Abstract
Improvement of snap melon (Cucumis melo L. var. momordica (Roxb.) has been constrained by the lack of adequate information on genetic control of different fruit and quality characters. The study was conducted to determine gene action, heterosis and narrow sense heritability for 13 quantitative characters using 5 × 5 half diallel analysis. No interaction between genes was evident in controlling most characters suggesting the adequacy of additive-dominance model. Both additive and dominance components of genetic variance were significant in most characters however, dominance component was much higher in magnitude. Overwhelming response of over-dominance was evident for most traits. Symmetrical distribution of positive and negative alleles in parents was recorded for days to first male and female flower, and number of fruits per plant while, asymmetrical distribution was evident for 10 characters. Dominant alleles were more frequent for 11 characters while, recessive alleles were more frequent for fruit length and diameter. One gene group showing dominance was responsible for the inheritance of 11 characters; two gene groups controlled days to first male flower while, three gene groups conditioned number of fruits per plant. Narrow sense heritability for different characters was very low to medium (2.75–34.58%). Hybrid breeding can be used to improve fruit yield and quality in snap melon however, manifestation of heterosis was highly dependent on the parents and traits considered.
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References
Akrami M, Arzani A (2019) Inheritance of fruit yield and quality in melon (Cucumis melo L.) grown under field salinity stress. Sci Rep 9:49–72
AOAC (1990) Official methods of analysis of the association of official analytical chemists. 15th edition (Ed. Helrich K), AOAC, Inc., Arlington, Virginia, USA
Bates DM, Robinson RW (1995) Cucumbers, melons and water-melons. In: Smartt, J, Simmonds NW (eds) Evolution of crop plants, 2nd edn. Longman Scientific, Harlow, Essex, UK, pp 89–96
Davis BH (1976) Carotenoids. In: Goodwin TW (ed) Chemistry and biochemistry of plant pigments, vol II. Academic Press, London, pp 38–165
Dhillion NPS, Singh J, Fergany M, Monforte AJ, Sureja AK (2009) Phenotypic and molecular diversity among landraces of snap melon (Cucumis melo var. momordica) adapted to the hot and humid tropics of eastern India. Plant Genet Resour 7(3):291–300
Dubois M, Gilles KA, Hamilton JK, Robers PA, Smithy F (1951) A colorimetric method for the determination of sugar. Nature 168(4265):167–169
Frimpong A, Safo Kantanka O (2006) Inheritance of quantitative characters in tomato (Lycopersicon esculentum Mill). Pak J Biol Sci 9:2770–2776
Hallauer AR, Miranda JB (1981) Quantitative genetics in maize breeding. Iowa State Univ. Press, Ames, pp 37–52
Hayman BI (1954) The theory and analysis of diallel crosses. Genetics 39:789–809
Johnson LPV (1963) Applications of the diallel cross technique to plant breeding. In: Hanson WD, Robinson HF (eds) Statistical genetics and plant breeding, National Academy of Science- National Research Council, Washington DC, USA, pp 561–569
Johnson RA, Wichern DW (1988) Applied multivariate statistical analysis. PrenticeHall, Englewood Cliffs, NJ
José MA, Iban E, Silvia A, Pere A (2005) Inheritance mode of fruit traits in melon: heterosis for fruit shape and its correlation with genetic distance. Euphytica 144:31–38
Kaur S, Sharma SP, Sarao NK, Deol JK, Gill R, Abd-Elsalam KA, Alghuthaymi MA, Hassan MM, Chawla N (2022) Heterosis and combining ability for fruit yield, sweetness, β-carotene, ascorbic acid, firmness and fusarium wilt resistance in muskmelon (Cucumis melo L.) involving genetic male sterile lines. Horticulturae 8:82. https://doi.org/10.3390/horticulturae8010082
Maurya IB, Arvindakshan K, Sharma SK, Jalwania R (2004) Status of indigenous vegetables in southern part of Rajasthan. Acta Hort 752:193–195
Melchinger AE, Gumber RK (1998) Overview of heterosis and heterotic groups in agronomic crops. In: Larnkey KR, Staub JE (eds) Concepts and breeding of heterosis in crop plants. Crop Science Society of America, Fitchburg, pp 29–44
Metwally EI, Ahmed MEM, Al-Ballat IA, Al-abbasy UK, Konsowa AM (2015) Gene action and heritability of fruit yield and its components on melon (Cucumis melo). Egypt J Plant Breed 19:37–55
Moon SS, Verma VK, Munshi AD (2003) Heterosis for yield and its components in muskmelon (Cucumis melo L.). Ann Agric Res 24:750–754
Napolitano M, Terzaroli N, Kashyap S, Russi L, Jones-Evans E, Albertini E (2020) Exploring heterosis in melon (Cucumis melo L.). Plants 9:282. doi:https://doi.org/10.3390/plants9020282
Nerson H (2012) Heterosis in fruit and seed characters in muskmelon. Asian Aust J Plant Sci Biotechnol 6:24–27
Nyquist WE (1991) Estimation of heritability and predictions. Crit Rev Plant Sci 10:235–322
Patil DS, Musmade AM, Shirsath HK (2016) Inheritance of fruit yield and its components in muskmelon (Cucumis melo L.). Asian J Hort 11(2):280–287
Sadasivam S, Manikeam A (1996) Biochemical methods for agricultural science. Wiley Eastern Ltd., New Delhi, p 256
Saha K, Choudhary H, Mishra S, Mahapatra S (2018) Gene action of nutritional and quality traits in muskmelon (Cucumis melo L.). Int J Chem Stud 6(3):3094–3097
Singh V (2018) Genetics analysis and inheritance of different fruit characters in muskmelon (Cucumis melo L.) using different parental lines. Int J Chem 6(5):1650–1652
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The first author acknowledges the financial support rendered by the Department of Science and Technology, Government of India in the form of INSPIRE FELLOWSHIP to carry out this research work.
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The first author has received research support from Department of Science and Technology, Government of India but other authors did not receive fund to carry out the study.
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All authors contributed significantly towards the final make-up of the paper. Conceptualisation (Pranab Hazra); Data curation (Pradipta Dutta and Arup Chattopadhyay); Formal analysis (Anirban Maji and Soham Hazra); Investigation and methodology (Pranab Hazra and Pradipta Dutta); Supervision (Pranab Hazra and Arup Chattopadhyay); Writing-original draft (Pranab Hazra); Writing-reviewing and editing (Pranab Hazra, Arup Chattopadhyay and Soham Hazra).
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Dutta, P., Hazra, P., Hazra, S. et al. Genetic expression of reproductive and fruit quality traits in snap melon (Cucumis melo var. momordica L.). Euphytica 219, 15 (2023). https://doi.org/10.1007/s10681-022-03146-1
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DOI: https://doi.org/10.1007/s10681-022-03146-1