Microbiology Independent Research Journal (MIR Journal)

Advanced search

Adaptation of the quantitative PCR method for the detection of the main representatives of cereal grain mycobiota

Full Text:


The content of fungal DNA and mycotoxins in cereal crops (31 varieties of wheat, oats, and barley) was quantitatively determined and used for comparative characterization of grains. The quantitative PCR has been adapted for the analysis of the target DNA of Alternaria spp., Bipolaris sorokiniana (B. sorokiniana), Fusarium graminearum (F. graminearum), F. culmorum, and F. sporotrichioides fungi, which are often present in mycobiota of small grain cereals. The content of DNA of aggressive pathogen B. sorokiniana was determined using quantitative PCR for the first time.
The DNA of Alternaria fungi was found abundantly in all grain samples, but its content in the oat was significantly higher compared to barley and wheat (5 and 9 times higher, respectively). In barley grain, the content of B. sorokiniana DNA was on average significantly higher than in the grains of oats and wheat. The presence of F. graminearum DNA was established in all the analyzed grain samples while the F. culmorum DNA was found in 70% of the oat’s samples and in all samples of barley and wheat. Mycotoxin deoxynivalenol (DON) produced by these fungi was detected in all analyzed cereal grains in a range from 77 to 4133 μg/kg. The DNA of F. sporotrichioides was detected in 70% of oats and 50% of barley samples but was not found in wheat. The T-2 toxin produced by this fungus was detected in 45% of all samples within the range from 2 to 89 μg/kg.
The statistically significant positive correlation with the Pearson correlation coefficient (r) equal to 0.49 (p<0.05) was observed between the amount of F. graminearum DNA and DON in the grain samples. Another significant positive correlation (r = 0.72, p<0.01) was found between DNA contents of Alternaria fungi and F. sporotrichioides in the grain samples. This leads to the suggestion that conditions for growth of these fungi in grain substrates are similar.

For citations:

Orina A.S., Gavrilova O.P., Gagkaeva T.Yu. Adaptation of the quantitative PCR method for the detection of the main representatives of cereal grain mycobiota. Microbiology Independent Research Journal (MIR Journal). 2018;5(1):78-83.


The microbiological quality of grain is generally characterized by the percentage of infected grains. However, fungi are able to penetrate into the inner tissues of grain to different depths and localize in glumes including the lemma and palea, in the aleurone layer, or completely infect the endosperm and germ. The depth of penetration into the grain depends on various factors (species of cereals, resistance, time of infection, environmental conditions, aggressiveness of fungus, etc.). Therefore, a percentage of infected grain, which is determined as a result of the mycological analysis, is usually not directly related to the grain colonization depth and content of mycotoxins that are produced by fungi [1][2]. This problem is especially important in case of husked small grain cereals (oats and barley), since their glumes are often abundantly colonized by different fungi, while the aleurone layer and endosperm are only slightly contaminated. In addition, the duration of the analysis of the fungal infection of the grain by the microbiological method (7-14 days) and the dependence of the results of the analysis from the subjective evaluation of the researchers add to the complexity of this method.

The quantitative analysis of the presence of pathogens in grain and the identification of the patterns of infection of the plants in different conditions (annual fluctuations of weather conditions and changes in agriculture technology) are of topical importance. The basic modern method of the quantitative analysis of the content of fungi in grain is a real-time or quantitative PCR (qPCR). This method is based on the use of fungal DNA fragments as molecular markers and allows estimating the quantity of target DNA for a certain pathogen or a group of similar pathogens [1][3-6].

The use of the qPCR method allows revealing fungi in plant material, even if the pathogen has lost its viability and has not been detected by the traditional microbiological method. The amount of fungal DNA detected in grain, while being dependent on the biomass of the fungus, is the most correct indicator of the presence of pathogen in grain. This parameter can be used for the reliable predicting of the presence of mycotoxins in grain. In addition, qPCR has some advantages over microbiological methods, such as the objectivity of quantitative assessment, high sensitivity, and speed of analysis as well as the possibility of simultaneous analysis of a large number of samples.

The goal of this study was the adaption of the qPCR method for the estimation of the DNA amount of the most common fungi in grain mycobiota: Alternaria Nees, Bipolaris Shoemaker and Fusarium Link.

Materials and Methods

Samples of grain

In 2016, a variety of small grain cereals were sown at the Volosovo State Experimental Station (Leningrad region, Russia). These cereals were represented by 10 varieties of oats: Avatar (Russia), Borrus (Germany), Vsadnik (Russia), Zalp (Russia), KWS Kontender ( Germany), Medved (Russia), Ozon (Germany), Privet (Russia), Stipler (Russia) and Yakov (Russia); 9 wheat varieties: Vellamo (Russia), Calixo (France), Leningradskaya 6 (Russia), Leningradskaya 12 (Russia), Leningradskaya 97 (Russia), Likamero (France), Marble (Canada), Sudarynya (Russia) and Trizo (Germany); and 12 varieties of barley: Bente (Germany), Despina (Germany), Inari (Finland), Krinichniy (Belarus), Leningradskiy (Russia), Moscowskiy 86 (Russia), Nord 132523 (Germany), Olympic (France), Salome (Germany), Suzdalets (Russia), Fest (Belarus) and Cherio (Denmark). All the seeds were not treated with any fungicides before the sowing. The cereals were cultivated according to the standard technology.

The 10 g of harvested grain samples of every variety were homogenized in sterile grinding cups using a Tube Mill Control (IKA, Germany) for 30 s at a rate of 20,000 rpm. The obtained flour samples were stored at -20℃. The subsequent isolation of the total DNA and extraction of mycotoxins from these samples were performed using 200 mg and 1 g of the corresponding flour, respectively.

Mycological analysis of grain

In order to identify the main groups of pathogens in grain mycobiota and to determine their DNA content using qPCR, the mycological analysis of six grain samples of different varieties (two of each individual species) was carried out. The 100- 200 grains of each sample were surface sterilized with 5% sodium hypochlorite solution for 1-3 min. Then, the grains were washed with sterile water and put into Petri dishes on potato sucrose agar (PSA) medium containing 1 μl/l of a mixture of antibiotics (HyClone™, GE Healthcare Life Sciences, Austria) that suppressed the growth of bacteria and 0.4 μl/l of Triton X-100 solution (Panreac, Spain) that reduced the linear growth of mycelial fungi [2].

After 7 days of incubation in the dark at 24℃, the species composition of fungi was identified and the number of colonies counted. The taxonomic status of isolated fungi was determined according to the sum of their macro- and micromorphological features [7]. The fungal infection rate of the grain was calculated as the ratio of the number of grains from which these fungi were isolated to the total number of analyzed grains, and expressed as a percentage.

DNA isolation and qPCR

The total DNA from grain flour was isolated using the Genomic DNA Purification Kit (Thermo Fisher Scientific, Lithuania) according to the modified manufacturer’s protocol. Using the same kit, DNA was also isolated from the mycelium of typical strains of Alternaria tenuissima (A. tenuissima) (Nees et T. Nees: Fr.) Wiltshire (MFP556081), B. sorokiniana Shoemaker (MFG59013), F. graminearum (MFG58775), F. culmorum (Wm.G. Sm.) Sacc. (MFG102100), F. sporotrichioides Sherb. (MGF163303) grown on PSA. All the typical strains of fungi are maintained in the Collection of the Laboratory of Mycology and Phytopathology of All-Russian Institute of Plant Protection (St. Petersburg, Russia).

The concentrations of DNA obtained from both the flour samples and typical strains were evaluated using a Qubit 2.0 fluorimeter with a Quant – iT dsDNA HS Assay Kit (Thermo Fisher Scientific, USA). All 31 varieties of small grain cereals were analyzed by qPCR. The concentration of DNA isolated from the flour samples was leveled to 2-50 ng/μl. The native DNA solutions of representative strains of fungi were diluted to a concentration of 10 ng/μl and used to construct a calibration curve.

The DNA amounts of F. graminearum and Alternaria fungi were evaluated by qPCR with TaqMan probes. The reaction was carried out in a 20 μl volume containing 10 μl of a 2× TaqMan Master Mix (AlkorBio, Russia), 300 nM of each primer, 100 nM of a fluorescent probe (Evrogen, Russia) and 2 μl of the corresponding DNA solution. The DNA amounts of F. culmorumF. sporotrichioides and B. sorokiniana were determined using qPCR with SYBR Green. The reaction was carried out in a 20 μl volume containing 4 μl of a 5× qPCRmix-HS SYBR Master Mix (Evrogen, Russia), 500 nM of each primer and 2 μl of DNA solution. The primer sequences and amplification protocols are presented in Table 1. The reactions were carried out on a CFX96 Real-Time System thermal cycler (BioRad, USA), and the primary data were processed using Bio-Rad CFX Manager 1.6 software.

Table 1. Sequences of primers and probes, qPCR amplification protocols used in the study


Name of the primers and probes

Sequences of primers and probes, 5’– 3’

Amplification protocols


F. graminearum



95℃ – 15 min; [95℃ – 15 s; 60℃ – 60 s]×40






F. culmorum



50℃ – 2 min, 95℃ – 10 s, []×40





F. sporotrichioides



95℃ – 3 min, []×40




Alternaria spp.



95℃ – 3 min; [95℃ – 10 s; 60℃ – 60 s; 72℃ – 3 s]×40

[5, 9]





B. sorokiniana



95℃ – 3 min; [95℃ – 10 s; 68℃ – 20 s; 72℃ – 45 s]×40




a The amplification protocol was modified.

The amount of fungal DNA was expressed as a fraction of the total DNA isolated from cereal flour (pg/ng total DNA). The lower limit of detection of the fungal DNA content in the total DNA sample was set at 5×10-4 pg/ng of total DNA.


The content of two mycotoxins – deoxynivalenol (DON) produced by F. graminearum and F. culmorum, and T-2 toxin produced mainly by F. sporotrichioides – were determined by enzyme linked immuno-sorbent assay (ELISA). Mycotoxins were extracted from 1 g of the flour sample by the addition of 5 ml of the mixture of acetonitrile and water (84:16, v/v), and constantly shaken on the S-3M (ELMI, Latvia) at  300 rpm for 14-16 h. The analysis was performed using two diagnostic test systems for an indirect solid-phase competitive ELISA – “Deoxynivalenol-ELISA” and “T-2 toxin-ELISA” (Institute of Veterinary Sanitation, Hygiene and Ecology (VNIIVSGE), Russia) with a detection limits of 20 and 4 μg/kg, respectively. The standards of mycotoxins diluted with acetonitrile to concentration of 1 μg/ml (VNIIVSGE, Russia) were used to prepare the calibration curves. ELISA was carried out on polystyrene plates (Biomedical, Russia). The optical density of final solutions was determined spectrophotometrically on a LEDETECT 96 (Biomed, Austria) at 492 nm.

Statistical analysis

All of the laboratory tests were performed at least twice. The mean values with the standard error of the mean (M ± SEM) were calculated. The results were processed using the statistical software Microsoft Excel 2010 and STATISTICA 10.0. The relationship between the quantitative traits was evaluated using the linear Pearson correlation coefficient (r) at a significance level of p<0.01 or p<0.05. The coefficient of variation (CV, %) was defined as the ratio of the standard deviation to the mean.


Mycological analysis showed an abundant presence of Alternaria and Fusarium fungi in all of the grain samples (Table 2). The B. sorokiniana was detected in the oat and barley grain samples but not in wheat. In addition to these representatives of mycobiota, some other fungi were isolated from the grain samples: Microdochium Syd. & P.Syd., Aureobasidium Viala & G.Boyer, Epicoccum Link and Trichothecium roseum (Pers) Link.

Table 2. The fungal infection of the grain samples revealed by the mycological analysis

Species of small grain cereals


Grain infected by fungi, %







T. roseum




















































The DNA of Alternaria fungi was detected in all of the analyzed grain samples. On average, the grains of different varieties of oats contained 5 and 9 times more DNA of Alternaria fungi compared with the samples of grain of barley and wheat varieties, respectively (Fig. 1). The smallest amount of Alternaria DNA was detected in the Triso wheat grain (184×10-4 pg/ng of total DNA), and the highest amount (11160×10-4 pg/ng) was found in the grain of oat of Ozon variety.

Fig. 1. Amounts of Alternaria DNA in oat, barley, and wheat grain samples. Data are presented as the mean value with the standard error of the mean (M ± SEM) and the confidence interval at a significance level of 0.05.

The quantitative estimation of B. sorokiniana infection of grain harvested in Russia was carried out using qPCR (Fig. 2) for the first time. In our study, the molecular primers that originally have been developed for the qualitative detection of DNA of this pathogen in grain [10], were successfully adapted for its quantitative analysis. According to the obtained results, B. sorokiniana DNA was detected in 100% of the barley and oats grain samples, but only in 56% of wheat grain samples. On average, the amount of B. sorokiniana DNA in the barley samples was significantly higher compared to the grain of oats and wheat. The highest amount of B. sorokiniana DNA (648×10-4 pg/ng) was detected in the grain of Olympic barley.

Fig. 2. Amounts of B. sorokiniana DNA in oat, barley, and wheat grain samples. Data are presented as the mean value and the standard error of the mean (M ± SEM) and the confidence interval at a significance level of 0.05. 

DNA of F. graminearum was detected in the grain of all the analyzed samples (Table 3). The maximum amount of F. graminearum DNA was found in barley grain of Fest variety (1110×10-4 pg/ng). F. culmorum DNA was detected in 70% of oat samples and 100% of barley and wheat samples. The oats grain of Medved variety contained the highest amount of the DNA of this fungus (90×10-4 pg/ng). The DNA of F. sporotrichioides was not detected in any wheat grain samples but was found in 70% of the oat samples and in 50% of the barley samples. On average, F. sporotrichioides DNA was detected in lower amounts (up to 47×10-4 pg/ng) compared with the DNA of other species of Fusarium fungi.

Table 3. Amounts of Fusarium fungi DNA and mycotoxins in the grain samples 


Analyzed fungus or toxin

Amounts of fungal DNA×10-4, pg/ng of total DNA and mycotoxins, µg/kg




n+а, %

Mean (range)

n+, %

Mean (range)

n+, %

Mean (range)

F. graminearum


76 (14-261)


170 (22-1,110)


203 (55-561)

F. culmorum


21 (8-90)


17 (9-43)


22 (11-39)

F. sporotrichioides


17 (5-47)


6 (6-26)





357 (9-666)


499 (77-2,154)


2318 (455-4,471)

Т-2 toxin


7 (5-12)


22 (3-89)


18 (2-38)

а n+ – number of grain samples containing the DNA of the analyzed fungus or mycotoxin

The DON mycotoxin was detected in all the analyzed grain samples in the range from 77 to 4,133 µg/kg, while T-2 toxin was found in only 45% of the samples in amounts from 2 to 89 µg/kg.

A comparative analysis of the contamination of the grain with mycotoxins showed that the amount of DON in the samples of wheat was significantly higher than in the samples of oats and barley. The content of T-2 toxin in barley grain samples was 7 and 3 times higher compared with the samples of oats and wheat, respectively.

The minimum quantity of DON was found in Leningradskiy barley grain, while the wheat grain of the Calixo variety contained the highest amount of this mycotoxin. In some grain samples, a strong correlation between the high content of F. graminearum and F. culmorum DNA and a high amount of DON was observed. In some cases, the revealed levels of DON exceeded the maximum permissible concentration (MPC) of this mycotoxin – 700-1,000 µg/kg – the accepted standard for grain and grain-based food products [11]. The number of grain samples with the amount of DON exceeding the MPC reached 32% (barley Moscowskiy 86 and Fest as well as all the wheat varieties except Leningradskaya 6). The amount of T-2 toxin in all the grain samples contaminated with this mycotoxin was below the established MPC (100 µg/kg) [11]. The maximum amount of T-2 toxin (89 µg/kg) was found in the grain of Cherio malt barley.

The statistical analysis of the experimental data revealed a significant positive correlation (r=0.49, p<0.05) between the amount of F. graminearum DNA and the amount of DON in grain samples. At the same time, there was not detected any correlation between the amount of F. culmorum DNA, which is another DON-producer, and the amount of this mycotoxin. It was noted earlier by Hofgaard et al. [12] that F. culmorum produced significantly smaller amounts of DON compared to F. graminearum [13].

Interestingly, a strong positive correlation (r=0.72, p<0.01) between the quantities of the DNA of Alternaria and F. sporotrichioides fungi was revealed, which implies that the conditions for their development on grain substrate are similar. In a previous study, we already showed that there is some symbiotic relationship between aggressive Fusarium fungi and relatively weak pathogens as Alternaria fungi, which are arising during the colonization of oat grains [14].


The fungi of the genus Alternaria have a broad host range but, the information about their harmfulness is controversial so far. In our study, we showed that the levels of contamination of studied varieties of small grain cereals with Alternaria fungi differ. However, among the same plant species the coefficients of variation (CV) of fungal DNA content were similar (41-68%), which indicates the absence of a differentiated interaction in the system “cereals – Alternaria spp.”.

The B. sorokiniana is a harmful pathogen for cereal crops, especially for barley – it causes a decrease in grain germination, leaf spot, and root rot. According to the data of mycological analysis only oats and barley grains were infected by this pathogen, on the contrary to the analyzed wheat samples. The results obtained by qPCR confirmed a significant DNA amount of B. sorokiniana in barley grain that exceeded its content in the grain of oats and wheat 8 and 40 times, respectively.

The analysis of the DNA content of F. graminearum, F. culmorum, and F. sporotrichioides as well as the dangerous mycotoxins produced by these fungi were carried out. It was shown that the amount of F. sporotrichioides DNA in grain samples was low as well as the content of T-2 toxin produced by this fungus. Significant contamination of grains with DON, especially of wheat samples, was associated with a high amount of F. graminearum DNA detected in these samples. A reliable correlation between the content of the fungal DNA and that of the mycotoxin produced by this fungus enables to use the qPCR method for the quick characterization of breeding material. Therefore, this method can be successfully used when creating new resistant varieties, for assessing the fungicides effectiveness, and for monitoring agricultural commodities as well as foods and feeds for the presence of a fungal contamination. Quantitative PCR is a convenient and reliable method for the analysis of the relationship between plants and diverse representatives of mycobiota. This method allows detecting the content of pathogens in grain and to assess the effects of various conditions on their content over time and, therefore, helps determining the effectiveness of measures focused on plant protection from dangerous pathogens.


Quantitative PCR is an appealing technology for the detection of plant pathogens, but the detection of mycotoxin producers is particularly challenging. The adapted qPCR enables quantifying the presence of pathogenic fungi F. graminearumF. culmorumF. sporotrichioidesB. sorokiniana, and widespread representatives of Alternaria spp. in the harvested grain samples of different varieties of wheat, oat, and barley. The abundant content of Alternaria fungi, the ecological significance of which is still not precisely known, was found in all of the analyzed grain samples. The B. sorokiniana DNA was detected in the grain of all cereals; however, the amount of DNA of this pathogen in the barley grain was significantly higher compared with the oat and wheat grain samples. It was shown that the high DNA amount of F. graminearum in grain samples reliably correlated with the significant contamination of the grain with DON.


1. Yli-Mattila T, Paavanen-Huhtala S, Jestoi M, Parikka P, Hietaniemi V, Gagkaeva T, Sarlin T, Haikara A, Laaksonen S, Rizzo A. Real-time PCR detection and quantification of Fusarium poae, F. graminearum, F. sporotrichioides and F. langsethiae in cereal grains in Finland and Russia. Arch Phytopathol Plant Protect, 2008; 41(4). 243–60. doi: 10.1080/03235400600680659.

2. Shipilova NP, Gavrilova OP, Gagkaeva TYu. Quality of winter wheat grain infected by Fusarium fungi. Plant Protection News, 2014; (4), 27–31 [In Russian].

3. Nicholson P, Simpson DR, Weston G, Rezanoor HN, Lees AK, Parry DW, Joyce D. Detection and quantification of Fusarium culmorum and Fusarium graminearum in cereals using PCR assays. Physiol Mol Plant Pathol, 1998; 53, 17–37. doi: 10.1006/pmpp.1998.0170.

4. Stakheev A, Ryazantsev DYu, Gagkaeva TYu, Zavrieva SK. PCR detection of Fusarium fungi with similar profiles of the produced mycotoxins. Food Control, 2011; (22), 462–8. doi: 10.1016/j.foodcont.2010.09.028.

5. Gagkaeva TYu, Gavrilova OP, Orina AS, Blinova EV, Loskutov IG. Response of wild Avena species to fungal infection of grain. The Crop Journal, 2017; 5(6), 499–508. doi: 10.1016/j.cj.2017.04.005.

6. Orina AS, Gavrilova OP, Gagkaeva TYu. Colonization of cultivated and wild grasses with the Alternaria, Cladosporium and Fusarium fungi. Plant protection and quarantine, 2017; (6), 25–7 [In Russian].

7. Ellis MB. Dematiaceos hyphomycetes. Kew: Commonwealth Mycological Institute; 1971.

8. Yli-Mattila T, Paavanen-Huhtala S, Parikka P, Konstantinova P, Gagkaeva TY. Molecular and morphological diversity of Fusarium fungi in Finland and northwestern Russia. Eur J Plant Pathology, 2004; 110, 573–85. doi: 10.1023/B:EJPP.0000032397.65710.69.

9. Pavón MÁ, González I, Martín R, García Lacarra T. ITS-based detection and quantification of Alternaria spp. in raw and processed vegetables by real-time quantitative PCR. Food Microbiol; 2012; 32(1), 165– 71. doi: 10.1016/

10. Matusinsky P, Frei P, Mikolasova R, Svacinova I, Tvaruzeka L, Spitzera T. Species-specific detection of Bipolaris sorokiniana from wheat and barley tissues. Crop Protection, 2010; 29, 1325–30. doi: 10.1016/j.cropro.2010.07.013.

11. Sanitary Rules and Regulations–01 Hygienic requirements for safety and nutritional value of food products; Russian Federation, 2002.

12. Hofgaard IS, Aamot HU, Torp T, Jestoi M, Lattanzio VMT, Klemsdal SS, Waalwijk C, van der Lee T, Brodal G. Associations between Fusarium species and mycotoxins in oats and spring wheat from farmers’ fields in Norway over a six-year period. World Mycotoxin J, 2016; 9(3), 365–78. doi: 10.3920/WMJ2015.2003.

13. Desjardins AE. Fusarium Mycotoxins. Chemistry, Genetics, and Biology. St. Paul: American Phytopathological Society; 2006. doi: 10.1111/j.1365-3059.2006.01505.x.

14. Orina AS, Gavrilova OP, Gagkaeva TYu, Loskutov IG. Symbiotic relationships between aggressive Fusarium and Alternaria fungi colonizing oat grain. Agricultural Вiology (Sel’skokhozyaistvennaya Biologiya), 2017; 52 (5), 986–94. doi: 10.15389/agrobiology.2017.5.986eng.

About the Authors

A. S. Orina
All-Russian Institute of Plant Protection
Russian Federation

Aleksandra Orina

St. Petersburg, Pushkin

O. P. Gavrilova
All-Russian Institute of Plant Protection
Russian Federation
St. Petersburg, Pushkin

T. Yu. Gagkaeva
All-Russian Institute of Plant Protection
Russian Federation
St. Petersburg, Pushkin


For citations:

Orina A.S., Gavrilova O.P., Gagkaeva T.Yu. Adaptation of the quantitative PCR method for the detection of the main representatives of cereal grain mycobiota. Microbiology Independent Research Journal (MIR Journal). 2018;5(1):78-83.

Views: 202

ISSN 2500-2236 (Online)