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2020-03-15

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Title:

Research progress on transformation in fungi mediated by Agrobacterium tumefaciens

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Author(s):

Li Junxiang; et al

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Abstract:

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²Î¿¼ÎÄÏ×/References:

£Û1£ÝDunn-Coleman N£¬Wang H. Agrobacterium T-DNA£ºa silver bullet for filamentous fungi?£ÛJ£ÝNature Biotechnology£¬1998£¬16(9)£º817-818.
£Û2£ÝBundock P£¬Den Dulk-Ras A£¬Beijersbergen A£¬et al. Trans-kingdom T-DNA transfer from Agrobacterium tumefaciens to Saccharomyces cerevisiae£ÛJ£Ý. EMBO Journal£¬1995£¬14(13)£º3206-3214.
£Û3£ÝPiers K L£¬Heath J D£¬Liang X£¬et al. Agrobacterium tumefaciens-mediated transformation of yeast£ÛJ£Ý. Proceedings of the National Academy of Sciences£¬1996£¬93(4)£º1613-1618.
£Û4£Ýde Groot M J A£¬Bundock P£¬Hooykaas P J J£¬et al. Agrobacterium tumefaciens-mediated transformation of filamentous fungi£ÛJ£Ý. Nature Biotechnology£¬1998£¬16(9)£º839-842.
£Û5£ÝMichielse C B£¬Hooykaas P J J£¬van den Hondel C A£¬et al. Agrobacterium-mediated transformation as a tool for functional genomics in fungi£ÛJ£Ý. Current Genetics£¬2005£¬48(1)£º1-17.
£Û6£ÝTzfira T£¬Citovsky V. Agrobacterium-mediated genetic transformation of plants£ºbiology and biotechnology£ÛJ£Ý. Current Opinion in Biotechnology£¬2006£¬17(2)£º147-154.
£Û7£ÝKyndt T£¬Quispe D£¬Zhai H£¬et al. The genome of cultivated sweet potato contains Agrobacterium T-DNAs with expressed genes£ºan example of a naturally transgenic food crop£ÛJ£Ý. Proceedings of the National Academy of Sciences£¬2015£¬112£º5844-5849.
£Û8£ÝYoung J M£¬Kuykendall L D£¬Mart¨ªnez-Romero E£¬et al. A revision of Rhizobium Frank 1889£¬with an emended description of the genus£¬and the inclusion of all species of Agrobacterium Conn 1942 and Allorhizobium undicola de Lajudie et al. 1998 as new combinations£ºRhizobium radiobacter£¬R. rhizogenes£¬R. rubi£¬R. undicola and R. vitis£ÛJ£Ý. International Journal of Systematic and Evolutionary Microbiology£¬2001£¬51(1)£º89-103.
£Û9£ÝLacroix B£¬Citovsky V. Transfer of DNA from bacteria to eukaryotes£ÛJ£Ý. MBio£¬2016£¬7(4)£ºe00863-00816.
£Û10£ÝKnight C J£¬Bailey A M£¬Foster G D. Investigating Agrobacterium-mediated transformation of Verticillium albo-atrum on plant surfaces£ÛJ£Ý. PLoS One£¬2010£¬5(10)£ºe13684.
£Û11£ÝMachida M£¬Asai K£¬Sano M£¬et al. Genome sequencing and analysis of Aspergillus oryzae£ÛJ£Ý. Nature£¬2005£¬438(7071)£º1157-1161.
£Û12£ÝLu J£¬Cao H£¬Zhang L£¬et al. Systematic analysis of Zn₂Cys₆ transcription factors required for development and pathogenicity by high-throughput gene knockout in the rice blast fungus£ÛJ£Ý. PLoS Pathogens£¬2014£¬10(10)£ºe1004432.
£Û13£ÝKilaru S£¬Steinberg G. Yeast recombination-based cloning as an efficient way of constructing vectors for Zymoseptoria tritici£ÛJ£Ý. Fungal Genetics and Biology£¬2015£¬79£º76-83.
£Û14£ÝLaniri G£¬Boyce K J£¬Idnurm A. Isolation of coniditional mutations in genes essential for viability of Coryptococus neoformans£ÛJ£Ý. Current Genetics£¬2017£¬63(3)£º519-530.
£Û15£ÝSidhu Y S£¬Chaudhari Y K£¬Usher J£¬et al. A suite of Gateway^¡k compatible ternary expression vectors for functional analysis in Zymoseptoria tritici£ÛJ£Ý. Fungal Genetics and Biology£¬2015£¬79£º180-185.
£Û16£ÝEngler C£¬Youles M£¬Gruetzner R£¬et al. A Golden Gate modular cloning toolbox for plants£ÛJ£Ý. ACS Synthetic Biology£¬2014£¬3(11)£º839-843.
£Û17£ÝTakken F L W£¬van Wijk R£¬Michielse C B£¬et al. A one-step method to convert vectors into binary vectors suited for Agrobacterium-mediated transformation£ÛJ£Ý. Current Genetics£¬2004£¬45(4)£º242-248.
£Û18£ÝAli S£¬Bakkeren G. Introduction of large DNA inserts into the barley pathogenic fungus£¬Ustilago hordei£¬via recombined binary BAC vectors and Agrobacterium-mediated transformation£ÛJ£Ý. Current Genetics£¬2011£¬57(1)£º63-73.
£Û19£ÝIto H£¬Fukuda Y£¬Murata K£¬et al. Transformation of intact yeast cells treated with alkali cations£ÛJ£Ý. Journal of Bacteriology£¬1983£¬153(1)£º163-168.
£Û20£Ývan den Berg M A£¬Maruthachalam K. Genetic transformation systems in fungi£¬Vol. ¢ñ & ¢ò£ÛM£Ý. Switzerland£ºSpringer£¬2015.
£Û21£ÝKunik T£¬Tzfira T£¬Kapulnik Y£¬et al. Genetic transformation of HeLa cells by Agrobacterium£ÛJ£Ý. Proceedings of the National Academy of Sciences£¬2001£¬98(4)£º1871-1876.
£Û22£ÝVijn I£¬Govers F. Agrobacterium tumefaciens mediated transformation of the oomycete plant pathogen Phytophthora infestans£ÛJ£Ý. Molecular Plant Pathology£¬2003£¬4(6)£º459-467.
£Û23£ÝKhrunyk Y£¬M¨¹nch K£¬Schipper K£¬et al. The use of FLP-mediated recombination for the functional analysis of an effector gene family in the biotrophic smut fungus Ustilago maydis£ÛJ£Ý. New Phytologist£¬2010£¬187(4)£º957-968.
£Û24£ÝGrigoriev I V£¬Nikitin R£¬Haridas S£¬et al. MycoCosm portal£ºgearing up for 1000 fungal genomes£ÛJ£Ý. Nucleic Acids Research£¬2014£¬42(D1)£ºD699-D704.
£Û25£ÝGamboa-Mel¨¦ndez H£¬Judelson H S. Development of a bipartite ecdysone-responsive gene switch for the oomycete Phytophthora infestans and its use to manipulate transcription during axenic culture and plant infection£ÛJ£Ý. Molecular Plant Pathology£¬2015£¬16(1)£º83-91.
£Û26£ÝArazoe T£¬Miyoshi K£¬Yamato T£¬et al. Tailor-made CRISPR/Cas system for highly efficient targeted gene replacement in the rice blast fungus£ÛJ£Ý. Biotechnology and Bioengineering£¬2015£¬112(12)£º2543-2549.
£Û27£ÝCairns T C£¬Studholme D J£¬Talbot N J£¬et al. New and improved techniques for the study of pathogenic fungi£ÛJ£Ý. Trends in Microbiology£¬2016£¬24(1)£º35-50.
£Û28£ÝGietz R D£¬Schiestl R H. High-efficiency yeast transformation using the LiAc/SS carrier DNA/PEG method£ÛJ£Ý. Nature Protocols£¬2007£¬2(1)£º31-34.
£Û29£ÝCatlett N L£¬Lee B N£¬Yoder O C£¬et al. Split-marker recombination for efficient targeted deletion of fungal genes£ÛJ£Ý. Fungal Genetics Reports£¬2003£¬50(1)£º9-11.
£Û30£ÝCairns T C£¬Sidhu Y S£¬Chaudhari Y K£¬et al. Construction and high-throughput phenotypic screening of Zymoseptoria tritici over-expression strains£ÛJ£Ý. Fungal Genetics and Biology£¬2015£¬79(SI)£º110-117.
£Û31£ÝIdnurm A£¬Reedy J L£¬Nussbaum J C£¬et al. Cryptococcus neoformans virulence gene discovery through insertional mutagenesis£ÛJ£Ý. Eukaryotic Cell£¬2004£¬3(2)£º420-429.
£Û32£ÝWalton F J£¬Idnurm A£¬Heitman J. Novel gene functions required for melanization of the human pathogen Cryptococcus neoformans£ÛJ£Ý. Molecular Microbiology£¬2005£¬57(5)£º1381-1396.
£Û33£ÝIdnurm A£¬Walton F J£¬Floyd A£¬et al. Identification of ENA1 as a virulence gene of the human pathogenic fungus Cryptococcus neoformans through signature-tagged insertional mutagenesis£ÛJ£Ý. Eukaryotic Cell£¬2009£¬8(3)£º315-326.
£Û34£ÝElliott C E£¬Howlett B J. Overexpression of a 3-ketoacyl-CoA thiolase in Leptosphaeria maculans causes reduced pathogenicity on Brassica napus£ÛJ£Ý. Molecular Plant-microbe Interactions£¬2006£¬19(6)£º588-596.
£Û35£ÝAleksenko A£¬Clutterbuck A J. Autonomous plasmid replication in Aspergillus nidulans£ºAMA1 and MATE elements£ÛJ£Ý. Fungal Genetics and Biology£¬1997£¬21(3)£º373-387.
£Û36£ÝKojic M£¬Holloman W K. Shuttle vectors for genetic manipulations in Ustilago maydis£ÛJ£Ý. Canadian Journal of Microbiology£¬2000£¬46(4)£º333-338.
£Û37£ÝZhu Y£¬Nam J£¬Humara J M£¬et al. Identification of Arabidopsis rat mutants£ÛJ£Ý. Plant Physiology£¬2003£¬132(2)£º494-505.
£Û38£ÝBourras S£¬Rouxel T£¬Meyer M. Agrobacterium tumefaciens gene transfer£ºhow a plant pathogen hacks the nuclei of plant and nonplant organisms£ÛJ£Ý. Phytopathology£¬2015£¬105(10)£º1288-1301.
£Û39£Ývan Attikum H£¬Bundock P£¬Hooykaas P J J. Non-homologous end-joining proteins are required for Agrobacterium T-DNA integration£ÛJ£Ý. The EMBO Journal£¬2001£¬20(22)£º6550-6558.
£Û40£ÝVan Attikum H£¬Hooykaas P J J. Genetic requirements for the targeted integration of Agrobacterium T-DNA in Saccharomyces cerevisiae£ÛJ£Ý. Nucleic Acids Research£¬2003£¬31(3)£º826-832.
£Û41£ÝSoltani J£¬van Heusden G P H£¬Hooykaas P J J. Deletion of host histone acetyltransferases and deacetylases strongly affects Agrobacterium-mediated transformation of Saccharomyces cerevisiae£ÛJ£Ý. FEMS Microbiology Letters£¬2009£¬298(2)£º228-233.
£Û42£ÝRolloos M£¬Dohmen M H C£¬Hooykaas P J J£¬et al. Involvement of Rad52 in T-DNA circle formation during Agrobacterium tumefaciens-mediated transformation of Saccharomyces cerevisiae£ÛJ£Ý. Molecular Microbiology£¬2014£¬91(6)£º1240-1251.
£Û43£ÝLuo Y£¬Chen Z£¬Zhu D£¬et al. Yeast actin-related protein ARP6 negatively regulates Agrobacterium-mediated transformation of yeast cell£ÛJ£Ý. Biomed Research International£¬2015(5)£º1-11.
£Û44£ÝOhmine Y£¬Satoh Y£¬Kiyokawa K£¬et al. DNA repair genes RAD52 and SRS2£¬a cell wall synthesis regulator gene SMI1£¬and the membrane sterol synthesis scaffold gene ERG28 are important in efficient Agrobacterium-mediated yeast transformation with chromosomal T-DNA£ÛJ£Ý. BMC Microbiology£¬2016£¬16(1)£º58.
£Û45£ÝRoberts R L£¬Metz M£¬Monks D E£¬et al. Purine synthesis and increased Agrobacterium tumefaciens transformation of yeast and plants£ÛJ£Ý. Proceedings of the National Academy of Sciences£¬2003£¬100(11)£º6634-6639.
£Û46£ÝChambers K£¬Lowe R G T£¬Howlett B J£¬et al. Next-generation genome sequencing can be used to rapidly characterise sequences flanking T-DNA insertions in random insertional mutants ofLeptosphaeria maculans£ÛJ£Ý. Fungal Biology Biotechnology£¬2014£¬1(1)£º10.
£Û47£ÝEsher S K£¬Granek J A£¬Alspaugh J A. Rapid mapping of insertional mutations to probe cell wall regulation in Cryptococcus neoformans£ÛJ£Ý. Fungal Genetics and Biology£¬2015£¬82£º9-21.
£Û48£ÝGyawali R£¬Zhao Y£¬Lin J£¬et al. Pheromone independent unisexual development in Cryptococcus neoformans£ÛJ£Ý. PLoS Genetics£¬2017£¬13(5)£ºe1006772.
£Û49£ÝDaley M£¬Knauf V C£¬Summerfelt K R£¬et al. Co-transformation with one Agrobacterium tumefaciens strain containing two binary plasmids as a method for producing marker-free transgenic plants£ÛJ£Ý. Plant Cell Reports£¬1998£¬17(6/7)£º489-496.
£Û50£ÝPadilla-Guerrero I E£¬Bidochka M J. Agrobacterium-mediated co-transformation of multiple genes in Metarhizium robertsii£ÛJ£Ý. Mycobiology£¬2017£¬45(2)£º84-89.
£Û51£ÝWang Y£¬DiGuistini S£¬Wang T C T£¬et al. Agrobacterium-meditated gene disruption using split-marker in Grosmannia clavigera£¬a mountain pine beetle associated pathogen£ÛJ£Ý. Current Genetics£¬2010£¬56(3)£º297-307.
£Û52£Ýde Boer P£¬Bronkhof J£¬Dukik K£¬et al. Efficient gene targeting in Penicillium chrysogenum using novel Agrobacterium-mediated transformation approaches£ÛJ£Ý. Fungal Genetics and Biology£¬2013£¬61£º9-14.
£Û53£ÝKrenek P£¬Samajova O£¬Luptovciak I£¬et al. Transient plant transformation mediated by Agrobacterium tumefaciens£ºprinciples£¬methods and applications£ÛJ£Ý. Biotechnology Advances£¬2015£¬33(6)£º1024-1042.
£Û54£ÝN¢idvig C S£¬Nielsen J B£¬Kogle M E£¬et al. A CRISPR-Cas9 system for genetic engineering of filamentous fungi£ÛJ£Ý. PLoS One£¬2015£¬10(7)£ºe0133085.
£Û55£ÝPohl C£¬Kiel J£¬Driessen A J M£¬et al. CRISPR/Cas9 based genome editing of Penicillium chrysogenum£ÛJ£Ý. ACS Synthetic Biology£¬2016£¬5(7)£º754-764.
£Û56£ÝSchuster M£¬Schweizer G£¬Reissmann S£¬et al. Genome editing in Ustilago maydis using the CRISPR-Cas system£ÛJ£Ý. Fungal Genetics and Biology£¬2016£¬89£º3-9.

ÏàËÆÎÄÏ×/References:

[1]ÕÅÁáÐã,ÌïæÃ,Ðíݼ,µÈ.1Öê²úÏËάËØø˿״Õæ¾ú²úÓ͹¤ÒÕµÄÓÅ»¯[J].½­ËÕÅ©Òµ¿Æѧ,2014,42(09):316.
¡¡Zhang Lingxiu,et al.Optimization of oil producing process of a strain of filamentous fungi producing cellulase[J].Jiangsu Agricultural Sciences,2014,42(03):316.
[2]ʯÎÄ»Û,°²È»,¹ùº£Ï¼,µÈ.°¢ÄªÎ÷ÁÖÔÚÅ©¸Ë¾ú½éµ¼¸ÊÀ¶ÐÍÓͲËÒÅ´«×ª»¯ÖеÄʹÓúÍÓÅ»¯[J].½­ËÕÅ©Òµ¿Æѧ,2018,46(12):58.
¡¡Shi Wenhui,et al.Application and optimization of amoxicillin in Agrobacterium-mediated genetic transformation of Brassica napus L.[J].Jiangsu Agricultural Sciences,2018,46(03):58.
[3]Ф»á,º«³¤Ö¾.Ö²Îﲡԭ˿״Õæ¾úÖÐÌÇÜÕË®½âøµÄÑо¿½øÕ¹[J].½­ËÕÅ©Òµ¿Æѧ,2024,52(8):1.
¡¡Xiao Hui,et al.Research progress of glycoside hydrolase in plant pathogenic filamentous fungi[J].Jiangsu Agricultural Sciences,2024,52(03):1.

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