Scientia Agricultura Sinica ›› 2015, Vol. 48 ›› Issue (7): 1262-1276.doi: 10.3864/j.issn.0578-1752.2015.07.02

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS • Previous Articles     Next Articles

Spatiotemporal Expression Pattern Analysis of NAM Transcription Factors Gpc-1 and Gpc-2 in Bread Wheat Cultivar Chinese Spring During Grain Filling

WU Dan1, DONG Jian1,2, YAO Yan-jie1, ZHAO Wan-chun1, GAO Xiang1,2   

  1. 1College of Agronomy, Northwest A&F University, Yangling 712100, Shaanxi
    2Wheat Engineering Research Center of Shaanxi Province/Breeding Research Center of New Wheat Variety in Shaanxi Province, Yangling 712100, Shaanxi
  • Received:2014-11-24 Online:2015-04-01 Published:2015-04-01

RichHTML

4

PDF

837

Abstract:

【Objective】The objective of this experiment is to study the roles of no apical meristem (NAM) transcription factors Gpc-1 and Gpc-2 in early senescence and nutrient remobilization to the grain of bread wheat. 【Method】 Their spatiotemporal expression patterns were investigated during the grain-filling stage in wheat cultivar Chinese Spring. Their temporal expression dynamics were studied in penultimate leaf, flag leaf, peduncle, glume, rachis and the kernel using quantitative real time polymerase chain reaction (qRT-PCR). And the relative expression level was quantified using Pfaffl method with normalization against multiple verified reference genes. Applying mRNA in situ hybridization, the spatial expression pattern was explored in post-anthesis flag leaf, peduncle and the kernel only with digoxin-labeled oligonucleotide probes which were specifically targeting 5′ or 3′ untranslated regions (UTRs) of Gpc-1 and Gpc-2. 【Result】 Contrary to a previous report, the functional TaNAM-B1 rather than its dysfunctional paralog was found in Chinese Spring, and its nucleotide sequence was identical with the wild-type TtNAM-B1 in T. turgidum TaNAM-B2 and TaNAM-A1 were the highest in flag leaf among five NAM genes.TaNAM-A1, TaNAM-B1, TaNAM-B2 and TaNAM-D2 were expressed in all studied tissues before anthesis, whereas TaNAM-D1 was expressed only since the ?rst-?owering date. TaNAM-A1 exhibited the distinct expression patterns among the tissues. Its transcript abundance began to decline in penultimate leaf, rachis and the kernel at 15 DAA, which was preceded that in flag leaf (25 DAA) and other tissues. The transcription levels of TaNAM-B1 and TaNAM-D2 kept increasing till the late filling stage (25 DAA or 30 DAA) in most organisms except for advanced declines of TaNAM-B1 and TaNAM-D2 in the grain and the glume, respectively.(25 DAA) and the peduncle (20 DAA). Unlike other genes, a consistent growth until 25 DAA and 30DAA in transcript abundance of TaNAM-D1 was observed. 【Conclusion】 In conclusion, Gpc-1 and Gpc-2were closely associated with mineral translocation in the grain; however, no obvious relationship between five NAM genes and the PCD in wheat grain was observed. And the discrepant temporal expression dynamics suggested that their functions were not identical. In addition, the potential effect of these genes on senescence in vegetative tissues was still elusive. Combined with previous findings, it was proposed that Gpc-1 and Gpc-2 may directly regulate nutrient remobilization only or in parallel with the senescence during grain filling. The expression level of TaNAM-B2 decreased from 15DAA in most tested tissues other than the flag leaf var.dicoccoides. All the results showed that Gpc-1 and Gpc-2 were all widely expressed in studied tissues with the exception of the root in which only the transcript of Gpc-1was detected. The outcomes of mRNA in situ hybridization indicated that all five genes shared cell-type specificities. To be specific, no transcripts were distributed in leaf epidermal cells, pericarp and the seed coat; however, they mainly aggregated in leaf mesophyll cells, aleurone layer, embryo, and the tissues responsible for the mineral element transport (vascular bundle, pigment strand, nucellar projection and the transfer cell) in grain, in which the highest expression level was observed in embryo. In addition, lower expression level was detected in the peduncle and leaf vascular bundle as well. The results of qRT-PCR showed that the temporal expression dynamics of Gpc-1 and Gpc-2 differed upon the organs and the genes. According to the Ct value, TaNAM-D2 was expressed less than other genes in all tested tissues. And the most abundant gene in wheat kernel was TaNAM-D1,whereas that in peduncle, glume and the rachis was TaNAM-B2. Besides, the expression levels of

Key words: Triticum aestivum, grain filling, senescence, nutrient remobilization, expression pattern, regulation

[1]    孟凡花, 魏幼璋. 水稻中铁的含量及其生物有效性研究进展. 西北农林科技大学学报: 自然科学版, 2004, 32(2): 73-77.
Meng F H, Wei Y Z. Progress of iron content and bioavailability of rice. Journal of Northwest Sci-tech University of Agriculture and Forest: Natural Science Edition, 2004, 32(2): 73-77. (in Chinese)
[2]    Mozumdar A, Liguori G. Persistent increase of prevalence of metabolic syndrome among U.S. adults: NHANES III to NHANES 1999–2006. Diabetes Care, 2011, 34 (1): 216-219.
[3]    Lee H, Lee J, Hwang S, Kim S, Chin H J, Han J S, Heo J N. Potassium intake and the prevalence of metabolic syndrome: The korean national health and nutrition examination survey 2008–2010. PLoS ONE, 2013, 8(1):e55106.
[4]    Uauy C, Distelfeld A, Fahima T, Blechl A, Dubcovsky J. A NAC gene regulating senescence improves grain protein, zinc, andiron content in wheat. Science,2006, 314(5803): 1298-1301.
[5]    Distelfeld A, Korol A, Dubcovsky J, Uauy C, Blake T, Fahima T. Colinearity between the barley grain protein content (GPC) QTL on chromosome arm 6HS and the wheat Gpc-B1 region. Molecular Breeding,2008, 22(1): 25-38.
[6]    Jamar C, Loffet F, Frettinger P, Ramsay L, Fauconnier M L, Jardin P D. Nam-1gene polymorphism and grain protein content in hordeum. Journal of Plant Physiology, 2009, 167(6): 497-501.
[7]    Asplund L, Bergkvist G, Leino M W, Westerbergh A, Weih M. Swedish spring wheat varieties with the rare high grain protein allele of NAM-B1 differ in leaf senescence and grain mineral content.PLoS ONE,2013, 8(3): e59704.
[8]    Cantu D, Pearce S P, Distelfeld A, Christiansen M W, Uauy C, Akhunov E, Fahima T, Dubcovsky J. Effect of the down-regulation of the high Grain Protein Content (GPC) genes on the wheat transcriptome during monocarpic senescence. BMC Genomics,2011, 12: 492-508.
[9]    Avni R, Zhao R, Pearce S, Jun Y, Uauy C, Tabbita F, Fahima T, Slade A, Dubcovsky J, Distelfeld A. Functional characterization of GPC-1 genes in hexaploid wheat. Planta, 2014, 239(2): 313-324.
[10]   Waters B M, Uauy C, Dubcovsky J, Grusak M A. Wheat (Triticum aestivum) NAM proteins regulate the translocation of iron, zinc, and nitrogen compounds from vegetative tissues to grain. Journal of Experimental Botany, 2009, 60(15): 4263-4274.
[11]   Paolacci A R, Tanzarella O A, Porceddu E, Ciaffi M. Identification  and validation of reference genes for quantitative RT-PCR normalization in wheat. BMC Molecular Biology, 2009, 10: 11-37.
[12]   Vandesompele J, Preter K D, Pattyn F, Poppe B, Roy N V, Paepe A D, Speleman F. Accurate normalization of real-time quantitative RT-PCR data by geometric averaging of multiple internal control genes. Genome Biology, 2002, 3(7): research0034.
[13]   Pfaffl M W. A new mathematical model for relative quantification in real-time RT-PCR. Nucleic Acids Research,2001, 29(9): 2002-2007.
[14]   Long X Y, Wang J R, Ouellet T, Rocheleau H, Wei Y M, Pu Z E, Jiang Q T, Lan X J, Zheng Y L. Genome-wide identification      and evaluation of novel internal control genes for Q-PCR based transcript normalization in wheat. Plant Molecular Biology,2010, 74: 307-311.
[15]   Buchner P, Parmar S, Kriegel A, Carpentier M, Hawkesford M J. The sulfate transporter family in wheat: Tissue-specific gene expression in relation to nutrition. Molecular Plant,2009, 3(2): 374-389.
[16] Asplund L, Hagenblad J, Leino M W. Re-evaluating the history of the wheat domestication gene NAM-B1 using historical plant material. Journal of Archaeological Science,2010, 37(9): 2303-2307.
[17]   Hagenblad J, Asplund L, Balfourier F, Ravel C, Leino M W. Strong presence of the high grain protein content allele of NAM-B1 in fennoscandian wheat. Theoretical and Applied Genetics,2012, 125(8): 1677-1686.
[18]   Stomph T J, Choi E Y, Stangoulis J C R. Temporal dynamics in wheat grain zinc distribution: Is sink limitation the key? Annals of Botany, 2011, 107(6): 927-937.
[19]   Baloglu M C, Oz M T, Oktem H A, Yucel M. Expression analysis   of TaNAC69-1 and TtNAMB-2, wheat NAC family transcription  factor genes under abiotic stress conditions in durum wheat  (Triticum turgidum). Plant Molecular Biology Reporter,2012, 30(5): 1246-1252.
[20] Saeedipour S, Moradi F. Validation of suitable reference genes for expression studies in different pilocarpine-induced models of mesial temporal lobe epilepsy. Agricultural Science,2011,3(3): 81-92.
[21]   Farooq M, Bramley H, Palta J A, Siddique K H M. Heat stress in wheat during reproductive and grain-filling phases. Critical Reviews in Plant Sciences,2011, 30(6): 491-507.
[22]   Bahrani A, Abad H H S, Aynehband A. Nitrogen remobilization in wheat as influenced by nitrogen application and post-anthesis water deficit during grain filling. African Journal of Biotechnology,2011, 10(52): 10585-10594.
[23]   Lobell D B, Sibley A, Ortiz-Monasterio J I. Extreme heat effects   on wheat senescence in India. Nature Climate Change,2012, 2: 186-189.
[24]   Christiansen M W, Gregersen P L. Members of the barley NAC transcription factor gene family show differential co-regulation with senescence-associated genes during senescence of flag leaves. Journal of Experimental Botany, 2014,65(14): 4009-4022.
[25]   Van Doorn W G, Woltering E J. Senescence and programmed cell death: Substance or semantics? Journal of Experimental Botany,2004, 55(406): 2147-2153.
[26]   Glenn M, Moshen M N. Increasing the supply of sulphur increases the grain zinc concentration in bread and durum wheat // Department of Plant Sciences, UC Davis, California, USA, 2009: The International Plant Nutrition Colloquium XVI. [2014-10-04]. https://escholarship. org/uc/item/43k2r1h8.
[27]   Welch R M, Shuman L. Micronutrient nutrition of plants. Critical Reviews in Plant Sciences,1995, 14(1): 49-82.
[28]   Peck A W, McDonald G K, Graham R D. Zinc nutrition influences the protein composition of flour in bread wheat (Triticum aestivum L.). Journal of Cereal Science,2008, 47(2): 266-274.
[29]   McDonald G K, Genc Y, Lewis J, Graham R D. Relationships between zinc and other nutrients in wheat grain // Cakmak Ismail, Istanbul, Turkey, May 24-26, 2007: Zinc Crops 2007 [2014-10-04]. http://www.researchgate.net/publication/242264942_Relationships_between_Zinc_and_Other_Nutrients_in_Wheat_Grain.
[30]   Andersson A, Johansson E, Oscarson P. Nitrogen redistribution from the roots in post-anthesis plants of spring wheat. Plant and Soil,2005, 269: 321-332.
[31]   Garnett T P, Graham R D. Distribution and remobilization of iron and copper in wheat. Annals of Botany,2005, 95: 817-826.
[32]   Simpson R J, Lambers H, Dalling M J. Nitrogen redistribution during grain growth in wheat (Triticum aestivum L.). Plant Physiology,1983, 71: 7-14.
[33]   Peoples M B, Dalling M J. The interplay between proteolysis and amino acid metabolism during senescence and nitrogen reallocation // Nooden L D, LeopoldA C. Senescence and Aging in Plants. San Diego: Academic Press,1988: 181-217.
[34]   Feller U, Anders I, Mae T. Rubiscolytics: Fate of rubisco after its enzymatic function in a cell is terminated. Journal of Experimental Botany,2008, 59(7): 1615-1624.
[35]   Young T E, Gallie D R. Programmed cell death during endosperm development. Plant Molecular Biology, 2000, 44: 283-301.
[36]   Domínguez F, Cejudo F J. Programmed cell death (PCD): An essential process of cereal seed development and germination. Frontiers in Plant Science, 2014, 5: 366-376.
[37]   Delorme Vr G R, McCabe P F, Kim D J, Leaver C J. A matrix metalloproteinase gene is expressed at the boundary of senescence and programmed cell death in cucumber. Plant Physiology,2000, 123(3): 917-927.
[38]   Wollaston V B, Earl S, Harrison E, Mathas E, Navabpour S, Page T, Pink D. The molecular analysis of leaf senescence-a genomics approach. Plant Biotechnology Journal,2003, 1(1): 3-22.
[39]   O'Brien T P, Sammut M E, Lee J W, Smart M G. The vascular system of the wheat spikelet. Australian Journal of Plant Physiology,1985, 12(5): 487-511.
[40]   Zee S Y, O'Brien T P. A special type of tracheary element associated with 'xylem discontinuity' in the floral axis of wheat. Australian Journal of Biological Sciences, 1970, 23(4): 783-791.
[41]   Pearson J N, Renge Z, Jenner C F, Graham R D. Transport of zinc and manganese to developing wheat grains. Physiologia Plantarum, 1995, 95(3): 449-455.
[42]   Oparka K J, Gates P J. Ultrastructure of the developing pigment strand of rice (Oryza sativa L.) in relation to its role in solute transport. Protoplasma, 1982, 113: 33-43.
[43]   Wu B, Andersch F, Weschke W, Weber H, Beckera J S. Diverse accumulation and distribution of nutrient elements in developing wheat grain studied by laser ablation inductively coupled plasma mass spectrometry imaging. Metallomics,2013,5(9): 1276-1284.
[44]   Brouns F, Hemery Y, Price R, Anson N M. Wheat aleurone: Separation, composition, health aspects, and potential food use. Critical Reviews in Food Science and Nutrition, 2012, 52: 553-568.
[45]   Singh S P, Vogel-Mikuš K, Ar?on I, Vavpeti? P, Jeromel L, Pelicon P, Kumar J, Tuli R. Pattern of iron distribution in maternal and filial tissues in wheat grains with contrasting levels of iron. Journal of Experimental Botany, 2014, 64(11): 3249-3260.
[46]   Ozturka L, Yazicia M A, Yucelb C, Torunb A, Cekicc C, Bagcid A, Ozkanb H, Braune H J, Sayersa Z, Cakmak I. Concentration and localization of zinc during seed development and germination in wheat. Physiologia Plantarum, 2006, 128: 144-152.
[47]   Patrick J W, Offler C E. Post-sieve element transport of sucrose in developing seed. Australian Journal of Plant Physiology, 1995, 22: 681-702.
[48]Li Z, Peng J, Wen X, Guo H. Gene network analysis and functional studies of senescence-associated genes reveal novel regulators of Arabidopsis leaf senescence. Journal of Integrative Plant Biology, 2012, 54(8): 526-539.
[1] LI XuFei,YANG ShengDi,LI SongQi,LIU HaiNan,PEI MaoSong,WEI TongLu,GUO DaLong,YU YiHe. Analysis of VlCKX4 Expression Characteristics and Prediction of Transcriptional Regulation in Grape [J]. Scientia Agricultura Sinica, 2023, 56(1): 144-155.
[2] FENG XiangQian,YIN Min,WANG MengJia,MA HengYu,CHU Guang,LIU YuanHui,XU ChunMei,ZHANG XiuFu,ZHANG YunBo,WANG DanYing,CHEN Song. Effects of Meteorological Factors on Quality of Late Japonica Rice During Late Season Grain Filling Stage Under ‘Early Indica and Late Japonica’ Cultivation Pattern in Southern China [J]. Scientia Agricultura Sinica, 2023, 56(1): 46-63.
[3] SONG SongQuan,LIU Jun,TANG CuiFang,CHENG HongYan,WANG WeiQing,ZHANG Qi,ZHANG WenHu,GAO JiaDong. Research Progress on the Physiology and Its Molecular Mechanism of Seed Desiccation Tolerance [J]. Scientia Agricultura Sinica, 2022, 55(6): 1047-1063.
[4] FANG HaoYuan, YANG Liang, WANG HongZhuang, CAO JinCheng, REN WanPing, WEI ShengJuan, YAN PeiShi. Effects of Cross-Ventilation System on Physiology and Production Performance of Beef Cattle in Summer [J]. Scientia Agricultura Sinica, 2022, 55(5): 1025-1036.
[5] ZHANG Jie,JIANG ChangYue,WANG YueJin. Functional Analysis of the Interaction Between Transcription Factors VqWRKY6 and VqbZIP1 in Regulating the Resistance to Powdery Mildew in Chinese Wild Vitis quinquangularis [J]. Scientia Agricultura Sinica, 2022, 55(23): 4626-4639.
[6] YaTing JIA,HuiHui HU,YaJun ZHAI,Bing ZHAO,Kun HE,YuShan PAN,GongZheng HU,Li YUAN. Molecular Mechanism of Regulation by H-NS on IncFⅡ Plasmid Transmission of Multi-drug Resistant Chicken Escherichia coli [J]. Scientia Agricultura Sinica, 2022, 55(18): 3675-3684.
[7] ZHANG YunXiu,JIANG Xu,WEI ChunXue,JIANG XueQian,LU DongYu,LONG RuiCai,YANG QingChuan,WANG Zhen,KANG JunMei. The Functional Analysis of High Mobility Group MsHMG-Y Involved in Flowering Regulation in Medicago sativa L. [J]. Scientia Agricultura Sinica, 2022, 55(16): 3082-3092.
[8] GUAN RuoBing,LI HaiChao,MIAO XueXia. Commercialization Status and Existing Problems of RNA Biopesticides [J]. Scientia Agricultura Sinica, 2022, 55(15): 2949-2960.
[9] XIAO ShanShan, ZHANG YiFei, YANG KeJun, MING LiWei, DU JiaRui, XU RongQiong, SUN YiShan, LI WeiQing, LI GuiBin, LI ZeSong, LI JiaYu. Effects of Intercropping with Different Maturity Varieties on Grain Filling, Dehydration Characteristics and Yield of Spring Maize [J]. Scientia Agricultura Sinica, 2022, 55(12): 2294-2310.
[10] LÜ ZhiWei,DU Kang,ZHOU ZhiGuo,ZHAO WenQing,HU Wei,ZHAO JianMing,ZHU SuQin,WANG YouHua. Research on Senescence Process and Suitable Indicators of Maize Ear Leaves [J]. Scientia Agricultura Sinica, 2022, 55(12): 2311-2323.
[11] JIN MengJiao,LIU Bo,WANG KangKang,ZHANG GuangZhong,QIAN WanQiang,WAN FangHao. Light Energy Utilization and Response of Chlorophyll Synthesis Under Different Light Intensities in Mikania micrantha [J]. Scientia Agricultura Sinica, 2022, 55(12): 2347-2359.
[12] YANG ShengDi,MENG XiangXuan,GUO DaLong,PEI MaoSong,LIU HaiNan,WEI TongLu,YU YiHe. Co-Expression Network and Transcriptional Regulation Analysis of Sulfur Dioxide-Induced Postharvest Abscission of Kyoho Grape [J]. Scientia Agricultura Sinica, 2022, 55(11): 2214-2226.
[13] HU DanDan,LI RongFa,LIU Peng,DONG ShuTing,ZHAO Bin,ZHANG JiWang,REN BaiZhao. Mixed-Cropping Improved on Grain Filling Characteristics and Yield of Maize Under High Planting Densities [J]. Scientia Agricultura Sinica, 2021, 54(9): 1856-1868.
[14] DU Yu,FAN XiaoXue,JIANG HaiBin,WANG Jie,FENG RuiRong,ZHANG WenDe,YU KeJun,LONG Qi,CAI ZongBing,XIONG CuiLing,ZHENG YanZhen,CHEN DaFu,FU ZhongMin,XU GuoJun,GUO Rui. MicroRNA-Mediated Cross-Kingdom Regulation of Apis mellifera ligustica Worker to Nosema ceranae [J]. Scientia Agricultura Sinica, 2021, 54(8): 1805-1820.
[15] WANG Yong,LI SiYan,HE SiRui,ZHANG Di,LIAN Shuai,WANG JianFa,WU Rui. Prediction and Bioinformatics Analysis of BLV-miRNA Transboundary Regulation of Human Target Genes [J]. Scientia Agricultura Sinica, 2021, 54(3): 662-674.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备09089781号-30
Copyright 2018 © Editorial office of Scientia Agricultura Sinica
Tel: 86-010-82106279    E-mail: zgnykx@mail.caas.net.cn
Supported by Beijing Magtech Co.Ltd