Toxigenicity of F. graminearum Residing on Host Plants Alternative to Wheat as Influenced by Environmental Conditions
by
, , , ,
Sigita Janaviciene
1,*
,
Skaidre Suproniene
1,
Grazina Kadziene
1
,
Romans Pavlenko
2
,
Zane Berzina
2 and
Vadims Bartkevics
2 1
Institute of Agriculture, Lithuanian Research Centre for Agriculture and Forestry, LT-58344 Akademija, Lithuania
2
Institute of Food Safety, Animal Health and Environment “BIOR”, Lejupes Iela 3, LV-1076 Riga, Latvia
*
Author to whom correspondence should be addressed.
Toxins 2022, 14(8), 541; https://doi.org/10.3390/toxins14080541
Submission received: 15 July 2022
/
Revised: 5 August 2022
/
Accepted: 5 August 2022
/
Published: 8 August 2022
(This article belongs to the Section Mycotoxins)
Abstract
:Fusarium graminearum is an important pathogen that causes Fusarium head blight (FHB) in several cereal crops worldwide. The potential of this pathogen to contaminate cereals with trichothecene mycotoxins presents a health risk for both humans and animals. This study aimed to evaluate the potential of different trichothecene genotypes of F. graminearum isolated from an alternative host plant to produce mycotoxins under different spring wheat grain incubation conditions. Fourteen F. graminearum strains were isolated from seven alternative host plants and identified as 3-acetyl-deoxynivalenol (3-ADON) and 15-acetyl-deoxynivalenol (15-ADON) genotypes. These strains were cultivated on spring wheat grains at 25 °C and 29 °C for 5 weeks. The mycotoxins produced were analysed with a high-performance liquid chromatograph (HPLC) coupled to a Thermo Scientific TSQ Quantiva MS/MS detector. The obtained results showed that the F. graminearum strains from alternative host plants could produce nivalenol (NIV), deoxynivalenol (DON), fusarenon-X (FUS-X), 3-ADON, deoxynivalenol-3-ß-d-glucoside (D3G), 15-ADON, and zearalenone (ZEA). F. graminearum strains produced DON and ZEA under both temperatures, with the mean concentrations varying from 363 to 112,379 µg kg−1 and from 1452 to 44,816 µg kg−1, respectively. Our results indicated the possible role of dicotyledonous plants, including weeds, as a reservoir of inoculum sources of F. graminearum-induced Fusarium head blight, associated with the risk of mycotoxin contamination in spring wheat.
Key Contribution: This study indicated the possible role of dicotyledonous plants, including weeds, as a reservoir of inoculum sources of F. graminearum-induced Fusarium head blight, associated with the risk of mycotoxin contamination in spring wheat.
1. Introduction
Wheat is the third most important crop in the world, with annual production in 2021 amounting to 770 million tons [1], which should increase in the future to meet the growing demand resulting from the rising human population. This aligns with the United Nations Sustainable Development Goal of promoting sustainable agriculture that provides sufficient, safe, and high-quality food by 2030 [2].
Climate change poses serious challenges to global food security. Long-term changes in the temperature, humidity, precipitation, and extreme weather influence farming practices and the quality of food crops. The susceptibility of microorganisms, especially those producing toxins and other pests, to climate factors suggests that climate change may promote the occurrence and severity of some foodborne diseases [3]. Food security depends on the resistance of the main food crops to climate change and extreme conditions, but the resistance of wheat to these factors in Europe remains unknown [4]. In wheat, a 1 °C rise in minimum or maximum temperatures during the cropping season could decrease global wheat production by ~5.6% [5]. Crop losses of many types of cereals due to climate change and fungal infections are among the most important concerns worldwide. Fusarium graminearum is primarily perceived as an agricultural pathogen affecting monocotyledonous plants, but its hosts also include dicotyledonous plants and various weeds in the agricultural environment. In the absence of host plants, weeds may serve as reservoirs of high genetic diversity and provide sources of Fusarium head blight (FHB) infection for host plants [6,7,8]. Exposure to climate change can dramatically increase FHB infection and thus the concentration of deoxynivalenol (DON) mycotoxin in wheat and processed food products, which may pose a health risk to humans and animals [8].
Mycotoxins are widely distributed throughout the world [3,8,9,10,11]. It has been reported that 25–50% of the world’s crop yield is contaminated with mycotoxins yearly [10,12,13]. Mycotoxins are frequently found in Lithuania-grown grains of spring cereals [14,15,16]. One of the most prevalent mycotoxins in Lithuania and other European countries is type B trichothecene DON. However, factors promoting the formation of its metabolites 3-acetyl-deoxynivalenol (3-ADON) and 15-acetyl-deoxynivalenol (15-ADON) have not been sufficiently elucidated. Most studies on the genotypes and chemotypes of F. graminearum populations were carried out using fungal strains isolated from the primary host plants wheat, barley, and other small-grained cereals [11,17,18]. A comprehensive analysis of trichothecene genotypes and population diversity of F. graminearum strains isolated from alternative host plants (oilseed rape, sugar beet, and various weeds) was conducted in Lithuania in 2015–2018 [6]. This study demonstrated the ability of F. graminearum isolated from all asymptomatic dicotyledonous hosts to induce FHB in spring wheat [7]. The distribution of DON and its metabolites in spring cereals has been investigated to date. Still, the information on the ability of F. graminearum from asymptomatic host plants to produce trichothecenes is not yet available. Therefore, it is especially important to clarify the situation in this regard, as the toxicity of the metabolites of DON is different [19,20]. The dominant mycotoxins produced by F. graminearum are zearalenone (ZEA), DON and their derivatives; these mycotoxins are often identified in different cereals contributing to the reduction in grain quality and safety [21,22,23,24]. The presence of mycotoxins lowers grain prices and poses serious risks to human and animal health [25,26]. Scientists worldwide working on food quality and safety are seeking to develop a flexible modeling approach to mycotoxin risk assessment. This includes the effects of climate change (temperature, humidity, etc.) on the production of mycotoxins and their occurrence in food [20].
The potential for trichothecene production is still unclear, depending on how different environmental conditions may influence mycotoxin production and what the effects of environmental stress are on the occurrence profiles of secondary metabolites. It is widely known that different mycotoxin-producing fungal species differ in their preferred climatic conditions, leading to a wide variation in mycotoxin distribution worldwide. Climate change is expected to influence the spread of microscopic fungi, lead to changes in agricultural practices, and affect the distribution and levels of mycotoxins in crops [27]. A better understanding of the role of individual factors in the production of mycotoxins would help to assess the risks to food safety and to design preventive strategies in anticipation of climate change.
This research aims to evaluate the potential of different genotypes of F. graminearum isolated from alternative host plants to produce mycotoxins upon incubation on spring wheat grains under different conditions.
2. Results
All strains of F. graminearum were found to grow mycelium on spring wheat grains and to produce particularly high levels of mycotoxins in the grains. The spring wheat grains were inoculated with F. graminearum strains that produced NIV, DON, FUS-X, 3-ADON, D3G, 15-ADON, and ZEA. All the spring wheat grain samples (100%) were contaminated with DON and ZEA (Figure 1).
The investigated F. graminearum strains produced DON and ZEA under both conditions tested, with the mean concentrations varying from 363 to 112,379 µg kg−1 and from 1452 to 44,816 µg kg−1, respectively (Table 1). 15-ADON was detected in between 57% and 95% of the samples, and 3-ADON was detected in between 67% and 86% of the samples, depending on the incubation conditions and trichothecene genotype. 15-ADON and 3-ADON were produced in lower amounts, and the mean concentrations varied from <50 to 22,246 µg kg−1 and from <50 to 28,800 µg kg−1, respectively. There was some distinction between ZEN, DON, 3-ADON, and 15-ADON production among the F. graminearum strains, i.e., the strain of Triticum aestivum (6K4V1) was the most potent producer of ZEN, whereas the Poa annua L (1350s) and Tripleurospermum inodorum (L.) Sch. (1120p) strains were mainly responsible for the increased 3-ADON and 15-ADON production, respectively. All strains were the most effective producers of DON, with the highest amount of DON produced by the Brassica napus L. (425l) strain at the concentration of 223,532 µg kg−1. In the spring wheat grain samples, NIV was detected between 14% and 43%, while D3G in between 0% and 43% of samples, depending on the incubation temperature and trichothecene genotype. NIV and D3G were detected at very low concentrations or not detected at all. The highest NIV and D3G concentrations were 3015 µg kg−1 and 187 µg kg−1, respectively. Importantly, FUS-X was detected in between 28% and 100% of samples, with concentrations varying from <10 to 220 µg kg−1.
The simultaneous presence of DON and ZEA was found in 100% of the wheat samples incubated at both temperatures using both trichothecene genotype strains. Higher concentrations were found in grain samples incubated at 25 °C and inoculated with 15-ADON trichothecene genotype strains. However, the strains of the 3-ADON genotype also produced relatively high concentrations of DON and ZEA. It should be noted that elevated concentrations of DON and ZEA were also produced at 29 °C.
The strains of the 3-ADON genotype incubated at 25 °C temperature produced NIV, FUS-X, and 3-ADON at higher concentrations than the strains of the 15-ADON genotype (Table 1). The strains of the 15-ADON genotype produced DON, ZEA, 15-ADON, and D3G at higher concentrations than the strains of the 3-ADON genotype. The strains of the 3-ADON genotype incubated at 29 °C produced NIV and 3-ADON at higher concentrations than those of the 15-ADON genotype. The strains of the 15-ADON genotype produced DON, ZEA, 15-ADON, FUS-X, and D3G at higher concentrations than the 3-ADON genotype strains.
Regarding the strain-dependent potential for mycotoxin production, we found that all strains can produce DON in spring wheat grains incubated at 25 °C. Figure 2 shows the mycotoxin production potential and concentrations compared to the control sample. All strains are potential producers of DON and ZEA in spring wheat grain. Poa annua L. (1350s) and Euphorbia helioscopia L. (762l) strains produced higher concentrations of 3-ADON than the strain isolated from the primary host plant—Triticum aestivum (B 45.4.1). Some of the highest concentrations of 15-ADON were produced by the Tripleurospermum inodorum (L.) Sch. (1120p) strain. The presence of NIV was also detected, but the average concentrations were lower, ranging from <100 to 2273 µg kg−1. Overall, the strain of Brassica napus L (425l) produced the highest amounts of toxins.
Slightly different results were obtained after the spring wheat grains were incubated at 29 °C. This temperature was less favorable for producing particularly high concentrations of mycotoxins in spring wheat grains inoculated with F. graminearum strains obtained from alternative host plants. However, the Triticum aestivum (6K4V1) strain produced higher DON and ZEA levels at this temperature (Figure 3). It should be noted that under these conditions, this strain produced higher amounts of ZEA in grains compared to those incubated at 25 °C. Additionally, both Brassica napus L strains (425l, 98p) produced higher concentrations of ZEA. Fallopia convolvulus (L.) Löve (144š, 283š) and Viola arvensis Murray (153l) strains produced higher levels of 15-ADON and FUS-X at 29 °C compared to the samples incubated at 25 °C.
The results of the analysis of variance are summarized in Table 2. The statistical analysis (ANOVA) showed that the identity of F. graminearum strains (Factor A) had a significant effect on the production of DON (p < 0.01), 3-ADON (p < 0.0001), 15-ADON (p < 0.001), and ZEA (p < 0.0001). The incubation temperature (Factor B) was significant for the production of DON (p < 0.0001), 3-ADON (p < 0.0001), 15-ADON (p < 0.001), D3G (p < 0.01), and ZEA (p < 0.0001). The combined effects of all the independent variables contributed significantly to the production of 3-ADON and 15-ADON (p < 0.001).
The statistical analysis showed that the strains of F. graminearum and the incubation temperature were insignificant in the production of NIV and FUS-X.
In our study, significant positive correlations were found between DON and 15-ADON, NIV and D3G, FUS-X, D3G and FUS-X, and between 3-ADON and 15-ADON in spring wheat grains incubated at 25 °C and inoculated with 15-ADON genotype strains. (Table 3 (left)). Apart from the relationships between some of the mycotoxins, the strongest positive correlation was observed between NIV and FUS-X (r = 0.991). Significant negative correlations were observed between NIV, D3G, FUS-X, and ZEA, with the strongest negative correlation between FUS-X and ZEA (r = −0.882).
Correlations between individual mycotoxins in spring wheat grains incubated at 25 °C and inoculated with the 3-ADON genotype were observed in the cases of NIV and DON, D3G and DON, NIV, as well as FUS-X and NIV, D3G, ZEA and 15-ADON. The strongest positive correlation was observed between D3G and NIV (r = 0.970) (Table 3 (right)).
Significant positive correlations between DON, D3G and 3-ADON, ZEA, FUS-X and 15-ADON, 3-ADON and ZEA were found in spring wheat grains incubated at 29 °C and inoculated with the 15-ADON genotype strains (Table 4 (left)). The strongest positive correlation was observed between DON and 3-ADON (r = 0.984).
Correlations between individual mycotoxins in spring wheat inoculated with the 3-ADON genotype and incubated at 29 °C were observed in the cases of DON and 3-ADON and between ZEA, DON and 3-ADON. The strongest positive correlation was observed between DON and 3-ADON (r = 0.834) (Table 4 (right)).
3. Discussion
In this study, we evaluated the potential of different trichothecene genotypes of F. graminearum isolated from alternative host plants to produce mycotoxins under different conditions of spring wheat grain incubation. In most parts of the world, F. graminearum is the predominant FHB-causing species [28]. Earlier studies have shown that F. graminearum isolates could be identified as 3-ADON and 15-ADON trichothecene genotypes. Out of the 210 F. graminearum isolates obtained from Lithuanian weeds and assessed for trichothecene genotype, 154 isolates (73.3%) were identified as the 15-ADON genotype, and 49 isolates (23.3%) belonged to the 3-ADON genotype. None of the isolates in that study corresponded to the NIV genotype [7]. Trichothecene genotype structure in alternative host plants appeared to be very similar to that of spring wheat (73%—15-ADON, 26%—3-ADON, and 1%—NIV) [29] and reflected the overall distribution of F. graminearum chemotypes from cereals in Europe [30,31,32]. Therefore, the 15-ADON and 3-ADON trichothecene genotypes were also selected for our study. The 15-ADON genotype is prevalent in most European countries, while the 3-ADON genotype has achieved greater prevalence in parts of North America [33]. The aggressiveness of the 3-ADON and 15-ADON genotypes varies in wheat. Some studies have demonstrated that the 3-ADON genotype is more aggressive and produces higher amounts of trichothecenes than the 15-ADON genotype [18,34]. Still, other studies reported no difference in aggressiveness between wheat’s 3-ADON and 15-ADON genotypes [35,36]. In the present study, F. graminearum 15-ADON genotype strains were more aggressive and produced more mycotoxins in wheat grain than F. graminearum 3-ADON genotype. It has been reported that trichothecenes are important factors in the aggressiveness of FHB disease in wheat and other cereal crops [37]. Isolates of the 3-ADON genotype have been shown to produce higher levels of FHB and trichothecenes in wheat, grow faster, and produce conidia more abundantly on the nutrient media than isolates with the 15-ADON genotype [18,38]. Our study observed that the levels of mycotoxin production depended not only on the trichothecene genotype but mostly on the strain and environmental conditions. It should be noted that isolates producing higher levels of mycotoxins and having the 15-ADON genotype were also found in our study. Generally, Fusarium graminearum isolates vary in their ability to cause disease in different hosts [39].
Based on their trichothecene production, F. graminearum strains can be divided into three genotype groups: the 15-ADON genotype produces DON and 15-ADON, the 3-ADON genotype produces DON and 3-ADON, and the NIV genotype produces NIV and 4ANIV [40]. Seojin Ahn et al. [41] showed that few Fusarium isolates produced NIV, 3-ADON, and 15-ADON mycotoxins. In our study, some of the isolates produced NIV, 3-ADON, and 15-ADON, but also DON and ZEA in combination. Different isolates produced different combinations of mycotoxins. The mycotoxin profile was affected not only by the identity of strains but also by the environmental conditions. Lithuania has a humid continental climate (Dfb in the Köppen climate classification) [42]. Climate change is expected to seriously affect wheat (Triticum aestivum L.) production around the world in the future [43]. Wheat grain yield is predicted to decrease because of the global increase in air temperature [44]. The Fusarium chemotypes can vary annually depending on weather conditions. The weather conditions of the alternative host plants’ collection times differed in 2015 and 2016. The summer period, especially August, was very dry and warm in 2015 compared to the summer of 2016, which was windy and warm. The beginning of summer was dry, later wet. Comparing the meteorological conditions in Lithuania each year with the long-term average of 1924–2018, the climate is warming, and the average temperature has increased by 1.4 °C. Precipitation remained similar on average. Climate warming is a very important factor in the spread of plant diseases and the emergence of mycotoxins. Fungal spores can be transported from the soil surface to the head via rain splash dispersal [45,46,47].
Deoxynivalenol and ZEN are two of the most relevant mycotoxins for the agri-food industry and the human food supply. Additionally, in our study, these mycotoxins were produced by all isolates at both temperatures. However, the mycotoxin accumulation potential may be a population-specific feature, not tied directly to the trichothecene genotype. Thus, we demonstrated that the Lithuanian F. graminearum alternative host plants with trichothecene 3-ADON and 15-ADON genotypes could produce not only large amounts of trichothecenes but also significant levels of ZEA. Previous studies by Mylona et al. [48] showed that at 30 °C, there was a significant reduction in the production of ZEN in stored wheat grain, indicating that intermediate temperatures of 15–25 °C may be more relevant to ZEN contamination of cereal-based commodities. In our study, the average amount of ZEA was higher at 25 °C, but several strains produced much more ZEA at 29 °C.
The potential of F. graminearum to produce DON, 15-ADON, 3-ADON, NIV, D3G, FUS-X, and ZEA was determined in our study. To our knowledge, this is the first report regarding mycotoxin production on spring wheat grains by F. graminearum strains isolated from alternative host plants in Europe.
Depending on environmental factors, F. graminearum can survive on crop residues, grow, and produce conidia and sexual structures, which provide the primary inoculum causing disease on wheat heads and later the production of secondary metabolites known as mycotoxins [49]. In the present study, F. graminearum isolates were able to cause FHB disease in spring wheat regardless of their chemotypes. This result strongly suggests that dicotyledonous plants, including weeds, can serve as alternative hosts for FHB-causing species, particularly F. graminearum, in spring wheat.
4. Conclusions
Strains with 3-ADON genotype consistently produced higher concentrations of 3-ADON, and the strain with 15-ADON genotype produced more 15-ADON in spring wheat grains after 5 weeks of incubation. However, the production of DON, ZEA, NIV, 15-ADON, and 3-ADON in spring wheat grains was more often dependent on the strain of F. graminearum and the environmental conditions than the trichothecene genotype.
Our results point to the potential role of weeds and dicotyledonous plants as a reservoir of inoculum sources of F. graminearum-induced FHB and the risk of mycotoxin contamination in spring wheat grain.
In the context of global warming trends, it is very important to note that the optimal conditions for ZEA and DON occurrence in crops have a wide range, and these mycotoxins can be formed under warmer conditions.
Appropriate weed control in the croplands is necessary as they could serve as potential hosts for Fusarium graminearum, which poses a risk of spring wheat fusarium head blight and grain contamination with mycotoxins.
5. Materials and Methods
5.1. Sample Collection
Alternative host plants were collected from fields located in Central Lithuania (55°23′50″ N, 23°51′40″ E) from 2015 to 2016 and had an endocalcic-epihypogleyic cambisol soil type. Asymptomatic weed plants were collected in August and September 2015 from non-cereal crops and in July 2016 from cereal crops. The trichothecene genotype of F. graminearum strains was identified in previous studies [7]. The ability of F. graminearum strains obtained from different host plants to produce mycotoxins in spring wheat grain was tested in experiments conducted in 2021 at the Institute of Agriculture, Lithuanian Research Centre for Agriculture and Forestry (Akademija, Kėdainiai distr., Lithuania).
A total of 14 F. graminearum strains comprising 10 F. graminearum strains were obtained from asymptomatic weeds, 2 from the primary host plant spring wheat (6K4V1; B 45.4.1), and 2 from spring oilseed rape (98p; 425l), were tested for their ability to produce mycotoxins in spring wheat grain. A total of 15 treatments were tested in triplicate. The control samples were not inoculated. The study scheme is presented in Table 5.
5.2. Revitalization of F. graminearum Isolates
Cryotubes containing spore suspensions of Fusarium isolates selected for the testing were removed from the freezer (−80 °C) and stored in a refrigerator for one day to allow the spore suspension to thaw slowly. A 10 µL aliquot of the spore suspension was spread using an L-shaped sterile Drigalski spatula on a water agar medium and incubated for 2 to 3 days at 22 ± 2 °C. When individual colonies appeared, they were transferred onto potato dextrose agar (PDA) medium, and the plates were incubated at 22 ± 2 °C for 7 days.
5.3. Spring Wheat Grain Inoculation under Laboratory Conditions
The spring wheat grain (100 g) was weighed into a 0.5 L glass bottle, and distilled water (50 mL) was added to the grain. The initial grain moisture was 13.8%. The bottles were closed with cellulose stoppers and autoclaved twice for 1 h at 121 °C. After cooling, the Fusarium isolates were inoculated onto the substrate with four mycelial discs per bottle. The control samples had the same treatment as described above but contained no fungal culture. The spring wheat grain was chosen as a substrate to simulate the natural habitat of the strains to obtain a better estimate of the toxin production in plants [50].
5.4. Storage Conditions
Spring wheat grain samples inoculated with F. graminearum isolates from different host plants were incubated in controlled climate chambers (Binder, Tuttlingen, Germany) for 5 weeks at 25 °C and 29 °C.
After the incubation period, the grain cultures were air dried at 45 °C and ground to flour using an Ultra Centrifugal Mill ZM 200 (Haan, Germany) with a 0.8 mm sieve. Sample preparation for chromatographic analysis of mycotoxins was performed.
5.5. Sample Preparation for Mycotoxin Analyses
The ground sample (2.50 ± 0.01 g) was added to a 50 mL PP tube and extracted with a mixture of deionized water (10 mL), acetonitrile (10 mL), and formic acid (20 μL) for 10 min on a mechanical shaker. After adding the QuEChERS salt mixture, samples were shaken for 10 min on a mechanical shaker. The samples were centrifuged for 10 min at 4000 rpm at room temperature. The extract was transferred to a 15 mL PP tube, placed in an ultra-low temperature freezer for 15 min at −80 °C, and, after removal, centrifuged immediately at 4000 rpm for 10 min at 10 °C.
A 3 mL portion of the extract was transferred to a 15 mL PP tube and evaporated to dryness at 50 °C under a stream of nitrogen. After evaporation, 0.1% formic acid in 1:1 acetonitrile-water solution (100 μL) was added, the solution was shaken on a Vortex mixer, and 0.1% aqueous formic acid solution (250 μL) was added. The extract was filtered through a 0.22 μm PVDF filter and centrifuged for 10 min at 3000 rpm at room temperature. Standard additives were added to the calibration and control samples in autosampler glass vials and evaporated to dryness under a gentle stream of nitrogen. Finally, 200 μL of the filtered extract was transferred to an autosampler glass vial with standard additives or without them.
5.6. Method of Analysis
The analysis was performed on an UltiMate 3000 (Thermo Fisher Scientific, Waltham, MA, USA) HPLC instrument coupled with a Thermo Scientific TSQ Quantiva MS/MS detector (Waltham, MA, USA). The separation was performed on a Phenomenex Luna C18 reversed-phase analytical column (150 × 2.0 mm, 3 µm). The autosampler was maintained at 4 °C, and the column temperature was 40 °C. The sample injection volume was 25 µL. Ion monitoring was conducted in both positive and negative ion modes, and the mass analysis was performed in the selected reaction monitoring (SRM) mode. The following instrumental settings were used: spray voltage 3.5 kV (positive ion mode), 2.5 kV (negative ion mode), vaporizer temperature 350 °C, ion transfer temperature 300 °C, sheath gas 55 arbitrary units (arb), auxiliary gas 25 arb, and sweep gas 5 arb. Data processing was performed with TraceFinder software (Thermo Fisher Scientific).
Phase A consisted of 0.1% formic acid, 0.5 mM ammonium acetate in water. Phase B consisted of 0.1% formic acid, 0.5 mM ammonium acetate in acetonitrile.
5.7. Method Validation
Five-point calibration curves were constructed using blanks spiked with standard mycotoxin mixtures to evaluate the linearity. The least-squares regression method was used for slope construction and calculation of the determination coefficients (R2) of the calibration curves, which were evaluated to a fit of at least 0.99. For quality control purposes, the blank samples were spiked with standard mycotoxin solvents at the following concentration levels: 10, 50, and 100 µg kg−1 for DON, 3-ADON, 15-ADON, NIV, D3G, FUSX, and ZEA. The precision and accuracy were validated by analyzing five replicates at each of the three determined spiking levels. All method validation results are shown in Table 6.
5.8. Statistical Analysis
The reliability of the data was assessed using the statistical data processing program SAS Enterprise Guide 7.1. A one-way analysis of variance (ANOVA) statistical package was used to evaluate the data scatter and identify significant differences between data averages. Significant differences between the two samples were compared by using Duncan’s criterion. Additionally, the experimental data were analyzed using the statistical program R, version 3.6.0 (R Core Team, 2019, Vienna, Austria). A two-way analysis of variance (ANOVA) statistical package was used. The level of significance was set at p < 0.05, p < 0.01, and p < 0.001.
Author Contributions
Conceptualization, S.S., G.K., and S.J.; methodology, S.S., S.J., V.B., R.P., Z.B.; validation, S.J., S.S., V.B., R.P., and Z.B.; investigation, S.J.; data curation, S.J., S.S.; writing—original draft preparation, S.J.; writing—review and editing, S.S., G.K., V.B., Z.B., R.P.; visualization, S.J.; supervision, S.S. All authors have read and agreed to the published version of the manuscript.
Funding
The current research was funded by the European Social Fund under Measure No. 09.3.3-LMT-K-712 “Development of Competencies of Scientists, other Researchers and Students through Practical Research Activities”. Project No. 09.3.3-LMT-K-712-19-0084.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Not applicable.
Acknowledgments
The authors wish to thank Gabija Vaitkevičiūtė of the Laboratory of Genetics and Physiology (Lithuanian Research Centre for Agriculture and Forestry) for her support.
Conflicts of Interest
The authors declare no conflict of interest.
References
- FAO. Crop Prospects and Food Situation—Quarterly Global Report No. 1; FAO: Rome, Italy, 2022. [Google Scholar] [CrossRef]
- Gil, J.D.B.; Reidsma, P.; Giller, K.; Todman, L.; Whitmore, A.; van Ittersum, M. Sustainable development goal 2: Improved targets and indicators for agriculture and food security. Ambio 2019, 48, 685–698. [Google Scholar] [CrossRef] [PubMed]
- Jacobs, C.; Berglund, M.; Kurnik, B.; Dworak, T.; Marras, S.; Mereu, V.; Michetti, M. Climate Change Adaptation in the Agriculture Sector in Europe (No. 4/2019); European Environment Agency (EEA): Copenhagen, Denmark, 2019; Available online: https://www.eea.europa.eu/publications/cc-adaptation-agriculture (accessed on 14 January 2022).
- Kahiluoto, H.; Kaseva, J.; Balek, J.; Olesen, J.E.; Ruiz-Ramos, M.; Gobin, A.; Kersebaum, K.C.; Takáč, J.; Ruget, F.; Ferrise, R. Decline in climate resilience of European wheat. Proc. Natl. Acad. Sci. USA 2019, 116, 123–128. [Google Scholar] [CrossRef] [PubMed]
- Lobell, D.B.; Field, C.B. Global scale climate—Crop yield relationships and the impacts of recent warming. Environ. Res. Lett. 2007, 2, 014002. [Google Scholar] [CrossRef]
- Rasiukevičiūtė, N.; Supronienė, S.; Kelpšienė, J.; Švėgžda, P.; Kadžienė, G.; Šneideris, D.; Ivanauskas, A.; Treikale, O. Susceptibility of non-cereal crops to Fusarium graminearum complex and their role within cereal crop rotation as a source of inoculum for Fusarium head blight. Span. J. Agric. Res. 2018, 16, 1–12. [Google Scholar] [CrossRef]
- Suproniene, S.; Kadziene, G.; Irzykowski, W.; Sneideris, D.; Ivanauskas, A.; Sakalauskas, S.; Serbiak, P.; Svegzda, P.; Auskalniene, O.; Jedryczka, M. Weed species within cereal crop rotations can serve as alternative hosts for Fusarium graminearum causing Fusarium head blight of wheat. Fungal Ecol. 2019, 37, 30–37. [Google Scholar] [CrossRef]
- Fulcher, M.R.; Winans, J.B.; Quan, M.; Oladipo, E.D.; Bergstrom, G.C. Population Genetics of Fusarium graminearum at the Interface of Wheat and Wild Grass Communities in New York. Phytopathology 2019, 109, 2124–2131. [Google Scholar] [CrossRef]
- Moretti, A.; Pascale, M.; Logrieco, A.F. Mycotoxin risks under a climate change scenario in Europe. Trends Food Sci. Technol. 2019, 84, 38–40. [Google Scholar] [CrossRef]
- Eskola, M.; Kos, G.; Elliott, C.T.; Hajšlová, J.; Mayar, S.; Krska, R. Worldwide contamination of food-crops with mycotoxins: Validity of the widely cited ‘FAO estimate’ of 25%. Crit. Rev. Food Sci. Nutr. 2019, 60, 2773–2789. [Google Scholar] [CrossRef]
- Burlakoti, R.R.; Neate, S.M.; Adhikari, T.B.; Gyawali, S.; Salas, B.; Steffenson, B.J.; Schwarz, P.B. Trichothecene profiling and population genetic analysis of Gibberella zeae from barley in North Dakota and Minnesota. Phytopathology 2011, 101, 687–695. [Google Scholar] [CrossRef]
- van Egmond, H.P.; Schothorst, R.C.; Jonker, M.A. Regulations relating to mycotoxins in food. Anal. Bioanal. Chem. 2007, 389, 147–157. [Google Scholar] [CrossRef]
- Pinstrup-Andersen, P. Case Studies in Food Policy for Developing Countries: Policies for Health, Nutrition, Food Consumption, and Poverty; Cornell University Press: Ithaca, NY, USA, 2018; Volume 1, p. 132. [Google Scholar]
- Mankevičienė, A.; Butkutė, B.; Gaurilčikienė, I.; Dabkevičius, Z.; Supronienė, S. Risk assessment of Fusarium mycotoxins in Lithuanian small cereal grains. Food Control 2011, 22, 970–976. [Google Scholar] [CrossRef]
- Janaviciene, S.; Mankeviciene, A.; Suproniene, S.; Kochiieru, Y.; Keriene, I. The prevalence of deoxynivalenol and its derivatives in the spring wheat grain from different agricultural production systems in Lithuania. Food Addit. Contam. Part A 2018, 35, 1179–1188. [Google Scholar] [CrossRef] [PubMed]
- Kochiieru, Y.; Mankeviciene, A.; Janaviciene, S.; Jonaviciene, A.; Ceseviciene, J. The influence of milling and sifting processes on deoxynivalenol distribution in whole-wheat flour and its products. World Mycotoxin J. 2019, 12, 133–140. [Google Scholar] [CrossRef]
- Burlakoti, R.R.; Ali, S.; Secor, G.A.; Neate, S.M.; McMullen, M.P.; Adhikari, T.B. Genetic relationships among populations of Gibberella zeae from barley, wheat, potato, and sugar beet in the upper Midwest of the United States. Phytopathology 2008, 98, 969–976. [Google Scholar] [CrossRef] [PubMed]
- Ward, T.J.; Clear, R.M.; Rooney, A.P.; O’Donnell, K.; Gaba, D.; Patrick, S.; Starkey, D.E.; Nowicki, T.W. An adaptive evolutionary shift in Fusarium head blight pathogen populations is driving the rapid spread of more toxigenic Fusarium graminearum in North America. Fungal Genet. Biol. 2008, 45, 473–484. [Google Scholar] [CrossRef] [PubMed]
- EFSA. EFSA panel on food additives and nutrient sources added to food. Scientific Opinion on the re-evaluation of aspartame (E 951) as a food additive. EFSA J. 2013, 11, 3496. [Google Scholar] [CrossRef]
- Knutsen, H.K.; Alexander, J.; Barregård, L.; Bignami, M.; Brüschweiler, B.; Ceccatelli, S.; Cottrill, B.; Dinovi, M.; Grasl-Kraupp, B.; Hogstrand, C.; et al. Risks to human and animal health related to the presence of deoxynivalenol and its acetylated and modified forms in food and feed. EFSA J. 2017, 15, e04718. [Google Scholar] [CrossRef]
- Waskiewicz, A.; Gromadzka, K.; Wisniewska, H.; Golinski, P. Accumulation of zearalenone in genotypes of spring wheat after inoculation with Fusarium culmorum. Cereal Res. Commun. 2008, 36, 401–403. Available online: https://www.jstor.org/stable/90003249 (accessed on 10 January 2022).
- Golinski, P.; Waskiewicz, A.; Wisniewska, H.; Kiecana, I.; Mielniczuk, E.; Gromadzka, K.; Rymaniak, E. Reaction of winter wheat (Triticum aestivum L.) cultivars to infection with Fusarium spp.: Mycotoxin contamination in grain and chaff. Food Addit. Contam. 2010, 27, 1015–1024. [Google Scholar] [CrossRef]
- Döll, S.; Dänicke, S. The Fusarium toxins deoxynivalenol (DON) and zearalenone (ZON) in animal feeding. Prev. Vet. Med. 2011, 102, 132–145. [Google Scholar] [CrossRef]
- Covarelli, L.; Beccari, G.; Prodi, A.; Generotti, S.; Etruschi, F.; Juan, C.; Ferrer, E.; Mañes, J. Fusarium species, chemotype characterisation and trichothecene contamination of durum and soft wheat in an area of central Italy. J. Sci. Food Agric. 2015, 95, 540–551. [Google Scholar] [CrossRef]
- McMullen, M.; Bergstrom, G.; De Wolf, E.; Dill-Macky, R.; Hershman, D.; Shaner, G.; Van Sanford, D. A unified effort to fight an enemy of wheat and barley: Fusarium head blight. Plant Dis. 2012, 96, 1712–1728. [Google Scholar] [CrossRef] [PubMed]
- Gilbert, J.; Haber, S. Overview of some recent research developments in Fusarium head blight of wheat. Can. J. Plant Pathol. 2013, 35, 149–174. [Google Scholar] [CrossRef]
- Van der Fels-Klerx, H.J.; Liu, C.; Battilani, P. Modelling climate change impacts on mycotoxin contamination. World Mycotoxin J. 2016, 9, 717–726. [Google Scholar] [CrossRef]
- Osborne, L.E.; Stein, J.M. Epidemiology of Fusarium head blight on small-grain cereals. Int. J. Food Microbiol. 2007, 119, 103–108. [Google Scholar] [CrossRef]
- Suproniene, S.; Sakalauskas, S.; Stumbriene, K.; Zvirdauskiene, R.; Svegzda, P. Variances in trichothecene chemotype distribution in Lithuanian wheat grain and within pure culture Fusarium graminearum isolated from the same grain samples. Eur. J. Plant Pathol. 2016, 144, 371–381. [Google Scholar] [CrossRef]
- Starkey, D.E.; Ward, T.J.; Aoki, T.; Gale, L.R.; Kistler, H.C.; Geiser, D.M.; O’Donnell, K. Global molecular surveillance reveals novel Fusarium head blight species and trichothecene toxin diversity. Fungal Genet. Biol. 2007, 44, 1191–1204. [Google Scholar] [CrossRef]
- Pasquali, M.; Migheli, Q. Genetic approaches to chemotype determination in type B-trichothecene producing Fusaria. Int. J. Food Microbiol. 2014, 189, 164–182. [Google Scholar] [CrossRef]
- Bryła, M.; Waśkiewicz, A.; Podolska, G.; Szymczyk, K.; Jędrzejczak, R.; Damaziak, K.; Sułek, A. Occurrence of 26 mycotoxins in the grain of cereals cultivated in Poland. Toxins 2016, 8, 160. [Google Scholar] [CrossRef]
- Przemieniecki, S.W.; Kurowski, T.P.; Korzekwa, K. Chemotypes and geographic distribution of the Fusarium graminearum species complex. Environ. Biotechnol. 2014, 10, 45–59. [Google Scholar] [CrossRef]
- Amarasinghe, C.; Sharanowski, B.; Fernando, W.G. Molecular phylogenetic relationships, trichothecene chemotype diversity and aggressiveness of strains in a global collection of Fusarium graminearum species. Toxins 2019, 11, 263. [Google Scholar] [CrossRef]
- Liu, Y.Y.; Sun, H.Y.; Li, W.; Xia, Y.L.; Deng, Y.Y.; Zhang, A.X.; Chen, H.G. Fitness of three chemotypes of Fusarium graminearum species complex in major winter wheat-producing areas of China. PLoS ONE 2017, 12, e0174040. [Google Scholar] [CrossRef]
- Spolti, P.; Del Ponte, E.M.; Cummings, J.A.; Dong, Y.; Bergstrom, G.C. Fitness attributes of Fusarium graminearum isolates from wheat in New York possessing a 3-ADON or 15-ADON trichothecene genotype. Phytopathology 2014, 104, 513–519. [Google Scholar] [CrossRef]
- Maier, F.J.; Miedaner, T.; Hadeler, B.; Felk, A.; Salomon, S.; Lemmens, M.; Kassner, H.; Schäfer, W. Involvement of trichothecenes in fusarioses of wheat, barley and maize evaluated by gene disruption of the trichodiene synthase (Tri5) gene in three field isolates of different chemotype and virulence. Mol. Plant Pathol. 2006, 7, 449–461. [Google Scholar] [CrossRef]
- von der Ohe, C.; Gauthier, V.; Tamburic-Ilincic, L.; Brule-Babel, A.; Fernando, W.G.; Clear, R.; Ward, T.J.; Miedaner, T. A comparison of aggressiveness and deoxynivalenol production between Canadian Fusarium graminearum isolates with 3-acetyl and 15-acetyldeoxynivalenol chemotypes in field-grown spring wheat. Eur. J. Plant Pathol. 2010, 127, 407–417. [Google Scholar] [CrossRef]
- Goswami, R.S.; Kistler, H.C. Pathogenicity and in planta mycotoxin accumulation among members of the Fusarium graminearum species complex on wheat and rice. Phytopathology 2005, 95, 1397–1404. [Google Scholar] [CrossRef]
- Ward, T.J.; Bielawski, J.P.; Kistler, H.C.; Sullivan, E.; O’Donnell, K. Ancestral polymorphism and adaptive evolution in the trichothecene mycotoxin gene cluster of phytopathogenic Fusarium. Proc. Natl. Acad. Sci. USA 2002, 99, 9278–9283. [Google Scholar] [CrossRef]
- Ahn, S.; Kim, M.; Lim, J.Y.; Choi, G.J.; Seo, J.A. Characterization of Fusarium asiaticum and F. graminearum isolates from gramineous weeds in the proximity of rice fields in Korea. Plant Pathol. 2022, 71, 1164–1173. [Google Scholar] [CrossRef]
- Beck, H.E.; Zimmermann, N.E.; McVicar, T.R.; Vergopolan, N.; Berg, A.; Wood, E.F. Present and future Köppen-Geiger climate classification maps at 1-km resolution. Sci. Data 2018, 5, 180214. [Google Scholar] [CrossRef]
- Asseng, S.; Ewert, F.; Martre, P.; Rötter, R.P.; Lobell, D.B.; Cammarano, D.; Kimball, B.A.; Ottman, M.J.; Wall, G.W.; White, J.W.; et al. Rising temperatures reduce global wheat production. Nat. Clim. Chang. 2015, 5, 143–147. [Google Scholar] [CrossRef]
- Sawada, H.; Matsuyama, H.; Matsunaka, H.; Fujita, M.; Okamura, N.; Seki, M.; Kojima, H.; Kiribuchi-Otobe, C.; Takayama, T.; Oda, S.; et al. Evaluation of dry matter production and yield in early-sown wheat using near-isogenic lines for the vernalization locus Vrn-D1. Plant Prod. Sci. 2019, 22, 275–284. [Google Scholar] [CrossRef]
- Parry, D.W.; Jenkinson, P.; McLeod, L. Fusarium ear blight (scab) in small grain cereals—A review. Plant Pathol. 1995, 44, 207–238. [Google Scholar] [CrossRef]
- Jenkinson, P.; Parry, D.W. Splash dispersal of conidia of Fusarium culmorum and Fusarium avenaceum. Mycol. Res. 1994, 98, 506–510. [Google Scholar] [CrossRef]
- Mirjami Hörberg, H. Patterns of splash dispersed conidia of Fusarium poae and Fusarium culmorum. Eur. J. Plant Pathol. 2002, 108, 73–80. [Google Scholar] [CrossRef]
- Mylona, K.; Sulyok, M.; Magan, N. Relationship between environmental factors, dry matter loss and mycotoxin levels in stored wheat and maize infected with Fusarium species. Food Addit. Contam. Part A 2012, 29, 1118–1128. [Google Scholar] [CrossRef]
- Leplat, J.; Friberg, H.; Abid, M.; Steinberg, C. Survival of Fusarium graminearum, the causal agent of Fusarium head blight. A review. Agron. Sustain. Dev. 2013, 33, 97–111. [Google Scholar] [CrossRef]
- Kokkonen, M.; Ojala, L.; Parikka, P.; Jestoi, M. Mycotoxin production of selected Fusarium species at different culture conditions. Int. J. Food Microbiol. 2010, 143, 17–25. [Google Scholar] [CrossRef]
Figure 1.
The percentage of spring wheat grain samples contaminated with mycotoxins depending on the temperature and trichothecene genotype.
Figure 1.
The percentage of spring wheat grain samples contaminated with mycotoxins depending on the temperature and trichothecene genotype.
Figure 2.
The average produced mycotoxin concentrations (µg kg−1) in spring wheat grains with alternative host strains incubated at 25 °C.
Figure 2.
The average produced mycotoxin concentrations (µg kg−1) in spring wheat grains with alternative host strains incubated at 25 °C.
Figure 3.
The average produced mycotoxin concentrations (µg kg−1) in spring wheat grains inoculated with alternative host strains and incubated at 29 °C.
Figure 3.
The average produced mycotoxin concentrations (µg kg−1) in spring wheat grains inoculated with alternative host strains and incubated at 29 °C.
Table 1.
Mycotoxin occurrence in spring wheat grains depending on the temperature and trichothecene genotype.
Table 1.
Mycotoxin occurrence in spring wheat grains depending on the temperature and trichothecene genotype.
| 25 °C | 29 °C | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Mycotoxin | Strain Genotype | Positive, % | Min, µg kg−1 | Max, µg kg−1 | Average | Positive, % | Min, µg kg−1 | Max, µg kg−1 | Average |
| DON | 3-ADON | 100 | 6804 | 101,100 | 37,013 | 100 | 286 | 15,473 | 3721 |
| 15-ADON | 100 | 8305 | 223,532 | 56,605 | 100 | 169 | 63,754 | 6577 | |
| NIV | 3-ADON | 43 | <100 | 3015 | 866 | 14 | <100 | 352 | 270 |
| 15-ADON | 19 | <100 | 573 | 377 | 14 | <100 | 162 | 129 | |
| D3G | 3-ADON | 28 | <10 | 78 | 32 | 0 | <10 | <10 | <10 |
| 15-ADON | 43 | <10 | 187 | 51 | 5 | <10 | 16 | 16 | |
| FUS-X | 3-ADON | 90 | <10 | 160 | 60 | 28 | <10 | 136 | 109 |
| 15-ADON | 100 | 11 | 152 | 39 | 33 | <10 | 220 | 154 | |
| 3-ADON | 3-ADON | 86 | <50 | 33,344 | 13,954 | 86 | <50 | 1150 | 407 |
| 15-ADON | 76 | <50 | 11,899 | 3159 | 67 | <50 | 1217 | 187 | |
| 15-ADON | 3-ADON | 71 | <50 | 2829 | 1133 | 57 | <50 | 4739 | 1195 |
| 15-ADON | 95 | <50 | 27,498 | 6815 | 67 | <50 | 6658 | 1610 | |
| ZEA | 3-ADON | 100 | 10,995 | 52,763 | 25,805 | 100 | 219 | 43,150 | 9803 |
| 15-ADON | 100 | 15,290 | 46,686 | 29,771 | 100 | 2950 | 52,728 | 13,464 | |
Table 2.
ANOVA of the contribution of F. graminearum strains (Factor A) and incubation temperature (Factor B) to the production of mycotoxins on spring wheat grains.
Table 2.
ANOVA of the contribution of F. graminearum strains (Factor A) and incubation temperature (Factor B) to the production of mycotoxins on spring wheat grains.
| DON | 3-ADON | 15-ADON | NIV | D3G | FUS-X | ZEA | ||
|---|---|---|---|---|---|---|---|---|
| Factor A | F | 4.632 | 8.012 | 7.295 | 1.643 | 0.989 | 1.050 | 8.575 |
| p | 0.0124 * | 0.000654 *** | 0.00120 ** | 0.1996 | 0.3761 | 0.355 | 0.000409 *** | |
| Factor B | F | 37.681 | 26.306 | 9.408 | 3.864 | 5.939 | 0.000 | 42.816 |
| p | 0.0000 *** | 0.000000 *** | 0.00291 ** | 0.0526 | 0.0169 * | 0.994 | 0.00000 *** | |
| Factor A x B | F | 2.990 | 7.320 | 4.946 | 1.224 | 0.905 | 1.179 | 1.249 |
| p | 0.0556 | 0.001174 ** | 0.00932 ** | 0.2992 | 0.4084 | 0.313 | 0.291984 |
*p < 0.01; **p < 0.001; ***p < 0.0001.
Table 3.
The correlations between individual mycotoxins with trichothecene 15-ADON genotype (left) and with trichothecene 3-ADON genotype (right) in spring wheat incubated at 25 °C. Significant r values (p < 0.05) are in bold.
Table 3.
The correlations between individual mycotoxins with trichothecene 15-ADON genotype (left) and with trichothecene 3-ADON genotype (right) in spring wheat incubated at 25 °C. Significant r values (p < 0.05) are in bold.
| DON | NIV | D3G | FUS-X | 3-ADON | 15-ADON | ZEA | |||
|---|---|---|---|---|---|---|---|---|---|
| 15-ADON genotype | DON | 0.696 | 0.791 | 0.416 | 0.603 | 0.071 | −0.266 | 3-ADON genotype | |
| NIV | 0.099 | 0.970 | 0.741 | 0.171 | −0.122 | −0.306 | |||
| D3G | 0.018 | 0.974 | 0.678 | 0.229 | −0.125 | −0.456 | |||
| FUS-X | 0.078 | 0.991 | 0.981 | 0.481 | −0.062 | −0.028 | |||
| 3-ADON | 0.230 | 0.087 | 0.022 | 0.093 | 0.210 | 0.157 | |||
| 15-ADON | 0.556 | 0.002 | −0.103 | −0.020 | 0.912 | 0.538 | |||
| ZEA | 0.042 | −0.863 | −0.787 | −0.882 | −0.182 | −0.038 |
Table 4.
The correlations between individual mycotoxins with trichothecene 15-ADON genotype (left) and with trichothecene 3-ADON genotype (right) in spring wheat incubated at 29 °C. Significant r values (p < 0.05) are in bold.
Table 4.
The correlations between individual mycotoxins with trichothecene 15-ADON genotype (left) and with trichothecene 3-ADON genotype (right) in spring wheat incubated at 29 °C. Significant r values (p < 0.05) are in bold.
| DON | NIV | D3G | FUS-X | 3-ADON | 15-ADON | ZEA | |||
|---|---|---|---|---|---|---|---|---|---|
| 15-ADON genotype | DON | 0.048 | - | −0.261 | 0.834 | −0.203 | 0.582 | 3-ADON genotype | |
| NIV | −0.157 | - | 0.473 | −0.154 | −0.119 | −0.299 | |||
| D3G | - | −0.202 | - | - | - | - | |||
| FUS-X | −0.294 | −0.317 | −0.262 | −0.089 | 0.381 | −0.390 | |||
| 3-ADON | 0.984 | −0.095 | 0.976 | −0.373 | −0.147 | 0.715 | |||
| 15-ADON | −0.164 | −0.294 | −0.137 | 0.967 | −0.237 | −0.116 | |||
| ZEA | 0.924 | −0.277 | 0.934 | −0.403 | 0.911 | −0.274 |
Table 5.
The study scheme.
| Treatment No. | Host Plant | Strain Code | TRI Genotypes |
|---|---|---|---|
| 1 | Control | ||
| 2 | Fallopia convolvulus (L.) Löve | 144š | 3-ADON |
| 3 | Fallopia convolvulus (L.) Löve | 283š | 15-ADON |
| 4 | Viola arvensis Murray | 153l | 15-ADON |
| 5 | Viola arvensis Murray | 541s | 3-ADON |
| 6 | Triticum aestivum | 6K4V1 | 15-ADON |
| 7 | Triticum aestivum | B 45.4.1 | 3-ADON |
| 8 | Brassica napus L. | 98p | 3-ADON |
| 9 | Brassica napus L. | 425l | 15-ADON |
| 10 | Euphorbia helioscopia L. | 762l | 3-ADON |
| 11 | Euphorbia helioscopia L. | 678v | 15-ADON |
| 12 | Tripleurospermum inodorum (L.) Sch. | 1120p | 15-ADON |
| 13 | Tripleurospermum inodorum (L.) Sch. | 1422p | 3-ADON |
| 14 | Poa annua L. | 787v | 15-ADON |
| 15 | Poa annua L. | 1350s | 3-ADON |
Table 6.
Chromatography method validation parameters.
| Validation Parameters | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|
| Mycotoxin | LOD, µg kg−1 | LOQ, µg kg−1 | Linear Range, µg kg−1 | R2 | Accuracy (Deviation from the Theoretical Value, %) | Precision (RSD, %) | ||||
| Level of Spiked Samples, µg kg−1 | ||||||||||
| 10 | 50 | 100 | 10 | 50 | 100 | |||||
| NIV | 14 | 42 | 42–500 | 0.9983 | x | −9 | −18 | x | 9 | 3 |
| D3G | 4.5 | 13 | 13–500 | 0.9972 | 12 | −3 | −1 | 12 | 5 | 8 |
| DON | 4.0 | 12 | 12–500 | 0.9991 | 23 | 5 | 4 | 10 | 6 | 3 |
| FUS-X | 1.2 | 3.5 | 3.5–500 | 0.9988 | 6 | 7 | 0 | 3 | 6 | 8 |
| 15-ADON | 14 | 42 | 42–500 | 0.9988 | x | 4 | 2 | x | 8 | 2 |
| 3-ADON | 3.6 | 11 | 11–500 | 0.9991 | −24 | −11 | −9 | 14 | 14 | 11 |
| ZEA | 2.4 | 7.1 | 7.1–500 | 0.9993 | 25 | −10 | −8 | 6 | 7 | 4 |
X—not found.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. |
© 2022 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Janaviciene, S.; Suproniene, S.; Kadziene, G.; Pavlenko, R.; Berzina, Z.; Bartkevics, V. Toxigenicity of F. graminearum Residing on Host Plants Alternative to Wheat as Influenced by Environmental Conditions. Toxins 2022, 14, 541. https://doi.org/10.3390/toxins14080541
AMA Style
Janaviciene S, Suproniene S, Kadziene G, Pavlenko R, Berzina Z, Bartkevics V. Toxigenicity of F. graminearum Residing on Host Plants Alternative to Wheat as Influenced by Environmental Conditions. Toxins. 2022; 14(8):541. https://doi.org/10.3390/toxins14080541
Chicago/Turabian StyleJanaviciene, Sigita, Skaidre Suproniene, Grazina Kadziene, Romans Pavlenko, Zane Berzina, and Vadims Bartkevics. 2022. "Toxigenicity of F. graminearum Residing on Host Plants Alternative to Wheat as Influenced by Environmental Conditions" Toxins 14, no. 8: 541. https://doi.org/10.3390/toxins14080541
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
