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2021-10-05

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Title:

Research frontier analysis of global crop biological breeding based on ESI

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Author(s):

Qi Shijie; et al

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Keywords:

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DOI:

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Abstract:

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²Î¿¼ÎÄÏ×/References:

£Û1£ÝÓýÖÖ£ºÊµÏÖ¿çÔ½·¢Õ¹£¬´òºÃÖÖÒµ·­ÉíÕÌ£ÛEB/OL£Ý. (2021-03-10)£Û2021-04-20£Ý. https£º//baijiahao.baidu.com/s£¿id=1693809839546724507&wfr=spider&for=pc.
£Û2£ÝÀîк££¬¹ÈÏþ·å£¬ÂíÓÐÖ¾£¬µÈ. Å©×÷Îï»ùÒòÉè¼ÆÓýÖÖ·¢Õ¹ÏÖ×´ÓëÕ¹Íû£ÛJ£Ý. ÖйúÅ©Òµ¿Æ¼¼µ¼±¨£¬2020£¬22(8)£º1-4.
£Û3£ÝIncites Essential Science Indicators £ÛEB/OL£Ý. (2019-03-10)£Û2021-04-20£Ý. http£º//help.incites.clarivate.com/incitesLiveESI/ESIGroup/indicatorsGroup/indicatorsESI/researchFro nts.html.
£Û4£ÝSauvage C£¬Segura V£¬Bauchet G£¬et al. Genome-wide association in tomato reveals 44 candidate loci for fruit metabolic traits£ÛJ£Ý. Plant Physiology£¬2014£¬165(3)£º1120-1132.
£Û5£Ývan Eeuwijk F A£¬Bustos-Korts D£¬Millet E J£¬et al. Modelling strategies for assessing and increasing the effectiveness of new phenotyping techniques in plant breeding£ÛJ£Ý. Plant Science£¬2019£¬282£º23-39.
£Û6£ÝTripathi J N£¬Ntui V O£¬Ron M£¬et al. CRISPR/Cas9 editing of endogenous banana streak virus in the B genome of Musa spp.overcomes a major challenge in banana breeding£ÛJ£Ý. Communications Biology£¬2019£¬2£º46.
£Û7£ÝJiang W Z£¬Henry I M£¬Lynagh P G£¬et al. Significant enhancement of fatty acid composition in seeds of the allohexaploid£¬Camelina sativa£¬using CRISPR/Cas9 gene editing£ÛJ£Ý. Plant Biotechnology Journal£¬2017£¬15(5)£º648-657.
£Û8£ÝWinfield M O£¬Allen A M£¬Burridge A J£¬et al. High-density SNP genotyping array for hexaploid wheat and its secondary and tertiary gene pool£ÛJ£Ý. Plant Biotechnology Journal£¬2016£¬14(5)£º1195-1206.
£Û9£ÝAllen A M£¬Winfield M O£¬Burridge A J£¬et al. Characterization of a Wheat Breeders¬ð Array suitable for high-throughput SNP genotyping of global accessions of hexaploid bread wheat (Triticum aestivum)£ÛJ£Ý. Plant Biotechnology Journal£¬2017£¬15(3)£º390-401.
£Û10£ÝHaghighattalab A£¬P¨¦rez L G£¬Mondal S£¬et al. Application of unmanned aerial systems for high throughput phenotyping of large wheat breeding nurseries£ÛJ£Ý. Plant Methods£¬2016£¬12£º35.
£Û11£ÝZaman-Allah M£¬Vergara O£¬Araus J L£¬et al. Unmanned aerial platform-based multi-spectral imaging for field phenotyping of maize£ÛJ£Ý. Plant Methods£¬2015£¬11£º35.
£Û12£ÝTattaris M£¬Reynolds M P£¬Chapman S C.A direct comparison of remote sensing approaches for high-throughput phenotyping in plant breeding£ÛJ£Ý. Frontiers in Plant Science£¬2016£¬7£º1131.
£Û13£ÝIsidro J£¬Jannink J L£¬Akdemir D£¬et al. Training set optimization under population structure in genomic selection£ÛJ£Ý. Theoretical and Applied Genetics£¬2015£¬128(1)£º145-158.
£Û14£ÝAppels R£¬Eversole K£¬Feuillet C. et al. Shifting the limits in wheat research and breeding using a fully annotated reference genome.£ÛJ£Ý. Science£¬2018£¬361(6403)£º1-13.
£Û15£ÝSu Z Q£¬Bernardo A£¬Tian B£¬et al. A deletion mutation in TaHRC confers Fhb1 resistance to Fusarium head blight in wheat£ÛJ£Ý. Nature Genetics£¬2019£¬51(7)£º1099-1105.
£Û16£ÝLiu S£¬Fan C C£¬Li J N£¬et al. A genome-wide association study reveals novel elite allelic variations in seed oil content of Brassica napus£ÛJ£Ý. Theoretical and Applied Genetics£¬2016£¬129(6)£º1203-1215.
£Û17£ÝSukumaran S£¬Dreisigacker S£¬Lopes M£¬et al. Genome-wide association study for grain yield and related traits in an elite spring wheat population grown in temperate irrigated environments£ÛJ£Ý. Theoretical and Applied Genetics£¬2015£¬128(2)£º353-363.
£Û18£ÝCui F£¬Zhang N£¬Fan X L£¬et al. Utilization of a Wheat660K SNP array-derived high-density genetic map for high-resolution mapping of a major QTL for kernel number£ÛJ£Ý. Scientific Reports£¬2017£¬7£º3788.
£Û19£ÝWen W W£¬Li D£¬Li X A£¬et al. Metabolome-based genome-wide association study of maize kernel leads to novel biochemical insights£ÛJ£Ý. Nature Communications£¬2014£¬5£º3438.
£Û20£ÝSpindel J£¬Begum H£¬Akdemir D£¬et al. Correction£ºgenomic selection and association mapping in rice (Oryza sativa)£ºeffect of trait genetic architecture£¬training population composition£¬marker number and statistical model on accuracy of rice genomic selection in elite£¬tropical rice breeding lines£ÛJ£Ý. PLoS Genetics£¬2015£¬11(6)£ºe1005350.
£Û21£ÝFeng Z Y£¬Mao Y F£¬Xu N F£¬et al. Multigeneration analysis reveals the inheritance£¬specificity£¬and patterns of CRISPR/Cas-induced gene modifications in Arabidopsis£ÛJ£Ý. Proceedings of the National Academy of Sciences of the United States of America£¬2014£¬111(12)£º4632-4637.
£Û22£ÝZhou H B£¬Liu B£¬Weeks D P£¬et al. Large chromosomal deletions and heritable small genetic changes induced by CRISPR/Cas9 in rice£ÛJ£Ý. Nucleic Acids Research£¬2014£¬42(17)£º10903-10914.
£Û23£ÝSvitashev S£¬Young J K£¬Schwartz C£¬et al. Targeted mutagenesis£¬precise gene editing£¬and site-specific gene insertion in maize using Cas9 and guide RNA£ÛJ£Ý. Plant Physiology£¬2015£¬169(2)£º931-945.
£Û24£ÝLi Z S£¬Liu Z B£¬Xing A Q£¬et al. Cas9-guide RNA directed genome editing in soybean£ÛJ£Ý. Plant Physiology£¬2015£¬169(2)£º960-970.
£Û25£ÝZhang Y£¬Liang Z£¬Zong Y A£¬et al. Efficient and transgene-free genome editing in wheat through transient expression of CRISPR/Cas9 DNA or RNA£ÛJ£Ý. Nature Communications£¬2016£¬7£º12617.
£Û26£ÝLiang Z£¬Chen K L£¬Li T D£¬et al. Efficient DNA-free genome editing of bread wheat using CRISPR/Cas9 ribonucleoprotein complexes£ÛJ£Ý. Nature Communications£¬2017£¬8£º14261.
£Û27£ÝSvitashev S£¬Schwartz C£¬Lenderts B£¬et al. Genome editing in maize directed by CRISPR-Cas9 ribonucleoprotein complexes£ÛJ£Ý. Nature Communications£¬2016£¬7£º13274.
£Û28£ÝZong Y A£¬Wang Y P£¬Li C£¬et al. Precise base editing in rice£¬wheat and maize with a Cas9-cytidine deaminase fusion£ÛJ£Ý. Nature Biotechnology£¬2017£¬35(5)£º438-440.
£Û29£ÝZong Y A£¬Song Q N£¬Li C£¬et al. Efficient C-to-T base editing in plants using a fusion of nCas9 and human APOBEC3A£ÛJ£Ý. Nature Biotechnology£¬2018£¬36(10)£º950-953.
£Û30£ÝÕÅٻٻ£¬ÐíÓ£¬ÌïÊØ壬µÈ. ÀûÓÃCRISPR/Cas9½éµ¼µÄµ¥¼î»ù±à¼­¼¼Êõ´´ÖÆ¿¹³ý²Ý¼ÁÎ÷¹ÏÐÂÖÖÖÊ£ÛJ£Ý. Öйú¹Ï²Ë£¬2019£¬32(8)£º219-220.
£Û31£ÝEndo M£¬Mikami M£¬Endo A£¬et al. Genome editing in plants by engineered CRISPR-Cas9 recognizing NG PAM£ÛJ£Ý. Nature Plants£¬2019£¬5(1)£º14-17.
£Û32£ÝAraki M£¬Ishii T.Towards social acceptance of plant breeding by genome editing£ÛJ£Ý. Trends in Plant Science£¬2015£¬20(3)£º145-149.
£Û33£ÝHartung F£¬Schiemann J.Precise plant breeding using new genome editing techniques£ºopportunities£¬safety and regulation in the EU£ÛJ£Ý. The Plant Journal£¬2014£¬78(5)£º742-752.
£Û34£ÝMacovei A£¬Sevilla N R£¬Cantos C£¬et al. Novel alleles of rice eIF4G generated by CRISPR/Cas9-targeted mutagenesis confer resistance to Rice tungro spherical virus£ÛJ£Ý. Plant Biotechnology Journal£¬2018£¬16(11)£º1918-1927.
£Û35£ÝOrtigosa A£¬Gimenez-Ibanez S£¬Leonhardt N£¬et al. Design of a bacterial speck resistant tomato by CRISPR/Cas9-mediated editing of SlJAZ2£ÛJ£Ý. Plant Biotechnology Journal£¬2019£¬17(3)£º665-673.
£Û36£ÝUeta R£¬Abe C£¬Watanabe T£¬et al. Rapid breeding of parthenocarpic tomato plants using CRISPR/Cas9£ÛJ£Ý. Scientific Reports£¬2017£¬7£º507.
£Û37£ÝKlap C£¬Yeshayahou E£¬Bolger A M£¬et al. Tomato facultative parthenocarpy results from SlAGAMOUS-LIKE 6 loss of function£ÛJ£Ý. Plant Biotechnology Journal£¬2017£¬15(5)£º634-647.
£Û38£ÝTang L£¬Mao B G£¬Li Y K£¬et al. Knockout of OsNramp5 using the CRISPR/Cas9 system produces low Cd-accumulating indica rice without compromising yield£ÛJ£Ý. Scientific Reports£¬2017£¬7£º14438.
£Û39£ÝMorineau C£¬Bellec Y£¬Tellier F£¬et al. Selective gene dosage by CRISPR-Cas9 genome editing in hexaploid Camelina sativa£ÛJ£Ý. Plant Biotechnology Journal£¬2017£¬15(6)£º729-739.
£Û40£ÝLi L£¬Zhang Q£¬Huang D F.A review of imaging techniques for plant phenotyping£ÛJ£Ý. Sensors£¬2014£¬14(11)£º20078-20111.
£Û41£ÝKirchgessner N£¬Liebisch F£¬Yu K£¬et al. The ETH field phenotyping platform FIP£ºa cable-suspended multi-sensor system£ÛJ£Ý. Functional Plant Biology£¬2017£¬44(1)£º154.
£Û42£ÝAndrade-Sanchez P£¬Gore M A£¬Heun J T£¬et al. Development and evaluation of a field-based high-throughput phenotyping platform£ÛJ£Ý. Functional Plant Biology£¬2013£¬41(1)£º68-79.
£Û43£ÝZhang X H£¬Huang C L£¬Wu D£¬et al. High-throughput phenotyping and QTL mapping reveals the genetic architecture of maize plant growth£ÛJ£Ý. Plant Physiology£¬2017£¬173(3)£º1554-1564.
£Û44£ÝChang Z Y£¬Chen Z F£¬Wang N£¬et al. Construction of a male sterility system for hybrid rice breeding and seed production using a nuclear male sterility gene£ÛJ£Ý. Proceedings of the National Academy of Sciences of the United States of America£¬2016£¬113(49)£º14145-14150.
£Û45£ÝChen L T£¬Liu Y G.Male sterility and fertility restoration in crops£ÛJ£Ý. Annual Review of Plant Biology£¬2014£¬65£º579-606.
£Û46£ÝZhang D F£¬Wu S W£¬An X L£¬et al. Construction of a multicontrol sterility system for a maize male-sterile line and hybrid seed production based on the ZmMs7 gene encoding a PHD-finger transcription factor£ÛJ£Ý. Plant Biotechnology Journal£¬2018£¬16(2)£º459-471.
£Û47£ÝAn X L£¬Dong Z Y£¬Tian Y H£¬et al. ZmMs30 encoding a novel GDSL lipase is essential for male fertility and valuable for hybrid breeding in maize£ÛJ£Ý. Molecular Plant£¬2019£¬12(3)£º343-359.
£Û48£ÝCasta¢‹eda-¦Blvarez N P£¬Khoury C K£¬Achicanoy H A£¬et al. Global conservation priorities for crop wild relatives£ÛJ£Ý. Nature Plants£¬2016£¬2£º16022.
£Û49£ÝKhoury C K£¬Amariles D£¬Soto J S£¬et al. Comprehensiveness of conservation of useful wild plants£ºan operational indicator for biodiversity and sustainable development targets£ÛJ£Ý. Ecological Indicators£¬2019£¬98£º420-429.
£Û50£ÝBohra A£¬Jha U C£¬Adhimoolam P£¬et al. Cytoplasmic male sterility (CMS) in hybrid breeding in field crops£ÛJ£Ý. Plant Cell Reports£¬2016£¬35(5)£º967-993.

ÏàËÆÎÄÏ×/References:

[1]¶Å¾ü,¿Ü¼ÑÀö,ÕÔÅàÑô.»ùÓÚCiteSpaceµÄÎÒ¹ú¾«×¼·öƶÑо¿ÈȵãÓëÇ°ÑØÇ÷ÊÆ·ÖÎö[J].½­ËÕÅ©Òµ¿Æѧ,2019,47(19):6.
¡¡Du Jun,et al.Analysis of hotspots and frontier trends of China¬ðs precision poverty alleviation research based on CiteSpace[J].Jiangsu Agricultural Sciences,2019,47(19):6.
[2]ÅË¿Æ,ÕÂÓñÆ»,ÁõÁ¶.»ùÓÚÎÄÏ×¼ÆÁ¿µÄ²ÝµØÌ°Ò¹¶êÑо¿ÈȵãÓëÇ°ÑØ·ÖÎö[J].½­ËÕÅ©Òµ¿Æѧ,2023,51(14):22.
¡¡Pan Ke,et al.Research hotspot and frontier analysis of Spodoptera frugiperda based on bibliometrics[J].Jiangsu Agricultural Sciences,2023,51(19):22.
[3]³ÂÐÀÓî,¹ùæÃ,´÷ºì¾ý,µÈ.Å©ÒµÁìÓò¿Æ¼¼¾ºÕùÁ¦Óë̬ÊÆ·ÖÎö·½·¨Ñо¿¡ª¡ªÒÔ³¤Èý½ÇµØÇøÐóÄÁÊÞÒ½ÁìÓòΪÀý[J].½­ËÕÅ©Òµ¿Æѧ,2023,51(23):236.
¡¡Chen Xinyu,et al.Study on scientific and technology competitiveness and situation analysis methods in agricultural field¡ªTaking the field of animal husbandry and veterinary medicine in the Yangtze River Delta region as an example[J].Jiangsu Agricultural Sciences,2023,51(19):236.

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