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Contribution of sugarcane crop wild relatives in the creation of improved varieties in Mauritius

Published online by Cambridge University Press:  16 January 2019

D. Santchurn*
Affiliation:
Mauritius Sugarcane Industry Research Institute (MSIRI), MCIA, Réduit, Mauritius
M.G.H. Badaloo
Affiliation:
Mauritius Sugarcane Industry Research Institute (MSIRI), MCIA, Réduit, Mauritius
M. Zhou
Affiliation:
South African Sugarcane Research Institute (SASRI), Mt Edgecombe, South Africa
M.T. Labuschagne
Affiliation:
University of the Free State, Bloemfontein South Africa
*
*Corresponding author. E-mail: [email protected]

Abstract

Significant genetic diversity for sucrose and fibre percentages exists in the species that served as the foundation of present day sugarcane cultivars. However, information is lacking worldwide on the recent contributions of sugarcane crop wild relatives (mainly Saccharum, Erianthus and Miscanthus wild species) in developing new varieties. There is renewed interest in using those relatives for creating new varieties to use as a dedicated bioenergy crop with higher fibre. This study focuses on past data analysis of sugarcane breeding in Mauritius with the objective to assess the efficiency in exploiting sugarcane wild relatives since 1970s to date. Pedigree analyses helped retrace the parentages of elite inter-specific hybrids reaching the final stages of selection. The studies confirmed the high prevalence of a few ‘wonder canes’ (successful hybrids with wild canes produced in the beginning of last century) among the ancestors of Mauritian varieties. Among the wild relatives, eight Saccharum spontaneum, two S. robustum, and one Erianthus clones were involved in generating elite genotypes worth evaluating at the advanced variety trial stages. A few early generation hybrids were released in the past for industrial exploitation, the latest one being M 1002/02 in 2016, with sugar as the primary output. Recent studies on the biomass potential and fibre yield of inter-specific hybrids are giving promising results, which expands the horizon in the use of sugarcane wild relatives for the generation of novel type of sugarcane varieties for multiple end-uses.

Type
Research Article
Copyright
Copyright © NIAB 2019 

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References

Annicchino, W, Ometto, JGS, Coury, R, Jacob, J, Brunelli, A, Zillo, JL, Balbo, M and Neto, PB (1987) Board of Directors of Copersucar - Presentation preface. In Proceedings of Copersucar International Sugarcane Breeding Workshop. Copersucar Technology Center, Piracicaba-SP, Brazil, iiiii.Google Scholar
Arceneaux, G (1967) Cultivated sugarcanes of the world and their botanical derivation. International Society of Sugar Cane Technologists 12: 844854.Google Scholar
Bischoff, KP, Gravois, KA, Reagan, TE and Hawkins, GL (2008) Registration of ‘L79-1002’ sugarcane. Journal of Plant Registrations 2: 211217.Google Scholar
Bremer, G (1961) Problems in breeding and cytology of sugarcane. Euphytica 10: 5978.Google Scholar
Chong, BF and O'Shea, MG (2012) Developing sugarcane lignocellusic biorefineries: opportunities and challenges. Biofuels 3: 307319.Google Scholar
Daniels, J and Roach, BT (1987) Taxonomy and evolution. In: Heinz, DJ (ed.) Sugarcane Improvement Through Breeding, Amsterdam, Netherlands: Elsevier, 11: 784.Google Scholar
Gao, Y-J, Liu, X-H, Zhang, R-H, Zhou, H, Liao, J-X, Duan, W-X and Zhang, G-M (2015) Verification of progeny from crosses between sugarcane (Saccharum spp.) and an intergeneric hybrid (Erianthus arundinaceus×Saccharum spontaneum) with molecular makers. Sugar Tech: An International Journal of Sugar Crops & Related Industries 17: 3135.Google Scholar
Giamalva, M, Clark, S and Stein, J (1985) Conventional vs high fiber sugarcane. Journal of the American Society of Sugar Cane Technologists 4: 106109.Google Scholar
Głowacka, K, Ahmed, A, Sharma, S, Abbott, T, Comstock, JC, Long, SP and Sacks, EJ (2016) Can chilling tolerance of C4 photosynthesis in Miscanthus be transferred to sugarcane? GCB Bioenergy 8: 407418.Google Scholar
Jessup, RW (2009) Development and status of dedicated energy crops in the United States. In Vitro Cellular and Developmental Biology Plant 45: 282289.Google Scholar
Legendre, BL and Burner, DM (1995) Biomass production of sugarcane cultivars and early-generation hybrids. Biomass and Bioenergy 8: 5561.Google Scholar
Matsuoka, S, Kennedy, AJ, Santos, EGD, Tomazela, AL and Rubio, LCS (2014) Energy cane: its concept, development, characteristics, and prospects. Advances in Botany 2014: 113.Google Scholar
Mukherjee, SK (1950) Search for wild relatives of sugarcane in India. International Sugar Journal 52: 261262.Google Scholar
Mukherjee, SK (1957) Origin and distribution of Saccharum. Botanical Gazette 17: 97106.Google Scholar
Ramdoyal, K and Badaloo, MGH (2007) An evaluation of interspecific families of different nobilized groups in contrasting environments for breeding novel sugarcane clones for biomass. International Society of Sugar Cane Technologists 26: 625632.Google Scholar
Roach, BT (1972) Nobilization of sugarcane. International Society of Sugarcane Technologists 14: 206216.Google Scholar
Santchurn, D and Badaloo, MGH (2017) Evaluation of high biomass sugarcane varieties in marginal areas for energy production. Mauritius Research Council (MRC) report under Unsolicited Research Grant Scheme. 166 p.Google Scholar
Santchurn, D, Ramdoyal, K, Badaloo, MGH and Labuschagne, MT (2012) From sugar industry to cane industry: investigations on multivariate data analysis techniques in the identification of different high biomass sugarcane varieties. Euphytica 185: 543558.Google Scholar
Santchurn, D, Ramdoyal, K, Badaloo, MGH and Labuschagne, MT (2014) From sugar industry to cane industry: evaluation and simultaneous selection of different types of high biomass canes. Biomass and Bioenergy 61: 8292.Google Scholar
Shen, WK, Deng, HH, Li, QW, Yang, ZD and Jiang, ZD (2014) Evaluation of BC1 and BC2 from the crossing Erianthus arundinaceus with Saccharum for resistance to sugarcane smut caused by Sporisorium scitamineum. Tropical Plant Pathology 39: 368373.Google Scholar
Sreenivasan, TV (1987) Cytogenetics. In: Heinz, DJ (ed.) Sugarcane Improvement Through Breeding. New York: Elsevier, pp. 211253.Google Scholar
Stevenson, GC (1965) Genetics and Breeding of Sugar Cane. London, UK: Longman.Google Scholar
Wang, L-P, Jackson, PA, Lu, X, Fan, Y-H, Foreman, JW, Chen, X-K, Deng, H-H, Fu, C, Ma, L and Aitken, KS (2008) Evaluation of sugarcane × Saccharum spontaneum progeny for biomass composition and yield components. Crop Science 48: 951961.Google Scholar