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"使用实验室自动化和贝叶斯优化进行催化活性包涵体的高通量筛选"。

"High-throughput screening of catalytically active inclusion bodies using laboratory automation and Bayesian optimization".

机构信息

Institute of Bio- and Geosciences IBG-1: Biotechnology, Forschungszentrum Jülich GmbH, 52425, Jülich, Germany.

Institute of Biotechnology, RWTH Aachen University, 52074, Aachen, Germany.

出版信息

Microb Cell Fact. 2024 Feb 24;23(1):67. doi: 10.1186/s12934-024-02319-y.

DOI:10.1186/s12934-024-02319-y
PMID:38402403
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10894497/
Abstract

BACKGROUND

In recent years, the production of inclusion bodies that retain substantial catalytic activity was demonstrated. These catalytically active inclusion bodies (CatIBs) are formed by genetic fusion of an aggregation-inducing tag to a gene of interest via short linker polypeptides. The resulting CatIBs are known for their easy and cost-efficient production, recyclability as well as their improved stability. Recent studies have outlined the cooperative effects of linker and aggregation-inducing tag on CatIB activities. However, no a priori prediction is possible so far to indicate the best combination thereof. Consequently, extensive screening is required to find the best performing CatIB variant.

RESULTS

In this work, a semi-automated cloning workflow was implemented and used for fast generation of 63 CatIB variants with glucose dehydrogenase of Bacillus subtilis (BsGDH). Furthermore, the variant BsGDH-PT-CBDCell was used to develop, optimize and validate an automated CatIB screening workflow, enhancing the analysis of many CatIB candidates in parallel. Compared to previous studies with CatIBs, important optimization steps include the exclusion of plate position effects in the BioLector by changing the cultivation temperature. For the overall workflow including strain construction, the manual workload could be reduced from 59 to 7 h for 48 variants (88%). After demonstration of high reproducibility with 1.9% relative standard deviation across 42 biological replicates, the workflow was performed in combination with a Bayesian process model and Thompson sampling. While the process model is crucial to derive key performance indicators of CatIBs, Thompson sampling serves as a strategy to balance exploitation and exploration in screening procedures. Our methodology allowed analysis of 63 BsGDH-CatIB variants within only three batch experiments. Because of the high likelihood of TDoT-PT-BsGDH being the best CatIB performer, it was selected in 50 biological replicates during the three screening rounds, much more than other, low-performing variants.

CONCLUSIONS

At the current state of knowledge, every new enzyme requires screening for different linker/aggregation-inducing tag combinations. For this purpose, the presented CatIB toolbox facilitates fast and simplified construction and screening procedures. The methodology thus assists in finding the best CatIB producer from large libraries in short time, rendering possible automated Design-Build-Test-Learn cycles to generate structure/function learnings.

摘要

背景

近年来,已经证明可以生产保留大量催化活性的包涵体。这些具有催化活性的包涵体(CatIB)是通过短连接多肽将聚集诱导标签与目的基因进行遗传融合而形成的。这些具有催化活性的包涵体以其易于生产、成本效益高、可回收以及稳定性提高而著称。最近的研究概述了连接子和聚集诱导标签对 CatIB 活性的协同作用。然而,目前还不可能进行预先预测以指示最佳的组合。因此,需要进行广泛的筛选以找到性能最佳的 CatIB 变体。

结果

在这项工作中,实施了半自动化克隆工作流程,并用于快速生成枯草芽孢杆菌葡萄糖脱氢酶(BsGDH)的 63 种 CatIB 变体。此外,变体 BsGDH-PT-CBDCell 用于开发、优化和验证自动化 CatIB 筛选工作流程,从而可以并行分析许多 CatIB 候选物。与以前的 CatIB 研究相比,重要的优化步骤包括通过改变培养温度来消除 BioLector 中的板位效应。对于包括菌株构建在内的整个工作流程,对于 48 个变体(88%),手动工作量可从 59 小时减少到 7 小时。在 42 个生物学重复中相对标准偏差为 1.9%的情况下,证明了高度重现性后,该工作流程与贝叶斯过程模型和汤普森抽样相结合。虽然过程模型对于得出 CatIB 的关键性能指标至关重要,但汤普森抽样是在筛选过程中平衡开发和探索的策略。我们的方法允许在仅三个批次实验中分析 63 种 BsGDH-CatIB 变体。由于 TDoT-PT-BsGDH 极有可能成为最佳 CatIB 表现者,因此在三个筛选轮次的 50 个生物学重复中选择了它,比其他表现不佳的变体更多。

结论

根据目前的知识状态,每种新酶都需要针对不同的连接子/聚集诱导标签组合进行筛选。为此,本文提出的 CatIB 工具箱简化了快速构建和筛选的过程。该方法可以帮助在短时间内从大型文库中找到最佳的 CatIB 生产者,从而实现自动化的设计-构建-测试-学习循环,以生成结构/功能学习。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/8ea8175d777b/12934_2024_2319_Fig7_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/6dd7978901d2/12934_2024_2319_Fig1_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/03f003fb718a/12934_2024_2319_Fig4_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/8ba47cd258ee/12934_2024_2319_Fig5_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/0a4c9ec5b937/12934_2024_2319_Fig6_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/8ea8175d777b/12934_2024_2319_Fig7_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/6dd7978901d2/12934_2024_2319_Fig1_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/6ca871b2823d/12934_2024_2319_Fig2_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/8d1ba6c10869/12934_2024_2319_Fig3_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/03f003fb718a/12934_2024_2319_Fig4_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/8ba47cd258ee/12934_2024_2319_Fig5_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/0a4c9ec5b937/12934_2024_2319_Fig6_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2102/10894497/8ea8175d777b/12934_2024_2319_Fig7_HTML.jpg

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