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基于转录组学鉴定增强酵母中异源蛋白分泌的新因子。

Transcriptomics-based identification of novel factors enhancing heterologous protein secretion in yeasts.

作者信息

Gasser Brigitte, Sauer Michael, Maurer Michael, Stadlmayr Gerhard, Mattanovich Diethard

机构信息

Institute of Applied Microbiology, Department of Biotechnology, University of Natural Resources and Applied Life Sciences Vienna, Muthgasse 18, A-1190 Vienna, Austria.

出版信息

Appl Environ Microbiol. 2007 Oct;73(20):6499-507. doi: 10.1128/AEM.01196-07. Epub 2007 Aug 31.

Abstract

Efficient production of heterologous proteins with yeasts and other eukaryotic hosts is often hampered by inefficient secretion of the product. Limitation of protein secretion has been attributed to a low folding rate, and a rational solution is the overexpression of proteins supporting folding, like protein disulfide isomerase (Pdi), or the unfolded protein response transcription factor Hac1. Assuming that other protein factors which are not directly involved in protein folding may also support secretion of heterologous proteins, we set out to analyze the differential transcriptome of a Pichia pastoris strain overexpressing human trypsinogen versus that of a nonexpressing strain. Five hundred twenty-four genes were identified to be significantly regulated. Excluding those genes with totally divergent functions (like, e.g., core metabolism), we reduced this number to 13 genes which were upregulated in the expression strain having potential function in the secretion machinery and in stress regulation. The respective Saccharomyces cerevisiae homologs of these genes, including the previously characterized secretion helpers PDI1, ERO1, SSO2, KAR2/BiP, and HAC1 as positive controls, were cloned and overexpressed in a P. pastoris strain expressing a human antibody Fab fragment. All genes except one showed a positive effect on Fab fragment secretion, as did the controls. Six out of these novel secretion helper factors, more precisely Bfr2 and Bmh2 (involved in protein transport), the chaperones Ssa4 and Sse1, the vacuolar ATPase subunit Cup5, and Kin2 (a protein kinase connected to exocytosis), proved their benefits for practical application in laboratory-scale production processes by increasing both specific production rates and the volumetric productivity of an antibody fragment up to 2.5-fold in fed-batch fermentations of P. pastoris.

摘要

利用酵母和其他真核宿主高效生产异源蛋白常常受到产物分泌效率低下的阻碍。蛋白质分泌受限被认为是折叠速率较低所致,一个合理的解决方案是过表达支持折叠的蛋白质,如蛋白质二硫键异构酶(Pdi)或未折叠蛋白反应转录因子Hac1。假设其他不直接参与蛋白质折叠的蛋白质因子也可能支持异源蛋白的分泌,我们着手分析过表达人胰蛋白酶原的毕赤酵母菌株与未表达菌株的差异转录组。共鉴定出524个基因受到显著调控。排除那些功能完全不同的基因(如核心代谢相关基因)后,我们将这个数字减少到13个,这些基因在表达菌株中上调,在分泌机制和应激调节方面具有潜在功能。这些基因各自的酿酒酵母同源物,包括先前已鉴定的分泌辅助因子PDI1、ERO1、SSO2、KAR2/BiP和HAC1作为阳性对照,被克隆并在表达人抗体Fab片段的毕赤酵母菌株中过表达。除一个基因外,所有基因对Fab片段的分泌均显示出积极作用,阳性对照也是如此。其中六个新的分泌辅助因子,更确切地说是Bfr2和Bmh2(参与蛋白质转运)、分子伴侣Ssa4和Sse1、液泡ATP酶亚基Cup5以及Kin2(一种与胞吐作用相关的蛋白激酶),在毕赤酵母的补料分批发酵中,通过提高抗体片段的比生产率和体积产率达2.5倍,证明了它们在实验室规模生产过程中的实际应用价值。

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