Abstract
This study aimed to elaborate the assembly processes and metabolic regulation of the microbial community under the conditions of environmental factors and artificial intervention using broad bean paste (BBP) fermentation as a tractable research object. Spatial heterogenicity of amino acid nitrogen, titratable acidity, and volatile metabolites were observed between upper and lower layers after fermentation for 2 weeks. Amino nitrogen contents in the upper fermented mash reached 0.86, 0.93, and 1.06 g/100 g at 2, 4, and 6 weeks, respectively, which were significantly higher than those of mash located at the lower layer (0.61, 0.79, and 0.78 g/100 g). Moreover, higher concentrations of titratable acidity were accumulated in upper layers (2.05, 2.25 and 2.56 g/100g) than those in lower layers, and the differentiation of volatile metabolites was the greatest (R = 0.543) at 36 days, after which the BBP flavor profiles converged with the fermentation progress. The successive heterogenicity of the microbial community in the mid-late stage was also found during fermentation, and Zygosaccharomyces, Staphylococcus, and Bacillus had heterogeneous characteristics driven by sunlight, water activity, and microbial interactions. This study provided new insights into the mechanisms underlying the succession and assembly of the microbial community of BBP fermentation, which also laid new clues for researches of the microbial communities in complex ecosystems. IMPORTANCE Gaining insights into the community assembly processes is essential and valuable for the elaboration of underlying ecological patterns. However, current studies about microbial community succession in multispecies fermented food usually treat the research object as a whole, are focused exclusively on temporal dimensions, and have ignored the changes of community structure in spatial dimensions. Therefore, dissecting the community assembly process from the view of spatiotemporal dimensions will be a more comprehensive and detailed perspective. Here, we found the heterogenicity of the BBP microbial community under the traditional production technology from spatial and temporal scales, systematically analyzed the relationship between the spatiotemporal succession of community and the difference of BBP quality, and elucidated the roles of environmental factors and microbial interactions to drive the heterogeneous succession of the microbial community. Our findings provide a new insight into understanding the association between microbial community assembly and the quality of BBP.