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嗜热木质芽孢杆菌木聚糖酶的生产受到种群多样化的损害,但可以通过管理欺骗行为来减轻。

Xylanase production by Thermobacillus xylanilyticus is impaired by population diversification but can be mitigated based on the management of cheating behavior.

机构信息

INRAE, FARE, UMR A 614, Chaire AFERE, Université de Reims Champagne Ardenne, 51097, Reims, France.

Laboratory of Microbial Processes and Interactions, TERRA Teaching and Research Centre, Gembloux Agro-Bio Tech, University of Liege, Avenue de la Faculté 2B, B140, 5030, Gembloux, Belgium.

出版信息

Microb Cell Fact. 2022 Mar 15;21(1):39. doi: 10.1186/s12934-022-01762-z.

DOI:10.1186/s12934-022-01762-z
PMID:35292016
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8922903/
Abstract

BACKGROUND

The microbial production of hemicellulasic cocktails is still a challenge for the biorefineries sector and agro-waste valorization. In this work, the production of hemicellulolytic enzymes by Thermobacillus xylanilyticus has been considered. This microorganism is of interest since it is able to produce an original set of thermostable hemicellulolytic enzymes, notably a xylanase GH11, Tx-xyn11. However, cell-to-cell heterogeneity impairs the production capability of the whole microbial population.

RESULTS

Sequential cultivations of the strain on xylan as a carbon source has been considered in order to highlight and better understand this cell-to-cell heterogeneity. Successive cultivations pointed out a fast decrease of xylanase activity (loss of ~ 75%) and Tx-xyn11 gene expression after 23.5 generations. During serial cultivations on xylan, flow cytometry analyses pointed out that two subpopulations, differing at their light-scattering properties, were present. An increase of the recurrence of the subpopulation exhibiting low forward scatter (FSC) signal was correlated with a progressive loss of xylanase activity over several generations. Cell sorting and direct observation of the sorted subpopulations revealed that the low-FSC subpopulation was not sporulating, whereas the high-FSC subpopulation contained cells at the onset of the sporulation stage. The subpopulation differences (growth and xylanase activity) were assessed during independent growth. The low-FSC subpopulation exhibited a lag phase of 10 h of cultivation (and xylanase activities from 0.15 ± 0.21 to 3.89 ± 0.14 IU/mL along the cultivation) and the high-FSC subpopulation exhibited a lag phase of 5 h (and xylanase activities from 0.52 ± 0.00 to 4.43 ± 0.61 over subcultivations). Serial cultivations on glucose, followed by a switch to xylan led to a ~ 1.5-fold to ~ 15-fold improvement of xylanase activity, suggesting that alternating cultivation conditions could lead to an efficient population management strategy for the production of xylanase.

CONCLUSIONS

Taken altogether, the data from this study point out that a cheating behavior is responsible for the progressive reduction in xylanase activity during serial cultivations of T. xylanilyticus. Alternating cultivation conditions between glucose and xylan could be used as an efficient strategy for promoting population stability and higher enzymatic productivity from this bacterium.

摘要

背景

微生物生产半纤维素酶混合物仍然是生物炼制行业和农业废物增值利用的一个挑战。在这项工作中,我们研究了嗜热解木聚糖菌(Thermobacillus xylanilyticus)对半纤维素酶的生产。由于该微生物能够产生一组原始的耐热半纤维素酶,特别是木聚糖酶 GH11,Tx-xyn11,因此该微生物具有重要的研究意义。然而,细胞间的异质性会影响整个微生物群体的生产能力。

结果

为了突出和更好地理解这种细胞间的异质性,我们考虑了该菌株在木聚糖作为碳源上的连续培养。连续培养表明,在 23.5 代后,木聚糖酶活性(损失约 75%)和 Tx-xyn11 基因表达迅速下降。在木聚糖的连续培养过程中,流式细胞术分析表明,存在两个在光散射特性上不同的亚群。随着几代的推移,具有低前向散射(FSC)信号的亚群的复发增加与木聚糖酶活性的逐渐丧失相关。细胞分选和对分选亚群的直接观察表明,低 FSC 亚群不产孢,而高 FSC 亚群包含处于孢子形成阶段开始的细胞。在独立生长过程中评估了亚群差异(生长和木聚糖酶活性)。低 FSC 亚群的培养滞后期为 10 小时(培养过程中木聚糖酶活性从 0.15±0.21 增加到 3.89±0.14 IU/mL),而高 FSC 亚群的培养滞后期为 5 小时(培养过程中木聚糖酶活性从 0.52±0.00 增加到 4.43±0.61)。在葡萄糖上进行连续培养,然后切换到木聚糖,可使木聚糖酶活性提高 1.5 倍至 15 倍,这表明交替培养条件可能是提高木聚糖酶生产效率的有效种群管理策略。

结论

总的来说,这项研究的数据表明,在嗜热解木聚糖菌的连续培养过程中,一种欺骗行为导致木聚糖酶活性逐渐降低。在葡萄糖和木聚糖之间交替培养条件可以作为促进该细菌种群稳定性和提高酶产量的有效策略。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/ccd2aead06c1/12934_2022_1762_Fig1_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/b87daa25e0e1/12934_2022_1762_Fig3_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/72e3191bc5d1/12934_2022_1762_Fig4_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/1b6812fd7e68/12934_2022_1762_Fig5_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/874cf19e0405/12934_2022_1762_Fig6_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/a5f8611a0a6d/12934_2022_1762_Fig7_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/d60d17943b31/12934_2022_1762_Fig8_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f9f/8922903/8e2dcaab5d3a/12934_2022_1762_Fig9_HTML.jpg

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