Insects are rich in proteins and could be an alternative source of proteins to feed animals and humans. Numerous companies have started the production of insects for feed purposes. In Europe, these processed animal proteins are not yet authorised by legislation as many questions still need to be answered concerning this 'novel food'. Authorisations will be possible when methods of authentication of the products are available. In this study we propose real-time PCR methods for the specific detection of the mealworm (Tenebriomolitor), one of the most widely used insects for food and feed production. Two PCR assays are proposed: the first based on the wingless gene and the second based on the cadherin gene. The PCR tests amplify fragments of 87 bp. These qualitative methods were tested according to several performance criteria. The specificity was tested on 34 insect species' DNA, but also on non-insect species including crustacean, mammals, birds and plants. The limit of detection was determined and was below 20 copies for the two PCR tests. The applicability of the tests was demonstrated by the analysis of real-life processed samples containing T. molitor.
Insects are rich in proteins and could be an alternative source of macronutrients to feed animals and humans. Over the past few years, numerous companies have started producing insects for feed purposes. In Europe, the processed animal proteins obtained from seven insect species have been authorised for aquaculture by Commission Regulation (EU) 2017/893 since 1 July 2017. Methods of authentication are required to check the conformity of the products. In this study, we propose a real-time PCR method for the specific detection of the black soldier fly (Hermetia illucens L.), one of the most widely used insects for feed production. The developed PCR assays amplify a 67 bp fragment based on the mitochondrial COX3 gene coding for subunit 3 of the cytochrome c oxidase. The qualitative method was tested according to several performance criteria. The specificity was tested against 51 insect species. The specificity was also checked against plant species and other animal species such as crustaceans, mammals and birds. The sensitivity, efficiency and robustness of the PCR test were successfully tested. The applicability of the test was proven through the analysis of real-life processed samples (industrial meals) of H. illucens.
The availability of robust methods for the species-specific detection of meat and bone meal (MBM) in compound feedingstuffs is an important prerequisite to enforce current and upcoming European legislation on the use of processed animal proteins in animal nutrition. Among possible methods, those based on DNA turned out to be a reliable tool for this aim, since DNA is a quite thermostable molecule able to resist severe heat treatments applied in the manufacturing of animal meals. The application of such methods by control laboratories implies that the method has been validated including an assessment of its robustness. Successful transferability between laboratories is considered an important robustness criterion of the method. However, corresponding guidelines regarding the design of such a study relevant to this field are missing. Here, we demonstrate the feasibility of an alternative concept that was applied to check for the transferability of a qualitative assay for the detection of banned MBM in feedingstuffs at trace level based on real-time PCR. The concept was based on an experimental nested design applying analysis of variance (ANOVA) that was conducted independently in two laboratories and which allows for establishing major factors influencing the result of analysis. Statistical assessment of the results confirmed the importance of the DNA extraction/purification step utilised, whereas the PCR step turned out to be a minor factor regarding the overall variability of the results. Furthermore, blind samples comprised of compound feed adulterated with MBM at 0.1% and blank compound feed were correctly classified as "positive" or "negative" samples, thus confirming fitness of purpose for the method. This approach can be of interest for other research groups working in the development of real-time PCR methods and in their use by control laboratories.
Description of the subject. This paper discusses the influence of amplicon length on real-time PCR results. Objectives. The aim of the experiments was to show that amplicon size has an influence on detection. Method. Tests were performed on genomic and plasmid DNA. Double-dye probes and SYBR® Green were used for detection by real-time PCR. Primers were selected in order to produce fragments with increasing sizes. Experiments dealt with two targets: an endogenous target for soybean (part of the lectin gene) and a transgenic target (junction P35S-CTP of the MON40-3-2 soybean). Results. The results show that the kinetics of amplification curves evolve as a function of amplicon length, and smaller amplicons yield a higher level of fluorescence for the plateau phase. DNA degradation within the sample as well as the principles of fluorescence acquisition as a function of the chemistry used can also be factors. Conclusions. It was experimentally shown that the observed effect is linked to the suboptimal elongation temperature used in real-time PCR. Detection using SYBR® Green is less impacted as the loss of efficiency is partially compensated by the greater integration of SYBR® Green molecules in the larger fragments.
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