Scientific Research Conducted at the Department of Mycology, University of Warmia and Mazury in Olsztyn


Acta Mycologica

Article ID: 5525
DOI: 10.5586/am.5525

Publication History
Received: 2020-06-15
Accepted: 2020-07-22
Published: 2021-02-05

Handling Editor
Wojciech Pusz; Wrocław
University of Environmental and
Life Sciences, Poland;
https://orcid.org/0000-0003-
1531-2739

Authors, Contributions
AB: concept for publication,
Chapter 2 preparation,
manuscript correction, final
manuscript revision; EE: Chapter
3 preparation; DK: Chapter 4
preparation, manuscript
correction, final manuscript
revision; ES: Chapter 5
preparation

Funding
This publication was financed by
the statutory funds of the
Department of Microbiology and
Mycology, Faculty of Biology and
Biotechnology, University of
Warmia and Mazury in Olsztyn.

Competing Interests
No competing interests have
been declared.

Copyright Notice
© The Author(s) 2020. This is an
open access article distributed
under the terms of the Creative
Commons Attribution License,
which permits redistribution,
commercial and noncommercial,
provided that the article is
properly cited.

REVIEW in MYCOLOGY

Scientific Research Conducted at the
Department of Mycology, University of
Warmia and Mazury in Olsztyn

Anna Biedunkiewicz
 

 

*, Elżbieta Ejdys
 

 

, Dariusz Kubiak
 

 

,
Ewa Sucharzewska

 

 

Department of Microbiology and Mycology, Faculty of Biology and Biotechnology, University
of Warmia and Mazury in Olsztyn, Poland

*To whom correspondence should be addressed. Email: alibi@uwm.edu.pl

Abstract
This paper presents a review of the research conducted by the staff of the
Department of Mycology at UWM, Olsztyn since its establishment to the
present. This unit was established and has been headed for over 20 years by Prof.
Maria Dynowska. Since 2004, the Department has been conducting extensive
mycological research, which is reflected in the dynamic growth of specialist
staff involved in teaching activities and popularizing scientific research. Owing
to the particular care of Prof. Dynowska, and maintenance of the principal
interdisciplinary character of the research, the Department has been occupying
a significant position in mycology in Poland recently. This paper attempts to
provide a summary of the major scientific accomplishments of the team headed
by Prof. Dynowska.

Keywords
potentially pathogenic fungi; aquatic ecosystem; school environment; urban
environment; lichenological studies; plant parasites; bioindication

1. Introduction

The Department of Mycology of the University of Warmia and Mazury in Olsztyn
was established on April 1, 2004. It was the product of the transformation of the
Department of Mycology established in 1996 from the Department of Botany at the
Institute of Biology and Environmental Protection, Faculty of Mathematics and Life
Sciences of the Teachers College in Olsztyn.
Prof. dr. hab. Maria Dynowska was appointed Head of the Department in 1996.
Initially, the research conducted at the department covered the issues of botany and
plant physiology in a broad sense. Over time, the subject matter evolved toward
pure mycology. In consequence, mycology was isolated from botany, and the
teaching offer was expanded to include obligatory and elective mycological subjects
(general and systematic mycology, lichenology, phytopathology, medical mycology,
hydromycology, mycosociology, mycoindication, mycological diagnostics, applied
mycology, etc.), whose status in the syllabus was adjusted to that of the major
subjects (biology, biotechnology, microbiology, and nursing), and two research
teams were appointed: The Ecology and Environment Monitoring Team and the
Applied Mycology Team. The teams included mycologists and botanists, who
prepared an assessment of the environment against which fungi were analyzed
(saprotrophs, phytopathogens, zoopathogens, anthropopathogens, and lichenized
fungi). Upon the establishment of the University of Warmia and Mazury in Olsztyn,
the scope of research was largely modified, and some of the staff of the Department
of Mycology were transferred to other University units. Owing to the initiative
of Prof. Dynowska, new research teams, viz., the Fungi and Lichens Monitoring
Team and the Medicinal and Applied Mycology Team, were appointed. These

Acta Mycologica / 2020 / Volume 55 / Issue 2 / Article 5525
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https://doi.org/10.5586/am.5525
https://creativecommons.org/licenses/by/4.0/
https://creativecommons.org/licenses/by/4.0/
https://orcid.org/0000-0003-3498-7432
https://orcid.org/0000-0002-5313-9247
https://orcid.org/0000-0001-7266-0647
https://orcid.org/0000-0001-6754-5994
mailto:alibi@uwm.edu.pl


Biedunkiewicz et al. / Scientific Research of the Department of Mycology (Olsztyn)

teams have operated throughout the history of the Department. The research was
interdisciplinary, and covered issues in mycology, microbiology, phytopathology,
lichenology, and ecology, with emphasis on the diversity of fungi in macro- and
microenvironments and the significance of fungi in bioindication (in a broad sense
of the term). It was conducted based on two multitask subjects:

• Biological and ecological factors that affect fungi diversity and expansiveness;
• Fungi and lichens against natural plant communities.

By presenting the findings of the research conducted at the Department via this
review paper, we wish to express our gratitude to Prof. Dynowska for her scientific
supervision, care for the development of our research, and continuous support for
our cooperation with various research centers. Each chapter was prepared by Prof.
Dynowska’s protégés, and presents diverse specialties of mycology.

2. Potentially Pathogenic Fungi Isolated from Waters and Their Application
in Bioindication

Research on the presence of fungi in various types of waters has been conducted
around the world since the 1960s. It has dealt with mycological environmental
monitoring in general terms (Cooke, 1965; Laundon, 1972), and resulted in the
development of standards of cleanliness in the USA and Canada, with fungi as
bioindicators of pollution in household, industrial, agricultural, and touristic
wastewater (American Society for Testing and Materials, 2005). Hydromycological
research in Poland has been conducted with regard to the number, species diversity,
and ecophysiology of fungi in waters of different trophic states, with attention also
being paid to potentially pathogenic species (Dynowska, 1995; Kurnatowski et
al., 2007). Continuous mycological monitoring of waters in north-east Poland was
initiated in the 1990s by Prof. Dynowska (Dynowska, 1993b, 1993d, 1995, 1997),
and it has been continued by her research team. The scope of research has
been expanded to include water bodies in the north-west (Biedunkiewicz et
al., 2007) and central parts of Poland (Biedunkiewicz & Ozimek, 2009; Ozimek
& Biedunkiewicz, 2008). The findings of the research not only explain the role
of microfungi in the trophic and energetic loops in water bodies, but also help
in identifying specific fungi with indicative properties, which can be used in
a multiaspect assessment of waters, especially regarding their sanitary and
epidemiological quality (Biedunkiewicz, 2011b; Dynowska, 1995, 1997).
The hydromycological research focused on microfungi (potential human pathogens)
present in different types of waters, their numbers and taxonomic differentiation
during all seasons of the year, and those with interesting epidemiological and
bioindicative features. Analyses were performed for tap and potable bottled
water (Biedunkiewicz et al., 2014; Biedunkiewicz & Schulz, 2012), and water
from places used for recreation, including municipal lakes and indoor swimming
pools (Biedunkiewicz, 2007a; Biedunkiewicz & Góralska, 2016; Biedunkiewicz et
al., 2007), as well as fountains situated in parks and at squares used by residents
for leisure (Biedunkiewicz, 2009). It was shown that, in the immediate vicinity of
bathing sites, the existing littoral zone retained yeasts (potential human pathogens)
on the phyllosphere surface. Long-term observations in one of the lakes in Olsztyn
have shown the presence of the same microfungi species in both habitats in 60% of
cases. The presence of many potentially pathogenic yeast species in the lake littoral
zone shows the huge impact of humans on the hydrosphere microbiological quality
(Biedunkiewicz et al., 2020).
The frequent presence of microfungi (including Candida albicans, C. tropicalis, C.
guilliermondii, and C. krusei) in waters used, in a variety of ways, by humans for
consumption or recreation has prompted observations of some ecophysiological
features of these fungi, such as the multiplication rate, enzymatic activity, and
pseudomycelium growth capability in controlled laboratory conditions, with the use
of modified media based on filtered water acquired from the natural environment,
and a photoperiod appropriate for the given environmental and daily temperature
fluctuations. One of the parameters – enzymatic activity – was tested before and

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after culturing four of the aforementioned fungi species in the laboratory. The
results showed that the microfungi retained a high physiological activity. Hence,
they should be entered in the list of pathogens whose presence in utility waters,
including thermal and recreational waters, disqualifies them from public use.
One cannot exclude the role of water as a habitat for potential pathogens, because
depending on the type, amount, and availability of organic matter, numerous fungi
species find favorable trophic conditions for development, which have a direct
impact on the metabolism rate (Biedunkiewicz, 2015). The study was conducted
as part of a research grant from the Ministry of Science/National Centre for Science,
entitled “Próba zastosowania grzybów potencjalnie chorobotwórczych dla człowieka
w standardowych metodach oceny czystości wód powierzchniowych [An attempt
to use fungi – potential human pathogens – in standard methods of surface water
cleanliness evaluation].”
As a permanent component of inland water microbiota, fungi were present
in all the types of water under study. However, an increase in their number
depended on the degree of anthropopressure and eutrophication. The eutrophic
lakes were found to contain numerous, frequently repetitive species of potential
pathogens or saprophytes; some fungi that had not been reported in the literature on
hydromycology were also isolated, viz., Candida kruisii and Dipodascus armillariae
(Biedunkiewicz & Baranowska, 2011).
The research conducted at the Department to date has demonstrated the diversity of
microfungi in waters and the increase in their numbers in proportion to the pace
and intensity of anthropogenic changes. This applies mainly to fungi that prefer
strongly eutrophicated waters that are rich in organic matter of various origins.
These fungi include ascomycetes and basidiomycetes, as well as some molds. It must
be emphasized that the majority of the species of these microfungi groups isolated
from waters are potential aetiological agents of surface and organ mycoses, and
their abundant proliferation in the waters under study may pose a serious epidemic
threat. Owing to this, a relatively complete picture of the water quality can be shown
with respect to the sanitary and epidemic status, taking into account fungi with high
pathogenic potential (Biedunkiewicz et al., 2013).
The majority of fungi isolated from water are opportunistic, and can settle on
the human skin and mucous membrane, most frequently in the respiratory and
alimentary tracts (Biedunkiewicz, 2011a). This may be temporary settlement or
colonization, which does not produce symptoms in carriers, while people with
impaired immunity acquire mycotic infection. The abundance of fungi that colonize
various sections of the respiratory tract was demonstrated in a multiyear study
conducted at Samodzielny Publiczny Zespół Gruźlicy i Chorób Płuc [Independent
Public Tuberculosis and Pulmonary Disease Unit] in Olsztyn, which was the
starting point for the hydromycological studies described herein. These studies
produced surprising findings and provided the basis for the doctoral thesis entitled
Dynamika mikoflory układu oddechowego człowieka [Mycoflora dynamics in
the human respiratory tract], with Prof. Dynowska as a scientific supervisor.
The analyses revealed the presence of 29 species of eight genera, viz., Candida,
Geotrichum, Saccharomyces, Saccharomycopsis, Schizosaccharomyces, Torulopsis,
Trichosporon, and Aspergillus. Many of these fungi have been isolated in the hospital
environment, indicating that the same species present in the human environment
can appear in this ontosphere under favorable conditions, i.e., immunosuppression
and dysbacteriosis (Biedunkiewicz, 2001; Dynowska et al., 2002, 2013). These
findings suggested the need for mycological analyses in healthy individuals, i.e.,
students of biology and veterinary medicine (Biedunkiewicz, 2007b, 2011a). The
results confirmed the carriage of 15 species of potentially pathogenic fungi of seven
genera in nearly 80% of the tested individuals. Combined with the results of clinical
observations, they directed the researchers’ attention to natural reservoirs of fungi in
immediate human surroundings.
The list of fungi that have been isolated from waters to date is long, and contains
185 species. Each aquatic ecosystem under study was found to contain C. albicans,
although it was not always a dominant species. It is particularly important in the
context of the relationship of the species with the ontospheres of humans and

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other vertebrates, which poses a potential violation of the biological balance, and
breakdown of body immunity. The presence of C. albicans in polluted waters
suggested its usability as an indicator of cleanliness and sanitary security, especially
since this species survives longer in marine and fresh waters than Escherichia
coli (Biedunkiewicz, 2015; Dynowska, 1995). Microfungi also survive at low
temperatures. The psychrosphere is not a habitat barrier for them. This has been
confirmed via mycological analyses of ice and snow cornices (Biedunkiewicz
& Ejdys, 2011; Ejdys, Biedunkiewicz, et al., 2014). All species proved to be
psychrotolerant, and they retained high viability following incubation at 37 ◦C.
These research findings provide grounds for regarding ice and snow cornices as
natural and temporary air filters and specific vectors of potential pathogens, which
pose a real epidemic threat in the environment.
The hydrosphere is one of the greatest fungi reservoirs with a diverse taxonomic
and trophic status. In addition to saprotrophs with dormant pathogenic potential,
species regarded as human and animal pathogens have been isolated from water
bodies. Quantitative and qualitative assessments of isolated microfungi are very
important in comprehensive mycological studies of various aquatic ecosystems and
utility waters. An analysis of the prevalence of their occurrence in recreationally
used waters, especially in summer, is imperative. There may be no officially
published epidemiological data concerning the correlations between microfungi
concentrations in waters and infections in humans who have contacts with
them; however, the occurrence of fungi in waters suggests such a possibility, and
also indicates that a water reservoir can be a serious source of mycoinfections.
Current knowledge of the ecophysiology of potentially pathogenic fungi and long-
term studies indicate that waters are important links in the mycoses epidemic
chain in the biosphere, especially if they contain fungi from household waste,
asymptomatic carriers, or people with mycoses (Dynowska, 1995). Therefore,
important achievements in hydromycological research include the development of
a procedure for the isolation, counting, and identification of potentially pathogenic
fungi, which can be used by laboratories in routine sanitary and epidemiological
testing of waters used for various purposes. This was incorporated, together with six
key publications (Biedunkiewicz, 2011b, 2015; Biedunkiewicz & Baranowska, 2011;
Biedunkiewicz & Ejdys, 2011; Biedunkiewicz & Góralska, 2016; Biedunkiewicz &
Ozimek, 2009), in the scientific accomplishment entitled “Możliwości wykorzystania
wybranych mikrogrzybów do oceny sanitarno-epidemiologicznej wód na tle
różnorodności i fenologii gatunków potencjalnie chorobotwórczych dla człowieka
[Use of selected microfungi in sanitary and epidemiological assessment of water
against the background of diversity and phenology of potential human pathogens],”
which was the basis for conferring the scientific degree of doctor habilitated in
biological sciences, microbiology specialty.
The research conducted to date at the Department has been devoted to the
taxonomy, quantitative aspects, and phenology of isolated fungi against the
background of natural and anthropogenic factors in aquatic environments. The
research findings have been published in nearly 110 scientific papers, showing a
relatively complete picture of water quality with respect to its sanitary and epidemic
status, taking into account fungi with high pathogenic potential (Dynowska &
Biedunkiewicz, 2013).

3. Circulation of Potentially Pathogenic Fungi in a School Environment

The research conducted by Prof. Dynowska on potentially pathogenic fungi in
the biosphere was expanded in the 2000s to include analyses of their occurrence
in organ ontocenoses in healthy children and adolescents in rural and urban
environments. The research conducted for the doctoral thesis entitled Analiza
mikologiczna wybranych ontocenoz dzieci w wieku 6–15 lat [Mycological analysis
of selected ontocenoses in children aged 6–15 years] (Ejdys, 2002) was used as the
starting point. It showed that schools were very interesting and poorly explored
objects of mycological research, especially with respect to the factors affecting the
occurrence of fungi in children and adolescents, as well as their surroundings. The

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results also encouraged researchers to plan studies of importance to epidemiology,
concerning multidirectional and multilevel analyses of the transmission of these
fungi.
The greatest attention in pediatric mycology literature is devoted to children in
risk groups. They include children with diabetes and cancers undergoing intensive
chemotherapy, and immunosuppression and antibiotic therapy, or those being
treated orthodontically. Few papers have been published on mycobiota in children
and adolescents regarded as healthy. The first/pilot study was conducted in 1997 on
70 children aged 0–9 and 10–15 years (Dynowska & Ejdys, 2000), and was aimed
at determining interindividual transmissibility within same-age groups. Forty-
five isolates of eight fungi species were obtained. These species were present in
39% of the population under study, and they occurred in children more frequently
than in adolescents. The phenological differences in the prevalence of fungi in
the children under study were emphasized. Unlike in adults (Dynowska, 1993a),
fungi were found twice more frequently in children’s ontocenoses in spring than
in fall. Obtaining multispecies isolates was an important outcome of this research.
Considering the findings and the epidemiological importance of the artificially
created population of children who stay as a group within a limited area of a school
building for up to 9 hours a day, it was decided to expand the school environment
research. Over three subsequent years, 270 generally healthy children aged 6–
15 years and living in the Voivodship of Warmia and Mazury were examined
(Ejdys, 2001, 2003a, 2003b). The research aimed to evaluate the relationship
between the occurrence of fungi in children’s oral cavities and noses, and the living
environment (town–village), gender, age, diet, prior diseases, antibiotic therapy, and
contacts with the hospital environment, as well as identify children at risk of mycotic
infections. Fungi were found in 36.3% of the population tested, which was a figure
comparable to that in preliminary examinations; 168 isolates of 13 yeast species were
obtained. Candida albicans – the main aetiological agent in the majority of human
mycoses – was a dominant species. The presence of C. glabrata and C. krusei, whose
increasing number of strains demonstrated resistance to main antimycotics, and the
relatively frequent occurrence of Trichosporon beigelii, Saccharomycopsis capsularis,
and Saccharomyces spp. – fungi of growing expansiveness and enzymatic activity
– was a cause for concern. Regardless of the season, the greatest fluctuations in the
mycocenoses diversity and count were observed in the oral cavity and nose, which
were the organs in direct contact with the contaminants in the environment and the
many potentially pathogenic fungi transmission agents.
The threat of a mycotic infection in the majority of the tested population increased
after antibiotic therapy, regardless of the season of the year or the age. This mainly
concerned the most stable ontocenosis of the pharynx. Children living in villages,
who had been ill immediately before the material was collected, were at the greatest
risk of having fungi in any of the ontocenoses under study. This is a consequence of,
among other things, more frequent contact of children in a rural environment with
natural reservoirs rich in fungi (Ejdys & Dynowska, 2004).
Since the differences between the prevalence of fungi in girls and boys living in
villages and those living in towns may have been caused by physiological, rather
than environmental factors, a study aimed at determining the effect of gender
on the frequency of fungal infections in children of school age was conducted
(Ejdys, 2008a). In spring and fall, tests were performed on 238 girls and 206 boys
(regarded as healthy) of the following ages: 6–9, 10–15, and 16–18 years. Although
the prevalence of fungi was similar in both genders (♀32.7% and ♂30.58%), the
species spectrum and occurrence of individual fungi species differed significantly
among the tested groups. The occurrence of C. albicans in girls decreased compared
to that of C. tropicalis and C. dubliniensis. An analysis of seasonal fungi occurrence,
depending on the specificity of the tested ontocenoses and children’s age, showed
that each gender is susceptible to infection by a different complex of factors, with a
correlation with age being observed for girls.
Infections of potential fungal pathogens in generally healthy children typically
end with the elimination of the fungi from the children’s bodies. According to the
findings of these researchers’ studies, it happens in approx. 65% cases (Ejdys, 2003a).

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In other cases, commensalism or colonization is suspected, with possible transition
to carriage. A single test of a child without any disease symptoms does not provide
a basis for a clear identification of the relationship between the child’s body and a
potential fungal pathogen. An inconclusive interpretation of the results of a single
test of children led the researcher to conduct a distance control, whose aim was to
differentiate fungal infections in healthy children into temporary and permanent,
and determine the factors that predispose children to temporary fungal infections
(commensalism and colonization) and carriage (Ejdys, 2006).
Tests were conducted on smears taken twice within a 5-year span during the same
season of the year from the oral cavities, pharynxes, and noses of 34 children
aged 7 and 12 years. Fungi were found in seven children in the first test and in
nine children in the second test, and the fungi incidence was 20.6% and 26.5%,
respectively, with fungi found only in three girls (8.8%) in both tests. Single-focus
infections were the most frequent. Fungi were isolated from the ontocenosis of the
oral cavity and the pharynx of one child in each test. Differences in the ontocenoses
diversity were observed in both tests. It was concluded that the children in whom
fungi were found twice could be carriers. The physiological status of cohabitation
with fungi in children with a single infection cannot be determined. However, all
positive results must be treated very seriously in the context of potential future
mycosis caused by yeasts (Ejdys, 2006).
Initially, the research conducted in the school environment focused on fungal
infections in children (Dynowska & Ejdys, 2000; Ejdys, 2003a), to identify
individuals particularly susceptible to infections (Ejdys, 2003b), and factors that
favor colonization of organ ontocenoses by various yeast species (Ejdys, 2008a; Ejdys
& Dynowska, 2004). However, in addition to individuals potentially susceptible to
infections, there are other sources, ways, or vectors of fungal infections in the school
environment.
Air is an important vector of fungi transmission between organisms (Dynowska
& Ejdys, 1999). Fungal diaspores account for the majority of bioaerosols in
atmospheric air. Spores of yeast-like fungi, which are heavier than those of mold
fungi, occur in the bottom part of the air column. This is the height at which there
are two main gateways of infection in primary school children: the mouth and
nose. Therefore, a high density of fungi in the air may pose a serious threat to the
health of children who breathe in such air. The presence of the aforementioned
fungi species in the air within and around school buildings was examined in May
(heating on) and November (heating off), and the fungal features that help them
survive in the school environment were analyzed (Ejdys, 2008b; 2009b; Ejdys et
al., 2009). The air in school buildings, of the right humidity and temperature, was
found to contain 28 species of 15 genera of yeast-like fungi. The atmospheric air
was found to contain 20 species of 14 genera. Kluyveromyces lactis dominated in
the indoor air, whereas Yarrowia lipolytica, which is the species with the highest
symbiotic capability, dominated in the air outdoors. A comparison of the habitats
under study showed, from an epidemiological perspective, that schoolrooms have
greater potential to cause infections than the air outdoors. The worst yeast species
spectrum was observed in intensively used rooms with limited access to light and
oxygen; hence, they are the greatest threat to the health of children and school
personnel.
Nonfermenting isolates and those that did not produce pigments dominated in
heated rooms, whereas fermenting fungi and those capable of producing pigments
dominated when heating was off (Ejdys, Dynowska, et al., 2014). The ability
to produce carotenoid pigments is clearly promoted in indoor yeast. It may be
associated with the addition of intermediate stages of carotenoid biosynthesis or
an excess of oxidative compounds. Two-thirds of the isolates did not require any
vitamins for their growth. Five isolates of four species exhibited acid-formation
properties: Dekkera anomala, D. bruxellensis, Y. lipolytica, and C. tropicalis (syn. C.
citrica). Owing to acid production, the fungi could dissolve inorganic compounds in
building structures and release essential micronutrients. These findings suggested
that some yeasts inhabit rooms as their main environment, whereas some live
there temporarily because the human body is their main habitat (Ejdys, 2008b).

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Determination of the survival factors for the fungi outside the human ontosphere
was regarded as particularly important (Ejdys, 2009a; Ejdys & Rasztęborska, 2010).
Isolates of C. albicans, C. dubliniensis, and C. tropicalis obtained from human organ
ontocenoses were used in the research. The strains were kept on dry glasses, with
only access to the aerosol in the laboratory room, and their viability and survival
rate was assessed every two weeks. A 100% death rate was not noted for any of the
isolates during the 22-week observation; this proves high viability and suggests the
need for improved hygiene in schoolrooms.
A 4-year mycological monitoring of school rooms demonstrated that yeasts account
for a third of the mycobiota in the air and on walls; a total of 772 fungal isolates
of 151 species and 48 genera were obtained in the test, with 70 sterile isolates.
Fungi of the genera Aspergillus (36 species), Penicillium (26), and Candida (14 +
two anamorphs) were the most frequent. Aspergillus fumigatus was the dominant
species (126 isolates). This fungus is a permanent component of mycobiota in
schools/public buildings in north-east Poland. Its count in rooms should be
monitored continuously; this applies particularly to thermophilic isolates, owing
to their environmental plasticity and potential pathogenicity (Ejdys et al., 2013).
Such a broad spectrum of fungi species has not yet been observed in studies
of indoor bioaerosols in this part of Europe (Ejdys, 2007a, 2007b; Ejdys &
Biedunkiewicz, 2011; Ejdys et al., 2013). It seems that it is largely a consequence of
the adopted research methodology (Ejdys, 2011; Ejdys et al., 2015). Simultaneous
application of different incubation temperatures (25, 37, and 40 ◦C) allowed
for the broadening of the known mycobiota spectrum in schoolrooms. Sterile
isolates (approx. 10%) pose an as yet undiscovered potential threat to users of the
building itself, related to pathogenicity, especially allergenicity and toxin production
potential, since all the 33 randomly selected fungi isolates obtained from the rooms
demonstrated toxin production potential (Ejdys et al., 2013).
The research on the school environment conducted at the Department of Mycology,
UWM in Olsztyn resulted in the publication of 34 papers and over 40 research
communications. In addition to the original papers, others devoted to research
methodology, describing the methods and techniques to collect and diagnose study
material more effectively, were published.

4. Lichenological Research

The beginnings of lichenological studies in Warmia and Mazury date back to the
late nineteenth century. The material collected in the region (the former German
province of East Prussia) by Ohlert (1870) provided data that are still valuable as
they enable researchers to assess the changes that have taken place in lichen biota
over 150 years (Cieśliński, 2003). After nearly 100 years, research on lichens was
started at the Department of Botany of the Academy of Agriculture and Technology
in Olsztyn (currently Department of Botany, UWM in Olsztyn). The research
was conducted by Hutorowicz (e.g., Hutorowicz, 1957, 1963), and subsequently,
Zalewska and her team (e.g., Kukwa, Łubek, et al., 2012; Szydłowska et al., 2013;
Szymczyk et al., 2014, 2015; Zalewska, 1998, 2012; Zalewska et al., 2004a, 2004b).
Lichenological research at the Department of Mycology of the UWM in Olsztyn was
started in 1997 (Kubiak, 1999), initially at the Botany Department of the Teachers
College in Olsztyn. One of the researchers involved was Professor Stanisław
Cieśliński, an eminent Polish lichenologist. Affiliated to a scientific center in
Kielce, he worked for a brief period (1993–1994) at the Botany Department of
the Teachers College in Olsztyn as a researcher and teacher. During that time, he
conducted extensive field research, the results of which were published in the Atlas
rozmieszczenia porostów (Lichenes) w Polsce północno-wschodniej [Distribution atlas
of Lichens (Lichenes) in north-eastern Poland] (Cieśliński, 2003). The introduction
to the atlas states that “the good condition of the lichen biota [in the north-east
of Poland] and preservation of biocenotic associations with lichens allows tracing
and describing processes and relationships which – due to the anthropogenic
impact, its pace and range – is not possible elsewhere in Poland.” The space for
such lichenological research was noted by Prof. Dynowska, and she initiated the

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related actions soon after taking over the position of Head of the Department of
Mycology of the Teachers College in Olsztyn. Dariusz Kubiak was appointed head
of this field of research at the Department. The initial period of the research was
the time when a new approach to taxonomic studies was becoming increasingly
popular among lichenologists. It involved a broader use of biochemical features in
species identification (Guzow-Krzemińska & Kukwa, 2013; Kubiak & Kukwa, 2011),
and was made possible by the development of techniques and procedures of
chromatographic separation of secondary metabolites of lichenized fungi, the
so-called “lichen acids” (Tønsberg, 1992). Owing to cooperation with other
research centers, particularly with the Department of Plant Taxonomy and Nature
Conservation of the University of Gdańsk (currently: Laboratory of Lichenology and
Experimental Mycology), a laboratory of planar thin-layer chromatography (TLC)
was established at the Department of Microbiology and Mycology; this proved
essential in the first research projects carried out at the Department.
The north-east of Poland, as an area of lichenological research, is a very interesting
region from a scientific perspective (Cieśliński, 2003); however, it is also a highly
demanding region because of the abundance of lichen biota and the number
of lichen species. The initial research conducted at the Department focused on
exploring the taxonomic diversity, ecology, and distribution of lichen biota in
the urban areas of Olsztyn (Kubiak, 2005). The research findings, analyzed from
a bioindicative perspective, provided the basis for the doctoral thesis written by
Dariusz Kubiak, entitled Porosty Olsztyna na tle antropogenicznych przekształceń
środowiska [Lichens in Olsztyn against the background of anthropogenic
transformations], with Prof. Dynowska as the scientific supervisor. The research,
conducted for many years, documented the occurrence of over 300 lichen species
within the city borders, which is a phenomenon on a global scale. (Kubiak, 2005;
Kubiak, Sucharzewska, & Ejdys, 2016).
The scope of the research was gradually expanded to include other areas
poorly explored from a lichenological perspective, especially those regarded
of key importance to lichen diversity in the region (Kubiak, 2011b; Kubiak,
Biedunkiewicz, & Ejdys, 2015; Kubiak, Biedunkiewicz, & Koźniewski, 2015; Kubiak
et al., 2014, 2017, 2019; Kubiak & Sucharzewska, 2018) In some cases, the study
findings proved so interesting that they were the basis for the decision to initiate
special protective measures (Kubiak, Biedunkiewicz, & Ejdys, 2015; Kubiak et
al., 2014; Kubiak & Sucharzewska, 2013, 2018) or, in the case of protected sites, to
expand the scope of protection (Kubiak et al., 2017).
The nature and scope of the research, as well as the specificity of the region,
which stands out against other parts of the country with respect to preservation
of biodiversity, resulted in the accumulation of a large amount of data on the
distribution and habitat preferences of many lichen species. The data concerning
a group of sterile crustose lichens, which have not been well-explored in Poland,
are of particular value. Such data made it possible to make the first, relatively
reliable assessment of the current status of the species and the danger to them
(Kubiak, 2010, 2011a; Kubiak & Łubek, 2016; Kubiak & Sucharzewska, 2014; Kubiak
& Westberg, 2011; Kubiak & Zalewska, 2009). The discovery of new taxons of the
lichen biota in Poland was one of the particularly valuable results of the research
(Kubiak, 2003; Kubiak & Malicek, 2012; Kubiak & Westberg, 2011; Kubiak &
Wilk, 2016; Kukwa & Kubiak, 2007); these include Loxospora cristinae Guzow-
Krzemińska, Łubek, Kubiak & Kukwa (Guzow-Krzemińska et al., 2018). The
relatively broad scope of the research was made possible by the fact that it was
financed as part of the Ministry of Science/National Centre for Science research
project entitled “Zróżnicowanie i środowiskowe uwarunkowania lichenobioty lasów
grądowych (Carpinion betuli) Pojezierza Mazurskiego [Diversity and environmental
factors affecting the lichen biota in the oak-hornbeam forests (Carpinion betuli) in
the Masurian Lakeland].”
At the same time, lichenological research was initiated in other parts of Poland.
Among the more significant studies conducted at the Department of Mycology
were those conducted in the Rogów forests (Kubiak & Szczepkowski, 2012),
Mazovia (Kubiak, 2009, 2013; Kubiak, Biedunkiewicz, & Koźniewski, 2015; Kubiak

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et al., 2010), and the south of the Wielkopolska region (Kubiak, 2008; Kubiak &
Biedunkiewicz, 2015). The Department participated in many team projects whose
aims included increasing the state of knowledge on lichen biota in selected regions
of Poland (Fałtynowicz et al., 2015; Kukwa, Kowalewska, et al., 2012 ; Kukwa et
al., 2008), Lithuania (Motiejūnaitė et al., 2012), and Latvia (Motiejūnaitė et al., 2016).
As the research at the Department of Microbiology and Mycology intensified, it
became increasingly specific. The research activities at the Department focused, on
the one hand, on issues related to lichen diversity, viz., methods of its assessment,
principles, and ways of data interpretation (Kubiak, 2012), and on the other, on
the usability of the research findings in activities aimed at the preservation or
sustainable exploitation of natural resources (Kubiak, Osyczka, & Rola, 2016). Many
papers note the potential role and importance of old trees in the conservation of
lichen diversity in forests, particularly that of stenotopic forest lichens (Kubiak &
Osyczka, 2017; Kubiak & Sucharzewska, 2012, 2018). As a specific summation of
this stage of lichenological research conducted at the Department of Microbiology
and Mycology, Dariusz Kubiak received the title of doctor habilitated of natural
sciences, biological sciences discipline, based on the scientific achievement
entitled “Naturalne i antropogeniczne uwarunkowania różnorodności porostów
epifitycznych [Natural and anthropogenic factors affecting the diversity of epiphytic
lichens].”
The current period of lichenological research at the Department of Microbiology
and Mycology covers issues related to the identification of environmental
factors that are potentially significant to species occurrence, and an assessment
of their impact on the diversity of epiphytic lichens, on the site, habitat, and
region/landscape scales. This research includes various types of forest communities
as well as selected forms of the cultural agricultural landscape, which includes
alleys of roadside trees (Kubiak & Osyczka, 2019, 2020; Osyczka & Kubiak, 2020).
To understand and study the regularities of epiphytic lichen ecology, the body of
environmental data, related both to the qualitative and quantitative diversity of
lichen biota, as well as specific physicochemical parameters of their environment,
is subjected to multidimensional statistical analyses and ordination techniques.
The aim is to use this solid basis to create scientific grounds for practical measures
to conserve natural resources and preserve the service that they perform for the
ecosystem, which is particularly important and urgent in the face of newly emerging
environmental threats.
The scientific achievements of the Department of Microbiology and Mycology in
lichenological research include 70 original papers published during the past 20 years.
In addition to the scientific papers, the Department has accumulated extensive
reference material in the form of herbarium exhibits kept at the Department of
Microbiology and Mycology (OLTC). A considerable number of sterile crustose
lichens are some of the remarkable items in this collection. This material has
significant scientific potential. It provided the basis for many published papers
written by the Department staff, and is used by other researchers in taxonomic or
phylogenetic studies.

5. Studies of Fungi – Parasites of Plants in the Urban Environment

Parasitic fungi are an important link in each biocenosis, and their presence in an
environment depends mainly on the accessibility of host plants (Majewski, 1971).
Finding a suitable host, which will ensure survival in different environmental
structures, is the most important element of a parasite’s life strategy. A close
relationship between a parasite and its host, which has developed by coevolution,
produces an inseparable biological system affected by environmental conditions
(Mułenko, 1998). The high diversity of plant species, many of which have been
introduced by humans, as well as the dynamic nature of the urban environment,
make urbicenosis an interesting basis for analyzing the species diversity of
parasites, studying their life strategies and the appearance of new species, and
registering cases of native species being pushed out. Life strategies of parasites
in natural conditions, under biocenotic homeostasis, are generally well defined
and relatively stable. On the other hand, under anthropopressure, all types of

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reactions are changed frequently by disturbing factors, affecting the number and
prevalence of phytopathogens. In urbicenoses, it is often a complex of transport-
generated pollution, which can be of strategic importance for the growth and
development of ectoparasites, such as powdery mildew, that play an important role
in adaptation. As a response to such considerations, Prof. Dynowska conducted
long-term studies on diverse responses and the bioindicative potential of fungi
of the order Erysiphales in the environment under strong anthropopressure
(Dynowska, 1993c, 1994, 1996a, 1996b). The reconnaissance study conducted by the
researcher for several years in north-east Poland showed that there are Erysiphales
species that respond in a variety of ways to urban, particularly transport-generated,
pollution. By analyzing the degree of infestation of host plants in different pollution
zones, expressed by the diseases index, she identified susceptible and resistant fungi.
In the case of the former, a high concentration of exhaust fumes was accompanied
by a decrease in the disease index, an increase in the mycelium growth rate, and
earlier maturation of the fruit body compared to those in nonurban areas. She
identified the following species as susceptible: Erysiphe alphitoides (Microsphaera
alphitoides; Braun, 1987), E. cichoracearum, E. heraclei, Golovinomyces sordidus
(E. sordida), and Podosphaera fusca (Sphaerotheca fusca, S. erigerontis-caadensis;
Braun, 1987). In contrast, she identified the following species as resistant: Erysiphe
berberidis (Microsphaera berberidis; Braun, 1987), E. depressa, E. palczewskii
(Microsphaera palczewskii; Braun, 1987), and E. vanbruntiana (Microsphaera
vanbruntiana; Braun, 1987; Braun & Takamatsu, 2000).
Since there were large gaps concerning the ecology of parasitic fungi in urbicenoses
in the Polish literature of the subject, the findings of Prof. Dynowska’s research
inspired other researchers to start detailed studies of their own. Their aim was to
observe the responses of selected Erysiphales species in the urban environment, and
determine the degree and scope of changes in their growth cycle. Interactions in
the “parasite–host” system, developed as a result of environmental changes, can be
additionally modified by the presence of hyperparasites, which is why the presence
of the Erysiphales hyperparasite, Ampelomyces quisqualis (Cicinnobolus cesatii), was
also taken into account in the study (Sucharzewska & Dynowska, 2002). Seven
Erysiphales species were covered by the study, considering the presence of host
plants in the area under study: E. alphitoides and E. hypophylla on Quercus robur, E.
palczewskii on Caragana arborescens, G. sordidus on Plantago major, Podosphaera
fusca on Taraxacum officinale, and Sawadaea tulasnei on Acer platanoides L.
(Sucharzewska, 2007).
Several research tasks were adopted in order to accomplish the objective:

• Comparison of the degree of infestation of host plants by selected Erysiphales
fungi species at sites located at various distances from the transport routes in the
city of Olsztyn.

• Analysis of the share of anamorphous and telemorphous stages in the material
under study as a potential adaptation index.

• Analysis of the adult stage – the time when chasmotetia appear, their number,
and the development of rhizines, sacs, and spores – depending on the distance
from transport routes.

• Assessment of the impact of A. quisqualis – an Erysiphales hyperparasite – and
other fungi that settle the thallus Erysiphales species on the growth of the fungi
under study, and the degree of infestation of host plants.

The study findings demonstrated a higher degree of host plant infestation by all the
phytopathogens selected for the study at the sites located near the main transport
routes, compared to that at the control points. This led to several conclusions.
In the case of E. alphitoides and E. hypophylla, a high disease index of Q. robur
at sites located in the zone of accumulation of transport-generated pollution
was proof of the resistance of both species to this type of pollution. This applied
especially to E. alphitoides, which, in the phytopathological literature, was regarded
as a species sensitive to urban and industrial pollution (Sucharzewska, 2009).
The disease index of C. arborescens and T. officinale, infested by E. palczewskii

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and P. fusca, respectively, was affected indirectly, but significantly, by human
activity. Impairment of plant health by systematic plant care treatment (lawn and
hedge trimming) and toxic car exhaust probably disrupted the basic physiological
processes in “plant–host” partnerships in the ecological systems under study. In
consequence, the dynamic equilibrium state was disrupted for the benefit of the
parasites, expressed by a high degree of infestation of host plants, of even 100%
(Sucharzewska & Dynowska, 2005). The high disease index for A. platanoides
infested by S. tulasnei on young maples, and the very low disease index or lack of
parasites on mature trees, suggest that the growth of this mildew species depends
mainly on the host plant age. Older trees were more resistant and healthier than
young ones (Sucharzewska, 2010). Erysiphe palczewskii was a species that stood out
as one that accomplished all its life functions in the urban environment. It was here
that the highest infestation degree in the host plant compared to that in the other
representatives was observed, in addition to the presence of a fungus growth stage at
every site, the largest number of fruiting bodies, as well as a >90% share of mature
fruiting bodies with fully developed rhizines, sacs, and spores (Sucharzewska &
Dynowska, 2005). Hyperparasites were found on all the Erysiphales species under
study, with the largest number of them belonging to the genus Ampelomyces. A
strong presence of other genera was observed on the mycelium of E. alphitoides and
E. palczewskii at sites near the main transport routes, e.g., Alternaria, Aureobasidium,
Cladosporium, Stemphylium, and Tripospermum. They reduced the number of
fruiting bodies of host fungi, which proved the weaker condition of Erysiphales
fungi, but did not affect the degree of plant infestation (Sucharzewska, Dynowska,
Ejdys, et al., 2012).
Continuous research on hyperparasitism, especially an assessment of the prevalence
of A. quisqualis and its impact on host growth in the urban environment, showed
that this hyperparasite finds very favorable conditions for growth on the mycelium
of Erysiphales fungi. Data obtained from the available literature showed a low share
of the species in the natural environment, such as natural reserves or national parks,
or even no records at all (Majewski, 1971). Based on the documented observations,
A. quisqualis was classified as an urbanophil. The high prevalence of mycoparasites
of the genus Ampelomyces, with a simultaneous high prevalence of Erysiphales
fungi, confirmed earlier conclusions that the presence of A. quisqualis in natural
conditions neither considerably limits the host plant infestation by Erysiphales nor
disrupts their life cycle (Sucharzewska et al., 2011). Ampelomyces quisqualis was
found most frequently in young fruit bodies of Erysiphales fungi, but with Erysiphe
flexuosa on Aesculus hippocastanum and E. vanbruntiana var. sambuci-racemosae
on Sambucus racemosa; conidiospores of the hyperparasite were also found inside
mature fruit bodies. This was the first description of this phenomenon. International
literature only provided information on A. quisqualis settling on young fruiting
bodies and transforming them into their own reproductive structures. The presence
of conidiospores inside fruit bodies with properly developed rhizines suggested
an improvement in the adaptive strategy (Sucharzewska, Dynowska, Kubiak, et
al., 2012). Colonization of mature chasmothecia, including the completion of
peridium formation with properly developed rhizines, creates proper conditions
for hyperparasites for better wintering and propagation in the environment. This
may result in an increase in the presence of A. quisqualis in the urban environment,
and in consequence, lead to changes in the Erysiphales population. An analysis
of the relationship of Erysiphales with other fungi (Alternaria, Cladosporium,
Stemphylium), noted in earlier studies, was also conducted. The use of electron
microscope techniques (project No. 2017/01/X/NZ8/00798) confirmed a
parasitic relation between Erysiphales spp. and the fungi present on their surface.
Hyperparasites destroyed the colonized development stages of Erysiphales, and
external and internal hyperparasitisms were observed. In the case of the former,
numerous structures of parasitic fungi were found on the surface of the pathogens
at the development and accompanying cell lysis stages. In the case of the latter,
parasites were present inside the pathogens at the sexual and asexual stages, e.g., the
presence of hyphae of Stemphylium sarciniforme in the rhizines of fruit bodies of E.
palczewskii (Sucharzewska, 2019).

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The development of parasitic fungi can also be affected by organisms that do not
directly interact with them. Several species compete for nutrients and habitat. This
is the case with E. flexuosa, which infests the horse-chestnut tree and a butterfly
called horse-chestnut leaf miner (Cameraria ohridella), which feeds on this plant
species. Both species colonize the plant leaves and compete for the most beneficial
living conditions. The observation of the development cycle of E. flexuosa on horse-
chestnut tree leaves in an urban environment, taking into account the presence
of C. ohridella, led to several conclusions. A high level of presence of the species
under study on two horse-chestnut species (A. hippocastanum and A. × carnea),
with a distinct preference of E. flexuosa for A. × carnea, and the butterfly for A.
hippocastanum, was observed. Erysiphe flexuosa may have completed its life cycle,
but the co-occurrence with C. ohridella affected the disease index and the number
of fruit bodies formed by the fungus. Analyses showed that the differences in
preference of hosts ensure that E. flexuosa has proper conditions for growth and
formation of a large number of fruit bodies with spores, which, as a result of the
sexual process, enable the parasite to adapt to changing environmental conditions,
which are particularly present in urbicenoses. Therefore, it was stressed that research
focusing mainly on controlling the horse-chestnut leaf miner should also take into
account the presence of E. flexuosa, which, because of its invasiveness, poses a
serious threat to horse-chestnut trees (Sucharzewska et al., 2018).
Long-term monitoring conducted at the Department of Mycology revealed the
presence of numerous parasitic fungi and fungi-like organisms on urban plants.
Altogether, over 300 species were identified (individual groups: Pucciniales, 45%;
Erysiphales, 22%; and others, 33%). Among the identified species, there are several
regarded as interesting from the perspective of Poland: Entomosporium mespili,
Erysiphe deutziae, Kuehneola uredinis, Monilia linhartiana, Phyllosticta juglandis,
and Seimatosporium lichenicola. Some new hosts were found, e.g., Juglans nigra
for Ascochyta juglandis, Quercus rubra for Discosia artocreas, Ginkgo biloba for
Epicoccum purpurascens, Juniperus communis for Pestalotia guepinii, and Crataegus
monogyna for Seimatosporium lichenicola. Erysiphe trifolii was driven out from C.
arborescens by E. palczewskii (Sucharzewska et al., 2011).
Despite reports on the species diversity and changes of parasitic mycobiota on
plants in Polish cities, these issues are still poorly explored. Owing to its dynamic
character, urbicenosis is a perfect research ground on which numerous interactions
and changes in the “parasite–host” and “host–parasite–hyperparasite” systems result
in the perfection of the life strategies of parasites, with consequent preservation of
the species.
Although studies of fungi ecophysiology in the urban environment were initiated
just after the research teams at the Department were formed, their dynamic growth
started with the doctoral thesis entitled Strategie życiowe wybranych grzybów z rzędu
Erysiphales w warunkach zróżnicowanej antropopresji [Life strategies of selected
Erysiphales fungi under variable anthropopressure] (Sucharzewska, 2007). The
findings to date have been published in 35 papers, most of which are original
scientific articles. Recently, field research aimed at analyzing parasitic fungi of
the phyllosphere of aquatic plants in the littoral of selected lakes in Olsztyn was
completed. It took into account the functioning of the fungi with respect to urban
pollution and biomonitoring.

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	Introduction
	Potentially Pathogenic Fungi Isolated from Waters and Their Application in Bioindication
	Circulation of Potentially Pathogenic Fungi in a School Environment
	Lichenological Research
	Studies of Fungi – Parasites of Plants in the Urban Environment
	References