Preparation and potential antitumor activity of alginate oligosaccharides degraded by alginate lyase from Cobetia marina

LWT Pub Date : 2023-09-01 DOI:10.1016/j.lwt.2023.115332

Lei Liu, Xing Chen, Yalin Li, Lu Yuan, Yu Rao

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Abstract

High-pressure processing (HPP) is considered effective for sterilizing minimally processed vegetable-based products. This study found that HPP could not completely inactivate the microorganisms in pickles. Candida albicans (C. albicans), an opportunistic pathogen in pickles, survived HPP exposure, while its death rate did not increase significantly with a further increase in holding time and pressure. It was striking that the biofilm formation and hyphae growth of C. albicans survived from 400 MPa HPP increased. Transcriptome analysis showed that 400 MPa affected more C. albicans genes than 300 MPa. The treatment at 300 MPa mainly facilitated transmembrane transport changes, while 400 MPa modified several metabolic processes. Furthermore, different pressure conditions caused various changes in important biofilm/hyphae-related genes, many of which were downregulated after 300 MPa treatment while upregulated after exposure to 400 MPa (NDT80, BRG1, GZF3, UME6, SET3, PES1, XOG1, RHR2, and SUN41). In addition, the GDH3, HGT9, and AAT21 genes may also play a vital role in the C. albicans tolerance of HPP. These findings emphasized the potential increased risk caused by the inability of HPP to inactive yeasts in food industry.

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褐藻酸解酶降解褐藻酸寡糖的制备及其潜在的抗肿瘤活性

高压处理(HPP)被认为是有效的灭菌最低限度加工蔬菜为基础的产品。本研究发现，HPP不能完全灭活泡菜中的微生物。酸菜中的条件致病菌白色念珠菌(C. albicans)在高温高压下存活，但其死亡率不随保温时间和压力的增加而显著增加。结果表明，在400 MPa高温高压下，存活的白色念珠菌的生物膜形成和菌丝生长明显增加。转录组分析显示，400 MPa对白色念珠菌基因的影响大于300 MPa。300 MPa处理主要促进了跨膜转运的变化，而400 MPa处理则改变了几个代谢过程。此外，不同的压力条件导致重要的生物膜/菌丝相关基因发生不同的变化，其中许多基因在300 MPa处理后下调，而在400 MPa处理后上调(NDT80、BRG1、GZF3、UME6、SET3、PES1、XOG1、RHR2和SUN41)。此外，GDH3、HGT9和AAT21基因也可能在白色念珠菌对HPP的耐受中发挥重要作用。这些发现强调了HPP对食品工业中失活酵母的无能造成的潜在风险增加。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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