Psychedelic fungus (Psilocybe sp.) authentication in a case of illegal drug traffic: sporological, molecular analysis and identification of the psychoactive substance.

In nature, there are >200 species of fungi with hallucinogenic properties. These fungi are classified as Psilocybe, Gymnopilus, and Panaeolus which contain active principles with hallucinogenic properties such as ibotenic acid, psilocybin, psilocin, or baeocystin. In Chile, fungi seizures are mainly of mature specimens or spores. However, clandestine laboratories have been found that process fungus samples at the mycelium stage. In this transient stage of growth (mycelium), traditional taxonomic identification is not feasible, making it necessary to develop a new method of study. Currently, DNA analysis is the only reliable method that can be used as an identification tool for the purposes of supporting evidence, due to the high variability of DNA between species. One way to identify the species of a distinctive DNA fragment is to study PCR products analyzed by real time PCR and sequencing. One of the most popular sequencing methods of forensic interest at the generic and intra-generic levels in plants is internal transcribed spacer (ITS). With real time PCR it is possible to distinguish PCR products by differential analysis of their melting temperature (Tm) curves. This paper describes morphological, chemical, and genetic analysis of mycelia of psychedelic fungi collected from a clandestine laboratory. The fungus species were identified using scanning electron microscopy (SEM), mass spectrometry, HRM analysis, and ITS sequencing. The sporological studies showed a generally smooth surface and oval shape, with maximum length 10.1 µm and width 6.4 µm. The alkaloid Psilocyn was identified by mass spectrometry, while HRM analysis and ITS sequencing identified the species as Psilocybe cubensis. A genetic match was confirmed between the HRM curves obtained from the mycelia (evidence) and biological tissue extracted from the fruiting bodies. Mycelia recovered from the evidence and fruiting bodies (control) were genetically indistinguishable.

Iterative l-Tryptophan Methylation in Psilocybe Evolved by Subdomain Duplication.

Psilocybe mushrooms are best known for their l-tryptophan-derived psychotropic alkaloid psilocybin. Dimethylation of norbaeocystin, the precursor of psilocybin, by the enzyme PsiM is a critical step during the biosynthesis of psilocybin. However, the "magic" mushroom Psilocybe serbica also mono- and dimethylates l-tryptophan, which is incompatible with the specificity of PsiM. Here, a second methyltransferase, TrpM, was identified and functionally characterized. Mono- and dimethylation activity on l-tryptophan was reconstituted in vitro, whereas tryptamine was rejected as a substrate. Therefore, we describe a second l-tryptophan-dependent pathway in Psilocybe that is not part of the biosynthesis of psilocybin. TrpM is unrelated to PsiM but originates from a retained ancient duplication event of a portion of the egtDB gene that encodes an ergothioneine biosynthesis enzyme. During mushroom evolution, this duplicated gene was widely lost but re-evolved sporadically and independently in various genera. We propose a new secondary metabolism evolvability mechanism, in which weakly selected genes are retained through preservation in a widely distributed, conserved pathway.

Translocation of mercury from substrate to fruit bodies of Panellus stipticus, Psilocybe cubensis, Schizophyllum commune and Stropharia rugosoannulata on oat flakes.

The cultivation and fructification of 15 saprotrophic and wood-rotting fungal strains were tested on three various semi-natural medium. The formation of fruit bodies was observed for Panellus stipticus, Psilocybe cubensis, Schizophyllum commune and Stropharia rugosoannulata in the frame of 1-2 months. Mercury translocation from the substrate to the fruit bodies was then followed in oat flakes medium. Translocation was followed for treatments of 0, 1.25, 2.5, 5, 10 and 20ppm Hg in the substrate. All four fungi formed fruit bodies in almost all replicates. The fruit body yield varied from 0.5 to 15.3g dry weight. The highest bioconcentration factor (BCF) of 2.99 was found for P. cubensis at 1.25ppm Hg. The BCF decreased with increasing Hg concentration in the substrate: 2.49, 0, 2.38, 1.71 and 1.82 for P. stipticus; 3.00, 2.78, 2.48, 1.81 and 2.15 for P. cubensis; 2.47, 1.81, 1.78, 1.07 and 0.96 for S. commune; and 1.96, 1.84, 1.21, 1.71 and 0.96 for S. rugosoannulata. The Hg contents in the fruit bodies reflected the Hg contents in the substrate; the highest contents in the fruit bodies were found in P. cubensis (43.08±7.36ppm Hg) and P. stipticus (36.42±3.39ppm).

[Poisoning with selected mushrooms with neurotropic and hallucinogenic effect]. / Zatrucia wybranymi grzybami o dzialaniu neurotropowym i halucynogennym.

Picking mushrooms, especially in summer and autumn, is still very popular in Poland. Despite raising awareness of poisonous mushrooms in the Polish society, year after year hospitals treat many patients diagnosed with poisoning with the most common toxic species of mushroom found in our country. Furthermore, growing interest in hallucinogenic mushrooms among young people has become a serious medical problem of our time. Websites make it incredibly easy for people to obtain information on the morphology and appearance of mushrooms with psychoactive properties, which leads inexperienced pickers to misidentification, resulting frequently in a fatal outcome. The article explores the subject of poisoning with the most common mushrooms with neurotropic effects, these are: Amanita muscaria, Amanita pantherina, Inocybe rubescens, Clitocybe dealbata, Clitocybe rivulosa and Psilocybe semilanceata. Toxins found in these species show symptoms that affect the central nervous system, parasympathetic system as well as the gastro-intestinal system. The effects of poisoning in the mushroom species mentioned above are mild in general, liver and kidney damage occur rarely, but the symptoms depend on both the dosage of the consumed toxins and individual susceptibility. In most cases the treatment is of symptomatic nature. There is no specific treatment. Medical procedures mainly involve induced gastrolavage--stomach pumping (providing that the patient is conscious), prescription of active carbon as well as replacement of lost body fluids and electrolytes. If the muscarinic symptoms prevail it is generally advised to dose atropine. Patients showing the signs of hyperactivity receive tranquilizers or narcoleptics to eliminate psychotic symptoms.

Primer registro de Psilocybe cubensis en un ambiente natural de Chile / First record of Psilocybe cubensis from a natural habitat in Chile

Psilocybe cubensiso también llamado hongo San Isidro, es un basidiomicete de distribución amplia que se encuentra por lo general en zonas de clima tropical y subtropical. Aquí se describe el primer registro de esta especie psicotrópica en condiciones naturales para Chile, desde una zona rural de clima de transición entre mediterráneo y templado. Se discuten los posibles causantes de esta extensión geográfica de la especie.(AU)

Psilocybe cubensis, also known as San Isidro, is a widely distributed basidiomycete, generally found in tropical and subtropical climate zones. Here, we describe the first record of this psychotropic speciesin natural conditions for Chile, from a rural environment in the transition zone between mediterranean and temperate climate. Possible causes for thisgeographic expansion of the species arediscussed.(AU)

The Japanese hallucinogenic mushrooms Psilocybe and a new synonym of P. subcaerulipes with three asiatic species belong to section Zapotecorum (Higher Basidiomycetes).

The subtropical Japanese bluing mushroom Psilocybe subcaerulipes, described by Hongo, has several synonyms: P. argentipes by Yokoyama (also from Japan), P. taiwanensis by Guzman and Yang (from Taiwan), and P. thaizapoteca by Guzman, Ramirez-Guillen, and Karunaratna (from Thailand). The study of the holotypes and others specimens of these mushrooms shows that they have basidiospores, pleurocystidia, cheilocystidia, and several other important taxonomic features in common, as well as habitat. Recent discussions of all Japanese hallucinogenic species of Psilocybe and their neurotropic effects are also considered.