Abstract
BackgroundThe infant intestinal microbiome plays an important role in metabolism and immune development with impacts on lifelong health. The linkage between the taxonomic composition of the microbiome and its metabolic phenotype is undefined and complicated by redundancies in the taxon-function relationship within microbial communities. To inform a more mechanistic understanding of the relationship between the microbiome and health, we performed an integrative statistical and machine learning-based analysis of microbe taxonomic structure and metabolic function in order to characterize the taxa-function relationship in early life.ResultsStool samples collected from infants enrolled in the New Hampshire Birth Cohort Study (NHBCS) at approximately 6-weeks (n = 158) and 12-months (n = 282) of age were profiled using targeted and untargeted nuclear magnetic resonance (NMR) spectroscopy as well as DNA sequencing of the V4-V5 hypervariable region from the bacterial 16S rRNA gene. There was significant inter-omic concordance based on Procrustes analysis (6 weeks: p = 0.056; 12 months: p = 0.001), however this association was no longer significant when accounting for phylogenetic relationships using generalized UniFrac distance metric (6 weeks: p = 0.376; 12 months: p = 0.069). Sparse canonical correlation analysis showed significant correlation, as well as identifying sets of microbe/metabolites driving microbiome-metabolome relatedness. Performance of machine learning models varied across different metabolites, with support vector machines (radial basis function kernel) being the consistently top ranked model. However, predictive R2 values demonstrated poor predictive performance across all models assessed (avg: − 5.06% -- 6 weeks; − 3.7% -- 12 months). Conversely, the Spearman correlation metric was higher (avg: 0.344–6 weeks; 0.265–12 months). This demonstrated that taxonomic relative abundance was not predictive of metabolite concentrations.ConclusionsOur results suggest a degree of overall association between taxonomic profiles and metabolite concentrations. However, lack of predictive capacity for stool metabolic signatures reflects, in part, the possible role of functional redundancy in defining the taxa-function relationship in early life as well as the bidirectional nature of the microbiome-metabolome association. Our results provide evidence in favor of a multi-omic approach for microbiome studies, especially those focused on health outcomes.
Highlights
The infant intestinal microbiome plays an important role in metabolism and immune development with impacts on lifelong health
Our results suggest a degree of overall association between taxonomic profiles and metabolite concentrations
Primary analyses were performed on paired microbiome-metabolome data sets on samples collected at approximately 6 weeks (N = 158 samples) and 12 months (N = 282 samples) of age (65 subjects have paired samples collected at both time points)
Summary
The infant intestinal microbiome plays an important role in metabolism and immune development with impacts on lifelong health. There is a need to understand how the microbiome participates in the multifactorial pathways leading to long-term disease outcomes. One key to this open question lies in the currently undefined relationship between the taxonomic structure of the microbiome and its metabolic phenotype. Previous studies addressing this question have mainly focused on DNA-based profiling of microbial functional potential, which, due to complicated regulatory mechanisms at the cellular level beyond the genome, is not equivalent to the microbiota’s realized functional landscape [7]
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