Screening for Ergot Alkaloid Producers among Microscopic Fungi by Means of the Polymerase Chain Reaction

The potential of the polymerase chain reaction for the detection of ergot alkaloid producers among microscopic fungi of the generaPenicilliumand Clavicepswas evaluated. Twenty-three strains of various species of fungi with a previously studied capacity for alkaloid production were used. The internal fragment of the gene encoding 4-dimethylallyltryptophan synthase, the enzyme catalyzing the first step in the biosynthesis of ergot alkaloids, was amplified using degenerate primers. This approach revealed an about 1.2-kb specific DNA fragment in micromycetes synthesizing ergot alkaloids with complete tetracyclic ergoline system. Microorganisms that produce alkaloids with modified C or D ergoline rings, as well as -cyclopiazonic acid, did not yield the PCR fragment of the expected size. This fragment was also not found in fungi incapable of ergot alkaloid production.     

Production of Alkaloids by Fungi of the Genus PenicilliumGrown on Wheat Grain

The ability to produce alkaloids has been studied in 13 strains belonging to ten species of the genus Penicillium. Most of these strains produce identical ranges of alkaloids when grown on wheat grain and synthetic Abe's medium. These are roquefortine, 3,12-dihydroroquefortine, and glandicolines A and B in strain P. chrysogenum VKM F-1987; fumigaclavines A and B, festuclavine, and pyroclavine in P. commune VKM F-308, F-3491, and KBP4; agroclavine 1 and epoxyagroclavine 1 in P. fellutanum VKM F-1073; fellutanine A in P. fellutanum F-3020; roquefortine, 3,12-dihydroroquefortine, meleagrin, and glandicolines A and B in P. glandicola VKM F-743; aurantioclavine in P. nalgiovense VKM F-229; isofumigaclavines A and B, festuclavine, roquefortine, and 3,12-dihydroroquefortine in P. roquefortii VKM F-2389; roquefortine, 3,12-dihydroroquefortine, and meleagrin in P. vitale VKM F-3624; roquefortine and oxaline in P. vulpinum VKM F-256; and -cyclopiazonic acid and rugulovasine B in P. viridicatum C-47. No alkaloids were found in P. rugulosum VKM F-352 grown on wheat grain. A simple method is proposed for isolating alkaloids from affected grain.     

Factors contributing to roquefortine yield variability during cultivation of penicillium roquefortii

Variability in the roquefortine yield was shown to be associated with its consumption by the mycelium during isolation of the end product, which depended on temperature, time of culture liquid storage, and biomass concentration. This was also related to the presence in chloroform of chlorocarbonic acid ethyl ester that reacted with roquefortine.     

Formation of alkaloids from Penicillium species fungi during growth on wheat kernels

The ability to produce alkaloids has been studied in 13 strains belonging to 10 species of the genus Penicillium. Most of these strains produce identical ranges of alkaloids when grown on wheat grain and synthetic Abe medium. They are roquefortine, 3,12-dihydroroquefortine, and glandicolines A and B in strain P. chrysogenum VKM F-1987; fumigaclavines A and B, festuclavine, and pyroclasine in P. commune VKM F-308, F-3491, and KBP4; agroclavine 1 and epoxyagroclavine 1 in P. fellutanum VKM F-1073; fellutanine A in P. fellutanum F-3020; roquefortine, 3,12-dihydroroquefortine, meleagrin, and glandicolines A and B in P. glandicola VKM F-743; aurantioclavine in P. nalgiovense VKM F-229; isofumigaclavines A and B, festuclavine, roquefortine, and 3,12-dihydroroquefortine in P. roquefortii VKM F-2389; roquefortine, 3,12-dihydroroquefortine, and meleagrin in P. vitale VKM F-3624; roquefortine and oxaline in P. vulpinum VKM F-256; and alpha-cyclopiazonic acid and rugulovasine B in P. viridicatum C-47. No alkaloids were found in P. rugulosum VKM F-352 grown on wheat grain. A simple method is proposed for isolating alkaloids from affected grains.     

Occurrence of indole alkaloids among secondary metabolites of soil Aspergillus

The occurrence of indole alkaloids among secondary fungal metabolites was studied in species of the genus Aspergillus, isolated from soils that were sampled in various regions of Russia (a total of 102 isolates of the species A. niger, A. phoenicis, A. fumigatus, A. flavus, A. versicolor, A. ustus, A. clavatus, and A. ochraceus). Clavine alkaloids were represented by fumigaclavine, which was formed by A. fumigatus. alpha-Cyclopiazonic acid was formed by isolates of A. fumigatus, A. flavus, A. versicolor, A. phoenicis, and A. clavatus. The occurrence of indole-containing diketopiperazine alkaloids was documented for isolates of A. flavus, A. fumigatus, A. clavatus, and A. ochraceus. No indole-containing metabolites were found among the metabolites of A. ustus or A. niger.     

Taxonomic position and nitrogen-containing secondary metabolites of the fungus Penicillium vitale Pidoplichko Et Bilai Apud Bilai

The type strain Penicillium vitale Pidoplichko et Bilai apud Bilai 1961 VKM F-3624 was found to considerably differ from a sibling species P. janthinellium (syn. P. simplicissimum) in some physiological and morphological features (growth rates at different temperatures, the size of philiades, and the shape of conidia), as well as in the pattern of the nitrogen-containing secondary metabolites produced (roquefortine, 3,12-dihydroroquefortine, meleagrin, aurantioclavine, indole-3-acetic acid, and N-acetyltryptamine). The data obtained suggest that P. vitale represent an independent species.     

Synthesis of alpha-cyclopiazonic acid by fungi of the genus Aspergillus

The presence of alpha-cyclopiazonic acid has been studied among metabolites of Aspergillus fungi. The study was performed with 138 cultures of 13 species obtained from the All-Russia Collection of Microorganisms and the collection of our institute. alpha-Cyclopiazonic acid was most frequently encountered among the metabolites of the section Flavi (the ability to synthesize alpha-cyclopiazonic acid was expressed in 61% of the strains of A. flavus, 83% of the strains of A. oryzae, and all strains of A. tamarii). This expression index for A. versicolor was less than 5%. We showed for the first time that alpha-cyclopiazonic acid is produced by A. fumigatus and A. phoenicis (expression in 30% of the strains of either species).     

Production of mycophenolic acid by fungi of the genus Penicillium link

Out of 36 strains of fungi of the genus Penicillium, some of which were isolated from ancient permafrost soils, 14 strains synthesized mycophenolic acid (MPA). Maximal (over 500 mg/l) accumulation of MPA in culture liquid was observed in P. brevicompactum strains (VKM F-457, VKM F-477, and VKM F-1150). This was the first study to detect MPA in representatives of the species P. rugulosum; in three strains of this species (VKM FW-665, VKM FW-717, and VKM FW-733), the level of MPA accumulation exceeded 300 mg/l. The time course of the synthesis of MPA by the P. rugulosum strain VKM FW-733 was studied. It was shown that the synthesis of this metabolite was dramatically intensified at the stationary growth phase (ten days).     

Distribution of glyphosate and methylphosphonate catabolism systems in soil bacteria <Emphasis Type="Italic">Ochrobactrum anthropi</Emphasis> and <Emphasis Type="Italic">Achromobacter</Emphasis> sp

Bacterial strains capable of utilizing methylphosphonic acid (MP) or glyphosate (GP) as the sole sources of phosphorus were isolated from soils contaminated with these organophosphonates. The strains isolated from MP-contaminated soils grew on MP and failed to grow on GP. One group of the isolates from GP-contaminated soils grew only on MP, while the other one grew on MP and GP. Strains Achromobacter sp. MPS 12 (VKM B-2694), MP degraders group, and Ochrobactrum anthropi GPK 3 (VKM B-2554D), GP degraders group, demonstrated the best degradative capabilities towards MP and GP, respectively, and were studied for the distribution of their organophosphonate catabolism systems. In Achromobacter sp. MPS 12, degradation of MP was catalyzed by C–P lyase incapable of degrading GP (C–P lyase I). Adaptation to growth on GP yielded the strain Achromobacter sp. MPS 12A, which retained its ability to degrade MP via C–P lyase I and was capable of degrading GP with formation of sarcosine, thus suggesting the involvement of a GP-specific C–P lyase II. O. anthropi GPK 3 also degraded MP via C–P lyase I, but degradation of GP in it was initiated by glyphosate oxidoreductase, which was followed by product transformation via the phosphonatase pathway.