Evaluation of 19 short tandem repeat markers for individualization of Papaver somniferum

Evaluation of chloroplast DNA barcoding markers to individualize Papaver somniferum for forensic intelligence purposes

The opium poppy, Papaver somniferum L., is a forensically important plant due to the medicinal and illegal uses for the milky latex stored in the pods. This latex contains the alkaloids morphine, codeine, and thebaine that are used for their analgesic properties and/or for synthesizing other opioids. However, these compounds are highly addictive and have caused a national opioid epidemic. Two other Papaver species, P. setigerum DC. and P. bracteatum Lindl., are also of forensic interest because they pose both forensic and legal issues. They are largely uncontrolled under the Controlled Substances Act, making these species a common defense strategy. Current morphological and chemical identification methods have been moderately successful but have drawbacks. There is also a lack of sequencing data available. Therefore, exploiting the genome using chloroplast DNA barcoding markers could help to accurately identify these species of interest when plant material is taken. This study screened and assessed the genetic variation both between species and within populations of P. somniferum in nine cpDNA barcode regions (ndhF-rpl32, petA-psbJ, rpl32-trnL, rps16-trnQ, trnE-trnT, trnH-psbA, trnL-trnF, rpl16 intron, and psbE-petL). Published reference genomes from the NCBI GenBank database were aligned and compared for an initial in silico screening. Additionally, ten P. somniferum seed samples from various vendors were sequenced and compared across samples and to published reference data at the various barcode regions of interest. This study showed that the regions trnH-psbA and petA-psbJ have promise for utility in individualization for both inter- and intra-species individualization of P. somniferum.

New Set of EST-STR Markers for Discrimination of Related Papaver somniferum L. Varieties

Papaver somniferum L. is cultivated for its edible seeds and for the production of alkaloids. A serious problem in seed trade and processing is the intentional mixing of excellent food-quality seeds with non-food-grade-quality seeds. Tracking the correct or illegitimate handling of seeds requires an efficient method for discrimination and individualization of poppy varieties. As in human and animal forensics, DNA variable regions containing short tandem repeats (STRs) located either in non-coding DNA or in gene sequences (EST-STRs) are preferred markers for discrimination between genotypes. Primers designed for 10 poppy EST-STR loci not analyzed so far were tested for their discriminatory ability on a set of 23 related P. somniferum L. genotypes. Thirty-three EST-STR alleles were identified together. Their polymorphic information content (PIC) values were in the range of 0.175-0.649. The PI value varied in the range of 0.140-0.669, and the cumulative PI was 1.2 × 10-5. PIsibs values varied between 0.436 and 0.820 and the cumulative value was lower (5.0 × 10-3). All analyzed genotypes were distinguished mutually, each with its own unique EST-STR profile. These newly developed EST-STR markers more effectively discriminated P. somniferum L. genotypes, even those genotypes whose DNA profiles were previously identical.

OpiumPlex is a novel microsatellite system for profiling opium poppy (Papaver somniferum L.)

Opium poppy (Papaver somniferum L.) is a versatile plant exploited by the pharmaceutical and food industries. Unfortunately, it is also infamously known as a source of highly addictive narcotics, primarily heroin. Drug abuse has devastating consequences for users and also has many direct or indirect negative impacts on human society as a whole. Therefore, developing a molecular genetic tool for the individualization of opium poppy, raw opium or heroin samples could help in the fight against the drug trade by retrieving more information about the source of narcotics and linking isolated criminal cases. Bioinformatic analysis provided insight into the distribution, density and other characteristics of roughly 150 thousand microsatellite loci within the poppy genome and indicated underrepresentation of microsatellites with the desired attributes. Despite this fact, 27 polymorphic STR markers, divided into three multiplexed assays, were developed in this work. Internal validation confirmed species-specific amplification, showed that the optimal amount of DNA is within the range of 0.625-1.25 ng per reaction, and indicate relatively well balanced assays according to the metrics used. Moreover, the stutter ratio (mean + 3 SD 2.28-15.59%) and allele-specific stutters were described. The analysis of 187 individual samples led to the identification of 158 alleles in total, with a mean of 5.85 alleles and a range of 3-14 alleles per locus. Most of the alleles (151) were sequenced by the Sanger method, which enabled us to propose standardized nomenclature and create three allelic ladders. The OpiumPlex system discriminates most of the varieties from each other and pharmaceutical varieties from the others (culinary, dual and ornamental).

Procedures for DNA Extraction from Opium Poppy (Papaver somniferum L.) and Poppy Seed-Containing Products

Several commonly used extraction procedures and commercial kits were compared for extraction of DNA from opium poppy (Papaver somniferum L.) seeds, ground seeds, pollen grains, poppy seed filling from a bakery product, and poppy oil. The newly developed extraction protocol was much simpler, reduced the cost and time required for DNA extraction from the native and ground seeds, and pollen grains. The quality of extracted DNA by newly developed protocol was better or comparable to the most efficient ones. After being extended by a simple purification step on a silica membrane column, the newly developed protocol was also very effective in extracting of poppy DNA from poppy seed filling. DNA extracted from this poppy matrix was amplifiable by PCR analysis. DNA extracted from cold-pressed poppy oil and suitable for amplifications was obtained only by methods developed previously for olive oil. Extracted poppy DNA from all tested matrices was analysed by PCR using primers flanking a microsatellite locus (156 bp) and two different fragments of the reference tubulin gene (553 bp and 96 bp). The long fragment of the reference gene was amplified in DNA extracted from native seeds, ground seeds, and pollen grains. Poppy DNA extracted from the filling of bakery product was confirmed only by amplification of short fragments (96 bp and 156 bp). DNA extracted from cold-pressed poppy oil was determined also only by amplification of these two short fragments.