Autofluorescence of ascospores and conidial spores in selected 
lichen species of the Opegrapha genus 

AnettA Wieczorek

Department of ecology, University of Szczecin 
Wąska 13, PL-71-415 Szczecin, anettaw@univ.szczecin.pl

Wieczorek A.: Autofluorescence of ascospores and conidial spores in selected lichen species of 
the Opegrapha genus. Acta Mycol. 43 (1): 99–103, 2008.

The paper presents findings of the research work on autofluorescence phenomenon in 
ascospores and conidial spores that was carried out on 12 selected species of the Opegrapha 
genus occurring in Poland.

Key words: lichens, Opegrapha, autofluorescence

introDUction

Autofluorescence is one of luminescence types and consists in emitting the own 
light, which is induced by photon capture by a body. Own luminescence of cells 
depends on the presence of endogenous chromophores in tissue. The phenomenon 
of autofluorescence is frequent not only in plants but also in fungi (Rost 1992). It 
has been observed, among others, in the cytoplasm of ascospore and konidial spore 
hyphae (Žižka, Gabriel 2006). Studies on the usefulness of autofluorescence meth-
ods in identification of fungi species are used in examination of mycorrhiza phe-
nomenon (Séjalon-Delmas et al. 1998) and in laboratory diagnostics, in particular 
of pathogenic fungi, and consist among other in determination of tissue colour dif-
ferences in healthy plants and animals and those pathologically changed (Margo, 
Bombardier 1985; Elston 2001). In lichens, autofluorescence phenomenon has been 
used, among others, in evaluation of the viability of hyphae and algal cells according 
to the method of their storage (Honegger 2003) as well as in evaluation of damages 
in the chlorophyll apparatus of algal cells induced by high pollutant concentration 
(Favali et al. 1991; Silberstein et al. 1996). Sometimes, this phenomenon can be used 
for determining germination capacity (Cathy, Warren 1984). This study aimed at 
taking up an attempt to use the autofluorescence phenomenon in identification of 
lichen species of the Opegrapha genus.

 ACTA MYCOLOGICA
 Vol. 43 (1): 99–103
 2008



100 A. Wieczorek 

MATERIAL AND METHODS

In the study were used selected epiphytic and epilitic species of the Opegrapha 
genus occurring in Poland (O. atra Pers., O. calcarea Sm., O. culmigena Lib., O. dolo-
mitica (Arnold) Clauzade & CL. Roux, O. gyrocarpa Flot., O. niveoatra (Borrer) J. 
R. Laundon, O. rufescens Pers., O. rupestris Pers., O. varia Pers., O. vermicellifera 
(Kunze) J. R. Laundon, O. viridis (Ach.) Behlen & Desberger, and O. vulgata (Ach.) 
Ach. Species terminology was adopted after Santesson et al. (2004) and Dietrich et 
al. (2008). In order to determine the intensity of autofluorescence, a series of mi-
croscope slides was prepared, 10 samples per each species, using the fresh material 
collected by the author from the bark of different tree species within the area of the 
western Poland in 2004-2006 as well as the herbarium material. The samples collect-
ed from the herbarium material were from 1940-2001. In order to examine in detail 
the subtle structures, such as ascospores and conidial spores, squashed microscope 
slides were prepared. In the study, a LSM 510 laser scanning microscope (Zeiss), 
operating on an Axiovert 200M motorised inverted microscope with fluorescence 
(Zeiss), was used. The used laser was an argon-ion laser with 11% power output, 
emitting 488 nm light waves, equipped with a 63x objective for ascospores and a 
100x objective for conidial spores and two red filters (between 505 nm–650 nm wave-
length) and one green filter (to 505 nm wavelength); when observing ascospores and 
conidial spores, a Nomarski filter was used.

RESULTS AND DISCUSSION

In all examined species, the emission of light within the wavelength range from 
488 nm to 505 nm, and sometimes over 650 nm, was found (Tab. 1). The examined 
taxa were separated into three groups with different fluorescence intensity. The as-
cospores of the following species were in the first group: O. atra (Fig. 1), O. calcarea, 
O. dolomitica (Fig. 2) and O. rupestris (Fig. 3), with the fluorescence intensity within 
both wavelength ranges being clearly observable. In the second group, the spores of 
O. gyrocarpa, O. vermicellifera, O. vulgata (Fig. 4), O. viridis and O. culmigena were 
found, the autofluorescence intensity of which was much weaker or almost com-
pletely inconspicuous. In case of the species of the second group, no expected effects 
were obtained despite intensification of autofluorescence with ultraviolet radiation. 
On the other hand, a more rapid burning of autofluorescence was observed after 
application of ultraviolet radiation.

Into the third group, the ascospores of such species as O. niveoatra, O. varia (Fig. 
5) and O. rufescens (Fig. 6) were included, in which a variable intensity of fluores-
cence was found. Different level of autofluorescence intensity in these species can be 
induced on the one hand by a different depth of spore location in microscope slide 
but on the other hand by a different degree of ascospore maturity.

It should be emphasised that observation of spores at the stage of transversal wall 
formation (Figs 7-9) in the taxa with weak autofluorescence showed the occurrence 
of such phenomenon.

In the species with intense autofluorescence, a fading of red light emission was 
observed as deeper spore layers were scanned due to autofluorescence burning.



 Autofluorescence of ascospores 101

No fundamental differences were observed in the intensity of spore fluorescence 
in microscope slides prepared both from the fresh and herbarium materials.

The conidial spores of all examined species showed similar autofluorescence, ir-
respective of the origin of the analysed material and their size (Figs 10-12).

The taken up research is the first attempt of using autofluorescence phenomenon 
for identification of lichen species of the Opegrapha genus. The carried out analyses 
showed the presence of endogenous chromophores in the cytoplasm of ascospres 
and conidial spores in all examined taxa. In the literature a correlation was showed 
between the fluorescence intensity and the viability, maturity degree and storage 
conditions of ascospores and conidial spores (Cathy, Warren 1984; Honegger 2003). 
It was also proved that the fluorescence intensity of algal cells changed depending 
on the degree of environmental pollution (Di Toppi et al. 2005) and other factors. 
In the work by Favali et al. 1991, not only changes in autofluorescence intensity 
connected with the harmful effect of such chemical elements as aluminium (Al), sili-
con (Si), phosphorus (P), sulphur (S), chlorine (Cl), and calcium (Ca) were demon-
strated but also differences were showed in the concentration of respective chemical 
elements in different elements of the thallus, including a considerable concentration 
of aluminium in the apothecia. It is not excluded that these stress factors could also 
affect the intensity of light emission in ascospores and conidial spores. Autofluo-
rescence depends also on the type and the amount of chromophore occurring in 
the cytoplasm. The carried out analyses of images show a variable autofluorescent 
response of ascospores in O. niveoatra, O. rufescens and O. varia. The spectrum of 
luminescence in the examined taxa may undergo changes and is not stable. Thus, it 
is difficult to determine simple criteria that would describe a given group of species, 
while autofluorescence intensity can not be a trait of diagnostic importance since 
it may be affected by many external factors. It appears thus that it is not a good 
method for identification of taxa, at least in that group of species. Nevertheless, it is 
worth expanding the research work on the usefulness of that method in taxonomic 
studies of other lichen and fungi genera.

Ta b l e  1 
Autofluorescence intensity of ascospores in selected lichen species of the Opegrapha genus

Species Light emission intensity within
wavelength range

488-659nm 488-505 nm
High Weak Very weak

O. atra Pers. +
O. calcarea Sm. +
O. dolomitica (Arnold) Clauzade & CL. Roux +
O. rupestris Pers. +
O. varia Pers. + +
O. rufescens Pers. + + +
O. niveoatra (Borrer) J. R. Laundon + +
O. gyrocarpa Flot. +
O. vermicellifera (Kunze) J. R. Laundon +
O. vulgata (Ach.) Ach. +
O. viridis (Ach.) Behlen & Desberger +
O. culmigena Lib. +



102 A. Wieczorek 

CONCLUSIONS

No fundamental taxonomic differences were found at the level of light emission 
intensity. The autofluorescent response of particular species results most probably 
from the size of spores and the same from the amount of cytoplasm inside them as 
well as from the degree of their maturity. As is showed by examinations, dead spores 
devoid of the cytoplasm as well as those being dormant do not show autofluores-
cence (Cathy, Warren 1984). The intensity of fluorescence in ascospores and conid-
ial spores in the genus Opegrapha does not seem to be a good method in taxonomic 
identification of particular species.

Acknowledgements. I would like to thank Aleksander Ratajczak, MSc, from the Laboratory of Electron 
and Confocal Microscopy of the Adam Mickiewicz University in Poznań for his assistance and kindness 
with carrying out microscope observations as well as Prof. Krystyna Czyżewska (University of Łódź) for 
her valuable suggestions and comments during preparation of this paper.

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 Autofluorescence of ascospores 103

Autofluorescencja zarodników workowych i konidialnych wybranych gatunków 
porostów z rodzaju Opegrapha

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

W pracy przedstawiono wyniki badań nad zjawiskiem autofluorescencji zarodników wor-
kowych i konidialnych wybranych gatunków porostów z rodzaju Opegrapha. Zaobserwowano 
i scharakteryzowano zjawisko autofluorescencji u 12 gatunków występujących w Polsce (O. 
atra, O. calcarea, O. culmigena, O. dolomitica, O. gyrocarpa, O. niveoatra, O. rufescens, O. rupe-
stris, O. varia, O. vermicellifera, O. viridis, O. vulgata). 

W badaniach wykorzystano laserowy mikroskop skaningowy LSM 510 (Zaiss) pracujący 
na odwróconym mikroskopie Axiovert 200M (Zaiss) z fluorescencją. Zastosowano laser argo-
nowy o mocy 11% wysyłający fale o długości 488 nm, obiektyw 63x dla zarodników workowych 
i 100x dla konidialnych oraz dwa filtry, czerwony o długości fal od 505 do 650 nm i zielo-
ny o długości, do 505 nm. Przy obserwacji zarodników wykorzystano filtr nomarskiego. Nie 
stwierdzono zasadniczych różnic taksonomicznych w poziomie intensywności emisji światła. 
Zaobserwowane różnice w intensywności świecenia poszczególnych gatunków wynikają praw-
dopodobnie z wielkości, a tym samym ilości cytoplazmy wewnątrz zarodników oraz stopnia 
ich dojrzałości. 

Po raz pierwszy opisano wykorzystanie zjawiska autofluorescencji w badaniach taksono-
micznych porostów z rodzaju Opegrapha. Zaprezentowano pierwsze zdjęcia tego zjawiska, 
które uzupełniają oryginalny opis rodzaju. 


		2014-01-01T11:47:32+0100
	Polish Botanical Society