基于 Omics 的研究:嗜麦芽单胞菌 DHHJ 在生物降解过程中控制角蛋白单体细胞内化的机制。

Pub Date : 2024-01-01 Epub Date: 2024-07-17 DOI:10.1159/000540072
Kai Xue, XiaoXiao Song, Wei Zhang, YunLong Zhang, Ting Chen, ZhangJun Cao, Feng Hong, XingQun Zhang
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引用次数: 0

摘要

导言:全球家禽业每年产生数百万吨废弃羽毛,这些羽毛可以降解制成饲料、肥料和日用化学品。然而,羽毛降解是一个复杂的过程,人们尚未完全了解。这导致降解效率低下,难以进行工业应用。Omics 驱动的系统生物学研究为快速全面地了解代谢途径中涉及的分子和机制提供了有效的解决方案:在这一过程的早期阶段,羽毛被水解成水溶性角蛋白单体。本研究利用高通量 RNA-seq 技术分析了嗜麦芽糖酵母菌 DHHJ 株细胞中参与角蛋白单体内化和降解的基因。此外,我们还利用 Co-IP 与 LC-MS/MS 技术来寻找与重组角蛋白单体相互作用的蛋白质:结果:我们发现了与角蛋白单体相关的TonB转运蛋白和分子伴侣蛋白,它们可能在角蛋白的跨膜转运过程中发挥了关键作用。同时,我们还发现了属于不同家族的多种蛋白酶与角蛋白单体的结合伙伴,其中与多种细胞活动相关的ATP酶(AAA+)家族蛋白酶所占比例较高。研究人员选取了四个基因作为代表,包括JJL50_15620、JJL50_17955(TonB依赖性受体)、JJL50_03260(ABC转运体ATP结合蛋白)和JJL50_20035(ABC转运体底物结合蛋白),利用qRT-PCR测定它们在不同培养条件下的表达量,结果发现它们在角蛋白降解过程中上调,这与RNA-seq和Co-IP的数据一致:本研究强调了嗜麦芽糖酵母菌DHHJ角蛋白生物降解的复杂性,其中涉及多种途径,如蛋白质折叠、蛋白质转运和多种蛋白酶系统。我们的研究结果为了解羽毛降解机制提供了新的视角。
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Omics-Based Investigation on Mechanisms Controlling Cellular Internalization of Keratin Monomers during Biodegradation by Stenotrophomonas maltophilia DHHJ.

Introduction: The global poultry industry produces millions of tons of waste feathers every year, which can be bio-degraded to make feed, fertilizer, and daily chemicals. However, feather bio-degradation is a complex process that is not yet fully understood. This results in low degradation efficiency and difficulty in industrial applications. Omics-driven system biology research offers an effective solution to quickly and comprehensively understand the molecularmechanisms involved in a metabolic pathway.

Methods: In the early stage of this process, feathers are hydrolyzed into water-soluble keratin monomers. In this study, we used high-throughput RNA-seq technology to analyze the genes involved in the internalization and degradation of keratin monomers in Stenotrophomonas maltophilia DHHJ strain cells. Moreover, we used Co-IP with LC-MS/MS technology to search for proteins that interact with recombinant keratin monomers.

Results: We discovered TonB transports and molecular chaperones associating with the keratin monomer, which may play a crucial role in the transmembrane transport of keratin. Meanwhile, multiple proteases belonging to distinct families were identified as binding partners of keratin monomers, among which ATPases associated with diverse cellular activity (AAA+) family proteases are overrepresented. Four genes, including JJL50_15620, JJL50_17955 (TonB-dependent receptors), JJL50_03260 (ABC transporter ATP-binding protein), and JJL50_20035 (ABC transporter substrate-binding protein), were selected as representatives for determining their expressions under different culture conditions using qRT-PCR, and they were found to be upregulated in response to keratin degradation consistent with the data from RNA-seq and Co-IP.

Conclusion: This study highlights the complexity of keratin biodegradation in S. maltophilia DHHJ, in which multiple pathways are involved such as protein folding, protein transport, and several protease systems. Our findings provide new insights into the mechanism of feather degradation.

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