LncRNA MIAT regulated by selenium and T-2 toxin increases NF-κB-p65 activation, promoting the progress of Kashin-Beck Disease.

LncRNA myocardial infarction associated transcript (MIAT) has been shown to be involved in osteoarthritis (OA), but its role in Kashin-Beck Disease (KBD) has rarely been reported. In this study, rats were administered with low selenium and/or T-2 toxin for 4 weeks to establish a KBD animal model. The serum selenium level, TNF-α and IL-1ß contents, phosphorylated p65 (p-p65) and MIAT expression were increased in each intervention group. Next, we isolated the primary epiphyseal chondrocytes, and found that selenium treatment reversed the effects of T-2 toxin on chondrocyte injury, p-p65 and MIAT expression. In addition, MIAT overexpression or T-2 toxin treatment led to increased cell death, apoptosis, inflammation, NF-κB-p65 pathway activation and MIAT expression, which was rescued by selenium treatment or MIAT siRNA transfection. Our results suggested that lncRNA MIAT regulated by selenium and T-2 toxin increased the activation of NF-κB-p65, thus being involved in the progress of KBD.

[Direct detection of T-2- and HT-2-mycotoxins producers of fungi the genus Fusarium in food grain by PCR (report 2)].

The improvement of the Fusarium DNA extraction method has been undertaken in order to reduce the error of PCR analysis for detection of toxigenic Fusarium species, including those contained in the grain in the uncultureted state, directly in the grain. The efficiency of Fusarium DNA extraction methods (nucleotides sorption and CTAB method) has been compared. The efficiency of CTAB method combined with 10-fold weight increase of milled grain sample has been demonstrated. This approach revealed a greater number of Fusarium species, than PCR analysis of combined Fusarium mycelium from the same samples. The uncultureted F. langsethiae was detected in the DNA extract from a sample of barley, which was not identified in the combined sample of the mycelium. This sample of the grain has the highest levels of T-2/NT-2-toxins--0,075/0,345 mg/kg (determined by HPLC) among positive samples. F. sporotrichioides--a potential producer of T-2- and HT-2-toxins has been revealed by PCR method in other grain samples both containing and not containing these toxins. The biosynthesis of T-2- and HT-2-toxins on the PSA-medium in vitro has been studied for 10 single-spores F. sporotrichioides isolates, allocated from grain. Synthesized T-2-toxin content (measured by ELISA) ranged from 0.4 to 184.5 mg per l of medium. Three strains showed very high levels from 117.2 to 184.4 mg/l, two of which have been isolated from barley which don't contain these toxins. The absence of the toxin in grain samples does not guarantee the absence of high-level producers of mycotoxins. The direct detection of Fusarium spp. in grain by PCR analysis with extraction of fungal DNA by CTAB method along with increased sample weight has been shown to make possible the detection of a more number of species of Fusarium (including uncultureol strains) compared with mycological method with PCR analysis of the combined sample of the mycelium.

Molecular studies to identify the Fusarium species responsible for HT-2 and T-2 mycotoxins in UK oats.

High levels of Fusarium mycotoxins HT-2 and T-2 have been detected in UK oats since surveys started in 2002. Fusarium langsethiae and the closely related species F. sporotrichioides have previously been associated with the contamination of cereals with type A trichothecenes HT-2 and T-2 in Nordic countries. Preliminary microbiological analysis of UK oat samples with high concentrations of HT-2 and T-2 detected and isolated F. langsethiae and F. poae but not the other type A trichothecene producing species F. sporotrichioides, F. sibiricum and F. armeniacum. Two hundred and forty oat flour samples with a known mycotoxin profile were selected from a previous four year study (2002-2005) to cover the full concentration range from below the limit of quantification (<20 µg/kg) to 9,990 µg/kg HT-2+T-2 combined. All samples were analysed for the DNA of F. langsethiae, F. poae and F. sporotrichioides based on previously published PCR assays. F. langsethiae was detectable in nearly all samples; F. poae was detected in 90% of samples whereas F. sporotrichioides was not detected in any sample. A real-time PCR assay was developed to quantify F. langsethiae DNA in plant material. The assay could quantify as low as 10(-4)ngF. langsethiae DNA/µl. Based on this assay and a previously published assay for F. poae, both species were quantified in the oat flour samples with known HT-2+T-2 content. Results showed a good regression (P<0.001, r(2)=0.60) between F. langsethiae DNA and HT-2+T-2 concentration. F. poae DNA concentration was not correlated to HT2+T2 concentration (P=0.448) but was weakly correlated to nivalenol concentration (P<0.001, r(2)=0.09). Multiple regression with F. langsethiae and F. poae DNA as explanatory variates identified that both F. langsethiae and F. poae DNA were highly significant (P<0.001) but F. poae DNA only accounted for an additional 4% of the variance and the estimate was negative, indicating that higher concentrations of F. poae DNA were correlated with slightly lower concentrations of HT2+T2 detected. A stronger regression (P<0.001, r(2)=0.77) between F. langsethiae DNA and HT-2+T-2 was obtained after extraction and quantification of DNA and mycotoxins from individual oat grains. The results from this study provide strong evidence that F. langsethiae is the primary, if not sole, fungus responsible for high HT-2 and T-2 in UK oats.

Phylogenetic analyses of the Fusarium poae, Fusarium sporotrichioides and Fusarium langsethiae species complex based on partial sequences of the translation elongation factor-1 alpha gene.

Phylogenetic relationships between four Fusarium species were studied using parts of the nuclear translation elongation factor-1 alpha (EF-1alpha) gene as a phylogenetic marker. Sequences from 12 isolates of Fusarium poae, 10 isolates of Fusarium sporotrichioides and 12 isolates of Fusarium langsethiae yielded 4, 5 and 5 haplotypes, respectively. In addition, we included one isolate of Fusarium kyushuense. The aligned sequences were subjected to neighbor-joining (NJ), maximum parsimony and maximum likelihood (ML) analyses. The results from the different analyses were highly concordant. The EF-1alpha-based phylogenies support the classification of F. langsethiae as a separate taxon in the section Sporotrichiella of Fusarium, as the closest sister taxon to F. sporotrichioides, while F. kyushuense is the sister taxon to F. poae. This corresponds well with the ability of F. langsethiae and F. sporotrichioides to produce T-2 and HT-2 toxins. In contrast, morphological characters indicate a closer relationship between F. langsethiae and F. poae on the one hand, and between F. sporotrichioides and F. kyushuense on the other hand.

Inactivation of a cytochrome P-450 is a determinant of trichothecene diversity in Fusarium species.

Species of the genus Fusarium produce a great diversity of agriculturally important trichothecene toxins that differ from each other in their pattern of oxygenation and esterification. T-2 toxin, produced by Fusarium sporotrichioides, and nivalenol (NIV), produced by some strains of F. graminearum, contain an oxygen at the C-4 position. Deoxynivalenol (DON), produced by other strains of F. graminearum, lacks a C-4 oxygen. NIV and DON are identical except for this difference, whereas T-2 differs from these trichothecenes at three other carbon positions. Sequence and Northern analyses of the F. sporotrichioides genomic region upstream of the previously described core trichothecene gene cluster have extended the cluster by two genes: TRI13 and TRI14. TRI13 shares significant similarity with the cytochrome P-450 class of enzymes, but TRI14 does not share similarity with any previously characterized proteins. Gene disruption and fermentation studies in F. sporotrichioides indicate that TRI13 is required for the addition of the C-4 oxygen of T-2 toxin, but that TRI14 is not required for trichothecene biosynthesis. PCR and sequence analyses indicate that the TRI13 homolog is functional in NIV-producing strains of F. graminearum but nonfunctional in DON-producing strains of the fungus. These genetic observations are consistent with chemical observations that biosynthesis of T-2 toxin and NIV requires a C-4 hydroxylase while biosynthesis of DON does not.

A genetic and biochemical approach to study trichothecene diversity in Fusarium sporotrichioides and Fusarium graminearum.

The trichothecenes T-2 toxin and deoxynivalenol (DON) are natural fungal products that are toxic to both animals and plants. Their importance in the pathogenicity of Fusarium spp. on crop plants has inspired efforts to understand the genetic and biochemical mechanisms leading to trichothecene synthesis. In order to better understand T-2 toxin biosynthesis by Fusarium sporotrichioides and DON biosynthesis by F. graminearum, we compared the nucleotide sequence of the 23-kb core trichothecene gene cluster from each organism. This comparative genetic analysis allowed us to predict proteins encoded by two trichothecene genes, TRI9 and TRI10, that had not previously been described from either Fusarium species. Differences in gene structure also were correlated with differences in the types of trichothecenes that the two species produce. Gene disruption experiments showed that F. sporotrichioides TRI7 (FsTRI7) is required for acetylation of the oxygen on C-4 of T-2 toxin. Sequence analysis indicated that F. graminearum TRI7 (FgTRI7) is nonfunctional. This is consistent with the fact that the FgTRI7 product is not required for DON synthesis in F. graminearum because C-4 is not oxygenated.

Evidence for a gene cluster involving trichothecene-pathway biosynthetic genes in Fusarium sporotrichioides.

Two overlapping cosmid clones (Cos1-1 and Cos9-1) carrying the Tox5 gene were isolated from a library of F. sporotrichioides strain NRRL 3299 genomic DNA. These cosmids were used to transform three T-2 toxin-deficient mutants that are blocked at different steps in the trichothecene pathway. Both cosmids restored T-2 toxin production to Tox3-1- or Tox4-1- mutants but neither restored T-2 toxin production to a Tox1-2- mutant. The production of T-2 toxin by the complemented Tox3-1- and Tox4-1- mutants, as well as the production of diacetoxycirpenol by the cosmid-transformed Tox1-2- mutant, were 2- to 10-fold higher than in strain NRRL 3299. In addition, those transformants carrying Cos9-1 produced significantly higher levels of trichothecenes than transformants carrying Cos1-1. Two different DNA fragments (FSC13-9 and FSC14-5), representing the region of overlap between the cosmid clones, were isolated. These fragments specifically complemented either the Tox3-1- mutant (FSC14-5) or the Tox4-1- mutant (FSC13-9). The trichothecene-production phenotype of these transformants was similar to NRRL 3299. These results suggest that two or more genes involved in the biosynthesis of trichothecenes are closely linked to Tox5.

Heterokaryosis in Fusarium tricinctum and F. sporotrichioides.

Heterokaryons were formed in intra- and interspecific crosses between Fusarium sporotrichioides and F. tricinctum auxotrophs. Segregant homokaryons were evaluated for trichothecene toxin production in culture. Results were consistent with nuclear control of toxin synthesis. The sexual compatibility of auxotrophs and 30 additional F. tricinctum sensu Snyder & Hansen strains was tested. Perithecial production was restricted to crosses between Florida isolates pathogenic to English ivy (Hedera helix). The linkage of several auxotrophic markers was determined by analysis of progeny of certain crosses. No T-2 toxin was produced by sexually compatible F. tricinctum isolates.