Multispecies solid-state fermentation is a traditional processing technique for the traditional Chinese food,such as cereal vinegar,Baijiu,etc.Generally,few abundant and many rare microbes were involved in such proces...Multispecies solid-state fermentation is a traditional processing technique for the traditional Chinese food,such as cereal vinegar,Baijiu,etc.Generally,few abundant and many rare microbes were involved in such processes,and the necessity and roles of the latter are less studied.Here the co-occurrence patterns of abundant and rare bacterial community and abiotic factors infuencing their community assembly were investigated in acetic acid fermentation following starter inoculation,using Zhenjiang aromatic vinegar as a model system.Abundant taxa that contribute to the function of accumulating acid exhibited a ubiquitous distribution while the distribution of rare taxa along the fermentation process unraveled.The species composition of the rare taxa signifcantly altered,but abundant taxa were maintained after inoculation.Moreover,the diversity of rare taxa changed more signifcantly than that of abundant taxa.Both abundant and rare sub-communities,which were contributed more with species turnover than species richness,were demonstrated to be driven by pH,acetic acid,ammonium nitrogen,and ethanol.Stochastic processes regulated the assembly of both sub-communities,but more prominent on rare sub-communities.Co-occurrence network was more governed by rare sub-communities,and the co-variations between microbial communities were predominantly positive,implying that rare taxa played more important role in the fermentation stability and network robustness.Furthermore,seven network connectors were identifed,and three of them belonged to rare taxa.These microbes of diferent modules were enriched at particular phases of fermentation.These results demonstrate the ecological signifcance of rare bacteria and provide new insights into understanding the abiotic factors infuence microbial structure in traditional fermented foods.展开更多
基金This work was supported by National Key R&D Program of China(2018YFC1603800 and 2018YFC1603802)Natural Science Foundation of China(NSFC)(No.31771967)We thank Jiangsu Hengshun Vinegar Industry Co,Ltd,for the samples provided.
文摘Multispecies solid-state fermentation is a traditional processing technique for the traditional Chinese food,such as cereal vinegar,Baijiu,etc.Generally,few abundant and many rare microbes were involved in such processes,and the necessity and roles of the latter are less studied.Here the co-occurrence patterns of abundant and rare bacterial community and abiotic factors infuencing their community assembly were investigated in acetic acid fermentation following starter inoculation,using Zhenjiang aromatic vinegar as a model system.Abundant taxa that contribute to the function of accumulating acid exhibited a ubiquitous distribution while the distribution of rare taxa along the fermentation process unraveled.The species composition of the rare taxa signifcantly altered,but abundant taxa were maintained after inoculation.Moreover,the diversity of rare taxa changed more signifcantly than that of abundant taxa.Both abundant and rare sub-communities,which were contributed more with species turnover than species richness,were demonstrated to be driven by pH,acetic acid,ammonium nitrogen,and ethanol.Stochastic processes regulated the assembly of both sub-communities,but more prominent on rare sub-communities.Co-occurrence network was more governed by rare sub-communities,and the co-variations between microbial communities were predominantly positive,implying that rare taxa played more important role in the fermentation stability and network robustness.Furthermore,seven network connectors were identifed,and three of them belonged to rare taxa.These microbes of diferent modules were enriched at particular phases of fermentation.These results demonstrate the ecological signifcance of rare bacteria and provide new insights into understanding the abiotic factors infuence microbial structure in traditional fermented foods.
