A quantitative sequencing framework for absolute abundance measurements of mucosal and lumenal microbial communities

A fundamental goal in microbiome studies is determining which microbes affect host physiology. Standard methods for determining changes in microbial taxa measure relative, rather than absolute abundances. Moreover, studies often analyze only stool, despite microbial diversity differing substantially among gastrointestinal (GI) locations. Here, we develop a quantitative framework to measure absolute abundances of individual bacterial taxa by combining the precision of digital PCR with the high-throughput nature of 16S rRNA gene amplicon sequencing. In a murine ketogenic-diet study, we compare microbial loads in lumenal and mucosal samples along the GI tract. Quantitative measurements of absolute (but not relative) abundances reveal decreases in total microbial loads on the ketogenic diet and enable us to determine the differential effects of diet on each taxon in stool and small-intestine mucosa samples. This rigorous quantitative microbial analysis framework, appropriate for diverse GI locations enables mapping microbial biogeography of the mammalian GI tract and more accurate analyses of changes in microbial taxa in microbiome studies. Changes in microbial taxa are commonly derived from estimations of relative abundance, which inherently limits the depth of the analysis. Here, the authors present an absolute quantification method based on digital PCR anchoring and 16S rRNA gene sequencing and show how a ketogenic diet affects individual taxon’s absolute abundance in stool and small-intestine mucosa samples in mice