Co-existence and interaction between myxomycetes and other 
organisms in shared niches

IRINA O. DUDKA and KATERINA O. ROMANENKO

Department of Mycology, M.G. Kholodny Institute of Botany
National Academy of Sciences of Ukraine

Tereshchenkivska 2, MSP 1 Kyiv, UA 01 001

Dudka I.O., Romanenko K.O. Co existence and interaction between myxomycetes and other 
organisms in shared niches. Acta Mycol. 41(1): 99 112, 2006.

The ecology of myxomycetes co existing with the Latridiidae (Coleoptera), bryophytes and 
ascomycetous, basidiomycetous and anamorphic fungi were studied in Crimea and at different 
locations on the left bank of Ukraine. Results from the left bank indicate that the Latridiidae 
feed on myxomycetes. Colonies of the most common 13 myxomycete species (which included 
Stemonitis axifera (Bull.) Macbr., S. fusca Roth, S. splendens Rost., Fuligo septica (L.) Wigg. and 
Mucilago crustacea Wigg.) were inhabited by 5 species of the Latridiidae. Myxomycete spores 
were present in guts of 19 of the 25 beetle specimens investigated. Beetles Latridius hirtus, 
Enicmus rugosus and E fungicola seem to be obligate myxomycete feeders, while Corticarina 
truncatella was clearly facultative. 13 species of myxomycetes were recorded on 9 species of 
moss and 3 species of liverwort developing on decaying wood or bark in the Crimean Nature 
Reserve. Relations between myxomycetes and bryophytes on woody substrata are spatial rather 
than trophic, and are possibly regulated by specific microclimatic conditions inside bryophyte 
thallomes. 69 species of myxomycetes were found co existing with 36 species of ascomycetes, 21 
species of basidiomycetes and 9 species of anamorphic fungi in the Crimean Nature Reserve. 
Associations formed by myxomycetes and fungi on different woody substrata are analyzed.

Key words: myxomycetes, ascomycetes, basidiomycetes, anamorphic fungi, bryophytes, 
Latridiidae beetles

INTRODUCTION

In terrestrial ecosystems, certain patterns can be found governing the spatial dis-
tribution of living organisms. These are connected with trophic, topic and another 
relations. Autotrophic plants are usually considered the foundation for the resulting 
consortia (ecological communities originating through co-development of heterog-
enous groups tightly joined by common activities), since they provide a prime food 
source, and a substratum on which other organisms can grow. Myxomycetes (also 
known as slime moulds) often form a part of those consortia, and may also make as-
sociations with various other groups of organisms (D u d k a  et al. 1976). Research on 

 ACTA MYCOLOGICA
 Vol. 41 (1): 99-112
 2006

Dedicated to Professor Alina Skirgiełło
on the occasion of her ninety fifth birthday



100 I. O. Dudka and K. O. Romanenko 

the co-existence of slime moulds with beetles (Coleoptera), bryophytes, ascomycet-
ous, basidiomycetous and anamorphic fungi is briefly reviewed below.

BRIEF HISTORICAL REVIEW

Myxomycetes are frequently associatiated with insects, especially beetles (Co-
leoptera). S t e p h e n s o n  et al. (1994) reviewed slime mould / beetle associations 
recorded since the end of the nineteenth century, and listed the beetle families most 
frequently forming these associations as follows: Rhizodidae, Leiodidae, Staphylini-
dae, Clambidae, Eucinetidae, Sphindidae, Cerylonidae, Latridiidae. The numerous and 
repeated records of these beetles on the same species of myxomycetes suggested an 
obligate connexion. Since examination of beetle gut contents usually reveals abun-
dant myxomycete spores, it is clear the beetles feed on them. In fact, some beetle 
species use not only spores but also plasmodia of slime moulds as a source of nutri-
tion (L a w r e n c e ,  N e w t o n  1980; W h e e l e r  1980). The term myxomycetophagy 
has been proposed to describe the phenomenon of beetles deriving nutrition from 
slime moulds (N e w t o n  1984; N e w t o n ,  S t e p h e n s o n  1990).

Despite their rather diverse taxonomic range, slime moulds used by beetles as food 
share a number of morphological, developmental and ecological characters as follows: 1) 
abundant spores in large simple sporophores or large aethalia which comprise a group of 
sporangia covered with a common cortex and pillow-like; 2) a long period of sporophore 
formation during the growing season; 3) long-lasting sporophores; 4) abundance; 5) de-
velopment on woody substrata; 6) spores with spiny, warty or net-like walls, 4 (5-9)-15 
µm diam. (B l a c k w e l l  1984). Arcyria incarnata (Pers.) Pers., Stemonitis axifera (Bull.) 
Macbr., S. fusca Roth, S. splendens Rost., Lycogala epidendrum (L.) Fr., Stemonaria 
longa (Peck) Nann.-Brem., Fuligo septica (L.) Wigg., Tubifera ferruginosa (Batsch) 
Gmel. and others largely match those criteria. S t e p h e n s o n  et al. (1994) have shown 
that myxomycetes of the genus Stemonitis Roth are used as food by 10 beetle genera, 
Fuligo Hall. by 9, and Arcyria Wigg. and Tubifera Gmel. by 7 each.

The feeding preferences of some beetles for myxomycetes explains their constant 
association with slime moulds. There is, however, evidence that these beetles also 
play some part in disseminating myxomycete spores. Observation of Fuligo septica 
spores from Sphindidae beetle guts has shown that some spores pass through insect 
intestines without damage and can subsequently germinate, while transfer of spores 
of Physarum straminipes Lister and F. septica from the exoskeleton surface of Latri-
diidae beetles to agar medium has also been observed, particularly when there are 
large numbers of such spores (B l a c k w e l l ,  L a m a n ,  G i l b e r t s o n  1 9 8 2 ).

Representatives of the family Latridiidae (Coleoptera) are small beetles, no more 
than 3 mm long, occurring under bark of fallen trunks, in decaying wood and in for-
est litter. Worldwide about 750 species are known, 55 in Ukraine. Typically they are 
associated with fungi, in particular anamorphic fungi, ascomycetes and basidiomyc-
etes, predominantly with basidiomata of wood-destroying fungi, where they feed on 
the spores (H o w a r d ,  C u r r i e  1932; N e w t o n ,  S t e p h e n s o n  1990; S t e p h e n -
s o n  et al. 1994). Information about associations between the Latridiidae and myxo-
mycetes has been summarized (D u d k a ,  Tr i k h l e b ,  R o m a n e n k o  2002).

The co-existence of myxomycetes and bryophytes has been studied much less 
than that of slide moulds and beetles. Myxomycete sporophores at the thallome 



 Co existence and interaction between myxomycetes 101

surface of mosses and liverworts are rather widespread in nature (S t e p h e n s o n , 
S t e m p e n  1994; H ä r k ö n e n  et al. 2002; S t o j a n o w s k a ,  P a n e k  2004). In most 
cases, however, associations of slime moulds and bryophytes arise accidentally since 
both components tend to occur on the same substratum – decaying and decompos-
ing wood of deciduous and/or coniferous trees (S t e p h e n s o n ,  S t u d l a r  1985). It 
has also been surmised that myxomycetes develop more intensively and occur more 
frequently on fallen decaying logs overgrown with bryophytes because of their high 
humidity (S t o j a n o w s k a ,  P a n e k  2004). Only a few myxomycetes, in particular 
Barbeyella minutissima Meylan, Colloderma oculatum (Lipp.) G. Lister and Lepido-
derma tigrinum (Schr.) Rost. seem to be true bryophilous species. The first of these 
species is adapted to rich communities of liverworts, especially Novellia curvifolia 
and species of the genus Cephalozia which sometimes completely cover the surface 
of fallen decaying coniferous logs by (S c h n i t t l e r ,  N o v o z h i l o v  1998; S c h n i t -
t l e r ,  S t e p h e n s o n ,  N o v o z h i l o v  2000; N o v o z h i l o v  2005).

In forest ecosystems many organisms are involved in decomposition of woody 
substrata. Apart from slime moulds, wood-inhabiting fungi are also active at various 
stages of succession. Some fungal species are known to develop and sporulate on the 
surface of myxomycete fruitbodies, using them as a feeding substratum (R o g e r s o n , 
S t e p h e n s o n  1993), but that is a case of fungal parasitism on slime moulds and an 
example of trophic relations which are probably negative for the myxomycete. Other 
interrelations between myxomycetes and these fungi so far remain almost totally 
unstudied, although side-by-side co-existence of myxomycetes and fungi on the same 
woody substatum is rather commonly observed in nature. Such relations appear to 
be indifferent, but that is only an assumption: exact information is absent not only 
about the nature of those relations but about also the slime mould and fungal spe-
cies compositions on which they are based. Co-existence of myxomycetes and true 
fungi has therefore been studied least of all (R o g e r s o n ,  S t e p h e n s o n  1993).

OBJECTIVES

It is clear that the characteristics of the co-existence and of interrelations between 
myxomycetes and other organisms is still poorly understood. The aim of the present 
work has therefore been to contribute to that research by identifying myxomycetes 
associated with Latridiidae family beetles, liverworts, mosses and wood-inhabiting 
anamorphic, ascomycetous and basidiomycetous fungi collected in different parts of 
southern Ukraine. This study has also been designed to begin analysis of relations 
between component members in the associations.

MATERIAL AND METHODS

Fieldwork was carried out from April to September 2000 on the left bank of 
Ukraine within three geobotanical regions (Donetsk, Leftbank and Starobilsk grass-
meadow steppes), and in the Crimean peninsula within the Crimean Nature Reserve 
(Montane Crimea geobotanical region) during the growing seasons of 2000 and 2001. 
Left bank myxomycete collections were predominantly from forest plantations near 
Donetsk, and flood-plane forests around Stanychno-Luganske settlement in the val-
ley of the Siverski Donets river (Table 1) where oak (Quercus robur L.), ash (Fraxinus 



102 I. O. Dudka and K. O. Romanenko 

excelsior L.) and aspen (Populus tremula L.) are dominant tree species. Beech (Fagus 
sylvatica L.) and Crimean pine (Pinus pallasiana D. Don) dominate other tree spe-
cies in the study areas of forest communities in the Crimean Nature Reserve.

Myxomycete colonies (groups of sporophores and aethalia) were sampled in 
the field from fallen trunks and logs of trees in various stages of wood decay, from 
fallen branches of various diameters and from decaying stumps. 53 field samples 
of myxomycetes were collected on woody substrata the left bank study areas and 
450 from the Crimean Nature Reserve. 300 samples of woody substrata from that 
reserve, mainly tree bark, were collected for laboratory detection of myxomycetes, 
using the moist chamber method (G i l b e r t ,  M a r t i n  1933; S t e p h e n s o n  1985; 
N a n n e n g a - B r e m e k a m p  1991). For myxomycete identification, the main manu-
als on the group were used (N a n n e n g a - B r e m e k a m p  1991; N o v o z h i l o v  1993; 
S t e p h e n s o n ,  S t e m p e n  1994). Slime mould nomenclature follows I n g  (1999).

Of the 53 samples collected from left bank forest plantations, 25 were examined 
for the presence of Latridiidae in the myxomycete colonies. The biggest colonies 
were selected from the field samples, then divided into three more or less equal parts 
and placed in 90 mm sterile Petri dishes with filter paper at the bottom. The dark 
bodies of beetles emerging from the colony were easily observed against the white 
surface of the paper. These individuals were then identified, and their gut contents 
sampled. For identification of beetles the appropriate volume of Fauna Hungariae 
was used (R ü c k e r  1983). Preparations of gut contents for identification of myxo-
mycetous spores were made in Fore liquid (50 ml distilled water, 20 g chloralhydrate, 
40 ml glycerine, 30 g gum-arabic).

In addition to gut content studies of Latridiidae specimens found on slime moulds 
collected in the field, living Latridius hirtus were kept in the laboratory on aethalia 
of Fuligo intermedia, to see if L. hirtus can complete its life cycle with only a single 
feed source present. Pillow-like aethalia of F. intermedia, 0·5-4 cm long, up to 10 
mm thick and undamaged by insects were collected in the field. These aethalia were 
checked for other insect inhabitants using a stereo microscope, then placed in sterile 
Petri dishes and stored for two weeks to ensured absence of insects. Adult Latridius 
hirtus individuals were then added, and the dishes were regularly examined to follow 
development of the successive beetle stages.

Associations between myxomycetes and bryophytes were studied in the Crimean 
Nature Reserve. Special attention was paid to associations where slime moulds de-
veloped sporophores, aethalia or plasmodia directly on the surface of bryophyte 
thallus or inside it.

Associations between myxomycetes and wood-inhabiting fungi were studied in 
the Crimean Nature Reserve to identify the component species and assess the influ-
ence of substratum size on species diversity.

RESULTS

Interactions between myxomycetes and Latridiidae beetles on woody substrata

Associations between myxomycetes and the Latridiidae are shown in Table 1. 
These associations were found to be rather widespread on the left bank of Ukraine, 



 Co existence and interaction between myxomycetes 103

Т а b l e  1
Myxomycetes associated with Latridiidae (Coleoptera) 

at the left bank of Ukraine

Myxomycete 
species, by order 
and family

Beetle 
species

Place and date of 
association collection

Beetle gut content

Liceales, Reticulariaceae

Tubifera ferruginosa 
(Batsch) Gmel.

Reticularia 
lycoperdon Bull.

Enicmus 
rugosus

Enicmus 
fungicola

E. rugosus

Melanoph
thalma sp.

Lugansk oblast, s. Stan
ychno Luganske, 1 July 
2000

Donetsk area, 6 June 2000

Donetsk area, 26 May 2000

Lugansk oblast, s. Stany
chno Luganske, 29 June 
2000

Spores of different myxomycete 
species including T. ferruginosa

Spores of R. lycoperdon

Spores of R. lycoperdon

Spores of Alternaria alternata 
(Hyphomycetes)

Trichiales, Trichiaceae

Arcyria obvelata 
(Oeder) Onsberg

E. rugosus Lugansk oblast, s. Stan
ychno Luganske, 30 June 
2000

Spores of A. obvelata

Stemonitales, Stemonitaceae

Comatricha nigra 
(Pers.) Schroet.

Enerthenema 
papillatum (Pers.) 
Rost.

Stemonaria longa 
(Peck) Nann. Brem.

Stemonitis axifera 
(Bull.) Macbr.

Stemonitis fusca
Roth

Stemonitis splendens 
Rost.

Symphytocarpus 
amaurochaeoides 
Nann. Brem.

E. rugosus

E. rugosus

E. rugosus

E. rugosus

Corticarina 
truncatella

E. rugosus

C. 
truncatella

E. rugosus

Latridius 
hirtus

E. rugosus

Donetsk area, 18 August 
2000

Donetsk area, 3 September 
2000

Donetsk oblast, Volodarski 
district, nature reserve 
Kamiani Mogyly, 22 July 
2000

Donetsk oblast, Novo
azovski district, Azovske 
forestry, 3 July 2000

Lugansk oblast, s. Stan
ychno Luganske, flood
plain forest, 2 July 2000

Lugansk oblast, s. Stan
ychno Luganske, flood
plain forest, 2 July 2000

Donetsk, 3d city pond, 8 
August 2000

Donetsk, 3d city pond, 8 
August 2000

Donetsk, 3d city pond, 8 
August 2000

Donetsk, Putylivski forest, 
18 July 2000

Spores of C. nigra

Spores of E. papillatum

Spores of S. longa

Spores of S. axifera

Spores of Alternaria alternata 
(Hyphomycetes)

Spores of S. fusca

Spores of S. splendens

Spores of S. splendens

Spores of S. splendens

Spores of S. amaurochaetoides



104 I. O. Dudka and K. O. Romanenko 

with 5 species from 4 Latridiidae genera being were found in the colonies of 13 spe-
cies of myxomycetes from 10 genera.

Gut content analysis (from 5 of the Latridiidae species encountered in colonies 
of the 25 investigated samples of 13 myxomycete species) revealed slime moulds 
spores in the guts of 19 individuals (Tab. 1). In 16 of those cases, the spores found 
belonged to the slime mould species on which the beetle was collected. Spores of 
Tubifera ferruginosa, Fuligo septica and Mucilago crustacea were found in the guts of 
Enicmus rugosus specimens not originating from colonies of those species. Other 
spores distinct in morphology and size were also present in the guts of those En-
icmus rugosus specimens. These may also have been myxomycete spores, but their 
taxonomic position was not established. No slime mould spores were found in the 
guts of female Melanophthalma sp. individuals found on Reticularia lycoperdon or 
from Corticarina truncatella individuals collected on Stemonitis fusca; instead, the 
guts of those beetles were filled with spores of the anamorphic fungus Alternation 
alternata (Fr.) Keisler.

Study of the living Latridius hirtus, kept in the laboratory on aethalia of Fuligo in
termedia, resulted in the following sequence of observations: adults, laying eggs in the 
aethalia, larvae, moult, pupae, young adults emerging from pupae.

Co-existence of myxomycetes and bryophytes on woody substrata

Altogether 13 species of myxomycetes were recorded on 9 species of moss and 3 
species of liverwort associated with woody substrata in the Crimean Nature Reserve 
(Table 2). Arcyria cinerea (Bull.) Pers., Echinostelium arboreum Keller et Brooks, E. 
minutum de Bary, Macbrideola cornea (G. Lister et Cran) Alexop., Perichaena ver-
micularis (Schw.) Rost., Physarum cinereum (Batsch) Pers. were most commonly en-
countered in association with the following bryophytes widespread in montane Cri-
mea: Hypnum cupressiforme, Leucodon sciuroides and Porella platyphylla. Didymium 

Physarales, Physaraceae

Fuligo intermedia 
Macbr.

Fuligo septica (L.) 
Wigg.

E. rugosus

L. hirtus

E. rugosus

L. hirtus

Donetsk area, 3 September 
2000

Donetsk area, 3 September 
2000

Donetsk, Putylivski forest, 
18 July 2000

Donetsk, valley of the river 
Bakhmutka, 27 June 2000

Spores of F. intermedia

Spores of F. intermedia

Spores of different myxomycete 
species including F. septica

Spores of  F. septica

Physarales, Didymiaceae

Mucilago crustacea 
Wigg.

L. rugosus

L. hirtus

Donetsk area, 10 July 2000

Donetsk area, 3 September 
2000

Spores of different myxomycete 
species including M. crustacea

Spores of M. crustacea

Tab. 1 cont.



 Co existence and interaction between myxomycetes 105

trachysporum G. Lister on Ctenidium molluscum, Licea minima Fr. on Hypnum cu-
pressiforme, Perichaena chrysosperma (Currey) Lister on Frullania dilata, Stemonitis 
fusca on Leucodon sciuroides, Symphytocarpus amaurochaetoides on Pterigynandrum 
filiforme, S. impexus Ing. et Nann.-Brem. on Porella platyphylla and Trichia varia 
(Pers.) Pers. on Anomodon viticulosus were more rare in bryophytes communities of 
the reserve (Tab. 2).

Augmenting information about woody substrata in Table 2, Echinostelium minu-
tum was collected on bark of Acer stevenii Pojark., Alnus glutinosa (L.) Gaertn., 
Carpinus betulus L., Fagus sylvatica, Pinus kochiana Klotzsch., P. pallasiana, P. sylves-
tris L., Quercus petraea (Mattuschka) Liebl., Q. robur, Sorbus torminalis (L.) Crantz., 
Macbrideola cornea was collected on bark of Acer campestre L., Acer stevenii, Carpi-
nus betulus, Cornus mas L., Crataegus sp., Fagus sylvatica, Fraxinus excelsior, Taxus 
baccata L., Tilia cordata Mill. and Perichaena vermicularis was collected on bark of 
Acer campestre, Alnus glutinosa, Cornus mas, Fraxinus excelsior, Pyrus communis L., 
Q. petraea, Taxus baccata, Tilia cordata. On the reserve Didymium trachysporum was 
associated with Ctenidium molluscum but there are additional records of it on fallen 
conifer needles, pieces of small bushes and herbivore dung. Physarum cinereum was 
found on fallen leaves and decaying wood, but was most frequent in bryophyte com-
munities as listed in Table 2.

Ta b l e  2
Myxomycetes collected in the Crimean nature reserve on bryophytes

Species of myxomycetes Species of bryophytes Woody substrata
Arcyria cinerea (Bull.) Pers. Frullania dilatata 

Hypnum cupressiforme 
Porella platyphylla 

absence

Didymium trachysporum G. Lister Ctenidium molluscum 
Echinostelium arboreum Keller et Brooks Leucodon sciuroides 

Hypnum cupressiforme 
Echinostelium minutum de Bary Hypnum cupressiforme 

Leucodon sciuroides 
Pterigynandrum filiforme 
Racomitrium canescens 

absence

Licea minima Fr. Hypnum cupressiforme decaying wood
Macbrideola cornea (G. Lister et Cran) 
Alexop.

Leucodon sciuroides
Porella platyphylla
Pterigynandrum filiforme 
Hypnum cupressiforme
Metzgeria furcata 

absence

Perichaena chrysosperma (Currey) Lister Frullania dilatata 
Perichaena vermicularis (Schw.) Rost. Hypnum vaucheri 

Porella platyphylla 
absence

Physarum cinereum (Batsch.) Pers. Anomodon viticulosus
Homolothecium sericeum
Hypnum cupressiforme
Porella platyphylla
Pseudoleskeella nervoza 

absence

Stemonitis fusca Leucodon sciuroides decaying wood
Symphytocarpus amaurochaetoides Pterigynandrum filiforme decaying wood
Symphytocarpus impexus Ing et Nann. Brem. Porella platyphylla 
Trichia varia (Pers.) Pers. Anomodon viticulosus decaying wood



106 I. O. Dudka and K. O. Romanenko 

Co-existence of myxomycetes and fungi on woody substrata

In the Crimean Nature Reserve, 69 species of myxomycetes and 66 species of 
fungi from the Ascomycota (36), Basidiomycota (21) and anamorphic fungi (9) were 
collected on decaying woody substrata of coniferous and broadleaf trees. All fun-
gi recorded were species usually regarded as wood-inhabiting. Various complexes 
could be distinguished according to substratum type (Tab. 3) and range of associated 
species (Tab. 4).

Altogether 52 associations (Tab. 3) were encountered in the Crimean Nature 
Reserve between slime moulds and wood-inhabiting fungi, including 7 on large fall-
en trunks of trees, 34 on fallen branches of various diameters and 11 on decaying 
stumps. The highest numbers of myxomycete and the fungal species (from 13 to 35) 
occurred in associations on large fallen tree trunks. Species diversity was significant-
ly less (from 2 to 8) in associations on fallen branches (from 5 to 15 cm in diameter) 
and on decaying stumps.

The following fungi were dominant (Tab. 4) in associations on small woody 
remnants and on large fallen decaying tree trunks. Pyrenomycetes: Ceratostomel-
la cirrhosa (Pers.) Sacc., Lasiosphaeria hirsuta (Fr.) Ces. et de Not., Melanomma 
pulvis-pyrius (Pers.) Fuckel, Nectria peziza (Tode) Fr., Rosellinia conglobata (Fr. et 
Fuckel) Sacc.; discomycetes: Bisporella citrina (Batsch) Korf et S.E. Carp., Mollisia 
melaleuca (Fr.) Sacc., Orbilia coccinella (Sommerf.) Fr. These were associated with 
the following myxomycetes: Arcyria denudata (L.) Wettst., Ceratiomyxa fruticulosa 
(Mull.) Macbr., Hemitrichia clavata (Pers.) Rost., Lycogala epidendrum, Metatrichia 
vesparium (Batsch) Nann-Brem., Physarum nutans Pers., Stemonitis fusca, Stemoni-
topsis typhina (Wigg.) Nann-Brem., Trichia decipiens (Pers.) Macbr., T. scabra Rost. 
and T. varia (Pers.) Pers. The basidiomycete Calocera cornea (Batsch) Fr. and the 
anamorphic fungus Brachysporium nigrum (Link: Fr.) S. Hughes often joined those 
associations. Fomes fomentarius (L.: Fr.) Fr., Stereum hirsutum (Willd.) Fr., some 
species of the genus Xylaria Hill ex Schrank [particularly X. longipes Nitschke and 
X. polymorpha (Pers.) Grev.] were also found in those assocations, but only on large 
fallen trunks. All listed species of myxomycetes and fungi formed the main body of 
associations on the woody substrata in the reserve. Frequency of occurrence in as-
sociations was high throughout the period of study.

Sometimes pyrenomycetes Amphisphaeria umbrina (Fr.) de Not., Strickeria ko-
chii Koerb., Lasiosphaeria ovina (Pers.) Ces. et de Not., discomycetes Mollisia cine-

Ta b l e  3
Distribution of associated complexes between myxomycetes and xylotrophic fungi on the 

different types of woody substrates

Type of woody substrate Number of associated 
complexes between 

myxomycetes and wood
inhabiting fungi

Range of species from 
both groups in associated 

complexes

Large fallen tree trunks 7 From 13 to 35
Fallen branches of trees 34 From 2 tо 6
Stumps 11 From 2 to 8
Total 52 133



 Co existence and interaction between myxomycetes 107

rea (Batsch) P. Karst., Trichophaeopsis bicuspis (Boud.) Korf et Erb., basidiomycetes 
Schizopora paradoxa (Schrad.: Fr.) Donk, Phellinus ferruginosus (Schrad.: Fr.) Pat., 
Fibuloporia mucida (Pers.: Fr.) Niemelä, anamorphic fungi Pleurothecium recurva-
tum (Morgan) Höhn., Periconia cambrensis E.W. Mason et M.B. Ellis, Heteroconium 
chaetospira (Grove) M.B. Ellis were also present on the numerous woody remnants 

Ta b l e  4
Some complexes of myxomycetes and wood inhabiting fungi on woody substrata differenti

ated by size

Myxomycete species Species of wood inhabiting fungi
Associated complexes on large fallen tree trunks

Arcyria denudata 
Fuligo septica 
Lycogala epidendrum 
Stemonitis fusca 
Stemonitis flavogenita Jahn
Trichia scabra 
Trichia varia 

Ceratostomella cirrhosa, C. ampullasca (Cooke) 
Sacc., Nectria coccinea (Pers.) Fr., N. peziza, 
Lasiosphaeria hirsuta, L. ovina, Melanomma 
pulvis pyrius, Coniochaeta ligniaria (Grev.) 
Massee, Rosellinia conglobata, Xylaria longipes,  
Strickeria kochii, Dasyscyphus virgineus S.F. Gray, 
Bisporella citrina,  Mollisia  melaleuca, Orbilia 
coccinella, Trichophaeopsis bicuspis, Calocera 
cornea,  Fibuloporia  mucida,  Stereum hirsutum, 
Fomes fomentarius,  Marasmius alliaceus (Jacq.) 
Fr., Oudemansiella sp., Armillaria mellea (Vahl.) P. 
Kumm.,, Pleurothecium recurvatum,  Pseudospiropes 
subuliferus (Corda) M.B. Ellis, Acrogenospora 
sphaerocephala (Berk. et Broome) M.B. Ellis, 
Graphium calicioides (Berk.) Cooke et Massee

Lycogala epidendrum 
Metatrichia vesparium
Stemonitis fusca 
Trichia varia 

Lasiosphaeria hirsuta, Nectria peziza, Melomastia 
mastoidea (Fr.) Schroet., Melanomma pulvis
pyrius,  Chaetosphaeria ovoidea Sacc., Mollisia 
melaleuca, Bisporella citrina,  Xylaria polymorpha, 
Calocera cornea,  Bjerkandera adusta (Willd. Ex Fr.) 
P. Karst., Stereum hirsutum,  Fomes fomentarius,   
Pleurotus ostreatus (Jacq.) P. Kumm., Pleurothecium 
recurvatum, Periconia cambrensis

Arcyria denudata
Comatricha laxa Rost.
Hemitrichia calyculata (Speg.) Farr
Hemitrichia clavata (Pers.) Rost.
Lycogala epidendrum
Stemonitis fusca
Symphytocarpus amaurochaetoides
Trichia scabra
Trichia varia

Melanomma pulvis pyrius
Rosellinia conglobata
Lasiosphaeria hirsuta
Bisporella citrina
Trichophaeopsis bicuspis
Fomes fomentarius

Associated complexes on fallen branches of trees
Trichia decipiens Ceratostomella cirrhosa, Mollisia melaleuca, Orbilia 

coccinella, Microthelia incrustans (El. et Ev.) Corlet 
et S. Hughes as anamorph Dendryphiopsis sp.

Arcyria cinerea (Bull.) Pers. Nectria coccinea, N. peziza, Eutypa lata (Pers.) Tul. et 
C. Tul., Orbilia coccinella, Trichophaeopsis bicuspis

Hemitrichia clavata
Trichia decipiens

Rosellinia conglobata, Chaetosphaeria ovoidea, 
Mollisia melaleuca, Calocera cornea

Associated complexes on the stumps
Comatricha nigra
Enerthenema papillatum

Hypocrea citrina (Pers.) Fr.,  Mollisia lignicola Phill., 
Stereum hirsutum

Ceratiomyxa fruticulosa
Trichia decipiens

Lasiosphaeria hirsuta, Amphisphaeria umbrina, 
Mollisia cinerea

Lycogala epidendrum Bisporella citrina, Stereum hirsutum, Brachysporium 
nigrum



108 I. O. Dudka and K. O. Romanenko 

of various sizes, but these fungi were rare in comparison with the dominant species: 
they were often represented by a single record in the reserve.

DISCUSSION

Interactions between myxomycetes and Latridiidae beetles on woody substrata

Outside Ukraine, Reticularia lycoperdon (Liceales, Reticulariaceae), various spe-
cies of the genus Stemonitis (Stemonitales, Stemonitaceae), in particular S. fusca, and 
more rarely Fuligo septica (Physarales, Physaraceae) are the most prevalent slime 
moulds in associations with the Latridiidae, while the genera Enicmus and Dienerella 
are the most wide-spread representatives of the family Latridiidae to be involved in 
associations with slime moulds (N e w t o n ,  S t e p h e n s o n  1990; S t e p h e n s o n  et 
al. 1994).

Within Ukraine, the same myxomycete and Latridiidae taxa were dominant in 
associations on the left bank. The myxomycete family Stemonitaceae (Stemonitales) 
was best represented, with 7 species from 5 genera, associated with 3 species of 
the Latridiidae, Enicmus rugosus being dominant (Tab. 1). Myxomycetes from the 
order Physarales were present in left bank Ukraine associations with the Latridi-
idae as follows (3 species from 2 genera and 2 families): Fuligio intermedia, F. septica 
(Physaraceae) and Mucilago crustacea (Didymiaceae). They were associated with 2 
species of the Latridiidae – E. rugosus and Latridius hirtus. Both beetle species were 
associated with each of the 3 Physarales species. Reticularia lycoperdon (Liceales) 
was found from 3 locations in association with Enicmus fungicola, E. rugosus and 
Melanophthalma sp. (distinguenda-group - an exact species identification was not 
possible from the females collected). Interestingly, R. lycoperdon has been widely 
reported as the basic myxomycete component in associations with the Latridiidae in 
many parts of the world.

Among the myxomycetes connected with Latridiidae beetles in our left bank sam-
pling sites, large aethalia (0·5-20 cm long and 0·1-3 cm thick) are typical for Reticularia 
lycoperdon, Fuligo intermedia, F. septica and Mucilago crustacea. Sporophores closely 
grouped in large and dense colonies are observed in species of the genus Stemonitis (espe-
cially S. fusca and S. splendens). Sporophores of Symphytocarpus amaurochaetoides tend 
to coalesce resulting in the formation of complex fruiting structures. The sporophores and 
aethalia of these slime moulds therefore provide sufficient spores to attract feeding by La
tridiidae beetles. Together with Stemonaria longa, Comatricha nigra and some other spe-
cies, they all have a long period of sporophore formation and the sporophores so formed 
then tend to be long-lasting. Furthermore, all of these slime mould species develop on 
woody substrata and have spores from 4-15 µm diam. with ornamented walls. They there-
fore have morphological, developmental and ecological characters which fit the criteria 
proposed by B l a c k w e l l  (1984) for slime moulds associated with beetles.

The presence of myxomycete spores in Latridiidae gut contents shows that these 
beetles eat not only true fungi but also myxomycetes, while our observations of La-
tridius hirtus kept alive in the laboratory in defined conditions showed that at least 
one species is able to complete its life cycle, apparently normally, with only aethalia 
of one myxomycete species, F. intermedia, as food.



 Co existence and interaction between myxomycetes 109

There are very few reports from other parts of the world of myxomycete feeding 
by Latridiidae beetles. A few individuals of an unknown species of Enicmus were col-
lected on colonies of Reticularia lycoperdon from four locations in Himachal Pradesh 
(India): the gut contents of two were analysed and spores of R. lycoperdon found in 
both. A few individuals of a previously undescribed species of Dienerella were dis-
covered on colonies of Stemonitis fusca from two locations in Himachal Pradesh: the 
guts content of an individual from each location were examined, and in both cases 
the guts were filled with spores of S. fusca (N e w t o n ,  S t e p h e n s o n  1990). Our re-
sults on for Latridiidae beetles and myxomycetes in Ukraine are entirely compatible 
with those observations. Our work therefore confirms that, in addition to the Cery-
lonidae, Leiodidae, Scaphidiinae (Staphylinidae), Sphindidae and some other beetle 
families, the Latridiidae also feed on myxomycetes.

There is some question about whether the Latridiidae are obligate or facultative 
feeders on myxomycetes. N e w t o n  and S t e p h e n s o n  (1990) considered their new 
species of Dienerella from India to be a facultative feeder. Results from the left bank 
of Ukraine suggest that Latridius hirtus, Enicmus rugosus and E. fungicola may be 
obligate feeders: L. hirtus, in particular, has been shown to be capable of completing 
its life cycle with only myxomycetes as a food supply. Corticarina truncatella, how-
ever, is more likely to be facultative: records on myxomycetes are rather rare, and it 
was usually found in forest litter, and on hay and other plant remains; furthermore 
gut content analysis shows this species can feed on fungal spores as well as those of 
slime moulds.

Use of myxomycetes by Latridiidae beetles extends beyond feeding: they may lay 
their eggs in sporophores, aethalia and plasmodia; large downy colonies of myxo-
mycetes may provide good cover for larvae and adults. The absence of myxomycete 
spores in guts of Melanophthalma sp. distinguenda-group beetles from colonies of 
Reticularia lycoperdon suggests that the association between these beetles and myxo-
mycetes is based on something other than a food chain - perhaps a spatial relation-
ship - although that needs further study.

Co-existence of myxomycetes with bryophytes on woody substrata

Decaying fallen trunks, logs, large branches, decomposing stumps are good sub-
strata for simultaneous development of a diverse biota, including slime moulds, liv-
erworts and mosses. Myxomycetes often occur on wood overgrown with bryophytes 
(S t e p h e n s o n ,  S t u d l a r  1985; S t e p h e n s o n ,  S t e m p e n  1994; S c h n i t t l e r , 
N o v o z h i l o v  1998; S c h n i t t l e r ,  S t e p h e n s o n ,  N o v o z h i l o v  2000; H ä r k ö n e n 
et al. 2002). Woody substrata covered with bryophytes provide favourable conditions 
for development of slime moulds, particularly on account of their high humidity 
(S t o j a n o w s k a ,  P a n e k  2004; N o v o z h i l o v  2005).

All slime mould species found in the reserve associated with mosses and liverworts 
are usually considered lignicolous or corticolous: Licea minima, Stemonitis fusca, 
Symphytocarpus amaurochaetoides and Trichia varia, usually collected from decaying 
wood (I n g  1999), were also found on that substratum in the reserve. Arcyria cinerea, 
Echinostelium arboreum, E. minutum, Macbrideola cornea, Perichaena vermicularis 
and Physarum cinereum are known as typical corticolous species (M i t c h e l l  1980). 
In our study area most of these corticolous species also were more often noted on 



110 I. O. Dudka and K. O. Romanenko 

bark of various trees (Tab. 2). Echinostelium arboreum was the exception. In the 
reserve, every collection was made on moss, predominantly Leucodon sciuroides but 
once Hypnum cupressiforme.

Didymium trachysporum and Physarum cinereum are well documented as species 
developing on plant remains in the litter (I n g  1999), but there is also a report of 
their occurrence in association with bryophytes (S t e p h e n s o n ,  S t u d l a r  1985). 
Our results from Crimea match this pattern exactly. Some slime mould species (Ar-
cyria cinerea, Echinostelium arboreum, E. minutum, Macbrideola cornea, Perichaena 
vermicularis and Physarum cinereum) developed on more than one bryophyte spe-
cies. This may be evidence that some associations between myxomycetes and bryo-
phytes are purely accidental, arising because slime moulds and bryophytes are both 
well-adapted to develop on the same substrata (bark or wood). The associations 
may, however, alternatively arise because bryophytes provide ideal protection and 
other ecological conditions in which slime moulds can complete their full life cycle 
from plasmodia to sporophores.

The relation between myxomycetes and bryophytes can be regarded as one of 
shared space. The bryophytes ensure temperature and humidity conditions suitable 
for slime mould development. Fluctuations of temperature and humidity are less 
inside the bryophyte thallomes than outside, so that the bryophytes function like 
a moist chamber for the slime moulds, providing favourable conditions for their 
development. This function benefits not only the myxomycetes but also the bac-
teria, algae and protozoa on which they feed (S t e p h e n s o n ,  S t e m p e n  1994). 
The myxomycetes produce sporophores and aethalia from plasmodia in the drier 
areas on the bryophyte open surfaces. Bryophytes associated with myxomycetes thus 
seem neither to benefit nor be damaged by them (S t e p h e n s o n ,  S t u d l a r  1985): 
bryophytes associated with slime moulds continue normal growth and reproduction, 
while the myxomycetes have a favourable biotope in the bryophytes communities. 
Interrelations between the bryophytes and the slime moulds are thus generally posi-
tive and may be classified as commensal: unilateral use of one species by another 
without damage.

Co-existence of myxomycetes and fungi on woody substrata

Large fallen tree trunks might be thought to provide the richest associations of 
slime moulds and wood-inhabiting fungi, but in fact most associations (34) were re-
corded on fallen branches (Tab. 3). Direct contact of fallen branches with soil allows 
water to accumulate in the wood. Shade and grass cover makes loss of humidity from 
fallen branches and temperature fluctuations in the lower layer of forest vegetation 
less than from large fallen trunks and stumps. The hydrothermal regime of the fallen 
branches and their location positively influenced formation of a significant number 
of associations between myxomycetes and wood-inhabiting fungi. Such associations 
on woody substrata of various sizes and volumes are not directly connected and can 
exist independently. The biotic relations within those associations can therefore be 
characterized as neutral.

Species diversity in myxomycete / fungal associations on woody substrata can be 
compared according to size and volume of the substrata sampled (Tab. 4). One pos-
sible explanation for the correlation between species diversity and size (diameter) 



 Co existence and interaction between myxomycetes 111

of the woody substratum may be that larger woody remnants conserve water longer 
thus providing both myxomycetes and wood inhabiting fungi with better conditions 
for development. Substratum size may also determine the amount and availability of 
nutrients necessary for growth and formation of fruitbodies.

CONCLUSIONS

Co-existence and interaction between slime moulds, beetles, bryophytes and 
fungi have specific features for every pair of interacting organisms: at one end, the 
Latridiidae may be either obligate or facultative feeders on slime moulds; at the oth-
er, relations between slime moulds and wood-inhabiting fungi are neutral. Further 
studies are necessary to clarify the mechanisms regulating these biotic relations.

Acknowledgements: We would like to thank Dr Tetiana Trikhleb from the National University in Donetsk 
(Ukraine) for identification of Latridiidae, and Dr Svitlana Nyporko from the Department of Lichenology 
and Bryology, M.G. Kholodny Institute of Botany NASU in Kyiv (Ukraine) who helped with identifica
tion of bryophytes. Our special thanks to David Minter (Egham) for his critical reading the paper and 
checking English.

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Współistnienie i interakcje pomiędzy śluzowcami a innymi organizmami

S t r e s z c z e n i e

W artykule podane są wyniki badań mikoekologicznych na terenie Krymu i Ukrainie Le
wobrzeżnej. Określono status taksonomiczny śluzowców, które współistnieją z owadami z ro
dziny Latridiidae (Coleoptera), mchami, grzybami: Ascomycota, Basidiomycota i grzybami 
anamorficznymi. Badania stosunków śluzowców i owadów z rodziny Latridiidae w stepowych 
regionach Ukrainy Lewobrzeżnej ukazały istnienie troficznego związku owadów i śluzowców. 
W koloniach 13 gatunków śluzowców, wśród których przeważały: Stemonitis axifera, S. fusca, 
S. splendens, Fuligo septica i Mucilago crustacea, występowało 5 gatunków owadów z rodziny 
Latridiidae. Analiza treści żołądkowej ukazała istnienie zarodników śluzowców w przewodach 
pokarmowych 19 z 25 przebadanych osobników. Stwierdzono, że owady Latridium hirtus, En
cimus rugosus, E. fungicola są myxomycetofagami obligatoryjnymi, a Corticarina truncatella 
może być uważany za myxomycetofaga fakultatywnego. 12 gatunków śluzowców podanych 
było z powierzchni 12 gatunków mchów, które rozwjiały się na butwiejącym drewnie lub na 
korze w Krymskim Rezerwacie Przyrody. Stosunki śluzowców i mchów, wspólnie rosnących 
w Rezerwacie, na jednym drzewnym substracie są scharakteryzowane jako topiczne. Są one 
regulowane przez specyficzne mikroklimatyczne warunki, które tworzą się w środku mchów  
z wysoką wylgotnością. Stwierdzono wspólne występowanie 69 gatunków śluzowców z 36 ga
tunkami workowców, 21 gatunkami podstawczaków, 9 gatunkami anamorficznych grzybów. 
Analizowany skład asocjacji, które tworzą śluzowce z grzybami zależy od rozmiarów i objęto
sci substratów drzewnych.


		2014-01-01T11:43:46+0100
	Polish Botanical Society