Wood-inhabiting fungi on pedunculate oak coarse woody debris 
in relation to substratum quantity and forest age

Reda IRšėnaItė1 and eRnestas KutoRga1, 2

1Laboratory of Mycology, Institute of Botany  
Žaliųjų ežerų 49, Lt-08406 Vilnius, reda.irsenaite@botanika.lt 

2department of Botany and genetics, Faculty of natural sciences, Vilnius university 
M.K. Čiurlionio 21/27, Lt-03101 Vilnius, ernestas.kutorga@gf.vu.lt

I r š ė n a i t ė  R., K u t o r g a  e.: Wood-inhabiting fungi on pedunculate oak coarse woody debris 
in relation to substratum quantity and forest age. acta Mycol. 42 (2):169-178, 2007.

Wood-inhabiting fungi on pedunculate oak (Quercus robur) coarse woody debris (CWd) 
was investigated in 50 plots of 0.1 ha in oak stands of different ages in Lithuania. In maturing 
stands (50-120 years) the average volume of oak CWd was 4.7 m3/ha, and in mature stands 
(over 120 years) – 13.9 m3/ha. Both in maturing and mature stands, the greatest fraction of 
CWd consisted of fallen oak branches (81 % and 84 % respectively), whereas fallen trunks 
comprised about 10 % of the total units of CWd. In total 1350 records of 203 species (49 
ascomycetes and 154 basidiomycetes) were collected during 2 years of investigation. species 
richness and abundance increased significantly with the increase of volume and abundance of 
CWd. Higher species richness was detected in mature stands than in maturing ones. Wood-
inhabiting species composition varied greatly at stand scale, and one third of all detected 
species occurred only in one plot. Red-listed fungi were found only in mature stands. We 
conclude that, even in managed oak stands, oak CWd maintains a rather diverse species 
composition of ascomycetes and basidiomycetes. However, the current practice of forestry in 
Lithuania of removing dying or dead wood of large volume, e.g. standing and fallen trunks, 
reduce the distribution of highly specialized, usually rare, and endangered fungi. 

Key words: Xylotrophic fungi, coarse woody debris, Quercus robur, fungal conservation

IntRoduCtIon

Large pieces of dead rotting fallen trunks, branches and stumps, which charac-
terize coarse woody debris (CWd), are substantial components in forest ecosystems 
(H a r m o n  et al. 1986). there is no doubt that woody debris plays an essential role 
in creating habitats for many saproxylic organisms, including wood-inhabiting fungi 
(B o d d y  2001; s i i t o n e n  2001). the diversity and frequency of wood-inhabiting 
fungi depend on the stage of wood decay (n i e m e l ä , R e n v a l l , P e n t i l l ä 1995; 

 aCta MYCoLogICa
 Vol. 42 (2): 169-178
 2007

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



170 R. Iršėnaitė and e. Kutorga 

R e n v a l l  1995; L i n d b l a d  1998) and in general considered to be greater on large- 
diameter woody debris (B a d e r , J a n s s o n , J o n s s o n  1995; H ø i l a n d ,  B e n d i k s e n 
1997; K r u y s  et al. 1999). Recent studies indicate that forest management and frag-
mentation in boreal coniferous forests have greatly affected the diversity of wood-in-
habiting fungi, especially the occurrence of rare species (s i p p o l a ,  R e n v a l l  1999; 
L i n d g r e n  2001; P e n t t i l ä , s i i t o n e n ,  K u u s i n e n  2004). studies dealing with 
temperate broadleaved forests have also analyzed the relationship between fungal 
species diversity (both basidiomycetes and ascomycetes) and woody debris quantity/
quality (R u n g e  1975; L a n g e  1992; H e i l m a n n - C l a u s e n ,  C h r i s t e n s e n  2004; 
n o r d é n  et al. 2004), some environmental factors (H e i l m a n n - C l a u s e n  2001), 
and stand structure/age (n o r d é n ,  P a l t t o  2001).

as in most parts of europe, the old-growth temperate broadleaved forests 
in Lithuania have been fragmented to rather small fractions (P e t e r k e n  1996; 
K e n s t a v i č i u s  1997), and intensive forest management has endangered many 
organisms, including fungi, associated with oak (s u n h e d e ,  Va s i l i a u s k a s  1996, 
2003). out of total 40 red-listed wood-inhabiting fungi in Lithuania (a n o n y m o u s 
2005), more than 10 species are confined to the pedunculate oak (Quercus robur), 
both ecologically and economically important tree species in Lithuania. Quercus 
robur stands occupy about 33600 ha, i.e. 1.8 % of the total forest area in Lithuania 
(n a v a s a i t i s  et al. 2003), and they usually grow intermixed with other deciduous 
or coniferous trees.

the main focus of most mycological studies on oak wood in Lithuania has been 
species composition and distribution, and the quantity and quality of CWd has not 
usually been considered. Moreover, there is no up to date and generally available 
information on the amount of woody debris in Lithuanian forests. the first attempt 
to examine fungi and CWd in various coniferous and deciduous unmanaged stands 
of 40-130 years old is that of Va s i l i a u s k a s  et al. (2004). they found the volume 
of CWd of different tree species to be larger in older stands than in younger ones, 
demonstrated the variation of structural characteristics of CWd, and recorded 41 
species of wood-decomposing polypores. nevertheless, their sampling of oak CWd 
was too limited to draw conclusions about distribution patterns, and the oak wood-
decomposing fungi were not specified. 

therefore, in this study we examined the present status of CWd of oak and the 
diversity of fungi associated with it. the study focuses on wood-inhabiting ascomyc-
etes and basidiomycetes on coarse woody debris in managed oak dominated stands 
of different age. the list of recorded species and the analysis of fungal composi-
tion on wood of different decay stage are presented in separate paper (I r š ė n a i t ė , 
K u t o r g a  2006). the aim of this paper was to analyse the species richness of oak 
wood-inhabiting fungi with respect to quantitative and structural features of CWd 
in maturing and mature oak stands. 

MateRIaL and MetHods

Study sites and plots. ten study sites were selected in different parts of Lithuania 
(Fig. 1) according to the forest management documents and maps. study sites 1-2, 
5-8 and 10 comprised of forests growing on mezotrophic humid soil and dominated 
by pedunculate oak (Quercus robur). the co-existing tree species are Picea abies, 



 Wood-inhabiting fungi 171

Populus tremula, Tilia cordata and Fraxinus excelsior. the bush layer is moderately 
thick and consists mainly of Corylus avellana, Lonicera xylosteum, Frangula alnus and 
Sorbus aucuparia. sites 3 and 4 comprised forests on mezotrophic dry soil, domi-
nated by both Quercus robur and Pinus sylvestris, and with a sparse shrub layer of Co-
rylus avellana and Sorbus aucuparia. site 9 is an abandoned oak-wood pasture with 
solitary Corylus avellana. Local foresters´ information and cut stumps we observed 
indicate that all sites were more or less managed during the last 50 years, mostly by 
thinning or removing dead trees.

the study comprised two oak stand age groups: I, – maturing (50–120 years); 
and II, – mature (over 120 years). according to the study site size, from one to nine 
circular study plots of 0.1 ha were randomly selected. In total, we surveyed 50 plots 
(25 in each age group). 

Examination of CWD. the method for the examination of CWd was prepared 
according to K r u y s  et al. (1999). Within each plot, all fallen and standing dead 
oak wood with the base 5 cm in diameter and more and over 30 cm in length was 
investigated. the following characteristics were recorded for each unit of dead wood 
that harboured a fungus: category of CWd (lying trunk, snag, stump, branch), maxi-
mum (base) and minimum (top) diameter (m), length (m), and decay stage (ds). 
Five CWd decay stages were defined following a modified classification of R e n v a l l 
(1995). If the stage of decomposition varied in different parts of a trunk, an average 
decay stage was considered. CWd volume was calculated by the smalian’s formula 
(P e t t e r s o n , W i a n t , Wo o d  1993). 

Sampling and identification of fungi. the fieldwork was undertaken in 2001–
2002 during the main period of fruit body production (august–october) in both 
those years, with a single visit at each plot (up to 3 hours). Both basidiomycetes 
and ascomycetes were inventoried. Recorded species were arranged into these fun-
gal groups: discomycetes, pyrenomycetes and loculoascomycetes, agarics (including 
cyphelloid fungi), corticioid fungi (including thelephoroid fungi), gasteromycetes, 
heterobasidiomycetes, polypores (including Ramaria). these commonly used fungal 
groups are based on fruit body types, and are not taxonomical groups reflecting phy-
logenetic relationships. a species found on a single unit of wood was considered as 

Fig. 1. the location of the study sites in Lithuania: 1, Kreiviškės; 2, Plikoji sala; 3, Minijos kilpa; 
4, šilas; 5, gojus; 6, drausgiris; 7, subartonys; 8, Ąžuolija; 9, ginučiai; and 10, dūkštos.



172 R. Iršėnaitė and e. Kutorga 

one record, regardless of the number of observed fruit bodies. easily recognizable 
species were identified in the field, and about 1000 specimens were collected for 
microscopic examination. Voucher specimens are preserved in the Herbarium of the 
Institute of Botany, Vilnius (BILas). 

Data analysis. differences in number of species and abundance and the amount 
and volume of CWd in different age stands were tested for significance using a 
non-parametric Mann-Whitney u-test. CWd profile was quantified by summarizing 
the volume of CWd in a 2-way cross-table of maximum diameter and decay stages 
(s t o k l a n d  2001). the Chi-squared test was used to examine differences in the 
distribution of fungal groups and CWd decay stages. the shannon diversity index 
(H’) was used to evaluate the diversity of decay stages of CWd in the study plots. 
the first-order jackknife estimator was used to calculate true species richness (Z a r 
1999). dissimilarity in species composition between study plots in one study site was 
calculated with the sørensen distance measure, and spearman’s rank correlation 
coefficient (rs) was used to express the correlation between different variables. all 
statistical analyses were run using statIstICa 6.0 (s t a t s o f t  I n c  2001) and PC-
oRd 4.0 software (M c C u n e ,  M e f f o r d  1999).

ResuLts

Characteristics of CWD. In total 321 units (46.5 m3) of oak coarse woody debris 
were recorded across all study plots, taking both years together. the mature stands 
had significantly more CWd (203 units; 34.8 m3) than the maturing ones (118 units; 
11.7 m3) (Mann-Whitney u-test; p<0.001). there was large variation in CWd vol-
ume within plots, from 0.01 m3 to 5.61 m3 in maturing stands, and from 0.25 m3 
to 7.12 m3 in mature stands. data on average characteristics of CWd are given in 
table 1.

the Chi-squared test indicates that volume of CWd of different decay stage is 
distributed in the same proportions in maturing and mature stands (χ2 = 4.62; df = 
4; α = 0.05). the CWd patterns with respect to dimensions and decay stages shown 
in table 2, 3.

Fallen branches comprised the largest proportion of the total units of CWd, both 
in maturing (81 %) and in mature stands (84 %). the proportion of lying oak trunks 
was respectively only 9 % and 10 %. stumps and snags formed the minority of all 
recorded CWd.

Species richness. In total 1350 records of 203 species (49 ascomycetes and 154 
basidiomycetes) were collected over the period of investigation. Four species (2 %) 

ta b l e  1 
Characteristics of the CWd, the number of records and fungal species  

(mean ± standard deviation) in study plots

stand age 
group

n no. of CWd 
units per ha 

Diamc of 
CWd (m)

Volume of 
CWd (m3/ha) 

no. of records 
per ha 

no. of species 
per ha

I a 25 47.2 (±17.7) 0.17 (±0.12) 4.7 (±11.4) 199.6 (±98.1) 157.2 (±73.7)
IIb 25 81.2 (±27.1) 0.22 (±0.07) 13.9 (±15.8) 338.0 (±107.2) 262.8 (±81.8)

explanations: a maturing stands; b mature stands; c base diameter of the CWd unit.



 Wood-inhabiting fungi 173

were found in more than half of the study plots, while 67 species (33 %) were found 
only in one. the most frequently encountered species (more than 30 records) were 
Eriopezia caesia, Humaria hemisphaerica, Hyphodontia quercina, Hymenochaete ru-
biginosa, Mollisia cinerea, Nemania serpens, Phanerochaete velutina and Schizopora 
paradoxa. two species, Fistulina hepatica and Xylobolus frustulatus, listed in the 
Lithuanian Red data Book (a n o n y m o u s  2005) were also found.

there was large variation in species numbers within plots in maturing stands 
(range 7 to 37 species) and in mature stands (range 11 to 43), but the number of spe-
cies in mature stands (167) was significantly higher than in the maturing ones (134) 
(Mann-Whitney u-test; p = 0.001). the mean number of species and records per 
ha in study plots are shown in table 1. thirty-six species were exclusive to maturing 
stands, and 69 to mature stands. nearly half (48 %) of all species were common to 
stands of both age groups. the total number of records made was significantly great-
er in mature stands than in maturing ones (Mann-Whitney u-test; p<0.001), but a 
comparison of distribution proportions of the species in the different fungal groups 
in maturing and mature stands revealed similar patterns of occurrence (χ2 = 11.5; 
df = 6; α = 0.05). the number of records of corticioid fungi and discomycetes in ma-
ture stands were almost twice as high as that in maturing ones, although the number 
of species in both stands were nearly the same (tab. 4). Polypores, gasteromycetes 
and heterobasidiomycetes were much less abundant in comparison with other fungal 
groups. as shown in table 5, species composition varied greatly between plots even 
within a single study site (dūkštos forest), but it was more similar in plots of the 
same age group. 

ta b l e  2 
the volume of CWd (m3 per ha) in maturing stands in a CWd profile based on their maxi-

mum (base) diameter and decay stage

D
ec

ay
 s

ta
ge

I - 0.05 - - - - - - - - - -
II 0.02 0.14 0.03 0.02 0.09 - 0.02 - - - - -
III 0.04 0.16 0.10 0.15 - - 0.15 - - - - -
IV 0.06 0.35 0.38 0.19 - 0.58 - 0.05 1.95 - - -
V 0.01 0.03 - - 0.02 - - - - - - -

   5 10 20 30 40 50 60 70 80 90 100 110 120
Base diameter (cm)

ta b l e  3 
the volume of CWd (m3 per ha) in mature stands in a CWd profile based on their maxi-

mum (base) diameter and decay stage

D
ec

ay
 s

ta
ge

I - 0.02 0.03 - - - - - - - - -
II 0.01 0.07 0.16 0.07 0.02 - - - - - - -
III 0.08 0.88 0.64 0.31 1.66 0.21 1.61 0.09 - 0.09 - -
IV 0.09 0.74 0.62 1.33 2.01 0.99 0.92 0.05 - - - 0.39
V 0.01 0.50 0.09 0.03 - - 0.11 0.12 - - - -

   5 10 20 30 40 50 60 70 80 90 100 110 120
Base diameter (cm)





 Wood-inhabiting fungi 175

the estimation of species richness by the jackknife estimator indicated that the 
actual number of species present should be higher than those recorded. In plots of 
age group I and II, 70 % and 73 % respectively of the estimated number of species 
were recorded.

Patterns of relationships. significant positive correlations were found between 
the abundance and richness of fungal species and CWd variables (tab. 6). the 
number of species and records showed a higher correlation with the volume of CWd 
than with the number and average diameter of CWd units. no significant correla-
tion between diversity of decay stages in the study plots and species abundance was 
revealed. However, there was a significant correlation between the mean dBH of 
living oaks, an expression of the oak’s age, and the variables measured.

dIsCussIon

Coarse woody debris of pedunculate oak. In Lithuania the average volume of 
Quercus robur CWd in mature oak stands (13.9 m3/ha) is three times higher than 
in maturing ones (4.7 m3/ha). this corresponds closely with the volume of CWd 
in switzerland: 13.8 m3/ha in natural oak forests, and 5.3 m3/ha in managed ones 
(B r e t z ,  g u b y  and d o b b e r t i n  1996). abandoned oak wood-pastures with high 
biodiversity conservation value in sweden are on average 100-160 years old and con-
tain only 5 m3/ha of coarse and 1.9 m3/ha of fine oak woody debris (n o r d é n  et al. 
2004). the average volume of CWd of managed mature deciduous forests in en-
gland (12–23 m3/ha) and Poland (10 m3/ha) is comparable to that of mature forests 
in Lithuania, but the calculated average volume of wood debris of natural deciduous 
forests in Poland is several times higher (94 m3/ha) (K i r b y , We b s t e r ,  a n t c k z a k 
1991). Comparison of these data shows that different amounts of CWd are affected 
by forest type, age, and management intensity. the important feature of our study 
plots was the abundance of fallen oak branches and the lack of large dead trunks. 
the volume of CWd of various decay stages was distributed in the same propor-
tions in mature and maturing stands, and in both stands low CWd abundance and 
multiply gaps were observed from CWd profile. the extremely small amount of re-
cently fallen woody debris (< 1 m3/ha) and very small amount of large diameter and 
strongly decayed wood indicates constant management in oak stands. 

Fungal species richness and composition. the diversity of wood-inhabiting spe-
cies on oak CWd in our study plots was high, and according to jackknife estimator 
it could be one third more in stands of both age group. to f t s  and o r t o n  (1998) 
stated that investigation of all species is hardly achievable in mycological inven-
tories, unless the investigated community is very homogenous, as in the corticioid 
fungal community on Alnus glutinosa (K ü f f e r ,  s e n n - I r l e t 2000). Most recorded 
species are not confined to oak wood, but can also fructify on wood of other decidu-
ous trees, and to a lesser extent also on wood of coniferous trees. some of them, 
like tomentelloid fungi, are not saprotrophs but ectomycorrhizal species, using oaks 
wood only as living habitat. Comparison of taxonomical structure of fungi on oak 
debris detected in this study with other related data is difficult because different 
sampling methods. L i n d h e , Å s e n b l a d  and to r e s s o n  (2004) investigated only 
cut Quercus robur logs and reported that the logs harboured 53 fungal species, where 



176 R. Iršėnaitė and e. Kutorga 

the agarics comprised 45 %, corticioid fungi 13 %, and polypores 11 %. our results 
(47 % of corticioid) are consistent with the data on fungi on coarse and fine woody 
debris in sweden (n o r d é n  et al. 2004), where the corticoid fungi also predomi-
nated (50 %). 

Comparison of maturing and mature stands. the number of species and occur-
rence rate of wood-inhabiting fungi correlated positively not only with the CWd 
amount and volume, but also with dBH of living oak, as expression of stand age. 
therefore, significantly more abundance of species was recorded in mature stands 
than in maturing ones. With a larger volume of CWd, higher numbers of wood-
inhabiting fungal species could be expected. thus, if in maturing stands the volume 
of CWd was larger the greater species richness of wood-inhabiting fungi would be 
expected. despite the proportions of fungal groups being similar in stands of dif-
ferent age groups, the differences in species composition between mature and ma-
turing plots as well as between plots of same age group were obvious. the number 
of unique species in mature stands was twice as high as in maturing ones, and red-
listed species were found only in mature stands, an observation consistent with other 
studies showing that the red-listed wood-inhabiting fungi prefer old-growth forests 
(s i p p o l a ,  R e n v a l l  1999; P e n t t i l ä  et al. 2004; Va s i l i a u s k a s  et al. 2004) and 
woody debris of large diameter (R e n v a l l  1995; K r u y s  et al. 1999; L i n d h e  et al. 
2004). In our study the occurrence of two red-listed species only in mature stands 
can be explained by the preference of Fistulina hepatica to large trunks or stumps, 
and of Xylobolus frustulatus to coarse branches or fallen trunks of old oaks. other 
red-listed species, such as Inonotus dryadeus, I. dryophilus, Piptoporus quercinus, Gri-
fola frondosa and Hapalopilus croceus, not found during our research are mostly 
confined to large old living oak trunks or recently fallen ones. Perenniporia medulla-
panis, specific to old oak stumps or snags, was also not recorded in study plots. this 
large diameter woody debris was remarkably scarce in both maturing and mature 
stands, which may have determined the low proportion of not only red-listed species, 
but of common polypores detected. 

ConCLusIons

our results confirm that wood-inhabiting fungal species richness depends on the 
amount of CWd. the average amount of CWd in managed mature oak stands in 
Lithuania is 13.9 m3/ha. In accordance with similar studies (K i r b y  et al. 1991) it is 
evidently advisable to maintain not less than 20 m3/ha of woody debris in temperate 
broadleaved stands. 

Fallen branches comprise the largest fraction of oak CWd and greatest diversity 
of fungi species. However, large fallen trunks should be maintained in stands as 
well, because this valuable substrate is usually heterogeneous and comprises less or 
more decayed parts, and remnants of bark and branches; such substrate is especially 
important for rare polypores. 

We conclude that, even in managed oak stands, oak CWd maintains a rather di-
verse species composition of ascomycetes and basidiomycetes. although in general 
the highest species richness was detected in mature stands in our study, the spe-
cies richness more correlated with the amount of CWd then with stand age itself. 



 Wood-inhabiting fungi 177

some maturing stands with a high amount of CWd, there were nearly as many or 
even more fungi than in particular mature stands. However, a very small amount of 
freshly fallen wood and strongly decayed woody debris, especially of large diameter 
trunks, and gaps in CWd continuity both in mature and maturing stands indicates 
long lasting management practices in Lithuanian oak stands, which reduce the dis-
tribution of highly specialized, usually rare, and endangered fungi. 

Acknowledgements. We thank nils Hallenberg (gothenburg) and urmas Kõljalg (tartu) for help in de-
termining various critical specimens. We are also grateful to david L. Hawksworth (Madrid) for the 
suggestions to improve the manuscript and linguistic revision of the manuscript. the study was financially 
supported partly by the Lithuanian state science and studies Foundation and the swedish Institute.

ReFeRenCes

a n o n y m o u s  2005. dėl aplinkos ministro 2003 m. spalio 13 d. įsakymo nr. 504 “dėl į Lietuvos 
raudonąją knygą įrašytų saugomų gyvūnų, augalų ir grybų rūšių sąrašo patvirtinimo” pakeitimo. 
Valstybės žinios 79: 2784.

B a d e r  P., J a n s s o n  s., J o n s s o n  B.g. 1995. Wood-inhabiting fungi and substratum decline in selec-
tively logged boreal spruce forests. Biol. Cons. 72: 355−362.

B o d d y  L. 2001. Fungal community ecology and wood decomposition processes in angiosperms: from 
standing tree to complete decay of coarse woody debris. (In:) B.g. J o n s s o n , n. K r u y s  (eds). 
ecology of wood debris in boreal forests. ecol. Bull. 49: 43−56. Blackwell science, oxford.

B r e t z  g u b y  n.a., d o b b e r t i n  M. 1996. Quantitative estimates of coarse woody debris and standing 
dead trees in selected swiss forests. global ecol. Biogeogr. 5: 327−341.

H a r m o n  M.e., F r a n k l i n  F.J., s w a n s o n  F.J., s o l l i n s  P., g r e g o r y  s.V., L a t t i n  J.d., a n d e r s o n 
n.H., C l i n e  s.P., a u m e n  n.g., s e d e l l  J.R., L i e n k a e m p e r  g.W., C r o m a c k  K., C u m m i n s 
K.W. 1986. ecology of coarse woody debris in temperate ecosystems. adv. ecol. Res. 15: 133−302.

H e i l m a n n - C l a u s e n  J. 2001. a gradient analysis of communities of macrofungi and slime moulds on 
decaying beech logs. Mycol. Res. 105: 575−596.

H e i l m a n n - C l a u s e n  J., C h r i s t e n s e n  M. 2004. does size matter? on the importance of vari-
ous dead wood fractions for fungal diversity in danish beech forests. Forest ecol. Manag. 201: 
105−117.

H ø i l a n d  K., B e n d i k s e n  e. 1997. Biodiversity of wood-inhabiting fungi in boreal coniferous forest in 
sør-trøndelag County, Central norway. nord. J. Bot. 16: 643−659.

I r š ė n a i t ė  R., K u t o r g a  e. 2006. diversity of fungi on decaying common oak coarse woody debris. 
ekologija 4: 22–30.

K e n s t a v i č i u s  J. 1997. ažuolynų plotų kaita ir dabartiniai taksaciniai rodikliai. (In:) s. K a r a z i j a 
(ed.). Lietuvos ąžuolynai: išsaugojimo ir atkūrimo problemos: 21-26. Lututė, Kaunas.

K i r b y  J., We b s t e r  s.d., a n t c k z a k  a. 1991. effect of forest management on stand structure and 
quality of fallen dead wood: some British and Polish examples. Forest ecol. Manag. 43: 167−174.

K r u y s  n., F r i e s  C., J o n s s o n  B.g., L ä m å s  t., s t å h l  g. 1999. Wood-inhabiting cryptogams on 
dead norway spruce (Picea abies) trees in managed swedish boreal forests. Can. J. Forest Res. 29: 
178−186.

K ü f f e r  n., s e n n - I r l e t  B. 2000. diversity and ecology of corticioid basidiomycetes in green alder 
stands in switzerland. nova Hedwigia 71: 131−143.

L a n g e  M. 1992. sequence of macromycetes on decaying beech logs. Persoonia 14: 449−456.
L i n d b l a d  I. 1998. Wood-inhabiting fungi on fallen logs of norway spruce: relation to forest manage-Wood-inhabiting fungi on fallen logs of norway spruce: relation to forest manage-

ment and substrate quality. nord. J. Bot. 18: 243−255.
L i n d g r e n  M. 2001. Polypore (Basidiomycetes) species richness and community structure in boreal 

forests of nW Russian Karelia and adjacent areas in Finland. acta Bot. Fennica 170: 1−41.
L i n d h e  a., Å s e n b l a d  n., to r e s s o n  H.-g. 2004. Cut logs and high stumps of spruce, birch, aspen 

and oak – nine years of saproxylic fungi succession. Biol. Cons. 119: 443−454.
M c C u n e  B., M e f f o r d  M.J. 1999. PC-oRd. Multivariate analysis of ecological data. Version 4.0. 

MjM software, oregon.



178 R. Iršėnaitė and e. Kutorga 

n a v a s a i t i s  M., o z o l i n č i u s  R., s m a l i u k a s  d., B a l e v i č i e n ė  J. 2003. Lietuvos dendroflora. 
Lututė, Kaunas. 

n i e m e l ä  t., R e n v a l l  P., P e n t i l l ä  R. 1995. Interaction of fungi at late stages of wood decomposition. 
ann. Bot. Fennici 32: 141−150.

n o r d é n  B., P a l t t o  H. 2001. Wood-inhabiting fungi in hazel wood: species richness correlated to stand 
age and dead wood features. Biol. Cons. 101: 1−8.

n o r d é n  B., R y b e r g  M., g ö t m a r k  F., o l a u s s o n  B. 2004. Relative importance of coarse and fine 
woody debris for the diversity of wood-inhabiting fungi in temperate broadleaf forests. Biol. Cons. 
117: 1−10.

P e n t t i l ä  R., s i i t o n e n  J., K u u s i n e n  M. 2004. Polypores diversity in managed and old-growth boreal 
Picea abies forests in southern Finland. Biol. Cons. 117: 271−283.

P e t e r k e n  g.F. 1996. natural Woodland: ecology and Conservation in northern temperate Regions. 
Cambridge university Press, Cambridge.

P e t t e r s o n  d.W., W i a n t  H.V.J., W o o d  g.B. 1993. Log volume estimations: the centroid method and 
standard formulas. J. Forest. 91: 39−41.

R e n v a l l  P. 1995. Community structure and dynamics of wood-rotting Basidiomycetes on decomposing 
conifer trunks in northern Finland. Karstenia 35: 1−51.

R u n g e  a .  v o n  1975. Pilzsukzession auf Laubholzstümpfen. Zeitschrift für Pilzkunde 41: 31−38.
s i i t o n e n  J. 2001. Forest management, coarse woody debris and saproxylic organisms: fenoscandian bo-

real forests as an example. (In:) B.g. J o n s s o n , n. K r u y s  (eds), ecology of wood debris in boreal 
forests. ecol. Bull. 49: 243−254. Blackwell science, oxford. 

s i p p o l a  a.-L., R e n v a l l  P. 1999. Wood-decomposing fungi and seed-tree cutting: a 40-year perspec-
tive. Forest ecol. Manag. 115: 183−201.

s t a t s o f t  I n c . 2001. statIstICa (data analysis software system), Version 6. www.statsoft.com.
s t o k l a n d  J.n. 2001. the coarse woody debris profile: an archive of recent forest history and an impor-

tant biodiversity indicator. (In:) B.g. J o n s s o n , n. K r u y s  (eds). ecology of wood debris in boreal 
forests. ecol. Bull. 49: 71−83. Blackwell science, oxford.

s u n h e d e  s., Va s i l i a u s k a s  R. 1996. Wood and bark inhabiting fungi on oak in Lithuania. Baltic 
Forestry 2: 23−27.

s u n h e d e  s., Va s i l i a u s k a s  R 2003. Hotade tickor på ek i Litauen. svensk Bot. tidskr. 97: 252−265. 
to f t s  R.J., o r t o n  P.d. 1998. the species accumulation Curve for agarics and Boleti from Caledonian 

Pinewood. Mycologists 12: 98−102.
Va s i l i a u s k a s  R., Va s i l i a u s k a s  a. s t e n l i d  J., M a t e l i s  a. 2004. Dead trees and protected 

polypores in unmanaged north-temperate forest stands of Lithuania. Forest ecol. Manag. 193: 
355−370.

Z a r  J.H. 1999. Biostatistical analysis. upper saddle River, new Jersey.


		2014-01-01T11:46:00+0100
	Polish Botanical Society