Publications
2026
Noordeloos, M. E.; Reschke, K.; Morozova, O.; Jordal, J. B.; Jansen, G. M.; Brandrud, T. E.; Bendiksen, E.; Larsson, E.; Karich, A.; Krisai-Greilhuber, I.; Ainsworth, A. M.; Nuytinck, J.; Borovička, J.; van der Vegte, M. J. C.; Frøslev, T. G.; Dima, B.
In: Persoonia, vol. 56, pp. 200–307, 2026, ISSN: 0031-5850.
@article{Noordeloos2026,
title = {The genus Entoloma (Basidiomycota, Agaricales) in Europe: new taxa and amended species concepts in a phylogenetic context; neo-, lecto- and epitypifications of classical names},
author = {M.E. Noordeloos and K. Reschke and O. Morozova and J.B. Jordal and G.M. Jansen and T.E. Brandrud and E. Bendiksen and E. Larsson and A. Karich and I. Krisai-Greilhuber and A.M. Ainsworth and J. Nuytinck and J. Borovička and M.J.C. van der Vegte and T.G. Frøslev and B. Dima},
doi = {10.3114/persoonia.2026.56.03},
issn = {0031-5850},
year = {2026},
date = {2026-02-13},
urldate = {2026-02-13},
journal = {Persoonia},
volume = {56},
pages = { 200–307},
publisher = {Westerdijk Fungal Biodiversity Institute},
abstract = {<jats:p>
The taxonomy and phylogeny of several clades of the genus
<jats:italic>Entoloma</jats:italic>
were revised using morphological and molecular genetic methods. Phylogenetic relationships among European species of the clades /Alboleptonia, /Caeruleopolitum, /Claudopus, /Griseorubidum, /Leptonia, /Olivaceotinctum, /Omphaliopsis, /Pouzarella, /Prunuloides, /Sphagneti, /Turfosa, /Undulatosporum, /Velenovskyi, and /Vinaceum were inferred using 694 newly generated sequences derived from the nrDNA ITS region including 80 sequences from type specimens. Anticipating the second volume of a completely revised monograph of the genus
<jats:italic>Entoloma</jats:italic>
in Europe, the following names are neotypified or epitypes are designated where, in case holotypes or lectotypes appeared unsuitable for molecular studies, viz.
<jats:italic>E. araneosum</jats:italic>
,
<jats:italic>E. byssisedum</jats:italic>
,
<jats:italic>E. griseorubidum</jats:italic>
,
<jats:italic>E. hirtum</jats:italic>
,
<jats:italic>E. lanicum</jats:italic>
,
<jats:italic>E. neglectum</jats:italic>
,
<jats:italic>E. ollare</jats:italic>
,
<jats:italic>E. opacum</jats:italic>
,
<jats:italic>E. plebejum</jats:italic>
,
<jats:italic>E. resutum</jats:italic>
,
<jats:italic>E. rusticoides</jats:italic>
,
<jats:italic>E. sericellum</jats:italic>
,
<jats:italic>E. triste</jats:italic>
,
<jats:italic>E. undatum</jats:italic>
,
<jats:italic>E. velenovskyi</jats:italic>
, and
<jats:italic>E. versatile</jats:italic>
. New type sequences for
<jats:italic>E. alliodorum</jats:italic>
,
<jats:italic>E. asperum</jats:italic>
,
<jats:italic>E. brunneoflocculosum</jats:italic>
,
<jats:italic>E. caeruleopolitum</jats:italic>
,
<jats:italic>E. calaminare</jats:italic>
,
<jats:italic>E. canosericeum</jats:italic>
,
<jats:italic>E. cettoi</jats:italic>
,
<jats:italic>E. cuboidoalbum</jats:italic>
,
<jats:italic>E. indutoides</jats:italic>
,
<jats:italic>E. iodiolens</jats:italic>
,
<jats:italic>E. jahnii</jats:italic>
,
<jats:italic>E. milleri</jats:italic>
,
<jats:italic>E. moguntinum</jats:italic>
,
<jats:italic>E. olivaceotinctum</jats:italic>
,
<jats:italic>E. ostreatum</jats:italic>
,
<jats:italic>E. politoflavipes</jats:italic>
,
<jats:italic>E. polyangulatum</jats:italic>
,
<jats:italic>E. pseudoconferendum</jats:italic>
,
<jats:italic>E. pseudonigellum</jats:italic>
,
<jats:italic>E. pseudosericeoides</jats:italic>
,
<jats:italic>E. ritae</jats:italic>
,
<jats:italic>E. sericeoides</jats:italic>
,
<jats:italic>E. sordidolamellatum</jats:italic>
, and
<jats:italic>E. undulatosporum</jats:italic>
have been generated and deposited in GenBank. Twenty-nine species new to science are described and illustrated, viz.
<jats:italic>E. albostriatum</jats:italic>
,
<jats:italic>E. amabile</jats:italic>
,
<jats:italic>E. assimile</jats:italic>
,
<jats:italic>E. bresadolae</jats:italic>
,
<jats:italic>E. brunneostrigosum</jats:italic>
,
<jats:italic>E. chloridicolor</jats:italic>
,
<jats:italic>E. cassiopeia</jats:italic>
,
<jats:italic>E. chioneum</jats:italic>
,
<jats:italic>E. cognatum</jats:italic>
,
<jats:italic>E. cornatum</jats:italic>
,
<jats:italic>E. eborinum</jats:italic>
,
<jats:italic>E. ermineum</jats:italic>
,
<jats:italic>E. fraudans</jats:italic>
,
<jats:italic>E. fusconigrum</jats:italic>
,
<jats:italic>E. griseopulchrum</jats:italic>
,
<jats:italic>E. hirsutum</jats:italic>
,
<jats:italic>E. ludwigii</jats:italic>
,
<jats:italic>E. nanoalbum</jats:italic>
,
<jats:italic>E. nix</jats:italic>
,
<jats:italic>E. olivaceovirens</jats:italic>
,
<jats:italic>E. ostreatum</jats:italic>
,
<jats:italic>E. paraindutoides</jats:italic>
,
<jats:italic>E. peraraneosum</jats:italic>
,
<jats:italic>E. pilosum</jats:italic>
,
<jats:italic>E. pumilionis</jats:italic>
,
<jats:italic>E. skadiae</jats:italic>
,
<jats:italic>E. umbrinotinctum</jats:italic>
,
<jats:italic>E. vilae</jats:italic>
, and
<jats:italic>E. weiriorum</jats:italic>
, and
<jats:italic>Entoloma</jats:italic>
sect.
<jats:italic>Atricoloria</jats:italic>
is described as new to science. The name
<jats:italic>E. myochroum</jats:italic>
is validated and the replacement name
<jats:italic>E. cobaltichlorum</jats:italic>
is proposed. Morphological and molecular studies made it necessary to provide new, amended descriptions for
<jats:italic>E. alliodorum</jats:italic>
,
<jats:italic>E. anthracinum</jats:italic>
,
<jats:italic>E. araneosum</jats:italic>
,
<jats:italic>E. brunneoflocculosum</jats:italic>
,
<jats:italic>E. byssisedum</jats:italic>
,
<jats:italic>E. calaminare</jats:italic>
,
<jats:italic>E. canosericeum</jats:italic>
,
<jats:italic>E. dysthaloides</jats:italic>
,
<jats:italic>E. griseorubidum</jats:italic>
,
<jats:italic>E. flocculosum</jats:italic>
,
<jats:italic>E. indutoides</jats:italic>
,
<jats:italic>E. inopiliforme</jats:italic>
,
<jats:italic>E. hirtum</jats:italic>
,
<jats:italic>E. lanicum</jats:italic>
,
<jats:italic>E. lidbergii</jats:italic>
,
<jats:italic>E. milleri</jats:italic>
,
<jats:italic>E. myochroum</jats:italic>
,
<jats:italic>E. neglectum</jats:italic>
,
<jats:italic>E. olivaceotinctum</jats:italic>
,
<jats:italic>E. ollare</jats:italic>
,
<jats:italic>E. opacum</jats:italic>
,
<jats:italic>E. plebejum</jats:italic>
,
<jats:italic>E. polyangulatum</jats:italic>
,
<jats:italic>E. pseudonigellum</jats:italic>
,
<jats:italic>E. pseudoparasiticum</jats:italic>
,
<jats:italic>E. pseudosericeoides</jats:italic>
,
<jats:italic>E. pseudoturbidum</jats:italic>
,
<jats:italic>E. resutum</jats:italic>
,
<jats:italic>E. rusticoides</jats:italic>
,
<jats:italic>E. sericellum</jats:italic>
,
<jats:italic>E. sericeoides</jats:italic>
,
<jats:italic>E. sordidolamellatum</jats:italic>
,
<jats:italic>E. triste</jats:italic>
,
<jats:italic>E. undatum</jats:italic>
,
<jats:italic>E. undulatosporum</jats:italic>
,
<jats:italic>E. velenovskyi</jats:italic>
, and
<jats:italic>E. versatile</jats:italic>
.
</jats:p>},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
<jats:p>
The taxonomy and phylogeny of several clades of the genus
<jats:italic>Entoloma</jats:italic>
were revised using morphological and molecular genetic methods. Phylogenetic relationships among European species of the clades /Alboleptonia, /Caeruleopolitum, /Claudopus, /Griseorubidum, /Leptonia, /Olivaceotinctum, /Omphaliopsis, /Pouzarella, /Prunuloides, /Sphagneti, /Turfosa, /Undulatosporum, /Velenovskyi, and /Vinaceum were inferred using 694 newly generated sequences derived from the nrDNA ITS region including 80 sequences from type specimens. Anticipating the second volume of a completely revised monograph of the genus
<jats:italic>Entoloma</jats:italic>
in Europe, the following names are neotypified or epitypes are designated where, in case holotypes or lectotypes appeared unsuitable for molecular studies, viz.
<jats:italic>E. araneosum</jats:italic>
,
<jats:italic>E. byssisedum</jats:italic>
,
<jats:italic>E. griseorubidum</jats:italic>
,
<jats:italic>E. hirtum</jats:italic>
,
<jats:italic>E. lanicum</jats:italic>
,
<jats:italic>E. neglectum</jats:italic>
,
<jats:italic>E. ollare</jats:italic>
,
<jats:italic>E. opacum</jats:italic>
,
<jats:italic>E. plebejum</jats:italic>
,
<jats:italic>E. resutum</jats:italic>
,
<jats:italic>E. rusticoides</jats:italic>
,
<jats:italic>E. sericellum</jats:italic>
,
<jats:italic>E. triste</jats:italic>
,
<jats:italic>E. undatum</jats:italic>
,
<jats:italic>E. velenovskyi</jats:italic>
, and
<jats:italic>E. versatile</jats:italic>
. New type sequences for
<jats:italic>E. alliodorum</jats:italic>
,
<jats:italic>E. asperum</jats:italic>
,
<jats:italic>E. brunneoflocculosum</jats:italic>
,
<jats:italic>E. caeruleopolitum</jats:italic>
,
<jats:italic>E. calaminare</jats:italic>
,
<jats:italic>E. canosericeum</jats:italic>
,
<jats:italic>E. cettoi</jats:italic>
,
<jats:italic>E. cuboidoalbum</jats:italic>
,
<jats:italic>E. indutoides</jats:italic>
,
<jats:italic>E. iodiolens</jats:italic>
,
<jats:italic>E. jahnii</jats:italic>
,
<jats:italic>E. milleri</jats:italic>
,
<jats:italic>E. moguntinum</jats:italic>
,
<jats:italic>E. olivaceotinctum</jats:italic>
,
<jats:italic>E. ostreatum</jats:italic>
,
<jats:italic>E. politoflavipes</jats:italic>
,
<jats:italic>E. polyangulatum</jats:italic>
,
<jats:italic>E. pseudoconferendum</jats:italic>
,
<jats:italic>E. pseudonigellum</jats:italic>
,
<jats:italic>E. pseudosericeoides</jats:italic>
,
<jats:italic>E. ritae</jats:italic>
,
<jats:italic>E. sericeoides</jats:italic>
,
<jats:italic>E. sordidolamellatum</jats:italic>
, and
<jats:italic>E. undulatosporum</jats:italic>
have been generated and deposited in GenBank. Twenty-nine species new to science are described and illustrated, viz.
<jats:italic>E. albostriatum</jats:italic>
,
<jats:italic>E. amabile</jats:italic>
,
<jats:italic>E. assimile</jats:italic>
,
<jats:italic>E. bresadolae</jats:italic>
,
<jats:italic>E. brunneostrigosum</jats:italic>
,
<jats:italic>E. chloridicolor</jats:italic>
,
<jats:italic>E. cassiopeia</jats:italic>
,
<jats:italic>E. chioneum</jats:italic>
,
<jats:italic>E. cognatum</jats:italic>
,
<jats:italic>E. cornatum</jats:italic>
,
<jats:italic>E. eborinum</jats:italic>
,
<jats:italic>E. ermineum</jats:italic>
,
<jats:italic>E. fraudans</jats:italic>
,
<jats:italic>E. fusconigrum</jats:italic>
,
<jats:italic>E. griseopulchrum</jats:italic>
,
<jats:italic>E. hirsutum</jats:italic>
,
<jats:italic>E. ludwigii</jats:italic>
,
<jats:italic>E. nanoalbum</jats:italic>
,
<jats:italic>E. nix</jats:italic>
,
<jats:italic>E. olivaceovirens</jats:italic>
,
<jats:italic>E. ostreatum</jats:italic>
,
<jats:italic>E. paraindutoides</jats:italic>
,
<jats:italic>E. peraraneosum</jats:italic>
,
<jats:italic>E. pilosum</jats:italic>
,
<jats:italic>E. pumilionis</jats:italic>
,
<jats:italic>E. skadiae</jats:italic>
,
<jats:italic>E. umbrinotinctum</jats:italic>
,
<jats:italic>E. vilae</jats:italic>
, and
<jats:italic>E. weiriorum</jats:italic>
, and
<jats:italic>Entoloma</jats:italic>
sect.
<jats:italic>Atricoloria</jats:italic>
is described as new to science. The name
<jats:italic>E. myochroum</jats:italic>
is validated and the replacement name
<jats:italic>E. cobaltichlorum</jats:italic>
is proposed. Morphological and molecular studies made it necessary to provide new, amended descriptions for
<jats:italic>E. alliodorum</jats:italic>
,
<jats:italic>E. anthracinum</jats:italic>
,
<jats:italic>E. araneosum</jats:italic>
,
<jats:italic>E. brunneoflocculosum</jats:italic>
,
<jats:italic>E. byssisedum</jats:italic>
,
<jats:italic>E. calaminare</jats:italic>
,
<jats:italic>E. canosericeum</jats:italic>
,
<jats:italic>E. dysthaloides</jats:italic>
,
<jats:italic>E. griseorubidum</jats:italic>
,
<jats:italic>E. flocculosum</jats:italic>
,
<jats:italic>E. indutoides</jats:italic>
,
<jats:italic>E. inopiliforme</jats:italic>
,
<jats:italic>E. hirtum</jats:italic>
,
<jats:italic>E. lanicum</jats:italic>
,
<jats:italic>E. lidbergii</jats:italic>
,
<jats:italic>E. milleri</jats:italic>
,
<jats:italic>E. myochroum</jats:italic>
,
<jats:italic>E. neglectum</jats:italic>
,
<jats:italic>E. olivaceotinctum</jats:italic>
,
<jats:italic>E. ollare</jats:italic>
,
<jats:italic>E. opacum</jats:italic>
,
<jats:italic>E. plebejum</jats:italic>
,
<jats:italic>E. polyangulatum</jats:italic>
,
<jats:italic>E. pseudonigellum</jats:italic>
,
<jats:italic>E. pseudoparasiticum</jats:italic>
,
<jats:italic>E. pseudosericeoides</jats:italic>
,
<jats:italic>E. pseudoturbidum</jats:italic>
,
<jats:italic>E. resutum</jats:italic>
,
<jats:italic>E. rusticoides</jats:italic>
,
<jats:italic>E. sericellum</jats:italic>
,
<jats:italic>E. sericeoides</jats:italic>
,
<jats:italic>E. sordidolamellatum</jats:italic>
,
<jats:italic>E. triste</jats:italic>
,
<jats:italic>E. undatum</jats:italic>
,
<jats:italic>E. undulatosporum</jats:italic>
,
<jats:italic>E. velenovskyi</jats:italic>
, and
<jats:italic>E. versatile</jats:italic>
.
</jats:p>
The taxonomy and phylogeny of several clades of the genus
<jats:italic>Entoloma</jats:italic>
were revised using morphological and molecular genetic methods. Phylogenetic relationships among European species of the clades /Alboleptonia, /Caeruleopolitum, /Claudopus, /Griseorubidum, /Leptonia, /Olivaceotinctum, /Omphaliopsis, /Pouzarella, /Prunuloides, /Sphagneti, /Turfosa, /Undulatosporum, /Velenovskyi, and /Vinaceum were inferred using 694 newly generated sequences derived from the nrDNA ITS region including 80 sequences from type specimens. Anticipating the second volume of a completely revised monograph of the genus
<jats:italic>Entoloma</jats:italic>
in Europe, the following names are neotypified or epitypes are designated where, in case holotypes or lectotypes appeared unsuitable for molecular studies, viz.
<jats:italic>E. araneosum</jats:italic>
,
<jats:italic>E. byssisedum</jats:italic>
,
<jats:italic>E. griseorubidum</jats:italic>
,
<jats:italic>E. hirtum</jats:italic>
,
<jats:italic>E. lanicum</jats:italic>
,
<jats:italic>E. neglectum</jats:italic>
,
<jats:italic>E. ollare</jats:italic>
,
<jats:italic>E. opacum</jats:italic>
,
<jats:italic>E. plebejum</jats:italic>
,
<jats:italic>E. resutum</jats:italic>
,
<jats:italic>E. rusticoides</jats:italic>
,
<jats:italic>E. sericellum</jats:italic>
,
<jats:italic>E. triste</jats:italic>
,
<jats:italic>E. undatum</jats:italic>
,
<jats:italic>E. velenovskyi</jats:italic>
, and
<jats:italic>E. versatile</jats:italic>
. New type sequences for
<jats:italic>E. alliodorum</jats:italic>
,
<jats:italic>E. asperum</jats:italic>
,
<jats:italic>E. brunneoflocculosum</jats:italic>
,
<jats:italic>E. caeruleopolitum</jats:italic>
,
<jats:italic>E. calaminare</jats:italic>
,
<jats:italic>E. canosericeum</jats:italic>
,
<jats:italic>E. cettoi</jats:italic>
,
<jats:italic>E. cuboidoalbum</jats:italic>
,
<jats:italic>E. indutoides</jats:italic>
,
<jats:italic>E. iodiolens</jats:italic>
,
<jats:italic>E. jahnii</jats:italic>
,
<jats:italic>E. milleri</jats:italic>
,
<jats:italic>E. moguntinum</jats:italic>
,
<jats:italic>E. olivaceotinctum</jats:italic>
,
<jats:italic>E. ostreatum</jats:italic>
,
<jats:italic>E. politoflavipes</jats:italic>
,
<jats:italic>E. polyangulatum</jats:italic>
,
<jats:italic>E. pseudoconferendum</jats:italic>
,
<jats:italic>E. pseudonigellum</jats:italic>
,
<jats:italic>E. pseudosericeoides</jats:italic>
,
<jats:italic>E. ritae</jats:italic>
,
<jats:italic>E. sericeoides</jats:italic>
,
<jats:italic>E. sordidolamellatum</jats:italic>
, and
<jats:italic>E. undulatosporum</jats:italic>
have been generated and deposited in GenBank. Twenty-nine species new to science are described and illustrated, viz.
<jats:italic>E. albostriatum</jats:italic>
,
<jats:italic>E. amabile</jats:italic>
,
<jats:italic>E. assimile</jats:italic>
,
<jats:italic>E. bresadolae</jats:italic>
,
<jats:italic>E. brunneostrigosum</jats:italic>
,
<jats:italic>E. chloridicolor</jats:italic>
,
<jats:italic>E. cassiopeia</jats:italic>
,
<jats:italic>E. chioneum</jats:italic>
,
<jats:italic>E. cognatum</jats:italic>
,
<jats:italic>E. cornatum</jats:italic>
,
<jats:italic>E. eborinum</jats:italic>
,
<jats:italic>E. ermineum</jats:italic>
,
<jats:italic>E. fraudans</jats:italic>
,
<jats:italic>E. fusconigrum</jats:italic>
,
<jats:italic>E. griseopulchrum</jats:italic>
,
<jats:italic>E. hirsutum</jats:italic>
,
<jats:italic>E. ludwigii</jats:italic>
,
<jats:italic>E. nanoalbum</jats:italic>
,
<jats:italic>E. nix</jats:italic>
,
<jats:italic>E. olivaceovirens</jats:italic>
,
<jats:italic>E. ostreatum</jats:italic>
,
<jats:italic>E. paraindutoides</jats:italic>
,
<jats:italic>E. peraraneosum</jats:italic>
,
<jats:italic>E. pilosum</jats:italic>
,
<jats:italic>E. pumilionis</jats:italic>
,
<jats:italic>E. skadiae</jats:italic>
,
<jats:italic>E. umbrinotinctum</jats:italic>
,
<jats:italic>E. vilae</jats:italic>
, and
<jats:italic>E. weiriorum</jats:italic>
, and
<jats:italic>Entoloma</jats:italic>
sect.
<jats:italic>Atricoloria</jats:italic>
is described as new to science. The name
<jats:italic>E. myochroum</jats:italic>
is validated and the replacement name
<jats:italic>E. cobaltichlorum</jats:italic>
is proposed. Morphological and molecular studies made it necessary to provide new, amended descriptions for
<jats:italic>E. alliodorum</jats:italic>
,
<jats:italic>E. anthracinum</jats:italic>
,
<jats:italic>E. araneosum</jats:italic>
,
<jats:italic>E. brunneoflocculosum</jats:italic>
,
<jats:italic>E. byssisedum</jats:italic>
,
<jats:italic>E. calaminare</jats:italic>
,
<jats:italic>E. canosericeum</jats:italic>
,
<jats:italic>E. dysthaloides</jats:italic>
,
<jats:italic>E. griseorubidum</jats:italic>
,
<jats:italic>E. flocculosum</jats:italic>
,
<jats:italic>E. indutoides</jats:italic>
,
<jats:italic>E. inopiliforme</jats:italic>
,
<jats:italic>E. hirtum</jats:italic>
,
<jats:italic>E. lanicum</jats:italic>
,
<jats:italic>E. lidbergii</jats:italic>
,
<jats:italic>E. milleri</jats:italic>
,
<jats:italic>E. myochroum</jats:italic>
,
<jats:italic>E. neglectum</jats:italic>
,
<jats:italic>E. olivaceotinctum</jats:italic>
,
<jats:italic>E. ollare</jats:italic>
,
<jats:italic>E. opacum</jats:italic>
,
<jats:italic>E. plebejum</jats:italic>
,
<jats:italic>E. polyangulatum</jats:italic>
,
<jats:italic>E. pseudonigellum</jats:italic>
,
<jats:italic>E. pseudoparasiticum</jats:italic>
,
<jats:italic>E. pseudosericeoides</jats:italic>
,
<jats:italic>E. pseudoturbidum</jats:italic>
,
<jats:italic>E. resutum</jats:italic>
,
<jats:italic>E. rusticoides</jats:italic>
,
<jats:italic>E. sericellum</jats:italic>
,
<jats:italic>E. sericeoides</jats:italic>
,
<jats:italic>E. sordidolamellatum</jats:italic>
,
<jats:italic>E. triste</jats:italic>
,
<jats:italic>E. undatum</jats:italic>
,
<jats:italic>E. undulatosporum</jats:italic>
,
<jats:italic>E. velenovskyi</jats:italic>
, and
<jats:italic>E. versatile</jats:italic>
.
</jats:p>
Haelewaters, Danny; Aghayeva, Dilzara; de-Miguel, Sergio; Degtjarenko, Polina; Dierickx, Glen; Dima, Bálint; Dyer, Paul S.; Fachada, Vasco; Favero-Longo, Sergio Enrico; Filippova, Nina V.; Ganado, Montserrat; Gonçalves, Susana C.; Heilmann-Clausen, Jacob; Hyland, Edel; Iršėnaitė, Reda; Jorjadze, Angelina; Krisai-Greilhuber, Irmgard; Lazarević, Jelena; Marques, Guilhermina; Meiere, Diāna; Nascimbene, Juri; Niell, Manel; Nuytinck, Jorinde; Ottosson, Elisabet; Papp, Viktor; Pärtel, Kadri; Prylutskyi, Oleh; Ramshaj, Qëndrim; Rinaldi, Andrea; Rusevska, Katerina; Ruszkiewicz-Michalska, Małgorzata; Schneider, Simone; Schoutteten, Nathan; Schwab, Nicolas; Siedlecki, Igor; Simão, Rui Soares; Sparrius, Laurens B.; Thüs, Holger; Vizzini, Alfredo; Westberg, Martin; Zambonelli, Alessandra; Zehnálek, Petr; Zervakis, Georgios I.; Pawłowska, Julia
Mapping the landscape of mycological organizations in europe: where citizen science meets professional mycology Journal Article
In: Biodivers Conserv, vol. 35, no. 1, 2026, ISSN: 1572-9710.
@article{Haelewaters2026,
title = {Mapping the landscape of mycological organizations in europe: where citizen science meets professional mycology},
author = {Danny Haelewaters and Dilzara Aghayeva and Sergio de-Miguel and Polina Degtjarenko and Glen Dierickx and Bálint Dima and Paul S. Dyer and Vasco Fachada and Sergio Enrico Favero-Longo and Nina V. Filippova and Montserrat Ganado and Susana C. Gonçalves and Jacob Heilmann-Clausen and Edel Hyland and Reda Iršėnaitė and Angelina Jorjadze and Irmgard Krisai-Greilhuber and Jelena Lazarević and Guilhermina Marques and Diāna Meiere and Juri Nascimbene and Manel Niell and Jorinde Nuytinck and Elisabet Ottosson and Viktor Papp and Kadri Pärtel and Oleh Prylutskyi and Qëndrim Ramshaj and Andrea Rinaldi and Katerina Rusevska and Małgorzata Ruszkiewicz-Michalska and Simone Schneider and Nathan Schoutteten and Nicolas Schwab and Igor Siedlecki and Rui Soares Simão and Laurens B. Sparrius and Holger Thüs and Alfredo Vizzini and Martin Westberg and Alessandra Zambonelli and Petr Zehnálek and Georgios I. Zervakis and Julia Pawłowska},
doi = {10.1007/s10531-025-03219-2},
issn = {1572-9710},
year = {2026},
date = {2026-01-00},
urldate = {2026-01-00},
journal = {Biodivers Conserv},
volume = {35},
number = {1},
publisher = {Springer Science and Business Media LLC},
abstract = {<jats:title>Abstract</jats:title>
<jats:p>Fungi have been used by humans since prehistoric times. Informal structures or groups for knowledge exchange regarding mushrooms and lichens probably existed for ages. Only recently, mycological activities have been structured in formal organizations. And where until a few centuries ago there were only learned societies and naturalists’ clubs, nowadays also mycological societies and citizen scientists have joined the landscape. However, the history of mycological organizations and activities in Europe is difficult to track. Here, we initiated two surveys to characterize the current landscape of mycological organizations focused on fungal diversity across Europe and to collate citizen science activities mapping fungi. The surveys were shared on social media and sent to mycologists in 49 countries in Europe. Responses of the surveys allowed us to present the history, geographical distribution, and structure of mycological organizations in Europe as well as their types of activities, including the publication of journals and magazines, the organization of meetings and educational initiatives, and citizen science projects. In addition to the surveys, local mycologists presented expert knowledge for a more comprehensive overview. Our data show that the mycological landscape in Europe is diverse and heterogeneous. We discuss ways to overcome economic, cultural, and linguistic barriers towards better integration of mycological communities, activities, and data in Europe. Mycological societies focused on studying fungal diversity can be leveraged towards common goals that include raising public awareness, data integration, uniting academics and non-academics, and developing common standards for research and communication.</jats:p>},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
<jats:title>Abstract</jats:title>
<jats:p>Fungi have been used by humans since prehistoric times. Informal structures or groups for knowledge exchange regarding mushrooms and lichens probably existed for ages. Only recently, mycological activities have been structured in formal organizations. And where until a few centuries ago there were only learned societies and naturalists’ clubs, nowadays also mycological societies and citizen scientists have joined the landscape. However, the history of mycological organizations and activities in Europe is difficult to track. Here, we initiated two surveys to characterize the current landscape of mycological organizations focused on fungal diversity across Europe and to collate citizen science activities mapping fungi. The surveys were shared on social media and sent to mycologists in 49 countries in Europe. Responses of the surveys allowed us to present the history, geographical distribution, and structure of mycological organizations in Europe as well as their types of activities, including the publication of journals and magazines, the organization of meetings and educational initiatives, and citizen science projects. In addition to the surveys, local mycologists presented expert knowledge for a more comprehensive overview. Our data show that the mycological landscape in Europe is diverse and heterogeneous. We discuss ways to overcome economic, cultural, and linguistic barriers towards better integration of mycological communities, activities, and data in Europe. Mycological societies focused on studying fungal diversity can be leveraged towards common goals that include raising public awareness, data integration, uniting academics and non-academics, and developing common standards for research and communication.</jats:p>
<jats:p>Fungi have been used by humans since prehistoric times. Informal structures or groups for knowledge exchange regarding mushrooms and lichens probably existed for ages. Only recently, mycological activities have been structured in formal organizations. And where until a few centuries ago there were only learned societies and naturalists’ clubs, nowadays also mycological societies and citizen scientists have joined the landscape. However, the history of mycological organizations and activities in Europe is difficult to track. Here, we initiated two surveys to characterize the current landscape of mycological organizations focused on fungal diversity across Europe and to collate citizen science activities mapping fungi. The surveys were shared on social media and sent to mycologists in 49 countries in Europe. Responses of the surveys allowed us to present the history, geographical distribution, and structure of mycological organizations in Europe as well as their types of activities, including the publication of journals and magazines, the organization of meetings and educational initiatives, and citizen science projects. In addition to the surveys, local mycologists presented expert knowledge for a more comprehensive overview. Our data show that the mycological landscape in Europe is diverse and heterogeneous. We discuss ways to overcome economic, cultural, and linguistic barriers towards better integration of mycological communities, activities, and data in Europe. Mycological societies focused on studying fungal diversity can be leveraged towards common goals that include raising public awareness, data integration, uniting academics and non-academics, and developing common standards for research and communication.</jats:p>
2025
Kudławiec, Barbara; Domian, Grażyna; Gorczak, Michał; Kujawa, Anna; Lożek, Marcin; Naser, Grażyna; Nowak, Maksymilian Emil; Pawłowska, Julia; Piskorski, Sebastian; Stasińska, Małgorzata; Tischer, Marta; Urbaniak, Monika; Wrzosek, Marta
Mycological records by Fungal Diversity and Conservation Section of the Polish Mycological Society. Part 6 Journal Article
In: Przegląd Przyrodniczy, vol. XXXVI, iss. 4, pp. 3-65, 2025.
@article{nokey,
title = {Mycological records by Fungal Diversity and Conservation Section of the Polish Mycological Society. Part 6},
author = {Barbara Kudławiec and Grażyna Domian and Michał Gorczak and Anna Kujawa and Marcin Lożek and Grażyna Naser and Maksymilian Emil Nowak and Julia Pawłowska and Sebastian Piskorski and Małgorzata Stasińska and Marta Tischer and Monika Urbaniak and Marta Wrzosek },
url = {https://fun-dive.eu/wp-content/uploads/2026/03/2025_Kudlawiec-et-al_Obserwacje-mykologiczne-cz.-6.pdf},
year = {2025},
date = {2025-12-31},
urldate = {2025-12-31},
journal = {Przegląd Przyrodniczy},
volume = {XXXVI},
issue = {4},
pages = {3-65},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Mielke, Louis; Haelewaters, Danny; De-Miguel, Sergio; Fachada, Vasco; Gross, Andrin; Kauserud, Håvard; Krah, Franz-Sebastian; Niskanen, Tuula; Nuytinck, Jorinde; Picek, Lukáš; Põldmaa, Kadri; Richard, Franck; Richter, Franziska; Rinaldi, Andrea C.; Tischer, Marta; Vizzini, Alfredo; Pawłowska, Julia; Heilmann-Clausen, Jacob
Join FunDive and help mycologists gain a deeper understanding of fungal diversity in Europe! Journal Article
In: Field Mycol., vol. 26, no. 3, pp. 78–86, 2025, ISSN: 2213-6843.
@article{Mielke2025,
title = {Join FunDive and help mycologists gain a deeper understanding of fungal diversity in Europe!},
author = {Louis Mielke and Danny Haelewaters and Sergio De-Miguel and Vasco Fachada and Andrin Gross and Håvard Kauserud and Franz-Sebastian Krah and Tuula Niskanen and Jorinde Nuytinck and Lukáš Picek and Kadri Põldmaa and Franck Richard and Franziska Richter and Andrea C. Rinaldi and Marta Tischer and Alfredo Vizzini and Julia Pawłowska and Jacob Heilmann-Clausen},
doi = {10.63482/php2v621},
issn = {2213-6843},
year = {2025},
date = {2025-10-27},
urldate = {2025-10-27},
journal = {Field Mycol.},
volume = {26},
number = {3},
pages = {78--86},
publisher = {British Mycological Society},
abstract = {<jats:p/>},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
<jats:p/>
Marxmüller, Helga; Hampe, Felix; Temmerman, Ines; De Lange, Ruben; Verbeken, Annemieke; Kleine, Jesko
Russula subpallidospora sp. nov. – ein seltener cremesporiger Weißtäubling Journal Article
In: Zeitschrift für Mykologie, vol. 91, iss. 2, pp. 295-319, 2025.
@article{nokey,
title = {Russula subpallidospora sp. nov. – ein seltener cremesporiger Weißtäubling},
author = {Marxmüller, Helga and Hampe, Felix and Temmerman, Ines and De Lange, Ruben and Verbeken, Annemieke and Kleine, Jesko},
url = {http://hdl.handle.net/1854/LU-01K47N1FWC96PZWS42MWVKVWXJ},
year = {2025},
date = {2025-07-24},
urldate = {2025-07-24},
journal = {Zeitschrift für Mykologie},
volume = {91},
issue = {2},
pages = {295-319},
keywords = {},
pubstate = {published},
tppubtype = {article}
}