College of Biological Engineering, Henan University of Technology, Zhengzhou 450001, Henan, China.
College of Biological Engineering, Henan University of Technology, Zhengzhou 450001, Henan, China.
Int J Food Microbiol. 2021 May 16;346:109168. doi: 10.1016/j.ijfoodmicro.2021.109168. Epub 2021 Mar 17.
Knowledge of the effects of various strains of acetic acid bacteria (AAB) on sourdough remains limited. In this study, the diversity of microbial taxa in sourdoughs fermented by different starters was assessed and their functional capacity was evaluated via high-throughput metagenomics sequencing. Results showed that Erwinia (29.43%), Pantoea (45.89%), and Enterobacter (9.16%) were predominant in the blank CK treatment. Lactobacillus (91.40%), Saccharomyces (6.13%), as well as the AAB genus Acetobacter (0.61%) were the dominant microbial genera in the sourdoughs started by yeast and a strain of lactic acid bacteria (YL treatment). By contrast, the dominant genera in the sourdoughs started by yeasts and various LAB and AAB strains (YLA treatment) were Komagataeibacter (0.39%) except for the inoculated Lactobacillus (68.37%), Acetobacter (20.17%), and Saccharomyces (8.31%) species. Functional prediction of these changes in microbial community and diversity revealed that various metabolism-related pathways, including alanine, aspartate, and glutamate metabolism (21.95%), as well as amino acid biosynthesis (19.14%), were predominant in the sourdoughs started by yeast and an AAB strain (YA treatment). Moreover, arginine biosynthesis (11.65%) were the dominant pathways in the YL treatment. The fermented dough added with sourdoughs started with yeast + AAB and yeast + AAB + LAB strains had substantially higher contents (more than 48.58% in total) of essential amino acids than the dough added with sourdoughs started with yeast + LAB strain. These results demonstrated that amino acid biosynthesis has a beneficial effect on sourdoughs inoculated with an AAB strain.
关于不同醋酸菌(AAB)菌株对面团的影响的知识仍然有限。在这项研究中,评估了不同发酵剂发酵的面团中微生物类群的多样性,并通过高通量宏基因组测序评估了它们的功能能力。结果表明,在空白 CK 处理中,肠杆菌属(29.43%)、泛菌属(45.89%)和肠杆菌属(9.16%)占优势。在酵母和一株乳酸菌(YL 处理)启动的面团中,乳杆菌(91.40%)、酿酒酵母(6.13%)以及 AAB 属醋酸菌(0.61%)是主要的微生物属。相比之下,在酵母和各种 LAB 和 AAB 菌株启动的面团(YLA 处理)中,除了接种的乳杆菌(68.37%)、醋酸菌(20.17%)和酿酒酵母(8.31%)外,优势属为Komagataeibacter(0.39%)。对微生物群落和多样性变化的功能预测表明,各种代谢相关途径,包括丙氨酸、天冬氨酸和谷氨酸代谢(21.95%)和氨基酸生物合成(19.14%)在酵母和 AAB 菌株启动的面团中占主导地位(YA 处理)。此外,精氨酸生物合成(11.65%)是 YL 处理中的主要途径。添加了由酵母+AAB 和酵母+AAB+LAB 菌株启动的酸面团的发酵面团中必需氨基酸的含量显著高于添加了由酵母+LAB 菌株启动的酸面团的发酵面团(总含量超过 48.58%)。这些结果表明,氨基酸生物合成对接种 AAB 菌株的酸面团具有有益作用。
