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.     

Authentication of anglerfish species (Lophius spp) by means of polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) and forensically informative nucleotide sequencing (FINS) methodologies

Lophius represents the most important genus of the family Lophiidae from a commercial point of view. The main marketing formats of the species included in this genus are tails and cheeks, making impossible the species identification on the basis of their morphological characters. In the present study, two methods based on the polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) and phylogenetic analysis of DNA sequences [forensically informative nucleotide sequencing (FINS)] were developed to differentiate the seven species contained in the genus Lophius. In both cases, the molecular marker studied was the cytochrome oxidase subunit I gene (COI). The RFLP analysis of the PCR products digested with the endonuclease Mbo I generated species-specific restriction profiles, and the phylogenetic analysis showing a neighbor-joining tree with independent nodes was strongly supported for all of the studied species. These methods were applied to 40 commercial samples, allowing us to detect the samples incorrectly labeled. The fraudulent labeling ratio was higher in processed products (68.75%) than whole fish (31.25%). The species subjected to mislabeling were L. budegassa (68.75%), L. vomerinus (18.75%), and L. piscatorius (12.5%). Therefore, both methodologies can be independently used to authenticate the species belonging to the genus Lophius, being useful to check the fulfillment of labeling regulations of seafood products and to verify the correct traceability of commercial trade and the control of fisheries.     

Identification of shark species in seafood products by forensically informative nucleotide sequencing (FINS)

The identification of commercial shark species is a relevant issue to ensure the correct labeling of seafood products, to maintain consumer confidence in seafood, and to enhance the knowledge of the species and volumes that are at present being captured, thus improving the management of shark fisheries. The polymerase chain reaction was employed to obtain a 423 bp amplicon from the mitochondrial cytochrome b gene. The sequences from this fragment, belonging to 63 authentic individuals of 23 species, were analyzed using a genetic distance method. Nine different samples of commercial fresh, frozen, and convenience food were obtained in local and international markets to validate the methodology. These samples were analyzed, and sequences were employed for species identification, showing that forensically informative nucleotide sequencing (FINS) is a suitable technique for identification of processed seafood containing shark as an ingredient. The results also showed that incorrect labeling practices may occur regarding shark products, probably because of incorrect labeling at the production point.     

Direct sequencing method for species identification of canned sardine and sardine-type products

A direct sequencing method based on a 103 bp diagnostic sequence derived from a species-specific mitochondrial DNA cytochrome b sequence of 150 bp obtained by Polymerase Chain Reaction was tested for the identification of 47 commercial canned sardine and sardine-type products from various countries. Multiple alignment of 14 analyzed reference samples belonging to Clupeomorpha species was performed versus the canned samples. Low intraspecific variability was observed for canned sardine (相似文献   

Genetic identification of squids (families Ommastrephidae and Loliginidae) by PCR-RFLP and FINS methodologies

Cephalopods are a taxonomic group that contains a great number of families, genera and species, with many of them very important at the commercial level. The existence of very similar species in this class added up to the transformation process applied to them makes it difficult or even impossible for species identification based on morphological characterization. Moreover, the global commerce makes it possible that one determined species can be marketed in its antipodes. These questions suggest the necessity of molecular techniques to solve this situation. In the present work, a genetic method was developed on the basis of the polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) and forensically informative nucleotide sequencing (FINS) technique and makes possible the identification of more than 20 species belonging to the families Ommastrephidae and Loliginidae, as well as some octopus and sepia species. The PCR was employed to amplify 651 and 208 bp fragments of the mitochondrial cytochrome b gene. These molecular systems were applied to fresh, frozen, precooked, even canned cephalopods, allowing for the identification of the species included in these products. Therefore, these molecular tools could be applied in questions related to correct labeling, traceability, and importation controls of squids, sepias, and octopuses.     

Identification of sole (Solea solea) and Greenland halibut (Reinhardtius hippoglossoides) by PCR amplification of the 5S rDNA gene.

Polymerase chain reaction (PCR) amplification of the nuclear 5S rDNA gene, has been used for the identification of sole (Solea solea) and Greenland halibut (Reinhardtius hippoglossoides). Two species-specific primers were designed to amplify specific fragments of the 5S rDNA gene in each species. The remarkably different size of the amplicons obtained gives, by simple agarose gel electrophoresis, two distinguishable band patterns for both flatfish species. This genetic marker can be very useful for the accurate identification of S. solea and Greenland halibut, to enforce labeling regulations.     

DNA identification of commercial ginseng samples

An investigation was performed with the objective of developing a DNA-based protocol for the identification of commercial samples of the herbal compound ginseng. There are currently two major herbal products referred to as ginseng. They are Korean or Chinese ginseng (Panax ginseng) and American ginseng (Panax quinquefolius). The market for ginseng in the United States is estimated to be approximately $300 million annually. Current tests for ginseng species identification rely on expert botanical identification of fresh plant/root specimens or on biochemical characterization of active and marker compounds (e.g., ginsenosides). For the determination of the feasibility of ginseng identification by DNA analysis, a strategy based on the direct DNA sequence analysis of the nuclear ribosomal internal transcribed spacer region was developed. Other genetic tests included sequence analysis of the chloroplast ribulose 1,5-bisphosphate carboxylase large subunit gene and DNA fingerprinting by the rapid amplification of polymorphic DNA technique. To confirm the results, each ginseng sample was identified using high-performance liquid chromatography. All methods were successful in distinguishing American from Korean ginseng. In addition, the protocol was improved for the isolation of genomic and plastid DNA from commercial ginseng preparations by incorporating an impact homogenization step into the standard column chromatography purification procedure.     

Development of a method for the genetic identification of mussel species belonging to Mytilus, Perna, Aulacomya, and other genera

Legislation regarding the labeling of processed products is an important issue in the protection of consumer rights. This labeling is especially important in products that cannot be identified on the basis of their morphological characters, because these are removed from the animal in the transformation process. The goal of this study was the identification of mussel species using Polymerase Chain Reaction-Restriction Fragment Length Polymorphism (PCR-RFLP) and Forensically Informative Nucleotide Sequencing (FINS) methodologies. The molecular marker selected was 18S rDNA (nuclear small-subunit rDNA gene), which allows identification at the genus level and at the species level in some cases. The genera included in this study were Mytilus, Perna, Aulacomya, Semimytilus, Brachidontes, Choromytilus, and Perumytilus. Different markers were used for genetic identification at the species level. To identify the species included in the genus Perna and Choromytilus, a fragment of ITS 1 (Internal Transcribed Spacer 1) was amplified by multiplex PCR and digested with restrictases. The species of Mytilus were identified by length polymorphism and RFLP of the polyphenolic adhesive protein gene. This methodology was validated with products manufactured in the authors' pilot plant and applied to commercial samples. Therefore, this sequential method can be completely or partially used to determine the mussel genus or species present in any food product.     

Fish species identification in surimi-based products

Whole fish morphologically identified as belonging to Theragra chalcogramma, Merluccius merluccius, Merluccius hubbsi, and Merluccius capensis and 19 fish products commercialized as surimi with different commercial brands and labeled as T. chalcogramma were analyzed by direct sequence analysis of the cytochrome b gene. A phylogenetic analysis of surimi products was performed as well. Results demonstrated that mislabeling is a large-scale phenomenon, since 84.2% of surimi-based fish products sold as T. chalcogramma (16/19) were prepared with species different from the one declared. In fact, only three samples (samples 15-17) were found to belong to T. chalcogramma. In the remaining samples, Merluccidae (samples 4-14), Gadidae (samples 18 and 19), Sparidae (sample 1), and Pomacentridae (samples 2 and 3) families were detected. A phylogenetic tree was constructed, and the bootstrap value was calculated. According to this methodology, 11 samples were grouped in the same clade as Merluccius spp.     

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.     

Identification of flatfish (Pleuronectiforme) species using DNA-based techniques

Identification of flatfish species using a DNA-based methodology was studied. The polymerase chain reaction was employed to obtain a 464 bp amplicon from mitochondrial cytochrome b gene. The sequences from this fragment belonging to 24 species were analyzed using a genetic distance method, and polymorphic sites were determined. The fragment was found to be highly polymorphic (231 sites), and this permitted the differentiation of most of the species. Phylogenetic tree construction was employed to allow the identification of flatfish species. As a result, each species was grouped in a well-differentiated clade, except for two pairs: Limanda ferruginea and L. limanda, and Solea impar and S. lascaris, which could not be differentiated. On the basis of the sequences obtained, restriction enzymes were selected to provide specific restriction profiles, which allow the differentiation of 21 species of flatfish in a faster and less expensive manner than sequencing. This polymerase chain reaction-restriction fragment length polymorphism methodology (PCR-RFLP) was tested using commercial samples.     

DNA barcoding for conservation and management of Amazonian commercial fish

DNA barcoding is used to assign a biological specimen to a species. DNA-based procedure has become the preferred forensic tool for criminal prosecution in cases involving the sale of incorrectly identified food. The aim of this work was to develop a DNA-based marker for allowing an accurate and reliable identification of Amazonian fish species of commercial interest. For this purpose, we extracted DNA from fish directly purchased in local markets and identified de visu by local experts. We PCR amplified the mitochondrial 12S rRNA and cytochrome oxidase I (COI) genes. Twenty-nine commercial species accounting for most commercial landings in the River Amazon markets were unambiguously identified based on their DNA for the first time. Phylogenetic trees reconstructed based on the sequences of the two mitochondrial genes clustered species in concordance with their taxonomic classification. We illustrated the utility of DNA barcoding demonstrating that the group of fish generically sold as “Acará” includes seven different species, which are being exploited together as a single species, thus estimation of exploitation rates was not possible until now. Application of genetic markers for species authentication in markets and control of commercial landings will contribute to recognition of the real fishing targets and to the conservation of fish resources in the Amazon basin.     

Compliance with Gluten‐Free Labelling Regulation in the Brazilian Food Industry

Gluten is an important protein complex for baking products found in wheat, rye, barley, and some oat varieties. However, some people need to avoid these grains and their products because they result in gluten‐related disorders. The only treatment for these individuals is to engage in a gluten‐free diet. The objective of this work was to verify if the gluten content of several commercial food products sold in Brazil complied with their labeling. The Méndez ELISA R5 sandwich method was used to analyze 437 samples, and of these, 70% were labeled as gluten‐free, 26% as containing gluten, and 4% not labeled in relation to gluten. The results indicated that 89% of the products labeled as gluten‐free were correctly labeled and 11% were not, which represented a risk for celiac people.     

High level of mislabeling in Spanish and Greek hake markets suggests the fraudulent introduction of African species

DNA analysis of hake products commercialized in southern European (Spanish and Greek) market chains have demonstrated more than 30% mislabeling, on the basis of species substitution. Tails and fillets were more mislabeled than other products, such as slices and whole pieces. African species were substitute species for products labeled as American and European species, and we suggest it is a case of deliberate economically profitable mislabeling because real market prices of European and American hake products are higher than those of African in Spanish market chains. The presented results suggest fraud detection that disadvantages African producers. Government-mandated genetic surveys of commercial hakes and the use of subsequent statements of fair trade on labels of seafood products could help to reduce fraud levels in a global market of increasingly conscious consumers sensitive to ethical issues.     

A rapid methodology for screening hake species (Merluccius spp.) by single-stranded conformation polymorphism analysis

An accurate screening method for hake species identification based in single-stranded conformation polymorphism analysis is presented. The differentiation of 11 species of the Merluccius genus and another five species of the Gadiformes order was studied. For this purpose, two fragments of the cytochrome b gene were sequenced; the first is the 5'-end, a fragment of 465 bp (Kocher fragment), and the second is the 3'-end of the cytochrome b, a 588 bp fragment (SB fragment). These two fragments were amplified, denatured, and submitted to native nondenaturing polyacrylamide gel electrophoresis. Results show that with this technique and both fragments, all of the species studied can be unequivocally identified. The validation of the methodology was carried out with 24 commercial hake products showing good performance of the technique for species identification in commercial products. Results show that all species were identified. This technique has advantages over other published methods, because only one polymerase chain reaction step is needed, saving time and money, and it decreases the time needed for hake species identification in food products, making it especially suitable as a screening methodology when a high number of samples should be analyzed in routine examinations.     

Chemical and genetic assessment of variability in commercial Radix Astragali (Astragalus spp.) by ion trap LC-MS and nuclear ribosomal DNA barcoding sequence analyses

Radix Astragali (Huangqi) has been demonstrated to have a wide range of immunopotentiating effects and has been used as an adjuvant medicine during cancer therapy. Identity issues in the collection of Radix Astragali exist because many sympatric species of Astragalus occur in the northern regions of China. In order to assess the quality, purity, and uniformity of commercial Radix Astragali, 44 samples were purchased from herbal stores in Hong Kong and New York City. The main constituents, including four isoflavonoids and three saponins, were quantitatively determined by liquid chromatography mass spectrometry (LC-MS). There was significant sample-to-sample variability in the amounts of the saponins and isoflavonoids measured. Furthermore, DNA barcoding utilizing the variable nuclear ITS spacer regions of the 44 purchased Radix Astragali samples were sequenced, aligned and compared. Eight polymorphic point mutations were identified which separated the Radix Astragali samples into three groups. These results indicate that the chemical and genetic variability that exists among Radix Astragali medicinal products is still a consistency and quality issue for this herbal. Two-way ANOVA analysis showed significant effects on the contents of the seven tested compounds when both phylogenetic and geographic (i.e., point of purchase) factors were considered. Therefore, chemical profiles determined by LC-MS and DNA profiles in ITS spacer domains could serve as barcode markers for quality control of Radix Astragali.     

Applying DNA techniques to the identification of the species of dressed toasted eel products

To differentiate the species of processed eel products, the gene identification of four fresh eel species was first established and the species of eel products collected from markets were investigated. Polymerase Chain Reaction (PCR) and sequence analysis were used to determine the genetic variation in a 362-nucleotide region of the mitochondrial cytochrome b gene in four fresh eels including Anguilla japonica, Anguilla anguilla, Anguilla rostrata, and Muraenesox cinereus. It was found that each eel species had a unique genotype, which was no different among fresh, frozen, and sterilized meats. The restriction enzyme HinfI could differentiate the species of A. japonica and A. rostrata but could not differentiate A. anguilla and M. cinereus. Another restriction enzyme, Sau96 I, was valuable in the differentiation of M. cinereus from the other three species of Anguilla. By applying PCR and restriction enzymes, the species of 12 commercial eel products were identified as A. japonica (9 samples), A. anguilla (2), and A. rostrata (1). This indicated that the sequence and restriction enzyme cutting site analyses were very usable to authenticate species of different processed eel products.     

Identification of Hake species (Merluccius Genus) using sequencing and PCR-RFLP analysis of mitochondrial DNA control region sequences.

The use of DNA-based methodologies in identification of hake species belonging to the Merluccius genus was shown to be successful. A short fragment of the left hypervariable domain of the mitochondrial control region was amplified, sequenced, and digested from 11 hake species. The hake-specific PCR product, due to its limited size, was obtained in a variety of tissue samples with different levels of DNA concentration and degradation, including sterilized food products. On the basis of this phylogenetically informative 156-bp sequence were selected four restriction enzymes (ApoI, DdeI, DraIII, and MboII) that allow the hake species discrimination. Species identification by phylogenetic analysis of sequences or by PCR-RFLP methodologies is useful in a variety of scenarios including authentication of thermally processed food, detection of food components, and species determination of individuals whose morphological characters are removed.     

Identification of Chinese alligators (Alligator sinensis) meat by diagnostic PCR of the mitochondrial cytochrome b gene

With the commercial farming and exploitation of Chinese alligators (Alligator sinensis), illegal and inappropriately labeled Chinese alligator meat has appeared in markets. To prevent the illegal hunting and commerce for Chinese alligators, it will be important to develop an expedient and practical method for the identification of Chinese alligator meat. In this study, a pair of the species-specific PCR primers (Alli-M and Alli-R) was designed using sequence variations of mitochondrial DNA (mtDNA) cytochrome b gene between Chinese alligators and other crocodilians. By the multiplex PCR of using the species-specific primers and 12S rRNA universal primers L1091 and H1478, 31 samples (27 meat samples, 4 skin samples) were identified. The result of amplification displayed that only the fresh and the cooked meat samples from the Chinese alligator could be amplified with two bands. We also present a case of identification of a crocodilian body part found in a local market using the newly developed primers. The specific primers designed in this study could be widely used for the rapid and accurate identification of not only alligator meat but also other commercial products from Chinese alligator.     

Fish species identification using PCR-RFLP analysis and lab-on-a-chip capillary electrophoresis: application to detect white fish species in food products and an interlaboratory study

Identification of 10 white fish species associated with U.K. food products was achieved using PCR-RFLP of the mitochondrial cytochrome b gene. Use of lab-on-a-chip capillary electrophoresis for end-point analysis enabled accurate sizing of DNA fragments and identification of fish species at a level of 5% (w/w) in a fish admixture. One restriction enzyme, DdeI, allowed discrimination of eight species. When combined with NlaIII and HaeIII, specific profiles for all 10 species were generated. The method was applied to a range of products and subjected to an interlaboratory study carried out by five U.K. food control laboratories. One hundred percent correct identification of single species samples and six of nine admixture samples was achieved by all laboratories. The results indicated that fish species identification could be carried out using a database of PCR-RFLP profiles without the need for reference materials.