News

Given the diversity of traded bivalve molluscs (scallops, oysters, mussels etc), broad taxonomic coverage is essential for untargeted screening to verify species authenticity. 

To address this challenge, the authors of this paper (open access) developed and validated a DNA metabarcoding approach employing two PCR assays, a singleplex and a duplex, to amplify mitochondrial 16S rDNA fragments (160–203 bp) across seven families: Ostreidae, Pectinidae, Mytilidae, Pharidae, Veneridae, Glycymerididae, and Cardiidae.

Taxa were identified at the species or genus level in 38 reference samples and four model food samples, with individual species detected at concentrations as low as 0.008–0.014% (w/w).

They report that all main and most minor components were detected in 40 DNA extract mixtures, with a small number of false negatives which they hypothesise result from primer-template mismatches causing amplification bias.

In a follow-up surveillance exercise they tested 70 commercial food products. They concluded that 29% of samples were mislabeled (either adulteration or substitution), with scallops being the most frequently affected family.

They conclude that the method is suitable for detecting species substitution and adulteration. This study presents the first DNA metabarcoding method targeting a broad taxonomic range of bivalves. The validated approach is particularly-suited for qualitative screening in routine food authentication and can support laboratories and regulatory agencies in enforcing international monitoring strategies.

Thanks to FAN member, and author, Julia Andronache for flagging this paper.  If you have a publication that it would be useful to share with our members then please get in touch.

This study (purchase required) reports the development of a novel recombinase aided amplification (RAA) assisted Cas12a assay to authenticate the commercially important Pacific oyster.

The COI gene was selected as a genetic marker for primer design. The authors report that the developed species-specific RAA assay was optimal at 40 °C for 25 min. The Cas12a assay successfully detected the target Pacific oyster DNA sequence in RAA products using 0.05 μM gRNA and 0.05 μM Cas12a enzyme within 40 min at 37 °C. The developed RAA primers and gRNA for CRISPR-Cas12a assay showed no cross-amplification and high specificity for C. gigas compared with C. belcheri and C. iridalei. The sensitivity test showed the ability of the assay to detect DNA concentrations as low as 10 fg/reaction. In addition, the developed assay successfully authenticated oyster samples in all processed forms, including boiled, steamed, fried, and canned samples.

A small follow-up survey found that 1 of the 15 commercial samples tested was mislabeled.

The authors conclude that the developed assay was a valuable technique with high potential for food safety authorities and stakeholders in ensuring authenticity, in which substitution and adulteration of seafood products can be detected.