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Beilstein J. Org. Chem. 2020, 16, 1596–1605, doi:10.3762/bjoc.16.132
Graphical Abstract
Figure 1: Doriprismatica stellata nudibranch, egg ribbon, and Spongia cf. agaricina specimen.
Figure 2: The structurally new 12-deacetoxy-4-demethyl-11,24-diacetoxy-3,4-methylenedeoxoscalarin (relative s...
Figure 3: Superimposed HPLC–MS chromatogram of Doriprismatica stellata nudibranch, egg ribbon, and Spongia cf...
Figure 4: Proposed relative configuration of 12-deacetoxy-4-demethyl-11,24-diacetoxy-3,4-methylenedeoxoscalar...
Beilstein J. Org. Chem. 2016, 12, 969–984, doi:10.3762/bjoc.12.96
Figure 1: Structures of cystobactamids 507, 919-1 and 919-2.
Figure 2: Structures of aurafuron A and corallopyronin A.
Figure 3: Structures of ixabepilone and capecitabine.
Figure 4: Structures of DKxanthene-534 and myxochelin A.
Figure 5: Phylogenetic tree of halotolerant and halophilic myxobacteria. The neighbor-joining tree is based o...
Figure 6: Structure of nannocystin A.
Figure 7: Structure of phenylnannolones A–C.
Figure 8: Structures of the pyrronazols, dihydroxyphenazin and 1-hydroxyphenazin-6-yl-α-D-arabinofuranoside.
Figure 9: Structures of nannozinones A + B and nannochelin A from N. pusilla strain MNa10913.
Figure 10: Structure of haliangicin from H. ochraceum.
Figure 11: Structure of haliamide from H. ochraceum SMP-2.
Figure 12: Structures of salimabromide, enhygrolides A + B and salimyxins A + B.
Figure 13: Structures of miuraenamides A–F from P. miuraensis.
Beilstein J. Org. Chem. 2016, 12, 571–588, doi:10.3762/bjoc.12.56
Figure 1: Selected monocyclic and monobenzo α-pyrone structures.
Figure 2: The basic core structure of dibenzo-α-pyrones.
Figure 3: Selected dibenzo-α-pyrones.
Figure 4: Structure of ellagic acid and of the urolithins, the latter metabolized from ellagic acid by intest...
Figure 5: Structure of murayalactone, the only dibenzo-α-pyrone described from bacteria.
Figure 6: Structures of the 6-pentyl-2-pyrone (29) and of trichopyrone (30). Only 29 showed antifungal activi...
Figure 7: Selected monocyclic α-pyrones.
Figure 8: Structures of the gibepyrones A–F.
Figure 9: Structures of the phomenins A and B.
Figure 10: Structures of monocyclic α-pyrones showing pheromone (47) and antitumor activity (48), respectively....
Figure 11: Structures of 6-alkyl (alkoxy or alkylthio)-4-aryl-3-(4-methanesulfonylphenyl)pyrones.
Figure 12: Structures of kavalactones.
Figure 13: Strutures of germicins.
Figure 14: Structures of the pseudopyronines.
Figure 15: The structures of the monobenzo-α-pyrone anticoagulant drugs warfarin and phenprocoumon.
Figure 16: Structures of selected monobenzo-α-pyrones.
Figure 17: Hypothetical pathway of 29 generation from linoleic acid [34].
Figure 18: Proposed biosynthetic pathway of alternariol (modified from [77]). Malonyl-CoA building blocks are appl...
Figure 19: Structures of phenylnannolones and of enterocin, both biosynthesized via polyketide synthase system...
Figure 20: Pyrone ring formation. Examples for the three types of PKS systems are shown in A–C. In D the mecha...
Figure 21: Structures of csypyrones.
Figure 22: Schematic drawing of the T-shaped catalytic cavities of the related enzymes CorB and MxnB. The two ...
Figure 23: Stereo representation of the CorB binding situation (modified from [89]). The substrate mimic (dark vio...
Figure 24: Proposed mechanism for the CsyB enzymatic reaction. A) Coupling reaction of the β-keto fatty acyl i...
Figure 25: Proposed biosynthesis of photopyrone D (37) by the enzyme PpyS from P. luminescens (modified from [63])...