经典菌株改良程序对产β-内酰胺的产黄青霉影响的基因组突变分析

Genomic mutational analysis of the impact of the classical strain improvement program on β-lactam producing Penicillium chrysogenum.

作者信息

Salo Oleksandr V, Ries Marco, Medema Marnix H, Lankhorst Peter P, Vreeken Rob J, Bovenberg Roel A L, Driessen Arnold J M

机构信息

Molecular Microbiology, Groningen Biomolecular Sciences and Biotechnology Institute, University of Groningen, Groningen, The Netherlands.

Division of Analytical Biosciences, Leiden/Amsterdam Center for Drug Research, Leiden, The Netherlands.

出版信息

BMC Genomics. 2015 Nov 14;16:937. doi: 10.1186/s12864-015-2154-4.

DOI:10.1186/s12864-015-2154-4

PMID:26572918

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4647614/

Abstract

BACKGROUND

Penicillium chrysogenum is a filamentous fungus that is employed as an industrial producer of β-lactams. The high β-lactam titers of current strains is the result of a classical strain improvement program (CSI) starting with a wild-type like strain more than six decades ago. This involved extensive mutagenesis and strain selection for improved β-lactam titers and growth characteristics. However, the impact of the CSI on the secondary metabolism in general remains unknown.

RESULTS

To examine the impact of CSI on secondary metabolism, a comparative genomic analysis of β-lactam producing strains was carried out by genome sequencing of three P. chrysogenum strains that are part of a lineage of the CSI, i.e., strains NRRL1951, Wisconsin 54-1255, DS17690, and the derived penicillin biosynthesis cluster free strain DS68530. CSI has resulted in a wide spread of mutations, that statistically did not result in an over- or underrepresentation of specific gene classes. However, in this set of mutations, 8 out of 31 secondary metabolite genes (20 polyketide synthases and 11 non-ribosomal peptide synthetases) were targeted with a corresponding and progressive loss in the production of a range of secondary metabolites unrelated to β-lactam production. Additionally, key Velvet complex proteins (LeaA and VelA) involved in global regulation of secondary metabolism have been repeatedly targeted for mutagenesis during CSI. Using comparative metabolic profiling, the polyketide synthetase gene cluster was identified that is responsible for sorbicillinoid biosynthesis, a group of yellow-colored metabolites that are abundantly produced by early production strains of P. chrysogenum.

CONCLUSIONS

The classical industrial strain improvement of P. chrysogenum has had a broad mutagenic impact on metabolism and has resulted in silencing of specific secondary metabolite genes with the concomitant diversion of metabolism towards the production of β-lactams.

摘要

背景

产黄青霉是一种丝状真菌，被用作β-内酰胺类抗生素的工业生产菌株。当前菌株的高β-内酰胺产量是六十多年前从类似野生型菌株开始的经典菌株改良计划（CSI）的结果。这涉及广泛的诱变和菌株筛选，以提高β-内酰胺产量和生长特性。然而，CSI对次级代谢的总体影响仍然未知。

结果

为了研究CSI对次级代谢的影响，通过对属于CSI谱系的三株产黄青霉菌株（即NRRL1951、Wisconsin 54-1255、DS17690菌株以及衍生的无青霉素生物合成簇菌株DS68530）进行全基因组测序，对产β-内酰胺菌株进行了比较基因组分析。CSI导致了广泛的突变，从统计学角度来看，这些突变并未导致特定基因类别的过度或不足表达。然而，在这组突变中，31个次级代谢产物基因（20个聚酮合酶和11个非核糖体肽合成酶）中有8个成为靶点，导致一系列与β-内酰胺生产无关的次级代谢产物产量相应且逐渐下降。此外，参与次级代谢全局调控的关键Velvet复合蛋白（LeaA和VelA）在CSI过程中多次成为诱变靶点。通过比较代谢谱分析，鉴定出了负责山梨素类生物合成的聚酮合酶基因簇，山梨素类是产黄青霉早期生产菌株大量产生的一组黄色代谢产物。

结论

产黄青霉的经典工业菌株改良对代谢产生了广泛的诱变影响，导致特定次级代谢产物基因沉默，同时使代谢转向β-内酰胺的生产。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d47a/4647614/8f52faaacbb3/12864_2015_2154_Fig1_HTML.jpg

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经典菌株改良程序对产β-内酰胺的产黄青霉影响的基因组突变分析

Genomic mutational analysis of the impact of the classical strain improvement program on β-lactam producing Penicillium chrysogenum.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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