic centres via a Diels-Alder reaction, starting from easily accessible 2-substituted naphthoquinones, is described. The [4+2]-cycloaddition is applicable for a broad range of substrates, runs under mild conditions and results in high yields. The highly regioselective outcome of the reactions is enabled by a benzoyl substituent at C2 of the dienophiles. The obtained hydroanthraquinones can be further modified and represent ideal substrates for follow-up intramolecular coupling reactions to create unique bicyclo[3.3.1] or -[3.2.2]nonane ring systems which are important natural product skeletons.

A Concise Approach to Anthraquinone-Xanthone Heterodimers

A synthetic approach to anthraquinone-xanthone heterodimers is described. The route to the pentacyclic core features an efficient assembly of a benzocycloheptenone via a new intramolecular oxidative arylation of an enol ether and a Hauser-Kraus annulation-aldol reaction sequence to access the characteristic bicyclo[3.2.2]nonene motif. Acremoxanthone A is synthesized in 10 steps from commercially available material to demonstrate the application of this approach.

The structure of ergot alkaloid hydroxyergotamine

The structure of natural alkaloid hydroxyergotamine (P212121, a = 11.242(1) Å, b = 13.006(2) Å, c = 22.208(2) Å, Z = 4) has been solved by direct methods and refined anisotropically to the R value of 0.041. It has been established that the absolute stereochemistry classifies the alkaloid among the members of d-lysergic acid series. Ergolene moiety possesses the usual flap down conformation of the D ring. The piperazine ring F is in envelope form with the benzyl substituent in the eclipsed conformation. The L-proline ring has a predominant envelope form. The observed extended conformation of LSD-amide bond is stabilized by N3–NH3 … O1 and O5–HO5 … O1 intramolecular hydrogen bonds.

Conformation of ergopeptam and ergopeptine alkaloids (ergocristam and ergocristine)

The crystal structures of two ergot alkaloids ergocristam (I) and ergocristine acetone solvate (II), have been determined by X-ray diffraction and compared with their conformation in solution obtained from NMR data. The presence of D-proline in I essentially influences the conformation of the alkaloid tripeptide moiety which seems likely to explain why I does not undergo further enzymatical hydroxylation and is found as a terminal step of ergot alkaloid biosynthesis.

Beticolins, nonpeptidic, polycyclic molecules produced by the phytopathogenic fungus Cercospora beticola, as a new family of ion channel-forming toxins

Beticolins are toxins produced by Cercospora beticola, a phytopathogenic fungus responsible for the leaf spot disease of sugar beet. They form a family of 20 nonpeptidic compounds (named B0 to B19) that share the same polycyclic skeleton but differ by isomeric configuration (ortho- or para-) and by a variable residue R (bridging two carbons in one of the six cycles). It has been previously shown that B0 assembles itself into a multimeric structure and forms ion channels into planar lipid bilayers (C. Goudet, A.-A. Very, M.-L. Milat, M. Ildefonse, J.-B. Thibaud, H. Sentenac, and J.-P. Blein, Plant J. 14:359-364, 1998). In the present work, we investigate pore formation by three ortho-beticolins, B0, B2, and B4, and their related (i.e., same R) para-isomers, B13, B1, and B3, respectively, using planar lipid bilayers. All beticolins were able to form ion channels with multiple conductance states, although the type of cyclization (ortho- or para-) and residue (R) result in variations of channel conductance and ionic permeability, respectively. Channel formation by beticolins is likely to be involved in the biological activity of these toxins.