Transformation and gene-disruption in the apple-pathogen, Neonectria ditissima.

IF 2.7 3区生物学 Hereditas Pub Date : 2022-08-12 DOI:10.1186/s41065-022-00244-x

Heriberto Vélëz, Jonas Skytte Af Sätra, Firuz Odilbekov, Salim Bourras, Larisa Garkava-Gustavsson, Kerstin Dalman

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Abstract

Background: Apple production in Sweden and elsewhere is being threatened by the fungus, Neonectria ditissima, which causes a disease known as European canker. The disease can cause extensive damage and the removal of diseased wood and heavily infected trees can be laborious and expensive. Currently, there is no way to eradicate the fungus from infected trees and our knowledge of the infection process is limited. Thus, to target and modify genes efficiently, the genetic transformation technique developed for N. ditissima back in 2003 was modified.

Results: The original protocol from 2003 was upgraded to use enzymes currently available in the market for making protoplasts. The protoplasts were viable, able to uptake foreign DNA, and able to regenerate back into a mycelial colony, either as targeted gene-disruption mutants or as ectopic mutants expressing the green fluorescent protein (GFP).

Conclusions: A new genetic transformation protocol has been established and the inclusion of hydroxyurea in the buffer during the protoplast-generation step greatly increased the creation of knockout mutants via homologous recombination. Pathogenicity assays using the GFP-mutants showed that the mutants were able to infect the host and cause disease.

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苹果病原菌新树突菌的转化与基因破坏。

背景:瑞典和其他地方的苹果生产正受到一种真菌的威胁，这种真菌会导致一种被称为欧洲溃疡病的疾病。这种疾病可造成广泛的损害，清除患病木材和严重感染的树木可能既费力又昂贵。目前，没有办法从受感染的树木中根除真菌，我们对感染过程的了解也很有限。因此，为了有效地靶向和修饰基因，对2003年发展起来的山毛草遗传转化技术进行了改进。结果:2003年的原始方案被升级为使用目前市场上可用的酶来制造原生质体。原生质体是有活力的，能够吸收外源DNA，并能够再生回菌丝集落，无论是作为靶向基因破坏突变体还是作为表达绿色荧光蛋白(GFP)的异位突变体。结论:建立了一种新的遗传转化方案，在原生质体产生步骤中，在缓冲液中加入羟基脲可以通过同源重组大大增加敲除突变体的产生。利用gfp突变体进行的致病性试验表明，突变体能够感染宿主并引起疾病。

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来源期刊

Hereditas Biochemistry, Genetics and Molecular Biology-Genetics

CiteScore

3.80

自引率

3.70%

发文量

期刊介绍： For almost a century, Hereditas has published original cutting-edge research and reviews. As the Official journal of the Mendelian Society of Lund, the journal welcomes research from across all areas of genetics and genomics. Topics of interest include human and medical genetics, animal and plant genetics, microbial genetics, agriculture and bioinformatics.