Application of the ITS2 region for barcoding plants of the genus Triticum L. and Aegilops L.

Molecular taxonomic studies have been performed in the past in order to identify different wheat species and construct a molecular phylogeny. These were based on universal but sufficiently divergent sequences from both the nuclear and chloroplastic genomes of wheat. They included two short plastid sequences from the plastid genes rbcL and matK which have been proposed as the core “barcode” sequences by the “barcoding” guidelines for general plant identification. Historically, in molecular plant taxonomy, plastidic sequences had been favored over nuclear sequences, due to their uniparental inheritance and consequently lower intra-molecular recombination. However recently, the short nuclear sequence from the internal transcribed spacer 2 (ITS2) has been used successfully for the accurate identification of many medicinal and other plant species. Herein, we have used the plastidic matK, rbcL trnL, and the nuclear ITS2 region for the identification of different wheat species of Triticum L. and goatgrass species of Aegilops L. We have successfully discriminated all species that were examined from both genera, thus, validating the ITS2 region as a ‘barcode tool’ for accurate distinction of plants in the genus Triticum L. and Aegilops L. The success rate of PCR amplification and sequencing of the ITS2 region was 100%. We report also that matK, rbcL and trnL regions could not discriminate all species in contrast to the ITS2 region which demonstrated full discriminatory capacity

DNA-based species identification of Greek macromycetes

Fungi comprise one of the largest and diverse groups of eukaryotes. Macromycetes, which are commonly known as mushrooms, include species in Basidiomycota and Ascomycota. Macromycetes are essential for ecosystem functioning and have high commercial value owing to their nutritional and medicinal properties. Despite the importance of macrofungi for the ecosystem and human welfare, macromycete diversity and phylogeny are poorly characterized, owing to the lack of molecular-based biodiversity descriptors supporting phenotypic classifications, especially for biodiversity rich countries such as Greece. In this study, we implemented a multi-marker DNA barcoding approach, utilizing the Internal Transcribed Spacer 1 (ITS1) and part of the 28S nuclear ribosomal Large Subunit (nrLSU) rDNA regions, for the molecular identification of representative Greek macromycetes. Our analysis involved 103 Greek macromycetes covering seven genera of Basidiomycota (Agaricus, Amanita, Boletus, Cantharellus, Lactarius, Pleurotus, and Russula) and one genus of Ascomycota (Morchella). Phylogenetic inference based on the generated rDNA sequences, revealed high DNA divergence among most of the examined macromycete genera, which formed discrete monophyletic groups. Our phylogenetic analysis, in accordance with previous studies in the field, further supports the early divergence of the Cantharellus clade, followed by the subsequent split of the Russulaceae from a sister clade formed by the Agaricus, Amanita, Boletus and Pleurotus genera. © 2021. Current Research in Environmental and Applied Mycology. All Rights Reserved

Multiple resistance of silky windgrass to acetolactate synthase-and acetyl-CoA synthase-inhibiting herbicides

Field and pot experiments were conducted in Greece to study the occurrence of resistance in silky windgrass to acetolactate synthase (ALS)-and acetyl-CoA synthase (ACCase)-inhibiting herbicides. Twenty-four populations of silky windgrass were examined in whole-plant response experiments. High levels of field-evolved resistance to chlorsulfuron (0% to 28% control in terms of fresh weight reduction) with the recommended field rates were confirmed in most silky windgrass populations. However, other ALS inhibitors, such as pyroxsulam and a premix of mesosulfuron-methyl and iodosulfuron, provided adequate control (76% to 100% in terms of fresh weight reduction) of most populations, except eight silky windgrass populations that were found to be cross-resistant to all ALS-inhibiting herbicides tested (i.e., chlorsulfuron, commercial mixture of mesosulfuron-methyl plus iodosulfuron, and pyroxsulam). Conversely, most silky windgrass populations were controlled effectively (90% to 100% in terms of fresh weight reduction) with the recommended field rates of ACCase inhibitors cycloxydim, clethodim, and pinoxaden, but five populations were also found to be resistant to clodinafop-propargyl (10% to 68% control in terms of fresh weight reduction). The ALS gene sequencing of the eight silky windgrass populations, with cross-resistance to ALS inhibitors, revealed a point mutation at the Pro-197 position, causing amino acid substitution by Ser or Thr in the ALS enzyme. Overall, chlorsulfuron and clodinafop-propargyl were selecting agents of field-evolved multiple resistance to ALS-and ACCase-inhibiting herbicides in five silky windgrass populations. As the available postemergence-applied chemistries/modes of action registered for grass weed control in cereals are rather limited, adopting integrated management practices and implementing proactive and reactive measures to delay the evolution of resistant populations is essential.

HRM and 16S rRNA gene sequencing reveal the cultivable microbiota of the European sea bass during ice storage

The total cultivable microbiota of the ice-stored European sea bass (Dicentrarchus labrax), the most important commercial fish species of the Mediterranean aquaculture, was determined using 16S rRNA gene sequence analysis. High Resolution Melting (HRM) curve profiles and sequencing analysis (V3–V4 region of the 16S rRNA gene) were used respectively for the differentiation and identification of the collected isolates from six time intervals (day 0, 4, 8, 12, 14 and 16) while fish were stored in ice. HRM analysis differentiated the unknown microbiota in ten groups (208 isolates) and in two single isolates based on their HRM curve profiles. The isolates with HRM profiles which were >91% similar within each group were found to belong to the same species using sequencing analysis. Thus, the ten groups consist of representatives of Psychrobacter glacincola, Ps. alimentarius, Ps. cryohalolentis, Ps. maritimus, Ps. fozii, Pseudomonas sp., Paeniglutamicibacter sp., Carnobacterium sp., Leucobacter aridicolis and Bacillus thuringiensis. Based on this approach, Ps. cryohalolentis was found to be the most dominant phylotype at the beginning of fish shelf-life compared to other species. The abundance of this bacterium decreased throughout storage, while Ps. glacincola increased and dominated at the time of the sensory minimum acceptability (day 14) and rejection (day 16). To conclude, HRM could be used for the rapid determination of sea bass microbiota, using the representatives of each group as reference bacterial strains, in order for scientists to solve rapidly stakeholders problems related with microbial quality or safety of fish. © 2020 Elsevier B.V

DNA-Based Identification of Eurasian Vicia Species Using Chloroplast and Nuclear DNA Barcodes

Many legume species of the Vicia L. genus (Fabaceae Lindl.) are key components of the Mediterranean diet and have an integral role in sustainable agriculture. Given the importance of the Vicia species for Eurasian culture, it is necessary to implement methodologies, such as DNA barcoding, that can enable the effective authentication and identification of species in the genus. In this study, we analysed the chloroplast trnL and rpoC1, as well as the nuclear ITS2 DNA barcoding regions, to identify 71 Vicia specimens of Eurasian descent. Both the trnL and ITS2 regions were highly effective in discriminating the analysed taxa, while the more conserved rpoC1 region could not identify all of the selected species due to high sequence conservation or non-annotated or absent rpoC1 species sequences in GenBank. A dendrographic representation of the generated trnL data showed sufficient clustering for most of the analysed taxa, although some topological discrepancies were observed. ITS2 and rpoC1 reconstructions were also used for resolving the topological discrepancies observed in the trnL tree. Our analysis suggests that a combination of DNA barcoding regions is essential for accurate species discrimination within the Vicia genus, while single-locus analyses do not provide the necessary resolution. © 2022 by the authors. Licensee MDPI, Basel, Switzerland

Characterization of the genetic diversity present in a diverse sesame landrace collection based on phenotypic traits and est-ssr markers coupled with an hrm analysis

A selection of sesame (Sesamum indicum L.) landraces of different eco-geographical origin and breeding history have been characterized using 28 qualitative morpho-physiological descriptors and seven expressed sequence tag-simple sequence repeat (EST-SSR) markers coupled with a high-resolution melting (HRM) analysis. The most variable qualitative traits that could efficiently discriminate landraces, as revealed by the correlation analyses, were the plant growth type and position of the branches, leaf blade width, stem pubescence, flowering initiation, capsule traits and seed coat texture. The agglomerative hierarchical clustering analysis based on a dissimilarity matrix highlighted three main groups among the sesame landraces. An EST-SSR marker analysis revealed an average polymorphism information content (PIC) value of 0.82, which indicated that the selected markers were highly polymorphic. A principal coordinate analysis and dendrogram reconstruction based on the molecular data classified the sesame genotypes into four major clades. Both the morpho-physiological and molecular analyses showed that landraces from the same geographical origin were not always grouped in the same cluster, forming heterotic groups; however, clustering patterns were observed for the Greek landraces. The selective breeding of such traits could be employed to unlock the bottleneck of local phenotypic diversity and create new cultivars with desirable traits. © 2021 by the authors. Licensee MDPI, Basel, Switzerland

Bar-HRM for Authentication of Plant-Based Medicines : Evaluation of Three Medicinal Products Derived from Acanthaceae Species

Medicinal plants are used as a popular alternative to synthetic drugs, both in developed and developing countries. The economic importance of the herbal and natural supplement industry is increasing every year. As the herbal industry grows, consumer safety is one issue that cannot be overlooked. Herbal products in Thai local markets are commonly sold without packaging or labels. Plant powders are stored in large bags or boxes, and therefore buying local herbal products poses a high risk of acquiring counterfeited, substituted and/or adulterated products. Due to these issues, a reliable method to authenticate products is needed. Here DNA barcoding was used in combination with High Resolution Melting analysis (Bar-HRM) to authenticate three medicinal Acanthaceae species (Acanthus ebracteatus, Andrographis paniculata and Rhinacanthus nasutus) commonly used in Thailand. The rbcL barcode was selected for use in primers design for HRM analysis to produce standard melting profiles of the selected species. Melting data from the HRM assay using the designed rbcL primers showed that the three chosen species could be distinguished from each other. HRM curves of all fifteen test samples indicated that three of tested products did not contain the indicated species. Two closely related species (A. paniculata and R. nasutus), which have a high level of morphological similarity, were interchanged with one another in three tested products. Incorrect information on packaging and labels of the tested herbal products was the cause of the results shown here. Morphological similarity among the species of interest also hindered the collection process. The Bar-HRM method developed here proved useful in aiding in the identification and authentication of herbal species in processed samples. In the future, species authentication through Bar-HRM could be used to promote consumer trust, as well as raising the quality of herbal products