بررسی اثر نور آبی و قرمز بر بیان ژن CRY1و HY5در دانه رست گیاه کلزا (Brassica napus L.)
محورهای موضوعی : زیست شناسی سلولی تکوینی گیاهی و جانوری ، تکوین و تمایز ، زیست شناسی میکروارگانیسم
کلید واژه: کلزا, نور آبی, نور قرمز, ژن کریپتوکروم1, ژن HY5,
چکیده مقاله :
در چند دهه اخیر، تحقیقات متعددی برای ارزیابی بیان ژنهای موثر از نور آبی و قرمز، در گیاهان،انجام گرفته است. هدف از این پژوهش، بررسی اثرات نور آبی و قرمز بر میزان بیان ژن کریپتوکروم 1 و HY5 در دانهرستهای گیاه کلزا،بود. دانهرستهای کلزا در شرایط یکنواخت محیطی، و سپس 5 روز تحت تیمار نور آبی (به مدت 2 ساعت، 4 ساعت، 8 ساعت) و نور قرمز (به مدت 2 ساعت ،4 ساعت ،8 ساعت) قرار گرفتند و تفاوت طول هیپوکوتیل در تیمارهای مختلف، مشاهده شد و میزان بیان ژن کریپتوکروم 1 توسط کنیک RT-PCR (Semiquantitative Reverse Transcription-Polymerase Chain Reaction) بررسی شد، همچنین میزان بیان ژن HY5 به موازات بیان ژن CRY1، توسط تکنیک (Quantitative real-time) qRT-PCR مورد بررسی قرار گرفت. نتایج بررسی های اثر تیمار نور آبی بر گیاهان شاهد و تحت تیمار، نشان داد که نور آبی قادر به تنظیم بیان ژن کریپتوکروم1، و در نتیجه کنترل ریخت زایی نوری(فتومورفوژنز) در گیاه (Brassica napus L.) شد به طوری که در 8 ساعت تیمار با نور آبی، بیشترین میزان بیان ژن کریپتوکروم 1، مشاهده شد، البته سطح بیان ژن HY5نیز در تیمار نور آبی به بالاترین حد خود رسید که نتیجه آن بیشترین میزان منع کردن از بلند شدن هیپوکوتیل در این گروه خاص بود.
In recent decades, several researches have been done on plants in order to evaluate the expression of genes influenced by blue and red light. The aim of present study is analyzing the effects of blue and red light on the expression of CRY1 and HY5 genes in rape seedlings. These seedlings were placed in steady environmental conditions and then in blue light treatment (2, 4 or 8 hr) and in red light treatment (2, 4 or 8 hr) for 5 days, and the variation of hypocotyl length in various treatments was scrutinized and the expression level of CRY1 gene was analyzed by Semi-quantitative Reverse Transcription-Polymerase Chain Reaction (RT-PCR) technique. Also, the amount of HY5 gene expression along with CRY1 gene expression was examined by Quantitative Real-time-Polymerase Chain Reaction (qRT-PCR) technique. Results of studying the effects of blue light treatment on control and treated plants showed that the blue light is capable to adjust expressing CRY1 gene and thus to control photomorphogenesis in rape (Brassica napus L.) plants, so that in an 8-hour treatment with blue light, we observed the highest level of CRY1 expression. Of course, the expression level of HY5 gene reached to its highest point, which resulted in maximum inhibition of hypocotyl elongation in this special group.
[1] Bae G; Choi G; 2008Decoding of light signals by plant phytochromes and their interacting proteins. Annual Review Of Plant Biology. 59: 281-311.
[2] Barrero J; Downie A; Xu Q; Gubler F; 2014; A role for barley cryptochrome1 in light regulation of grain dormancy and germination. Plant Cell. 26: 1094–1104.
[3] Beggs C; Wellmann E; 1994; Photocontrol of flavonoid biosynthesis. Photomorphogenesis In Plant. 78: 733–52.
[4] Blum D; Elzenga J; Linnemeyer P; 1992; Stimulation of growth and ion uptake in bean leaves by red and blue light.Plant Physiol. 100: 1968–75.
[5] Boylan M; Quail P; 1983; Oat phytochrome is biologically active in transgenic tomatoes. Plant Cell.1:765–73.
[6] Chen M; Chory J; Fankhauser C; 2004; Light signal transduction in higher plants. Anna Rev Genet. 38: 87-117.
[7] Cosgrove D; 1994; Photomodulation of growth. Photobiology in plants. 78: 631–58
[8] Dehesh K; Franci C; Parks B; Seeley K; Short T; 1993; Arabidopsis HY8 locus encodes phytochrome A. Plant Cell. 5: 1081–88.
[9] Downs R; 1995; Photoreversibility of leaf and hypocotyl elongation of dark grown red kidney bean seedlings. Plant Physiol. 30: 468–73.
[10]Duek P; Elmer M; Oosten V; Fankhauser C; 2004; The degradation of HFR1, a putatire bHLH class transcription factor involved in light signaling, is regulated by phosphorylation and requires, cop1. Current Biology. 14: 2296-2301.
[11]Fankhauserl C., Ulm R; 2011; Light-regulated interactions with SPA proteins underlie cryptochrome-mediated gene expression. Gene and Development. 25: 1004–1009.
[12]Goto N; Yamamoto K; Watanabe M; 1993; Action spectra for inhibition of hypocotyl growth of wild-type plants and of the hy2 long-hypocotyl mutant of Arabidopsis thaliana L. Photochem. Photobiol. 57: 867–71.
[13]Gyula P; Schäfer E; Nagy F; 2003; Light perception and signalling in higher plants. Current Opinion in Plant Biology. 6: 446-452.
[14]Holm M; Mal G; Qu L; Deng X; 2002; Two interacting bZIP proteins are direct targets of COP1-mediated control of light dependent gene expression in Arabidopsis. Gene Dev. 16: 1247-1259.
[15]Jing, Y., Zhang, D.(2013). Arabidopsis chromatin remodeling factor pickle interacts with transcription factor HY5 to regulate hypocotyl cell elongation. The Plant Cell. 25: 1 242-256.
[16]Jordan E; Hatfield P; Hondred D; Talon M; Zeevaart J; Vierstra R; 1995; Phytochrome A overexpression in transgenic tobacco: correlation of dwarf phenotype with high concentrations of phytochrome in vascular tissue and attenuated gibberellin levels. Plant Physiol. 107: 797–805.
[17]Khurana J; Dasgupta V; Laxmi A; Kumar D; Paul L; 2004; Light control of plant development by phytchromes. Proccedings of The India National Science Academy. 70: 370-411.
[18]Khurana J; Chattergee M; Sharma P; Kumar D; 2009; Blue light sensing cryptochromes: structure-function perspective and their genetic manipulation in plants. Proceedings of the Indian National science Academy. 79: 81-103.
[19]Khush G; 2001; Green vevolution: the way forward. Nature Reviews Genetics. 2: 815-822.
[20]Koornneef M; Cone J; Dekens R; Herne E; Spruit C; Kendrick R; 1985; Photomorphogenic responses of long hypocotyl mutants of tomato.J. Plant Physiol. 120: 153–65.
[21]Koornneef M; Rolf E; Spruit C; 1980; Genetic control of light inhibited hypocotyl elongation in Arabidopsis thaliana (L.) Heynh. Z. Plant Physiol. 100: 147–60.
[22]Lopez E; Kobayashi M; Sakurai A; Kamiya Y; Kendrick R; 1995; Phytochrome, giberellins, and hypocotyl growth. Plant Physiol. 107: 131–40.
[23]Lumsden P; 1991; Circadian rhythms and phytochrome. Plant Mol. Biol. 42: 351–71.
[24]Mancinelli A; 1994; The physiology of phytochrome action. Photomorphogenesis in Plants. 78: 211–70.
[25]Nemhauser J; Mockler T; Chory J; 2004; Interdependency of brassinosteroid and auxin signaling in Arabidopsis. PLOS Biology. 16: 144-156.
[26]Muangprom A; Osborn T; 2004; Characterization of dwarf gene in Brassica rapa, including the identification of a candidate gere. Theoretical and Applied Genetic. 108: 1378-1384.
[27]Nemhauser J; Mockler T; Chory J; 2004; Interdependency of brassinosteroid and auxin signaling in Arabidopsis. Plos Biology. 16: 144-156.
[28]Oelze H; Schopfer P; 1971; Demonstration of a threshold regulation by phytochrome in the photomodulation of longitudinal growth of the hypocotyl of mustard seedlings (Sinapis alba L.). Planta. 100: 167–75.
[29]Osterlund M; Hardtke C; Deng X; 2000; Targeted destabilization of HY5 during light-regulated development of Arabidopsis. Nature. 405: 462-466.
[30]Oyam T; Shimura Y; Okada K; 1997; The Arabidopsis HY5 gene encodes a bZIP protein that regulates stimulus- induced development of root and hypocotyl. Gene Dev. 11: 2983-2995.
[31]Reed J; Nagatani A; Elich T; Fagan M; Chory J; 1991; Phytochrome A and phytochrome B have overlapping but distinct functions in Arabidopsis development. Photobiol. 66: 732-741.
[32]Reed J; Nagpal P; Chory J; 1992; Searching for phytochrome mutants. Photochem.Photobiol. 56: 833–38.
[33]Ross J; Willis C; Gaskin P; Reid J; 1992; Shoot elongation in Lathyrus elongates L.: giberellin levels in light and darkgrown tall and dwarf seedlings. Planta. 187: 10–13.
[34]Somers D; Sharrock R; Tepperman J; Quail P; 1991; The hy3 long hypocotyl mutant of Arabidopsis is deficient in phytochrome B. Plant Cell 3: 1263–74
[35]Sullivan J; Deny X; 2003; From seed to seed: the role of photoreceptors in Arabidopsis development. Developmental Biology. 260: 289-297.
[36]Wall J; Johnson C; 1983; An analysis of phytochrome action in the ‘high irradiance response. Planta. 159: 387–97.
[37]Wang H; Gen L; Zhao H; Deng X; 2001; Direct interaction of Arabidopsis cryptochromes with COP1 in light control development. Science 294:154-158.
[38]Whitelam G; Harberd P; 1994; Action and function of phytochrome family members revealed through the study of mutant and transgenic plants. Plant Cell Environ. 17: 615–25.
[39]Yang H; Wu Y; Tang R; Liu D; Cashmore A; 2000; The C Termini of Arabidopsis Cryptochromes Mediate a Constitutive Light Response. Plant Cell. 5: 815–827.
[40]Yu X; Liu H; Klejnot J; Lin C; 2010; The cryptochrome blue light receptors in the Arabidopsis. The American Society of Plant Biologists. 10:27-39.