Potential toxicity of wild Ipomoea ingested by schoolchildren in remote Northeastern Thailand
Main Article Content
Abstract
Background: Natural plant toxins can cause food poisoning upon intentional or unintentional consumption of wild plants. Some toxic wild plants can be mistaken for edible species because of their morphological resemblance. This study examined a poisoning case report of schoolchildren who consumed a steamed tuberous root of wild Ipomoea, misidentified as I. mauritiana, and experienced gastrointestinal toxicity.
Objectives: This study aimed to identify the tuberous root of wild Ipomoea using the internal transcribed spacer (ITS) region as a DNA barcode and characterize compounds obtained using gas chromatography-mass spectrometry (GC-MS).
Materials and methods: DNA was extracted from fresh and cooked samples of the storage root. PCR amplification and DNA sequencing of the entire ITS region were performed. FastTree and maximum likelihood analyses were used to obtain phylogenetic trees of the Ipomoea species. Root extracts were prepared for GC-MS analysis, and potentially harmful phytochemicals responsible for poisonous plant exposure were predicted based on a well-established plant toxin database.
Results: ITS phylogeny showed a close relationship between wild toxic Ipomoea and edible I. mauritiana. The chemometric profile obtained from GC-MS analysis of the root extracts revealed the presence of 31 phytochemicals. Among them, two putatively toxic compounds identified were β-amyrin and coumarin.
Conclusion: Misidentification of the wild poisonous plant reported herein resulted in toxic plant ingestion. Although most poisonous plant exposures are not life threatening, measures should be taken to ensure the safety of the general public.
Article Details
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Personal views expressed by the contributors in their articles are not necessarily those of the Journal of Associated Medical Sciences, Faculty of Associated Medical Sciences, Chiang Mai University.
References
Cao Y, Li R, Zhou S, Song L, Quan R, Hu H. Ethnobotanical study on wild edible plants used by three trans-boundary ethnic groups in Jiangcheng County, Pu’er, Southwest China. J Ethnobiol Ethnomed. 2020; 16(1): 66.
Mishra A, Swamy SL, Thakur TK, Bhat R, Bijalwan A, Kumar A. Use of wild edible plants: can they meet the dietary and nutritional needs of indigenous communities in central India. Foods. 2021; 10(7): 1453.
Ojelel S, Mucunguzi P, Katuura E, Kakudidi EK, Namaganda M, Kalema J. Wild edible plants used by communities in and around selected forest reserves of Teso-Karamoja region, Uganda. J Ethnobiol Ethnomed. 2019; 15(1): 3.
Gayao BT, Meldoz DT, Backian GS. Indigenous knowledge and household food security: The role of root and tuber crops among indigenous peoples in the Northern Philippines. In: Niehof A, Gartaula HN, Quetulio-Navarra M, editors. Diversity and change in food wellbeing – Cases from Southeast Asia and Nepal. 2018: 43-69.
Mukhopadhyay S, Chattopadhyay A, Chakraborty I, Bhattacharya I. Crops that feed the world 5. Sweetpotato. Sweetpotatoes for income and food security. Food Secur. 2011; 3: 283-305.
Aparicio H, Hedberg I, Bandeira S, Ghorbani A. Ethnobotanical study of medicinal and edible plants used in Nhamacoa area, Manica province–Mozambique. South African J Bot. 2021; 139: 318-28.
Muñoz-Rodríguez P, Carruthers T, Wood JRI, Williams BRM, Weitemier K, Kronmiller B, et al. A taxonomic monograph of Ipomoea integrated across phylogenetic scales. Nat Plants. 2019; 5(11): 1136-44.
Wood JRI, Muñoz-Rodríguez P, Williams BRM, Scotland RW. A foundation monograph of Ipomoea (Convolvulaceae) in the New World. PhytoKeys. 2020; 143: 1-823.
Beyer SF, Beesley A, Rohmann PFW, Schultheiss H, Conrath U, Langenbach CJG. The Arabidopsis non-host defence-associated coumarin scopoletin protects soybean from Asian soybean rust. Plant J. 2019; 99(3): 397-413.
Döll S, Kuhlmann M, Rutten T, Mette MF, Scharfenberg S, Petridis A, et al. Accumulation of the coumarin scopolin under abiotic stress conditions is mediated by the Arabidopsis thaliana THO/TREX complex. Plant J. 2018; 93(3): 431-44.
Diaz JH. Poisoning by herbs and plants: rapid toxidromic classification and diagnosis. Wilderness Environ Med. 2016; 27(1): 136-52.
Sriapha C, Tongpoo A, Wongvisavakorn S, Rittilert P, Trakulsrichai S, Srisuma S, et al. Plant poisoning in Thailand: A 10-year analysis from Ramathibodi Poison Center. Southeast Asian J Trop Med Public Health. 2015; 46(6): 1063-76.
White TJ, Bruns TD, Lee SB, Taylor JW. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. In: Innis MA, Gelfand DH, Sninsky JJ, White T, editors. PCR Protocols: a guide to methods and applications. New York: Academic Press; 1990: 315-22.
Price MN, Dehal PS, Arkin AP. FastTree 2 – Approximately maximum-likelihood trees for large alignments. PLoS One. 2010; 5(3): e9490.
Stamatakis A. RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics. 2014; 30(9): 1312-3.
Günthardt BF, Hollender J, Hungerbühler K, Scheringer M, Bucheli TD. Comprehensive toxic plants–phytotoxins database and its application in assessing aquatic micropollution potential. J Agric Food Chem. 2018; 66(29): 7577-88.
Ratnatilaka A, Yakandawala D, Pupasinghe N, Ratnayake K. Poisoning of “binthamburu” (Ipomoea asarifolia) due to misidentification as “kankun” (Ipomoea aquatica). Ceylon Med J. 2010; 55(2): 54-5.
Medeiros RMT, Barbosa RC, Riet-Correa F, Lima EF, Tabosa IM, de Barros SS, et al. Tremorgenic syndrome in goats caused by Ipomoea asarifolia in Northeastern Brazil. Toxicon. 2003; 41(7): 933-5.
Wamalwa LN, Cheseto X, Ouna E, Kaplan F, Maniania NK, Machuka J, et al. Toxic ipomeamarone accumulation in healthy parts of sweetpotato (Ipomoea batatas L. Lam) storage roots upon Infection by Rhizopus stolonifer. J Agric Food Chem. 2015; 63(1): 335-42.
Oliveira CA, Riet-Correa G, Lima E, Medeiros RMT, Miraballes C, Pfister JA, et al. Toxicity of the swainsonine-containing plant Ipomoea carnea subsp. fistulosa for goats and sheep. Toxicon. 2021; 197: 40-7.
Meira M, Silva E, David J, David J. Review of the genus Ipomoea: traditional uses, chemistry and biological activities. Rev Bras Farmacogn. 2012; 22(3): 682-713.
Srivastava D. Medicinal plants of genus Ipomoea found in Uttar-Pradesh, India. Res J Recent Sci. 2017; 6(12): 12-22.
Staples G, Na Songkhla B, Khunwasi C, Traiperm P. Annotated checklist of Thai Convolvulaceae. Thai For Bull. 2005; (33): 171-84.
Staples G, Chitchak N, Kochaiphat P, Rattamanee C, Rattanakrajang P, Traiperm P. Convolvulaceae in the flora of Thailand: addenda, corrigenda and emendanda, I. Thai For Bull. 2021; 49(1): 88-101.
Staples G, Traiperm P. New species, new combinations, and new records in Convolvulaceae for the flora of Thailand. Thai For Bull. 2008; 36: 86-108.
Nittayasoot N, Lekcharoen P, Tantiworrawit P. Plant poisoning outbreak in a primary school in the northern Thailand, October 2015. Outbreak Surveill Investig Rep. 2017; 10(4): 17-21.
Viji Z, Paulsamy S. Phytoconstituents analysis, and GC-MS profiling of tubers of Ipomoea mauritiana Jacq (convolvulaceae). Int J Recent Adv Multidiscip Res. 2016; 3(3): 1345–9.
Gnonlonfin GJB, Sanni A, Brimer L. Review Scopoletin – A Coumarin phytoalexin with medicinal properties. CRC Crit Rev Plant Sci. 2012; 31(1): 47-56.
Bayoumi SAL, Rowan MG, Blagbrough IS, Beeching JR. Biosynthesis of scopoletin and scopolin in cassava roots during post-harvest physiological deterioration: the E-Z-isomerisation stage. Phytochemistry. 2008; 69(17): 2928-36.
Perkowska I, Potrykus M, Siwinska J, Siudem D, Lojkowska E, Ihnatowicz A. Interplay between coumarin accumulation, iron deficiency and plant resistance to Dickeya spp. Int J Mol Sci. 2021; 22(12): 6449.
Chutia R, Abel S, Ziegler J. Iron and phosphate deficiency regulators concertedly control coumarin profiles in Arabidopsis thaliana roots during iron, phosphate, and combined deficiencies. Front Plant Sci. 2019; 10: 113.
Ibanez S, Gallet C, Després L. Plant insecticidal toxins in ecological networks. Toxins (Basel). 2012; 4(4): 228-43.
Tripathi AK, Bhakuni RS, Upadhyay S, Gaur R. Insect feeding deterrent and growth inhibitory activities of scopoletin isolated from Artemisia annua against Spilarctia obliqua (Lepidoptera: Noctuidae). Insect Sci. 2011; 18(2): 189-94.
Zhou H, Zhang Y-Q, Lai T, Wang D, Liu J-L, Guo F-Y, et al. Silencing chitinase genes increases susceptibility of Tetranychus cinnabarinus (Boisduval) to Scopoletin. Biomed Res Int. 2017; 12: 9579736.
Scopoletin; MSDS No.sc-206059; Santa Cruz Biotechnology, Inc. CA, November 26, 2009.