Phytotoxic Strains of Isolated from Truffles.

Most species are known as endophytes and/or phytopathogens of higher plants and have a worldwide distribution. Recently, information discovered with molecular tools has been also published about the presence of these fungi in the microbiome of truffle fruiting bodies. In the present work, we isolated and identified three strains from truffle fruiting bodies.

Formation of Azaphilone Pigments and Monasnicotinic Acid by the Fungus .

Due to the ever-increasing demand for healthy and safe food, much attention has been gained by natural food colorants. This study showed the culture fluid extract of the fungus VKM F-906 to contain red pigment and monasnicotinic acid (MNA) in predominant amounts. The structure of the pigment corresponded to -cavernamine (red pigment, RP).

Austalides V and W, new meroterpenoids from the fungus Aspergillus ustus and their antitumor activities.

Two new austalide meroterpenoids, named austalides V and W (1 and 2), were isolated from the fungus Aspergillus ustus VKM F-4692. Their structures were elucidated by extensive spectroscopic analysis and by comparison with related known compounds. The main structural feature of both compounds is a tetrahydrofuranyl ring (G), a structural fragment, first found in austalides.

Secondary metabolites of the genus Penicillium from undisturbed and anthropogenically altered Antarctic habitats.

From undisturbed Antarctic habitats (permafrost sediments 30-150 thousand years of age, water of Radok Lake) and superficial deposits contaminated with petroleum products, we isolated 14 and 9 strains of Penicillium fungi, respectively. Comparison of the fungal complexes showed them to differ by species composition; only two species-P. palitans and P.

[Secondary Metabolites of Fungi of the Usti Section, Genus Aspergillus and Their Application in Chemosystematics].

Secondary metabolites of 22 fungal strains (genus Aspergillus, section Usti) isolated at diverse geographic regions, including the Arctic permafrost deposits, were studied. The studied strains were found to synthesize a variety of biologically active compounds, structurally identified as drimane sesqueterpenoids, isoquinoline alkaloids (TMC-120 A−C, derivative 1), meroterpenoids (austalides О and J), and anthraquinone pigments (averufin, versicolorin C). Desferritriacetylfusigen production by A.

[Exometabolites of the Fungal Isolates (Genus Penicillium, Section Chrysogena) from Low-Temperature Ecotopes].

Exometabolites of 22 strains of the genus Penicillium, section Chrysogena isolated from low-temperature ecotopes of various geographical regions were analyzed. The ecotopes included permafrost deposits, frozen volcanic ash, a fossil horse, cryopeg, and water from an Antarctic lake. The studied strains were found to contain exometabolites belonging to the groups of penicillins (penicillin G), chrysogins (chrysogin, 3-acetylquinazolone-4, 2-pyruvoyl aminobenzamide, 2-hydroxypropionyl amunobenzamide, and questiomycin A), roquefortines (3,12-dihydroroquefortine, roquefortine, glandicolines A and B, and meleagrine), xanthocillins (xanthocillin X), and simple tryptophan derivatives (N-acetyltriptamine and indoleacetic acid).

[Biosynthesis of biologically active low-molecular weight compounds by fungi of the genus Penicillium (review)].

The recent data on exometabolite biosynthesis in fungi of the genus Penicillium is summarized. The study of creative species, as well as those isolated from extreme ecotopes, resulted in the identification of a number of novel, biologically active compounds. Alkaloid biosynthesis has been shown to begin on.

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.

[Fungi of the genus Penicillium as producers of physiologically active compounds (review)].

Fungi of the genus Penicillium isolated from little studied habitats are able to synthesize both previously known and new physiologically active compounds with diverse structures. They include secondary metabolites of alkaloid nature, i.e.

[Biosynthesis of fumiquinazolines by the fungus Penicillium thymicola].

Biosynthesis of fumiquinazolines F and G (FQs), PC-2, and pigments by the fungus P. thymicola VKM FW-869 is directly dependent on the content of carbon substrate (mannitol) in the medium. Pigment production prevailed at all of the tested mannitol concentrations.

[Physiological and biochemical characteristics of fungi of the genus Penicillium as producers of ergot alkaloids and quinocitrinins].

Four cultures of fungi of the genus Penicillium belonging to Furcatum Pitt subgenus, such as P. citrinum Thom, 1910; P. corylophilum Dierckx, 1901; P.

[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, diketopiperazines, and quinoline derivatives. A large group of the identified metabolites belongs to mycotoxins.

[The influence of medium composition on alkaloid biosynthesis by Penicillium citrinum].

The fungus P. citrinum produces secondary metabolites, clavine ergot alkaloids (EA), and quinoline alkaloids quinocitrinines (QA) in medium with various carbon and nitrogen sources and in the presence of iron, copper, and zinc additives. Mannitol and sucrose are most favorable for EA biosynthesis and mannitol is most favorable for QA.

[Clavine alkaloid biosynthesis by the fungus Penicillium palitans westling 1911 isolated from ancient permafrost deposits].

The relic strain of Penicillium palitans isolated from the ancient permafrost deposits produces clavine alkaloids such as festuclavine, fumigaclavine A, and fumigaclavine B. Alkaloid biosynthesis is concurrent with the growth. Tryptophan and zinc ion additives to the culture medium stimulate the synthesis of alkaloids.

[Effect of various factors on the biosynthesis of piscarinines, secondary metabolites of the fungus Penicillium piscarium westling].

Piscarinines A and B were synthesized most actively during the surface cultivation of the fungus Penicillium piscarium in a complex medium (5.5 mg/l). Under conditions of submerged cultivation in a mineral medium, the yield of piscarinines was two times lower.

[Growth and biosynthesis of rugulovasines in Penicillium variabile Sopp 1912].

Production of clavine alkaloids rugulovasines by P. variabile did not depend on the habitat of the producers. During submerged cultivation on a simple synthetic medium in early growth stages, microcyclic conidiation was observed in the tested fungi; its presence or absence, as well as the activity of the cultures as to biosynthesis of rugulovasines, depended on the composition of the culture medium.

[Transport of ergot alkaloids and quinocitrinins in the producing fungus Penicillium citrinum].

The decrease in the concentration of alkaloids in the culture liquid of Penicillium citrinum grown to the early stationary phase was found to be due to the uptake of quinocitrinins and ergot alkaloids by fungal cells. The ability of the fungal mycelium to absorb autogenous quinocitrinins does not depend on the mycelium age, whereas its ability to absorb ergot alkaloids is higher in the young than in the 12-day-old mycelium. The uptake of exogenously added ergot alkaloids by the fungal mycelium is accompanied by excretion of intracellular quinocitrinins.

[The fungus Penicillium variabile sopp 1912 isolated from permafrost deposits as a producer of rugulovasines].

It has been established that relict fungi Penicillium variabile Sopp can synthesize clavine alkaloids, rugulovasines A and B, which are revealed in this species for the first time. Submerged cultivation of the strain-producer revealed several microcycles of conidia formation. The synthesis of alkaloids was also of a cyclic character.

[Fungus Penicillium citrinum, isolated from permafrost sediments, as a producer of ergot alkaloids and new quinoline alkaloids quinocitrinines].

Quinocitrinines and ergot alkaloids are synthesized by the strain Penicillium citrinum VKM FW-800 as the culture grows. The major part of these secondary metabolites are secreted into the medium. In the phase of growth deceleration, these metabolites were partly absorbed by the producer cells.

[Penicillium expansum, a resident fungal strain of the orbital complex Mir, producing xanthocillin X and questiomycin A].

It was demonstrated that the fungus Penicillium expansum 2-7, a resident strain of the orbital complex Mir, which became dominating 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. Time courses of their biosyntheses during growth and development of the producer culture were studied.

[The fungus Penicillium citrinum Thom 1910 VKM FW-800 isolated from ancient permafrost sediments as a producer of the ergot alkaloids agroclavine-1 and epoxyagroclavine-1].

The study of the secondary metabolites of the relict strain Penicillium citrinum VKM FW-800 isolated from ancient Arctic permafrost sediments showed that this fungus produces agroclavine-1 and epoxyagroclavine-1, which are rare ergot alkaloids with the 5R,10S configuration of the tetracyclic ergoline ring system. The production of the alkaloids by the fungus showed a biphasic behavior, being intense in the phase of active growth and slowing down in the adaptive lag phase and in the stationary growth phase. The addition of zinc ions to the incubation medium led to a fivefold increase in the yield of the alkaloids.

[Isolation of Penicillium DIERCKX 1901--a producer of diketopiperazine alkaloids rokefortin and 3,12-dihydrokefortin--from permafrost].

Secondary metabolites of the three strains of Penicillium aurantiogriseum, isolated from permafrost sediments, were identified. It was found that these fungi synthesized diketopiperazine alkaloids roquefortine and 3,12-dihydroroquefortine. The strain VKM FW-766 synthesized alkaloids in in the course of certain growth-related processes.