Journal Search Engine

to

Search Advanced Search Adode Reader(link)
Download PDF Export Citation PMC Previewer
ISSN : 1225-5009(Print)
ISSN : 2287-772X(Online)
Flower Research Journal Vol.27 No.4 pp.278-284
DOI : https://doi.org/10.11623/frj.2019.27.4.05

Analysis of Ploidy Levels of Korean Wild Asteraceae Species Using Chromosome Counting

Wang Yan1†, Jin Hee Lim2†, Jae A Jung3, Won Hee Kim3, Ki-Byung Lim4, Raisa Aone M. Cabahug5, Yoon-Jung Hwang1*
1Department of Convergence Science, Sahmyook University, Seoul, 01795, Korea
2Department of Plant Biotechnology, Sejong University, Seoul, 05006, Korea
3Floriculture Research Division, National Institute of Horticultural & Herbal Science, Wanju, 55365, Korea
4Department of Horticultural Science, Kyungpook National University, Daegu, 41566, Korea
5Chromosome Research Institute, Sahmyook University, Seoul, 01795, Korea



These authors contribute equally to this work.


Corresponding author: Yoon-Jung Hwang Tel: +82-2-3399-1718 E-mail: hyj@syu.ac.kr
21/10/2019 28/11/2019 02/12/2019

Abstract


Because of their attractive and colorful flowers, many species from the genus Aster serve as garden plants. Chrysanthemum owes its popularity to its ornamental and medicinal herb value. It can be used as a cut flower, potted plant, vegetable, and herbal tea. Plant breeders have attempted to identify the available species and produce new cultivars to improve the quality of Chrysanthemum for commercial purposes. The use of cytogenetic studies has paved the way for identifying compatibility, ancestry, and other useful information for this undertaking. Thus, an investigation was conducted into the chromosome numbers of 23 wild Asteraceae species in Republic of Korea to determine their genetic characteristics and variations. The somatic chromosome spread has been used for chromosome counting. The results revealed that Asteraceae species have a chromosome range from 18 (diploid) to 54 (hexaploid). These findings provide primary and important information on the chromosome numbers in Chrysanthemum plants that can be used to select the right variety for cultivation.



chromosome number , cytogenetics , diploid , tetraploid , hexaploid , polyploidy

초록

    Rural Development Administration
    PJ012804

    Introduction

    The Asteraceae is one of the largest angiosperm families in the herbaceous plants throughout the world. It contains 1600 genera, including genus Chrysanthemum and genus Aster (Atri et al. 2009). The genus Chrysanthemum contains about 41 species that are mainly distributed in East Asia and chiefly in China, Korea, and Japan (Hwang et al. 2013;Liu et al. 2012;Masuda et al. 2009;Zhao et al. 2010). In Korea, there are 17 known species of wild chrysanthemums that grow in their respective habitats. Among them, Chrysanthemum boreale and C. indicum are used for landscaping and medicinal purposes. Many Aster species are serving as garden plants due to their attractive and colorful flowers.

    One of the most widely marketed cut-flower in the world, chrysanthemum is famous for its wide array of flower variations in size, color, and shape as well as its long vase life, early production and photoperiod responses (Junqueira and Peetz 2014;Zandonadi et al. 2018). Due to these desirable traits, chrysanthemums rank among the top three highest cut flowers imported annually by Netherlands (2.7 billion pieces) and Taiwan (7.1 Million bunches) (Hanks 2018).

    The increasing awareness of the importance of wild germplasm recognizes that wild species play a key role as progenitors in many plant improvement programs. Therefore, it is necessary to use desirable genetic traits from wild chrysanthemums that have not been exploited in these breeding programs (Datta and Janakiram 2015). Take for example the white rust disease, caused by the fungus Puccinia horiana, which caused economical loses in chrysanthemum (Park and Kim 1993). In the study of Park et al. (2014), it was reported that among the wild chrysanthemum infected by Puccinia horiana, C. boreale and C. zawadskii were found to be resistant, and C. indicum and Aster spathulifolius were highly susceptible. Studies like these can contribute to the improvement of genetic diversity in chrysanthemum.

    However, breeding chrysanthemum proves to be difficult because they have various ploidy level, self-incompatibility, and genetic heterozygosity. Therefore, chromosomal information in the chrysanthemum breeding program is essential and crucial. The basic chromosome number of chrysanthemum is x = 9 and shows a variety of their ploidy levels ranging from diploid (2n = 2x = 18) to decaploid (2n = 10x = 90). In particular, chrysanthemum cultivars (C. morifolium) are mostly known as allohexaploid (2n = 6x = 54). It was reported that polyploidization is caused by natural cross-hybrid between C. indicum, C. japonense, C. lavandulifolium, C. makinoi, C. sinense, C. ornatum, C. vesticum, and C. zawadskii etc. (Dai et al. 2005;Ma et al. 2016) and possessing various aneuploidy (2n = 45-71) (Chang et al. 2009;Zhu et al. 2011). The formation of abnormal pairs of chromosomes during meiosis caused by the aneuploidy affects pollen viability. Therefore, identification of chrysanthemum species using cytological investigation is essential for an efficient breeding program.

    Hence, this paper investigated the chromosome number and ploidy level information of Korean wild Asteraceae species collected from 17 different areas within Republic of Korea by performing cytogenetic analysis. The results of this study provide basic information of Asteraceae genetic diversity in Korea and can be used for breeding schemes as basic data for breeder.

    Materials and methods

    Plant materials

    Twenty-three individuals of Asteraceae species were collected from 17 different areas in Republic of Korea (Table 1). Plant samples were provided by Sejong University, Seoul, Korea and being cultivated in the green-house of Sahmyook University, Seoul, Korea.

    Ploidy level determination

    Investigation of ploidy level was determined by chromosome counting method. Young root tips of actively growing plants were harvested and pre-treated with 2 mM 8-hydroxyquinoline for 5 h at 18°C, and then fixed in Carnoy’s solution [3:1 = ethanol : glacial acetic acid (v/v)] for 24 h at room temperature. The material was stored at -20°C in 70% ethanol solution. For chromosome analysis study, pretreated roots were washed thoroughly with distilled water and the root tips were treated with a mixture of enzymes (0.3% cellulase, 0.3% cytohelicase, 0.3% pectolyase in 150 mM of citrate buffer) for 1.5 h at 37°C. Carnoy’s solution was pipetted into meristematic tissue, and vortexed for 15 sec. The suspension was then centrifuged at 5,000 rpm for 5 min, and the supernatant was decanted carefully. The protoplast was re-suspended in acetic acid:ethanol (9:1 v/v) solution. The final suspension was spread on an 80°C pre-warmed glass slide in a humid chamber and followed by air dried at room temperature. The slides were counterstained with premixed 4′,6-diamidino-2-phenylindole (DAPI) solution (1 μg・ml-1; DAPI in Vectashield, Vector Laboratories, Burlingame, CA, USA).

    Image acquisition

    Images were captured under a model BX53 fluorescence microscope (Olympus, Tokyo, Japan) equipped with a DFC365 FS CCD camera (Leica Microsystems, Wetzlar, Germany) and processed using Cytovision ver. 7.2 (Leica Microsystems). Further image enhancements were performed with Adobe Photoshop CC (Adobe Systems, San Jose, CA, USA).

    Results and discussion

    Of the twenty-three individuals across genus Chrysanthemum and Aster have been examined, and the chromosome results revealed that chromosome number are listed in Table 1. All the investigated plants are the first time to report except A05 and B06 under the species of C. boreale and B27 under the species of Aster spathulifolius. Extensive variation in ploidy levels was found in wild Asteraceae species and ploidy level varies from diploid (2x) to hexaploid (6x) with a basic chromosome number of 9.

    Chrysanthemum boreale (2n = 18)

    C. boreale is a perennial flowering plant that is often well-known by its yellow flower. In Korea, wild C. boreale can be found in various habitats, such as Gyeongsangbuk-do, Gangwon-do, Gyeonggi-do, Gyeongsangnam-do, and Jeollabuk-do (Table 1). All the investigated plant showed diploid with chromosome number of 2n = 18 (Fig. 1), which is consistent with the previously report (Cuyacot et al. 2016;Dowrick 1952;Hwang et al. 2013;Kim 1999;Kim 2015;Kim et al. 2008;Kim et al. 2015;Liu et al. 2012).

    Chrysanthemum indicum (2n = 18 / 36)

    C. indicum is flowering plant with small capitula and yellow ray florets (Lim 2012) and commonly called Indian chrysanthemum and Yejuhua (China). It is used to treat infectious diseases and hypertension disorders in Korea, China and Japan (Lograda et al. 2013). As an antiphlogistic used for the treatment of carbuncle, furuncle, conjunctivitis, headache, and vertigo in traditional Chinese medicine (Tang and Eisenbrand 1992). The species are wild to Korea and being extensively distributed at Jeollabuk-do, Chungcheongbuk-do, Jeju-do, Gyeongsangbuk-do, and Incheon (Table 1). It was reported that C. indicum was diploid (2n = 18) and tetraploid (2n = 36) by Kim (1999), Kim et al. (2008), Hong-Bo et al. (2009), Liu et al. (2012), Li et al. (2013). The current study also revealed that C. indicum has chromosome number of 18 (diploid) and 36 (tetraploid) within the infraspecies. The species is also known to have hexaploid with 2n = 54 (Kim et al. 2015;Liu et al. 2012). Fig. 2

    Chrysanthemum zawadskii (2n = 18 / 36 / 45 / 54)

    C. zawadskii has a white-purple ray floret with large captitula (Kim 2015). C. zawadskii is the major and most popular wild plant in Korea (Lim 2012). Diploid (2n = 18), tetraploid (2n = 36), hexaploid (2n = 54), and octaploid (2n = 72) species from Korea have been reported by Kim et al. (2003), Kim et al. (2008), Kim et al. (2015), Stuessy and Ono (2007). Tetraploid (2n = 36) and hexaploid (2n = 54) were also reported in China and Japan (Liu et al. 2012;Suzuki et al. 2014) Besides, the present study adds a new cytotype of pentaploid (5X) to this species (Fig. 3D).

    Chrysanthemum zawadskii spp. lucidum (2n = 36)

    C. zawadskii spp. lucidum is a Chrysanthemum subspecies from Ullengdo, Korea. Chromosome number of C. zawadskii spp. lucidum were showed tetraploid (2n = 4x = 36), which are same as the earlier study (Cuyacot et al. 2017;Kim 1999;Kim et al. 2015;Kim 2015;Lee 1975). Fig. 4

    Aster spathulifolius (2n = 18)

    A. spathulifolius, a perennial herb of the genus Aster within the family Asteraceae, are native to the coastal regions of Korea and Japan (Maki and Morita 1998;Yoon et al. 2005). It grows on seashores due to its short height and thick leaves. This species has vivid white or light blue flowers (Maki and Morita 1998). The plants used for studies were collected from Ulleungdo, Busan, and Jeju-do (Table 1) and all showed diploid with chromosome number of 2n = 18. The number of chromosome is same with previous report (Huziwara 1957;Maki and Morita 1998;Li and Zhang 2004;Yoon et al. 2005). Moreover, all three plants from different native areas had a pair of satellite chromosome (Fig. 5), which is consistent with the study of Yoon et al. (2005).

    Variations in ploidy level

    Chromosome counts reveal that subspecies variation were highly occurred except C. boreale. For example, C. indicum was found to have 2x (A06, A13, and A16), 4x (A01, A96, and B25), and C. zawadskii was found to have 2x (B75), 4x (A57 and B30), 5x (A99), and 6x (A25) populations. The existence of a regular succession of chromosome number within a species is an evidence for polyploidy (Heslop‐ Harrison and Schwarzacher 2011) and this probably due to plants from different location is examined (Gutiérrez-Flores et al. 2018). Variation in chromosome numbers may be the result of habitat adaptation, which explains their widely distribution (El-Twab and Kondo 2006).

    However, both of the C. boreale and A. spathulifolius are diploid with a chromosome number of 2n = 18, but their distribution patter is opposite. C. boreale is widely distributed around the country (Table 1), while A. spathulifolius are narrowly distributed and habitat-specific in the coastline. According to Liu et al. (2012), this can be explained that the diploid species appear to be endemic or narrowly distributed, and polyploidy are usually widely distributed in most instances. All this information suggests that speciation is related to polyploidy and ecological tolerances.

    Polyploidy is one of the major biological events in plant evolution process that often leading to complex patterns of genetic diversity, reproductive isolation, and discrepancy in breeding systems (Gutiérrez-Flores et al. 2018). It is often the result of climatic change, human, and other disturbance (Li et al. 2013). Studies of chromosome numbers could provide information for a better understanding of evolutionary relationships between species (Peng and Hsu 1978). Thus, studies that focus on chromosomal number can be used to determine the distribution of different cytotypes and reproductive variation at both intra- and inter-population levels. As well as being of basic research, understanding and exploiting evolutionary mechanisms in plant is likely to be a key for crop development.

    Acknowledgments

    This work was carried out with the support of “Cooperative Research Program for Agriculture Science and Technology Development (Project No. PJ012804)” Rural Development Administration, Republic of Korea.

    Figure

    FRJ-27-4-278_F1.gif

    Mitotic metaphase chromosomes of C. boreale (2n = 2x = 18): A05 (A), A79 (B), A82 (C), A84 (D), B06 (E), B16 (F), B24 (G), B58 (H). Scale bars = 10 μm.

    FRJ-27-4-278_F2.gif

    Mitotic metaphase chromosomes of C. indicum: A06, 2n = 2x = 18 (A); A13, 2n = 2x = 18 (B); A16, 2n = 2x = 18 (C); A01, 2n = 2x = 36 (D); A96, 2n = 2x = 36 (E); B25, 2n = 2x = 36 (F). Scale bars = 10 μm.

    FRJ-27-4-278_F3.gif

    Mitotic metaphase chromosomes of C. zawasdskii: B75, 2n = 2x = 18 (A); A57, 2n = 4x = 36 (B); B30, 2n = 4x = 36 (C); A99, 2n = 5x = 45 (D); A25, 2n = 6x = 54 (E). Scale bars = 10 μm.

    FRJ-27-4-278_F4.gif

    Mitotic metaphase chromosomes of C. zawasdskii spp. lucidum (A103, 2n = 4x = 36). Scale bar = 10 μm.

    FRJ-27-4-278_F5.gif

    Mitotic metaphase chromosomes of A. spathulifolius: B27, 2n = 2x = 18 (A); B32C, 2n = 2x = 18 (B); B46, 2n = 2x = 18 (C). Scale bars = 10 μm.

    Table

    Geographical distribution and chromosome number variation in 23 Asteraceae species from South Korea.

    Reference

    1. Atri M , Chehregani A , Jalali F , Yousefi S (2009) New chromosome counts in some species of the genus Artemisia L. (Asteraceae) from Iran. The Japan Mendel Society Cytologia 74:443-448
    2. Chang L , Chen SM , Chen FD , Zhen L , Fang WM (2009) Karyomorphological studies on Chinese pot Chrysanthemum cultivars with large inflorescences. Agricultural Sciences in China 8:793-802
    3. Cuyacot AR , Lim KB , Kim HH , Hwang YJ (2017) Chromosomal characterization based on repetitive DNA distribution in a tetraploid cytotype of Chrysanthemumzawadskii. Hortic Environ Biotech 58:488-494
    4. Cuyacot AR , Won SY , Park SK , Sohn SH , Lee J , Kim JS , Kim HH , Lim KB , Hwang YJ (2016) The chromosomal distribution of repetitive DNA sequences in Chrysanthemum boreale revealed a characterization in its genome. Sci Hort 198:438-444
    5. Dai SL , Wang WK , Li MX , Xu YX (2005) Phylogenetic relationship of Dendranthema (DC.) Des Moul. revealed by fluorescent in situ hybridization. J Integr Plant Biol 47:783-791
    6. Datta S , Janakiram T (2015) Breeding and genetic diversity in Chrysanthemum morifolium in India: A review. Indian J Agr Sci 85:1379-1395
    7. Dowrick G (1952) The chromosomes of Chrysanthemum, I: The species. Heredity 6:365
    8. El-Twab MHA , Kondo K (2006) FISH physical mapping of 5S, 45S and Arabidopsis-type telomere sequence repeats in Chrysanthemum zawadskii showing intra-chromosomal variation and complexity in nature. Chromosome Botany 1:1-5
    9. Gutierrez-Flores C , Leon-De La Luz JL , Garcia-De Leon FJ , Cota-Sanchez JH (2018) Variation in chromosome number and breeding systems: implications for diversification in Pachycereus pringlei (Cactaceae). Comp Cytogenet 12:61-82
    10. Hanks G (2018) A review of production statistics for the cut flower and foliage sector. Accessed Oct. 2019, https://horticulture.ahdb.org.uk/sites/default/files/CFC%20Cut%20Flower%20production%20statistics%202018.pdf
    11. Heslop‐Harrison J , Schwarzacher T (2011) Organisation of the plant genome in chromosomes. The Plant J 66:18-33
    12. Hong-Bo Z , Li C , Tang FP , Chen FD , Chen SM (2009) Chromosome numbers and morphology of eighteen Anthemideae (Asteraceae) taxa from China and their systematic implications. Caryologia 62:288-302
    13. Huziwara Y (1957) Karyotype analysis in some genera of Compositae. Cytologia 22:96-112
    14. Hwang YJ , Younis A , Ryu KB , Lim KB , Eun CH , Lee J , Sohn SH , Kwon SJ (2013) Karyomorphological analysis of wild Chrysanthemum boreale collected from four natural habitats in Korea. Flower Res J 21:182-189
    15. Junqueira AH , da Silva Peetz M (2014) The productive sector of flowers and ornamental plants of Brazil, in the period from 2008 to 2013: updates, balance sheets and prospects. Ornamental Horticulture 20:115-120
    16. Kim J (1999) Phylogenetic relationship among Korean Dendranthema using the analysis of chromosome characters and cpDNA intergenic region sequences. MS Dissertation, Kyungpook National University, Korea
    17. Kim JS , Oginuma K , Tobe H (2008) Analysis of meiotic chromosome behaviour in diploid individuals of Chrysanthemum zawadskii and related species (Asteraceae): Evidence for chromosome rearrangements. Cytologia 73:425-435
    18. Kim JS , Pak JH , Seo BB , Tobe H (2003) Karyotypes of metaphase chromosomes in diploid populations of Dendranthema zawadskii and related species (Asteraceae) from Korea: diversity and evolutionary implications. J Plant Res 116:47-54
    19. Kim SJ (2015) Taxonomic study of Korean Chrysanthemum based on morphological, molecular, and chemotaxonomical characteristics. PhD Dissertation, Seoul National University, Korea, URI: http://hdl.handle.net/10371/120997
    20. Kim SJ , Cho KS , Yoo KO , Lim KB , Hwang YJ , Chang DC , Kim KS (2015) Sequence analysis of the internal transcribed spacer (ITS) region of the nuclear ribosomal DNA (nrDNA) Chrysanthemum species in Korea. Hortic Environ Biotech 56:44-53
    21. Lee YN (1975) Taxonomic study on white flowered wild Chrysanthemum in Asia. Korean J Bot 14:63-73
    22. Li J , Wan Q , Abbott RJ , Rao GY (2013) Geographical distribution of cytotypes in the Chrysanthemum indicum complex as evidenced by ploidy level and genome‐size variation. J Syst Evol 51:196-204
    23. Li WP , Zhang ZG (2004) Aster shennongjiaensis (Asteraceae), a new species from central China. Bot Bull Acad Sin 45:95-99
    24. Lim TK (2012) Edible medicinal and non-medicinal plants. Springer, Netherlands
    25. Liu PL , Wan Q , Guo YP , Yang J , Rao GY (2012) Phylogeny of the genus Chrysanthemum L .: e vidence from single-copy nuclear gene and chloroplast DNA sequences. PloS One 7:e48970
    26. Lograda T, R am dani M , Chalard P, F igueredo G , Silini H , Kenoufi M (2013) Chemical composition, antibacterial activity and chromosome number of Algerian populations of two Chrysanthemum species. J App Pharml Sci 3:6-11
    27. Ma YP , Chen MM , Wei JX , Zhao L , Liu PL , Dai SL , Wen J (2016) Origin of Chrysanthemum cultivars—Evidence from nuclear low-copy LFY gene sequences. Biochem Syst Ecol 65:129-136
    28. Maki M , Morita H (1998) Genetic diversity in island and mainland populations of Aster spathulifolius (Asteraceae). Int J Plant Sci 159:148-152
    29. Maoxue L , Xiaofang Z , Junyu C (1983) Cytological studies on some Chinese wild Dendranthema species and Chrysanthemum cultivars. Acta Horti Sinica 10:199-205
    30. Masuda Y , Yukawa T , Kondo K (2009) Molecular phylogenetic analysis of members of Chrysanthemum and its related genera in the tribe Anthemideae, the Asteraceae in East Asia on the basis of the internal transcribed spacer (ITS) region and the external transcribed spacer (ETS) region of nrDNA. Chromosome Botany 4:25-36
    31. Park KS , Kim CH (1993) Effect of temperature and pH on sporidia formation of Puccinia horiana on Chrysanthemum and evaluation of varietal resistance. Plant Pathol J 9:42-46
    32. Park SK , Lim JH , Shin HK , Jung JA , Kwon YS , Kim MS , Kim KS (2014) Identification of Chrysanthemum genetic resources resistant to white rust caused by Puccinia horiana. Plant Breeding and Biotechnology 2:184-193
    33. Peng C , Hsu C (1978) Chromosome numbers in Taiwan Compositae. Bot Bull Acad Sin 19:53-66
    34. Stuessy TF , Ono M (2007) Evolution and speciation of island plants. Cambridge University Press, New York, USA
    35. SuzukI K , Masuda Y , Kondo K (2014) Induction of new types of Chrysanthemums by intergeneric cross-hybridizations in relations of a synteny among the members of the tribe Anthemideae, the Asteraceae. Chromosome Botany 9:113-120
    36. Tang W , Eisenbrand G (1992) Chrysanthemum indicum L. and C. morifolium R am at. In C hinese D rugs o f Plant Origin. Springer, UK
    37. Yoon PS , Park HM , Kim DM , Kim HH (2005) Morphological characteristics and karyotypic analysis of Aster spathulifolius according to native area. Plant Resources 8:244-249
    38. Zandonadi AS , Maia C , Barbosa JG , Finger FL , Grossi JAS (2018) Influence of long days on the production of cut Chrysanthemum cultivars. Horticultura Brasileira 36:33-39
    39. Zhang F , Chen S , Chen F , Fang W , Li F (2010) A preliminary genetic linkage map of chrysanthemum (Chrysanthemum morifolium) cultivars using RAPD, ISSR and AFLP markers. Scientia Horticulturae 125:422-428
    40. Zhao H-B , Chen F-D , Chen S-M , Wu G-S , Guo W-M (2010) Molecular phylogeny of Chrysanthemum, Ajania and its allies (Anthemideae, Asteraceae) as inferred from nuclear ribosom al I TS a nd c hloroplast trnL-F IGS sequences. Plant Syst Evol 284: 153-169.
    41. Zhu M , Liu Q , Dai S (2011) Karyotype analysis of 38 large-flowered Chrysanthemum cultivars from China. Chinese Bull Bot 46:447-455
    
    1. SEARCH

    2. Journal Abbreviation : 'Flower Res. J.'
      Frequency : Quarterly
      Doi Prefix : 10.11623/frj.
      ISSN : 1225-5009 (Print) / 2287-772X (Online)
      Year of Launching : 1991
      Publisher : The Korean Society for Floricultural Science
      Indexed/Tracked/Covered By :

    3. Online Submission

      submission.ijfs.org

    4. Template DOWNLOAD

      Original Research
      Articles      국문 영문
      Review Articles 리뷰
      ★NEWTechnical Reports단보
      New Cultivar
      Introduction       품종

    5. 논문유사도검사

    6. KSFS

      Korean Society for
      Floricultural Science

    7. Contact Us
      Flower Research Journal

      - Tel: +82-54-820-5472
      - E-mail: kafid@hanmail.net