Highly Efficient Gene Knockout Method in Fusarium verticillioides Using Nonhomologous End-joining Deficiency

doi:10.19586/j.2095-2341.2024.0013

Current Biotechnology ›› 2024, Vol. 14 ›› Issue (3): 422-432.DOI: 10.19586/j.2095-2341.2024.0013

• Articles • Previous Articles Next Articles

Highly Efficient Gene Knockout Method in Fusarium verticillioides Using Nonhomologous End-joining Deficiency

Kaifei XI(), Chengjie LI, Yi DING, Wei GUO()

Institute of Food Science and Technology，Chinese Academy of Agricultural Sciences，Beijing 100193，China

Received:2024-01-23 Accepted:2024-02-27 Online:2024-05-25 Published:2024-06-18
Contact: Wei GUO

利用非同源末端连接缺陷构建拟轮枝镰孢菌的高效基因敲除方法

席凯飞(), 李成杰, 丁艺, 郭维()

中国农业科学院农产品加工研究所，北京 100193

通讯作者: 郭维
作者简介:席凯飞 E-mail: kaifeix@163.com；
基金资助:
国家自然科学基金项目(32072377);中国农业科学院科技创新工程所重点任务(CAAS-ASTIP-G2022-IFST-01)

Abstract

Abstract:

Fusarium verticillioides is a major pathogen responsible for maize ear and stalk rot， posing a serious threat to maize yield and quality. To investigate the gene function and improve frequency of gene knock-out in F. verticillioides， two key genes in the non-homologous end joining （NHEJ） pathway， FvKu70 and FvKu80， were individually knocked out. A comparative analysis was conducted on various aspects， including vegetative growth rate， colony morphology， conidiation， pathogenicity on maize， and knockout efficiency. The results showed that ΔFvKu70 and ΔFvKu80 had no significant differences in their morphological characteristics （mycelium morphology， vegetative growth rate， conidiation， and colony diameter） on the PDA plate. Moreover， they displayed similar pathogenicity in maize stalks compared to the wild-type strain FvLNF15-11. Notably， the frequency of homologous recombination was significantly higher in the deletion mutant strains of ΔFvKu70 and ΔFvKu80 compared to the wild type， and ΔFvKu70 exhibited the highest efficiency of homologous recombination. By successfully constructing ΔFvKu70 and ΔFvKu80 deletion mutants， it becomes feasible to rapidly and effectively achieve gene knockout mutants in F. verticillioides， thereby facilitating the study of key gene functions in this pathogen.

Key words: Fusarium verticillioides, gene knockout, homologous recombination, non-homologous end joining

摘要：

拟轮枝镰孢菌（Fusarium verticillioides）是引起玉米茎基腐病和穗粒腐病的主要病原菌之一，严重威胁玉米的产量和品质。为了深入研究拟轮枝镰孢菌致病基因的功能，对该菌中非同源末端连接（non-homologous end joining，NHEJ）途径中的2个关键基因FvKu70和FvKu80分别进行了基因敲除以创制高效的基因敲除菌株，并比较了野生型菌株和突变体菌株在营养生长速率、菌落形态、产孢量、对玉米的致病力和基因敲除效率等方面的差异。研究结果表明，FvKu70和FvKu80的基因缺失突变体与野生型FvLNF15-11相比，在PDA平板上的形态特征（如菌丝形态、生长速率、菌落直径、产孢量）没有明显差异，对玉米茎秆的致病力也类似。此外，选择尿嘧啶生物合成相关基因FvpyrG作为敲除的靶基因，分析了FvKu70或FvKu80缺失突变体菌株的同源重组效率，结果显示突变体菌株均显著高于野生型，其中ΔFvKu70的同源重组效率最高。综上所述，FvKu70或FvKu80基因缺失突变体可以快速又高效地实现拟轮枝镰孢菌的基因敲除，为进一步研究该菌的功能基因提供了技术支持。

关键词: 拟轮枝镰孢菌, 基因敲除, 同源重组, 非同源末端连接

CLC Number:

Kaifei XI, Chengjie LI, Yi DING, Wei GUO. Highly Efficient Gene Knockout Method in Fusarium verticillioides Using Nonhomologous End-joining Deficiency[J]. Current Biotechnology, 2024, 14(3): 422-432.

席凯飞, 李成杰, 丁艺, 郭维. 利用非同源末端连接缺陷构建拟轮枝镰孢菌的高效基因敲除方法[J]. 生物技术进展, 2024, 14(3): 422-432.

Figures/Tables 8

References 27

1	KAMLE M, MAHATO D K, DEVI S, et al.. Fumonisins: impact on agriculture, food, and human health and their management strategies[J/OL]. Toxins, 2019, 11(6): 328[2023-10-20]. .
2	JONES R E, HUMPHREY T C. Homologous recombination and nonhomologous end-joining repair in yeast[M]. 2nd ed. New York: Academic Press, 2019: 2715-2726.
3	HABER J E. Transpositions and translocations induced by site-specific double-strand breaks in budding yeast[J]. DNA Repair, 2006, 5(9-10): 998-1009.
4	KITO H, FUJIKAWA T, MORIWAKI A, et al.. MgLig4, a homolog of Neurospora crassa Mus-53 (DNA ligase IV), is involved in, but not essential for, non-homologous end-joining events in Magnaporthe grisea [J]. Fungal Genet. Biol., 2008, 45(12): 1543-1551.
5	XU D, ZHAO H. Pathway choice for DNA double strand break repair[J]. Sci. Sin. Vitae, 2021, 51(1): 56-69.
6	GUHA S, BHAUMIK S R. Transcription-coupled DNA double-strand break repair[J/OL]. DNA Repair, 2022, 109: 103211[2024-04-08]. .
7	D'ADDA DI FAGAGNA F, HANDE M P, TONG W M, et al.. Effects of DNA nonhomologous end-joining factors on telomere length and chromosomal stability in mammalian cells[J]. Curr. Biol., 2001, 11(15): 1192-1196.
8	PRYOR J M, CONLIN M P, CARVAJAL-GARCIA J, et al.. Ribonucleotide incorporation enables repair of chromosome breaks by nonhomologous end joining[J]. Science, 2018, 361(6407): 1126-1129.
9	NINOMIYA Y, SUZUKI K, ISHII C, et al.. Highly efficient gene replacements in Neurospora strains deficient for nonhomologous end-joining[J]. Proc. Natl. Acad. Sci. USA, 2004, 101(33): 12248-12253.
10	WEYDA I, YANG L, VANG J, et al.. A comparison of Agrobacterium-mediated transformation and protoplast-mediated transformation with CRISPR/Cas9 and bipartite gene targeting substrates, as effective gene targeting tools for Aspergillus carbonarius [J]. J. Microbiol. Meth., 2017, 135: 26-34.
11	KRAPPMANN S, SASSE C, BRAUS G H. Gene targeting in Aspergillus fumigatus by homologous recombination is facilitated in a nonhomologous end-joining-deficient genetic background[J]. Eukaryot. Cell, 2006, 5(1): 212-215.
12	MEYER V, ARENTSHORST M, EL-GHEZAL A, et al.. Highly efficient gene targeting in the Aspergillus niger kusA mutant[J]. J. Biotechnol., 2007, 128(4): 770-775.
13	VILLALBA F, COLLEMARE J, LANDRAUD P, et al.. Improved gene targeting in Magnaporthe grisea by inactivation of MgKU80 required for non-homologous end joining[J]. Fungal Genet. Biol., 2008, 45(1): 68-75.
14	CHANG P K, SCHARFENSTEIN L L, WEI Q, et al.. Development and refinement of a high-efficiency gene-targeting system for Aspergillus flavus [J]. J. Microbiol. Meth., 2010, 81(3): 240-246.
15	PÖGGELER S, KÜCK U. Highly efficient generation of signal transduction knockout mutants using a fungal strain deficient in the mammalian Ku70 ortholog[J]. Gene, 2006, 378: 1-10.
16	LI Z H, DU C M, ZHONG Y H, et al.. Development of a highly efficient gene targeting system allowing rapid genetic manipulations in Penicillium decumbens [J]. Appl. Microbiol. Biotechnol., 2010, 87(3): 1065-1076.
17	XI K, SHAN L, YANG Y, et al.. Species diversity and chemotypes of Fusarium species associated with maize stalk rot in Yunnan Province of Southwest China[J/OL]. Front. Microbiol., 2021, 12: 652062[2021-10-20]. .
18	MARTINS M P, GOMES E V, SANCHES P R, et al.. Mus-52 disruption and metabolic regulation in Neurospora crassa: transcriptional responses to extracellular phosphate availability[J/OL]. PLoS ONE, 2018, 13(4): e0195871[2023-10-30]. .
19	ZHOU J, LI S M. Conversion of viridicatic acid to crustosic acid by cytochrome P450 enzyme-catalysed hydroxylation and spontaneous cyclisation[J]. Appl. Microbiol. Biotechnol., 2021, 105(24): 9181-9189.
20	FENG J, LI W, HWANG S F, et al.. Enhanced gene replacement frequency in KU70 disruption strain of Stagonospora nodorum [J]. Microbiol. Res., 2012, 167(3): 173-178.
21	HOFF B, KAMEREWERD J, SIGL C, et al.. Homologous recombination in the antibiotic producer Penicillium chrysogenum: strain DeltaPcku70 shows up-regulation of genes from the HOG pathway[J]. Appl. Microbiol. Biotechnol., 2010, 85(4): 1081-1094.
22	TAKAHASHI T, MASUDA T, KOYAMA Y. Enhanced gene targeting frequency in Ku70 and Ku80 disruption mutants of Aspergillus sojae and Aspergillus oryzae [J]. Mol. Genet. Genom., 2006, 275(5): 460-470.
23	许铭,尹志远,高明煜,等.苹果树腐烂病菌高效基因敲除受体菌株ΔVmKu80的构建[J].西北农业学报,2016,25(2):298-305.
	XU M, YIN Z Y, GAO M Y, et al.. Construction of enhanced gene deletion frequency recipient strain ΔVmKu80 in Valsa mali[J]. Acta Agric. Boreali Occidentalis Sin., 2016, 25(2): 298-305.
24	QI X, SU X, GUO H, et al.. A Ku70 null mutant improves gene targeting frequency in the fungal pathogen Verticillium dahliae [J]. World J. Microbiol. Biotechnol., 2015, 31(12): 1889-1897.
25	HAARMANN T, LORENZ N, TUDZYNSKI P. Use of a nonhomologous end joining deficient strain (Deltaku70) of the ergot fungus Claviceps purpurea for identification of a nonribosomal peptide synthetase gene involved in ergotamine biosynthesis[J]. Fungal Genet. Biol., 2008, 45(1): 35-44.
26	WANG H, PERRAULT A R, TAKEDA Y, et al.. Biochemical evidence for Ku-independent backup pathways of NHEJ[J/OL]. Nucleic Acids Res., 2020, 48(9): 5200[2023-10-20]. .
27	DAI Z, POMRANING K R, DENG S, et al.. Deletion of the KU70 homologue facilitates gene targeting in Lipomyces starkeyi strain NRRL Y-11558[J]. Curr. Genet., 2019, 65(1): 269-282.

引物	引物序列（5’→3’）
1F	5’-GATTACGAATTCGAGCTCGGTACCACTCCTTGTTGGTCTTGCCT-3’
1R	5’-ATCTCTAGAGGATCCCCGGGTACCATTGATACGATTGATGTCTG-3’
2F	5’-GTCGACCTGCAGGCATGCAAGCTTGACTGAGGTCGAAGGGCAAA-3’
2R	5’-AAAACGACGGCCAGTGCCAAGCTTAATATGTAAAAGTCCAACCC-3’
3F	5’-GATTACGAATTCGAGCTCGGTACCCTCCGATACCAAGCCAGCA-3’
3R	5’-ATCTCTAGAGGATCCCCGGGTACCTCATACCCATCATCGTCTTG-3’
4F	5’-GTCGACCTGCAGGCATGCAAGCTTGAGTGAATCATAGGGCCTTG-3’
4R	5’-AAAACGACGGCCAGTGCCAAGCTTACATCTCTGGGTGTTGCGAA-3’
7F	5’-GGGTAAGGATCACCTTGATA-3’
7R	5’-TTAAAGGCAATCGCGATCGA-3’
8F	5’-TCCATCAGCATACCACTCCT-3’
8R	5’-ATAGACTCGAAGATGGTGAG-3’
HYR	5’-GTATTGACCGATTCCTTGCGGTCCGAA-3’
YGF	5’-GATGTAGGAGGGCGTGGATATGTCCT-3’
HYF	5’-ATGAAAAAGCCTGAACTC-3’
YGR	5’-TTCCTTTGCCCTCGGACG-3’
Hyg-F	5’-ATGAAAAAGCCTGAACTCAC-3’
Hyg-R	5’-CTATTCCTTTGCCCTCGGAC-3’
Ku70F	5’-GATGACTTGGGTGACATTTC-3’
Ku70R	5’-GTCCAAAGGAGGAAACTGGT-3’
Ku80F	5’-GGAGACGAGAAATTCGACCT-3’
Ku80R	5’-CTGAAGAATTCTGTAGTGCC-3’
pyrG-up-F	5’-GATTACGAATTCGAGCTCGGTACCCATAAAAACCATGAACCATT-3’
pyrG-up-R	5’-ATCTCTAGAGGATCCCCGGGTACCGAGGTGAGAGGTGAGAGGTG-3’
pyrG-dw-F	5’-GTCGACCTGCAGGCATGCAAGCTTTGGAAGTCGGGACGGCCTTG-3’
pyrG-dw-R	5’-AAAACGACGGCCAGTGCCAAGCTTAGCCTTGTACCTTTCCTTGA-3’
pyrG-u1300-F	5’-TAACCGTCTCAGACCTGAAAG-3’
pyrG-d1300-R	5’-TCGGATAGTACTGCCAGTTGA-3’
pyrG-in-F	5’-CAAGGCCTCGGTTGCATCTC-3’
pyrG-in-R	5’-CCATGTCATAATGCGTCTTGA-3’
pyrG-F/	5’-CGACATTCCACCCATTTACGC-3’
pyrG-R	5’-GACGTGGTGAATCGGCCGACT-3’

引物	引物序列（5’→3’）
1F	5’-GATTACGAATTCGAGCTCGGTACCACTCCTTGTTGGTCTTGCCT-3’
1R	5’-ATCTCTAGAGGATCCCCGGGTACCATTGATACGATTGATGTCTG-3’
2F	5’-GTCGACCTGCAGGCATGCAAGCTTGACTGAGGTCGAAGGGCAAA-3’
2R	5’-AAAACGACGGCCAGTGCCAAGCTTAATATGTAAAAGTCCAACCC-3’
3F	5’-GATTACGAATTCGAGCTCGGTACCCTCCGATACCAAGCCAGCA-3’
3R	5’-ATCTCTAGAGGATCCCCGGGTACCTCATACCCATCATCGTCTTG-3’
4F	5’-GTCGACCTGCAGGCATGCAAGCTTGAGTGAATCATAGGGCCTTG-3’
4R	5’-AAAACGACGGCCAGTGCCAAGCTTACATCTCTGGGTGTTGCGAA-3’
7F	5’-GGGTAAGGATCACCTTGATA-3’
7R	5’-TTAAAGGCAATCGCGATCGA-3’
8F	5’-TCCATCAGCATACCACTCCT-3’
8R	5’-ATAGACTCGAAGATGGTGAG-3’
HYR	5’-GTATTGACCGATTCCTTGCGGTCCGAA-3’
YGF	5’-GATGTAGGAGGGCGTGGATATGTCCT-3’
HYF	5’-ATGAAAAAGCCTGAACTC-3’
YGR	5’-TTCCTTTGCCCTCGGACG-3’
Hyg-F	5’-ATGAAAAAGCCTGAACTCAC-3’
Hyg-R	5’-CTATTCCTTTGCCCTCGGAC-3’
Ku70F	5’-GATGACTTGGGTGACATTTC-3’
Ku70R	5’-GTCCAAAGGAGGAAACTGGT-3’
Ku80F	5’-GGAGACGAGAAATTCGACCT-3’
Ku80R	5’-CTGAAGAATTCTGTAGTGCC-3’
pyrG-up-F	5’-GATTACGAATTCGAGCTCGGTACCCATAAAAACCATGAACCATT-3’
pyrG-up-R	5’-ATCTCTAGAGGATCCCCGGGTACCGAGGTGAGAGGTGAGAGGTG-3’
pyrG-dw-F	5’-GTCGACCTGCAGGCATGCAAGCTTTGGAAGTCGGGACGGCCTTG-3’
pyrG-dw-R	5’-AAAACGACGGCCAGTGCCAAGCTTAGCCTTGTACCTTTCCTTGA-3’
pyrG-u1300-F	5’-TAACCGTCTCAGACCTGAAAG-3’
pyrG-d1300-R	5’-TCGGATAGTACTGCCAGTTGA-3’
pyrG-in-F	5’-CAAGGCCTCGGTTGCATCTC-3’
pyrG-in-R	5’-CCATGTCATAATGCGTCTTGA-3’
pyrG-F/	5’-CGACATTCCACCCATTTACGC-3’
pyrG-R	5’-GACGTGGTGAATCGGCCGACT-3’

[1]	Licun LIANG, Wenlong LIU, Xiaoqing LIU, Bin YAO, Huoqing HUANG, Haomeng YANG. The Effect of Chemical Reagents on the Efficiency of Gene Editing in Aspergillus tubingensis [J]. Current Biotechnology, 2024, 14(4): 586-593.
[2]	LI Wei-wei1,2, ZHANG Ji1, CHEN Chao-ru1, WANG Zhi1, QU Juan-juan2, DUN Bao-qing1, LI Gui-ying1, LU Ming1. Research on the Effects of CIT2 Gene on Xylose Utilization of the Recombinant Saccharomyces cerevisiae [J]. Curr. Biotech., 2016, 6(6): 455-461.
[3]	GAO Li, CHEN Yan, HU Ting-mao, LI Guang-peng*. The Latest Research Progress of Myostatin in Mammals [J]. Curr. Biotech., 2014, 4(6): 381-388.
[4]	SU Yue-yan, WANG Xu-jing, WANG Zhi-xing*. Research Progress on Marker-free Plant Transgenic Technology [J]. Curr. Biotech., 2013, 3(3): 157-161.
[5]	XIAO Shui-hua1,2, HONG Qin-yang1,3, LIN Yan-zhen1,2, LI Jin-yu1,2. Research and Application of Gene Knockout Technology in Bacillus* [J]. Curr. Biotech., 2013, 3(2): 81-84.
[6]	ZHANG Chen, ZHOU Zheng-fu, CHEN Ming, LIN Min, ZHANG Wei. Research Progress on DNA Repair Mode and Functional Proteins Involved in the Extreme Radiation Resistant Deinococcus radiodurans* [J]. Curr. Biotech., 2013, 3(2): 103-108.
[7]	ZHANG Ya-xu. Research Summary on DNA Recombination Technology [J]. journal1, 2012, 2(1): 57-63.
[8]	ZHANG Xiao-juan, WEN Yin*. Ku Gene in Microorganisms [J]. journal1, 2011, 1(1): 26-31.

Highly Efficient Gene Knockout Method in Fusarium verticillioides Using Nonhomologous End-joining Deficiency

利用非同源末端连接缺陷构建拟轮枝镰孢菌的高效基因敲除方法

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 8

References 27

Related Articles 8

Recommended Articles

Metrics

Comments