ITS1-rDNA-based methodology to identify world-wide hake species of the Genus Merluccius

Species-specific DNA-based tags are valuable tools for the management of both fisheries and commercial fish products. In this study, we have developed a two-step molecular tool to detect the presence of hake DNA (Merluccius spp.) and to identify the exact hake species present in an blind sample. The first test involves PCR amplification of an ITS1-rDNA fragment of 193 bp using nested primers that are interspecifically conserved in Merluccius spp. and Atlantic cod, Gadus morhua. The second test consists of the PCR amplification of a 602-659 bp DNA fragment spanning part of the ribosomal cluster 18S-ITS1-5.8S and digesting it with four restriction enzymes whose targets map at interspecifically nonconserved sites of the ITS1. Alternatively, the identification of hake species can be achieved by FINS or BLAST, using the nucleotide sequence of either the whole ITS1 sequence or its nested fragment of 193 bp. Because of their high reproducibility and ease of execution, these procedures allow for routine analysis and constitute high reliable tools for the rapid identification of 12 species of hake.     

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.     

Identification of gadoid species in fish meat by polymerase chain reaction (PCR) on genomic DNA

Identification of fish species is significant due to the increasing interest of consumers in the meat of sea fish. Methods focusing on fish species identification help to reveal fraudulent substitution among economically important gadoid species in commercial seafood products. The objective of this work was to develop a conventional PCR method for the differentiation of the following gadoid fish species in fish products: Alaska pollack ( Theragra chalcogramma), blue whiting ( Micromesistius poutassou), hake spp. ( Merluccius spp.), Atlantic cod ( Gadus morhua), saithe ( Pollachius virens), and whiting ( Merlangius merlangus). The species-specific primer pairs for gadoid species determination were based on the partial pantophysin I ( PanI) genomic sequence. Sequence identification was confirmed by cloning and sequencing of the PCR products obtained from the species considered. For the simultaneous detection of Alaska pollack, blue whiting, and hake spp., a quadruplex PCR system was constructed. Other gadoid species were detected in separate PCR reactions. After optimization of the reactions, the developed PCR systems were used for the analysis of codfish samples obtained from the Czech market and the customs' laboratories. This method represents an alternative approach in the use of genomic DNA for the identification of fish species. This method is rapid, simple, and reliable without the need for further confirmative methods. Furthermore, the identification of a mixture of more than one species is possible. The PCR system has been optimized for routine diagnostic purposes.     

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 anchovy (Engraulis encrasicholus L.) and gilt sardine (Sardinella aurita) by polymerase chain reaction, sequence of their mitochondrial cytochrome b gene, and restriction analysis of polymerase chain reaction products in semipreserves

A method of authenticating anchovy (Engraulis encrasicholus L.) and gilt sardine (Sardinella aurita) semipreserves (salt-cured and fillets in oil) has been developed by polymerase chain reaction (PCR) followed by sequence and restriction site analysis. The amplification of a fragment of the cytochrome b gene by universal primers produced a 376 base pairs (bp) fragment in all samples analyzed. Digestion of PCR products with XhoI, TaqI, AluI, and HinfI endonucleases yielded species-specific profiles distinguishing anchovy from gilt sardine. Therefore, the restriction length fragment polymorphism (RLFP) technique can be used to determine the species identity of anchovy and gilt sardine in semipreserves.     

Detection of mislabeling in hake seafood employing mtSNPs-based methodology with identification of eleven hake species of the genus Merluccius

Species-specific DNA-based tags are valuable tools for the management of both fisheries and commercial fish products. Eleven hake species of the genus Merluccius have been identified employing mtSNPs-based methodology. The method is highly reproducible, fast, and technically easy. It is a reliable tool, allowing for routine analysis of commercial seafood. It can be applied by nonexperts in genetics because both laboratory handling and interpretation of results are easy and direct. The convenience of routine surveys in fish markets has been clearly established with a survey of commercial hake batches imported in south Europe. A total of 40 commercial processed hake were analyzed in this study. More than 20% of mislabeling has been detected.     

Polymerase Chain Reaction assay for the detection of Kudoa paniformis and Kudoa thyrsites in Pacific Hake (Merluccius productus)

Myoliquefaction of Pacific hake has been attributed to proteolytic action associated with parasitic infection. Among the two infecting species of Kudoa, Kudoa paniformis and Kudoa thyrsites, the former is reported to be more virulent for the "soft flesh" phenomenon in Pacific hake. The objective of this research was to develop a sensitive and specific polymerase chain reaction (PCR) assay to detect infection of hake by K. paniformis. Primers based on specific regions ( approximately 1562 bp) of the small subunit ribosomal DNA of K. paniformis successfully amplified the target DNA segments from both spore and muscle extracted DNA templates. DNA sequencing confirmed the veracity of this method to distinguish parasitic infection by K. paniformis versus K. thyrsites. The established PCR method was applied to investigate Kudoa infection in 44 Pacific hake samples using DNA extracted from muscle and/or spores, and the results were compared to infection evaluated by microscopic examination of extracted spores.     

Chemical and sensory changes in Mediterranean hake (Merluccius merluccius) under refrigeration (6-8 degrees C) and stored in ice

Fresh Mediterranean hake (Merluccius merluccius var. mediterraneus), a species mainly caught off the shores of Spain, was stored at usual temperatures: in ice (commercial chain) and under refrigeration (home). Sensory and chemical analyses were performed throughout the storage time to determine the changes that took place and evaluate the effect of the storage temperature. Storage in ice resulted in a slight accumulation of volatile and biogenic amines in hake. When it was stored at 6-8 degrees C, a significant production of both trimethylamine and total volatile basic nitrogen (TVB-N) was observed, and biogenic amines were formed. Sensory analysis revealed that hake stored in ice was inedible after 29 days, the figure for refrigerated hake being 20 days. There was a nonsignificant correlation (p > 0.05) between TVB-N values and sensory score in hake stored at 0 degrees C. In all other cases, a significant correlation (p < 0.001) between volatile parameters and sensory analysis was found.     

Molecular phylogeny and species identification of sardines

The DNA sequence diversity of Sardina pilchardus (Walbaum, 1792) and some closely related species of Clupeomorpha was investigated using the mitochondrial DNA gene encoding cytochrome b. The nucleotide sequences of complete and partial mtDNA cytochrome b were determined in numerous specimens. Sequence divergence between species and genera was evenly distributed in the cytochrome b gene but rather high compared to reports for other fish species. Phylogenetic analyses on complete cytochrome b were used to study the relationships among the considered species. S. pilchardus was easily differentiated, showing a genetic distance of 0.25 with respect to Clupeidae species and 0.26 with respect to the other species. A species-specific short fragment (<150 bp) was isolated by polymerase chain reaction (PCR) using primers designed for Clupeomorpha. A rapid and reliable PCR method using restriction fragment length polymorphism (RFLP) with two restriction enzymes (MnlI/HinfI) was optimized for unambiguous differentiation of S. pilchardus from the other species tested (raw and canned products).     

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.     

小麦AB基因组中一个重复序列的分离、定位与应用

利用102对微卫星引物对5份黑麦（Secale）、4份普通小麦（Triticum aestivum）和1份分枝小黑麦（Triticale）进行SSR分析,引物Xgwm614能在分枝小黑麦中扩增出一个387bp的特异DNA片段（记为FZ387,GenBank登录号为EF179137）,而黑麦未能扩增出。序列比对结果显示该片段与一粒小麦（T. monococcum）（AY485644）和栽培二粒小麦（T. turgidum）（AY494981）A基因组中Gypsy Ty3-LTR反转座子fatima的一部分分别有94%和95%同源性。根据序列同源性比对结果,在FZ387内部设计1对特异引物FaF和FaR。引物Xgwm614F和FaR能在含有A基因组的物种中扩增出约350bp的条带（记为A350）,而其不含A基因组的物种都未扩增出该条带。利用小麦二体和端体代换系材料对其进行定位,结果显示该片段分布在所有A染色体的长臂和断臂上。此外,引物FaF和Xgwm614R能在含有A、B或AB基因组的物种中扩增出约350bp的条带（记为AB350）,而不含AB基因组的材料未扩增出目标条带。利用这两对特异引物对小麦属近缘物种进行PCR扩增,发现只有中国春能够扩增出A350和AB350。序列比对结果和FZ387两侧SSR引物结合区的规律性变化表明该反转座子在进化上可能存在属间多样性和属内相似性。A350和AB350也可以分别作为分子标记检测A染色体和AB染色体。     

One-step triplex-polymerase chain reaction assay for the authentication of yellowfin (Thunnus albacares), bigeye (Thunnus obesus), and skipjack (Katsuwonus pelamis) tuna DNA from fresh, frozen, and canned tuna samples

A one-step triplex-polymerase chain reaction (PCR)-based assay was developed to discriminate between three tuna species, Thunnus albacares, Thunnus obesus, and Katsuwonus pelamis, even in highly processed food samples such as canned or cooked tuna. Diagnostic nucleotides were identified by direct sequencing and alignment of part of the mitochondrial cytochrome b gene of 30 authenticated exemplars, which allowed us to evaluate intraspecific variation and the genetic distance between three tuna species. The assay relies on a one-step triplex-PCR reaction in which in a single tube species-specific amplification products are generated only in the presence of the correct template nucleic acid and the species of origin of the DNA is indicated by the distinctive size of the PCR product. The identification of tuna species can be performed with a good accuracy, low cost, and with potential automation for large-scale high-throughput screenings in small in-house laboratories.     

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.     

Reliable detection and identification of genetically modified maize, soybean, and canola by multiplex PCR analysis

Multiplex PCR procedures were developed for simultaneously detecting multiple target sequences in genetically modified (GM) soybean (Roundup Ready), maize (event 176, Bt11, Mon810, T14/25), and canola (GT73, HCN92/28, MS8/RF3, Oxy 235). Internal control targets (invertase gene in corn, lectin and beta-actin genes in soybean, and cruciferin gene in canola) were included as appropriate to assess the efficiency of all reactions, thereby eliminating any false negatives. Primer combinations that allowed the identification of specific lines were used. In one system of identification, simultaneous amplification profiling (SAP), rather than target specific detection, was used for the identification of four GM maize lines. SAP is simple and has the potential to identify both approved and nonapproved GM lines. The template concentration was identified as a critical factor affecting efficient multiplex PCRs. In canola, 75 ng of DNA template was more effective than 50 ng of DNA for the simultaneous amplification of all targets in a reaction volume of 25 microL. Reliable identification of GM canola was achieved at a DNA concentration of 3 ng/microL, and at 0.1% for GM soybean, indicating high levels of sensitivity. Nonspecific amplification was utilized in this study as a tool for specific and reliable identification of one line of GM maize. The primer cry1A 4-3' (antisense primer) recognizes two sites on the DNA template extracted from GM transgenic maize containing event 176 (European corn borer resistant), resulting in the amplification of products of 152 bp (expected) and 485 bp (unexpected). The latter fragment was sequenced and confirmed to be Cry1A specific. The systems described herein represent simple, accurate, and sensitive GMO detection methods in which only one reaction is necessary to detect multiple GM target sequences that can be reliably used for the identification of specific lines of GMOs.     

PCR-RFLP authentication of meats from red deer (Cervus elaphus), fallow deer (Dama dama), roe deer (Capreolus capreolus), cattle (Bos taurus), sheep (Ovis aries), and goat (Capra hircus)

PCR-RFLP analysis has been applied to the identification of meats from red deer (Cervus elaphus), fallow deer (Dama dama), roe deer (Capreolus capreolus), cattle (Bos taurus), sheep (Ovis aries), and goat (Capra hircus). PCR amplification was carried out using a set of primers flanking a conserved region of approximately 712 base pairs from the mitochondrial 12S rRNA gene. Restriction site analysis based on sequence data from this DNA fragment permitted the selection of MseI, MboII, BslI, and ApoI endonucleases for species identification. The restriction profiles obtained when amplicons were digested with the chosen enzymes allowed the unequivocal identification of all domestic and game meat species analyzed in the present work.     

PCR-RFLP analysis of mitochondrial DNA: a reliable method for species identification

A method for identification of game species has been developed on the basis of the amplification of a specific part of the mitochondrial genome (tRNA(Glu)/cytochrome b) using the polymerase chain reaction (PCR). To distinguish between several game species, the obtained 464-bp-long PCR products were cut with different restriction endonucleases (RE) resulting in species-specific restriction fragment length polymorphism (RFLP). Even closely related deer species could be distinguished by application of one or two RE. Natural polymorphisms of the target sequence within one species were examined for red deer (Cervus elaphus), and base pair substitutions were identified affecting the RFLP pattern.     

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.     

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.     

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.     

Identifying unique populations in long-dispersal marine species: Gulfs as priority conservation areas

Identification of areas which should be a subject of protection is crucial for safeguarding the marine ecosystems. Amongst the reasons for protecting a region or location, the existence of unique populations or evolutionary significant units for one or more key species is a priority. The North American silver hake, Merluccius bilinearis, is currently managed as two stocks (northern and southern) without considering gulf areas separately. Employing microsatellite and mitochondrial markers we have detected significant F_ST values between hake individuals inhabiting gulfs and those distributed in the open sea, and asymmetric gene flow, higher from the gulf to the open sea than in the opposite direction. These differences can be interpreted as signals of separate populations in gulfs which may act as sources of variability for hake species. Occurrence of similar phenomena in Atlantic waters in both the northern and the southern Hemisphere, for these two pelagic–demersal hake species, suggests that gulfs may constitute a target for designing marine protected areas and confirms the adequacy of gulf-specific management already employed in Argentina.