Mycobiota of Dead Ulmus glabra Wood as Breeding Material for the Endangered Rosalia alpina (Coleoptera : Cerambycidae)

Bartnik, Czesław; Michalcewicz, Jakub; Ledwich, Dominika; Ciach, Michał

doi:10.3161/15052249PJE2020.68.1.002

Artykuł - szczegóły

Tytuł artykułu

Mycobiota of Dead Ulmus glabra Wood as Breeding Material for the Endangered Rosalia alpina (Coleoptera : Cerambycidae)

Autorzy

Bartnik Czesław , Michalcewicz Jakub , Ledwich Dominika , Ciach Michał

Wybrane pełne teksty z tego czasopisma

http://www.miiz.waw.pl/index.php/pl/wydawnictwa/polish-journal-of-ecology

Identyfikatory

DOI

10.3161/15052249PJE2020.68.1.002

Warianty tytułu

Języki publikacji

Abstrakty

The presence in wood of saprotrophic fungi is crucial for xylophagous insects, as they modify its chemical composition, moisture content and structure, and thus govern the survival and growth rate of larvae. Little is known about the mycobiota colonising the breeding material of saproxylic species. This paper focuses on the mycobiota of dead wych elms Ulmus glabra as breeding material for the endangered Rosalia alpina. Fungal isolates from wood fragments of the breeding material were identified using molecular techniques. A total of 24 taxa of wood-decay fungi were found (16 Ascomycota, 6 Basidiomycota, 1 Zygomycota, 1 unidentified) – saprotrophs and facultative parasites, saprotrophic fungi, fungal parasites and tree parasites. Six taxa were isolated from both the surface and deeper layers of the wood, and also from the wood dust and frass left in R. alpina foraging sites: Cladosporium cladosporioides, Cladosporium sp., Hypoxylon macrocarpum, Phaeoacremonium fraxinopennsylvanicum, Sistotrema brinkmannii and Stereum hirsutum. These fungi may be crucial in enabling R. alpina to colonise dead or dying trees and affect its larval development. Ph. fraxinopennsylvanicum, H. macrocarpum and Daldinia childiae are reported for the first time from Poland.

Słowa kluczowe

Carpathian Mts saprotrophic fungus trophic relations wood decomposition xylophagous insect

Karpaty grzyb saprotroficzny relacje troficzne rozkład drewna owad ksylofagousowy

Wydawca

Museum and Institute of Zoology, Polish Academy of Sciences

Czasopismo

Polish Journal of Ecology

Rocznik

2020

Tom

Vol. 68, nr 1

Strony

13--22

Opis fizyczny

Bibliogr. 46 poz., tab.

Twórcy

autor

Bartnik Czesław

Department of Forest Ecosystem Protection, Faculty of Forestry, University of Agriculture in Kraków, al. 29 Listopada 46, 31-425 Kraków, Poland

autor

Michalcewicz Jakub

Department of Forest Ecosystem Protection, Faculty of Forestry, University of Agriculture in Kraków, al. 29 Listopada 46, 31-425 Kraków, Poland

autor

Ledwich Dominika

Department of Forest Ecosystem Protection, Faculty of Forestry, University of Agriculture in Kraków, al. 29 Listopada 46, 31-425 Kraków, Poland

autor

Ciach Michał

michal.ciach@urk.edu.pl

Department of Forest Biodiversity, Faculty of Forestry, University of Agriculture in Kraków, al. 29 Listopada 46, 31-425 Kraków, Poland

Bibliografia

1. Bartnik C., Michalcewicz J., Ciach M. 2015 – Dutch elm disease and the habitat of endangered Rosalia longicorn Rosalia alpina (L.): a conservation paradox? – Pol. J. Ecol. 63: 440-447.
2. Bartnik C., Michalcewicz J., Kubiński R. 2016 – Rosalia longicorn Rosalia alpina (Linnaeus, 1758) (Coleoptera: Cerambycidae) as a host of the entomopathogenic fungus Cordyceps bassiana Li, Li, Huang & Fan, 2001 (Ascomycota: Hypocreales) – Pol. J. Entomol. 85: 261-267.
3. Becker G. 1966 – Über Beziehungen zwischen Tieren und Mikroorganismen im Holz – Material und Organismen, Berlin, 1: 481-496.
4. Bense U. 1995 – Longhorn beetles. Illustrated Key to the Cerambycidae and Vesperidae of Europe – Margraf Verlag, Weikersheim, 512 pp.
5. Binner V., Bussler H. 2006 – Erfassung und Bewertung von Alpenbock-Vorkommen – Naturschutz und Landschaftsplanung, 38: 378-382.
6. Birkemoe T., Jacobsen R. M., Sverdrup-Thygeson A., Biedermann P. H. W. 2018 – Insect-fungus interactions in dead wood systems (In: Saproxylic insects, Ed: M. Ulyshen) – Zool. Monogr. 1, Springer, Cham, pp. 377-427.
7. Boddy L. 2001 – Fungal community ecology and wood decomposition processes in angiosperms: from standing tree to complete decay of coarse woody debris – Ecol. Bull. 49: 43-56.
8. Burakowski B., Mroczkowski M., Stefańska J. 1990 – [Beetles – Coleoptera. Cerambycidae and Bruchidae. Catalogue of Polish Fauna XXIII, 15] – PWN, Warszawa (in Polish).
9. Castro-Gil A., Murguía-Fernández L. M. de., Molino-Olmedo F. 2017 – First record of Rosalia alpina (Linnaeus 1758) (Coleoptera, Cerambycidae) in Prunus avium (L.) (Rosaceae) – Graellsia, 73 (2): e061. https://doi.org/10.3989/graellsia.2017.v73.182.
10. Chen Y., Forschler B. T. 2016 – Elemental concentrations in the frass of saproxylic insects suggest a role in micronutrient cycling – Ecosphere, 7 (3): e01300. https://doi.org/10.1002/ecs2.1300.
11. Ciach M., Michalcewicz J., Fluda M. 2007 – The first report on development of Rosalia alpina (Linnaeus, 1758) (Coleoptera: Cerambycidae) in wood of Ulmus L. in Poland – Pol. J. Entomol. 76: 101-105.
12. Dominik J., Starzyk J. R. 2004 – [Wood Damaging Insects] – PWRiL, Warszawa, 584 pp. (in Polish).
13. Eckelt A., Müller J., Bense U., Brustel H., Bußler H. et al. 2018 – “Primeval forest relict beetles” of Central Europe: a set of 168 umbrella species for the protection of primeval forest remnants – J. Insect Conserv. 22: 15-28.
14. Filipiak M. 2018 – Nutrient dynamics in decomposing dead wood in the context of wood eater requirements: The ecological stoichiometry of saproxylophagous insects (In: Saproxylic insects, Ed: M. Ulyshen) – Zool. Monogr. 1, Springer, Cham, pp. 429-469.
15. Filipiak M., Sobczyk Ł., Weiner J. 2016 – Fungal transformation of tree stumps into a suitable resource for xylophagous beetles via changes in elemental ratios – Insects, 7: 13. https://doi.org/10.3390/insects7020013.
16. Filipiak M., Weiner J. 2014 – How to make a beetle out of wood: Multi-elemental stoichiometry of wood decay, xylophagy and fungivory – PLoS ONE, 9 (12): e115104. https://doi.org/10.1371/journal.pone.0115104.
17. Filipiak M., Weiner J. 2017 – Nutritional dynamics during the development of xylophagous beetles related to changes in the stoichiometry of 11 elements – Physiol. Entomol. 42: 73-84.
18. Floren A., Krüger D., Müller T., Dittrich M., Rudloff R., Hoppe B., Linsenmair K. E. 2015 – Diversity and interactions of wood-inhabiting fungi and beetles after deadwood enrichment – PLoS ONE, 10: e0143566. https://doi.org/10.1371/journal.pone.0143566.
19. Głowaciński Z., Nowacki J. (ed.). 2004 – [Polish red data book of animals, invertebrates] – Instytut Ochrony Przyrody PAN, Kraków, Akademia Rolnicza im. A. Cieszkowskiego, Poznań (in Polish).
20. Groenewald M., Kang J.-C., Crous P. W., Gams W. 2001 – ITS and β-tubulin phylogeny of Phaeoacremonium and Phaeomoniella species – Mycol. Res. 105: 651-657.
21. Gutowski J. M. 2004 – [ Rosalia alpina (Linnaeus, 1758), Rosalia longicorn] (In: [Animal Species (except for birds). Guides for protection of habitats and species of Natura 2000 – a methodological textbook. vol. 6], Eds: P. Adamski, R. Bartel, A. Bereszyński, A. Kepel, Z. Witkowski) – Ministerstwo Środowiska, Warszawa, pp. 130-134 (in Polish).
22. Gutowski J. M. 2006 – [Saproxylic beetles] – Kosmos, 55: 53-73 (in Polish).
23. Hausner G., Eyjólfsdóttir G. G., Reid J., Klassen G. R. 1992 – Two additional species of the genus Togninia – Can. J. Bot. 70: 724-734.
24. IUCN (International Union for Conservation of Nature). 2018 – The IUCN Red List of Threatened Species – Version 2018-1. <http://www.iucnredlist.org>. Downloaded on 13 January 2019.
25. Jankowiak R. 2004 – [Interactions among cambiophagoues insects, fungi, and plant] – Kosmos, 53: 39-50 (in Polish).
26. Johannesson H., Laessøe T., Stenlid J. 2000 – Molecular and morphological investigation of the genus Daldinia in Northern Europe – Mycol. Res. 104: 275-280.
27. Ju Y. M., Rogers J. D., San Martin F. 1997 – A revision of the genus Daldinia – Mycotaxon, 61: 243-293.
28. Kazemzadeh Chakusary M., Mohammadi H., Khodaparast A. 2017 – Decline-associated Phaeoacremonium species occurring on forest trees in the north of Iran – Forest Pathol. 47: e12368. https://doi.org/10.1111/efp.12368.
29. Kubátová A., Kolarik M., Pazoutová S. 2004 – Phaeoacremonium rubrigenum – hyphomycete associated with bark beetles found in Czechia – Folia Microbiol. 49: 99-104.
30. Michalcewicz J., Bodziarczyk J., Ciach M. 2013 – Development of the rosalia longicorn Rosalia alpina (L.) (Coleoptera: Cerambycidae) in the sycamore maple Acer pseudoplatanus L. – the first report from Poland – Pol. J. Entomol. 82: 19-24.
31. Michalcewicz J., Ciach M., Bodziarczyk J. 2011 – The unknown natural habitat of Rosalia alpina (L.) (Coleoptera: Cerambycidae) and its trophic association with the mountain elm Ulmus glabra in Poland – a change of habitat and host plant – Pol. J. Entomol. 80: 23-31.
32. Mostert L., Groenewald J. Z., Summerbell R. C., Gams W., Crous P. W. 2006 – Taxonomy and pathology of Togninia (Diaporthales) and its Phaeoacremonium Anamorphs – Stud. Mycol. 54: 1-113.
33. Mühlbauer A., Triebel D., Persoh D., Wollweber H., Seip S., Stadler M. 2002 – Macrocarpones, novel metabolites from stromata of Hypoxylon macrocarpum, and new evidence on the chemotaxonomy of Hypoxylon species – Mycol. Prog. 1: 235-248.
34. Parisi F., Pioli S., Lombardi F., Fravolini G., Marchetti M., Tognetti R. 2018 – Linking deadwood traits with saproxylic invertebrates and fungi in European forests - a review – iForest, 11: 423-436.
35. Pawłowski J., Kubisz D., Mazur M. 2002 – [Coleoptera Beetles] (In: [Red list of endangered and threatened animals in Poland], Ed: Z. Głowaciński) – Instytut Ochrony Przyrody PAN, Kraków, pp. 88-110 (in Polish).
36. Pourmoghaddam M. J., Khodaparast S. A., Pedramfar H. 2014 – The genus Daldinia in Guilan province (N Iran) – Rostaniha, 15: 122-132.
37. Pouzar Z. 1978 – Hypoxylon macrocarpum Pouz. spec. nov., a new fragrant Pyrenomycete – Ceská Mykol. 32: 19-21.
38. Prodi A., Sandalo S., Tonti S., Nipoti P., Pisi A. 2008 – Phialophora-like fungi associated with kiwifruit elephantiasis – J. Plant Pathol. 90: 487-494.
39. Russo D., Cistrone L., Garonna A. 2011 – Habitat selection by the highly endangered long-horned beetle Rosalia alpina in Southern Europe: a multiple spatial scale assessment – J. Insect Conserv. 15: 685-693.
40. Sama G. 2002 – Atlas of the Cerambycidae of Europe and the Mediterranean Area. Volume 1: Northern, Western, Central and Eastern Europe. British Isles and Continental Europe from France (excl. Corsica) to Scandinavia and Urals – Nakladatelství Kabourek, Zlín, 173 pp.
41. Stadler M., Læssøe T., Fournier J., Decock C., Schmieschek B., Tichy H.-V., Peršoh D. 2014 – A polyphasic taxonomy of Daldinia (Xylariaceae) – Stud. Mycol. 77: 1-143.
42. Starzyk J. R. 2004 – [Rosalia alpina (Linnaeus, 1758)] (In: [Polish red data book of animals, invertebrates], Eds: Z. Głowaciński, J. Nowacki) – Instytut Ochrony Przyrody PAN, Kraków, Akademia Rolnicza, Poznań, pp. 148-149 (in Polish).
43. Švácha P., Danilevsky M. L. 1988 – Cerambycoid larvae of Europe and Soviet Union (Coleoptera, Cerambycoidea). Part II – Acta Univ. Carolinae, Ser. Biol. 31: 121-284.
44. Venugopal P., Junninen K., Linnakoski R., Edman M., Kouki J. 2016 – Climate and wood quality have decayer-specific effects on fungal wood decomposition – Forest Ecol. Manag. 360: 341-351.
45. Weslien J., Djupstrom L. B., Schroeder M., Widenfalk O. 2011 – Long-term priority effects among insects and fungi colonizing decaying wood – J. Anim. Ecol. 80: 1155-1162.
46. White T. J., Bruns T. D., Lee S. B., Taylor J. W. 1990 – Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics (In: PCR Protocols: A Guide to Methods and Applications, Eds: M. A. Innis, D. H. Gelfand, J. J. Sninsky, T. J. White) – Academic Press, San Diego, CA, pp. 315-22.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-a141139d-11d4-45ae-8d29-44fc7aec63ea