High-throughput sequencing of African chikanda cake highlights conservation challenges in orchids

Veldman, Sarina; Gravendeel, Barbara; Otieno, Joseph; Lammers, Youri; Duijm, Elza; Nieman, Aline M.; Bytebier, Benny; Ngugi, Grace; Martos, Florent; Andel, Tinde van; Boer, Hugo de

doi:10.1007/s10531-017-1343-7

Cited by 20 publications

(24 citation statements)

References 37 publications

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“…Our DNA metabarcoding results corroborate previous research that used metabarcoding to authenticate herbal products (Coghlan et al, 2012, 2015; Cheng et al, 2014; Ivanova et al, 2016; Veldman et al, 2017). In this study we confirm its applicability to test for presence of V. officinalis and simultaneously to detect substitution, adulteration and/or admixture of other Veronica species.…”

Section: Resultssupporting

confidence: 88%

Veronica officinalis Product Authentication Using DNA Metabarcoding and HPLC-MS Reveals Widespread Adulteration with Veronica chamaedrys

et al. 2017

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Studying herbal products derived from local and traditional knowledge and their value chains is one of the main challenges in ethnopharmacology. The majority of these products have a long history of use, but non-harmonized trade and differences in regulatory policies between countries impact their value chains and lead to concerns over product efficacy, safety and quality. Veronica officinalis L. (common speedwell), a member of Plantaginaceae family, has a long history of use in European traditional medicine, mainly in central eastern Europe and the Balkans. However, no specified control tests are available either to establish the quality of derived herbal products or for the discrimination of its most common substitute, V. chamaedrys L. (germander speedwell). In this study, we use DNA metabarcoding and high performance liquid chromatography coupled with mass spectrometry (HPLC-MS) to authenticate sixteen V. officinalis herbal products and compare the potential of the two approaches to detect substitution, adulteration and the use of unreported constituents. HPLC-MS showed high resolution in detecting phytochemical target compounds, but did not enable detection of specific plant species in the products. DNA metabarcoding detected V. officinalis in only 15% of the products, whereas it detected V. chamaedrys in 62% of the products. The results confirm that DNA metabarcoding can be used to test for the presence of Veronica species, and detect substitution and/or admixture of other Veronica species, as well as simultaneously detect all other species present. Our results confirm that none of the herbal products contained exactly the species listed on the label, and all included substitutes, contaminants or fillers. This study highlights the need for authentication of raw herbals along the value chain of these products. An integrative methodology can assess both the quality of herbal products in terms of target compound concentrations and species composition, as well as admixture and substitution with other chemical compounds and plants.

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Section: Resultssupporting

confidence: 88%

Veronica officinalis Product Authentication Using DNA Metabarcoding and HPLC-MS Reveals Widespread Adulteration with Veronica chamaedrys

et al. 2017

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“…In DNA barcoding and plant product identification and authentication projects it is common to work with degraded DNA substrates for which it might be difficult to use methylation enrichment or the full plastid genome as a barcoding strategy. However, alternatives such as target enrichment and amplicon sequencing are possible [64, 123–125]. Here we have identified four variable regions that possess sufficient variation and genetic structure to discriminate most ginseng species.…”

Section: Discussionmentioning

confidence: 98%

Phylogenomics and barcoding ofPanax: toward the identification of ginseng species

Manzanilla

Kool

Nhat

et al. 2018

Preprint

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11Background 12The economic value of ginseng in the global medicinal plant trade is estimated to be in excess 13 of US$2.1 billion. At the same time, the evolutionary placement of ginseng (Panax ginseng) 14 and the complex evolutionary history of the genus is poorly understood despite several 15 molecular phylogenetic studies. In this study, we use a full plastome phylogenomic 16 framework to resolve relationships in Panax and to identify molecular markers for species 17 discrimination. 18 Results 19We used high-throughput sequencing of MBD2-Fc fractionated Panax DNA to supplement 20 publicly available plastid genomes to create a phylogeny based on fully assembled and 21 annotated plastid genomes from 60 accessions of 8 species. The plastome phylogeny based on 22 a 163 kbp matrix resolves the sister relationship of Panax ginseng with P. quinquefolius. The 23 closely related species P. vietnamensis is supported as sister of P. japonicus. The plastome 24 matrix also shows that the markers trnC-rps16, trnS-trnG, and trnE-trnM could be used for 25 unambiguous molecular identification of all the represented species in the genus. 26 Conclusions 27MBD2 depletion reduces the cost of plastome sequencing, which makes it a cost-effective 28 alternative to Sanger sequencing based DNA barcoding for molecular identification. The 29 plastome phylogeny provides a robust framework that can be used to study the evolution of 30 morphological characters and biosynthesis pathways of ginsengosides for phylogenetic 31 bioprospecting. Molecular identification of ginseng species is essential for authenticating 32 ginseng in international trade and it provides an incentive for manufacturers to create 33 authentic products with verified ingredients. 34 35 3 Plastid 37 38 39 Background 40 41Ginseng has been used in traditional medicine in China for thousands of years [1], but 42 it was not until early 18th century that long-term, intense harvest nearly extirpated Panax 43 ginseng C.A.Mey. from the wild [2]. Demand for ginseng roots in the 18th century also 44 fuelled a subsequent boom in wild-harvesting American ginseng (P. quinquefolius L.) that 45 decimated wild populations in North America [3]. Today wild P. ginseng occurs in only a few 46 localities in Russia and China, with the largest distribution in the southern part of the Sikhote-47 Alin mountain range [4]. P. ginseng is Red-Listed in Russia, and roots and parts thereof from 48Russian populations are CITES Appendix II/NC listed [5]. Many other Asian ginseng species 49 are also endangered but preliminary data is only available for wild-harvesting and 50 conservation of P. assamicus R.N.Banerjee (synonym of P. bipinnatifidus var. angustifolius 51 (Burkill) J.Wen) [6], P. japonicus (T.Nees) C.A.Mey. [7] and P. pseudoginseng Wall. [8, 9]. 52Elucidating the evolutionary relationships among species in the genus is essential to 53 understand evolution of this Holarctic disjunct genus, but also evolution of derived secondary 54 metabolite pathways. In addition, a phylogenetic framework can...

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“…When we look at the chikanda type known as kapapa for example, SJK44 contains Platycoryne crocea, whereas SJK11, which is supposed to be a mix of kasebelela and kapapa, only seems to contain Satyrium species. In case of other chikanda types there seems to be more consistency: myala or real chikanda referred to Disa robusta, D. welwitschii and Satyrium buchananii, mshilamshila samples between fake chikanda samples as well [19]. It is well-known from literature that local species concepts are not necessarily congruent with scientific classifications and that species might be subject to overor underdifferentiation [50,51].…”

Section: Local Versus Scientific Classification Of Chikandamentioning

confidence: 99%

“…[12,13], whereas recently at least 32 species belonging to the genera Brachycorythis, Disa, Eulophia, Habenaria, Roeperocharis and Satyrium were suggested to be used for chikanda production based on collections in the field [12,[14][15][16][17][18][19] and one metabarcoding study of ready-made chikanda cakes [19]. To date, however, no study identified the orchids traded at the local markets, since the tubers lack sufficient morphological characters for taxonomic identification to species level [8,19]. Local classification systems categorize the tubers based on texture, harvesting locality, soil colour and phenology, but these are not likely to be congruent with scientific classifications [6,15].…”

Section: Introductionmentioning

confidence: 99%

“…DNA barcoding and metabarcoding has proven to be effective in the authentication of commercial wood species (Jiao, 2018), medicinal plants [21] and salep-producing orchids on Iranian markets [5]. The analysis of ingredients in Tanzanian chikanda cake with DNA metabarcoding revealed the presence of 21 different orchid species [19], but a DNA barcoding approach has not yet been applied to individual orchid tubers used to make this product. The aim of this study was to test to what extent species delimitation using standard molecular markers yields robust identification of chikanda orchid tubers traded on Zambian markets.…”

Section: Introductionmentioning

confidence: 99%

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Trade in Zambian Edible Orchids – DNA Barcoding Reveals Use of Unexpected Orchid Taxa for <em>Chikanda</em>

Veldman¹,

Kim²,

Andel³

et al. 2018

Preprint

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In Zambia wild edible terrestrial orchids are used to produce a local delicacy called chikanda, which has become increasingly popular throughout the country. Commercialization puts orchid populations in Zambia and neighbouring countries at risk of overharvesting. Hitherto, no study has documented which orchid species are traded on local markets, as orchid tubers are difficult to identify morphologically. In this study, the core land-plant DNA barcoding markers rbcL and matK were used in combination with nrITS to determine which species were sold on Zambian markets. Eighty-two interviews were conducted to determine harvesting areas, as well as possible sustainability concerns. By using nrITS DNA barcoding, a total of 16 orchid species in six different genera could be identified. Both rbcL and matK proved suitable to identify the tubers up to genus- or family level. Disa robusta, Platycoryne crocea and Satyrium buchananii were identified most frequently and three previously undocumented species were encountered on the market. Few orchid species are currently listed on the global IUCN Red List. Local orchid populations and endemic species could be at risk of overharvesting due to the intensive and indiscriminate harvesting of chikanda orchids and we therefore encourage increased conservation assessment  of terrestrial African orchids.

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High-throughput sequencing of African chikanda cake highlights conservation challenges in orchids

Cited by 20 publications

References 37 publications

Veronica officinalis Product Authentication Using DNA Metabarcoding and HPLC-MS Reveals Widespread Adulteration with Veronica chamaedrys

Veronica officinalis Product Authentication Using DNA Metabarcoding and HPLC-MS Reveals Widespread Adulteration with Veronica chamaedrys

Phylogenomics and barcoding ofPanax: toward the identification of ginseng species

Trade in Zambian Edible Orchids – DNA Barcoding Reveals Use of Unexpected Orchid Taxa for <em>Chikanda</em>

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High-throughput sequencing of African chikanda cake highlights conservation challenges in orchids

Cited by 20 publications

References 37 publications

Veronica officinalis Product Authentication Using DNA Metabarcoding and HPLC-MS Reveals Widespread Adulteration with Veronica chamaedrys

Veronica officinalis Product Authentication Using DNA Metabarcoding and HPLC-MS Reveals Widespread Adulteration with Veronica chamaedrys

Phylogenomics and barcoding ofPanax: toward the identification of ginseng species

Trade in Zambian Edible Orchids &ndash; DNA Barcoding Reveals Use of Unexpected Orchid Taxa for <em>Chikanda</em>

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Trade in Zambian Edible Orchids – DNA Barcoding Reveals Use of Unexpected Orchid Taxa for <em>Chikanda</em>