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Australian Journal of Botany Australian Journal of Botany Society
Southern hemisphere botanical ecosystems
RESEARCH ARTICLE (Open Access)

Myxomycetes associated with the bark, cones and leaves of Australian cypress pines (Callitris spp.)

Steven L. Stephenson A , Todd F. Elliott https://orcid.org/0000-0001-9304-7040 B * , Kelsey Elliott C and Karl Vernes B
+ Author Affiliations
- Author Affiliations

A Department of Biological Sciences, University of Arkansas, Fayetteville, AR 720701, USA.

B Ecosystem Management, University of New England, Armidale, NSW 2351, Australia.

C Integrative Studies Department, Warren Wilson College, Swannanoa, NC 28778, USA.

* Correspondence to: toddfelliott@gmail.com

Handling Editor: Garry Cook

Australian Journal of Botany 71(3) 157-165 https://doi.org/10.1071/BT22128
Submitted: 16 November 2022  Accepted: 8 February 2023   Published: 15 March 2023

© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Context: The diversity of myxomycetes associated with Australia’s most diverse native conifer genus, Callitris, has been incompletely studied.

Aims: In this study, we examine the diversity of myxomycetes associated with outer bark, fallen cones and dead litter (leaves/needles) of four Callitris species.

Methods: Substrate samples were collected from 13 localities in New South Wales, Queensland and the Northern Territory. Samples were used to prepare moist-chamber cultures, and species of associated myxomycetes were identified.

Key results: Twenty-three species in 15 genera were recorded. Percentage occurrence of myxomycetes varied depending on substrate, being 87% (cones), 83% (bark) and 63% (litter). Bark yielded the most species (17), followed by litter (10) and cones (6). Only two species (Arcyria cinerea and S. fusca) were recorded from all three substrates. Substrate pH is often an important factor for the occurrence of myxomycetes, but the mean values recorded for cones (5.7), litter (5.8), and bark (5.9) showed little difference. This suggests that other undetermined factors contributed to the differences in species occurrence. In addition to the records generated in the present study, we provide a list of previous records of myxomycetes found in association with Callitris.

Conclusions: This study has highlighted, for the first time, the diversity of myxomycetes associated with members of the genus Callitris and has shown the importance of cypress pines as a substrate for myxomycetes.

Implications: This study leads to a better understanding of the biogeography, distribution and ecology of myxomycetes and their associated organisms.

Keywords: amoebozoans, conifer myxomycete ecology, Cupressaceae, microbial ecology, moist chamber cultures, myxogastrids, plasmodial slime moulds, slime moulds.


References

Adamonyte G, Stephenson SL, Michaud A, Seraoui E-H, Meyer M, Novozhilov YK, Krivomaz T (2011) Myxomycete species diversity on the island of La Réunion (Indian Ocean). Nova Hedwigia 92, 523–549.
Myxomycete species diversity on the island of La Réunion (Indian Ocean).Crossref | GoogleScholarGoogle Scholar |

Adamonytė G, Motiejūnaitė J, Iršėnaitė R (2016) Crown fire and surface fire: effects on myxomycetes inhabiting pine plantations. Science of The Total Environment 572, 1431–1439.
Crown fire and surface fire: effects on myxomycetes inhabiting pine plantations.Crossref | GoogleScholarGoogle Scholar |

Blackwell M, Gilbertson RL (1984) Distribution and sporulation phenology of myxomycetes in the Sonoran desert of Arizona. Microbial Ecology 10, 369–377.
Distribution and sporulation phenology of myxomycetes in the Sonoran desert of Arizona.Crossref | GoogleScholarGoogle Scholar |

Crisp MD, Cook LG, Bowman DMJS, Cosgrove M, Isagi Y, Sakaguchi S (2019) Turnover of southern cypresses in the post-Gondwanan world: extinction, transoceanic dispersal, adaptation and rediversification. New Phytologist 221, 2308–2319.
Turnover of southern cypresses in the post-Gondwanan world: extinction, transoceanic dispersal, adaptation and rediversification.Crossref | GoogleScholarGoogle Scholar |

Dagamac NHA, Stephenson SL, Dela Cruz TEE (2012) Occurrence, distribution and diversity of myxomycetes (plasmodial slime moulds) along two transects in Mt. Arayat National Park, Pampanga, Philippines. Mycology 3, 119–126.
Occurrence, distribution and diversity of myxomycetes (plasmodial slime moulds) along two transects in Mt. Arayat National Park, Pampanga, Philippines.Crossref | GoogleScholarGoogle Scholar |

Dagamac NHA, Rojas C, Novozholov YK, Moreno GH, Schlueter R, Schnittler M (2017) Speciation in progress? A phylogeographic study among populations of Hemitrichia serpula (Myxomycetes). PLoS ONE 12, e0174825
Speciation in progress? A phylogeographic study among populations of Hemitrichia serpula (Myxomycetes).Crossref | GoogleScholarGoogle Scholar |

Estrada-Torres A, Wrigley de Basanta D, Conde E, Lado C (2009) Myxomycetes associated with dryland ecosystems of the Tehuacán–Cuicatlán Valley Biosphere Reserve, Mexico. Fungal Diversity 36, 17–56.

Feng Y, Schnittler M (2015) Sex or no sex? Group I introns and independent marker genes reveal the existence of three sexual but reproductively isolated biospecies in Trichia varia (Myxomycetes). Organisms Diversity & Ecology 15, 631–650.
Sex or no sex? Group I introns and independent marker genes reveal the existence of three sexual but reproductively isolated biospecies in Trichia varia (Myxomycetes).Crossref | GoogleScholarGoogle Scholar |

Fiore-Donno AM, Nikolaev SI, Nelson M, Pawlowski J, Cavalier-Smith T, Baldauf SL (2010) Deep phylogeny and evolution of slime moulds (Mycetozoa). Protist 161, 55–70.
Deep phylogeny and evolution of slime moulds (Mycetozoa).Crossref | GoogleScholarGoogle Scholar |

Härkönen M (1977) Corticulous myxomycetes in three different habitats in southern Finland. Karstenia 17, 19–32.
Corticulous myxomycetes in three different habitats in southern Finland.Crossref | GoogleScholarGoogle Scholar |

Ing B (1999) ‘The Myxomycetes of Britain and Ireland.’ (Richmond Publishing: Slough, UK)

Keller HW, Eliasson UH, Braun KL, Buben-Zurey MJ (1988) Corticolous myxomycetes X: ultrastructure and taxonomic status of Cribraria minutissima and C. confusa. Mycologia 80, 536–545.
Corticolous myxomycetes X: ultrastructure and taxonomic status of Cribraria minutissima and C. confusa.Crossref | GoogleScholarGoogle Scholar |

Knight KJ, Lado C (2020) Clastoderma confusum (Myxomycetes: Amoebozoa), a remarkable new species of slime mould from Western Australia. Nuytsia 31, 35–40.

Kylin H, Mitchell DW, Seraoui EH, Buyck B (2013) Myxomycetes from Papua New Guinea and New Caledonia. Fungal Diversity 59, 33–44.
Myxomycetes from Papua New Guinea and New Caledonia.Crossref | GoogleScholarGoogle Scholar |

Lado C (2005–2022) An online nomenclatural information system of Eumycetozoa. Real Jardin Botánico de Madrid, CSIC, Madrid [Internet]. Available at http://www.eumycetozoa.com [Accessed 10 November 2021]

Lado C, Estrada-Torres A, Stephenson SL, Wrigley de Basanta D, Schnittler M (2003) Biodiversity assessment of myxomycetes from two tropical forest reserves in Mexico. Fungal Diversity 12, 67–110.

Martin GW, Alexopoulos CJ (1969) ‘The Myxomycetes.’ (University of Iowa Press: Iowa City, IA, USA)

Martin GW, Alexopoulos CJ, Farr ML (1983) ‘The Genera of Myxomycetes.’ (University of Iowa Press: Iowa City, IA, USA)

McHugh R, Stephenson SL, Mitchell DW, Brims MH (2003) New records of Australian Myxomycota. New Zealand Journal of Botany 41, 487–500.
New records of Australian Myxomycota.Crossref | GoogleScholarGoogle Scholar |

McHugh R, Mitchell DW, Brims MH, Stephenson SL (2009) New additions to the Myxomycota of Australia. Australasian Mycologist 28, 56–64.

Ndiritu GG, Spiegel FW, Stephenson SL (2009) Distribution and ecology of the assemblages of myxomycetes associated with major vegetation types in Big Bend National Park, USA. Fungal Ecology 2, 168–183.
Distribution and ecology of the assemblages of myxomycetes associated with major vegetation types in Big Bend National Park, USA.Crossref | GoogleScholarGoogle Scholar |

Novozhilov YK, Schnittler M, Rollins AW, Stephenson SL (2000) Myxomycetes from different forest types in Puerto Rico. Mycotaxon 77, 285–299.

Novozhilov YK, Schnittler M, Vlasenko AV, Fefelov KA (2010) Myxomycete diversity of the Altay Mountains (southwestern Siberia, Russia). Mycotaxon 111, 91–94.
Myxomycete diversity of the Altay Mountains (southwestern Siberia, Russia).Crossref | GoogleScholarGoogle Scholar |

Piggin J, Bruhl JJ (2010) Phylogeny reconstruction of Callitris Vent. (Cupressaceae) and its allies leads to inclusion of Actinostrobus within Callitris. Australian Systematic Botany 23, 69–93.
Phylogeny reconstruction of Callitris Vent. (Cupressaceae) and its allies leads to inclusion of Actinostrobus within Callitris.Crossref | GoogleScholarGoogle Scholar |

Rojas C, Stephenson SL (Eds) (2021) ‘Myxomycetes: biology, systematics, biogeography, and ecology.’ p. 582. (Academic Press: Cambridge, MA, USA)

Rosing WC, Mitchell DW, Stephenson SL (2007) Corticolous myxomycetes from Victoria. Australasian Mycologist 26, 9–15.

Schnittler M, Stephenson SL (2000) Myxomycete biodiversity in four different forest types in Costa Rica. Mycologia 92, 626–637.
Myxomycete biodiversity in four different forest types in Costa Rica.Crossref | GoogleScholarGoogle Scholar |

Snell KL, Keller HW, Eliasson UH (2003) Tree canopy myxomycetes and new records from ground sites in the Great Smoky Mountains National Park. Castanea 68, 97–108.

Stephenson SL (1988) Distribution and ecology of myxomycetes in temperate forests. I. Patterns of occurrence in the upland forests of southwestern Virginia. Canadian Journal of Botany 66, 2187–2207.
Distribution and ecology of myxomycetes in temperate forests. I. Patterns of occurrence in the upland forests of southwestern Virginia.Crossref | GoogleScholarGoogle Scholar |

Stephenson SL (1989) Distribution and ecology of myxomycetes in temperate forests. II. Patterns of occurrence on bark surface of living trees, leaf litter, and dung. Mycologia 81, 608–621.
Distribution and ecology of myxomycetes in temperate forests. II. Patterns of occurrence on bark surface of living trees, leaf litter, and dung.Crossref | GoogleScholarGoogle Scholar |

Stephenson SL (2021) ‘Secretive slime moulds: Myxomycetes of Australia.’ (CSIRO Publishing: Melbourne, Vic., Australia)

Stephenson SL, Stempen H (1994) ‘Myxomycetes: a handbook of slime molds.’ (Timber Press: Portland, OR, USA)

Stephenson SL, Marbaniang TM, Gupta P, Rojas C (2020a) Assemblages of corticolous myxomycetes associated with species of Pinus (Pinaceae) in four different regions of the world. Nova Hedwigia 111, 199–217.
Assemblages of corticolous myxomycetes associated with species of Pinus (Pinaceae) in four different regions of the world.Crossref | GoogleScholarGoogle Scholar |

Stephenson SL, Kaur G, Payal N, Elliott TF, Vernes K (2020b) Myxomycetes associated with arid habitats in northeastern South Australia. Transactions of the Royal Society of South Australia 144, 139–153.
Myxomycetes associated with arid habitats in northeastern South Australia.Crossref | GoogleScholarGoogle Scholar |

Stephenson SL, Elliott TF, Elliott K, Vernes K (2022) Myxomycetes associated with Australian vertebrate dung. Australasian Zoologist
Myxomycetes associated with Australian vertebrate dung.Crossref | GoogleScholarGoogle Scholar |

Takahashi K (2004) Distribution of myxomycetes on different decay states of deciduous broadleaf and coniferous wood in a natural temperate forest in the southwest of Japan. Systematics and Geography of Plants 74, 133–142.

Takahashi K, Hada Y (2010) Geographical distribution of myxomycetes on coniferous deadwood in relation to air temperature in Japan. Mycoscience 51, 281–290.
Geographical distribution of myxomycetes on coniferous deadwood in relation to air temperature in Japan.Crossref | GoogleScholarGoogle Scholar |

Takahashi K, Harakon Y (2012) Comparison of wood-inhabiting myxomycetes in subalpine and montane coniferous forests in the Yatsugatake Mountains of Central Japan. Journal of Plant Research 125, 327–337.
Comparison of wood-inhabiting myxomycetes in subalpine and montane coniferous forests in the Yatsugatake Mountains of Central Japan.Crossref | GoogleScholarGoogle Scholar |

Wellman P (2019) Australian corticolous myxomycetes: models of distribution and development. Australian Journal of Botany 67, 617–629.
Australian corticolous myxomycetes: models of distribution and development.Crossref | GoogleScholarGoogle Scholar |

White MA, Elliott TF, Kennedy BPA, Stephenson SL (2020) First records of myxomycetes from Bathurst Island (one of the Tiwi Islands) in the Northern Territory, Australia. Austral Ecology 45, 1183–1187.
First records of myxomycetes from Bathurst Island (one of the Tiwi Islands) in the Northern Territory, Australia.Crossref | GoogleScholarGoogle Scholar |

Wrigley de Basanta D (2000) Acid deposition in Madrid and corticolous myxomycetes. Stapfia 73, 113–120.