Exopolysaccharide production in fermented milk using Lactobacillus casei strains AP and AG.

IF 2.7 Q3 MICROBIOLOGY AIMS Microbiology Pub Date : 2022-04-25 eCollection Date: 2022-01-01 DOI:10.3934/microbiol.2022012

Hafidh Shofwan Maajid, Nurliyani Nurliyani, Widodo Widodo

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引用次数: 1

Abstract

This study evaluated the ability of two strains of bacterial starter cultures, Lactobacillus casei AP (AP) and Lactobacillus casei AG (AG), to produce exopolysaccharides (EPSs). First, the physicochemical properties of the fermented milk produced by AP and AG were assessed, including physical qualities like viscosity and syneresis and chemical qualities, such as pH, acidity, protein, lactose, fat content, and total solid. Then, AP and AG's ability to produce EPS was measured. Additionally, the EPS' microstructure was observed using a scanning electron microscope, and its chemical structure was assessed using Fourier transform-infrared (FT-IR) spectroscopy. Also, AP and AG's ability to produce EPS was tracked at the molecular level by studying the glycosyltransferase (gtf) gene. Statistical analysis showed that the milk fermented using AP and AG had similar physicochemical qualities (P > 0.05) but significantly different physical qualities (P < 0.05). Additionally, the milk fermented with AP had lower viscosity (1137.33 ± 34.31 centiPoise) than AG (1221.50 ± 20.66 centiPoise). In addition, the milk fermented using AP had higher syneresis (19.42%) than AG (17.83%). The higher viscosity and lower syneresis in the milk fermented using AG were associated with AG's ability to produce more EPS (1409 mg/L) than AP (1204 mg/L). In addition, according to the FT-IR analysis, the AP- and AG-synthesized EPS contained absorption bands at 3323, 2980, 2901, 1642, 1084, 1043, and 873 cm^-1. The absorption band at 1642 and 2980 cm^-1 corresponds to carbonyl and methylene groups, respectively. Absorption band 873 cm^-1 is characteristic of the α-glycosidic bond of α-glucan in EPS. Moreover, the absorption bands on the wavelength region corresponding to the functional groups in the AP- and AG-produced EPS were similar to those in commercially available EPS. Lastly, gtf, contributing to EPS synthesis, was found in the genomes of AP and AG, suggesting the role of glycosyltransferase in the EPS synthesis by both strains.

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利用干酪乳杆菌AP和AG菌株生产发酵乳中的外多糖。

本研究评价了两株发酵剂干酪乳杆菌AP (AP)和干酪乳杆菌AG (AG)产生胞外多糖(eps)的能力。首先，对AP和AG生产的发酵乳的理化性质进行了评估，包括粘度和协同作用等物理性质以及pH、酸度、蛋白质、乳糖、脂肪含量和总固形物等化学性质。然后测定AP和AG产生EPS的能力。此外，利用扫描电镜观察了EPS的微观结构，并利用傅里叶变换红外(FT-IR)光谱分析了EPS的化学结构。此外，通过研究糖基转移酶(gtf)基因，在分子水平上追踪了AP和AG产生EPS的能力。统计分析表明，AP和AG发酵的乳理化品质相近(P > 0.05)，但物理品质差异显著(P < 0.05)。此外，添加AP发酵的乳粘度(1137.33±34.31厘泊)低于添加AG发酵的(1221.50±20.66厘泊)。此外，用AP发酵的乳的增效率(19.42%)高于AG(17.83%)。AG发酵乳中较高的粘度和较低的协同作用与AG产生的EPS (1409 mg/L)高于AP (1204 mg/L)有关。此外，根据FT-IR分析，AP-和ag -合成的EPS在3323、2980、2901、1642、1084、1043和873 cm-1处有吸收带。1642和2980 cm-1处的吸收带分别对应羰基和亚甲基。873 cm-1是EPS中α-葡聚糖α-糖苷键的特征吸收带。此外，AP-和ag -制备的EPS中官能团对应波长区域的吸收带与市售EPS相似。最后，在AP和AG的基因组中发现了参与EPS合成的gtf，提示糖基转移酶在这两种菌株的EPS合成中发挥了作用。

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