Castellaniella defragrans 厌氧 β-月桂烯降解途径缺失突变体的生理学研究。

Physiology of deletion mutants in the anaerobic β-myrcene degradation pathway in Castellaniella defragrans.

机构信息

Dep, of Microbiology, Max Planck Institute for Marine Microbiology, Bremen, Germany.

出版信息

BMC Microbiol. 2012 Sep 4;12:192. doi: 10.1186/1471-2180-12-192.

DOI:10.1186/1471-2180-12-192

PMID:22947208

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3490891/

Abstract

BACKGROUND

Monoterpenes present a large and versatile group of unsaturated hydrocarbons of plant origin with widespread use in the fragrance as well as food industry. The anaerobic β-myrcene degradation pathway in Castellaniella defragrans strain 65Phen differs from well known aerobic, monooxygenase-containing pathways. The initial enzyme linalool dehydratase-isomerase ldi/LDI catalyzes the hydration of β-myrcene to (S)-(+)-linalool and its isomerization to geraniol. A high-affinity geraniol dehydrogenase geoA/GeDH and a geranial dehydrogenase geoB/GaDH contribute to the formation of geranic acid.A genetic system was for the first time applied for the betaproteobacterium to prove in vivo the relevance of the linalool dehydratase-isomerase and the geraniol dehydrogenase. In-frame deletion cassettes were introduced by conjugation and two homologous recombination events.

RESULTS

Polar effects were absent in the in-frame deletion mutants C. defragrans Δldi and C. defragrans ΔgeoA. The physiological characterization of the strains demonstrated a requirement of the linalool dehydratase-isomerase for growth on acyclic monoterpenes, but not on cyclic monoterpenes. The deletion of geoA resulted in a phenotype with hampered growth rate on monoterpenes as sole carbon and energy source as well as reduced biomass yields. Enzyme assays revealed the presence of a second geraniol dehydrogenase. The deletion mutants were in trans complemented with the broad-host range expression vector pBBR1MCS-4ldi and pBBR1MCS-2geoA, restoring in both cases the wild type phenotype.

CONCLUSIONS

In-frame deletion mutants of genes in the anaerobic β-myrcene degradation revealed novel insights in the in vivo function. The deletion of a high-affinity geraniol dehydrogenase hampered, but did not preclude growth on monoterpenes. A second geraniol dehydrogenase activity was present that contributes to the β-myrcene degradation pathway. Growth on cyclic monoterpenes independent of the initial enzyme LDI suggests the presence of a second enzyme system activating unsaturated hydrocarbons.

摘要

背景

单萜是一类具有广泛用途的植物源不饱和烃，包括香料和食品工业。Castellaniella defragrans 菌株 65Phen 中的厌氧 β-月桂烯降解途径与已知的需氧、含单加氧酶的途径不同。初始酶芳樟醇脱水酶-异构酶 ldi/LDI 催化 β-月桂烯水合生成（S）-（+）-芳樟醇及其异构化为香叶醇。高亲和力的香叶醇脱氢酶 geoA/GeDH 和牻牛儿醛脱氢酶 geoB/GaDH 有助于形成庚酸。首次应用遗传系统来证明β-变形菌体内的 linalool dehydratase-isomerase 和 geraniol dehydrogenase 的相关性。通过共轭和两个同源重组事件引入了框内缺失盒。

结果

在框内缺失突变体 C. defragrans Δldi 和 C. defragrans ΔgeoA 中不存在极性效应。菌株的生理特征表明，linalool dehydratase-isomerase 对于环状单萜烯的生长是必需的，但对于环状单萜烯则不是必需的。geoA 的缺失导致了在单萜烯作为唯一碳源和能源时生长速度受阻以及生物量产量降低的表型。酶测定表明存在第二种牻牛儿醛脱氢酶。缺失突变体在转座子上用广谱宿主表达载体 pBBR1MCS-4ldi 和 pBBR1MCS-2geoA 进行互补，在两种情况下均恢复了野生型表型。

结论

在厌氧β-月桂烯降解中的基因框内缺失突变体揭示了体内功能的新见解。高亲和力的香叶醇脱氢酶的缺失阻碍了，但并没有排除单萜烯的生长。存在第二种牻牛儿醛脱氢酶活性，有助于β-月桂烯降解途径。不依赖于初始酶 LDI 生长表明存在第二个激活不饱和烃的酶系统。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/adc6/3490891/6829c6e7c7db/1471-2180-12-192-1.jpg

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Castellaniella defragrans 厌氧 β-月桂烯降解途径缺失突变体的生理学研究。

Physiology of deletion mutants in the anaerobic β-myrcene degradation pathway in Castellaniella defragrans.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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