Document Type : Research Article

Authors

1 Ferdowsi University of Mashhad

2 Ferdowsi University Of Mashhad

3 Citrus and Subtropical Fruits Research Center, Agricultural Research Education and Extension Organization

Abstract

Introduction: Among citrus producing provinces in the country, Mazandaran province ranks first with 1.88 million tons yields. Orange is one of the horticulture crop which is sensitive to low temperature stress. Low temperature stress is one of the abiotic stresses that its negative effects is the disruption of the electron transfer process through the thylacoid membrane. Actived oxygen radicals can be reacted with methyl unsaturated fatty acid groups and produce active fatty acid radicals. Very reactive formed radicals are capable of initiating lipid peroxidation chain reactions, which leads to the accumulation of free oxygen radicals that can lead to degradation of plant chlorophylls and membrane peroxidation and disruption of photosynthesis, accumulation of ROS, damage to cell membranes, destruction of plant pigments and nucleic acids. Plants can resist against low temperature stress by water saving and utilization of antioxidant system. The amount of free proline in many plants increases in response to environmental stresses such as cold and drought stress, and this physiological response can affect the resistance of the herbal substance under stress. Due to the diversity of citrus native genotypes in the country, the aim of this study was to determine the tolerance of native genotypes against low temperature stress in north of the country.
Materials and Methods: This experiment was conducted during the years 2015_2016 at the Citrus and Semi-Traditional Fruit Research Center in Ramsar with the aim of determining the low temperature tolerance of six native pseudo orange genotypes at 4 temperature levels (3, 0,- 3,- 6), compared to The test was carried out by Unsho and Sensitive Persian Lime (low temperature stress). Therefore, in this study, the vulnerability to low-stress conditions in controlled environmental conditions was compared with that of temperature treatments (3, 0, _3 and -6 degrees Celsius) in six genotypes of native pseudo-orange (number 1-6) sensitive cultivar (Persian lime) and resistant cultivars (Unsho) were investigated. This experiment was conducted as a factorial in a completely randomized design. The results of analysis of variance showed that temperature, genotype and interaction of these two treatments were significant in lipid peroxidation, proline, antioxidant capacity, ion leakage, hydroxylation, chlorophyll a and chlorophyll content. The temperature of the device began to decrease at a temperature of 6 ° C. The temperature of the device was 1 ° C / hour, after which the samples were kept at the specified temperatures for 3 hours and at the end of this period (3 Clock) sampling was performed to measure the traits. Accordingly, the leaf aquaculture was calculated by calculating the leaf area using a leaf surface gauge device. Ionic leakage measurements were also investigated using the method of the conversation and Meg Donald method. The presence of genotypes under cold stress led to an increase in malondialdehyde. In these conditions, due to increased oxidative activity, the accumulation of antioxidant compounds such as superoxide dismutase, glutathione peroxidase and catalase increased. The data obtained from this research were based on factorial experiment in a completely randomized design with three replications of analysis of variance and then averages were compared by Tukey test at 5% level using SAS software.
Results: Orange is a low temperature stress sensitive horticultural plant. Therefore, in this study, the vulnerability to low temperature stress in controlled environment (3, 0, 3- and -6 degrees Celsius) in six native poderotal genotypes (No.1-6) sensitive cultivars (Persian Liam) and resistant cultivars (Unsho) were studied. This experiment was conducted as a factorial in a completely randomized design. The results of analysis of variance showed that temperature, genotype and interaction of these two treatments were significant in lipid peroxidation, proline, antioxidant capacity, ion leakage, hydroxylation, chlorophyll a and chlorophyll content. Meanwhile, soluble carbohydrate was only affected by the simple factor of genotype. No effects on chlorophyll b and carotenoid pigments were significant. The highest incidences (99.33%), ion leakage (91.63%) and lipid peroxidation reaction (with a mean of 3.33 μg / kg of fresh leaf weight) were recorded in sensitive lambspeed control at 6 °C. In contrast, the highest amount of proline (32.01 mg / g leaf weight) and antioxidant capacity (73.36%) was recorded in the control group at 3 °C. Among the native pseudo-orange genotypes, in this study, different reactions were also observed under low-temperature stress conditions. Accordingly, after the control of the bird, the native pseudo-orange genotype number one was better than the one under temperature decrease. However, in most of the studied orange genotypes, in most of the destructive traits, the native pseudo-orange genotype number 6 was in the same statistical position or close to the sensitive Peninsula. The presence of genotypes under cold stress led to an increase in malondialdehyde. In these conditions, due to increased oxidative activity, the accumulation of antioxidant compounds such as superoxide dismutase, glutathione peroxidase and catalase increased.

Keywords

1- Afshary H., Zahedy R., Parvaneh T., and ZadeBaghery M. 2014. Effect of salicylic acid on proline soluble sugar and electrolyte leakage in two apricot’ cultivar under cold stress. Journal of Crops Improvement (Journal of agriculture). 16:127-138 (in Persian).
2- Annual statistics. Horticultural Crops. 2014. Ministry of Jahad-Keshavarzi Iran. (In Persian)
3- Arji. E., Hasani B., and Ghamarniya H. 2015. Effecs of deficit irrigation on growth characteristics and the quantity and quality of Golden Delicious apples. Journal of Horticulture Science. 29:610-620 (in Persian).
4- Arnon A.N. 1967. Method of extraction of chlorophyll in the plants. Agronomy Journal. 23:112-121.
5- Ashraf M., and Foolad M.R. 2007. Role of glycine betaine and proline in improving plant abiotic stress resistance. Enviro. Exp. Bot.59:206-216.
6- Bandyopadhyay U., Das D., and Banerjee R.K. 1999. Reactive oxygen species: Oxidative damage and pathogenesis. Curr. Sci. India. 77:658-666.
7- Bartolozzi F., Mencuccini M., and Fontanazza G. 2001. Enhancement of frost tolerance in olive shoots in vitro by cold acclimation and sucrose increase in the culture medium. Biomed. Life. Sci. 67:299-302.
8- Bates l S., Waldren R.P., and Tears I.D. 1973. Rapid determination of free proline for water stress studies. Plant Soil, 39:205-207.
9- Campos P., Quartin V., Ramalho J.C., and Nunes M.A. 2003. Electrolyte leakage and lipid degradation account for cold sensitivity inleaves of Coffea sp. Plants journal of Plant Physiology. 160: 238-292.
10- Close TJ. 1997. Dehydrins: a commonalty in the response of plantsto dehydration and low temperature. Physiology of Plant. 100: 291-296.
11- Fatahimoghadam J., Kiaeshkevarian M., and Tajvar Y. 2012. Investigation of Naringin Content and Antioxidant Activity in 14 Citrus Fruit Varieties in Response to Freezing Stress, Plant Production Technology,12:11-25. (in Persian with English abstract).
12- Flexas J., Badger M., Chow W.S., Medrano H., and Osmond C.B. 1999. Analysis of the relative increase in photosynthetic O2 uptake when photosynthesis in grapevine leaves is inhibited following low night temperatures and or water stress. Plant. Physiol. 121:675-684.
13- Fotouhi Ghazvini R., Baghbanha M.R., Hatamzadeh A., and Heidari M. 2008. Effect of water stress on freezing tolerance of Mexican lime (Citrus aurantifolia L.) seedling. Hort. Environ. Botechnol. 49:267-280.
14- Fuleki F., and Francis J.F. 1986. Quantitative method for anthocyanin determination of total anthocyanin and degradation index for cranberry Juice. Journal of Food Science. 33: 78-83.
15- Gao J.C., Wang H. X., and Li X. X. 2010. Relationship between soluble proteins, MDA, andjujube (Ziziphus mauritiana) tree cold hardiness. Beifang Yuanyi (Northern Horticulture). 23: 18-20.
16- Hincha DK., and Schmitt JM. 1992. Freeze-thaw injury and cryoprotectionof thylakoid membranes. In Water and Life Edited by: Somero GN, Osmond CB, Bolis CL. Berlin: Springer: 1992:316-337.
17- Karimi R., Ershadi A., Asnaashari M., and Mashhadiakbarboojar M. 2015. Seasonal variation in the content of soluble protein, total phenol and MDA and Their relationship with cold tolerance of vine varieties. Agriculture Crops Management. 16:999-1013. (in Persian).
18- Kavikishore P.B., Sangam S., Amrutha R.N., Laxmi P.S., Naidu K.R., Rao S., Reddy K.J., Therianppan P., and Sreenivasulu N. 2005. Regulation of proline biosynthesis, degradation, uptake and transport in higher plants: Its implications in plant growth.Curr.Sci.88:424-438.
19- Kirakosyan A., Seymour E., Kaufman P.B., Warber S., Bolling S., and Chang S.C. 2003. Antioxidant Capacity of Polyphenolic Extracts from Leaves of Crataegus laevigata and Crataegus monogyna (Hawthorn) Subjected to Drought and Cold Stress. J. Agric. Food Chem. 51(14): 3973–3976.
20- Leng P., and Qi J.X. 2003. Effect of anthocyanin on David peach (Prunus davidiana Franch) under low temperature stress. Sci. Hortic-Amsterdam. 97: 27-39
21- Mashayekhy K., Sadeghy H., Akbarpoor V., Atashy S., Ghasemy Y., and Moosavy Zadeh S. 2014. Changes in leaf carbohydrates and fruit throughout the growing season in the nectarines Redgold the weather conditions .Gorgan, Journal of Horticultural Science (agricultural science and technology). 9.28:1-9. (in Persian)
22- McCollum T.G., and McDonald R.E. 1991. Electrolyte leakage, respiration and ethylene production as indices of chilling injury in grapefruit. Horticulture Science, 26: 1191-1192.
23- Omokolo N.D., Tsala N.G., and Djocgoue P.F. 1996. Changes in carbohydrate, amino acid and phenol content in cocoa pods from three clones after infection with Phythphthora megakarya Bra. and Grif. Annals of Botany.77:153–158.
24- Qiujie D., Bin Y.S., Xiao Z., and Wang Z. 1996. Flooding induce membrane damage, lipid oxidation and activated oxygen generation in Corn leaves. Plant Soil. 179: 261-268
25- Ranney T.G., Bassuk and Whitlow T.H. 1991. Osmotic adjustment and solute constituents in leaves and roots of- waterstressed cherry trees. Am. Hort. Sci. 116: 684-688.
26- Sala J.M., and Lafuente M.T. 2000. Catalase enzyme activity is related to tolerance of mandarin. Fruits to chilling. Postharvest Biol. Tec. 20: 81–89.
27- Salahvarzi Y., Davarinezhad GH., Tehranifar A., Nemati H., and Nezami A. 2010. Physiochemical responses of six pomegranate cultivars from Razavi Khorasan under freezing stress. Iranian Journal of Horticultural Science and Technology.11: 217-230.(in Persian ).
28- Shanker A.K., and Venkateswarlu B. 2011. Abiotic Stress in Plants Mechanisms and Adaptations. InTech Croatia 428 p.
29- Tajvar Y., Fotouhi Ghazvini R., HamidOughly Y., and HassanSajedi R. 2011. Physiological and biochemical responses of Page mandarin on citrange rootstock to low temperature stress. Plant Biology. 3.9:1-12 (in Persian with English abstract).
30- Tajvar Y., FotouhiGhazvini R., HamidOughly Y., and Hasan Sajed R. 2012. A Study of Rootstock and Low Temperature Effects on Antioxidant Reaction of Page Mandarin. Iranian Journal of Horticultural Science and Technology. 12.3:307-316. (in Persian)
31- Zhang J., Wu X., Niu R., Liu Y., Liu N., Xu W., and Wang Y. 2012.Cold resistance evaluation in 25 wild grape species.Vitis. 51(4): 153-160.
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