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Article

Relationship of Deoxynivalenol Content in Grain, Chaff, and Straw with Fusarium Head Blight Severity in Wheat Varieties with Various Levels of Resistance

1
State Key Laboratory Breeding Base of Food Quality and Safety in Jiangsu Province, Ministry of Agriculture, Nanjing 210014, China
2
Key Laboratory of Control Technology and Standardfor Agro-product Safety and Quality, Ministry of Agriculture, Nanjing 210014, China
3
Key Laboratory of Agro-product Safety Risk Evaluation (Nanjing), Ministry of Agriculture, Nanjing 210014, China
4
Institute of Food Quality and Safety, Jiangsu Academy of Agricultural Sciences, Nanjing 210014, China
*
Author to whom correspondence should be addressed.
Submission received: 12 November 2014 / Revised: 31 December 2014 / Accepted: 22 February 2015 / Published: 5 March 2015
(This article belongs to the Section Mycotoxins)

Abstract

:
A total of 122 wheat varieties obtained from the Nordic Genetic Resource Center were infected artificially with an aggressive Fusariumasiaticum strain in a field experiment. We calculated the severity of Fusarium head blight (FHB) and determined the deoxynivalenol (DON) content of wheat grain, straw and glumes. We found DON contamination levels to be highest in the glumes, intermediate in the straw, and lowest in the grain in most samples. The DON contamination levels did not increase consistently with increased FHB incidence. The DON levels in the wheat varieties with high FHB resistance were not necessarily low, and those in the wheat varieties with high FHB sensitivity were not necessarily high. We selected 50 wheat genotypes with reduced DON content for future research. This study will be helpful in breeding new wheat varieties with low levels of DON accumulation.

1. Introduction

Fusarium head blight (FHB) is a fungal disease that affects numerous small grain species [1,2,3,4]. This disease is caused by members of the Fusarium graminearum species complex, which consists of at least 16 phylogenetically distinct species [5]. FHB reduces kernel set and kernel weight, which contribute to significant grain yield losses. The disease also decreases the nutritive and baking quality of grain through degradation of proteins. Mycotoxins may accumulate to unacceptable levels, making harvested grain and their byproducts unsuitable for human and animal consumption.
Deoxynivalenol (DON) is one of the most economically important trichothecenes produced by F. graminearum. It is stable at high temperatures and is soluble in water and some polar solvents [6]. DON is also referred to as vomitoxin, due to its ability to induce vomiting, especially in pigs [7]. In plants, DON delays seed germination and subsequent plant growth and development [8]. At the cellular level, the main toxic effect of DON is inhibition of protein synthesis via binding to ribosomes [9]. Additionally, DON acts as a virulence factor and plays an essential role in the spread of F. graminearum after the initial injection of a wheat plant [10].
Since the 1990s, interest in the health benefits and safety of cereal products has increased. Alimentary mycotoxin accumulation is a risk associated with the consumption of infected grain [11], and this has resulted in the establishment of maximum permissible DON levels for grain destined for human consumption. In China, the maximum permissible level of DON in cereals and their byproducts is 1 mg/kg [12].
Wheat straw and chaff are often used for feedstuff, but may be unsuitable for animal consumption if contaminated by Fusarium toxins. Kang and Buchenauer (2000) and Matthäus et al. (2004) reported that natural contamination of feed by Fusarium toxins resulted in altered nutrient composition and marked modification of cell wall compounds in the infected grain due to higher activities of protease, amylase, and several NSP-degrading enzymes [13,14]. K. Seeling et al. demonstrated that feeding animals with wheat and wheat chaff contaminated with the Fusarium toxins DON and zearalenone (ZON) caused slight changes in ruminal nutrient degradability and in rumen physiological parameters, probably due to fungus-related modifications of the grain [15].
The development of FHB-resistant cultivars has been effective in reducing damage caused by the disease, However, resistance to FHB is affected by the relationship between symptom intensity and toxin production [16,17,18]. Understanding the relationship between FHB and DON accumulation could be important in predicting the risks of mycotoxins in food, and may aid in the development of a more reliable and rational strategy for managing the FHB disease complex and reducing DON production. Numerous attempts have been made to relate disease incidence or severity to mycotoxin concentrations and the results have varied [19]. Despite the fact that most studies reported positive correlations between disease incidence and mycotoxin accumulation, the quantity of mycotoxins per unit of disease index differed considerably and some studies failed to find a significant relationship [20]. The warm and humid climate in Jiangsu Province, China, during wheat flowering is favorable for the development of FHB epidemics. In this study, 250 winter wheat varieties obtained from the Nordic Genetic Resource Center in Alnarp, Sweden, for FHB resistance in China (data not shown), we selected 122 varieties that exhibited stable type II resistance to examine the relationship between DON content and FHB severity and to screen for wheat genotypes with reduced DON content. In addition, we measured the concentrations of DON in the grain, chaff and straw of these varieties. Our results mayfacilitate the selection of varieties used for animal feed.

2. Results

2.1. FHB Severity in Wheat Cultivars

During an FHB epidemic in Jiangsu Province, China, in 2012 [21], the rate of infected spikelets was as low as 24% in the Sumai-3 cultivar, which exhibited the highest resistance, but was as high as 89% in susceptible cultivars. In this study, we found a large range of genetic variation among the varieties in the severity of FHB infection. The occurrence of infected spikelets was less than 25% in eleven varieties and greater than 89% in 26 varieties, and the remaining varieties exhibited intermediate levels of resistance to FHB (Table 1).
Table 1. Fusarium head blight (FHB) severity for selected wheat varieties from Sweden based on field-grown plants in 2012.
Table 1. Fusarium head blight (FHB) severity for selected wheat varieties from Sweden based on field-grown plants in 2012.
NO.Accession nameOriginPIS 1
1LoyalSweden31.69 ± 10.56
2HerefordSweden24.34 ± 7.64
3SkagenSweden23.35 ± 6.04
4PAJ706-575ASweden45.82 ± 22.35
5MaribossSweden29.96 ± 22.27
6Harnesk-7Sweden65.15 ± 11.67
7IDUNASweden39.17 ± 16.00
8ANKARSweden38.53 ± 20.22
9ÅRING IIISweden100.00
10EROICASweden22.61 ± 19.92
11AROSSweden33.08 ± 22.40
12BANCOSweden16.86 ± 8.73
13NORRESweden12.19 ± 8.80
14STURESweden56.28 ± 31.01
15HELGESweden14.40 ± 0.73
16LINNASweden29.39 ± 12.89
17JYVÄSweden95.14 ± 6.82
18SIGYN IISweden100 ± 0.00
19FOLKESweden32.61 ± 13.48
20HOLGERSweden24.12 ± 9.90
21ALEMAR UST. HV. SG.Sweden61.48 ± 13.55
22GUSALEK K.17Sweden96.07 ± 6.79
23LANTVETE FRÅN UPPSALASweden100 ± 0.00
24KOTTESweden53.70 ± 11.88
25EXTRA SQUAREHEADSweden47.02 ± 11.75
26RENODLAT SAMMETSVETESweden91.61 ± 6.20
27THULE IISweden92.81 ± 11.84
28PANSAR IISweden29.68 ± 6.63
29SVEA ISweden97.27 ± 6.10
30PANSAR IIISweden79.84 ± 10.06
31GYLLEN IISweden85.29 ± 10.23
32GLUTENSweden93.75 ± 12.50
33BORGSweden89.91 ± 14.39
34PÄRL IISweden37.50 ± 17.68
35ROBURSweden26.34 ± 10.49
36SEBASweden68.30 ± 11.44
37VIRGOSweden88.38 ± 18.02
38SOLIDSweden40.82 ± 15.72
39HILDURSweden17.09 ± 6.66
40HANKKIJAN ILVESSweden39.52 ± 10.72
41Harnesk-5Sweden24.68 ± 9.89
42GUSALEK K.10 ASweden38.41 ± 23.08
43KOSACKSweden46.04 ± 11.00
44MK 2-114Sweden74.57 ± 11.86
45MK 2-302Sweden32.31 ± 6.84
46MK 2-304Sweden85.23 ± 17.94
47MK 2-306Sweden95.56 ± 9.94
48MK 2-313Sweden27.27 ± 6.43
49MK 2-502Sweden41.36 ± 10.15
50MK 2-503Sweden100.00 ± 0.00
51MK 2-506Sweden46.11 ± 16.35
52MK 2-508Sweden31.11 ± 12.57
53MK 2-542Sweden59.82 ± 15.41
54MK 2-543Sweden83.43 ± 9.19
55MK 2-547Sweden97.37 ± 5.26
56MK 2-548Sweden21.67 ± 21.62
57MK 2-556Sweden90.73 ± 11.73
58MK 2-557Sweden77.06 ± 11.22
59MK 2-558Sweden84.31 ± 13.25
60MK 2-564Sweden63.92 ± 25.45
61SALUTSweden53.91 ± 12.70
62ØSTBYSweden30.81 ± 9.26
63MK 2-501Sweden59.04 ± 11.22
64MK 2-510Sweden94.18 ± 8.85
65PORTALSweden30.01 ± 10.00
66TJELVARSweden45.51 ± 9.95
67TRYGGVESweden88.81 ± 10.62
68MK 2-549Sweden79.50 ± 11.95
69MK 2-566Sweden91.67 ± 14.43
70MK 2-651Sweden42.84 ± 11.66
71MK 2-656Sweden66.51 ± 28.36
72MK 2-659Sweden39.18 ± 13.15
73MK 2-660Sweden61.33 ± 21.33
74MK 2-775Sweden44.96 ± 7.58
75MK 2-780Sweden88.18 ± 21.70
76MK 2-786Sweden86.93 ± 15.12
77MK 2-787Sweden44.74 ± 12.32
78PANUSweden65.90 ± 34.88
79KONGE IIISweden37.50 ± 15.52
80TYSTOFTE SMAAHVEDESweden34.03 ± 10.88
81RENTALSweden57.33 ± 13.20
82STAVASweden53.88 ± 15.44
83RUDOLF RUBINSweden90.58 ± 13.79
84KIRSTENSweden42.80 ± 11.91
85LONESweden43.68 ± 8.71
86BRANDTSweden40.56 ± 11.73
87KARATSweden39.61 ± 17.13
88MK 2-101Sweden41.43 ± 17.05
89MK 2-113Sweden49.57 ± 24.98
90MK 2-116Sweden71.81 ± 24.64
91MK 2-122Sweden94.44 ± 13.61
92MK 2-130Sweden29.91 ± 10.39
93MK 2-316Sweden47.09 ± 15.38
94MK 2-317Sweden69.01 ± 13.76
95MK 2-337Sweden64.83 ± 15.38
96MK 2-567Sweden57.99 ± 39.13
97MK 2-655Sweden68.97 ± 26.56
98MK 2-138Sweden32.40 ± 16.47
99MK 2-679Sweden81.00 ± 7.12
100MK 2-788Sweden70.70 ± 10.31
101MK 2-847Sweden25.99 ± 13.17
102SaxildSweden37.17 ± 18.92
103AbbaSweden33.86 ± 4.74
104KonsulSweden100.00 ± 0.00
105RektorSweden35.89 ± 8.00
106StakadoSweden100.00 ± 0.00
107KerimäkeläinenSweden95.45 ± 9.09
108SampoSweden95.83 ± 9.32
109VäinöSweden87.20 ± 11.37
110Speltti VaaleaSweden67.79 ± 19.61
111Speltti Ruskea BaulanderSweden56.30 ± 18.53
112KökarSweden31.96 ± 8.09
113OlympiaSweden77.45 ± 13.20
114H 8703Sweden100.00 ± 0.00
115H 8196Sweden100.00 ± 0.00
116H 8202Sweden100.00 ± 0.00
117H 8222Sweden76.78 ± 35.98
118H 8296Sweden34.72 ± 28.69
119H 8300Sweden88.75 ± 15.56
120H 8305Sweden19.57 ± 7.03
121H 8310Sweden94.44 ± 9.62
122H 8311Sweden33.55 ± 7.08
-Control cultivar--
-Annong 8455China89.65 ± 2.33
-Sumai 3China24.21 ± 9.04
1 PIS is the percentage of infected spikelets.

2.2. Deoxynivalenol (DON) Levels in Wheat Grain, Straw, and Glume Tissues after Artificial Inoculation of Wheat Ears

A total of 122 wheat varieties were inoculated, and DON levels were determined in a total of 366 grain, straw, and glume samples. DON content was higher in glumes than in straw in 90.16% of the samples, and higher in straw than in grain samples in 73.77%. The DON content was higher in glumes than in grain in 95.90% of the samples (Figure 1). One-way analysis of variance (ANOVA) showed significant differences in DON content among grain, straw, and glumes (F = 42.20, p < 0.0001). The different plant sample types showed positive correlations (rgrain vs. straw = 0.261 **, rgrain vs. glume = 0.251 **, and rstraw vs. glume = 0.879 **). Although differences in mycotoxin content were large, the distribution of DON in plant tissues exhibited a distinct pattern (Table 2).
Table 2. Deoxynivalenol (DON) levels in samples of various wheat tissues determined using High Performance Liquid Chromatography-tandem Mass Spectrometry.
Table 2. Deoxynivalenol (DON) levels in samples of various wheat tissues determined using High Performance Liquid Chromatography-tandem Mass Spectrometry.
DON (mg/kg)
TissuenMean *MedianMaxMin
grain1223.88 A2.3823.460.16
straw12215.30 B7.85123.740.04
glume12220.95 C19.1355.421.15
*: Values in the same column with different capital letters were significantly different (α = 0.01); Different letters within a column represent significant difference at p = 0.01.
Figure 1. Distribution of deoxynivalenol in grain, glume and straw of wheat with different varieties.
Figure 1. Distribution of deoxynivalenol in grain, glume and straw of wheat with different varieties.
Toxins 07 00728 g001

2.3. DON Levels in Tissues from Wheat Varieties Exhibiting Differing FHB Disease Severity

To better understand how the level of DON contamination varied with FHB severity, we divided the entire dataset into three levels of FHB severity relative to the severity of FHB according to the control cultivars (Figure 2): <25% (n = 11, mean = 20.08%), 25%–89% (n = 85, mean = 52.94%), and >89% (n = 26, mean = 96.30%).
The DON contamination levels did not increase consistently with increasing FHB severity (Figure 2). The average and median DON levels were the highest in all three wheat tissues when the FHB severity was greater than 89%. In the grain and the straw, the average and median DON levels were lowest when the FHB severity was between 25% and 89%, whereas the lowest average and median levels in the glume occurred when the FHB severity was below 25%. In general, the DON levels in the wheat varieties that were highly resistant to FHB were not necessarily low, and the DON levels in the varieties that were highly sensitive to FHB were not necessarily high.
Figure 2. Box plots of the distribution of deoxynivalenol (DON) levels in wheat tissues ((A): grain; (B): straw; (C): glumes) inoculated with Fusarium graminearum at various levels of Fusarium head blight disease severity. Solid and dashed lines indicate medians and means, respectively. The box boundaries indicate the 75% and 25% quartiles. The whisker caps indicate 90th and 10th percentiles and the circles indicate the 95th and 5th percentiles.
Figure 2. Box plots of the distribution of deoxynivalenol (DON) levels in wheat tissues ((A): grain; (B): straw; (C): glumes) inoculated with Fusarium graminearum at various levels of Fusarium head blight disease severity. Solid and dashed lines indicate medians and means, respectively. The box boundaries indicate the 75% and 25% quartiles. The whisker caps indicate 90th and 10th percentiles and the circles indicate the 95th and 5th percentiles.
Toxins 07 00728 g002

2.4. Relationship between FHB Severity and DON Levels among Wheat Varieties and Selection of Wheat Genotypes with Reduced DON Content

To further compare the variation of DON contamination levels with FHB severity among wheat varieties, the data were allocated into four groups according to average FHB severity and DON contamination level: (1) varieties with low FHB severity and low DON contamination; (2) varieties with low FHB severity and high DON contamination; (3) varieties with high FHB severity and low DON contamination; and (4) varieties with high FHB severity and high DON contamination (Figure 2). The horizontal and vertical lines represent the y- and x-axis average values, respectively.
The relationship between DON content in grain and FHB severity is shown in Figure 3A. Groups 1, 2, 3, and 4 included 45, 25, 36, and 16 varieties, respectively. For the straw samples of the 122 wheat varieties, 41% were in group 1, 16% in group 2, 30% in group 3, and 13% in group 4 (Figure 3B). For the glume samples, 33% were in group 1, 25% in group 2, 26% in group 3, and 16% in group 4 (Figure 3C). Many of the samples exhibited low DON contamination levels (groups 1 and 3) and may correspond to varieties that would be useful for breeding new wheat varieties with low levels of DON accumulation.
Among the 122 varieties, 27 were consistently in group 1, six were consistently in group 2, 23 were consistently in group 3, and seven were consistently in group 4. For both straw and glumes, 13 varieties were consistently in group 1, 14 were consistently in group 2, nine were consistently in group 3, and nine were consistently in group 4. For both straw and grain, four varieties were consistently in group 1 and four varieties were consistently in group 3. For both grain and glumes, only six varieties were consistently in group 2.The varieties in group 1 had low DON contamination levels not only in the grain but also in the straw and glume. These varieties were Skagen, IDUNA, ANKA, EROICA, BANCO, NORRE, ROBUR, HILDUR, Harnesk-5, MK 2-302, MK2-313, MK 2-506, MK 2-508, MK 2-547, SALUT, MK 2-549, MK 2-775, MK 2-787, KONGE III, TYSTOFTE SMAAHVEDE, MK 2-316, MK 2-317, MK 2-567, Abba, Speltti Vaalea, Kökar, and Olympia.
Figure 3. Relationship between Fusarium head blight (FHB) severity and deoxynivalenol levels in wheat tissues ((A): grain; (B): straw; (C): glumes). Dashed lines indicate the average FHB severity (59%) and average concentration of DON ((A): 3.78 mg/kg, (B): 14.77 mg/kg, (C): 20.65 mg/kg) in 366 samples (grain samples = 122, straw samples = 122, glume samples = 122).
Figure 3. Relationship between Fusarium head blight (FHB) severity and deoxynivalenol levels in wheat tissues ((A): grain; (B): straw; (C): glumes). Dashed lines indicate the average FHB severity (59%) and average concentration of DON ((A): 3.78 mg/kg, (B): 14.77 mg/kg, (C): 20.65 mg/kg) in 366 samples (grain samples = 122, straw samples = 122, glume samples = 122).
Toxins 07 00728 g003
The varieties in group 3 had low DON contamination levels in all three wheat tissues while exhibiting high FHB severity. These varieties were Harnesk-7, ÅRING III, JYVÄ, SIGYN II, LANTVETE FRÅN UPPSALA, RENODLAT SAMMETSVETE, SVEA I, GUSALEK K.10 A, MK 2-304, MK 2-306, MK 2-557, MK 2-558, MK 2-564, MK 2-501, TJELVAR, MK 2-651, MK 2-780, PANU, MK 2-113, MK 2-788, Konsul, Sampo and Speltti Ruskea Baulander. We selected these 50 varieties as wheat genotypes with reduced DON content for future studies.

3. Discussion

Resistance to FHB can be characterized as consisting of two components: resistance to initial penetration and resistance to pathogen spread in the host tissue [22]. In addition to the resistance mechanisms that determine the severity of FHB, other mechanisms may influence DON content in kernels, including degradation or conjugation of DON and tolerance to DON [8,23,24]. DON tolerance results in an increased level of resistance and inherent prevention of trichothecene accumulation [25]. DON production is an important factor in the overall pathogenesis of FHB. Several studies have reported a significant positive correlation between the incidence of FHB and DON concentration [20,26]. Snijders and Perkowski reported that reduced disease incidence in the field ensured reduced mycotoxin content of the grain [8]. Correlations between FHB ratings and DON content were high in segregating material and in a collection of varieties with different levels of FHB resistance [27,28]. Others have demonstrated a significant correlation between DON and the fungal biomass of the grain [18,20,29]. These results suggest that new cultivars could be selected based on disease symptoms to ensure low levels of DON.
Bai et al. identified some wheat cultivars with severe FHB symptoms and low DON levels, particularly in cultivars with moderate resistance to F. graminearum [20]. Chen et al. inoculated five wheat varieties with a strain of F. graminearum and found no correlation between DON concentration and FHB severity [30]. Liu also found no correlation between DON concentration and FHB severity in wheat, barley (Hordeum vulgare L.) and oats (Avena sativa L.) after inoculation with a complex of Fusarium species [23]. In natural contamination, there was also no correlation between FHB severity in wheat and DON concentration or between the presence of Fusarium and DON concentration [31,32,33]. These differences in results may be due to the differences in the genotypes planted, pathogen populations, weather conditions, or management practices among the various studies.
Certain genotypes can limit the development of mycelium in the grain, thereby protecting it from degradation and limiting the visual signs of attack, but those genotypes often have low tolerance to mycotoxins [20]. Conversely, other cultivars may exhibit severe FHB symptoms and low mycotoxin levels. Beyer et al. studied the moderately susceptible wheat cultivar Dekan, which can partially avoid infection and then limit DON accumulation in the kernels when infections cannot be avoided [34].
We found DON contamination to be highest in glumes, intermediate in the straw, and lowest in the grain. DON produced by FHB in wheat can also have physiological effects in other parts of the plant [25]. Between the chaff and the kernel, several physical barriers could potentially limit the movement of the fungus and therefore prevent DON to move from the point of initial infection on the glumes or chaff to the kernel [35]. Snijiders et al. and Doohan et al. reported the ability of the toxin to translocate from chaff to the grain [36,37]. Data from previous studies suggest that the highest accumulation of mycotoxins in the barley hull [38]. Legzdina et al. reported that hulless barley tends to be less prone to mycotoxin contamination than covered barley, assuming a similar level of field FHB severity [39]. Wang and Miller reported higher levels of DON in the chaff than in the kernel of wheat [40].
In mature plants, DON appears to circulate in the phloem, with concentration following a descending gradient from the rachis, through the lemmas and grain, to the peduncle [41]. In our results, we found that the DON content was lowest in grain, then in straw and highest in glume. Schroeder and Christensen injected spores into the rachis and showed that the pathogen was able to migrate within the plant and propagate more rapidly longitudinally than transversely. Contaminated straw and glume residues remaining on the soil surface can infect seedlings of the following crop during the vegetative growth stage [42].
In conclusion, understanding the relationship between FHB severity and mycotoxin contamination is important. The conditions under which this relationship is purely qualitative rather than quantitative are unclear. In China, the increased use of high-yielding wheat varieties with greater susceptibility to FHB has increased the incidence of mycotoxins, indicating that the goal of a breeding program should be to select for both mycotoxin resistance and grain yield.

4. Materials and Methods

4.1. Reagents and Chemicals

DON was obtained from Sigma-Aldrich (Shanghai, China) at a concentration of 100 µg/mL in acetonitrile. HPLC-grade acetonitrile and methanol were obtained from Merck (Darmstadt, Germany). Deionized water (<8 MΩ cm−1 resistivity) was produced using a Milli-Q water purification system (Millipore, Bedford, MA, USA). All solvents were passed through 0.22-µm cellulose filters (Jinteng, Tianjin, China) before use.

4.2. Plant Material

Winter wheat seeds were obtained from the Nordic Genetic Resource Center in Alnarp, Sweden. Sumai-3 (high resistance) and Annong-8455 (high susceptibility) cultivars were used as control varieties to define levels of FHB resistance [43,44].
Winter wheat was grown according to current recommendations of integrated pest management, although applications of fungicide against Fusarium species were omitted. The field experiment was conducted at the Luhe experimental station, Jiangsu Academy of Agricultural Science (Luhe), Nanjing, China (32°28.583′N, 118°38′E) in 2011. Wheat was sown in late October in rows 150 cm in length and 33 cm apart with three replicates using a randomized block design.
An aggressive strain, F0613, was used to produce macroconidia in mung bean extraction liquid medium, as previously described [45]. The F0613 strain was isolated originally from diseased wheat grain in 2006 in Jiangsu Province. It belongs to Fusarium asiaticum, a member of the Fusarium graminearum species complex. At the heading stage, the middle spikelets of wheat flowers were inoculated with 10 μL of the conidial suspension containing 1 × 105 spores mL−1. Twenty days after inoculation, the numbers of infected spikelets and spikelets per head were recorded. The percentage of infected spikelets was calculated for each head. The mean FHB severity of 50 heads was calculated and all the 50 heads were pool into one sample for further analysis [46].

4.3. Mycotoxin Analysis

4.3.1. Preparation of Analytical Standard Solutions

Individual stock standard solutions were prepared as prescribed by the manufacturer. The working dilution for the calibration curve was prepared using a sample extract from a blank wheat sample (matrix-matched standard curve).

4.3.2. Sample Preparation

Harvested grain samples were cleaned manually. The glume was separated from the kernel. Straw was chopped into 3.0-cm segments that were subsequently pulverized. The grain was ground to a powder of 20-meshe fineness in a laboratory mill (Ika Werke, Staufen, Germany), and the chaff and straw were treated with liquid nitrogen and pulverized using a Moulinette 320-grinder (Moulinex, Barcelona, Spain). All samples were stored at 4 °C for a maximum of 7 day.
The finely ground samples (10 g) were weighed and extracted with 40 mL of acetonitrile:water:acetic acid (79:20:1 v/v/v) at 180 rpm for 30 min [47].
After centrifugation at 3000 rpm for 10 min, 0.5 mL of each final extract was diluted with acetonitrile:water:acetic acid (20:79:1, v/v/v) and filtered through a nylon filter (13 mm in diameter, 0.22-µm pore size) into an autosampler vial, capped and analyzed by LC-MS/MS [48].

4.3.3. LC-MS/MS Analysis

The LC-MS/MS system consisted of an Agilent 1200 HPLC, an Agilent 6410B triple-quadrupole mass spectrometer, and an Agilent MassHunter Workstation running Qualitative Analysis Version B.01.03 software (Agilent, Shanghai, China, 2001) for data acquisition and analysis. The analytical column was an XDB-C18 (2.1 × 150 mm, 3.5-µm bead diameter; Agilent, Shanghai, China) column and the column temperature was held constant at 30 °C. Nitrogen was used as a drying gas at 10 L/min. The capillary voltage was 4 kV, the nebulizer pressure was 25 psi, and the drying gas temperature was 350 °C. Mycotoxins were analyzed via multiple reaction monitoring (MRM). Mass spectrometric parameters of the mycotoxins and the composition of the mobile phase have been described by Soleimany et al. [49].
Quantification was performed against a matrix-matched calibration curve. During method development, limits of detection (LOD) and quantification (LOQ) scores for each analyte were determined on the basis of the signal-to-noise rations of 3:1 and 10:1. The LOD and LOQ scores were 10 and 20 µg/kg, respectively.

4.4. Statistical Analysis

All data are expressed as percentages or means ± relative standard deviation (RSD) using MS Excel.

Acknowledgments

The authors wish to acknowledge the Nordic Genetic Resource Center in Alnarp, Sweden, for providing winter wheat seeds. The work was supported financially by the National Institute of Food and Agriculture, Special Fund for Agro-scientific Research in the Public Interest (201303088), the National Natural Science Foundation of China (31271988), the Jiangsu Agriculture Science and Technology Innovation Fund of China (CX(13)3092), the Science and Technology Planning Project of Jiangsu Province, China (BE2014738), and the National Agricultural Products Quality Safety Risk Assessment Program of China (GJFP2014006)

Author Contributions

Jianrong Shi and Fang Ji conceived and designed the experiments; Fang Ji performed the experiments, analyzed the data and wrote the paper; Jirong Wu conducted the field experiment and calculated the Fusarium head blight severity; Hongyan Zhao and Jianhong Xu contributed reagents/materials/analysis tools.

Conflicts of Interest

The authors declare no conflict of interest.

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MDPI and ACS Style

Ji, F.; Wu, J.; Zhao, H.; Xu, J.; Shi, J. Relationship of Deoxynivalenol Content in Grain, Chaff, and Straw with Fusarium Head Blight Severity in Wheat Varieties with Various Levels of Resistance. Toxins 2015, 7, 728-742. https://0-doi-org.brum.beds.ac.uk/10.3390/toxins7030728

AMA Style

Ji F, Wu J, Zhao H, Xu J, Shi J. Relationship of Deoxynivalenol Content in Grain, Chaff, and Straw with Fusarium Head Blight Severity in Wheat Varieties with Various Levels of Resistance. Toxins. 2015; 7(3):728-742. https://0-doi-org.brum.beds.ac.uk/10.3390/toxins7030728

Chicago/Turabian Style

Ji, Fang, Jirong Wu, Hongyan Zhao, Jianhong Xu, and Jianrong Shi. 2015. "Relationship of Deoxynivalenol Content in Grain, Chaff, and Straw with Fusarium Head Blight Severity in Wheat Varieties with Various Levels of Resistance" Toxins 7, no. 3: 728-742. https://0-doi-org.brum.beds.ac.uk/10.3390/toxins7030728

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