The levels of antioxidant activity and vitamins can change with varying ratios of different wavelengths. This study was conducted as a pot experiment under soilless culture conditions in order to investigate the interactive effects of light supplementation and nutrition (calfomyth solution) on some qualitative traits of tomato fruit. The research was carried out as a split-plot experiment based on a completely randomized design with three light treatments including without supplementary light (control), 60% red light+40% blue light and 90% red light+10% blue light. There were two nutritional treatments including no spraying with calfomyth as commercial fertilizer and foliar application with a concentration of 2 mg/L in three replicates. According to the results, the amounts of vitamin C (16.1 mg/g FW fruit), soluble solids (12.33 mg/g FW fruit), and lycopene (2.95 mg/g FW fruit) were all uppermost by the effect of a higher percentage of red light treatment. Higher percentage of the blue light resulted in the highest leaf chlorophyll content (38.4 mg/g FW leaf), but supplementary light treatments had no significant effects on the titratable acidity. Nutrition (calfomyth foliar application) showed positive impacts on all treatment traits compared to control. Beta-carotene content was affected by none of the treatments with no significant differences. According to this research, it can be expected that the use of complementary light treatments and calfomyth foliar spray may have positive effects on most of the qualitative traits in tomato fruit (cv. 240).
Keywords: biochemical properties, tomato, optical spectra, calfomyth, antioxidant, lycopene, phytochrome
DOI: 10.25165/j.ijabe.20201305.5797

Citation: Ajdanian L, Aroiee H, Azizi M, Babaei M. Changes in biochemical properties of tomato (cv.240) affected by combination of blue/red optical spectra and Calfomyth spray (Ca and P). Int J Agric & Biol Eng, 2020; 13(5): 79–84.

biochemical properties, tomato, optical spectra, calfomyth, antioxidant, lycopene, phytochrome

Taragola N, van Lierde D, editors. Competitive strategies in the sector of greenhouse tomato production in Belgium. XXV International Horticultural Congress, Part 14: Horticultural Economics at Micro and Macro Level, International Trade and 524; 1998; pp.149–156.

Atherton J, Rudich J. The tomato crop chapman and hall. London UK, 1986; 661p.

Giovanelli G, Lavelli V, Peri C, Nobili S. Variation in antioxidant components of tomato during vine and post-harvest ripening. Journal of the Science of Food and Agriculture, 1999; 79(12): 1583–1588.

Ronen G, Cohen M, Zamir D, Hirschberg J. Regulation of carotenoid biosynthesis during tomato fruit development: expression of the gene for lycopene epsilon–cyclase is down-regulated during ripening and is elevated in the mutant Delta. The Plant Journal, 1999; 17(4): 341–351.

Curran-Celentano J, Hammond Jr B R, Ciulla T A, Cooper D A, Pratt L M, Danis R B. Relation between dietary intake, serum concentrations, and retinal concentrations of lutein and zeaxanthin in adults in a Midwest population. The American journal of clinical nutrition, 2001; 74(6): 796–802.

Dumas Y, Dadomo M, Di Lucca G, Grolier P. Effects of environmental factors and agricultural techniques on antioxidantcontent of tomatoes. Journal of the Science of Food and Agriculture, 2003; 83(5):369–382.

Thomas R L, Jen J J. Red light intensity and carotenoid biosynthesis in ripening tomatoes. Journal of Food Science, 1975; 40(3): 566–568.

Schopfer P. The control by phytochrome of the contents of ascorbic acid and dehydroascorbic acid in the mustard seedling (Sinapis alba L.). Planta, 1966; 69(2):158–177.

Alba R, Cordonnier-Pratt M-M, Pratt L H. Fruit-localized phytochromes regulate lycopene accumulation independently of ethylene production in tomato. Plant Physiology, 2000; 123(1): 363–370.

O’Carrigan A, Hinde E, Lu N, Xu X Q, Duan H, Huang G, et al. Effects of light irradiance on stomatal regulation and growth of tomato. Environmental and Experimental Botany, 2014; 98: 65–73.

Massa G D, Kim H-H, Wheeler R M, Mitchell C A. Plant productivity in response to LED lighting. HortScience, 2008; 43(7): 1951–1956.

Bukhov N, Drozdova I, Bondar V, Mokronosov A. Blue, red and blue plus red light control of chlorophyll content and CO2 gas exchange in barley leaves: Quantitative description of the effects of light quality and fluence rate. Physiologia Plantarum, 1992; 85(4): 632–638.

Evans J, Poorter H. Photosynthetic acclimation of plants to growth irradiance: The relative importance of specific leaf area and nitrogen partitioning in maximizing carbon gain. Plant, Cell & Environment, 2001; 24(8): 755–767.

Poovaiah B. Role of calcium in prolonging storage life of fruits and vegetables. Food Technol, 1986; 40(5): 86–89.

Nirupama P, Gol N B, Rao T R. Effect of postharvest treatments on physicochemical characteristics and shelf life of tomato (Lycopersicon esculentum Mill.) fruits during storage. American-Eurasian Journal of Agricultural & Environmental Sciences, 2010; 9(5): 470–479.

Ramezanian A, Rahemi M, Vazifehshenas M R. Effects of foliar application of calcium chloride and urea on quantitative and qualitative characteristics of pomegranate fruits. Scientia Horticulturae, 2009; 121(2): 171–175.

Saito S, Kano F. Influence of nutrients on the growth of solanaceous vegetable plants, their quality and the chemical composition of their fruits. 1. on the effect of different phosphate levels on the lycopene content of tomatoes. Agric Sci, 1970; 14: 233–238.

Keithly J, Yokoyama H, Gausman H. Enhanced yield of tomato in response to 2-(3, 4-dichlorophenoxy) triethylamine (DCPTA). Plant Growth Regulation, 1990; 9(2): 127–136.

Şükran D, GÜNEŞ T, Sivaci R. Spectrophotometric determination of chlorophyll-A, B and total carotenoid contents of some algae species using different solvents. Turkish Journal of Botany, 1998; 22(1): 13–18.

Helvich K. Official methods of analysis. Association of Official Analytical Chemists, 1990; pp.685–1298.

Navarro J M, Flores P, Garrido C, Martinez V. Changes in the contents of antioxidant compounds in pepper fruits at different ripening stages, as affected by salinity. Food Chemistry, 2006; 96(1): 66–73.

Urbonavičiūtė A, Pinho P, Samuolienė G, Duchovskis P, Vitta P, Stonkus A, et al. Effect of short-wavelength light on lettuce growth and nutritional quality. Sodininkystė ir Daržininkystė, 2007; 26: 157–165.

Frechijia S, Zhu J, Talbott L D, Zeiger E. Stomata from npq1, a zeaxanthin-less Arabidopsis mutant, lack a specific response to blue light. Plant and Cell Physiology, 1999; 40(9): 949–954.

Yanagi T, Okamoto K, Takita S, editors. Effects of blue, red, and blue/red lights of two different PPF levels on growth and morphogenesis of lettuce plants. International Symposium on Plant Production in Closed Ecosystems 440, 1996; pp.117–122.

Wu M-C, Hou C-Y, Jiang C-M, Wang Y-T, Wang C-Y, Chen H-H, et al. A novel approach of LED light radiation improves the antioxidant activity of pea seedlings. Food Chemistry, 2007; 101(4): 1753–1758.

Ajdanian L, Babaei M, Aroiee H. The growth and development of cress (Lepidium sativum) affected by blue and red light. Heliyon, 2019; 5(7): e02109. doi: 10.1016/j.heliyon.2019.e02109.

Smirnoff N. Ascorbic acid: metabolism and functions of a multi-facetted molecule. Current Opinion in Plant Biology, 2000; 3(3): 229–235.

Paliyath G, Murr D P, Handa A K, Lurie S. Postharvest biology and technology of fruits, vegetables, and flowers. John Wiley & Sons, 2008; 496p.

Shafiee M, Taghavi T, Babalar M. Addition of salicylic acid to nutrient solution combined with postharvest treatments (hot water, salicylic acid, and calcium dipping) improved postharvest fruit quality of strawberry. Scientia Horticulturae. 2010; 124(1): 40–45.

Shokraleh Fam S, Hajilou J, Zare F, Tabatabai S J, Naghshiband Hassani R. Effect of calcium chloride and salicylic acid on the qualitative and peculiar characteristics of prune gold drop cultivars. Journal of Food Industry Research, 2012; 22(1): 75–88. (in Farsi)

Tsantili E, Konstantinidis K, Athanasopoulos P, Pontikis C. Effects of postharvest calcium treatments on respiration and quality attributes in lemon fruit during storage. The Journal of Horticultural Science and Biotechnology, 2002; 77(4): 479–484.

Lo C, Manurung R, Esyanti R R. Enhancement of lycopene and βcarotene production in cherry tomato fruits (Solanum Lycopersicum L. var. Cerasiforme) by using red and blue light treatment. International Journal of Technical Research and Applications, 2014; 2: 7–10.

Vassey T L. Phytochrome mediated regulation of sucrose phosphate synthase activity in maize. Plant Physiology, 1988; 88(3): 540–542.

Fraser P D, Kiano J W, Truesdale M R, Schuch W, Bramley P M. Phytoene synthase-2 enzyme activity in tomato does not contribute to carotenoid synthesis in ripening fruit. Plant Molecular Biology. 1999; 40(4): 687–698.

Lois L M, Rodríguez-Concepción M, Gallego F, Campos N, Boronat A. Carotenoid biosynthesis during tomato fruit development: Regulatory role of 1-deoxy-D-xylulose 5-phosphate synthase. The Plant Journal, 2000; 22(6): 503–513.

Schofield A, Paliyath G. Modulation of carotenoid biosynthesis during tomato fruit ripening through phytochrome regulation of phytoene synthase activity. Plant Physiology and Biochemistry, 2005; 43(12): 1052–1060.

Yan Z, He D, Niu G, Zhou Q, Qu Y. Growth, nutritional quality, and energy use efficiency in two lettuce cultivars as influenced by white plus red versus red plus blue LEDs. Int J Agric & Biol Eng, 2020; 13(2): 33–40.