•An affinity-improved scFv antibody was compared to its parent monoclonal antibody.•scFv antibody-based detection of three fumonisin toxins in agricultural samples.•Good agreement of novel antibody-based fumonisin detection and a chemical method.•Favorable modeling of the scFv antibody structure complementary to fumonisins.Fumonisin B analogs, particularly FB1, FB2, and FB3, are major mycotoxins found in cereals. Single-chain fragment variable (scFv) antibodies represent a promising alternative immunoassay system. A phage-displayed antibody library derived from four monoclonal antibodies (mAbs) generated against FB1 was used to screen high binding affinity scFv antibodies; the best candidate was designated H2. Surface plasmon resonance measurements confirmed that the H2 scFv displayed a 82-fold higher binding affinity than its parent mAb. Direct competitive enzyme-linked immunosorbent assay demonstrated that the H2 antibody could competitively bind to free FB1, FB2, and FB3, with an IC50 of 0.11, 0.04, and 0.10 μM, respectively; it had no cross-reactivity to deoxynivalenol, nivalenol and aflatoxin. Validation assays with naturally contaminated samples revealed a linear relationship between the H2 antibody-based assay results and chemical analysis results, that could be expressed as y = 1.7072x + 5.5606 (R2 = 0.8883). Homology modeling of H2 revealed a favorable binding structure highly complementary to the three fumonisins. Molecular docking analyses suggested that the preferential binding of the H2 scFv to FB2 was due to the presence of a hydrogen radical in its R1 position, leading to a proper electrostatic matching and hydrophobic interaction. The H2 scFv antibody can be used for the rapid, accurate, and specific detection of fumonisin contamination in agricultural samples.

Wheat-specific ribosomal protein L21 (RPL21) is an endogenous reference gene suitable for genetically modified (GM) wheat identification. This taxon-specific RPL21 sequence displayed high homogeneity in different wheat varieties. Southern blots revealed 1 or 3 copies, and sequence analyses showed one amplicon in common wheat. Combined analyses with sequences from common wheat (AABBDD) and three diploid ancestral species, Triticum urartu (AA), Aegilops speltoides (BB), and Aegilops tauschii (DD), demonstrated the presence of this amplicon in the AA genome. Using conventional qualitative polymerase chain reaction (PCR), the limit of detection was 2 copies of wheat haploid genome per reaction. In the quantitative real-time PCR assay, limits of detection and quantification were about 2 and 8 haploid genome copies, respectively, the latter of which is 2.5–4-fold lower than other reported wheat endogenous reference genes. Construct-specific PCR assays were developed using RPL21 as an endogenous reference gene, and as little as 0.5% of GM wheat contents containing Arabidopsis NPR1 were properly quantified.

A sensitive and specific analytical method to detect ubiquitous aflatoxigenic Aspergillus pathogens is essential for monitoring and controlling aflatoxins. Four highly reactive chicken single-chain variable fragments (scFvs) against soluble cell wall proteins (SCWPs) from Aspergillus flavus were isolated by phage display. The scFv antibody AfSA4 displayed the highest activity toward both A. flavus and A. parasiticus and specifically recognized a surface target of their cell walls as revealed by immunofluorescence localization. Molecular modeling revealed a unique compact motif on the antibody surface mainly involving L-CDR2 and H-CDR3. As measured by surface plasmon resonance, AfSA4 fused to alkaline phosphatase had a higher binding capability and 6-fold higher affinity compared with AfSA4 alone. Immunoblot analyses showed that the fusion had good binding capacity to SCWP components from the two fungal species. Direct sandwich enzyme-linked immunosorbent assays with mouse antiaspergillus monoclonal antibody mAb2A8 generated in parallel as a capture antibody revealed that the detection limit of the two fungi was as low as 10–3 μg/mL, 1000-fold more sensitive than that reported previously (1 μg/mL). The fusion protein was able to detect fungal concentrations below 1 μg/g of maize and peanut grains in both artificially and naturally contaminated samples, with at least 10-fold more sensitivity than that reported (10 μg/g) thus far. Thus, the fusion can be applied in rapid, simple, and specific diagnosis of Aspergillus contamination in field and stored food/feed commodities.

Fusarium and its poisonous mycotoxins are distributed worldwide and are of particular interest in agriculture and food safety. A simple analytical method to detect pathogens is essential for forecasting diseases and controlling mycotoxins. This article describes a proposed method for convenient and sensitive detection of Fusarium pathogens that uses the fusion of single-chain variable fragment (scFv) and alkaline phosphatase (AP). A highly reactive scFv antibody specific to soluble cell wall-bound proteins (SCWPs) of F. verticillioides was selected from an immunized chicken phagemid library by phage display. The antibody was verified to bind on the surface of ungerminated conidiospores and mycelia of F. verticillioides. The scFv–AP fusion was constructed, and soluble expression in bacteria was confirmed. Both the antibody properties and enzymatic activity were retained, and the antigen-binding capacity of the fusion was enhanced by the addition of a linker. Surface plasmon resonance measurements confirmed that the fusion displayed 4-fold higher affinity compared with the fusion's parental scFv antibody. Immunoblot analyses showed that the fusion had good binding capacity to the components from SCWPs of F. verticillioides, and enzyme-linked immunosorbent assays revealed that the detection limit of the fungus was below 10−2 μg mL−1, superior to the scFv antibody. The fusion protein was able to detect fungal concentrations as low as 10−3 mg g−1 of maize grains in both naturally and artificially contaminated samples. Thus, the fusion can be applied in rapid and simple diagnosis of Fusarium contamination in field and stored grain or in food.Graphical abstractA phage-displayed chicken scFv antibody, FvSG7, binds on the surface antigen of conidiospores and the mycelia of F. verticillioides. Its fusion with alkaline phosphatase (AP) through a 218 linker displayed a 4-fold higher affinity compared with the parent scFv antibody and efficiently detected toxigenic Fusarium pathogens in cereal grains.Highlights► Generation of a highly reactive scFv antibody against F. verticillioides. ► Localization of the antibody binding to the surface target of F. verticillioides. ► Expression of the antibody–alkaline phosphatase (AP) fusion linked by a 218 linker. ► The antibody–AP fusion has a higher affinity than the parental antibody. ► The antibody–AP fusion detects toxigenic Fusarium pathogens in cereal grains.

Introduction of alien genes into wheat has been proposed as a strategy to breed cultivars with improved resistance to Fusarium seedling blight (FSB) and Fusarium head blight (FHB). In this study, we co-transformed different anti-fungal peptides (AFPs) into an elite wheat cultivar Yangmai11. We identified the genetically stable transgenic wheat lines carrying single or multiple genes by PCR, qRT-PCR and Southern blot analyses. Transgenic wheat lines 451 and 513 expressing two AFPs displayed a consistent, significantly improved overall resistance to FSB and FHB, whereas only FHB resistance was observed from other lines. Furthermore, crude proteins extracted from the lines 451 and 513 showed a clear inhibitory activity against F. graminearum in vitro. Taken together, it was essential to properly combine and express AFPs in transgenic wheat in order to obtain an improved overall resistance to Fusarium pathogens.

Fusarium graminearum (FG) is a serious plant pathogen causing huge losses in global production of wheat and other cereals. Tri5-gene encoded trichodiene synthase is the first key enzyme for biosynthesis of trichothecene mycotoxins in FG. To further our understandings of FG metabolism which is essential for developing novel strategies for controlling FG, we conducted a comprehensive investigation on the metabolic changes caused by Tri5-deletion by comparing metabolic differences between the wild-type FG5035 and an FG strain, Tri5−, with Tri5 deleted. NMR methods identified more than 50 assigned fungal metabolites. Combined metabonomic and quantitative RT-PCR (qRT-PCR) analyses revealed that Tri5 deletion caused significant and comprehensive metabolic changes for FG apart from mycotoxin biosynthesis. These changes involved both carbon and nitrogen metabolisms including alterations in GABA shunt, TCA cycle, shikimate pathway, and metabolisms of lipids, amino acids, inositol, choline, pyrimidine, and purine. The hexose transporter has also been affected. These findings have shown that Tri5 gene deletion induces widespread changes in FG primary metabolism and demonstrated the combination of NMR-based metabonomics and qRT-PCR analyses as a useful way to understand the systems metabolic changes resulting from a single specific gene knockout in an eukaryotic genome and thus Tri5 gene functions.

A protocol for chloroplast transformation of an elite rapeseed cultivar (Brassica napus L.) was developed based on optimized conditions for callus induction and regeneration from cotyledonary tissues. Comparison of six different media with three elite cultivars showed that B5 medium plus 3 mg/l AgNO3 supplemented with 0.6 mg/l 2,4-dichlorophenoxyacetic acid and 0.2 mg/l 6-furfurylaminopurine was optimal for callus formation and maintenance without differentiation, while the medium suitable for regeneration was B5 medium supplemented with 1 mg/l 6-benzylaminopurine, 1 mg/l 6-furfurylaminopurine and 0.5 mg/l α-naphthaleneacetic acid. A rapeseed-specific chloroplast transformation vector was constructed with the trnI and trnA sequences amplified from the rapeseed chloroplast genome using two primers designed according to Arabidopsis homologs. The aadA gene was used as a selection marker regulated by the ribosome-binding site from the bacteriophage T7 gene 10L, the tobacco 16S rRNA promoter and the psbA terminator. After bombardment, cotyledonary segments were cultured for callus formation on media containing 10 mg/l spectinomycin and regeneration was carried out on medium with 20 mg/l spectinomycin. Heteroplasmic plastid transformants were isolated. An overall efficiency for the chloroplast transformation was one transplastomic plant per four bombarded plates. Southern blot analyses demonstrated proper integration of the target sequence into the rapeseed chloroplast genome via homologous recombination. The expression of the aadA gene was confirmed by Northern blot analysis. Analysis of T1 transplastomic plants revealed that the transgenes integrated into the chloroplast were inheritable with a ratio of about 8%. These results suggest that rapeseed may be a suitable crop for chloroplast transformation with cotyledons as explants under appropriate conditions.

Highlights•Functional characterization of a Myo2 gene in F. graminearum.•Myo2 is essential for septation and sexual development.•Myo2 is required for virulence and mycotoxin biosynthesis.•Time-lapse imaging of septation process in Δmyo2 mutant and wild-type.•Lively monitoring of GFP-tagged Myo2 in hyphal and conidial development.Type II myosin is required for cytokinesis/septation in yeast and filamentous fungi, including Fusarium graminearum, a prevalent cause of Fusarium head blight in China. A type II myosin gene from the Chinese F. graminearum strain 5035, isolated from infected wheat spikes, was identified by screening a mutant library generated by restriction enzyme-mediated integration. Disruption of the Myo2 gene reduced mycelial growth by 50% and conidiation by 76-fold, and abolished sexual reproduction on wheat kernels. The Δmyo2 mutants also had a 97% decrease in their pathogenicity on wheat, and mycotoxin production fell to just 3.4% of the normal level. The distribution of nuclei and septa was abnormal in the mutants, and the septal ultrastructure appeared disorganized. Time-lapse imaging of septation provided direct evidence that Myo2 is required for septum initiation and formation, and revealed the dynamic behavior of GFP-tagged Myo2 during hyphal and macroconidia development, particularly in the delimiting septum of phialides and macroconidial spores. Microarray analysis identified many genes with altered expression profiles in the Δmyo2 mutant, indicating that Myo2 is required for several F. graminearum developmental processes and biological activities.

The viviparous-1 (Vp1) gene from maize encodes a transcription factor involved in abscisic acid (ABA) signaling that is associated with seed dormancy and preharvest sprouting (PHS). Mis-splicing of wheat homologous Vp1 transcripts has been considered the main factor causing PHS sensitivity in wheat. A maize Vp1 gene including its promoter and coding sequence was used for Agrobacterium tumefaciens mediated transformation of an elite wheat cultivar, Zheng9023. Plants expressing the Vp1 gene displayed a genetically stable, significantly enhanced seed dormancy and PHS tolerance. A significant reduction of α-amylase activity of mature grains was detected in all the transgenic wheat plants. Furthermore, quantitative real-time polymerase chain reactions revealed that more transcripts for the genes involved in VP1/ABA signaling, such as the genes coding for wheat ABA-insensitivity, malate oxidoreductase, peroxiredoxin, and late embryogenesis abundant proteins, were concomitantly accumulated during seed development in the transgenic wheat plants compared with the non-transgenic Zheng9023. These results indicated a highly functional compensation of the Vp1 gene in wheat by an alien homolog from maize, providing a promising approach to breed wheat cultivars with improved tolerance for PHS through a genetic engineering process.Highlights► Heterologous expression of a maize Vp1 gene regulated by its own promoter in wheat. ► Enhancement of seed dormancy and PHS tolerance in wheat by genetic engineering. ► Seed dormancy and PHS tolerance closely correlated with α-amylase activity and expression of ABA signaling genes in transgenic wheat. ► Functional compensation of wheat Vp1 by a maize homolog. ► Generation of transgenic wheat using Pmi gene as selection marker mediated by Agrobacterium.

A large number of isolates from the Fusarium graminearum clade representing all regions in China with a known history of Fusarium head blight (FHB) epidemics in wheat were assayed using PCR to ascertain their trichothecene mycotoxin chemotypes and associated phylogenetic species and geographical distribution. Of the 299 isolates assayed, 231 are from F. asiaticum species lineage 6, which produce deoxynivalenol and 3-acetyldeoxynivalenol (3-AcDON); deoxynivalenol and 15-acetyldeoxynivalenol (15-AcDON); and nivalenol and 4-acetylnivalenol (NIV) mycotoxins, with 3-AcDON being the predominant chemotype. Ninety-five percent of this species originated from the warmer regions where the annual average temperatures were above 15 °C, based on the climate data of 30 y during 1970–1999. However, 68 isolates within F. graminearum species lineage 7 consisted only of 15-AcDON producers, 59 % of which were from the cooler regions where the annual average temperatures were 15 °C or lower. Identification of a new subpopulation of 15-AcDON producers revealed a molecular distinction between F. graminearum and F. asiaticum that produce 15-AcDON. An 11-bp repeat is present in F. graminearum within their Tri7 gene sequences but is absent in F. asiaticum, which could be directly used for differentiating the two phylogenetic species of the F. graminearum clade.