BackgroundThe current study was carried out to provide a reference for monitory of aflatoxin B1 (AFB1), zearalenone (ZEN) and deoxynivalenol (DON) contamination in feed ingredients and complete feeds were collected from different Province in China from 2013 to 2015.MethodsA total of 443 feed ingredients, including 220 corn, 24 wheat, 24 domestic distillers dried grains with soluble (DDGS), 55 bran, 20 wheat shorts and red dog, 37 imported DDGS, 34 corn germ meal and 29 soybean meal as well as 127 complete feeds including 25 pig complete feed (powder), 90 pig complete feed (pellet), six duck complete feed and six cattle complete feed were randomly collected from different Province in China, respectively, by high-performance chromatography in combined with UV or fluorescence analysis.ResultsThe incidence rates of AFB1, ZEN and DON contamination of feed ingredients and complete feeds were 80.8, 92.3 and 93.9 %, respectively. The percentage of positive samples for DON ranged from 66.7 to 100 %. Domestic DDGS and imported DDGS presented the most serious contamination AFB1, ZEN and DON contamination levels of feeds ranged from 61.5 to 100 %, indicated that serious contamination over the studied 3-year period.ConclusionThe current data provide clear evidence that AFB1, ZEN and DON contamination of feed ingredients and complete feeds in different Province in China is serious and differs over past 3-year. The use of corn, domestic DDGS, imported DDGS and corn germ meal, which may be contaminated with these three mycotoxins, as animal feed may triggered a health risk for animal. Feeds are most contaminated with DON followed by ZEN and AFB1. Mycotoxins contamination in feed ingredients and complete feeds should be monitored routinely in China.
BackgroundItaconic acid, which has been declared to be one of the most promising and flexible building blocks, is currently used as monomer or co-monomer in the polymer industry, and produced commercially by Aspergillus terreus. However, the production level of itaconic acid hasn’t been improved in the past 40 years, and mutagenesis is still the main strategy to improve itaconate productivity. The genetic engineering approach hasn’t been applied in industrial A. terreus strains to increase itaconic acid production.ResultsIn this study, the genes closely related to itaconic acid production, including cadA, mfsA, mttA, ATEG_09969, gpdA, ATEG_01954, acoA, mt-pfkA and citA, were identified and overexpressed in an industrial A. terreus strain respectively. Overexpression of the genes cadA (cis-aconitate decarboxylase) and mfsA (Major Facilitator Superfamily Transporter) enhanced the itaconate production level by 9.4% and 5.1% in shake flasks respectively. Overexpression of other genes showed varied effects on itaconate production. The titers of other organic acids were affected by the introduced genes to different extent.ConclusionsItaconic acid production could be improved through genetic engineering of the industrially used A. terreus strain. We have identified some important genes such as cadA and mfsA, whose overexpression led to the increased itaconate productivity, and successfully developed a strategy to establish a highly efficient microbial cell factory for itaconate protuction. Our results will provide a guide for further enhancement of the itaconic acid production level through genetic engineering in future.Electronic supplementary materialThe online version of this article (doi:10.1186/s12934-014-0119-y) contains supplementary material, which is available to authorized users.
Faced with the complex medical challenge presented by spinal cord injuries (SCI) and considering the lack of any available curative therapy, the development of a novel method of delivering existing drugs or candidate agents can be perceived to be as important as the development of new therapeutic molecules. By combining three ingredients currently in clinical use or undergoing testing, we have designed a central nervous system targeted delivery system based on apamin-modified polymeric micelles (APM). Apamin, one of the major components of honey bee venom, serves as the targeting moiety, poly(ethylene glycol) (PEG) distearoylphosphatidylethanolamine (DSPE) serves as the drug-loaded material, and curcumin is used as the therapeutic agent. Apamin was conjugated with NHS (N-hydroxysuccinimide)-PEG-DSPE in a site-specific manner, and APM were prepared by a thin-film hydration method. A formulation comprising 0.5 mol % targeting ligand with 50 nm particle size showed strong targeting efficiency in vivo and was evaluated in pharmacodynamic assays. A 7-day treatment by daily intravenous administration of low doses of APM (corresponding to 5 mg/kg of curcumin) was performed. Significantly enhanced recovery and prolonged survival was found in the SCI mouse model, as compared to sham-treated groups, with no apparent toxicity. A single dose of apamin-conjugated polymers was about 700-fold lower than the LD50 amount, suggesting that APM and apamin have potential for clinical applications as spinal cord targeting ligand for delivery of agents in treatment of diseases of the central nervous system.
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