Abstract
Peppermint (Mentha piperita L.) is an important medicinal aromatic plant. In this study, the morphology, physiology, biochemistry and gene expression of chromosomes doubling peppermint (D1 lines) were analyzed. The analysis showed that D1 lines had larger, thicker and darker leaves, and stronger roots when planted in the pots, but delayed growth in the field condition. Under NaCl stress, the D1 lines increased cell oxidative defense through more active antioxidant enzymes and decreased the oxidative damages of cell membrane, leading to a significantly greater survival rate and photosynthesis intensity than WT lines. The size and density of glandular trichomes of D1 lines was larger, which contributed to its higher essential oil yield. In addition, chromosome doubling reduced the inhibition of NaCl stress on essential oil yield and quality, through changing the expression of genes in the oil biosynthesis pathway. The traits of chromosome doubling peppermint provide new technical and theoretical evidence for peppermint germplasm improvement.
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References
Blakeslee AF, Avery AG (1937) Methods of inducing doubling of chromosomes in plants by treatment with colchicine. J Hered 28:393–411
Chen EG, Tsai KL, Chung HH, Chen JT (2018) Chromosome doubling-enhanced biomass and dihydrotanshinone I production in Salvia miltiorrhiza, a traditional Chinese medicinal plant. Molecules 23:3106
Dhindsa RS, Plumbdhindsa P, Thorpe TA (1981) Leaf senescence: correlated with increased levels of membrane permeability and lipid peroxidation, and decreased levels of superoxide dismutase and catalase. J Exp Bot 32:93–101
Ebrahimzadeh H, Soltanloo H, Shariatpanahi ME, Eskandari A, Ramezanpour SS (2018) Improved chromosome doubling of parthenogenetic haploid plants of cucumber (Cucumis sativus L.) using colchicine, trifluralin, and oryzalin. Plant Cell Tiss Org Cult 135:407–417
García-García AL, Grajal-Martín MJ, González-Rodríguez ÁM (2020) Polyploidization enhances photoprotection in the first stages of Mangifera indica. Sci Hortic 264:109198
Huy NP, Tam DTT, Luan VQ, Tung HT, Hien VT, Ngan HTM, Duy PN, Nhut DT (2019) In vitro polyploid induction of Paphiopedilum villosum using colchicine. Sci Hortic 252:283–290
Iannicelli J, Elechosa MA, Juárez MA, Martínez A, Bugallo V, Bandoni AL, Escandón AS, van Baren CM (2016) Effect of polyploidization in the production of essential oils in Lippia integrifolia. Ind Crops Prod 81:20–29
Iannicelli J, Guariniello J, Tossi VE, Regalado JJ, Di Ciaccio L, van Baren CM, Pitta lvarez SI, Escandn AS, (2020) The “polyploid effect” in the breeding of aromatic and medicinal species. Sci Hortic 260:108854
Kim YS, Hahn EJ, Murthy HN, Paek KY (2004) Effect of polyploidy induction on biomass and ginsenoside accumulations in adventitious roots of ginseng. J Plant Bio 47:356–360
Kulaka M, Gulb F, Sekeroglu N (2020) Changes in growth parameter and essential oil composition of sage (Salvia officinalis L.) leaves in response to various salt stresses. Ind Crops Prod 145:112078
Kumar S, Suresh R, Singh V, Singh AK (2011) Economic analysis of menthol mint cultivation in Uttar Pradesh: a case study of Barabanki district. Agric Econ Res Rev 24:345–350
Lavania UC, Srivastava S, Lavania S, Basu S, Misra NK, Mukai Y (2012) Autopolyploidy differentially influences body size in plants, but facilitates enhanced accumulation of secondary metabolites, causing increased cytosine methylation. Plant J 71:539–549
Li Z, Guo K, Hu XY, Wang WW, Wei YL, Li JS, Yang HT (2014) Effect of NaCl stress on peppermint essential oil yield and quality by gas chromatography-mass spectrometry. Environ Chem 10:1802–1805
Li Z, Yang HT, Wu XQ, Guo K, Li JS (2015) Some aspects of salinity responses in peppermint (Mentha piperita L.) to NaCl treatment. Protoplasma 252:885–899
Li M, Guo Y, Liu S, Zhao Y, Pang X, Li Y (2019) Autotetraploidization in Ziziphus jujuba Mill. var. spinosa enhances salt tolerance conferred by active, diverse stress responses. Environ Exp Bot 165:92–107
Lin X, Zhou Y, Zhang J, Lu X, Zhang F, Shen Q, Wu S, Chen Y, Wang T, Tang K (2011) Enhancement of artemisinin content in tetraploid Artemisia annua plants by modulating the expression of genes in artemisinin biosynthetic pathway. Biotechnol Appl Biochem 58:50–57
Livak JK, Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2–∆∆Ct method. Methods 25:402–408
Luriea S, Fallika E, Handrosa A, Shapirab R (1997) The possible involvement of peroxidase in resistance to Botrytis cinerea in heat treated tomato fruit. Physiol Mol Plant P 50:141–149
Lv S, Yang A, Zhang K, Wang L, Zhang J (2007) Increase of glycinebetaine synthesis improves drought tolerance in cotton. Mol Breed 20:233–248
Madani H, Hosseini B, Dehghan E, Rezaei-chiyaneh E (2015) Enhanced production of scopolamine in induced autotetraploid plants of Hyoscyamus reticulatus L. Acta Physiol Plant 37:55
Magangana TP, Stander MA, Masondo NA, Makunga NP (2021) Steviol glycoside content and essential oil profiles of Stevia rebaudiana Bertoni in response to NaCl and polyethylene glycol as inducers of salinity and drought stress in vitro. Plant Cell Tiss Org Cult 145:1–18
Mishra BK, Pathak S, Sharma A, Trivedi PK, Shukla S (2010) Modulated gene expression in newly synthesized autotetraploid of Papaver somniferum L. S Afr J Bot 76:447–452
Parsons JL, Martin SL, James T, Golenia G, Boudko EA, Hepworth SR (2019) Polyploidization for the genetic improvement of Cannabis sativa. Front Plant Sci 10:476
Regalado JJ, Carmona-Martin E, Querol V, Velez CG, Encina CL, Pitta-Alvarez SI (2017) Production of compact petunias through polyploidization. Plant Cell Tiss Org Cult 129:61–71
Rios-Estepa R, Lange I, Lee JM, Lange BM (2010) Mathematical modeling-guided evaluation of biochemical, developmental, environmental, and genotypic determinants of essential oil composition and yield in peppermint leaves. Plant Physiol 152:2105–2119
Salma U, Kundu S, Mandal N (2017) Artificial polyploidy in medicinal plants: advancement in the last two decades and impending prospects. J Crop Sci Biotechnol 20:9–19
Sattler MC, Carvalho CR, Clarindo WR (2016) The polyploidy and its key role in plant breeding. Planta 243:281–296
Sugiyama SI (2005) Polyploidy and cellular mechanisms changing leaf size: comparison of diploid and autotetraploid populations in two species of Lolium. Ann Bot 96:931–938
Swathi L, Babu C, Iyanar K, Siva kumar U, Prabakaran AJ (2019) Doubling of chromosomes of pearl millet Napier hybrids and preliminary screening based on stomatal characteristics. Electron J Plant Breed 10:47–57
Tavan M, Mirjalili MH, Karimzadeh G (2015) In vitro polyploidy induction: changes in morphological, anatomical and phytochemical characteristics of Thymus persicus (Lamiaceae). Plant Cell Tiss Org Cult 122:573–583
Wallaart T, Pras N, Quax WJ (1999) Seasonal variations of artemisinin and its biosynthetic precursors in tetraploid Artemisia annua plants compared with the diploid wild-type. Planta Med 65:723–728
Widoretno W (2016) In vitro induction and characterization of tetraploid Patchouli (Pogostemon cablin Benth.) plant. Plant Cell Tiss Org Cult 125:261–267
Winkler H (1916) Ueber dei experimentelle Erzeugung von Pflanzen mit abweichenden Chromosomenzahlen. Zeitschrift Botanik 8:417–531
Xu CG, Tang TX, Chen R, Liang CH, Liu XY, Wu CL, Yang YS, Yang DP, Wu H (2014) A comparative study of bioactive secondary metabolite production in diploid and tetraploid Echinacea purpurea (L.) Moench. Plant Cell Tiss Org Cult 116:323–332
Zeng Q, Liu Z, Du K, Kang X (2019) Oryzalin-induced chromosome doubling in triploid Populus and its effect on plant morphology and anatomy. Plant Cell Tiss Org Cult 138:571–581
Zhang XY, Hu CG, Yao JL (2010) Tetraploidization of diploid Dioscorea results in activation of the antioxidant defense system and increased heat tolerance. J Plant Physiol 167:88–94
Zhao ZJ, Wei YL, Wang YL, Li CY, Chen K, Yang HT, Li JS (2017) Research on the chromosome doubling of peppermint induced by colchicines. Shandong Sci 30:103–108
Acknowledgements
This work was supported by the Natural Science Foundation of Shandong Province of China [Grant number ZR2019BC076, ZR2020QC044], Major Scientific and Technological Innovation Project of Shandong Province [Grant number 2019JZZY010723), Produce and Study and Research Cooperation Innovation Fund between Shandong Academy of Sciences and Local [Grant number 2019-CXY5].
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Zhao, Z., Wei, Y., Li, L. et al. Chromosome doubling influences the morphological, physiological, biochemical and genetic traits related to essential oil biosynthesis of peppermint (Mentha piperita) under salinity stress. J Plant Res 135, 93–104 (2022). https://doi.org/10.1007/s10265-021-01347-8
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DOI: https://doi.org/10.1007/s10265-021-01347-8