Beatriz Herrero

Authentication of Atlantic cod (Gadus morhua) using real time PCR.

This work describes the development of a real-time polymerase chain reaction (RT-PCR) system for the detection and identification of Atlantic cod (Gadus morhua). Among the advantages of this technique, it is worth highlighting that this is reliable in terms of specificity and sensitivity. The TaqMan real-time PCR is the simplest, fastest testing process and has the highest potential for automation, therefore representing the currently most suitable method for screening, allowing the detection of fraudulent or unintentional mislabeling of this species. The method can be applied to all kinds of products, fresh, frozen, and processed products, including those undergoing intensive processes of transformation. The developed methodology using specific primer-probe set was validated and further applied to 40 commercial samples labeled as cod in order to determinate if the species used for their manufacturing corresponded to G. morhua, detecting 20% that were incorrectly labeled. A C(t) value of about 19 was obtained when G. morhua was present. In samples with a species mixture, all samples that had a fluorescence signal were positive (C(t) < 30) for the presence of G. morhua by conventional end-point RT-PCR, and the estimated limit of detection for these type of samples was of 20 pg of DNA. The methodology herein developed is useful to check the fulfilment of labeling regulations for seafood products and verify the correct traceability in commercial trade and for fisheries control.

Genetic identification of horse mackerel and related species in seafood products by means of forensically informative nucleotide sequencing methodology.

In the present study, a methodology based on the amplification of a fragment of mitochondrial cytochrome b and subsequent phylogenetic analysis (FINS: forensically informative nucleotide sequencing) to genetically identify horse mackerels have been developed. This methodology makes possible the identification of more than 20 species belonging to the families Carangidae, Mullidae, and Scombridae. The main novelty of this work lies in the longest number of different horse mackerel species included and in the applicability of the developed methods to all kinds of processed products that can be found by consumers in markets around the world, including those that have undergone intensive processes of transformation, as for instance canned foods. Finally, the methods were applied to 15 commercial samples, all of them canned products. Therefore, these methods are useful for checking the fulfillment of labeling regulations for horse mackerels and horse mackerel products, verifying the correct traceability in commercial trade, and fisheries control.

Fast real-time PCR for the detection of crustacean allergen in foods.

Crustaceans are one of the most common allergens causing severe food reaction. These food allergens are a health problem, and they have become very important; there are various regulations that establish that labeling must be present regarding these allergens to warn consumers. In the present work a fast real-time PCR, by a LNA probe, was developed. This allows the detection of crustaceans in all kinds of products, including processed products in which very aggressive treatments of temperature and pressure during the manufacturing process are used. This methodology provides greater sensitivity and specificity and reduces the analysis time of real-time PCR to 40 min. This methodology was further validated by means of simulating products likely to contain this allergen. For this, products present on the market were spiked with crustacean cooking water. The assay is a potential tool in issues related to the labeling of products and food security to protect the allergic consumer.

Validation of end-point and real-time PCR methods for the rapid detection of soy allergen in processed products

This work describes the development and validation of two PCR methods, end-point and real-time PCR, for the detection of soy protein in a wide rage of foodstuffs. These techniques are reliable and sensitive, allowing detection of trace amounts of soybean in processed products. TaqMan real-time PCR was the simpler and more rapid process, with a higher potential for automation and, therefore, currently the most suitable screening method. To verify correct operation of the proposed methodology, ELISA was used for quantitative determination of soy protein. In addition, 35 meat, fish and bakery processed products, which could potentially contain soy but was not declared on the label, were tested for the presence of soy DNA using the proposed methods. The methodologies will be valuable in issues regarding the presence of soy protein in processed products, especially in verifying labelling and security regulations to protect consumers rights.

Authentication of Atlantic salmon (Salmo salar) using real-time PCR

A real-time PCR assay based on LNA TaqMan probe technology was developed for the detection and identification of Atlantic salmon (Salmo salar). Among the advantages it is worth highlighting simplicity, rapidity, highest potential for automation and minor risk of contamination of this technique. The TaqMan real-time PCR is the currently most suitable method for screening, allowing the detection of fraudulent or unintentional mislabelling of this species. The method can be applied to all kind of products, fresh, frozen and processed products, including those undergoing intensive processes of transformation. The developed methodology using specific primers-probe set was validated and further applied to 20 commercial samples labelled as salmon or S. salar in order to determinate if the species used for their manufacturing corresponded to this species. The methodology herein developed is useful to check the fulfilment of labelling regulations for seafood products, verify the correct traceability in commercial trade and for fisheries control.

Real-time PCR method applied to seafood products for authentication of European sole (Solea solea) and differentiation of common substitute species

Judged by quality and taste, the European sole (Solea solea) is considered one of the finest flatfish and is, thus, of considerable commercial value. In the present work, a specific fast real-time PCR was developed for the authentication of S. solea, i.e. to distinguish it from other related species and avoid substitution of this species, either deliberately or unintentionally. The method is based on a species-specific set of primers and MGB Taqman probe which amplifies a 116-bp fragment of the internal transcribed spacer 1 (ITS 1) ribosomal DNA region. This assay combines the high specificity and sensitivity of real-time PCR with the rapidity of the fast mode, allowing the detection of S. solea in a short period of time. The present methodology was validated for application to all types of manufactured products for the presence of S. solea, with successful results. Subsequently, the method was applied to 40 commercial samples to determine whether correct labeling had been employed in the market. It was demonstrated that the assay is a useful tool in monitoring and verifying food labeling regulations.

Development of an in-house fast real-time PCR method for detection of fish allergen in foods and comparison with a commercial kit.

Food allergy is recognised as an important human health problem. Fish represent one of the most important causes of food hypersensitivity reaction. Small amounts of the allergen can cause severe reactions in sensitive individuals, so correct labelling is essential to ensure the protection of consumers. The objective of the present work was to develop a reliable, sensitive and specific real-time PCR method for the detection of fish and traces of fish in all kind of products included those that have undergone aggressive treatments such as high temperature or pressure. This methodology was validated simulating products likely to contain this allergen and spiking them with fish cooking water. In addition, a comparison between the performance of in-house methodology and a commercial kit, both of them based on real-time PCR, was carried out. This work is relevant because it is the first, rapid real-time PCR method developed to date for the detection of fish in processed food products. The results obtained confirm the present assay is a useful tool in detecting fish and, therefore, minimising exposure and reducing incidences of allergic reaction to fish in contaminated products.

Authentication of male beef by multiplex fast real-time PCR

Meat is a significant source of high-quality nutrients, which are very important in the diet. Among meat products, one of the most prized is bovine meat, of which male beef has been designated to be of a higher quality. However, because of its similarity with female beef, deliberate or unintentional substitutions can occur. To avoid this, methodology based on the fast real-time polymerase chain reaction has been developed to authenticate the species and gender origin of beef. This technique consists of two polymerase chain reactions: one bovine-specific reaction and another Y-chromosome–specific multiplex reaction. This methodology has been validated for all kinds of beef products, including those subjected to intensive processing treatments, and it has subsequently been applied to 10 commercial samples labelled as ox to determine whether they are properly labelled. This assay has been shown to have high specificity, sensitivity and rapidity, with the potential to be a powerful tool in enforcing food labelling regulations.

Rapid method for controlling the correct labeling of products containing European squid (Loligo vulgaris) by fast real-time PCR

The squids are a group of cephalopods widely distributed and with high commercial value. In the present work, a fast real-time PCR was developed for the authentication of the European squid (Loligo vulgaris). This method is based on a specific primer/probe set that amplifies a fragment of the Internal Transcribed Spacer 1 (ITS 1) ribosomal DNA region. This technique is notable for its conceptual and practical simplicity, together with its combination of speed, sensitivity and specificity in a homogeneous assay. To all this must be added the time savings produced by the fast real-time PCR due to shorter runs. The presented methodology was validated to check how the degree of food processing affects the applicability of this technique and therefore the detection of L. vulgaris. It was demonstrated that the technique can be applied to all kinds of processed products. The commercial denomination of some cephalopods, including European squids, is an important issue due to the legal gaps, since the same species has different commercial name depending on the format in the market. The methodology herein developed was applied to 42 commercial samples to evaluate the situation regarding the labeling of products made from these species. Moreover, the method can be applied to all kinds of products regardless of the degree of processing.

Rapid identification of seaweeds in food products by PCR combined with ALF-RFLP and FINS methodologies.

In the present study, two methods for the genetic identification of the most important seaweed species used for human consumption were developed. Both are carried out through PCR amplification of an 18S rRNA gene fragment. The first one is based on the phylogenetic analysis of DNA sequences (FINS), while the second is based on length polymorphism and RFLP visualized by means of an ALF system. The main novelty of this work lies in the fact that it allows genetic identification of the main commercial species of seaweed. Moreover, the developed systems can be applied to all kinds of processed products, including those that have undergone intensive transformation, as for instance canned foods. These methodologies also permit the detection of species in complex matrixes where more than one algal species is present. The methods were validated using products manufactured in a pilot plant showing correct functioning. Finally, the methods were applied to 23 commercial samples including some that had been subjected to intensive thermal treatment, allowing the detection of those that were incorrectly labeled (30%). Therefore, these molecular tools can be used for clarifying questions related to the correct labeling and traceability of commercial products that include some seaweeds in their composition.