基于文献计量的主要作物QTL定位研究动态分析

doi:10.13998/j.cnki.issn1002-1248.2018.11.001

Abstract

Abstract: The development of quantitative trait locus (QTL) mapping in crops is helpful to understand the genetic basis of the complex traits, mine and clone genes, and provide strong support for marker-assisted selection breeding and molecular design breeding. Taking SCI-E database of Web of Science as data source, this paper collected the QTL mapping papers of twelve main crops cited during 2003 to 2017, and used bibliometrics to analyze the features of paper numbers, compare research emphasis of different countries and authors, reveal the development status of research in major crops in the past fifteen years, clear the top institutions, groups and main stream journals, explore the research hotspots, identify international status, clarify the existing problems and predict the development status, so as to offer some reference for the researchers in the future.

CLC Number:

G250

JIANG Wei, ZHANG Qi, PAN Rui, WANG Qi, ZHANG Wenying. Trends of QTL Mapping Research in Major Crops Based on Bibliometrics[J]., 2018, 30(11): 5-9.

References

[1] Korstanje R, Paigen B.From QTL to gene: the harvest begins[J].Nature Genetics,2002,31(3):235-236.
[2] Paterson A H, Lander E S, Hewitt J D, et al.Resolution of quantitative traits into Mendelian factors by using a complete linkage map of restriction fragment length polymorphisms[J].Nature,1988,335(6192):721-726.
[3] Andersen S B, Torp A M.QTL mapping in crop plants. In:Jain S M, Ahloowalia S F, Brar D S (eds) Molecular techniques in crop improvement[M].Dordrecht: Springer,2002:541-562.
[4] Xu Y B.Molecular Plant Breeding[M]. London:CABI, 2010.
[5] Xu Y, Li P C, Yang Z F, et al.Genetic mapping of quantitative trait loci in crops[J].The Crop Journal,2017,5(2):175-184.
[6] Ye J, Yang Y H, Chen B, et al.An integrated analysis of QTL mapping and RNA sequencing provides further insights and promising candidates for pod number variation in rapeseed (Brassica napus L.)[J].BMC Genomics, 2017,18(1):71.
[7] Xu K N, Xu X, Fukao T, et al.Sub1A is an ethylene-response-factor-like gene that confers submergence tolerance to rice[J].Nature,2006,442(7 103):705-708.
[8] Buckler E S, Holland J B, Bradbury P J, et al.The genetic architecture of maize flowering time[J].Science,2009, 325(5 941):714-718.
[9] Wang X L, Wang H W, Liu S X, et al.Genetic variation in ZmVPP1 contributes to drought tolerance in maize seedlings[J].Nature Genetics,2016,48(10):1 233-1 241.
[10] Nadeem M A, Nawaz M A, Shahid M Q, et al.DNA molecular markers in plant breeding: currentstatus and recent advancements in genomic selection and genome editing[J].Biotechnology & Biotechnological Equipment,2018,32(2):261-285.
[11] 袁建霞,董瑜,张博,等.从文献计量角度分析作物分子标记辅助育种国际发展态势[J].科学观察,2012,7(2):24-32.
[12] Garrido-Cardenas J A, Mesa-Valle C, Manzano-Agugliaro F. Trends in plant research using molecular markers[J].Planta, 2018, 247(3):543-547.
[13] 卢垚,宋敏. 基于文献计量学的中国2006—2015年植物分子生物学研究态势分析[J].中国农业科技导报, 2017,19(6):10-20.
[14] Martín-Martín A, Orduna-Malea E, López-Cózar E D. A novel method for depicting academic disciplines through google scholar citations: the case of bibliometrics[J].Scientometrics,2018,114(3):1 251-1 273.
[15] Saunders T F C, Rymer B C, Mcnamara K J. A global bibliometric analysis of otolaryngology: head and neck surgery literature[J].Clinical Otolaryngology,2017,42(6):1 338-1 342.
[16] Montazerian M, Zanotto E D, Eckert H.Bibliometrics in glass and other sciences: a plea for reason[J]. International Journal of Applied Glass Science, 2017,8(3):352-359.
[17] Aleixandre-Benavent R, Aleixandre-Tudó J L, Castelló-Cogollos L, et al. Trends in scientific research on climate change in agriculture and forestry subject areas (2005-2014)[J].Journal of Cleaner Production, 2017,(147):406-418.
[18] 高懋芳,邱建军,刘三超,等. 基于文献计量的农业面源污染研究发展态势分析[J].中国农业科学,2014,47(6):1 140-1 150.
[19] 刘彬,邓秀新. 基于文献计量的园艺学基础研究发展状况分析[J].中国农业科学,2015,48(17):3504-3514.
[20] Yevide A S I, Wu B F, Khan A S, et al. Bibliometric analysis of ecosystem monitoring-related research in Africa: implications for ecological stewardship and scientific collaboration[J].International Journal of Sustainable Development & World Ecology,2016, 23(5):412-422.
[21] 杨红玉,王明元,游晓朝,等. 植物共生信号的文献计量分析[J].生态学报,2017,37(14):4 913-4 918.
[22] Salvi S, Bellotti M, Conti S, et al.The art and science of cloning QTLs in plants.In:Tuberosa R, Phillips R L, Gale M (eds) In the wake of the double helix: from the green revolution to the gene revolution[M]. Bologna:Avenue Media,2005:327-345.
[23] Mauricio R.Mapping quantitative trait loci in plants: uses and caveats for evolutionary biology[J].Nature Reviews Genetics,2001,2(5):370-381.
[24] 阮成江,何祯祥,钦佩. 中国农作物QTL定位研究的现状和进展[J].植物学报,2003,20(1):10-22.
[25] 章元明. 作物QTL定位方法研究进展[J].科学通报,2006,51(19):2 223-2 231.
[26] 戴高兴,邓国富,张迎信,等.作物动态QTL研究进展[J].中国稻米,2012,18(4):22-25.
[27] 赵振卿,顾宏辉,盛小光,等. 作物数量性状位点研究进展及其育种应用[J].核农学报,2014,28(9): 1 615-1 624.
[28] International Grains Council[WB/OL].[2015-05-12]https://www.igc.int.
[29] 任义英,崔翠,王倩,等. 油菜主花序角果密度及其相关性状的全基因组关联分析[J].中国农业科学, 2018,51(6):1 020-1 033.
[30] 杜龙岗,王美兴.玉米SLAF标记的开发及其在玉米果皮纤维素含量BSA分析中的应用[J].中国农业科学,2018,51(8):1 421-1 430.
[31] 王婷,颜蕴,刘敏娟,等.中国作物学发展现状及策略研究[J].农业展望,2015,11(12):54-61.
[32] Vilvert E, Lana M, Zander P, et al.Multi-model approach for assessing sunflower food value chain in Tanzania[J]. Agricultural Systems,2018,159:103-110.
[33] 王彩红,王磊,阮刘青. 国家自然科学基金“青年基金”资助效果评估——以水稻、小麦及玉米学科为例[J]. 农业图书情报学刊,2018,30(2):92-98.
[34] Feng B, Chen K, Cui Y R, et al.Genetic dissection and simultaneous improvement of drought and low nitrogen tolerances by designed QTL pyramiding in rice[J]. Frontiers in Plant Science,2018,(9):306.
[35] Kolmer J A, Bernardo A, Bai G H, et al.Adult plant leaf rust resistance derived from Toropi wheat is conditioned by Lr78 and three minor QTL[J].Phytopathology,2018,108(2):246-253.

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Trends of QTL Mapping Research in Major Crops Based on Bibliometrics

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