Karyotype analysis from four species of edible plants in northeastern Thailand

Surapon Saensouk; Piyaporn Saensouk; Natkamon  Saen-in

doi:10.13057/biodiv/d221212

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DOI https://doi.org/10.13057/biodiv/d221212

Issue

Vol. 22 No. 12 (2021)

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Articles

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

SURAPON SAENSOUK

Walai Rukhavej Botanical Research Institute, Mahasarakham University

PIYAPORN SAENSOUK ♥

Plant and Invertebrate Taxonomy and Its Applications Unit Group, Department of Biology, Faculty of Science, Mahasarakham University

NATKAMON SAEN-IN

Walai Rukhavej Botanical Research Institute, Mahasarakham University, Kantarawichai District, Maha Sarakham, 44150, Thailand

Abstract

Karyotype analysis from four species of edible plants, namely one species from family Cannaceae (Canna indicaL.), one species including 2 variants from family Araceae (Colocasia esculenta(L.) Schott, green taro and black taro) and two species from family Apiaceae (Eryngium foetidum L. and Centella asiatica (L.) Urb.) in Maha Sarakham province, northeastern Thailand were determined from root tips. The results showed that the chromosome numbers and karyotype formulae were 2n= 28 = 14m + 10sm + 4st (2sat) with NF = 56 for green taro, 2n= 42 = 20m
+ 20sm + 2st (3sat) with NF = 84 for black taro, 2n = 18 = 18sm with NF = 36 for Centella asiatica (L.) Urb., 2n = 16 = 2m +14 sm with NF = 32 for Eryngium foetidum L., 2n= 27 = 2m
+ 25sm with NF = 54 for Canna indica L. Both taros had differences in the chromosome numbers and karyotype formulae. The chromosomes of both taros were the asymmetrical karyotype. While, the chromosome structure of both taros, including the number of metacentric, submetacentric and subtelocentric as well as the position of satellite-chromosomes, were found to be different, which indicated inter-and intra-specific variations in this species. Therefore, the chromosome number, karyotype formula, chromosome structure, position of satellite-chromosomes and idiogram can be used for classification of both taros in this study. Moreover, idiograms of both taros were reported for the first time. The karyotype, NF, RL, CI and
ideogram of Centella asiatica(L.) Urb., Eryngium foetidum L. and Canna indica L. were reported for the first time.

References

Belling J. 1925. Chromosomes of Canna and of Hemerocallis. Journal of Heredity 16(12): 465–466.

Boyce PC, Sookchaloem D. 2012. Araceae. In: Santisuk, T. andLarsen, K. (eds.). Flora of Thailand. Vol. 11 Part 2. Prachachon Co., Ltd., Bangkok. pp. 101-325.

Coates DJ, Yen DE, Gaffey PM. 1988. Chromosome Variation in Taro, Colocasia esculenta: Implications for origin in the Pacific. Cytologia 53: 551-560.

Grayum MH. 1990. Evolution and phylogeny of the Araceae. Ann. Mo. Bot. Gard. 77: 628–697.

Gogoi R, Borah S. 2013. Two new species and a new record for Colocasia (Araceae: Colocasieae) from Arunachal Pradesh. Northeast India. Gard. Bull. Singapore 65: 27-37.

Guerra M. 1986. Citogenetica de Angiospermas coletadas en Pernambuco. Brazilian Journal of Genetics 9: 21–40.

Hore A. 1980. Structure and behaviour of chromosomes as an aid to the study of phylogeny of Umbelliferae with special reference to the tribe Apieae (Ammineae) and Saniculeae. Cytologia 45: 389–402.

Huang SF, Zhao ZF, Chen ZY, Chen SJ, Huang XX.1989. Chromosome counts on one hundred species and infraspecific taxa. Acta Bot. Austr. Sin. 5: 161-176.

Ismed Wahidi and Nursyahra. 2018. Starch and Karyotype Study of Taro (Colocasia esculenta L.) from West Sumatra, Indonesia. IJSRP. 8: 256-260.

Ivancic A, Lebot V. 1999. Botany and genetics of New Caledonian wild taro, Colocasia esculenta. Pacific Sci. 53: 273-285.

Kokubugata G, Kondo K, Randall LM. 1998. Intraspecific polyploidy in Centella asiastica and their karyotypes in five populations in Australia and Japan. Chromosome Science 2: 43–46.

Kuruvilla KM, Singh A. 1981. Karyotypic and electrophoretic studies on taro and its origin.

Euphytica 30: 405-413.

Kuruvilla KM, Dutt B, Roy RP. 1989. Karyomorphological investigations on aroids of North-

Eastern Hills. J. Cytol. Genet. 24: 13-22.

Levan A, Fredya K, Sandberg AA. 1964. Nomenclature forcentromeric position chromosome. Hereditas 52: 201-220.

Li RQ. 1989. Studies on Karyotypes of Vegetables in China. Wuhan University Press, Wuhan.

Mayo SJ, Bogner J, Boyle PC. 1997. The Genera of Araceae. The Trustees, Royal Botanic Gardens, Kew.

Nauheimer L, Metzler D, Renner SS. 2012. Global history of the ancient monocot family Araceae inferred with models accounting for past continental positions and previous ranges based on fossils. New Phytol. 195: 938–950.

Okada H, Hambali GG. 1989. Chromosome behaviors in meiosis of the interspecific hybrids between Colocasia esculenta (L.) Schott and C. gigantea Hook. f. Cytologia. 54: 389-393.

Parvin S, Kabir G, Ud-Deen MM, Sarker JK. 2008. Karyotype analysis of seven varieties of taro Colocasia esculenta (L.)Schott. from Bangladesh. J. Biol. Sci. 16: 15–18.

Ramachandran K. 1978. Cytological studies on South Indian Araceae. Cytologia 43: 289-303.

Saensouk S, Saensouk P, Senavongse R. 2019. Karyological Study in Three Thailand Species of Colocasia (Araceae). Cytologia 84: 179-182.

Senavongse R, Saensouk S, Saensouk P. 2018. Comparative karyotype analysis in five strains of Colocasia esculenta (L.) Schott (Araceae) in Thailand. Cytologia 83: 169-173.

Senavongse R, Saensouk S, Saensouk, P. 2020. Karyological study of three native species of the

genus Alocasia (Araceae) in the northeast of Thailand. Nucleus 63: 81-85.

Saensouk S, Saensouk P. 2021. Karyotype analysis ofthree species of Allium (Amaryllidaceae) from Thailand. Biodiversitas 22(8): 3458-3466.

Saensouk P, Saensouk S. 2021. Diversity and cytological studies on the genus Amomum Roxb. former Elettariopsis Baker (Zingiberaceae) in Thailand. Biodiversitas 22(6): 3209-3218.

Sharma AK, Sarkar AK. 1963. Cytological analysis of different cytotypes of Colocasia antiquorum. Bull. Bot. Soc. Bengal. 17: 16-22.

Zhang CS. 1998. A preliminary study on making plant chromosomal specimens using peppermint

oil compound as pretreatmentagent. J. Wuhan Bot. Res. 16: 280-282.

Subramanian D, Munian M. 1988. Cytotaxonomical studies in South Indian Araceae. Cytologia

: 59-66.

Sreekumari MT, Mathew PM. 1989. Karyomorphology of six cultivars of taro (Colocasia esculenta Schott). New Bot. 16: 127-135.

Sreekumari MT, Mathew PM. 1991. Effect of colchicine treatment in a triploid variety of taro

(Colocasia esculenta (L.) Schott). New Bot. 18: 211-215.

Sreekumari MT, Mathew PM. 1991a. Karyomorphology of five morphotypes of taro (Colocasia esculenta (L.) Schott). Cytologia 56: 215-218.

Sreekumari MT, Mathew PM. 1991b. Karyotypically distinct morphotypes in taro (Colocasia

esculenta (L.) Schott). Cytologia 56: 399-402.

Sreekumari MT, Mathew PM. 1995. Karyotype distinction in Indian taros. J. Cytol. Genet.

: 143-149.

Stebbins GL. 1971. Chromosomal Evolution in Higher Plants. Edward Arnold, London.

Tanimoto T, Matsumoto T. 1986. Variations of morphological characters and isozyme patterns

in Japanese cultivars of Colocasia esculenta Schott and C. gigantea Hook. Jpn. J. Breed. 36: 100-111.

Zhang CS. 1998. A preliminary study on making plant chromosomal specimens using peppermint

oil compound as pretreatment agent. J. Wuhan Bot. Res. 16: 280-282.

Zhang GM, Yang ZH. 1984. Studies on chromosome numbers of main cultivars of Colocasia

esculenta in China. Acta Hort. Sin. 11: 187-190.

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