工业上重要真菌的快速和稳健的压扁孢子/菌落PCR。

Q1 Agricultural and Biological Sciences
Guoliang Yuan, Jeffrey J Czajka, Ziyu Dai, Dehong Hu, Kyle R Pomraning, Beth A Hofstad, Joonhoon Kim, Ana L Robles, Shuang Deng, Jon K Magnuson
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引用次数: 0

摘要

背景:真菌在医学、农业和工业上的应用已经有几个世纪了。系统生物学技术的发展使这些真菌的设计和代谢工程能够从可再生原料中生产新的燃料、化学品和酶。为了操纵基因组和快速创造突变体,已经开发了许多遗传工具。然而,在许多工业真菌的设计、构建、测试和学习周期中,筛选和确认转化体仍然是一个效率低下的步骤,因为提取真菌基因组DNA既费力又耗时,而且涉及有毒化学物质。结果:在这项研究中,我们开发了一种快速而强大的技术,称为“南瓜PCR”,可以打开孢子并释放真菌基因组DNA作为PCR的模板。研究了Squash-PCR在11株不同丝状真菌中的应用效果。所有被试真菌均获得了纯度高的PCR产物。孢子年龄和DNA聚合酶类型对南瓜pcr的效率没有影响。然而,在黑曲霉中,孢子浓度被发现是南瓜PCR的关键因素,起始材料的稀释通常会导致更高的PCR产物产量。然后,我们进一步评估了压扁程序对九种不同酵母菌株的适用性。我们发现,与直接集落PCR相比,squsquash -PCR可以提高所测试酵母菌的集落PCR的质量和产量。结论:该技术将提高丝状真菌和酵母菌转化子的筛选效率,加快基因工程的发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Rapid and robust squashed spore/colony PCR of industrially important fungi.

Rapid and robust squashed spore/colony PCR of industrially important fungi.

Rapid and robust squashed spore/colony PCR of industrially important fungi.

Rapid and robust squashed spore/colony PCR of industrially important fungi.

Background: Fungi have been utilized for centuries in medical, agricultural, and industrial applications. Development of systems biology techniques has enabled the design and metabolic engineering of these fungi to produce novel fuels, chemicals, and enzymes from renewable feedstocks. Many genetic tools have been developed for manipulating the genome and creating mutants rapidly. However, screening and confirmation of transformants remain an inefficient step within the design, build, test, and learn cycle in many industrial fungi because extracting fungal genomic DNA is laborious, time-consuming, and involves toxic chemicals.

Results: In this study we developed a rapid and robust technique called "Squash-PCR" to break open the spores and release fungal genomic DNA as a template for PCR. The efficacy of Squash-PCR was investigated in eleven different filamentous fungal strains. Clean PCR products with high yields were achieved in all tested fungi. Spore age and type of DNA polymerase did not affect the efficiency of Squash-PCR. However, spore concentration was found to be the crucial factor for Squash-PCR in Aspergillus niger, with the dilution of starting material often resulting in higher PCR product yield. We then further evaluated the applicability of the squashing procedure for nine different yeast strains. We found that Squash-PCR can be used to improve the quality and yield of colony PCR in comparison to direct colony PCR in the tested yeast strains.

Conclusion: The developed technique will enhance the efficiency of screening transformants and accelerate genetic engineering in filamentous fungi and yeast.

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来源期刊
Fungal Biology and Biotechnology
Fungal Biology and Biotechnology Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics
CiteScore
10.20
自引率
0.00%
发文量
17
审稿时长
9 weeks
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