用于一氧化碳依赖性产氢机制组成型表达的Y19

Y19 for constitutive expression of carbon monoxide-dependent hydrogen-production machinery.

作者信息

Ainala Satish Kumar, Seol Eunhee, Kim Jung Rae, Park Sunghoon

机构信息

School of Chemical and Biomolecular Engineering, Pusan National University, San 30, Jangeon-dong, Geumjeong-gu, Busan, 609-735 Republic of Korea.

出版信息

Biotechnol Biofuels. 2017 Mar 28;10:80. doi: 10.1186/s13068-017-0770-8. eCollection 2017.

DOI:10.1186/s13068-017-0770-8

PMID:28360938

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5371261/

Abstract

BACKGROUND

Y19 is a good biocatalyst for production of hydrogen (H) from oxidation of carbon monoxide (CO) via the so-called water-gas-shift reaction (WGSR). It has a high H-production activity (23.83 mmol H g cell h) from CO, and can grow well to a high density on various sugars. However, its H-production activity is expressed only when CO is present as an inducer and in the absence of glucose.

RESULTS

In order to avoid dependency on CO and glucose, in the present study, the native CO-inducible promoters of WGSR operons (CO dehydrogenase, CODH, and CODH-dependent hydrogenase, CO-) in Y19 were carefully analyzed and replaced with strong and constitutive promoters screened from Y19. One engineered strain (Y19-PR1), selected from three positive ones after screening ~10,000 colonies, showed a similar CO-dependent H-production activity to that of wild-type Y19, without being affected by glucose and/or CO. Compared with wild-type Y19, transcription of the CODH operon in Y19-PR1 increased 1.5-fold, although that of the CO- operon remained at a similar level. To enhance the activity of CO-Hyd in Y19-PR1, further modifications, including an increase in gene copy number and engineering of the 5' untranslated region, were attempted, but without success.

CONCLUSIONS

Convenient recombinant Y19-PR1 that expresses CO-dependent H-production activity without being limited by CO and glucose was obtained.

摘要

背景

Y19是一种优良的生物催化剂，可通过所谓的水煤气变换反应（WGSR）将一氧化碳（CO）氧化以生产氢气（H）。它从CO产生氢气的活性很高（23.83 mmol H g细胞 h），并且可以在各种糖类上良好生长至高密度。然而，其产氢活性仅在有CO作为诱导剂且无葡萄糖存在时才表达。

结果

为了避免对CO和葡萄糖的依赖，在本研究中，对Y19中WGSR操纵子（CO脱氢酶，CODH，以及依赖CODH的氢化酶，CO-）的天然CO诱导型启动子进行了仔细分析，并用从Y19中筛选出的强组成型启动子进行了替换。在筛选了约10,000个菌落之后，从三个阳性菌株中选出的一个工程菌株（Y19-PR1）显示出与野生型Y19相似的依赖CO的产氢活性，且不受葡萄糖和/或CO的影响。与野生型Y19相比，Y19-PR1中CODH操纵子的转录增加了1.5倍，而CO-操纵子的转录水平保持相似。为了提高Y19-PR1中CO-Hyd的活性，尝试了进一步的修饰，包括增加基因拷贝数和对5'非翻译区进行工程改造，但未成功。

结论

获得了方便的重组体Y19-PR1，其表达依赖CO的产氢活性，且不受CO和葡萄糖的限制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5b02/5371261/793532f4b4ae/13068_2017_770_Fig1_HTML.jpg

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用于一氧化碳依赖性产氢机制组成型表达的Y19

Y19 for constitutive expression of carbon monoxide-dependent hydrogen-production machinery.

作者信息

Ainala Satish Kumar, Seol Eunhee, Kim Jung Rae, Park Sunghoon

机构信息

School of Chemical and Biomolecular Engineering, Pusan National University, San 30, Jangeon-dong, Geumjeong-gu, Busan, 609-735 Republic of Korea.