A. G. Kozlovsky

Penicillium aurantiogriseum Dierckx 1901: Producer of Diketopiperazine Alkaloids (Roquefortine and 3,12-Dihydroroquefortine), Isolated from Permafrost

Secondary metabolites of three strains of Penicillium aurantiogriseumisolated from permafrost sediments were identified. It was found that these fungi synthesized the diketopiperazine alkaloids roquefortine and 3,12-dihydroroquefortine. The strain VKM FW-766 synthesized alkaloids in the course of certain growth-related processes. When the strain was grown on a mineral medium, the time courses of the roquefortine and 3,12-dihydroroquefortine concentrations were characterized by biphasic curves.

Rugulosuvines A and B, Diketopiperazine Alkaloids of Penicillium rugulosumand Penicillium piscariumFungi

Two diketopiperazine alkaloids, rugulosuvines A and B (tryptophan and phenylalanine are their precursors), were isolated and purified from a culture liquid of Penicillium rugulosumVKM F-352 and Penicillium piscariumVKM F-325 fungi. Physical and physicochemical studies showed the absolute structure of rugulosuvine A. The absolute structure of rugulosuvine B was demonstrated to be identical to that of rugulosuvine A.

Secondary metabolites in taxonomy of the Penicillium fungi

A correlation was established between species specificity and synthesis of specific secondary metabolites by the Penicillium fungi. Strains of the subgenus Aspergilloides usually synthesize metabolites of polyketide nature. Most strains of the subgenus Furcatum produce clavine ergot alkaloids and metabolites of diketopiperazine nature. The only clavine ergot alkaloids and diketopiperazine alkaloids produced by strains of the subgenus Biverticillium are rugulovasines and rugulosuvines, respectively. Species designations of the strains of the subgenus Penicillium isolated from permafrost soil, the Mir orbital complex, and sites undergoing anthropogenic load were refined based on the marker secondary metabolites. Changes in the taxonomic position of some strains in the genus Penicillium are suggested.

Diketopiperazine Alkaloids from the fungusPenicillium piscarium westling

Fungi of the speciesPenicillium piscarium produced diketopiperazine alkaloids (isorugulosuvine, puberuline, verrucosine, prolyltryptophanyldiketopiperazine, 12,13-dehydroprolyltryptophanyldiketopiperazine, fellutanine A, phenylalanylphenylalanyldiketopiperazine, as well as roquefortine and 3,12-dihydroroquefortine, whose precursors are tryptophan, phenylalanine, leucine, proline, and histidine.

The Fungus Penicillium citrinum, Isolated from Permafrost Sediments, as a Producer of Ergot Alkaloids and New Quinoline Alkaloids Quinocitrinines

Quinocitrinines and ergot alkaloids were synthesized by the strain Penicillium citrinum VKM FW-800 as the culture grews. The major part of these secondary metabolites was secreted into the medium. In the phase of growth deceleration, these metabolites were partly absorbed by the producer cells. Zinc ions stimulated both the primary and secondary metabolic processes. Addition of this microelement into the culture medium stimulated biomass accumulation and the synthesis of clavine alkaloids and quinocitrinines.

Piscarinines, New Polycyclic Diketopiperazine Alkaloids from Penicillium piscarium NKM F-691

Abstract Penicillium piscarium VKM F-961 produces two new polycyclic diketopiperazine alkaloids, piscarinines A (1) and B (2) displaying moderate cytotoxicity. Their structures were established by MS and NMR investigations.

Secondary metabolites of Penicillium fungi isolated from permafrost deposits as chemotaxonomic markers

Species identification of slow-growing fungi of the genus Penicillium isolated from ancient permafrost deposits was performed using micro- and macromorphological characteristics as well as the composition of secondary metabolites. The strains producing clavine ergot alkaloids fumigaclavines A and B and festuclavine were assigned to the species P. palitans Westling 1911, whereas the strains forming ochratoxins A and B were identified as P. verrucosum Dierckx 1901.

New producers of biologically active compounds—fungal strains of the genus Penicillium isolated from permafrost

Screening of producers of secondary metabolites was carried out among 25 fungal strains of Penicillium genus isolated from permafrost in Arctic and Antarctic regions and Kamchatka. Nearly 50% of the investigated strains synthesize biologically active substances of alkaloid nature: ergot alkaloids, diketopiperazinees, and quinoline derivatives. A large group of the identified metabolites belongs to mycotoxins. A strain of Penicillium waksmanii was found producing epoxyagroclavine-I and quinocitrinines. The main physiological and biochemical characteristics of this producer were investigated.

Penicillium expansum, a Resident Fungal Strain of the Orbital Complex Mir, Producing Xanthocyllin X and Questiomycin A

It was demonstrated that the fungus Penicillium expansum 2-7, a resident strain of the orbital complex Mir, which became dominant at the end of a long-term space flight, formed biologically active secondary metabolites (antibiotics). Using physicochemical methods these metabolites were identified as xanthocyllin X and questiomycin A. The time courses of their biosyntheses during the growth and development of the producer culture were studied. The addition of zinc to the culture medium affected both the growth of the culture and the biosyntheses of the antibiotics. The concentrations of zinc in the medium, optimum for xanthocyllin X and questiomycin A production, were 0.3 and 3.0 mg/l, respectively.

Exo-metabolites of mycelial fungi isolated in production premises of cheese-making and meat-processing plants

Data were obtained on the species composition of mycelial fungi isolated from the air of workrooms and production premises in cheese-making and meat-processing plants. The strains studied were shown to be capable of producing various low molecular weight compounds. Many of them are mycotoxins such as α-cyclopiazonic acid (CPA), mycophenolic acid (MPA), citrinin, cladosporin, roquefortine and ergot alkaloids. The profiles of the secondary metabolites were used to elucidate the species’ names of the isolated strains.