Characteristics and diversity of Rhizoctonia spp. population in soil of selected forest bare-root nurseries in Poland


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that the article is properly cited. © The Author(s) 2014 Published by Polish Botanical Society

Acta Mycologica

Introduction

Coniferous species cover 69.9% of the total forest area in Poland, with Scots pine grow-
ing on 59.5% of the forest area of all forms of ownership [1]. The large percentage of pine 
stands in Polish forests requires constant renewal and therefore continuous production 
of large quantities of high-quality planting stock for reforestation is necessary.

Scots pine seedlings, both in nurseries and in natural stands, are vulnerable to attack 
by various pathogens [2–4].The most prevalent and severe disease of conifer seedlings 
is damping-off, the more frequently occurring, the longer a nursery is being operated, 
which is associated with accumulation of inoculum in soil [3,4].

ORIGINAL RESEARCH PAPER Acta Mycol 49(2):279–290 DOI: 10.5586/am.2014.025 
Received: 2014-10-05 Accepted: 2014-12-21 Published electronically: 2014-12-31

Characteristics and diversity of Rhizoctonia spp. 
population in soil of selected forest bare-root 
nurseries in Poland

Marta Bełka*, Małgorzata Mańka
Department of Forest Pathology, Faculty of Forestry, Poznań University of LIfe Sciences, Wojska Polskiego 71c, 60-625 Poznań, Poland

Abstract

Fourty three Rhizoctonia isolates obtained from four forest nurseries situated in the 
Wielkopolska region (central-western Poland) has been proved as multinucleate (ana-
morph – R. solani). They represented four anastomosis groups (AG): AG1-IC, AG-5, 
AG4-HG2 and AG2-1. Three AGs were found in Jarocin nursery (AG-5, AG4-HG2 and 
AG2-1), two in Łopuchówko (AG-5 and AG4-HG2) and one in Konstantynowo (AG1-IC) 
and Pniewy (AG-5). All isolates were highly pathogenic to Scots pine (Pinus sylvestris) 
seedlings and pose a large damping-off threat to the seedlings in the nurseries with single 
AG and in those where more AGs exists.

Keywords: Rhizoctonia spp.; anastomosis group; pathogenicity; forest nursery; Pinus 
sylvestris; damping-off

* Corresponding author. Email: marticz@poczta.onet.pl 

Handling Editor: Maria Rudawska

http://creativecommons.org/licenses/by/3.0/
mailto:marticz%40poczta.onet.pl?subject=am.2014.025


280© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

The most severe pathogens causing damping-off in Polish forest nurseries include 
species from genera: Fusarium, Rhizoctonia, Pythium, Alternaria and Cylindrocarpon 
[3,5–8]. Fungi belonging to the Rhizoctonia genus represent a wide range of pathogenic, 
non-pathogenic and mutualistic species [9]. Most studies on this group of fungi, known 
to attack more than 200 different species of plants, relate to agricultural plants, while 
only few researchers have studied this group of organisms in forest nurseries [4,6,10–22].

Fungi classified as Rhizoctonia spp. are a collection of fungi, in which the differences 
relate to the stage of anamorph, teleomorph, size and shape of sclerotia, and color of the 
mycelium [23–30].

The first reports on anastomosis reactions between isolates of R. solani date back to 1920 
and 1930 [31,32]. However, only since the emergence of the anastomosis groups (AGs) 
concept within Rhizoctonia spp. [33], it has become an important tool in understanding 
the genetic diversity of this complex of fungi, considering the fact that isolates subscribed 
to different anastomosis groups can differ in pathogenicity to their host plants [34].

Although Rhizoctonia spp. are an important problem in a number of forest nurseries 
in Poland but until recently, there has been little research in this area. The fact that hyphal 
anastomosis groups in Rhizoctonia spp. are not always host specific is well known and 
most isolates from different anastomosis groups are capable of causing infection on a 
variety of plant species [24]. Because virulence and host range of AGs is differentiated, 
therefore knowledge about affinity of isolates of R. solani to particular anastomosis group 
is very important, in view of protection of Scots pine seedlings not only in Wielkopolska 
region but in the entire country.

The aim of this study was to investigate the inter- and intra-species diversity within 
Rhizoctonia spp. isolated from soil of four selected forest nurseries in the Poznań region 
(central-western Poland) in connection with their pathogenicity diversity and the resulting 
threat to Scots pine seedlings in Polish nurseries.

Material and methods

Collecting isolates
Soil samples were harvested from the top 15 cm of the soil profile from nurseries of 

Forest Districts: Jarocin, Łopuchówko, Konstantynowo and Pniewy. The soil was collected 
in early spring, before any chemicals were used. Samples were placed in sterile cotton 
bags and stored at 5°C for no longer than two days.

Rhizoctonia isolates were obtained from soil samples using two trapping methods. 
The first method based on the use of pine seeds which were sown (25 seeds per pot) to a 
volume of 700 ml of unified soil from a nursery. Then, after emergence of the first seedlings 
observation was carried out in order to capture the very first symptoms of damping-off. 
The symptomatic seedlings were disinfected with 0.5% sodium hypochlorite for 5 min-
utes, 70% ethanol (1 minute) and washed three times in distilled sterilized water, for five 
minutes jointly. Next, the symptomatic parts of seedlings (up to 2 cm) were transferred 
onto Martin-Johnson agar medium, supplemented with antibiotics (streptomycin 0.05 g/l 
and aureomycin 0.05 g/l) to prevent the growth of bacteria. All isolates growing out of 
them were transferred onto potato dextrose agar (PDA medium).



281© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

The second method used in the study was a modified method described by Paulitz 
and Schroeder [35] where wooden toothpicks were used. Toothpics (10 per 700 ml of soil 
in pot) were inserted into the soil to a depth of 5 cm, evenly spaced in the pot. After 48 
hours, toothpicks were removed and placed on Petri plates with PDA, supplemented with 
antibiotics (as described above). The plates with two toothpics per plate were incubated 
for 24 hours at room temperature. All mycelia growing from tothpicks were transferred 
onto PDA plates in order to identify Rhizoctonia isolates.

Rhizoctonia identification
MICROSCOPIC EXAMINATION BY CELL NUCLEI STAINING. Determining the 

number of nuclei in the cells of the Rhizoctonia spp. is an important part of the process 
of assigning isolates to this genus [28].

The number of nuclei per cell was determined with the method described by Bandoni 
[36]. The average number of nuclei was calculated for 50 cells of each isolate.

MOLECULAR IDENTIFICATION. DNA isolation. In order to isolate DNA, isolates 
were grown on liquid broth for 6–8 days. After that time the mycelium was placed on sterile 
filter paper and the excessive medium was removed. The dried mycelium was put into Ep-
pendorf tubes (1.2 ml), and placed for 24 hours at −20°C. The next step was freeze-drying 
of the frozen mycelia in a lyophilizer (Christ Alpha 1-2 LD) at −55°C and a pressure of 
10−2 bar. After at least 18 hours, the mycelium was crushed with metal rods, then the cap 
was secured with parafilm, and the tubes were stored at −20°C until the DNA extraction. 
DNA extraction was carried out using a DNeasy Plant Mini Kit (Qiagen) according to 
manufacturer’s recommendations. PCR-RFLP analysis of rDNA-ITS region. Isolates 
obtained in the study have been first separated based on morphological differences and 
the number of nuclei per cell. In order to assign isolates to the anastomosis subgroups 
the restriction enzymes digestion of RFLP of rDNA-ITS regions was performed. Primers 
ITS4 (TCCTCCGCTTATTGATATGC) and ITS5 (GGAAGTAAAAGTCGTAACAAGG) 
were used for amplification of the nuclear rDNA-ITS region [37]. The PCR amplification 
reactions were conducted by adding 2 μl genomic DNA to 23 μl of PCR-mix, containing 
2.5 μl 10× PCR buffer (Qiagen), 5 μl Q-solution (Qiagen), 0.5 μl dNTPs (10 mm, Fermentas 
GmbH), 1.75 μl of each primer (10 μm), 0.15 μl Taq polymerase (Fermentas GmbH) 
and 11.35 μl sterile highly purified water. The denaturation step at 94°C for 10 min was 
followed by 35 cycles of 1 min at 94°C, 1 min at 60°C and 1 min at 72°C. Cycling ended 
with a final extension step at 72°C for 10 min (Biometra, T-Gradient Thermoblock). After 
the DNA extraction and restriction enzymes digestion of RFLP of rDNA-ITS regions the 
results of electrophoresis were checked under the UV light, and the resulting patterns 
were compared with those presented in the work of Guillemaut et al. [38]. Four restriction 
enzymes (MseI, AvaII, HincII, and MunI) were used in the study. Sequence analysis of 
ITS-rDNA region. Sequencing of ITS-rDNA region and previous cleaning of the DNA 
has been carried out in the Laboratory of Medical Genetics, CB DNA (Mickiewicza 31, 
60-835 Poznań). The sequencing results were then used for further work. The sequences 
of rDNA-ITS region were compared with sequences available in the GenBank (http://
www.ncbi.nlm.nih.gov/GenBank) to check and compare if the results of those carried 
with Guillemault et al. [38] method were the same.

CHARACTERISTICS OF RHIZOCTONIA ISOLATES. Growth rate measurement. 
Fungal colonies were grown at 21°C, according to the work of Tewoldemedhin et al. [39]. 

http://www.ncbi.nlm.nih.gov/GenBank
http://www.ncbi.nlm.nih.gov/GenBank


282© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

The mycelial disc (0.5 cm diameter) of each isolate (4 reps) was placed in the center of 
Petri dishes with PDA. The Petri dishes were incubated in the dark. The growth rate of 
individual isolates on PDA was measured every 24 hours, in two directions on each plate. 
Pathogenicity of Rhizoctonia isolates. Plastic pots (500 ml volume) were filled up to 2/3 
with sterilized soil (120°C for 2 hours, for three days in a row). On the soil surface PDA 
medium overgrown with seven-day-old mycelium removed from a Petri dish was placed 
and covered with a further layer of soil (about 1 cm) into which the Scots pine seeds were 
sown (25 seeds per pot). Seeds were previously surface sterilized for 10 minutes in 30% 
H2O2, then rinsed with distilled water three times. Thus prepared pots, and the control 
pots (with sterile PDA medium) were watered with tap water as needed. After the first 
seedlings were observed emerging from the soil, the pots were checked daily and infested 
plants were counted. For each isolate four reps were carried out.

Results

Collected isolates
Of all the soil samples collected from the surveyed nurseries 43 isolates (Tab. 1) clas-

sified as Rhizoctonia were obtained, 24 isolates from forest nursery belonging to Jarocin 
Forest District, 8 from Łopuchówko, 7 from Pniewy and 4 from Konstantynowo.

All the isolates were multinucleate, that is representing R. solani anamorph. No 
binucleate or uninucleate Rhizoctonia were found in the surveyed nurseries. The lowest 
average number of nuclei was observed in AG1-IC isolates obtained from Konstantynowo 
(Tab. 2). The highest number of nuclei per cell was observed in AG-5 isolates obtained from 
Jarocin, with the average number of 9.5 nuclei per cell (AG-5 isolates from Łopuchówko 
and Pniewy average 8.853 and 8.637 nuclei per cell, accordingly). Rhizoctonia AG2-1 
was characterized by the average number of 6.02 nuclei per cell while AG4-HG2 by 5.5 
and 7.268 nuclei per cell (Jarocin and Łopuchówko, accordingly).

Characteristics of Rhizoctonia isolates
MYCELIUM GROWTH RATE. On average, isolates belonging to AG-5 were charac-

terized by the fastest growth within all isolates (13.9 mm/24 h), and the slowest growing 
were those assigned to AG4-HG2 (8.91 mm/day). The greatest differences in growth were 
observed within AG-5, and the least within AG4-HG2 (Fig. 1).

PATHOGENICITY OF RHIZOCTONIA ISOLATES. Differentiation within anas-
tomosis groups in terms of pathogenicity was statistically significant for all nurseries (at 
a confidence level of 0.001; Fig. 2). All isolates, regardless of the place of origin of the 
individual anastomosis groups, were characterized by high pathogenicity to pine seedlings.

The most pathogenic isolates proved those belonging to AG-5 isolated from Łopuchówko 
(100% mortality). The least pathogenic ones were found to be AG4-HGII isolates, wherein 
the average pathogenicity of all the isolates tested was 92.81% (Fig. 2).

ANASTOMOSIS GROUPS. Rhizoctonia isolates obtained in the study have been first 
separated based on morphological differences and the number of nuclei per cell. After 
the DNA extraction and restriction enzymes digestion of RFLP of rDNA-ITS regions 
the results of electrophoresis were checked under the UV light, and the resulting pat-
terns were compared with those presented in the work of Guillemaut et al. [38] (Fig. 2). 



283© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

No. Isolate Anamorph Teleomorph
Anastomosis 
group/subset Accession No.

Percentage 
sequence 

simillarity

Konstantynowo

1 140712 R. solani T. cucumeris AG1-IC FJ746941.1 99
2 140711 R. solani T. cucumeris AG1-IC FJ746941.1 99
3 140707 R. solani T. cucumeris AG1-IC FJ746941.1 99
4 140729 R. solani T. cucumeris AG1-IC FJ746941.1 99

Jarocin

5 130750 R. solani T. cucumeris AG-5 GU055587.1 99
6 130711 R. solani T. cucumeris AG-5 GU055587.1 99
7 130724 R. solani T. practicola AG4-HG2 AB000032.1 99
8 130725 R. solani T. practicola AG4-HG2 AB000032.1 99
9 130728 R. solani T. practicola AG4-HG2 AB000032.1 99

10 130714 R. solani T. practicola AG4-HG2 AB000032.1 99
11 130704 R. solani T. practicola AG4-HG2 AB000034.1 99
12 130703 R. solani T. practicola AG4-HG2 AB000034.1 99
13 130733 R. solani T. cucumeris AG2-1 AY154317.1 99
14 130710 R. solani T. cucumeris AG2-1 AY154317.1 99
15 130734 R. solani T. cucumeris AG2-1 AY154317.1 99
16 130712 R. solani T. cucumeris AG2-1 AY154317.1 99
17 130707 R. solani T. cucumeris AG2-1 FJ492102.3 99
18 130745 R. solani T. cucumeris AG2-1 AY154317.1 99
19 130752 R. solani T. cucumeris AG2-1 FJ492102.3 99
20 130718 R. solani T. cucumeris AG2-1 FJ492102.3 99
21 130744 R. solani T. cucumeris AG2-1 AB054853.1 99
22 130713 R. solani T. cucumeris AG2-1 AY154317.1 99
23 130723 R. solani T. cucumeris AG2-1 AY154317.1 99
24 130729 R. solani T. cucumeris AG2-1 AY154317.1 99
25 130772 R. solani T. cucumeris AG2-1 AY154317.1 99
26 130764 R. solani T. cucumeris AG2-1 AY154317.1 99
27 130765 R. solani T. cucumeris AG2-1 FJ492102.3 99
28 130794 R. solani T. cucumeris AG2-1 FJ492102.3 99

Łopuchówko

29 150711 R. solani T. practicola AG4-HG2 AB000020.1 99
30 150708 R. solani T. practicola AG4-HG2 AB000020.1 99
31 150703 R. solani T. practicola AG4-HG2 HQ629864.1 99
32 150710 R. solani T. practicola AG4-HG2 AB000020.1 99
33 150712 R. solani T. practicola AG4-HG2 HQ629864.1 99
34 150702 R. solani T. cucumeris AG-5 EU244843.1 99
35 150707 R. solani T. cucumeris AG-5 EU244843.1 99
36 150709 R. solani T. cucumeris AG-5 EU244843.1 99

Tab. 1 Anastomosis groups and species of Rhizoctonia isolates studied.



284© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

On this basis, the isolates were assigned to particular anastomosis groups. It has also been 
verified by comparing the ITS-rDNA sequences of all isolates with sequences deposited 
in GenBank (Tab. 1).

Isolates assigned to AG1-IC have only been found in Konstantynowo. They were 
characterized by the largest similarity to the isolates deposited in the GenBank database 
under FJ746941.1 accession number. The isolate deposited in GenBank has been isolated 
from zoysiagrass (Zoysia sp.) where it has been a causal agent of large patch disease.

Jarocin’s isolates assigned to AG-5 showed a high homology (99%) with isolate 
GU055587.1, obtained from agricultural soil from Lower Austria. AG-5 isolate obtained 
from Łopuchówko was similar in 99% to those obtained from Switzerland (EU244843.1), 
whereas those obtained from Pniewy showed high homology with isolates HQ898767.1, 
associated with potato tubers in France, and isolate HQ629863.1 affecting Pisum sativum 
in North Dakota.

No. Isolate Anamorph Teleomorph
Anastomosis 
group/subset Accession No.

Percentage 
sequence 

simillarity

Pniewy

37 160710 R. solani T. cucumeris AG-5 HQ898767.1 99
38 160702 R. solani T. cucumeris AG-5 HQ629863.1 99
39 160704 R. solani T. cucumeris AG-5 HQ629863.1 99
40 160712 R. solani T. cucumeris AG-5 HQ898767.1 99
41 160703 R. solani T. cucumeris AG-5 HQ898767.1 99
42 160729 R. solani T. cucumeris AG-5 HQ898767.1 99
43 160705 R. solani T. cucumeris AG-5 HQ898767.1 99

Tab. 1 (continued)

Anastomosis 
group

Jarocin Konstantynowo Łopuchówko Pniewy
Mean s.d. Mean s.d. Mean s.d. Mean s.d.

AG-5 9.50a 0.707      8.853a 1.263  8.637 0.989
AG1-IC  4.700 0.294
AG2-1 6.02b 0.830
AG4-HG2 5.50b 0.775 7.268a 1.345

NIR0.05 1.69 2.36
P > F <0.001       0.151      

Tab. 2 The average number of nuclei per cell in different anastomosis groups (mean value and 
standard deviation – s.d.; univariate analysis followed by NIR test was carried out only for two 
nurseries).



285© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

Fig. 1 Growth rate of different anastomosis groups of Rhizoctonia spp. used in the study (Box-
and-Whisker Plot: upper whisk – highest value; upper quartile; median; lower quartile; lower 
whisk – lowest value).

Fig. 2 Pathogenicity of isolates of Rhizoctonia spp. belonging to different anastomosis groups 
(Box-and-Whisker Plot: upper whisk – highest value; upper quartile; median; lower quartile; lower 
whisk – lowest value).



286© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

Isolates described in this work as AG4-HG2 were found in two nurseries – Jarocin and 
Łopuchówko. From among AG4-HG2 isolates from Jarocin four were highly similar to 
AB000032.1, whereas two were more similar to AB000034.1. Both sequences deposited 
in GenBank were obtained from Inner Mongolia. Isolates from Łopuchówko were most 
similar to HQ629864.1 isolated from Pisum sativum in North Dakota (isolates 150703 
and 150712) and AB000020.1 isolated from potato in Inner Mongolia (isolates 150708, 
150710, 150711). The biggest number of isolates (16) obtained in this study belonged 
to AG2-1. All of them were isolated from Jarocin. They were highly homological with 
AY154317.1, FJ492102.3 and AB054853.1 deposited in GenBank. Unfortunately, in the 
GenBank database there is no information from what plant isolate AY154317.1 has 
been obtained. The isolate FJ492102,3 was isolated from sugar beet in the USA. Isolate 
deposited in the GenBank under the number AB054853.1 has been obtained in Italy 
from Nicotiana tabacum.

Discussion

In this study, 43 Rhizoctonia isolates were obtained from four forest nurseries and their 
anastomosis groups (AGs) and anastomosis subgroups were determined. They all proved 
to be R. solani, a species widely distributed in Polish forest nurseries. Our understanding 
concerning the occurrence of Rhizoctonia anastomosis groups in Polish forest nurseries is 
very scarce. Knowledge of Rhizoctonia spp. AGs occurring in the nursery could facilitate 
the selection of plant protection methods and products to protect the seedlings against 

Fig. 3 Example of RFLP analysis of the ITS rDNA region for isolates of 150707, 150709 and 
160705 (AG-5) of Rhizoctonia solani amplified with primers ITS4 and ITS5 and digested with MunI.



287© The Author(s) 2014 Published by Polish Botanical Society Acta Mycol 49(2):279–290

Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

these pathogens. The results of some studies [40–42] point to different sensitivity to 
fungicides of isolates belonging to different AGs. On the other hand, the works of Herr 
[43] and Sharon et al. [44] suggest the possibility of using non-pathogenic strains as 
biological control agents against highly pathogenic strains of Rhizoctonia.

Pathogenicity tests of different AGs to Scots pine and Norway spruce (Picea abies) 
carried out on uninucleate isolates confirm that they are the causing agents of damping-
off in many Finnish nurseries [45–47]. At the same time from Norwegian and Finnish 
forest nurseries uninucleate and binucleate strains of Rhizoctonia have been isolated 
from healthy seedlings of Scots pine and Norway spruce [48–51]. So far, no uninucleate 
isolates were obtained from Polish forest nurseries.

In one of the few works on Rhizoctonia spp. in forest nurseries Camporota and Perrin 
[52] have demonstrated the predominant role of R. solani as the primary pathogen causing 
damping-off of pine seedlings. This is also confirmed by our study where all the obtained 
isolates proved to be multinucleate. So far, 14 anastomosis groups (AG-1 to AG-13 and 
AG-B1) have been described within multinucleate Rhizoctonia [53]. Eight groups (AG-1 
to AG-6, AG-8 and AG-9) were further subdivided into subgroups. From among those 
Stępniewska-Jarosz et al. [6] found five different anastomosis groups in Polish forest 
nurseries. The most frequent was AG-5 (37% of isolates), followed by AG 2-1 (30%) 
and 27% of the isolates were identified as AG-4. Groups AG 1-IB and AG 2-2 were only 
represented by single isolates. In our study one of the nurseries (forest nursery Jarocin) 
examined earlier by Stępniewska-Jarosz et al. [6], was surveyed for Rhizoctonia spp. for 
the second time and no binucleate isolates were found. Two AGs found in the previous 
study were also isolated: AG-5 (2 isolates) and AG 2-1 (16 isolates), while the AG4-HG2 
(6 isolates) has not been previously observed. The difference may result from possible 
bridging of some isolates belonging to certain AGs with isolates belonging to the other 
[24] in the meantime and/or from the fact that different techniques were used to assign 
isolates to certain AGs. While Stępniewska-Jarosz et al. [6] used classic techniques, with 
culture of isolates in vitro and subsequent observation of their growth under microscope, 
our study was fully based on molecular methods.

Though the anastomosis groups differed significantly from each other in terms of 
pathogenicity, all the isolates studied proved to be highly pathogenic to Scots pine seed-
lings. This means that the AGs in question may contribute to considerable damping-off 
threat to the seedlings in all the nurseries.

As most of the research on Rhizoctonia in Poland has been conducted on agricultural 
plants, it is highly desirable to further screen forest nurseries for the pathogen as well, 
both for better recognition of the situation and for the hope of finding non-pathogenic 
or mutualistic species, which could possibly contribute to decreasing the infection threat.

Acknowledgments
The authors thank two anonymous reviewers for useful comments improving the manuscript. This work was 
due to grant financed by the Ministry of Science and Higher Education No. N N309 134335.

Authors’ contributions
The following declarations about authors’ contributions to the research have been made: collected material, 
laboratory works, photographs, statistics, bibliography, draft of the manuscript: MB; helped writing the 
manuscript, critical revising: MM.



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Bełka and Mańka / Rhizoctonia spp. in forest nurseries 

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	Abstract
	Introduction
	Material and methods
	Collecting isolates
	Rhizoctonia identification

	Results
	Collected isolates
	Characteristics of Rhizoctonia isolates

	Discussion
	Acknowledgments
	Authors’ contributions
	References

		2014-12-31T17:44:22+0000
	Polish Botanical Society