生物
微生物群
转录组
基因组
瘤胃
计算生物学
生态系统
寄主(生物学)
微生物生态学
表型
适应(眼睛)
代谢组学
表型可塑性
进化生物学
遗传学
系统生物学
代谢途径
微生物种群生物学
生态学
宿主适应
细胞生物学
核糖核酸
转录因子
模式生物
微生物代谢
抄写(语言学)
基因表达谱
基因
生物信息学
基因组学
末端限制性片段长度多态性
RNA序列
环境变化
作者
Sanbao Zhang,Qinyang Jiang,Junjie Ma,J. H. Zou,Fan Wang,Feifei Lv,Yanna Huang,Yongcheng Wang,Ziye Xu
摘要
The adaptation of complex, host-associated microbiomes to environmental perturbations is a critical determinant of ecosystem stability and resilience to climate change, as exemplified in ruminants. While single-microbe RNA sequencing advances community interrogation, complex microbial cell walls severely constrain unbiased single-cell transcriptomic profiling in the rumen. In this study, we developed an optimized 25 min time-resolved enzymatic lysis strategy using smRandom-seq to map the sheep rumen microbiome at single-cell resolution. By profiling 60 748 cells across 21 samples, we captured previously intractable lineages, resolving the transcriptional states of 213 genera and 662 species, achieving a physiologically relevant 0.303% recovery of methanogenic archaea. Unsupervised clustering partitioned the ecosystem into seven cross-species functional clusters, uncovering a spatial coupling between microbial lifestyle and metabolic specialization. Applying this framework to a model of host thermal adaptation demonstrated that host resilience was associated with rapid transcriptional activation of key energy-metabolism clusters. Notably, a lineage-specific metabolic shift toward a glycolytic phenotype in Anaerovibrio lipolyticus contributes to a compensatory "nutritional sparing" effect associated with host resilience. This dataset provides a foundational resource for rumen microbial ecology and establishes a technical framework for dissecting phenotypic plasticity within complex microbiomes.
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